Evolutionary conservation of protein dynamics: insights from all-atom molecular dynamics simulations of 'peptidase' domain of Spt16.

Protein function is encoded in its sequence, manifested in its three-dimensional structure, and facilitated by its dynamics. Studies have suggested that protein structures with higher sequence similarity could have more similar patterns of dynamics. However, such studies of protein dynamics within and across protein families typically rely on coarse-grained models, or approximate metrics like crystallographic B-factors.

Machine learning classifiers aid virtual screening for efficient design of mini-protein therapeutics.

De novo design of mini-proteins (4-12 kDa) has recently been shown to produce new candidates for protein therapeutics. They are temperature stable molecules that bind to the drug target with high affinity for inhibiting its interactions. The development of mini-protein binders requires laboratory screening of tens of thousands of molecules for effective target binding.

Crystal structure of XCC3289 from Xanthomonas campestris: homology with the N-terminal substrate-binding domain of Lon peptidase.

LonA peptidase is a major component of the protein quality-control mechanism in both prokaryotes and the organelles of eukaryotes. Proteins homologous to the N-terminal domain of LonA peptidase, but lacking its other domains, are conserved in several phyla of prokaryotes, including the Xanthomonadales order. However, the function of these homologous proteins (LonNTD-like proteins) is not known.

Structural basis for the unusual substrate specificity of unique two-domain M1 metallopeptidase.

M1 metallopeptidases regulate many important biological processes such as angiogenesis, tumour growth, hormone regulation, and immune cell development. Knowledge of substrate specificity mechanism in this family is valuable. An M1 peptidase from Deinococcus radiodurans (M1dr) with preference for bulky hydrophobic residues at N-terminus of peptide substrates was recently reported.

Phylogenetic spread of sequence data affects fitness of consensus enzymes: Insights from triosephosphate isomerase.

The concept of consensus in multiple sequence alignments (MSAs) has been used to design and engineer proteins previously with some success. However, consensus design implicitly assumes that all amino acid positions function independently, whereas in reality, the amino acids in a protein interact with each other and work cooperatively to produce the optimum structure required for its function. Correlation analysis is a tool that can capture the effect of such interactions.

Two-domain aminopeptidase of M1 family: Structural features for substrate binding and gating in absence of C-terminal domain.

Zinc metallopeptidases of the M1 family (M1 peptidases) with unique metal binding motif HEXXH(X)E regulate many important biological processes such as tumor growth, angiogenesis, hormone regulation, and immune cell development. Typically, these enzymes exist in three-domain [N-terminal domain (N-domain), catalytic domain, and C-terminal domain (C-domain)] or four-domain (N-domain, catalytic domain, middle domain, and C-domain) format in which N-domain and catalytic domain are more conserved. The C-domain plays important roles in substrate binding and gating.

Catalytic triad heterogeneity in S51 peptidase family: Structural basis for functional variability.

Peptidase E (PepE) is a nonclassical serine peptidase with a Ser-His-Glu catalytic triad. It is specific for dipeptides with an N-terminal aspartate residue (Asp-X dipeptidase activity). Its homolog from Listeria monocytogenes (PepElm) has a Ser-His-Asn "catalytic triad.

Crystal structures and biochemical analyses of intermediate cleavage peptidase: role of dynamics in enzymatic function.

Intermediate cleavage peptidase (Icp55) processes a subset of mitochondrial matrix proteins by removing a bulky residue at their N termini, leaving behind smaller N-terminal residues (icp activity). This contributes towards the stability of the mitochondrial proteome. We report crystal structures of yeast Icp55 including one bound to the apstatin inhibitor.

Structures and activities of widely conserved small prokaryotic aminopeptidases-P clarify classification of M24B peptidases.

M24B peptidases cleaving Xaa-Pro bond in dipeptides are prolidases whereas those cleaving this bond in longer peptides are aminopeptidases-P. Bacteria have small aminopeptidases-P (36-39 kDa), which are diverged from canonical aminopeptidase-P of Escherichia coli (50 kDa). Structure-function studies of small aminopeptidases-P are lacking.

Carboxypeptidase in prolyl oligopeptidase family: Unique enzyme activation and substrate-screening mechanisms.

Serine peptidases of the prolyl oligopeptidase (POP) family are of substantial therapeutic importance because of their involvement in diseases such as diabetes, cancer, neurological diseases, and autoimmune disorders. Proper annotation and knowledge of substrate specificity mechanisms in this family are highly valuable. Although endopeptidase, dipeptidyl peptidase, tripeptidyl peptidase, and acylaminoacyl peptidase activities have been reported previously, here we report the first instance of carboxypeptidase activity in a POP family member.

