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ABSTRACT: The Graded Autocatalysis Replication Domain (GARD) model describes an origin of life scenario which involves non-covalent compositional assemblies, made of monomeric mutually catalytic molecules. GARD constitutes an alternative to informational biopolymers as a mechanism of primordial inheritance. In the present work, we examined the effect of mutations, one of the most fundamental mechanisms for evolution, in the context of the networks of mutual interaction within GARD prebiotic assemblies. We performed a systematic analysis analogous to single and double gene deletions within GARD. While most deletions have only a small effect on both growth rate and molecular composition of the assemblies, ~10% of the deletions caused lethality, or sometimes showed enhanced fitness. Analysis of 14 different network properties on 2,000 different GARD networks indicated that lethality usually takes place when the deleted node has a high molecular count, or when it is a catalyst for such node. A correlation was also found between lethality and node degree centrality, similar to what is seen in real biological networks. Addressing double knockout mutations, our results demonstrate the occurrence of both synthetic lethality and extragenic suppression within GARD networks, and convey an attempt to correlate synthetic lethality to network node-pair properties. The analyses presented help establish GARD as a workable alternative prebiotic scenario, suggesting that life may have begun with large molecular networks of low fidelity, that later underwent evolutionary compaction and fidelity augmentation.
Journal of Molecular Evolution 09/2009; 69(5):568-78. · 2.27 Impact Factor
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05/2008; , ISBN: 9780470048672
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ABSTRACT: Despite their key roles in many normal and pathological processes, the molecular details by which zinc-dependent proteases hydrolyze their physiological substrates remain elusive. Advanced theoretical analyses have suggested reaction models for which there is limited and controversial experimental evidence. Here we report the structure, chemistry and lifetime of transient metal-protein reaction intermediates evolving during the substrate turnover reaction of a metalloproteinase, the tumor necrosis factor-alpha converting enzyme (TACE). TACE controls multiple signal transduction pathways through the proteolytic release of the extracellular domain of a host of membrane-bound factors and receptors. Using stopped-flow x-ray spectroscopy methods together with transient kinetic analyses, we demonstrate that TACE's catalytic zinc ion undergoes dynamic charge transitions before substrate binding to the metal ion. This indicates previously undescribed communication pathways taking place between distal protein sites and the enzyme catalytic core. The observed charge transitions are synchronized with distinct phases in the reaction kinetics and changes in metal coordination chemistry mediated by the binding of the peptide substrate to the catalytic metal ion and product release. Here we report key local charge transitions critical for proteolysis as well as long sought evidence for the proposed reaction model of peptide hydrolysis. This study provides a general approach for gaining critical insights into the molecular basis of substrate recognition and turnover by zinc metalloproteinases that may be used for drug design.
Proceedings of the National Academy of Sciences 04/2007; 104(12):4931-6. · 9.68 Impact Factor
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T. Comp. Sys. Biology. 01/2005; 1:14-27.
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ABSTRACT: The metalloproteinase tumor necrosis factor-alpha-converting enzyme (TACE) is involved in the regulation of several key physiological and pathological processes. Therefore, potent and selective synthetic inhibitors are highly sought for the study of the physiological roles of TACE as well as for therapeutic purposes. Because of the high structural similarities between the active site of TACE and those of other related zinc endopeptidases such as disintegrin (ADAMs) and matrix metalloproteinases (MMPs), the design of such tailor-made inhibitors is not trivial. To obtain new insights into this problem, we have used a selective MMP inhibitor as a probe to examine the structural and kinetic effects occurring at the active site of TACE upon inhibition. Specifically, we used the selective MMP mechanism-based inhibitor SB-3CT to characterize the fine structural and electronic differences between the catalytic zinc ions within the active sites of TACE and MMP-2. We show that SB-3CT directly binds the metal ion of TACE as observed before with MMP-2. However, in contrast to MMP-2, the binding mode of SB-3CT to the catalytic zinc ion of TACE is different in the length of the Zn-S(SB-3CT) bond distance and the total effective charge of the catalytic zinc ion. In addition, SB-3CT inhibits TACE in a non-competitive fashion by inducing significant conformational changes in the structure. For MMP-2, SB-3CT behaved as a competitive inhibitor and no significant conformational changes were observed. An examination of the second shell amino acids surrounding the catalytic zinc ion of these enzymes indicated that the active site of TACE is more polar than that of MMP-2 and of other MMPs. On the basis of these results, we propose that although there is a seemingly high structural similarity between TACE and MMP-2, these enzymes are significantly diverse in the electronic and chemical properties within their active sites.
