Your search keyword '"Rawlings, Neil"' showing total 12 results

1. LUD, a new protein domain associated with lactate utilization

Author

Hwang, William C, Bakolitsa, Constantina, Punta, Marco, Coggill, Penelope C, Bateman, Alex, Axelrod, Herbert L, Rawlings, Neil D, Sedova, Mayya, Peterson, Scott N, Eberhardt, Ruth Y, Aravind, L, Pascual, Jaime, and Godzik, Adam

Subjects

Underpinning research, 1.1 Normal biological development and functioning, Generic health relevance, Amino Acid Sequence, Bacterial Proteins, Crystallography, X-Ray, Deinococcus, Humans, Lactic Acid, Microbiota, Molecular Sequence Data, Protein Structure, Tertiary, LUD, DUF162, LutB, LutC, Domain of unknown function, Deinococcus radiodurans, Mathematical Sciences, Biological Sciences, Information and Computing Sciences, Bioinformatics

Abstract

BackgroundA novel highly conserved protein domain, DUF162 [Pfam: PF02589], can be mapped to two proteins: LutB and LutC. Both proteins are encoded by a highly conserved LutABC operon, which has been implicated in lactate utilization in bacteria. Based on our analysis of its sequence, structure, and recent experimental evidence reported by other groups, we hereby redefine DUF162 as the LUD domain family.ResultsJCSG solved the first crystal structure [PDB:2G40] from the LUD domain family: LutC protein, encoded by ORF DR_1909, of Deinococcus radiodurans. LutC shares features with domains in the functionally diverse ISOCOT superfamily. We have observed that the LUD domain has an increased abundance in the human gut microbiome.ConclusionsWe propose a model for the substrate and cofactor binding and regulation in LUD domain. The significance of LUD-containing proteins in the human gut microbiome, and the implication of lactate metabolism in the radiation-resistance of Deinococcus radiodurans are discussed.

Published

2013

2. Structural and sequence analysis of imelysin-like proteins implicated in bacterial iron uptake.

Author

Xu, Qingping, Rawlings, Neil D, Farr, Carol L, Chiu, Hsiu-Ju, Grant, Joanna C, Jaroszewski, Lukasz, Klock, Heath E, Knuth, Mark W, Miller, Mitchell D, Weekes, Dana, Elsliger, Marc-André, Deacon, Ashley M, Godzik, Adam, Lesley, Scott A, and Wilson, Ian A

Subjects

Bacteroides, Psychrobacter, Iron, Bacterial Proteins, Sequence Analysis, Protein, Amino Acid Sequence, Amino Acid Motifs, Conserved Sequence, Protein Structure, Tertiary, Structure-Activity Relationship, Biological Transport, Models, Molecular, Molecular Sequence Data, Models, Molecular, Protein Structure, Tertiary, Sequence Analysis, Protein, General Science & Technology

Abstract

Imelysin-like proteins define a superfamily of bacterial proteins that are likely involved in iron uptake. Members of this superfamily were previously thought to be peptidases and were included in the MEROPS family M75. We determined the first crystal structures of two remotely related, imelysin-like proteins. The Psychrobacter arcticus structure was determined at 2.15 Å resolution and contains the canonical imelysin fold, while higher resolution structures from the gut bacteria Bacteroides ovatus, in two crystal forms (at 1.25 Å and 1.44 Å resolution), have a circularly permuted topology. Both structures are highly similar to each other despite low sequence similarity and circular permutation. The all-helical structure can be divided into two similar four-helix bundle domains. The overall structure and the GxHxxE motif region differ from known HxxE metallopeptidases, suggesting that imelysin-like proteins are not peptidases. A putative functional site is located at the domain interface. We have now organized the known homologous proteins into a superfamily, which can be separated into four families. These families share a similar functional site, but each has family-specific structural and sequence features. These results indicate that imelysin-like proteins have evolved from a common ancestor, and likely have a conserved function.

Published

2011

3. Structural analysis of papain-like NlpC/P60 superfamily enzymes with a circularly permuted topology reveals potential lipid binding sites.

