An Evolutionary Marker of the Ribokinase Superfamily Is Responsible for Zinc-Mediated Regulation of Human Pyridoxal Kinase

The ribokinase superfamily catalyzes the phosphorylation of a vast diversity of substrates, and its members are characterized by the conservation of a common structural fold along with highly conserved sequence motifs responsible for phosphoryl transfer (GXGD) and stabilization of the metal-nucleotide complex (NXXE). Recently, a third motif (HXE) exclusive from ADP-dependent enzymes was identified, with its glutamic acid participating in water-mediated interactions with the metal-nucleotide complex and in stabilization of the ternary complex during catalysis. In this work, we bioinformatically determine that the aspartic acid of another motif (DPV), exclusively found in hydroxyethyl thiazole (THZK), hydroxymethyl pyrimidine (HMPK) and pyridoxal kinases (PLK), is structurally equivalent to the acidic residue in the HXE motif. Moreover, this residue is highly conserved among all ribokinase superfamily members. To determine whether the functional role of the DPV motif is similar to the HXE motif, we employed molecular dynamics simulations using crystal structures of phosphoryl donor substrate-complexed THZK and PLK, showing that its aspartic acid participated in water-mediated or direct interactions with the divalent metal of the metal-nucleotide complex. Lastly, enzyme kinetic assays on human PLK, an enzyme that utilizes zinc, showed that site-directed mutagenesis of the aspartic acid from the DPV motif abolishes the inhibition of this enzyme by increasing free zinc concentrations. Altogether, our results highlight that the DPV and HXE motifs are evolutionary markers of the functional and structural divergence of the ribokinase superfamily and evidence the role of the DPV motif in the interaction with both free and nucleotide-complexed divalent metals in the binding site of these enzymes.

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The structure of the genomicBacillus subtilisdUTPase: novel features in the Phe-lid

Acta Crystallographica Section D Biological Crystallography ◽

10.1107/s0907444910026272 ◽

2010 ◽

Vol 66 (9) ◽

pp. 953-961 ◽

Cited By ~ 7

Author(s):

Javier García-Nafría ◽

Lynn Burchell ◽

Mine Takezawa ◽

Neil J. Rzechorzek ◽

Mark J. Fogg ◽

...

Keyword(s):

Active Site ◽

Sequence Motifs ◽

Conserved Sequence ◽

General Base ◽

Base Points ◽

Phosphate Chain ◽

C Terminus ◽

Conserved Sequence Motifs ◽

Key Residues

dUTPases are a ubiquitous family of enzymes that are essential for all organisms and catalyse the breakdown of 2-deoxyuridine triphosphate (dUTP). InBacillus subtilisthere are two homotrimeric dUTPases: a genomic and a prophage form. Here, the structures of the genomic dUTPase and of its complex with the substrate analogue dUpNHpp and calcium are described, both at 1.85 Å resolution. The overall fold resembles that of previously solved trimeric dUTPases. The C-terminus, which contains one of the conserved sequence motifs, is disordered in both structures. The crystal of the complex contains six independent protomers which accommodate six dUpNHpp molecules, with three triphosphates in thetransconformation and the other three in the activegaucheconformation. The structure of the complex confirms the role of several key residues that are involved in ligand binding and the position of the catalytic water. Asp82, which has previously been proposed to act as a general base, points away from the active site. In the complex Ser64 reorients in order to hydrogen bond the phosphate chain of the substrate. A novel feature has been identified: the position in the sequence of the `Phe-lid', which packs against the uracil moiety, is adjacent to motif III, whereas in all other dUTPase structures the lid is in a conserved position in motif V of the flexible C-terminal arm. This requires a reconsideration of some aspects of the accepted mechanism.