Structure of Asp-bound peptidase E from Salmonella enterica: Active site at dimer interface illuminates Asp recognition.

Peptidase-E, a nonclassical serine peptidase, is specific for dipeptides with an N-terminal aspartate. This stringent substrate specificity remains largely unexplained. We report an aspartate-bound structure of peptidase-E at 1.

Phylogenetic spread of sequence data affects fitness of SOD1 consensus enzymes: Insights from sequence statistics and structural analyses.

Non-natural protein sequences with native-like structures and functions can be constructed successfully using consensus design. This design strategy is relatively well understood in repeat proteins with simple binding function, however detailed studies are lacking in globular enzymes. The SOD1 family is a good model for such studies due to the availability of large amount of sequence and structure data motivated by involvement of human SOD1 in the fatal motor neuron disease amyotrophic lateral sclerosis (ALS).

Crystal structure of a novel prolidase from Deinococcus radiodurans identifies new subfamily of bacterial prolidases.

Xaa-Pro peptidases (XPP) are dinuclear peptidases of MEROPS M24B family that hydrolyze Xaa-Pro iminopeptide bond with a trans-proline at the second position of the peptide substrate. XPPs specific towards dipeptides are called prolidases while those that prefer longer oligopeptides are called aminopeptidases P. Though XPPs are strictly conserved in bacterial and archaeal species, the structural and sequence features that distinguish between prolidases and aminopeptidases P are not always clear.

Active site gate of M32 carboxypeptidases illuminated by crystal structure and molecular dynamics simulations.

Enzyme gates are important dynamic features that regulate function. Study of these features is critical for understanding of enzyme mechanism. In this study, the active-site gate of M32 carboxypeptidases (M32CP) is illuminated.

Structure of the human aminopeptidase XPNPEP3 and comparison of its activity with Icp55 orthologs: Insights into diverse cellular processes.

The human aminopeptidase XPNPEP3 is associated with cystic kidney disease and TNF-TNFR2 cellular signaling. Its yeast and plant homolog Icp55 processes several imported mitochondrial matrix proteins leading to their stabilization. However, the molecular basis for the diverse roles of these enzymes in the cell is unknown.

Gating role of His 72 in TmPurL enzyme uncovered by structural analyses and molecular dynamics simulations.

Histidine is ubiquitous in enzyme active sites but its role is often difficult to ascribe due to ambiguity of protonation state and complex electrostatic and dynamic effects involved. In this study the role of His 72 in TmPurL, a glutamine amidotransferase (GAT) enzyme, is investigated. TmPurL is a large 66kDa enzyme that works as part of an even larger (>100kDa) multi-protein complex.

Crystal structure and biochemical investigations reveal novel mode of substrate selectivity and illuminate substrate inhibition and allostericity in a subfamily of Xaa-Pro dipeptidases.

Xaa-Pro dipeptidase (XPD) catalyzes hydrolysis of iminopeptide bond in dipeptides containing trans-proline as a second residue. XPDs are found in all living organisms and are believed to play an essential role in proline metabolism. Here, we report crystal structures and extensive enzymatic studies of XPD from Xanthomonas campestris (XPDxc), the first such comprehensive study of a bacterial XPD.

Crystallization and preliminary X-ray crystallographic analysis of an artificial molten-globular-like triosephosphate isomerase protein of mixed phylogenetic origin.

A bioinformatics-based protein-engineering approach called consensus design led to the construction of a chimeric triosephosphate isomerase (TIM) protein called ccTIM (curated consensus TIM) which is as active as Saccharomyces cerevisiae TIM despite sharing only 58% sequence identity with it. The amino-acid sequence of this novel protein is as identical to native sequences from eukaryotes as to those from prokaryotes and shares some biophysical traits with a molten globular protein. Solving its crystal structure would help in understanding the physical implications of its bioinformatics-based sequence.

Importance of hydrophobic cavities in allosteric regulation of formylglycinamide synthetase: insight from xenon trapping and statistical coupling analysis.

Formylglycinamide ribonucleotide amidotransferase (FGAR-AT) is a 140 kDa bi-functional enzyme involved in a coupled reaction, where the glutaminase active site produces ammonia that is subsequently utilized to convert FGAR to its corresponding amidine in an ATP assisted fashion. The structure of FGAR-AT has been previously determined in an inactive state and the mechanism of activation remains largely unknown. In the current study, hydrophobic cavities were used as markers to identify regions involved in domain movements that facilitate catalytic coupling and subsequent activation of the enzyme.