Author

Xu, Qingping, Rawlings, Neil D, Chiu, Hsiu-Ju, Jaroszewski, Lukasz, Klock, Heath E, Knuth, Mark W, Miller, Mitchell D, Elsliger, Marc-Andre, Deacon, Ashley M, Godzik, Adam, Lesley, Scott A, and Wilson, Ian A

Subjects

Humans, Bacillus cereus, Papain, Fatty Acids, Lipoproteins, Bacterial Proteins, Ligands, Binding Sites, Amino Acid Sequence, Catalytic Domain, Conserved Sequence, Models, Molecular, Molecular Sequence Data, Lipid Metabolism, Biocatalysis, Hydrophobic and Hydrophilic Interactions, Models, Molecular, General Science & Technology

Abstract

NlpC/P60 superfamily papain-like enzymes play important roles in all kingdoms of life. Two members of this superfamily, LRAT-like and YaeF/YiiX-like families, were predicted to contain a catalytic domain that is circularly permuted such that the catalytic cysteine is located near the C-terminus, instead of at the N-terminus. These permuted enzymes are widespread in virus, pathogenic bacteria, and eukaryotes. We determined the crystal structure of a member of the YaeF/YiiX-like family from Bacillus cereus in complex with lysine. The structure, which adopts a ligand-induced, "closed" conformation, confirms the circular permutation of catalytic residues. A comparative analysis of other related protein structures within the NlpC/P60 superfamily is presented. Permutated NlpC/P60 enzymes contain a similar conserved core and arrangement of catalytic residues, including a Cys/His-containing triad and an additional conserved tyrosine. More surprisingly, permuted enzymes have a hydrophobic S1 binding pocket that is distinct from previously characterized enzymes in the family, indicative of novel substrate specificity. Further analysis of a structural homolog, YiiX (PDB 2if6) identified a fatty acid in the conserved hydrophobic pocket, thus providing additional insights into possible function of these novel enzymes.

Published

2011

4. Evolution of proteins of the cystatin superfamily

Author

Rawlings, Neil D. and Barrett, Alan J.

Published

1990

5. iProt-Sub: a comprehensive package for accurately mapping and predicting protease-specific substrates and cleavage sites.

Author

Song, Jiangning, Wang, Yanan, Li, Fuyi, Akutsu, Tatsuya, Rawlings, Neil D, Webb, Geoffrey I, and Chou, Kuo-Chen

Subjects

AMINO acid sequence, PROTEOLYTIC enzymes, PREDICTION models, FORECASTING, FEATURE selection

Abstract

Regulation of proteolysis plays a critical role in a myriad of important cellular processes. The key to better understanding the mechanisms that control this process is to identify the specific substrates that each protease targets. To address this, we have developed iProt-Sub, a powerful bioinformatics tool for the accurate prediction of protease-specific substrates and their cleavage sites. Importantly, iProt-Sub represents a significantly advanced version of its successful predecessor, PROSPER. It provides optimized cleavage site prediction models with better prediction performance and coverage for more species-specific proteases (4 major protease families and 38 different proteases). iProt-Sub integrates heterogeneous sequence and structural features and uses a two-step feature selection procedure to further remove redundant and irrelevant features in an effort to improve the cleavage site prediction accuracy. Features used by iProt-Sub are encoded by 11 different sequence encoding schemes, including local amino acid sequence profile, secondary structure, solvent accessibility and native disorder, which will allow a more accurate representation of the protease specificity of approximately 38 proteases and training of the prediction models. Benchmarking experiments using cross-validation and independent tests showed that iProt-Sub is able to achieve a better performance than several existing generic tools. We anticipate that iProt-Sub will be a powerful tool for proteome-wide prediction of protease-specific substrates and their cleavage sites, and will facilitate hypothesis-driven functional interrogation of protease-specific substrate cleavage and proteolytic events. [ABSTRACT FROM AUTHOR]

Published

2019

6. [32] Families of cysteine peptidases

Author

Rawlings, Neil D. and Barrett, Alan J.

Subjects

Cysteine Endopeptidases, Sequence Homology, Amino Acid, Molecular Sequence Data, Amino Acid Sequence, Article

Abstract

Publisher Summary This chapter presents families of cysteine peptidases. The activity of all cysteine peptidases depends on a catalytic dyad of cysteine and histidine. The order of the cysteine and histidine residues (Cys/His or His/Cys) in the linear sequence differs between families and this is among the lines of evidence suggesting that cysteine peptidases have had many separate evolutionary origins. The families C1, C2, and C10 can be described as “papainlike,” and form clan CA. The papain family contains peptidases with a wide variety of activities, including endopeptidases with broad specificity, endopeptidases with narrow specificity, aminopeptidases, and peptidases with both endopeptidase and exopeptidase activities. Papain homologs are generally either lysosomal or secreted proteins. The calpain family includes the calcium-dependent cytosolic endopeptidase calpain, which is known from birds and mammals, and the product of the sol gene in Drosophila. Calpain is a complex of two peptide chains. Picornains are a family of polyprotein-processing endopeptidases from single-stranded RNA viruses. Each picornavirus has two picornains (2A and 3C).

