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A rapid and sensitive method for detection of calcineurin and calmodulin binding proteins using biotinylated calmodulin
Abstract
Purified bovine brain calmodulin was biotinylated with biotinyl-epsilon-aminocaproic acid N-hydroxysuccinimide. Biotinylated calmodulin was used to detect and quantify calmodulin-binding proteins following both protein blotting and slot-blot procedures by using alkaline phosphatase or peroxidase coupled to avidin. When purified bovine brain calcineurin, a calmodulin-dependent protein phosphatase, was immobilized on nitrocellulose slot blots, biotinylated calmodulin bound in a calcium-dependent saturable manner; these blots were then quantified by densitometry. Biotinylated calmodulin was able to detect as little as 10 ng of calcineurin, and the binding was competitively inhibited by addition of either native calmodulin or trifluoperazine. When biotinylated calmodulin was used to probe protein blots of crude brain cytosol and membrane preparations after gel electrophoresis, only protein bands characteristic of known calmodulin-binding proteins (i.e., calmodulin-dependent protein kinase, calcineurin, spectrin) were detected with avidin-peroxidase or avidin-alkaline phosphatase procedures. Purified calcineurin was subjected to one- and two-dimensional gel electrophoresis and protein blotting; as expected, only the 61-kDa calmodulin-binding subunit was detected. When the two-dimensional protein blot was incubated with biotinylated calmodulin and detected with avidin-alkaline phosphatase, several apparent forms of the 61-kDa catalytic subunit were detected, consistent with isozymic species of the enzyme. The results of these studies suggest that biotinylated calmodulin can be used as a simple, sensitive, and quantifiable probe for the study of calmodulin-binding proteins.
... Labelling of CUM-binding proteins in protein blots (after Billingsley et al., 1985). Proteins were isolated and separated by SDS-PAGE (13%, w/v, acrylamide) (St Leger et al., 1989a), transferred to nitrocellulose and probed for 1 h with biotinylated CaM (10 pg ml-I) in buffer (50 mM-Tris/HCl, pH 7.4, 300 mM-NaC1, 1 m~-CaCl,, 5%, w/v, nonfat dry milk). ...
... Proteins were isolated and separated by SDS-PAGE (13%, w/v, acrylamide) (St Leger et al., 1989a), transferred to nitrocellulose and probed for 1 h with biotinylated CaM (10 pg ml-I) in buffer (50 mM-Tris/HCl, pH 7.4, 300 mM-NaC1, 1 m~-CaCl,, 5%, w/v, nonfat dry milk). Specific CaM-binding proteins were visualized with avidin-alkaline-phosphatase and appropriate chromogens (Billingsley et al., 1985). In order to demonstrate Ca2+-dependence of binding, 5 mM-EGTA was used for certain blots instead of 1 mM-Ca2+. ...
Protein synthesis and phosphorylation were studied in Metarhizium anisopliae. Calmodulin (CaM) and CaM-target proteins were found in conidia and germlings of M. anisopliae. Conidial uptake of [35S]methionine and [32P]orthophosphate and their incorporation into protein was massively reduced by known antagonists of CaM, depletion of intracellular Ca2+ by ionophoresis or antagonism of Ca2+ with La3+, agents which prevented nuclear division and germination. Inhibitors of C-kinase (H-7) and cyclic-nucleotide-dependent kinase (H-8) selectively repressed phosphorylation of a 27 kDa protein but did not affect the profile of protein synthesis nor change germination frequency and mode of growth. By contrast, inhibitor and ionophoresis studies on mycelia showed that extracellular secretion of proteins but not protein synthesis was Ca2+-dependent. Protein phosphorylation in mycelia was also Ca2+-dependent/ CaM-independent. CaM antagonists stimulated phosphorylation of 17 and 33 kDa polypeptides. Most proteins in mycelia were phosphorylated at serine and threonine residues. However, immunoblotting with anti-phosphotyrosine serum revealed prominent bands at 34.5 and 38 kDa. The 38 kDa protein was detectable on isolated plasma membranes. Our results suggest that M. anisopliae possesses stimulus transduction pathways similar to those known in plant and animal systems.
... 1. Incubate 189 μL of 20 mM biotinoyl-ε-aminocaproic acid NHS ester in N,N-dimethylformamide with purified recombinant S100A6 protein (2.4 mg) in 2 mL PBS at molar ratio of 16:1 at 4 C for 2 h with constant stirring [8]. ...
S100A6 is a member of the EF-hand Ca²⁺-binding protein family, which plays important roles in a wide variety of Ca²⁺ signaling in the cells, as well as in pathophysiological conditions. Herein, we describe analytical protocols for evaluating the interaction of S100A6 with multiple target proteins in vitro, including biotinylated S100A6 overlay, glutathione-S-transferase (GST)-precipitation, surface plasmon resonance, and a GST-precipitation assay in living cells. These methods will elucidate the detailed molecular mechanisms of S100A6/target interactions and further improve our understanding of the physiological significance of S100A6-mediated Ca²⁺ signaling. Moreover, they may be used to evaluate other physical S100/target interactions.
... The nitrocellulose sheet was blocked with 5% BSA in TBS (25 mM Tris-HCL pH 8.8, 150 mM NaCl, 2.7 mM KCl) containing 0.1% Tween-20. Specific CaM-binding proteins were visualized based on the protocol previously described by Billingsley et al. [42]. Briefly, the blots were incubated with 0.9 mg/ml of CaM-biotinylated (diluted 1/2000) and followed by detection with streptavidin conjugated to peroxidase (diluted 1:3000). ...
Trypanosoma equiperdum belongs to the subgenus Trypanozoon, which has a significant socio-economic impact by limiting animal protein productivity worldwide. Proteins involved in the intracellular Ca²⁺ regulation are prospective chemotherapeutic targets since several drugs used in experimental treatment against trypanosomatids exert their action through the disruption of the parasite intracellular Ca²⁺ homeostasis. Therefore, the plasma membrane Ca²⁺-ATPase (PMCA) is considered as a potential drug target. This is the first study revealing the presence of a PMCA in T. equiperdum (TePMCA) showing that it is calmodulin (CaM) sensitive, revealed by ATPase activity, western-blot analysis and immuno-absorption assays. The cloning sequence for TePMCA encodes a 1080 amino acid protein which contains domains conserved in all PMCAs so far studied. Molecular modeling predicted that the protein has 10 transmembrane and three cytoplasmic loops which include the ATP-binding site, the phosphorylation domain and Ca²⁺ translocation site. Like all PMCAs reported in other trypanosomatids, TePMCA lacks a classic CaM binding domain. Nevertheless, this enzyme presents in the C-terminal tail a region of 28 amino acids (TeC28), which most likely adopts a helical conformation within a 1-18 CaM binding motif. Molecular docking between Trypanosoma cruzi CaM (TcCaM) and TeC28 shows a significant similarity with the CaM-C28PMCA4b reference structure (2kne). TcCaM-TeC28 shows an anti-parallel interaction, the peptide wrapped by CaM and the anchor buried in the hydrophobic pocket, structural characteristic described for similar complexes. Our results allows to conclude that T. equiperdum possess a CaM-sensitive PMCA, which presents a non-canonical CaM binding domain that host a 1-18 motif.
... Recombinant rat CaM was expressed using plasmid pET-CaM (kindly provided by Dr. N. Hayashi, Tokyo Institute of Technology, Yokohama, Japan) and purified as previously described [23]. Purified recombinant CaM (5 mg) was biotinylated with biotinyl--aminocaproic acid-N-hydroxysuccimide methy ester [24] followed by purification with phenyl-Sepharose chromatography. FLAG/GST-tagged Venus, IgG, and FLAG/GST-tagged human proteins including CaMKII␦-2 (NP 742126), CaMKI␣ (NP 003647), CaMKII␦-3 (NP 001212), CaMKI␦ (NP 705718), CaMKK␣ (NP 757343), and CaMKIV (NP 001735) were synthesized with a wheat germ cell-free expression system [19] using the WEPRO7240 G Expression Kit (CellFree Sciences, Matsuyama, Japan) as follows; translation reactions were performed using a bilayer method. ...
To search for novel target(s) of the Ca(2+)-signaling transducer, calmodulin (CaM), we performed a newly developed genome-wide CaM interaction screening of 19,676 GST-fused proteins expressed in human. We identified striated muscle activator of Rho signaling (STARS) as a novel CaM target and characterized its CaM binding ability and found that the Ca(2+)/CaM complex interacted stoichiometrically with the N-terminal region (Ala13-Gln35) of STARS in vitro as well as in living cells. Mutagenesis studies identified Ile20 and Trp33 as the essential hydrophobic residues in CaM anchoring. Furthermore, the CaM binding deficient mutant (Ile20Ala, Trp33Ala) of STARS further enhanced its stimulatory effect on SRF-dependent transcriptional activation. These results suggest a connection between Ca(2+)-signaling via excitation-contraction coupling and the regulation of STARS-mediated gene expression in muscles.
... Slot blots are commonly used to quantify DNA, RNA or protein (Billingsley et al. 1985;Sahm et al. 1999;Nicklas and Buel 2003). The samples are bound to a nitrocellulose membrane and then can be probed and detected by an antibody specific to the protein of interest. ...
... Biotinylated polypeptides were prepared using biotin-6- aminohexanoyl N-hydroxysuccinimide ester using the conditions described by Billingsley et al. (1985) . Purified polypeptide was incubated at 0.1 mg/mi with the reagent for 2 h at 4°Cwith gentle shaking using a 1:1 molar ratio of protein to biotin. ...
: Spectrin isotypes segregate in neurons and are differentially distributed between axons and somatodendritic compartments. Their functions in those compartments are likely to be mediated by proteins that interact selectively with one or other isotype. Fodaxin (an axon-specific protein previously termed A60) colocalizes in CNS neurons with axonal spectrin and in vitro binds brain spectrin (a mixture of αI, βI, αII, and βII polypeptides) but not erythrocyte spectrin (αI and βI). Because αII and βII spectrin polypeptides are enriched in axons, we investigated a possible binding of fodaxin to the types of spectrin found in axons. Fodaxin did not bind to isolated brain α chains. Bacterially expressed C-terminal segments 18–19 of βII spectrin bound to fodaxin and inhibited the binding of fodaxin to whole brain spectrin. By contrast, recombinant segments 18–19 of the somatodendritic βIΣ2 spectrin showed no interaction with fodaxin. Within βII, fodaxin binding activity was localized to residues 2,087–2,198, which are unique to βII and link between the end of segment 18 and the pleckstrin homology domain in segment 19. The divergent regions of sequence in segments 19 of βII and βIΣ2 are candidates to mediate the isotype-specific functions of spectrin. Fodaxin is the first protein to be described that discriminates between the unique regions of β spectrin isoforms.
... Biotinylation of CaM. Homogeneous CaM was prepared from cauliflower according to the procedure as described by Biro et al. (1984) and biotinylated according to the procedure of Billingsley et al. (1985) with small modifications. Briefly, purified cauliflower CaM was dialyzed against 0.1 M phosphate buffer (pH 7.4) overnight at 4~ Biotinamidocaproate N-hydroxysuccinimide ester (2.8 mg; Sigma Chemical Co., St. Louis, Mo., USA) was dissoved in 90 ~tl of N,N-dimethylformamide, added to 6 ml of CaM solution and made up to a final concentration of 1 mM CaM with 1 mM CaCI2; the molar ratio between the biotinylating agent and CaM was kept at 19: 1. ...
A 21-kDa calmodulin (CaM)-binding protein and a 19-kDa calmodulin-binding protein were detected in 0.1 M CaCl2 extracts of Angelica dahurica L. suspension-cultured cells and carrot (Daucus carota L.) suspension-cultured cells, respectively, using a biotinylated cauliflower CaM gel-overlay technique in the presence of 1 mM Ca2+. No bands, or very weak bands, were shown on sodium dodecyl sulfate-polyacrylamide gel electrophoresis gels overlayed with biotinylated cauliflower CaM when 1 mM Ca2+ was replaced by 5 mM EGTA, indicating that the binding of these two CaM-binding proteins to CaM was dependent on Ca2+. Less 21-kDa CaM-binding protein was found in culture medium of Angelica dahurica suspension cells; however, a 21-kDa protein was abundant in the cell wall. We believe that the 21-kDa CaM-binding protein is mainly in the cell wall of Angelica dahurica. Based on its reaction with periodic acid-Schiff (PAS) reagent, this 21-kDa protein would appear to be a glycoprotein. The 21-kDa CaM-binding protein was purified by a procedure including Sephadex G-100 gel filtration and CM-Sepharose cation-exchange column chromatography. The purity reached 91% according to gel scanning. The purified 21-kDa CaM-binding protein inhibited the activity of CaM-dependent NAD kinase and the degree of inhibition increased with augmentation of the 21-kDa protein, which appeared to be the typical characteristic of CaM-binding protein.