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Conserved sequence motifs among bacterial, eukaryotic, and archaeal phosphatases that define a new phosphohydrolase superfamily

Protein Science ◽

10.1002/pro.5560070722 ◽

1998 ◽

Vol 7 (7) ◽

pp. 1647-1652 ◽

Cited By ~ 96

Author(s):

Maria Cristina Thaller ◽

Serena Schippa ◽

Gian Maria Rossolini

Keyword(s):

Sequence Motifs ◽

Conserved Sequence ◽

Conserved Sequence Motifs

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Identification and Analysis of Novel Amino-Acid Sequence Repeats inBacillus anthracisstr.AmesProteome Using Computational Tools

Comparative and Functional Genomics ◽

10.1155/2007/47161 ◽

2007 ◽

Vol 2007 ◽

pp. 1-23 ◽

Cited By ~ 2

Author(s):

G. R. Hemalatha ◽

D. Satyanarayana Rao ◽

L. Guruprasad

Keyword(s):

Amino Acid ◽

Amino Acid Residue ◽

Protein Sequence ◽

Amino Acid Residues ◽

Sequence Motifs ◽

Computational Tools ◽

Conserved Sequence ◽

Conserved Sequence Motifs ◽

Multiple Copies ◽

Domain 3

We have identified four repeats and ten domains that are novel in proteins encoded by theBacillus anthracisstr.Amesproteome using automated in silico methods. A “repeat” corresponds to a region comprising less than 55-amino-acid residues that occur more than once in the protein sequence and sometimes present in tandem. A “domain” corresponds to a conserved region with greater than 55-amino-acid residues and may be present as single or multiple copies in the protein sequence. These correspond to (1) 57-amino-acid-residue PxV domain, (2) 122-amino-acid-residue FxF domain, (3) 111-amino-acid-residue YEFF domain, (4) 109-amino-acid-residue IMxxH domain, (5) 103-amino-acid-residue VxxT domain, (6) 84-amino-acid-residue ExW domain, (7) 104-amino-acid-residue NTGFIG domain, (8) 36-amino-acid-residue NxGK repeat, (9) 95-amino-acid-residue VYV domain, (10) 75-amino-acid-residue KEWE domain, (11) 59-amino-acid-residue AFL domain, (12) 53-amino-acid-residue RIDVK repeat, (13) (a) 41-amino-acid-residue AGQF repeat and (b) 42-amino-acid-residue GSAL repeat. A repeat or domain type is characterized by specific conserved sequence motifs. We discuss the presence of these repeats and domains in proteins from other genomes and their probable secondary structure.

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Conserved sequence motifs, alignment, and secondary structure for the third domain of animal 12S rRNA

Molecular Biology and Evolution ◽

10.1093/oxfordjournals.molbev.a025552 ◽

1996 ◽

Vol 13 (1) ◽

pp. 150-169 ◽

Cited By ~ 181

Author(s):

R. E. Hickson ◽

C. Simon ◽

A. Cooper ◽

G. S. Spicer ◽

J. Sullivan ◽

...

Keyword(s):

Secondary Structure ◽

12S Rrna ◽

Sequence Motifs ◽

Conserved Sequence ◽

The Third ◽

Conserved Sequence Motifs

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SAND, a New Protein Family: From Nucleic Acid to Protein Structure and Function Prediction

Comparative and Functional Genomics ◽

10.1002/cfg.93 ◽

2001 ◽

Vol 2 (4) ◽

pp. 226-235 ◽

Cited By ~ 5

Author(s):

Amanda Cottage ◽

Yvonne J. K. Edwards ◽

Greg Elgar

Keyword(s):

Genomic Sequence ◽

Protein Family ◽

Sequence Motifs ◽

Est Database ◽

Computational Tools ◽

Conserved Sequence ◽

Conserved Sequence Motifs ◽

And Function ◽

New Protein ◽

Genomic Organisation

As a result of genome, EST and cDNA sequencing projects, there are huge numbers of predicted and/or partially characterised protein sequences compared with a relatively small number of proteins with experimentally determined function and structure. Thus, there is a considerable attention focused on the accurate prediction of gene function and structure from sequence by using bioinformatics. In the course of our analysis of genomic sequence fromFugu rubripes, we identified a novel gene,SAND, with significant sequence identity to hypothetical proteins predicted inSaccharomyces cerevisiae, Schizosaccharomyces pombe, Caenorhabditis elegans, aDrosophila melanogastergene, and mouse and human cDNAs. Here we identify a furtherSANDhomologue in human andArabidopsis thalianaby use of standard computational tools. We describe the genomic organisation ofSANDin these evolutionarily divergent species and identify sequence homologues from EST database searches confirming the expression of SAND in over 20 different eukaryotes. We confirm the expression of two different SAND paralogues in mammals and determine expression of one SAND in other vertebrates and eukaryotes. Furthermore, we predict structural properties of SAND, and characterise conserved sequence motifs in this protein family.

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