Published

2004

7. [2] Families of serine peptidases

Author

Rawlings, Neil D. and Barrett, Alan J.

Subjects

Molecular Sequence Data, Serine Endopeptidases, Chymotrypsin, Amino Acid Sequence, Carboxypeptidases, Subtilisins, Article

Abstract

Publisher Summary This chapter examines families of serine peptidases. Serine peptidases are found in viruses, bacteria, and eukaryotes. They include exopeptidases, endopeptidases, oligopeptidases, and omega peptidases. On the basis of three-dimensional structures, most of the serine peptidase families can be grouped together into about six clans that may have common ancestors. The structures are known for members of four of the clans, chymotrypsin, subtilisin, carboxypeptidase C, and Escherichia D-Ala-D-Ala peptidase A. The peptidases of chymotrypsin, subtilisin, and carboxypeptidase C clans have a common “catalytic triad” of three amino acids—namely, serine (nucleophile), aspartate (electrophile), and histidine (base). The geometric orientations of these are closely similar between families; however the protein folds are quite different. The arrangements of the catalytic residues in the linear sequences of members of the various families commonly reflect their relationships at the clan level. The members of the chymotrypsin family are almost entirely confined to animals. 10 families are included in chymotrypsin clan (SA), and all the active members of these families are endopeptidases. The order of catalytic residues in the polypeptide chain in clan SA is His/Asp/Ser.

Published

2004

8. Peptidase specificity from the substrate cleavage collection in the MEROPS database and a tool to measure cleavage site conservation.

Author

Rawlings, Neil D.

Subjects

*PEPTIDASE, *IMMUNOSPECIFICITY, *BIOCHEMICAL substrates, *PROTEIN structure, *AMINO acid sequence

Abstract

One peptidase can usually be distinguished from another biochemically by its action on proteins, peptides and synthetic substrates. Since 1996, the MEROPS database ( http://merops.sanger.ac.uk ) has accumulated a collection of cleavages in substrates that now amounts to 66,615 cleavages. The total number of peptidases for which at least one cleavage is known is 1700 out of a total of 2457 different peptidases. This paper describes how the cleavages are obtained from the scientific literature, how they are annotated and how cleavages in peptides and proteins are cross-referenced to entries in the UniProt protein sequence database. The specificity profiles of 556 peptidases are shown for which ten or more substrate cleavages are known. However, it has been proposed that at least 40 cleavages in disparate proteins are required for specificity analysis to be meaningful, and only 163 peptidases (6.6%) fulfil this criterion. Also described are the various displays shown on the website to aid with the understanding of peptidase specificity, which are derived from the substrate cleavage collection. These displays include a logo, distribution matrix, and tables to summarize which amino acids or groups of amino acids are acceptable (or not acceptable) in each substrate binding pocket. For each protein substrate, there is a display to show how it is processed and degraded. Also described are tools on the website to help with the assessment of the physiological relevance of cleavages in a substrate. These tools rely on the hypothesis that a cleavage site that is conserved in orthologues is likely to be physiologically relevant, and alignments of substrate protein sequences are made utilizing the UniRef50 database, in which in each entry sequences are 50% or more identical. Conservation in this case means substitutions are permitted only if the amino acid is known to occupy the same substrate binding pocket from at least one other substrate cleaved by the same peptidase. [ABSTRACT FROM AUTHOR]

Published

2016

9. Structure and computational analysis of a novel protein with metallopeptidase-like and circularly permuted winged-helix-turn-helix domains reveals a possible role in modified polysaccharide biosynthesis.

Author

Das, Debanu, Murzin, Alexey G., Rawlings, Neil D., Finn, Robert D., Coggill, Penelope, Bateman, Alex, Godzik, Adam, and Aravind, L.

Subjects

BIOCHEMISTRY, CLOSTRIDIUM, AMINO acid sequence, PROTEOLYTIC enzymes, BIOINFORMATICS

Abstract

Background CA_C2195 from Clostridium acetobutylicum is a protein of unknown function. Sequence analysis predicted that part of the protein contained a metallopeptidase-related domain. There are over 200 homologs of similar size in large sequence databases such as UniProt, with pairwise sequence identities in the range of ~40-60%. CA_C2195 was chosen for crystal structure determination for structure-based function annotation of novel protein sequence space. Results The structure confirmed that CA_C2195 contained an N-terminal metallopeptidase-like domain. The structure revealed two extra domains: an α+β domain inserted in the metallopeptidase-like domain and a C-terminal circularly permuted winged-helix-turn-helix domain. Conclusions Based on our sequence and structural analyses using the crystal structure of CA_C2195 we provide a view into the possible functions of the protein. From contextual information from gene-neighborhood analysis, we propose that rather than being a peptidase, CA_C2195 and its homologs might play a role in biosynthesis of a modified cell-surface carbohydrate in conjunction with several sugar-modification enzymes. These results provide the groundwork for the experimental verification of the function. [ABSTRACT FROM AUTHOR]