... Only the radioactive probes, however, were used for screening expression libraries to isolate cDNAs for CBPs (Baum et al., 1993;Fromm and Chua, 1992;Reddy et al., 1993;Sikela and Hahn, 1987;Widada et al., 1989). The biotinylated calmodulin has been shown to detect as little as 10 ng of CBP on protein blots and the sensitivity of biotinylated calmodulin is found to be comparable to lzSI-calmodulin (Billingsley et al., 1985;Walker et al., 1993). Hence, we attempted to use biotinylated calmodulin to screen expression libraries. ...
Calmodulin labeled with125I or34S has been used to screen expression libraries to isolate cDNAs encoding calmodulin-binding proteins (CBPs) from several eukaryotic
systems. The use of radiolabeled calmodulin has, however, several disadvantages. We have developed a nonradiactive method
to isolate cDNAs for CBPs using biotinylated calmodulin. Screening of a cDNA library in an expression vector with biotinylated
calmodulin resulted in the isolation of cDNAs encoding CBPs. Avidin and biotin blocking steps, prior to incubation of the
filters with biotinylated calmodulin, are found to be essential to eliminate the cDNAs that code for biotin-containing polypeptides.
The cDNA clones isolated using this nonradioactive method bound calmodulin in a calcium-dependent manner. The binding of biotinylated
calmodulin to these clones was completely abolished by ethylene glycolbis(\-aminoethylether)-N,N′-tetraacetic acid (EGTA),
a calcium chelator. Furthermore, the isolated cDNAs were confirmed by probing the clones with35S-labeled calmodulin. All the isolated clones bound to radiolabeled calmodulin in the presence of calcium but not in the presence
of EGTA. The method described here is simple, fast, and does not involve preparation and handing of radiolabeled calmodulin.
All the materials used in this method are commercially available; hence, this procedure should be widely applicable to isolate
cDNAs encoding CBPs from any eukaryotic organism.
Calmodulin (CaM) is known to function as a central signal transducer in calcium-mediated intracellular pathways. In this study, a fusion molecule of a recently developed proximity biotinylation enzyme (AirID) with rat CaM (AirID-CaM) was expressed and purified to near homogeneity using an E. coli expression system to examine the physical interactions between CaM and its target proteins by converting the interaction to biotinylation of CaM targets under nondenatured conditions. AirID-CaM catalyzed a Ca2+-dependent biotinylation of a target protein kinase (Ca2+/CaM-dependent protein kinase kinase α/1, CaMKKα/1) in vitro, which was suppressed by the addition of excess amounts of CaM, and AirID alone did not catalyze the biotinylation of CaMKKα/1, indicating that the biotinylation of CaMKKα/1 by AirID-CaM likely occurs in an interaction-dependent manner. Furthermore, we also observed the Ca2+-dependent biotinylation of GST-CaMKIα and GST-CaMKIV by AirID-CaM, suggesting that AirID-CaM can be useful for the rapid detection of CaM/target interactions with relatively high sensitivity.
The 70-kilodalton heat shock protein (hsp70) family members appear to be essential components in a number cellular protein-protein interactions. We report here on the characterization of a new functional region in hsp70, a calmodulin-binding site. We have identified a 21-amino-acid sequence within the hsp70 protein that contains a calmodulin-binding domain. The peptide formed a potential amphipathic alpha helix and bound calmodulin with high affinity. Comparison of amino acid homology of this calmodulin-binding sequence with analogous hsp70 sequences from other species showed a high degree of conservation.
An important function of the mammalian nonerythroid α-spectrin chain (α-fodrin) that distinguishes it from the closely related erythroid isoform is its ability to bind calmodulin. By analysis of a series of deleted recombinant spectrin fusion proteins, we have identified a region in the nonerythroid α chain involved in calcium-dependent binding of calmodulin. The region is distinctive in that the sequence is absent from the homologous domain of the erythroid α chain and diverges from the normal internal repeat structure observed throughout other spectrins. In order to determine limits of this functional site, a synthetic peptide as small as 24 residues was shown to compete with either recombinant or brain α-spectrin in binding to calmodulin. The active peptide, which was derived from a segment between repeats 11 and 12, was composed of the following sequence: Lys-Thr-Ala-Ser-Pro-Trp-Lys-Ser-Ala-Arg-Leu-Met-Val-His-Thr-Val-Ala-Thr-Phe-Asn - Ser-Ile-Lys-Glu. Comparison of this sequence with functional sites in other diverse calcium-dependent calmodulin-binding proteins has revealed a structural motif common to all of these proteins, namely clusters of hydrophobic residues interspersed with basic residues. When folded into α-helical conformations, these binding sites are predicted to form amphipathic structures.
Biotinylation of antibodies to be used in immunolocalization studies is a well established approach to mapping epitopes in biological specimens at both the light and ultrastructural level. Biotinylation of antibodies does not appear to significantly alter their interaction with antigen. A similar approach has been proposed for examining ligand interaction with receptors. Producing a soluble biotinylated ligand that behaves similarly to unlabeled ligand avoids the problems introduced by particulate labels such as ferritin, gold and latex. Particulate labels for ligands can be especially problematic in studies of receptor behavior in live cells since viable cells may directly react to the particulate probe itself. The interaction of plasma fibrinogen with its receptor on blood platelets, GPIIb-IIIa, is required for platelet-platelet cohesion and subsequent formation of a hemostatic platelet plug at sites of vascular injury. To study the events that follow binding of fibrinogen to its receptor5 we have produced a series of fibrinogens biotinylated with molar ratios of biotin:fibrinogen that range from 5 to 50.
Pinctada fucata, famous as one of the most important economically bivalves all over the world, is also an excellent animal model for biomineralization study, the process of which is conducted by reaction and precipitation via converting ions into solid minerals where matrix protein functions as crucial regulators (Pertea G et al, Bioinformatics 19:651–652, 2003; Conesa A et al, 21:3674–3676, 2005). In general, the studies of pearl formation could be separated into two aspects: the isolation, identification, and functional analysis of shell matrix proteins and calcium metabolism process, including Ca²⁺ absorption, transportation, storage and deposition, etc (Ye et al. 34:W293–W297, 2006). We successfully constructed three suppression subtractive hybridization (SSH) libraries and established transcriptome database to obtain and analyze novel matrix proteins and their functions. In addition, we first isolated the full-length of CaM cDNA and characterized its functions. Other calcium metabolism-related proteins, such as calmodulin-like proteins and calcineurin, were also identified, the working mechanisms of which were studied in more detail at the same time. The primary techniques adopted in this chapter comprised RNA-seq, rapid amplification of cDNA ends (RACE), cell co-localization, in situ hybridization, RNA interference, CaCO3 crystallization, etc. In summary, elucidating the underlying mechanisms of biomineralization will lead to the innovative understanding of medical sciences and materials and also provide significant technical supports for pearl shellfish farming and pearl production.
Calmodulin (CaM) is a major intracellular receptor for second messenger Ca2+ signals and is expressed in every cell of all eukaryotes, including plants. CaM transduces these signals by binding four Ca2+, and binding to and altering the activities of a variety of enzymatic, cytoskeletal, and structural proteins. This chapter presents various methods to detect plant CaM-binding proteins that exploit the simplicity with which recombinant plant CaM can be purified in milligram amounts from modest-sized cultures of induced Escherichia coli and labeled with a variety of reporters, which offer the advantages of sensitive detection of CaM-binding proteins and relatively low toxicity. The utility of these methods described for labeling CaM to use as a probe for detecting CaM-binding proteins can be illustrated by using two applications, which involve detecting CaM-binding activity in protein fractions after separation by sodium dodecyl sulfate–polyacrylamide gel electrophoresis (SDS–PAGE) and in induced lysates of recombinant bacteriophage harboring complementary DNA (cDNA) expression libraries.
Enamel cells are likely to experience heavy demands for intracellular calcium homeostasis during the secretion and hypermineralization of dental enamel. Here, the two major high-affinity calcium-binding proteins in rat enamel epithelium were identified as calbindin2gkDa and calmodulin, using a microscale approach. Both proteins were hyperabundant, totalling up to 2% of the soluble protein and surpassing the amounts in cerebellum, the benchmark tissue. Calbindin28kDa and calmodulin accounted for 26% of the total calcium-binding capacity in enamel cell cytosol, under near physiological conditions. Numerous calmodulin-binding proteins were detected with an overlay assay, indicating that calmodulin has multiple major targets in enamel cells. The calcium/calmodulin-regulated protein phosphatase, calcineurin, was identified as a principal calmodulin target constituting 0.1% of the soluble protein. Calmodulin and calcineurin were expressed constitutively, implying continued heavy usage of calcium/calmodulin-based and phosphorylation-based signalling events throughout enamel cell development. Calbindin28kDa, in contrast, was expressed at fourfold higher levels in secretion-phase cells than during the calcium-intensive hypermineralization phase, unexpectedly pointing to an important role associated with secretion. Supporting this notion, immunoblots revealed that 33 % of total (SDS-soluble) calbindin2SkDa was in the particulate fraction and predominantly associated with the Triton-insoluble cytoskeleton. Solubilisation of cytoskele-tal calbindin28kDa required high concentrations of NaCl or urea, indicating the existence of a high-affinity target ligand. The unusual abundance of calmodulin, calbindin28kDil and calcineurin demonstrated here provides the first molecular evidence that enamel cells possess a strong capability for intracellular calcium homeostasis. Since none of these proteins was up-regulated during enamel hypermineralization, it appears that other calcium-binding proteins are primarily involved in the putative transcellular passage of calcium.
USING a magnetic method which was designed for identification of CaMBPs according to the principles of affinity chromatography, we were able to isolate 3 CaMBPs with calmodulin (CaM) binding activity from the cell wall fractions of transgenic tobacco. After SDS-PAGE and CaM gel overlay analysis, we found that CaMBPs were retained and the isolation is efficient. To further identify the elute fraction as CaMBPs, the ability to reversibly inhibit the activity of CaM-activated PDE was tested. The inhibition of our potential CaMBPs to CaM-activated PDE activity was eliminated by adding an excess amount of exogenous commercial CaM. Previous results have shown that exogenously applied CaM could significantly accelerate the division and proliferation of suspension cultured cells of Daucus Carota L, and also increase the second mitosis of generative cells of Sorbaria sorbifola A. Br . During our research on photo-signal transduction, we microinjected activated CaM into the hypocotyls of etiolated transgenic tobacco seedlings with RbcS-GUS chimeric constructs and found that the RbcS promoter of transgenic tobacco plants gained function even in complete darkness. These reports indicated that extracellular CaM can affect the proliferation of both plant somatic and generative cells. Since it is relatively a large molecule, for exogenous CaM to function, its receptor(s) may be located on the exterior of the cell. Here we report the potential existence of such receptors outside the cell wall. 1 Materials and methods Leaves of five-month-old transgenic tobacco NC89 plants with RbcS-GUS chimeric gene were used as plant materials. Biotinamidocaproate N-hydroxysuccinimide ester (BCNHS) , Avidin-HRP, 3', 3'-diaminobenzidine-4HCL (DAB) and molecular weight standard, Phosphodiesterase (PDE), CAMP, EGTA, were purchased from Sigma. Plant CaM was a gift from
Antigen presentation induces lymphokine gene expression in T cells and an autocrine stimulatory pathway leading to cell growth and proliferation. Cyclosporin A (CsA) and FK-506, two potent, clinically relevant immunosuppressive compounds, function by preventing lymphokine production, particularly interleukin-2. These compounds act at the level of transcription by inhibiting the activation of a set of transcription factors that are required for initiation of lymphokine gene expression. Several of these factors have been the subject of intense scrutiny. Some, such as NF-AT (nuclear factor of activated T cells) are cell type specific, while others, such as NF-B, are ubiquitously expressed. These factors do not share a common mechanism of activation, but calcineurin, a Ca2+-dependent phosphoprotein phosphatase plays a central role in the activation of each of them. Thus, not only are these immunosuppressive drugs clinically important, but they have served as unique probes of the signal transduction pathways that lead to activation of specific transcription factors involved in lymphokine gene expression.