Journal of Biological Chemistry 08/2004; 279(30):31646-54. · 4.77 Impact Factor
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ABSTRACT: Tumor necrosis factor-alpha-converting enzyme (TACE) is a disintegrin metalloproteinase that processes tumor necrosis factor and a host of other ectodomains. TACE is biosynthesized as a zymogen, and activation requires the removal of an inhibitory pro domain. Little is known about how the pro domain exerts inhibition for this class of enzymes. To study the inhibitory properties of the pro domain of TACE, we have expressed it in isolation from the rest of the protease. Here we show that the TACE pro domain (TACE Pro) is a stably folded protein that is able to inhibit this enzyme. TACE Pro inhibited the catalytic domain of TACE with an IC(50) of 70 nm. In contrast, this inhibitory potency decreased over 30-fold against a TACE form containing the catalytic plus disintegrin/cysteine-rich domains (IC(50) greater that 2 microm). The disintegrin/cysteine-rich region in isolation also decreases the interaction of TACE Pro with the catalytic domain. Surprisingly, we found that the cysteine switch motif located in TACE Pro was not essential for inhibition of the enzymatic activity of TACE; the pro domain variant C184A showed the same inhibitory potency against both TACE forms as wild type TACE Pro. X-ray absorption spectroscopy experiments indicate that binding of TACE Pro to the catalytic domain does include ligation of the catalytic zinc ion via the sulfur atom of its conserved Cys(184) residue. Moreover, the binding of TACE Pro to the catalytic zinc ion partially oxidizes the catalytic zinc ion of the enzyme. Despite this, the nature of the interaction between the pro and catalytic domains of TACE is not consistent with a simple competitive model of inhibition based on cysteine switch ligation of the zinc ion within the active site of TACE.
Journal of Biological Chemistry 08/2004; 279(30):31638-45. · 4.77 Impact Factor
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ABSTRACT: L-selectin is a key lectin essential for leukocyte capture and rolling on vessel walls. Functional adhesion of L-selectin requires a minimal threshold of hydrodynamic shear. Using high temporal resolution videomicroscopy, we now report that L-selectin engages its ligands through exceptionally labile adhesive bonds (tethers) even below this shear threshold. These tethers share a lifetime of 4 ms on distinct physiological ligands, two orders of magnitude shorter than the lifetime of the P-selectin-PSGL-1 bond. Below threshold shear, tether duration is not shortened by elevated shear stresses. However, above the shear threshold, selectin tethers undergo 14-fold stabilization by shear-driven leukocyte transport. Notably, the cytoplasmic tail of L-selectin contributes to this stabilization only above the shear threshold. These properties are not shared by P-selectin- or VLA-4-mediated tethers. L-selectin tethers appear adapted to undergo rapid avidity enhancement by cellular transport, a specialized mechanism not used by any other known adhesion receptor.
The Journal of Cell Biology 12/2003; 163(3):649-59. · 10.26 Impact Factor
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ABSTRACT: L-selectin is a key lectin essential for leukocyte capture and rolling on vessel walls. Functional adhesion of L-selectin
requires a minimal threshold of hydrodynamic shear. Using high temporal resolution videomicroscopy, we now report that L-selectin
engages its ligands through exceptionally labile adhesive bonds (tethers) even below this shear threshold. These tethers share
a lifetime of 4 ms on distinct physiological ligands, two orders of magnitude shorter than the lifetime of the P-selectin–PSGL-1
bond. Below threshold shear, tether duration is not shortened by elevated shear stresses. However, above the shear threshold,
selectin tethers undergo 14-fold stabilization by shear-driven leukocyte transport. Notably, the cytoplasmic tail of L-selectin
contributes to this stabilization only above the shear threshold. These properties are not shared by P-selectin– or VLA-4–mediated
tethers. L-selectin tethers appear adapted to undergo rapid avidity enhancement by cellular transport, a specialized mechanism
not used by any other known adhesion receptor.
The Journal of Cell Biology 11/2003; 163(3):649-659. · 10.26 Impact Factor
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ABSTRACT: Drosophila gliotactin (Gli) is a 109-kDa transmembrane, cholinesterase-like adhesion molecule (CLAM), expressed in peripheral glia, that is crucial for formation of the blood-nerve barrier. The intracellular portion (Gli-cyt) was cloned and expressed in the cytosolic fraction of Escherichia coli BLR(DE3) at 45 mg/L and purified by Ni-NTA (nitrilotriacetic acid) chromatography. Although migration on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), under denaturing conditions, was unusually slow, molecular weight determination by matrix-assisted laser desorption/ionization time-of-flight (MALDI-TOF) mass spectrometry (MS) confirmed that the product was consistent with its theoretical size. Gel filtration chromatography yielded an anomalously large Stokes radius, suggesting a fully unfolded conformation. Circular dichroism (CD) spectroscopy demonstrated that Gli-cyt was >50% unfolded, further suggesting a nonglobular conformation. Finally, 1D-(1)H NMR conclusively demonstrated that Gli-cyt possesses an extended unfolded structure. In addition, Gli-cyt was shown to possess charge and hydrophobic properties characteristic of natively unfolded proteins (i.e., proteins that, when purified, are intrinsically disordered under physiologic conditions in vitro).
Proteins Structure Function and Bioinformatics 11/2003; 53(3):758-67. · 3.39 Impact Factor