Published

2014

10. Structural and Sequence Analysis of Imelysin-Like Proteins Implicated in Bacterial Iron Uptake.

Author

Qingping Xu, Rawlings, Neil D., Farr, Carol L., Hsiu-Ju Chiu, Grant, Joanna C., Jaroszewski, Lukasz, Klock, Heath E., Knuth, Mark W., Miller, Mitchell D., Weekes, Dana, Elsliger, Marc-André, Deacon, Ashley M., Godzik, Adam, Lesley, Scott A., and Wilson, Ian A.

Subjects

*PROTEIN structure, *AMINO acid sequence, *BACTERIAL proteins, *IRON content of bacteria, *PEPTIDASE, *CRYSTAL structure, *TOPOLOGY

Abstract

Imelysin-like proteins define a superfamily of bacterial proteins that are likely involved in iron uptake. Members of this superfamily were previously thought to be peptidases and were included in the MEROPS family M75. We determined the first crystal structures of two remotely related, imelysin-like proteins. The Psychrobacter arcticus structure was determined at 2.15 Å resolution and contains the canonical imelysin fold, while higher resolution structures from the gut bacteria Bacteroides ovatus, in two crystal forms (at 1.25 Å and 1.44 Å resolution), have a circularly permuted topology. Both structures are highly similar to each other despite low sequence similarity and circular permutation. The all-helical structure can be divided into two similar four-helix bundle domains. The overall structure and the GxHxxE motif region differ from known HxxE metallopeptidases, suggesting that imelysin-like proteins are not peptidases. A putative functional site is located at the domain interface. We have now organized the known homologous proteins into a superfamily, which can be separated into four families. These families share a similar functional site, but each has family-specific structural and sequence features. These results indicate that imelysin-like proteins have evolved from a common ancestor, and likely have a conserved function. [ABSTRACT FROM AUTHOR]

Published

2011

11. Peptidase inhibitors in the MEROPS database

Author

Rawlings, Neil D.

Subjects

*PEPTIDASE, *PROTEASE inhibitors, *AMINO acid sequence, *PROTEIN structure, *PHARMACEUTICAL industry, *BINDING sites

Abstract

Abstract: The MEROPS website (http://merops.sanger.ac.uk) includes information on peptidase inhibitors as well as on peptidases and their substrates. Displays have been put in place to link peptidases and inhibitors together. The classification of protein peptidase inhibitors is continually being revised, and currently inhibitors are grouped into 67 families based on comparisons of protein sequences. These families can be further grouped into 38 clans based on comparisons of tertiary structure. Small molecule inhibitors are important reagents for peptidase characterization and, with the increasing importance of peptidases as drug targets, they are also important to the pharmaceutical industry. Small molecule inhibitors are now included in MEROPS and over 160 summaries have been written. [ABSTRACT FROM AUTHOR]

Published

2010

12. Twenty-five years of nomenclature and classification of proteolytic enzymes.

Author

Rawlings, Neil D.

Subjects

*PROTEOLYTIC enzymes, *BINDING sites, *TERTIARY structure, *PEPTIDASE, *AMINO acid sequence, *CLASSIFICATION

Abstract

Proteolytic enzymes and their homologues have been classified into clans by comparing the tertiary structures of the peptidase domains, into families by comparing the protein sequences of the peptidase domains, and into protein-species by comparing various attributes including domain architecture, substrate preference, inhibitor interactions, subcellular location, and phylogeny. The results are compared with the earlier classification (Rawlings and Barrett, 1993 [1]). The numbers of sequences, protein-species, families, clans and even catalytic type have substantially increased during the intervening 26 years. The alternative classifications by catalytic type and/or activity are shown not to reflect evolutionary relationships. • Proteolytic enzymes are classified by tertiary structure similarity into clans and by sequence similarity into families. • Criteria have been devised to differentiate paralogous enzymes within a family, and a unique identifier assigned. • There has been a significant increase in clans, families, different enzymes and active site mechanisms since 1993. [ABSTRACT FROM AUTHOR]

Published

2020