We recently identified a novel IQ motif-containing protein family, IQM, which shares sequence homology with a pea heavy metal-induced protein 6 and a ribosome inactivating protein, trichosanthin. Distinct expression patterns for each gene suggest that each IQM family member may play a different role in plant development and response to environmental cues. However functions of the IQM family members remain to be analyzed. IQM1 bound with calmodulin 5 (CaM5) in yeast two-hybrid assay via its IQ-motif. The CaM binding was Ca(2+)-independent in vitro, and was also observed in bimolecular fluorescence complementation analyses in onion epidermal cells. IQM1 was found to express strongly in guard cells and the cortex of roots. The T-DNA insertion mutants of IQM1 displayed a smaller stomatal aperture, a decreased water loss rate and a shorter primary root. Moreover, iqm1 did not change its stomatal aperture when treated with light, dark, ABA and chitin obviously. Microarray analyses showed that 243 and 28 genes were up- and down-regulated by more than twofold in iqm1-1, respectively. Interesting, 34 of 117 and 7 of 30 chitin-responsive transcriptional factor and ubiquitin ligase genes were up-regulated, respectively. Stomatal guard cells of iqm1-1 also showed enhanced expression of genes involved in production and signaling of reactive oxygen species (ROS). Consistently, increased ROS level was observed in the iqm1 guard cells.
Recent findings indicate that extracellular ATP (xATP) plays an important regulatory role in both animals and plants. The turnover of xATP is controlled largely by the activity of ecto-phosphatases, including ecto-apyrases. Two apyrases, termed Atapy1 (Arabidopsis thaliana apyrase 1) and Atapy2, were cloned and sequenced. The transcripts of Atapy1 and Atapy2 are widely distributed; however, the expression patterns are not identical. In roots, for example, the mRNA level of Atapy1 is greater than that of Atapy2. Atapy1 and Atapy2 are 87 % identical at the amino acid sequence level. Both contain four apyrase conserved regions (ACRs), an ATP-binding motif and a hydrophobic segment at the N-terminus. However, only Atapy1 demonstrates a calmodulin (CaM)-binding domain. The two cDNAs were overexpressed in bacteria, and the resulting proteins were biochemically analyzed. The purified proteins displayed enzymatic properties characteristic of apyrases, such as the hydrolysis of ATP and ADP, but not AMP, and an insensitivity to inhibitors of ATPases. In a CaM-binding assay, only the protein of Atapy1 bound to CaM under the conditions tested. To date Atapy1 represents the only other apyrase, besides pea NTPase, shown to contain a functional CaM-binding domain.
We are reporting a distinct constitutive isoform of nitric oxide synthase that has been purified to homogeneity from human platelet cytosolic fractions. Purification involved ultra centrifugation at 100 000 × g followed by two sequential affinity chromatograhy procedures: adenosine 2′,5′-biphosphate (2′m5′-ADP)-Sepharose and calmodulin Sepharose 4B. Purified enzyme appeared as a single banc (≈ 80 kDa) under denaturing condition (SDS-PAGE). The native appearrs to be dimeric, since its molecular weight estimated by gel filtration was ≈ 150 kDa. Enzyme activity was dependent of l-arginine, NADPH and (6R)-5,6,7,8-tetrahydro-l-biopterine. Partially purified platelet NOS (100 000 × g supernatant) activity was sensitive to calmodulin antagonists and teh the , a substrate analog of l-arginine.
Trifuoperazine, an anti-calmodulin agent, inhibited afatoxin production by Aspergillus parasiticus NRRL 2999,
without affecting the growth signi®cantly. Culturing the organism for 3 days in the presence of 0.14 mM tri-
¯uoperazine resulted in a generalized decrease in the production of all a¯atoxins; the production of afatoxin B1, a
potent hepatocarcinogen, was inhibited to 88% under such conditions. Culturing 7-day-old preformed cultures in
the presence of higher concentrations of tri¯uoperazine (>1 mM) completely abolished production of all a¯atoxins
including AFB1. The inhibitory infuence of trifuoperazine on afatoxin production was accompanied by calmodulin-
dependent phosphorylation of an 85 kDa cytoplasmic calmodulin-binding protein. While the functions of
calmodulin in mediating primary events of germination, growth and differentiation in fungi have earlier been
reported, the present results indicate a possible role for calmodulin in the production of fungal toxins.
Catalytic cores of skeletal and smooth muscle myosin light chain kinases and Ca2+/calmodulin-dependent protein kinase II are regulated intrasterically by different regulatory segments containing autoinhibitory
and calmodulin-binding sequences. The functional properties of these regulatory segments were examined in chimeric kinases
containing either the catalytic core of skeletal muscle myosin light chain kinase or Ca2+/calmodulin-dependent protein kinase II with different regulatory segments. Recognition of protein substrates by the catalytic
core of skeletal muscle myosin light chain kinase was altered with the regulatory segment of protein kinase II but not with
smooth muscle myosin light chain kinase. Similarly, the catalytic properties of the protein kinase II were altered with regulatory
segments from either myosin light chain kinase. All chimeric kinases were dependent on Ca2+/calmodulin for activity. The apparent Ca2+/calmodulin activation constant was similarly low with all chimeras containing the skeletal muscle catalytic core. The activation
constant was greater with chimeric kinases containing the catalytic core of Ca2+/calmodulin-dependent protein kinase II with its endogenous or myosin light chain kinase regulatory segments. Thus, heterologous
regulatory segments affect substrate recognition and kinase activity. Furthermore, the sensitivity to calmodulin activation
is determined primarily by the respective catalytic cores, not the calmodulin-binding sequences.
Not available Biological Sciences, School of
Typescript. Thesis (Ph. D.)--University of Hawaii at Manoa, 1991. Includes bibliographical references (leaves 103-130) Microfiche. x, 130 leaves, bound ill. 29 cm
Synapsin 1 is a nerve terminal phosphoprotein whose role seems to encompass the linking of small synaptic vesicles to the cytoskeleton. Synapsin 1 can join small synaptic vesicles to neuronal spectrin, microfilaments and microtubules; it can also bundle microtubules and microfilaments. In this paper, the mode of interaction between synapsin 1 and microtubules has been investigated. Bundling is shown to be highly cooperative: the apparent Hill coefficient is 3.06 +/- 0.3, and bundling is half-maximal at 0.63 +/- 0.02 microM. Bundling occurs either when whole synapsin 1 preparations (containing monomers and oligomers) or when monomeric synapsin 1 is added to microtubules. However, it is not clear that synapsin 1 remains monomeric in the presence of microtubules. Synapsin 1-microtubule mixtures contain two types of filament. One type is characterised by microtubules often with synapsin 1 bound to their surface. The other type is composed of filaments of diameter 15 +/- 5 nm. This filament type is granular and made up in part of 14-nm-diameter particles. These dimensions are consistent with their being made up of polymerised synapsin 1. It is possible that microtubules induce the polymerisation of synapsin 1. Synapsin 1 had independent tubulin binding sites in the N-terminal head domain and in the C-terminal tail domain. Whole synapsin 1 can interact with tubulin after it has been digested to remove the tubulin C terminus (des-C-terminal tubulin). The interaction of des-C-terminal tubulin with synapsin 1 appears to be via the head domain, since 125I-des-C-terminal tubulin only shows specific binding to the head domain on gel blots. By contrast intact tubulin binds to both head and tail domains. Binding to the tail domain can be inhibited by a synthetic peptide representing the microtubule-associated protein 2 (MAP2) binding site of class II beta tubulin. These results suggest a model for microtubule bundling by synapsin 1 in which independent sites in the head and tail domains of synapsin 1 cross-link microtubules by interactions with two distinct sites in tubulin.
In the mammalian brain, there are multiple catalytic subunits for the Ca2+- and calmodulin-dependent protein phosphatase [also called protein phosphatase 2B (PP-2B) and calcineurin] that are derived from two structural genes. The coding sequences of these two genes are distinguished by the absence (PP2Bα1) or the presence (PP2Bα2) of an amino terminus containing polyproline. Both of these genes can produce intragenic isoforms through alternative splicing. In the present study, a potential phylogenetic relationship of these genes was inferred from analysis of genomic DNA and from studies of mRNA and protein expression. Southern blot analysis showed unique restriction fragments for both genes in seven mammalian species; however, in organisms from two nonmammalian vertebrates (chicken and lizard), hybridization was observed only for PP2Bα1. In agreement with these results, Northern blots of mammalian brain RNA showed transcripts for both genes, with about two to three times more of the PP2Bα1 mRNAs, whereas in chicken and lizard, only PP2Bα1 transcripts were detected. An analysis of protein expression by two-dimensional electrophoresis was also consistent with these findings. For the purified mammalian brain protein, eight to ten variants were observed with isoelectric points of 5.2-5.8; immunoblot analysis using anti-peptide antibodies indicated that the majority of these were PP2Bα1 forms. In chicken brain, multiple isoforms were recognized by antibodies against the PP2Bα1 forms, but no reactivity was seen with those against the PP2Bα2 forms. Taken together, these findings suggest that: (i) in mammals, the predominant catalytic subunit isoforms in brain are PP2Bα1 products and (ii) the gene for the polyproline-containing catalytic subunit of calmodulin- dependent phosphatase (PP2Bα2) may have evolved after the avian/reptilian branching point, perhaps to carry out a role(s) of particular significance in mammals.
Initial autophosphorylation of multifunctional Ca2+/calmodulin-dependent protein kinase (CaM kinase) occurs at Thr286 (the "autonomy" site) and converts the kinase from a Ca(2+)-dependent to a partially Ca(2+)-independent or autonomous enzyme. After removal of Ca2+/calmodulin, the autonomous kinase undergoes a "burst" of inhibitory autophosphorylation at sites distinct from the autonomy site which may be masked in the presence of bound calmodulin. This burst of Ca(2+)-independent autophosphorylation blocks the ability of calmodulin to activate the kinase. We have used site-directed mutagenesis to replace putative inhibitory autophosphorylation sites within the calmodulin binding domain of recombinant alpha-CaM kinase with nonphosphorylatable alanines and examined the effects on autophosphorylation, kinase activity, and calmodulin binding. Although prominent Ca(2+)-independent autophosphorylation occurs within the calmodulin binding domain at Thr305, Thr306, and Ser314 in wild-type alpha-CaM kinase, the inhibitory effect on kinase activity and calmodulin binding is retained in mutants lacking any one of these three sites. However, when both Thr305 and Thr306 are converted to alanines the kinase does not display inhibition of either activity or calmodulin binding. Autophosphorylation at either Thr305 or Thr306 is therefore sufficient to block both binding and activation of the kinase by Ca2+/calmodulin. Thr306 is also slowly autophosphorylated in a basal reaction in the continuous absence of Ca2+/calmodulin. Autophosphorylation of Thr306 by the kinase in either its basal or autonomous state suggests that in the absence of bound calmodulin, the region of the autoregulatory domain surrounding Thr306, rather than the region near the autonomy site, lies nearest the peptide substrate binding site of the kinase.
The molecular and biochemical properties of myosin light chain kinases from chicken skeletal and smooth muscle were investigated by recombinant DNA techniques. Deletion of the amino-terminal region of either the smooth or skeletal muscle myosin light chain kinase resulted in a decrease in Vmax with no significant change in Km values for light chain substrates. Skeletal/smooth muscle chimeric kinases were inactive when a 65-residue region amino-terminal of the catalytic core was exchanged between the two forms. Changing alanine 494 to glutamic acid within this region in the chicken skeletal muscle myosin light chain kinase increased the Km values for light chains 10-fold. These results are consistent with the hypothesis that the region amino-terminal of the catalytic core in myosin light chain kinases is involved in light chain recognition. A skeletal muscle kinase which contained the smooth muscle calmodulin binding domain remained regulated by Ca2+/calmodulin. Thus, the calmodulin binding domains of smooth and skeletal muscle myosin light chain kinases share structural elements necessary for regulation.
Myosin I is an actin-based motor responsible for powering a wide variety of motile activities in amebae and slime molds and has been found previously in vertebrates as the lateral bridges within intestinal epithelial cell microvilli. Although neurons exhibit extensive cellular and intracellular motility, including the production of ameboid-like growth cones during development, the proteins responsible for the motor in these processes are unknown. Here, we report the isolation of a partially purified protein fraction from bovine brain that is enriched for a 150-kDa protein; immunochemical and biochemical analyses suggest that this protein possesses a number of functional properties that have been ascribed to myosin I from various sources. These properties include an elevated K(+)-EDTA ATPase, a modest actin-activated Mg(2+)-ATPase, the ability to bind calmodulin, and a ready association with phospholipid vesicles made from phosphatidylserine, but not from phosphatidylcholine. The combination of these properties, together with a molecular mass of 150 kDa (most myosin I molecules found to date have molecular masses in the range 110-130 kDa) yet recognition by an anti-myosin I antibody, suggests the presence of a new member of the myosin I family within mammalian brain.
