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ABSTRACT: Activated sulfate in the form of 3'-phosphoadenosine 5'-phosphosulfate (PAPS) is needed for all sulfation reactions in eukaryotes with implications for the build-up of extracellular matrices, retroviral infection, protein modification, and steroid metabolism. In metazoans, PAPS is produced by bifunctional PAPS synthases (PAPSS). A major question in the field is why two human protein isoforms, PAPSS1 and -S2, are required that cannot complement for each other. We provide evidence that these two proteins differ markedly in their stability as observed by unfolding monitored by intrinsic tryptophan fluorescence as well as circular dichroism spectroscopy. At 37 °C, the half-life for unfolding of PAPSS2 is in the range of minutes, whereas PAPSS1 remains structurally intact. In the presence of their natural ligand, the nucleotide adenosine 5'-phosphosulfate (APS), PAPS synthase proteins are stabilized. Invertebrates only possess one PAPS synthase enzyme that we classified as PAPSS2-type by sequence-based machine learning techniques. To test this prediction, we cloned and expressed the PPS-1 protein from the roundworm Caenorhabditis elegans and also subjected this protein to thermal unfolding. With respect to thermal unfolding and the stabilization by APS, PPS-1 behaved like the unstable human PAPSS2 protein suggesting that the less stable protein is evolutionarily older. Finally, APS binding more than doubled the half-life for unfolding of PAPSS2 at physiological temperatures and effectively prevented its aggregation on a time scale of days. We propose that protein stability is a major contributing factor for PAPS availability that has not as yet been considered. Moreover, naturally occurring changes in APS concentrations may be sensed by changes in the conformation of PAPSS2.
Journal of Biological Chemistry 03/2012; 287(21):17645-55. · 4.77 Impact Factor
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Stefanie Ohlig,
Pershang Farshi,
Ute Pickhinke, Johannes van den Boom,
Susanne Höing,
Stanislav Jakuschev,
Daniel Hoffmann,
Rita Dreier,
Hans R Schöler,
Tabea Dierker,
Christian Bordych,
Kay Grobe
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ABSTRACT: All Hedgehog (Hh) proteins are released from producing cells despite being synthesized as N- and C-terminally lipidated, membrane-tethered molecules. Thus, a cellular mechanism is needed for Hh solubilization. We previously suggested that a disintegrin and metalloprotease (ADAM)-mediated shedding of Sonic hedgehog (ShhNp) from its lipidated N and C termini results in protein solubilization. This finding, however, seemed at odds with the established role of N-terminal palmitoylation for ShhNp signaling activity. We now resolve this paradox by showing that N-palmitoylation of ShhNp N-terminal peptides is required for their proteolytic removal during solubilization. These peptides otherwise block ShhNp zinc coordination sites required for ShhNp binding to its receptor Patched (Ptc), explaining the essential yet indirect role of N-palmitoylation for ShhNp function. We suggest a functional model in which membrane-tethered multimeric ShhNp is at least partially autoinhibited in trans but is processed into fully active, soluble multimers upon palmitoylation-dependent cleavage of inhibitory N-terminal peptides.
Developmental cell 06/2011; 20(6):764-74. · 13.36 Impact Factor
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ABSTRACT: Peptidyl-prolyl cis/trans isomerases (PPIases) are enzymes assisting protein folding and protein quality control in organisms of all kingdoms of life. In contrast to the other sub-classes of PPIases, the cyclophilins and the FK-506 binding proteins, little was formerly known about the parvulin type of PPIase in Archaea. Recently, the first solution structure of an archaeal parvulin, the PinA protein from Cenarchaeum symbiosum, was reported. Investigation of occurrence and frequency of PPIase sequences in numerous archaeal genomes now revealed a strong tendency for thermophilic microorganisms to reduce the number of PPIases. Single-domain parvulins were mostly found in the genomes of recently proposed deep-branching archaeal subgroups, the Thaumarchaeota and the ARMANs (archaeal Richmond Mine acidophilic nanoorganisms). Hence, we used the parvulin sequence to reclassify available archaeal metagenomic contigs, thereby, adding new members to these subgroups. A combination of genomic background analysis and phylogenetic approaches of parvulin sequences suggested that the assigned sequences belong to at least two distinct groups of Thaumarchaeota. Finally, machine learning approaches were applied to identify amino acid residues that separate archaeal and bacterial parvulin proteins from each other. When mapped onto the recent PinA solution structure, most of these positions form a cluster at one site of the protein possibly indicating a different functionality of the two groups of parvulin proteins.
Evolutionary bioinformatics online 01/2011; 7:135-48. · 1.23 Impact Factor
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ABSTRACT: 3'-Phospho-adenosine-5'-phosphosulphate (PAPS) synthases are fundamental to mammalian sulphate metabolism. These enzymes have recently been linked to a rising number of human diseases. Despite many studies, it is not yet understood how the mammalian PAPS synthases 1 and 2 interact with each other. We provide first evidence for heterodimerisation of these two enzymes by pull-down assays and Förster resonance energy transfer (FRET) measurements. Kinetics of dimer dissociation/association indicates that these heterodimers form as soon as PAPSS1 and -S2 encounter each other in solution. Affinity of the homo- and heterodimers were found to be in the low nanomolar range using anisotropy measurements employing proteins labelled with the fluorescent dye IAEDANS that--in spite of its low quantum yield--is well suited for anisotropy due to its large Stokes shift. Within its kinase domain, the PAPS synthase heterodimer displays similar substrate inhibition by adenosine-5'-phosphosulphate (APS) as the homodimers. Due to divergent catalytic efficacies of PAPSS1 and -S2, the heterodimer might be a way of regulating PAPS synthase function within mammalian cells.
Biochemical and Biophysical Research Communications 04/2010; 395(3):420-5. · 2.48 Impact Factor