It is postulated that basic residues in the regulatory region of myosin light chain kinase are important for conferring autoinhibition by binding to the catalytic core. To investigate this proposal, 10 basic amino acids within the regulatory region of rabbit smooth muscle myosin light chain kinase (Lys961-Lys979) were replaced either singularly or in combination with acidic or nonpolar residues by site-directed mutagenesis. All active mutant kinases were dependent on Ca2+/calmodulin for catalytic activity. None of the mutants was active in the absence of Ca2+/calmodulin, suggesting that the autoinhibitory region has not been defined completely. Charge reversal mutants at Arg974, Arg975, and Lys976 resulted in loss of high affinity binding of calmodulin and increased the concentration of calmodulin required for half-maximal activation (KCaM). The charge reversal mutant at Lys979 also increased KCaM but to a lesser extent. Charge reversal mutants at Lys965 and Arg967 resulted in an inactive myosin light chain kinase that could not be proteolytically activated. When these residues were mutated to Ala, the expressed kinase was dependent upon Ca2+/calmodulin for activity and exhibited a decrease in KCaM. Charge reversal mutants in Lys961 and Lys962 also had decreased KCaM values. These basic residues amino-terminal of the calmodulin binding domain may play an important role in the activation of the kinase.
Skeletal muscle myosin light chain kinase can phosphorylate myosin light chains isolated from skeletal or smooth muscle. In contrast, smooth muscle myosin light chain kinase specifically phosphorylates light chains isolated from smooth muscle. In this study, we have identified residues within the rabbit smooth and skeletal muscle myosin light chain kinases which may interact with the basic residues that are important substrate determinants in the light chains. Mutation of aspartic acid 270 amino-terminal of the catalytic core of the skeletal muscle myosin light chain kinase increased the Km value for both smooth and skeletal muscle light chains. Although deletions of the analogous region of the smooth muscle myosin light chain kinase (residues 663-678) markedly increased the Km value for light chain, mutation of any single acidic residue within this region did not have a similar effect. Mutation of single residues within the catalytic core of the skeletal muscle (E377 and E421) and smooth muscle (E777 and E821) myosin light chain kinases increased Km values for the smooth muscle light chain at least 35- and 100-fold, respectively. It is proposed that these residues may form ionic interactions with the arginine that is 3 residues amino-terminal of the phosphorylatable serine in the smooth muscle light chain.
Calmodulin, as a major intracellular calcium-binding protein, regulates many Ca(2+)-dependent enzymes and plays an important role in a wide spectrum of cellular functions of the eukaryotes. Interaction between calmodulin and human lactoferrin, a 78 kDa protein with antibacterial properties, was found in the presence of Ca2+ using (i) a method for the detection of calmodulin binding proteins with biotinylated calmodulin, (ii) affinity chromatography on an agarose-calmodulin column with subsequent detection by an enzyme-linked immunosorbent assay (ELISA). The binding of calmodulin to lactoferrin blocked the ability of lactoferrin to agglutinate Micrococcus lysodeikticus.
Calmodulin (CaM) mediates the Ca(2+)-dependent activation of many enzyme systems in accordance with its cellular localization. We have described previously a muscarinic receptor-mediated translocation of CaM from membranes into the cytosol of SK-N-SH human neuroblastoma cells. To explore the potential targets (CaM-binding proteins, CaMBP) for CaM upon translocation, a photoreactive CaM derivative was introduced into living SK-N-SH cells using a scrape-loading technique. Scrape-loading incorporated rhodamine isothiocyanate-labeled CaM with an efficiency of 38%. CaM-diazopyruvamide (CaM-DAP), a Ca(2+)-dependent and CaM-specific probe, was also introduced into the cells. The muscarinic agonist carbachol stimulated a translocation of CaM from membranes into cytosol in CaM-DAP-loaded SK-N-SH cells. Upon photochemical cross-linking, cross-linked adducts of CaM-CaMBP were detected by immunoblotting with anti-CaM antibody. Carbachol stimulated increased photoaffinity labeling of three proteins with relative adduct molecular masses of 70, 120, and 180 kDa. The time course of labeling for the 70- and 120-kDa adducts showed maximal increased by 15-30 min. The 180-kDa adduct displayed a slower time course of maximal labeling, with increases maintained for 2-4 h. Subtracting the molecular mass of CaM, carbachol stimulated binding to CaMBPs of 55, 105, and 163 kDa. Predominant cellular CaMBP were identified using a biotinylated CaM overlay procedure. Western blot analysis indicated the expression of specific CaM-dependent enzymes such as calcineurin, phosphodiesterase, the beta-isoform (rat brain) of CaM kinase II, and Ca(2+)-ATPase. Numerous cytoskeletal CaMBP were expressed such as microtubule-associated protein-2, spectrin, tubulin, caldesmon, adducin, and neuromodulin. Of the CaMBP expressed, phosphodiesterase, calcineurin, caldesmon, and adducin cross-linked with CaM-DAP in the loaded SK-N-SH cells. Carbachol stimulated the time-dependent CaM-DAP labeling of calcineurin and adducin. This study demonstrates the novel incorporation of a photoreactive CaM derivative into living cells, as well as muscarinic receptor-activated CaM-DAP interaction with several cellular CaMBP. We postulate that carbachol-stimulated CaM translocation in SK-N-SH cells may affect the activity of CaM-dependent enzymes and may alter aspects of cytoskeletal function.
Calcium and calmodulin (CaM) are known to play critical roles in controlling cell cycle progression in a variety of cells. We observed that the CaM antagonist, N-(6-aminohexyl)-5-chloro-1-naphthalensulfonamide hydrochloride (W-7), inhibited 3H-thymidine incorporation into DNA of factor-dependent hematopoietic cells. To delineate the role of CaM in proliferation of hematopoietic cells, we have investigated intracellular distribution of specific CaM-binding proteins (CaM-BPs) in response to hematopoietic growth factors in FDC-P1, 32D, NFS-60, and T1165 cells. Each of these cell lines, when deprived of cytokines for 16 to 18 hours, essentially ceased proliferation, even in the presence of fetal calf serum. Concomitant to the cessation of proliferation, there was a dramatic depletion of a specific CaM-BP of about 68 Kd in both their cytoplasmic and nuclear fractions. Within 6 to 12 hours of reexposure to proliferation-specific cytokines, there was a restoration of the nuclear as well as cytoplasmic 68-Kd CaM-BP. Furthermore, such an induction and nuclear localization of the 68-Kd CaM-BP by the cytokines coincided temporally with the progression of synchronized FDC-P1 cells from G1 to S phase. By contrast, colony-stimulating factor-1 (CSF-1)-dependent bone marrow macrophages and BAC-1 cells did not exhibit 68-Kd CaM-BP in the nuclear or cytoplasmic fractions. These studies suggest that while hematopoietic growth factor granulocyte CSF-, granulocyte-macrophage CSF-, interleukin-3 (IL-3)-, or IL-6-, whose receptors are members of the hematopoietin receptor family, induced cell proliferation is associated with a common mechanism involving nuclear localization of the 68-Kd CaM-BP, the CSF-1-induced proliferation seems to involve 68-Kd CaM-BP-independent pathways.
Biotinylated derivatives of calmodulin (CaM) were prepared and their biological properties characterized by using enzyme assays, affinity and hydrophobic-interaction chromatography. Several N-hydroxysuccinimidobiotin derivatives [sulphosuccinimidobiotin (sulpho-NHS) and sulphosuccinimido-6-(biotinamido)hexanoate (BNHS-LC)] differing in spacer arm length were used to modify CaM. The shorter-spacer-arm CaM derivative (sulpho-CaM) activated CaM-dependent cyclic nucleotide phosphodiesterase and CaM-dependent protein kinase II; preincubation with avidin blocked its ability to activate these enzymes. The extended-spacer-arm derivative (BNHS-LC-CaM) activated CaM-dependent enzymes both in the presence and in the absence of avidin, suggesting that the longer spacer arm diminished steric effects from avidin preincubation. Other biotinylated CaM derivatives were prepared with biotinylated tyrosine and/or histidine residues (diazobenzoylbiocytin; DBB-CaM) or nucleophilic sites (photobiotin acetate; photo-CaM). These derivatives activated CaM-dependent enzymes in the presence and in the absence of avidin. Oriented affinity columns were constructed with covalently immobilized avidin complexed to each biotinylated CaM derivative. The chromatographic profiles obtained revealed that each column interacted with a specific subset of CaM-binding proteins. Elution profiles of biotinyl CaM derivatives on phenyl-Sepharose hydrophobic-interaction chromatography suggested that several derivatives displayed diminished binding to the matrix in the presence of Ca2+. Development and characterization of a series of biotinylated CaM molecules can be used to identify domains of CaM that interact with specific CaM-dependent enzymes.
A cDNA for the catalytic subunit of a calmodulin (CaM)-dependent protein phosphatase was cloned from Neurospora crassa. The open reading frame of 1557 base pairs encoded a protein of Mr approximately 59,580 and was followed by a 3'-untranslated region of 363 base pairs including the poly(A) tail. Based on primer extension analysis, the mRNA transcript in vivo was 2403 base pairs. Expression of this CaM-protein phosphatase mRNA was developmentally regulated, being highest during early mycelial growth; production of the corresponding protein followed mRNA with a time lag of 8-12 h. Polymerase chain reaction amplification of genomic DNA revealed three small introns, the positions of which coincided with those in the mouse gene, indicating evolutionary conservation of these structures. The deduced sequence showed approximately 75% identity with the mammalian homologue, calcineurin, in aligned regions. A region of 40 amino acids preceding the CaM-binding domain was essentially unchanged, suggesting conservation of a crucial interaction site. Three small segments in the carboxyl half of the protein were unrelated to the mammalian gene and may constitute "variable regions" that confer substrate specificity to the enzyme. An active recombinant catalytic subunit was expressed in bacteria and purified by CaM-Sepharose chromatography. This preparation was stimulated 2- 3-fold by CaM and showed a p-nitrophenol phosphatase activity equal to that of the bovine brain holoenzyme, although its dephosphorylation of phosphoprotein substrates was markedly different. These findings demonstrate that the catalytic subunit of this phosphatase can exhibit high activity in the absence of its intrinsic Ca(2+)-binding subunit.
Biotin-dependent enzymes are involved in carboxylation, decarboxylation and transcarboxylation reactions. Here, we have used sodium dodecyl sulfate polyacrylamide gel electrophoresis and electroblotting followed by probing with avidin to identify biotin-containing polypeptides in Dictyostelium discoideum. Twenty biotinyl polypeptides were visualized, with a 23 kDa protein appearing transiently. Based upon the molecular mobility of the biotinyl polypeptides, D. discoideum may contain the biotin-dependent enzymes acetyl CoA carboxylase, proprionyl CoA carboxylase, pyruvate carboxylase, and 3-methylcrotonyl CoA carboxylase.
The soluble form of guanylyl cyclase-activating-factor (GAF) synthase from rat cerebellum was purified to homogeneity by sequential affinity chromatographic steps on adenosine 2',5'-bisphosphate (2',5'-ADP)-Sepharose and calmodulin-agarose. Enzyme activity during purification was bioassayed by the L-arginine-, NADPH-, and Ca2+/calmodulin-dependent formation of a plasma membrane-permeable nitric oxide-like factor that stimulated soluble guanylyl cyclase in RFL-6 cells. With calmodulin and NADPH as cofactors, purified soluble GAF synthase induced an increase of 1.05 mumol of cGMP per 10(6) RFL-6 cells per 3 min per mg of protein. The coproduct of this signal-transduction pathway appeared to be L-citrulline. GAF synthase catalyzed the conversion of 107 nmol of L-arginine into L-citrulline per min per mg of protein. Based on these assays, this represents a purification of GAF synthase of approximately 10,076- and 8925-fold with recoveries of 16% and 19%, respectively. Rechromatography of the purified enzyme on Mono P (isoelectric point = 6.1 +/- 0.3), Mono Q, and Superose 12 or 6 resulted in no further purification or increase in specific activity. A Stokes radius of 7.9 +/- 0.3 nm and a sedimentation coefficient s20,w of 7.8 +/- 0.2 S were used to calculate a molecular mass of about 279 +/- 25 kDa for the native enzyme. SDS/PAGE revealed a single protein band with a molecular mass of about 155 +/- 3 kDa. These data suggest that soluble GAF synthase purified from rat cerebellum is a homodimer of 155-kDa subunits and that enzyme activity is dependent upon the presence of calmodulin.
Using affinity-purified calmodulin-binding proteins from human epidermis we have developed a monoclonal IgM antibody, ROC 129.1, to a human desmosomal calcmodulin-binding protein. This antibody reacts with a submembranous 250-kD protein from human keratinocytes and stains human epidermis in a "cell-surface pattern". Permeability studies indicated that the epitope with which this monoclonal reacts is on the inner surface of the cell membrane. Immunoelectronmicroscopy localized the antigen to the desmosome. The epitope is restricted to stratified squamous epithelia and arises between 8-12 wk of fetal development. This desmosomal calmodulin-binding protein, which we have termed keratocalmin, may be involved in the calcium-regulated assembly of desmosomes.
Transsynaptic regulation is one mechanism that controls expression of several calmodulin (CaM)-dependent enzymes. This observation and the demonstration that expression of several CaM-dependent enzymes in developing striatum occurred with a spatial and temporal pattern similar to that seen for dopamine and tyrosine hydroxylase suggested that the nigrostriatal pathway may influence the expression of CaM-binding proteins (CaM-BPs) during striatal development. Therefore, the possible role of nigrostriatal dopamine systems regulating the expression of CaM-dependent enzymes was studied in Sprague-Dawley rats by using surgical hemitransections of brain, 6-hydroxydopamine lesions, and chronic haloperidol treatments. Alterations in CaM-BP expression following perturbation of the developing nigrostriatal tract were analyzed by using immunoblots, biotinylated CaM overlays, and enzyme assays. The extent of nigrostriatal lesions was assessed by using depletion of immunoreactive tyrosine hydroxylase levels in striatum. All three experimental paradigms failed to alter the normal developmental expression of CaM-dependent enzymes. From these results we conclude that the increased expression of CaM-dependent enzymes during striatal development is not directly dependent on synaptic input from the nigrostriatal dopamine system.
We report that the rat pituitary cell line GH3 contains a Ca2(+)- and calmodulin-dependent protein kinase with properties characteristic of multifunctional Ca2+/calmodulin-dependent protein kinase (CaM kinase) from rat brain. The GH3 kinase exhibits the hallmark of authentic CaM kinase: conversion from Ca2(+)-dependent to Ca2(+)-independent activity following a brief initial phosphorylation in vitro. This phosphorylation occurs at a site which is similar or identical to that of the "autonomy" site of the rat brain enzyme and thus may be an autophosphorylation event. GH3 CaM kinase is phosphorylated and becomes Ca2(+)-independent in situ. Depolarization of intact cells with K+ opens calcium channels and leads to the phosphorylation of CaM kinase at the autonomy site, and the kinase becomes significantly and persistently Ca2(+)-independent. Treatment of cells with thyrotropin-releasing hormone (TRH), which activates the phosphatidylinositol signaling pathway, also generates a Ca2(+)-independent CaM kinase in situ. The primary effect of TRH on CaM kinase activity is transient and correlates with the spike of Ca2+ released from intracellular stores and the rapid phase of prolactin release from GH3 cells. This study demonstrates that CaM kinase is able to detect and respond to both calcium that enters the cell through voltage-sensitive Ca2+ channels and calcium released from internal stores via the phosphatidylinositol pathway. We find that TRH, a hormone that causes release of prolactin and was previously believed to activate primarily protein kinase C, also significantly activates CaM kinase in intact cells.
Calmodulin is an ubiquitous cytoplasmic protein which mediates many of the actions of calcium on intestinal tissue including regulation of growth and differentiation of normal and neoplastic cells. Using a biotinylated calmodulin overlay system, we compared the pattern of calmodulin binding proteins throughout the gastrointestinal tract of mice, rats, rabbits, and humans, and in human colonic adenomas and adenocarcinomas. A common calmodulin binding protein of 67 kDa was found in membrane and cytosolic fractions of oesophagus, stomach, proximal and distal small intestine, and colon from all four species. In human tissue this 67 kDa protein was present in greatest concentration in stomach tissue. Furthermore, a 67 kDa binding protein was the major calmodulin binding protein from human stomach and ileum as determined by ion exchange and calmodulin affinity chromatography. A similar pattern of binding proteins was noted between rabbit and human cytosolic fractions; proteins of 60/67 kDa and 105 kDa were present in stomach tissue. A 94 kDa protein was present in samples of rabbit and human ileum but not of mouse or rat. A similar pattern of calmodulin binding proteins was seen in normal and neoplastic large bowel tissue, apart from one of nine adenocarcinomas, where a distinct 54 kDa band was noted in both cytosolic and membrane fractions. The results of this study show interspecies and organ differences between calmodulin binding proteins, but suggest that a 67 kDa protein is the major binding protein present throughout normal gastro-intestinal tract and neoplastic human tissue.
The 70-kilodalton heat shock protein (hsp70) family members appear to be essential components in a number cellular protein-protein
interactions. We report here on the characterization of a new functional region in hsp70, a calmodulin-binding site. We have
identified a 21-amino-acid sequence within the hsp70 protein that contains a calmodulin-binding domain. The peptide formed
a potential amphipathic alpha helix and bound calmodulin with high affinity. Comparison of amino acid homology of this calmodulin-binding
sequence with analogous hsp70 sequences from other species showed a high degree of conservation.
The cloning and characterization of cDNAs for the catalytic subunit of calcineurin (CN) from murine and human brain libraries were carried out using nonisotopic methods. A murine cDNA clone encoding a protein of 521 amino acids (Mr approximately 58,650) was isolated; overlapping clones established a 3'-untranslated region of 554 base pairs preceding the poly(A) tail. Homologous cDNAs from human brain showed greater than 92% nucleotide sequence identity in both coding and non-coding regions with greater than 99% conservation of amino acid sequence. A second class of cDNAs lacking a specific 30-base pair region following the calmodulin-binding domain was found in four murine and human libraries. Oligonucleotide probes for both cDNA isoforms hybridized to mRNA from several brain regions indicating the existence of transcripts in vivo. The nucleotide sequences of the two forms were identical except for the inserted sequence, and Southern blot analysis of mouse and rat DNA was consistent with their having originated from the same gene; these data suggest that alternative splicing may give rise to molecular isoforms of the catalytic subunit in brain. Northern blots showed a predominant mRNA for CN in most tissues of approximately 4.0 kilobases (kb) with lower amounts of a 3.6-kb species. Brain showed 10 times more of these mRNAs than skeletal muscle while other tissues had less than or equal to 5% that in brain. In testis, multiple mRNAs were observed, with the major forms being approximately 2.8 and 1.6 kb; the total amount of CN message was about 15% that in brain. The presence of mRNA isoforms of the catalytic subunit may provide for isoenzymes of this phosphatase having distinct phosphoprotein substrate specificities or regulatory properties. The structural relatedness of CN to other mammalian serine/threonine protein phosphatases was highest over a region of approximately 240 amino acids near the amino terminus of this subunit, with greater similarity to protein phosphatase 2A than protein phosphatase 1. The conservation of many regions found in lambda phage phosphatase (Cohen, P.T.W., and Cohen, P. (1989) Biochem. J. 260, 931-934) indicates a common origin for the catalytic domain of this enzyme.
This chapter describes the results of a literature survey showing applications of avidin–biotin technology in tabular forms. One of the tables presents the experimental details from investigations that have used avidin columns for the isolation of target material. Native biotin-containing systems can be isolated directly on such columns. The isolation of other materials, such as membrane proteins and glycol-conjugates, is dependent on the mediation of a biotinylated binder. One of the problems in the use of avidin–biotin technology for isolation purposes is the difficulty encountered in eluting the bound material from the column. Other tables provide information relating to cytochemical localization investigations. These types of investigations usually involve the microscopic visualization of membrane-based sites mediated through the avidin–biotin interaction. In some cases, target sites have been directly biotinylated using group-specific biotinylating reagents. In others, biotinylated lectins, hormones, antibodies, and other binders were employed to mediate between the target molecule and the avidin-probe conjugate or complex.
In Chinese hamster embryo fibroblast cells, an increase in intracellular calmodulin levels coincided with the nuclear localization of a calmodulin-binding protein of about 68 kDa as the cells progressed from G1 to S phase. When cells were limited from entering into S phase, by omitting insulin a defined medium, intracellular CaM levels did not increase and the 68 kDa calmodulin-binding protein was completely absent from the nuclei. Corresponding to the nuclear localization of calmodulin and the 68 kDa calmodulin-binding protein in S phase cells, there was a dramatic increase in DNA polymerase and thymidine kinase activities in the nuclei of S phase cells as compared to G1 phase cells. In addition, the 68 kDa calmodulin-binding protein, along with calmodulin, is observed to be an integral component of replitase complex responsible for nuclear DNA replication in S phase cells. These observations point to the association of calmodulin and calmodulin-binding protein(s) with the replication machinery responsible for nuclear DNA replication during S phase. A possible regulatory role of these proteins in the onset of DNA replication and cell proliferation is discussed.
We used brief bilateral carotid artery occlusion in gerbils to examine the effects of temperature on ischemia-induced inhibition of calcium/calmodulin-dependent protein kinase II activity and neuronal death. In normothermic (36 degrees C) gerbils, ischemia induced a severe loss of hippocampal CA1 pyramidal neurons measured 7 days after ischemia (28.4 neurons/mm, n = 10; control density in 10 naive gerbils 262.1 neurons/mm) and a significant decrease in forebrain calcium/calmodulin-dependent protein kinase II autophosphorylation measured 2 hours after ischemia (12.9 fmol/min, n = 6; control phosphorylation in six naive gerbils 23.5 fmol/min). The effect of temperature on these indicators of ischemic damage was examined by adjusting intracerebral temperature before and during the ischemic insult. Hyperthermic (39 degrees C) gerbils showed almost complete loss of neurons in the CA1 region (3.0 neurons/mm, n = 11) and extension of neuronal death into the CA2, CA3, and CA4 regions. In addition, hyperthermia exacerbated ischemia-induced inhibition of calcium/calmodulin-dependent protein kinase II activity (4.2 fmol/min, n = 6). Hypothermia (32 degrees C) protected against ischemia-induced CA1 pyramidal cell damage (257.0 neurons/mm, n = 20) and inhibition of calcium/calmodulin-dependent protein kinase II activity (26.0 fmol/min, n = 6). Our results are consistent with the hypothesis that loss of calcium/calmodulin-dependent protein kinase II activity may be a critical event in the development of ischemia-induced cell death.
The developmental patterns of calmodulin-binding proteins (CaM-BPS) in rat brain were examined using biotinylated calmodulin overlays of one- and two-dimensional gels. Hippocampus showed the earliest onset of CaM-BP expression (postnatal day 5; PND5), followed by cerebral cortex and striatum, both of which had detectable levels of CaM-BPs by PND7. Cerebellum had the latest onset of CaM-BP expression; CaM-BPs were not detectable until PND9. Very few CaM-BPs were present in brain before PND5 and all regions reached near adult levels by PND20. However, several unique CaM-BPs were seen in embryonic brain and these proteins may have an important role in developing neurons. These data suggest an orderly, complex expression of CaM-BPs which increases during times of synaptogenesis and synaptic maturation.
The patterns of expression of calmodulin-dependent cyclic nucleotide phosphodiesterase (CaM-PDE) have been studied in developing and adult rat brain using affinity-purified polyclonal antibodies against CaM-PDE. An immunocytochemical map of adult brain regions expressing CaM-PDE, constructed from serial coronal brain sections, illustrated that CaM-PDE was expressed in specific neuronal subpopulations throughout the adult rat brain. Immunoblot analysis coupled with subcellular fractionation indicated that CaM-PDE was primarily localized to cytoplasmic fractions, with a small amount associated with synaptosomal membranes. Immunoblots from developing brain indicated that CaM-PDE expression increased dramatically during postnatal days 7-20 (PND 7-20); parallel increases in CaM-PDE enzyme activity occurred during this same time. Immunocytochemical studies indicated that several distinct patterns of CaM-PDE expression occurred during development. Neocortex showed low levels of CaM-PDE immunoreactivity in neuronal somata of layers III, V and VI on PND 4 that increased by PND 11; the adult somatodendritic pattern of immunoreactivity was observed by PND 60. Similar patterns were observed in cerebellar Purkinje cells, with somatodendritic staining observed by PND 12. By contrast, caudate-putamen, the inferior olive and the hypoglossal nuclei expressed high levels of CaM-PDE on PND 4, with levels considerably lower in the adult animal. The different patterns of expression suggest that in neocortex and cerebellum, CaM-PDE increases during the period of neuronal differentiation and active synaptogenesis, while in the caudate-putamen, inferior olive and hypoglossal nucleus, high levels may be required early in development.
Calcium-pumping membrane ATPases play the essential function of terminating Ca2+-dependent responses. Two broad classes of Ca2+-pumping ATPases are now known to exist in animal cells, those of internal membranes (100 kDa) and the plasma membrane enzymes (120–140 kDa). These two families of Ca2+-pumping ATPases differ substantially in molecular, enzymatic and regulatory properties commensurate with their differiential localization and physiological roles. Recent studies in a number of laboratories have provided evidence that multiple isoforms of each type of Ca2+ -ATPase are produced in different cell types as products of either differential splicing events or different genes. These sets of isoforms are almost certain to have subtle differences in functional properties related to the requirements of a particular biological setting.
Calcineurin, a calmodulin-binding protein from brain, has been shown to possess a metal ion-dependent and calmodulin-stimulated phosphatase activity towards phosphorylase kinase and inhibitor-1 (Stewart, A. A., Ingebritsen, T. S., Manalan, A., Klee, C. B., and Cohen, P. (1982) FEBS Lett. 137, 80-84). In this report, we show that calcineurin can also dephosphorylate p-nitrophenyl phosphate and free phosphotyrosine. However, calcineurin does not show significant activity towards phosphothreonine, phosphoserine, or several other low molecular weight phosphocompounds tested. As we have found with phosphorylase kinase and phosphocasein, the dephosphorylation of p-nitrophenyl phosphate and free phosphotyrosine is stimulated by calmodulin and is metal ion-dependent with the order of efficiency being Mn2+ much greater than Co2+ greater than Ca2+. The dephosphorylation of these substrates appears to be an intrinsic property of calcineurin and is not due to contamination by alkaline phosphatases since the pH optimum for calcineurin activity occurs at a neutral rather than an alkaline pH. The dephosphorylation of p-nitrophenyl phosphate provides an easy, rapid, and accurate method for the quantification of calcineurin activity as well as permitting insight into reaction kinetics. The dephosphorylation of free phosphotyrosine by calcineurin suggests that this compound may be a physiological substrate of calcineurin.
Biotin was covalently attached to antibodies, antigens and enzymes, and the effects of this labeling on the antigen and antibody binding capacity and on enzymatic activity were tested. Based on avidin-biotin interaction, the labeled proteins were used in quantitative enzyme-immunoassay and enzyme-immunohistochemical staining procedures. Two procedures were developed. In the first procedure, named the Bridged Avidin-Biotin (BRAB) technique four steps were used sequentially in order to quantify or detect an immobilized antigen: 1) incubation with biotin-labeled antibody; 2) incubation with avidin; 3) incubation with biotin-labeled enzyme; 4) measurement or histochemical staining of the enzyme. The technique is based on the observation that avidin possesses four active sites. In the second procedure, named the Labeled Avidin-Biotin (LAB) technique, biotin-labeled antibody and enzyme-labeled avidin are used sequentially. Enzyme-associated antigen is then quantified or revealed immunohistochemically. The optimal conditions for enzyme-immunoassay and enzyme-immunohistochemical staining using BRAB and LAB procedures were established.
A technique has been developed for the separation of proteins by two-dimensional polyacrylamide gel electrophoresis. Due to its resolution and sensitivity, this technique is a powerful tool for the analysis and detection of proteins from complex biological sources. Proteins are separated according to isoelectric point by isoelectric focusing in the first dimension, and according to molecular weight by sodium dodecyl sulfate electrophoresis in the second dimension. Since these two parameters are unrelated, it is possible to obtain an almost uniform distribution of protein spots across a two-diminsional gel. This technique has resolved 1100 different components from Escherichia coli and should be capable of resolving a maximum of 5000 proteins. A protein containing as little as one disintegration per min of either 14C or 35S can be detected by autoradiography. A protein which constitutes 10 minus 4 to 10 minus 5% of the total protein can be detected and quantified by autoradiography. The reproducibility of the separation is sufficient to permit each spot on one separation to be matched with a spot on a different separation. This technique provides a method for estimation (at the described sensitivities) of the number of proteins made by any biological system. This system can resolve proteins differing in a single charge and consequently can be used in the analysis of in vivo modifications resulting in a change in charge. Proteins whose charge is changed by missense mutations can be identified. A detailed description of the methods as well as the characteristics of this system are presented.
A method has been devised for the electrophoretic transfer of proteins from polyacrylamide gels to nitrocellulose sheets. The method results in quantitative transfer of ribosomal proteins from gels containing urea. For sodium dodecyl sulfate gels, the original band pattern was obtained with no loss of resolution, but the transfer was not quantitative. The method allows detection of proteins by autoradiography and is simpler than conventional procedures. The immobilized proteins were detectable by immunological procedures. All additional binding capacity on the nitrocellulose was blocked with excess protein; then a specific antibody was bound and, finally, a second antibody directed against the first antibody. The second antibody was either radioactively labeled or conjugated to fluorescein or to peroxidase. The specific protein was then detected by either autoradiography, under UV light, or by the peroxidase reaction product, respectively. In the latter case, as little as 100 pg of protein was clearly detectable. It is anticipated that the procedure will be applicable to analysis of a wide variety of proteins with specific reactions or ligands.
Forebrain and cerebellar Type II Ca2+/calmodulin-dependent protein kinases have different subunit compositions. The forebrain holoenzyme, characterized in our laboratory, is a 650-kDa holoenzyme composed of 50-kDa alpha-subunits and 60-kDa beta-subunits assembled in approximately a 3:1 ratio (Bennett, M. K., Erondu, N. E., and Kennedy, M. B. (1983) J. Biol. Chem. 258, 12735-12744). The cerebellar isozyme is a 500-kDa holoenzyme composed of alpha-subunits and beta-subunits assembled in almost the converse ratio, approximately four beta-subunits for each alpha-subunit. When compared by tryptic peptide mapping and by immunochemical techniques, the beta-subunits from the two brain regions are indistinguishable and the alpha-subunits appear closely related. The specific activities, substrate specificities, and catalytic constants of the cerebellar and forebrain isozymes are similar, suggesting that the alpha- and beta-subunits contain similar catalytic sites. However, two differences in the properties of the isozymes may result in functional differences between them in vivo. First, the apparent affinity of the cerebellar kinase for Ca2+/calmodulin is 2-fold higher than that of the forebrain kinase. Second, the two isozymes appear to associate differently with subcellular structures. Approximately 85% of the cerebellar kinase and 50% of the forebrain kinase remain in the particulate fraction after homogenization under standard conditions. However, they are present in different amounts in postsynaptic density fractions. Postsynaptic densities prepared from forebrain contain the forebrain isozyme. Immunochemical measurements show that it comprises approximately 16% of their total protein. In contrast, postsynaptic densities prepared from cerebellum contain the cerebellar isozyme, but it comprises only approximately 1-2% of their total protein. Thus, the alpha-subunit may play a role in anchoring Type II Ca2+/calmodulin-dependent protein kinase to postsynaptic densities.
We recently reported the detection of multiple classes of calmodulin-binding proteins in subcellular fractions of chicken embryo fibroblasts by using a gel binding procedure (Van Eldik, L.J., and W.H. Burgess, 1983, J. Biol. Chem., 258:4539-4547). In this report we identify many of these calmodulin-binding proteins and provide further evidence for the existence of multiple classes of calmodulin-binding proteins based on the interaction of these proteins with calmodulin and other calcium-modulated proteins. The fact that, in some cases, the same calmodulin-binding protein can bind troponin C and S100 alpha suggests that similar functional domains may be present in these distinct calcium-modulated proteins. We also have used protocols based on purification steps for calmodulin-binding proteins and calmodulin-regulated activities from other systems, in conjunction with enzymatic assays and various immunological methods, to identify many of the calmodulin-binding proteins in chicken embryo fibroblasts. The identities of these proteins suggest in vivo roles for calmodulin in the regulation of cell shape and motility, cyclic nucleotide metabolism, and possibly nucleic acid and protein turnover in fibroblasts.
Highly purified preparations of cytosolic brain RII contain a tightly associated polypeptide with a Mr of 75,000 (P75). When purified brain and heart RII were preincubated with Ca2+ and 125I-calmodulin and then were subjected to polyacrylamide gel gelectrophoresis under nondenaturing conditions a major calmodulin-binding component was found only in the brain RII sample. The calmodulin-binding activity exhibited a higher sedimentation coefficient (9 S) than free RII (5 S) indicating that it might be a complex of P75 and RII dimers. This possibility was investigated using two specific monoclonal antibodies. Western blot analyses revealed that monoclonal antibody 918 exclusively bound to P75 in the brain RII preparation while monoclonal antibody 107 complexed RII. The calmodulin-binding component was noncovalently labeled with 125I-calmodulin and separated from excess free RII by polyacrylamide gel electrophoresis under nondenaturing conditions. The identity of the polypeptides comprising the binding protein was subsequently established by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Western blot analysis. Polypeptides with Mrs values of 55,000 and 75,000 that bound monoclonal antibodies 107 and 918, respectively, were observed. Thus the calmodulin-binding component in brain RII preparations is a complex containing an RII dimer and one or two molecules of P75. P75 was also present in high concentrations in Triton X-100 extracts prepared from cerebral cortex and liver membranes. P75 is phosphorylated by both cAMP-dependent and calcium-phospholipid-activated protein kinases.
A method has been developed for binding calmodulin, radioiodinated by the lactoperoxidase method, to denaturing gels and has been used to attempt to identify the calmodulin-binding proteins of cerebral cortex postsynaptic densities (PSDs). Calmodulin primarily bound to the major 51,000 Mr protein in a saturatable manner; secondarily bound to the 60,000 Mr region, 140,000 Mr region, and 230,000 Mr protein; and bound in lesser amounts to a number of other proteins. The major 51,000 Mr calmodulin-binding protein is one of unknown identity. Binding of iodinated calmodulin to these proteins was blocked by EDTA, EGTA, chlorpromazine, and preincubation with unlabeled calmodulin. Calmodulin iodinated by the chloramine-T method, which inactivates calmodulin did not bind to the PSD but bound nonspecifically to histone. Calmodulin did not bind to proteins from a variety of sources for which calmodulin interactions have not been found. Except for three proteins, all of the proteins of synaptic membranes that bind calmodulin could be accounted for by proteins of the PSD which are a part of the synaptic membrane fraction. The major 51,000 M, protein and the corresponding iodinated calmodulin binding were greatly reduced in cerebellar PSDs and this difference between cerebral cortex and cerebellar PSDs is discussed in light of the possible function of calmodulin in synaptic excitatory responses.
A new, rapid method for purification of calmodulin-stimulated phosphodiesterase from bovine, ovine, and porcine brain using only DEAE-agarose and calmodulin-Sepharose chromatography is described. Purified enzymes from the three species each exhibited a single polypeptide of Mr approximately 59,000 on gel electrophoresis under denaturing conditions. Proteolysis of ovine and bovine enzymes with alpha-chymotrypsin, however, yielded different peptides, indicating that these proteins differ in primary sequence. Homogeneous preparations of bovine and ovine enzymes (purified approximately 5,000- and 2,000-fold, respectively) had different specific activities, although their substrate affinities and activation by calmodulin (8- to 14-fold activation, Kact approximately 1 nM) were very similar. The total amount in ovine was almost twice that in bovine brain. The hydrodynamic properties of bovine and ovine enzymes were indistinguishable with a Stokes radius of 4.35 nm and s20,w of 5.95 S. The calculated frictional ratios of 1.30 to 1.38 suggest a slightly asymmetric molecule. Equilibrium sedimentation data yielded apparent Mr approximately 57,000 in the presence of 6 M guanidine and 124,000 and 112,000 for the native bovine and ovine enzymes, respectively. In addition to the enzyme that was purified to homogeneity (pI approximately 5.6), a major fraction of calmodulin-activated phosphodiesterase with a lower isoelectric point was found in bovine and ovine brain. Whether these represent isozymes, perhaps localized in different types of cells, or whether one is a post-translationally modified form, remains to be determined. The existence of these two otherwise very similar forms of the enzyme has apparently not been previously recognized.
A major protein of postsynaptic densities (PSDs), a doublet of 230,000 and 235,000 Mr that becomes enriched in PSDs after treatment of synaptic membranes with 0.5% Triton X-100, has been found to be identical to fodrin (Levine, J., and M. Willard, 1981, J. Cell Biol. 90:631) by the following criteria. The upper bands of the PSD doublet and purified fodrin (alpha-fodrin) were found to be identical since both bands (a) co-migrated on SDS gels, (b) reacted with antifodrin, (c) bound calmodulin, and (d) had identical peptide maps after Staphylococcus aureus protease digestion. The lower bands of the PSD doublet and of purified fodrin (beta-fodrin) were found to be identical since both bands co-migrated on SDS gels and both had identical peptide maps after S. aureus protease digestion. The binding of calmodulin to alpha-fodrin was confirmed by cross-linking azido-125I-calmodulin to fodrin before running the protein on SDS gels. No binding of calmodulin to beta-fodrin was observed with either the gel overlay or azido-calmodulin techniques. A second calmodulin binding protein in the PSD has been found to be the proteolytic product of alpha-fodrin. This band (140,000 Mr), which can be created by treating fodrin with chymotrypsin, both binds calmodulin and reacts with antifodrin.
Cerebrum and cerebellum contain numerous asymmetric synapses characterized by the presence of a postsynaptic thickening prominently stained by phosphotungstic acid and other electron-dense stains suitable for electron microscopy. A 51,000-Mr protein, copurified in postsynaptic density-enriched fractions from cerebrum, is considered to be a well established marker for the postsynaptic density. On the basis of two criteria, our studies demonstrate that the 51,000-Mr protein marker for postsynaptic densities is virtually absent in cerebellum, First, it is present in negligible amounts in deoxycholate-insoluble fractions from cerebellum but abundant in parallel fractions from cerebrum. Secondly, the 51,000-Mr protein, which binds 125I-calmodulin after SDS PAGE is readily visualized in membrane samples from cerebrum but is virtually undetectable in cerebellar samples. It is apparent that these results require reexamination of the role of the 51,000-Mr protein in postsynaptic density structures.
A protein determination method which involves the binding of Coomassie Brilliant Blue G-250 to protein is described. The binding of the dye to protein causes a shift in the absorption maximum of the dye from 465 to 595 nm, and it is the increase in absorption at 595 nm which is monitored. This assay is very reproducible and rapid with the dye binding process virtually complete in approximately 2 min with good color stability for 1 hr. There is little or no interference from cations such as sodium or potassium nor from carbohydrates such as sucrose. A small amount of color is developed in the presence of strongly alkaline buffering agents, but the assay may be run accurately by the use of proper buffer controls. The only components found to give excessive interfering color in the assay are relatively large amounts of detergents such as sodium dodecyl sulfate, Triton X-100, and commercial glassware detergents. Interference by small amounts of detergent may be eliminated by the use of proper controls.
A method has been developed for binding calmodulin, radioiodinated by the lactoperoxidase method, to denaturing gels and has been used to attempt to identify the calmodulin-binding proteins of cerebral cortex postsynaptic densities (PSDs). Calmodulin primarily bound to the major 51,000 Mr protein in a saturatable manner; secondarily bound to the 60,000 Mr region, 140,000 Mr region, and 230,000 Mr protein; and bound in lesser amounts to a number of other proteins. The major 51,000 Mr calmodulin-binding protein is one of unknown identity. Binding of iodinated calmodulin to these proteins was blocked by EDTA, EGTA, chlorpromazine, and preincubation with unlabeled calmodulin. Calmodulin iodinated by the chloramine-T method, which inactivates calmodulin did not bind to the PSD but bound nonspecifically to histone. Calmodulin did not bind to proteins from a variety of sources for which calmodulin interactions have not been found. Except for three proteins, all of the proteins of synaptic membranes that bind calmodulin could be accounted for by proteins of the PSD which are a part of the synaptic membrane fraction. The major 51,000 M, protein and the corresponding iodinated calmodulin binding were greatly reduced in cerebellar PSDs and this difference between cerebral cortex and cerebellar PSDs is discussed in light of the possible function of calmodulin in synaptic excitatory responses.
We recently reported the detection of multiple classes of calmodulin-binding proteins in subcellular fractions of chicken embryo fibroblasts by using a gel binding procedure (Van Eldik, L.J., and W.H. Burgess, 1983, J. Biol. Chem., 258:4539-4547). In this report we identify many of these calmodulin-binding proteins and provide further evidence for the existence of multiple classes of calmodulin-binding proteins based on the interaction of these proteins with calmodulin and other calcium-modulated proteins. The fact that, in some cases, the same calmodulin-binding protein can bind troponin C and S100 alpha suggests that similar functional domains may be present in these distinct calcium-modulated proteins. We also have used protocols based on purification steps for calmodulin-binding proteins and calmodulin-regulated activities from other systems, in conjunction with enzymatic assays and various immunological methods, to identify many of the calmodulin-binding proteins in chicken embryo fibroblasts. The identities of these proteins suggest in vivo roles for calmodulin in the regulation of cell shape and motility, cyclic nucleotide metabolism, and possibly nucleic acid and protein turnover in fibroblasts.
Cerebrum and cerebellum contain numerous asymmetric synapses characterized by the presence of a postsynaptic thickening prominently stained by phosphotungstic acid and other electron-dense stains suitable for electron microscopy. A 51,000-Mr protein, copurified in postsynaptic density-enriched fractions from cerebrum, is considered to be a well established marker for the postsynaptic density. On the basis of two criteria, our studies demonstrate that the 51,000-Mr protein marker for postsynaptic densities is virtually absent in cerebellum, First, it is present in negligible amounts in deoxycholate-insoluble fractions from cerebellum but abundant in parallel fractions from cerebrum. Secondly, the 51,000-Mr protein, which binds 125I-calmodulin after SDS PAGE is readily visualized in membrane samples from cerebrum but is virtually undetectable in cerebellar samples. It is apparent that these results require reexamination of the role of the 51,000-Mr protein in postsynaptic density structures.
A major protein of postsynaptic densities (PSDs), a doublet of 230,000 and 235,000 Mr that becomes enriched in PSDs after treatment of synaptic membranes with 0.5% Triton X-100, has been found to be identical to fodrin (Levine, J., and M. Willard, 1981, J. Cell Biol. 90:631) by the following criteria. The upper bands of the PSD doublet and purified fodrin (alpha-fodrin) were found to be identical since both bands (a) co-migrated on SDS gels, (b) reacted with antifodrin, (c) bound calmodulin, and (d) had identical peptide maps after Staphylococcus aureus protease digestion. The lower bands of the PSD doublet and of purified fodrin (beta-fodrin) were found to be identical since both bands co-migrated on SDS gels and both had identical peptide maps after S. aureus protease digestion. The binding of calmodulin to alpha-fodrin was confirmed by cross-linking azido-125I-calmodulin to fodrin before running the protein on SDS gels. No binding of calmodulin to beta-fodrin was observed with either the gel overlay or azido- calmodulin techniques. A second calmodulin binding protein in the PSD has been found to be the proteolytic product of alpha-fodrin. This band (140,000 Mr), which can be created by treating fodrin with chymotrypsin, both binds calmodulin and reacts with antifodrin.
A simple, economical, and efficient procedure for analysis of proteins (Western blotting) and DNA (Southern blotting) transferred to nitrocellulose for reaction with antibodies or nucleic acid probes is described. The techniques utilize nonfat dry milk as a protein-nucleic acid source for blocking nonspecific reactions, as an incubation medium, and for subsequent washing to remove unreacted reagents. The incubation cocktail, termed BLOTTO (Bovine Lacto Transfer Technique Optimizer), is superior to bovine serum albumin or gelatin for preventing nonspecific absorption in Western blot analyses and does not require the use of detergents or chaotropic agents to effect efficient reduction of background. BLOTTO, at the proper dilution in NaClNa citrate, is just as efficient in Southern blot analyses as more complicated cocktails typically used in the latter technique. We also found that BLOTTO works well for blocking, incubating, and washing ELISA plate assays relative to the normal BSA carrier, at a considerable savings to the laboratory.
Biotin-labelled DNA probes, prepared by nick-translation in the presence of biotinylated analogs of TTP, are hybridized to DNA or RNA immobilized on nitrocellulose filters. After removal of residual probe, the filters are incubated for 2--5 min with a preformed complex made with avidin-DH (or streptavidin) and biotinylated polymers of intestinal alkaline phosphatase. The filters are then incubated with a mixture of 5-bromo-4-chloro-3-indolyl phosphate and nitro blue tetrazolium, which results in the deposition of a purple precipitate at the sites of hybridization. This procedure will detect target sequences in the 1- to 10-pg range after enzyme incubation periods of 1 hr or less. The incubation period can be extended up to 24 hr, if required, to increase the color intensity of the hybridization signal. Furthermore, at high probe concentrations (250--7560 ng/ml), biotin-labeled DNA exhibits lower nonspecific binding to nitrocellulose than does radiolabeled DNA, so hybridization times required for the analysis of unique mammalian gene sequences can be decreased to 1--2 hr. This nonradiographic method of probe detection should be of general utility for genetic studies using Southern, RNA, or dot-blot hybridization protocols.
An activating factor of adenylate cyclase (EC 4.6.1.1) HAS BEEN OBTAINED FROM DETERGENT-DISPERSED PREPARATIONS OF PORCINE CEREBRAL CORTEX BY COLUMN CHROMATOGRAPHY ON ECTEOLA-cellulose. The factor was identified by acrylamide gel electrophoresis and by enzyme activation studies as the Ca2+-binding protein that regulates the activity of a brain cyclic nucleotide phosphodiesterase. This Ca2+-binding protein confers a Ca2+-dependent activation upon the adenylate cyclase, which is reversed by the subsequent addition of egta in excess of the free Ca2+. It is proposed that this Ca2+-dependent regulator controls enzymatic activities responsible for the synthesis of adenosine 3':5'-monophosphate and for the hydrolysis of guanosine 3':5'-monophosphate.
The Ca2+-dependent, reversible, interaction of cyclic adenosine 3',5'-monophosphate (cAMP) phosphodiesterase with its activator has been used to purify the enzyme by affinity chromatography. Activator-dependent cAMP phosphodiesterase is only a minor component of the proteins specifically adsorbed in the presence of Ca2+ by the Ca2+-dependent activator protein coupled to Sepharose and subsequently released by [ethylenebis(oxyethylenenitrilo)]tetraacetic acid. The major protein component can be partially resolved from the enzyme by gel filtration on Sephadex G-200. This protein has been purified to apparent homogeneity and shown to be composed of two polypeptide chains with molecular weights of 61,000 and 15,000 respectively. This protein is, by itself, devoid of phosphodiesterase activity and inhibits the activation of cAMP phosphodiesterase by its activator without affecting the basal activity. Thus, activation of cAMP phosphodiesteriase by the Ca2+-dependent activator protein may be controlled by interactions with yet a third component of the enzyme complex.
The calcium-dependent regulatory protein (CDR).Ca2+ sensitive cyclic nucleotide phosphodiesterase was purified to apparent homogeneity from bovine heart by using ammonium sulfate fractionation, DEAE-ceelulose chromatography, and CDR-Sepharose affinity chromatography. The enzyme was purifed 13 750-fold with a 10% yield and a specific activity of 275 mumol of cAMP min-1 mg-1. The purified enzyme ran as a single band during sodium dodecyl sulfate-polyacrylamide gel electrophoresis with an apparent molecular weight of 57 000. Phosphodiesterase activity was stimulated 10-fold by Ca2+ and CDR with half-maximal activation occurring at 9 ng/assay. [125I]CDR was cross-linked to the purified phosphodiesterase by using dimethyl suberimidate Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the cross-linked products revealed a number of discrete 125I-labeled bands. The molecular weights of the cross-linked products indicate that the stoichiometry of the phosphodiesterase complex is A2C2, where A is the phosphodiesterase catalytic subunit and C is the calcium-dependent regulatory protein.
Synaptic vesicles have a Ca(2+)-dependent protein kinase system that may play a role in mediating Ca(2+)-stimulated neurotransmitter release and vesicle function. Calcium's ability to initiate norepinephrine release and protein phosphorylation in synaptic vesicle preparations was shown to be stimulated by the presence of an endogenous heat-stable vesicle protein fraction. The heat stability and characteristics of this endogenous vesicle fraction were similar to those of calmodulin (Ca(2+)-dependent regular protein) isolated from rat and bovine brain. Calmodulin, like endogenous heat-stable vesicle factor, restored calcium's ability to stimulate vesicle neurotransmitter release and protein kinase activity. Calmodulin-like vesicle protein and purified calmodulin were also equally effective in stimulating cyclic nucleotide-dependent phosphodiesterase, further indicating that these two proteins are functionally equivalent. Depolarization-dependent Ca(2+) uptake in intact synaptosomes simultaneously stimulated release of neurotransmitter and phosphorylation of particular synaptic vesicle proteins that were shown in the isolated vesicle preparation to be dependent on Ca(2+) and calmodulin. The results suggest that calcium's effects on neurotransmitter release and presynaptic nerve terminal protein phosphorylation may be mediated by endogenous calmodulin-like proteins.
THE important role of Ca2+ in the physiology of the nervous system is well documented1,2. However, the biochemical mechanisms underlying certain of its physiological effects, such as stimulus-secretion coupling3,4 and synthesis of cate-cholamines5,6, have not yet been elucidated. Calcium has been implicated in several biochemical reactions of potential importance to synaptic function. Thus, calcium and a heat-stable calcium-binding protein activate the cyclic nucleotide phosphodiesterase from mammalian brain7,8. The calcium-dependent regulator (CDR) from porcine brain9, bovine heart10 and bovine brain11 has been purified and characterised. CDR seems to be a calcium receptor as it binds calcium strongly and specifically. There is evidence that a CDR.Ca2+ complex is the true activator of cyclic nucleotide phosphodiesterase12-14. A detergent-solubilised preparation of brain adenylate cyclase can also be activated by this calcium-binding protein15. Calcium stimulates protein phosphorylation in both intact16,17 and lysed18,19 synaptosomes and this cyclic nucleotide-independent mechanism may mediate or modulate some of the intracellular effects of Ca2+ on the function of presynaptic nerve terminals. We report here that calcium-dependent phosphorylation of synaptosomal membrane fractions from rat cerebral cortex requires an endogenous protein factor present in the synaptosomal cytoplasm. Calcium stimulated phosphorylation is lost on purification of synaptic membranes and can be effectively recovered by reconstitution with either the synaptosomal cytoplasm or with a purified preparation of CDR. Thus, regulation by calcium of calcium-dependent protein kinase activity may be mediated physiologically by the calcium-binding protein postulated to regulate cyclic nucleotide phosphodiesterase and adenylate cyclase.
A protein determination method which involves the binding of Coomassie Brilliant Blue G-250 to protein is described. The binding of the dye to protein causes a shift in the absorption maximum of the dye from 465 to 595 nm, and it is the increase in absorption at 595 nm which is monitored. This assay is very reproducible and rapid with the dye binding process virtually complete in approximately 2 min with good color stability for 1 hr. There is little or no interference from cations such as sodium or potassium nor from carbohydrates such as sucrose. A small amount of color is developed in the presence of strongly alkaline buffering agents, but the assay may be run accurately by the use of proper buffer controls. The only components found to give excessive interfering color in the assay are relatively large amounts of detergents such as sodium dodecyl sulfate, Triton X-100, and commercial glassware detergents. Interference by small amounts of detergent may be eliminated by the use of proper controls.
Calcineurin, a calmodulin-stimulated protein phosphatase, was a substrate for purified bovine brain protein carboxyl O-methyltransferase (protein O-methyltransferase; EC 2.1.1.24) and incorporated up to 2 mol of CH3 per mol of calcineurin. Carboxyl methylation was dependent on the concentrations of S-adenosyl-L-[methyl-3H]methionine and was prevented by addition of the carboxyl methylation inhibitor S-adenosylhomocysteine. The stoichiometry of methyl group incorporation was related to the ratio of methyltransferase/calcineurin. The rate of spontaneous hydrolysis of carboxyl methylester groups on calcineurin increased rapidly above pH 6.5 with those on native carboxyl-methylated calcineurin substantially more labile than for trichloracetic acid-precipitated calcineurin. Polyacrylamide gel electrophoresis in the presence of NaDodSO4 (pH 2.4) confirmed that the A subunit of calcineurin (Mr = 61,000) was the primary site of carboxyl methylation with little, if any, modification of the B subunit (Mr = 18,000). When carboxyl-methylated calcineurin (approximately 1-2 mol of CH3 per mol of protein) was assayed for p-nitrophenyl phosphatase activity at pH 6.5, a marked inhibition of calmodulin-stimulated activity was observed while there was little effect on Mn2+-stimulated phosphatase activity. Thus, calcineurin appears to be an excellent substrate for protein carboxyl O-methylation and this modification, which impairs calmodulin stimulation of phosphatase activity, may be of functional significance.
The activity of a mixture of a purified and a crude cyclic 3???,5???-nucleotide phosphodiesterase was greater than the summed activities of the individual preparations. The crude enzyme contained an activator, which was removed from the purified enzyme during purification. The activator, isolated free of phosphodiesterase activity, effectively reconstituted the activity of the purified enzyme. The relative inactivity of purified phosphodiesterase was due to removal of the activator from the enzyme.
To streamline detection of calmodulin-binding proteins, blotting techniques for the electrophoretic transfer of proteins onto nitrocellulose filters, followed by overlay with 125I-calmodulin, have been adapted. Autoradiography of the 125I-calmodulin-labeled blots allows the identification and quantitation of proteins that possess affinity for calmodulin. Five protocols for suppressing nonspecific binding and for enhancing specific interactions of 125I-calmodulin with electrophoretically separated proteins were investigated. Tween 20 and bovine serum albumin alone, as well as combinations of bovine serum albumin and poly(ethylene oxide) or hemoglobin and gelatin, were evaluated as quenching and enhancing agents. Tween 20 proved highly effective for quenching nonspecific binding and for enhancing specific 125I-calmodulin binding of a 61,000-Mr rat brain protein, which was only faintly observed on blots quenched with proteins alone. However, Tween 20 dissociated 50% of 68,000-Mr proteins and 80% of 21,000-Mr 125I-labeled protein standards from the nitrocellulose filter. An alternative, the combination of bovine serum albumin followed by incubation with 15,000- to 20,000-Mr poly(ethylene oxide), proved satisfactory for the recovery of 61,000-Mr calmodulin-binding activity and for the detection of calmodulin-binding peptides (50,000 to 14,000 Mr) produced by limited proteolysis of rat brain 51,000-Mr calmodulin-binding protein. These blotting procedures for detection of calmodulin-binding proteins are compatible with a variety of one-dimensional and two-dimensional electrophoresis systems, including a two-dimensional electrophoresis system utilizing urea and sodium dodecyl sulfate in the first dimension and nonurea sodium dodecyl sulfate electrophoresis in the second, a system which proved useful for resolving calmodulin-binding proteins displaying anomalous electrophoretic migration in the presence of urea.
Different azidocalmodulin derivatives were synthesized by modification of either one carboxylic acid group or one or several arginine residues and their binding and activation capacity investigated in three target enzyme systems. The systems studied were smooth-muscle myosin light-chain kinase, cardiac sarcoplasmic-reticulum kinase and erythrocyte (Mg2+ + Ca2+)-dependent ATPase. The results indicated that the activation ability of each calmodulin derivative was different depending on the system studied. Binding studies carried out by the displacement of 125I-calmodulin indicated that the monosubstitutions did not greatly alter the apparent Kd of calmodulin for the enzymes but that the modification of four arginine residues caused a 4-8-fold increase in the apparent Kd in all systems. These results have shown that azidocalmodulin derivatives may have different degrees of usefulness in the study of calmodulin target proteins in different systems, with the behaviour of the derivatives not predictable on the basis of the nature (soluble or membrane-bound) or the type (ATPase or kinase) of enzyme system to be investigated. However, the monosubstituted calmodulin and, in particular, the carboxylic acid-group-modified derivative (where the modification was statistically dispersed over the protein chain) are good candidates for photolabelling calmodulin-binding proteins.
Tubulin is a major substrate for endogenous Ca2+-calmodulin-dependent phosphorylation in synaptic cytoplasm. The present study details the purification to apparent homogeneity and characterization of a brain cytosolic Ca2+-calmodulin-dependent kinase which phosphorylates tubulin and microtubule-associated proteins as major substrates. The cytosolic kinase system, purified by sequential chromatography on phosphocellulose resin, calmodulin-affinity resin, and Fractogel TSK HW-55, chromatographs as a homogeneous complex of approximately 600,000 Da on Sephacryl S-300. This calmodulin-dependent kinase possesses a group of properties which specifically characterize this enzyme system: 1) the enzyme contains two calmodulin-binding doublets, rho and sigma, of approximately 52,000 and 63,000 Da, respectively; 2) both the rho and the sigma subunits demonstrate isoelectric points between 6.7 and 7.2; 3) both the rho and sigma subunits demonstrate autophosphorylation; 4) both the rho and sigma subunits show significant homologies as assessed by tryptic peptide fingerprints; 5) in the absence of substrate, both the rho and sigma subunits manifest lower mobility autophosphorylated species; 6) the kinase phosphorylates beta-tubulin equally on threonine and serine residues. Substrate specificity, kinetic parameters, calmodulin-binding properties, subunit composition, and subunit isoelectric points clearly differentiate this enzyme from other previously reported calmodulin-dependent kinases.
Caldesmon is a calmodulin-binding and F-actin-binding protein originally purified from chicken gizzard smooth muscle. This protein binds to F-actin filaments in a Ca2+- and calmodulin-dependent 'flip-flop' fashion, thereby regulating the function of actin filaments. Here we report that various lines of cultured cells contain a M(r) 77,000 protein that specifically reacts with the affinity-purified caldesmon antibody raised against chicken gizzard caldesmon. Among the fibroblast proteins that had been pulse-labeled with [35S]methionine, the M(r) 77,000 protein was the only protein band detected on the NaDodSO4 gel that reacted with the anticaldesmon. The subcellular distribution of the M(r) 77,000 protein was investigated by the indirect immunofluorescence technique using the anticaldesmon. In the fibroblast cell lines examined, the immunofluorescence localized along the cellular stress fibers and in leading edges of the cell. In Rous sarcoma virus-transformed cells (S7-1), however, the distribution of the fluorescence changed to a diffuse and blurred appearance. These staining patterns of anticaldesmon obtained with the normal and transformed cells coincided with those of antiactin in the corresponding states, strongly suggesting the functional linkage between the M(r) 77,000 protein and actin filaments. We propose to refer to this M(r) 77,000 protein as caldesmon77. The cellular level of Caldesmon77 in transformed S7-1 cells decreased to about one-third of that in their normal counterparts (cell line no. 7). Essentially the same result was obtained with normal rat kidney cells infected with the temperature-sensitive transformation mutant Schmidt-Ruppin strain of Rous sarcoma virus (68 N2 clone). The cellular level of caldesmon77 observed at a permissive temperature (35° C) was about one-third of that a nonpermissive temperature (38.5°C). These changes of caldesmon77 in transformed cells may correlate with the loss of Ca2+ regulation in the transformed state.
The calmodulin-dependent protein phosphatase from bovine brain is composed of two subunits: subunit A, Mr 60,000, and subunit B, Mr 16,500. Using in vitro immunization techniques, we have produced a monoclonal antibody specific for the phosphatase. The antibody was immobilized to Sepharose 4B to prepare an immunoabsorbent column, which was used to purify the enzyme. Phosphatase isolated from the column showed a polypeptide with Mr 60,000, equivalent to subunit A, which showed calmodulin-dependent phosphatase activity. Subunit B was not obtained from the column. Limited trypsin digestion stimulated phosphatase activity, yielding polypeptides of Mr 59,000, 43,000, and 16,000; the phosphatase activity after trypsin digestion was calmodulin independent. Chromatography of trypsin-treated phosphatase on an immunoaffinity column yielded two proteins, Mr 59,000 and 43,000, that were catalytically active and calmodulin independent. In a separate experiment, the two subunits of the phosphatase were separated by gel filtration in 6 M urea. Subunit A isolated from the filtration column showed little or no activity in the presence of Ca2+ and calmodulin, but it showed calmodulin-dependent phosphatase activity in the presence of 0.8 mM Mn2+. Subunit B was catalytically inactive. Collectively, these results indicate that subunit A and its proteolytic fragment contain the catalytic site and the antigenic determinant for the monoclonal antibody.
An immunoassay method is described for the quantitative determination of synapsin I (protein I) and of a 36,000-dalton membrane protein from rat brain synaptic vesicles. The samples are spotted on nitrocellulose membrane filters, incubated sequentially with specific antibodies and 125I-labeled protein A, and assayed for radioactivity in a gamma scintillation counter. Conditions have been established to prevent losses of protein from the sheets during processing, to quench background radioactivity, and to adjust the sensitivity to the range desired. A large number of samples can be handled in parallel. The assay does not require iodination of the antigen and is accurate even with crude tissue samples. Standard curves were linear over a 20- to 50-fold range. The sensitivity of the method is such that 10 pmol of synapsin I and 50 ng of total vesicle membrane protein could be measured with accuracy. The method should prove useful for a wide range of proteins.
Calmodulin binds quantitatively to phenyl-Sepharose and octyl-Sepharose affinity columns in the presence of micromolar concentrations of Ca2+. In addition to EGTA, calmodulin also can be eluted from these affinity columns with low ionic strength buffer, non-ionic detergent (i.e., 1% Triton X-100), or ethylene glycol (50%), suggesting hydrophobic interaction. Using hydrophobic interaction chromatography calmodulin can be purified to homogeneity from bovine brain homogenate in a single step. For large-scale purification the protein fraction containing calmodulin was concentrated by isoelectric precipitation prior to application to the affinity column. The yield obtained by this procedure (160–180 mg calmodulin per kg brain) is significantly greater, and the time required (∼ 5 hr) is substantially less, than that of previously described procedures for calmodulin purification. It is apparent that phenyl-Sepharose offers several advantages over phenothiazine-Sepharose for affinity purification of calmodulin.
Calmodulin, a protein that binds calcium with high affinity and specificity, is structurally conserved and functionally preserved throughout the animal and plant kingdoms. It serves as an intracellular Ca2+-receptor and mediates the Ca2+ regulation of cyclic nucleotide and glycogen metabolism, secretion, motility and Ca2+ transport. Calmodulin is also a dynamic component of the mitotic apparatus.
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