The structure of serine palmitoyltransferase; gateway to sphingolipid biosynthesis

Sphingolipid biosynthesis commences with the condensation of L-serine and palmitoyl-CoA to produce 3-ketodihydrosphingosine (KDS). This reaction is catalysed by the PLP-dependent enzyme serine palmitoyltransferase (SPT; EC 2.3.1.50), which is a membrane-bound heterodimer (SPT1/SPT2) in eukaryotes such as humans and yeast and a cytoplasmic homodimer in the Gram-negative bacterium Sphingomonas paucimobilis. Unusually, the outer membrane of S. paucimobilis contains glycosphingolipid (GSL) instead of lipopolysaccharide (LPS), and SPT catalyses the first step of the GSL biosynthetic pathway in this organism. We report here the crystal structure of the holo-form of S. paucimobilis SPT at 1.3 A resolution. The enzyme is a symmetrical homodimer with two active sites and a monomeric tertiary structure consisting of three domains. The PLP cofactor is bound covalently to a lysine residue (Lys265) as an internal aldimine/Schiff base and the active site is composed of residues from both subunits, located at the bottom of a deep cleft. Models of the human SPT1/SPT2 heterodimer were generated from the bacterial structure by bioinformatics analysis. Mutations in the human SPT1-encoding subunit have been shown to cause a neuropathological disease known as hereditary sensory and autonomic neuropathy type I (HSAN1). Our models provide an understanding of how these mutations may affect the activity of the enzyme.     

Crystal Structure of Zebrafish Hatching Enzyme 1 from the Zebrafish Danio rerio

Fish hatching enzymes are zinc metalloproteases that digest the egg envelope (chorion) at the time of hatching. The crystal structure of zebrafish hatching enzyme 1 (ZHE1) has been solved at 1.10 Å resolution. ZHE1 is monomeric, is mitten shaped, and has a cleft at the center of the molecule. ZHE1 consists of three 3₁₀-helices, three α-helices, and two β-sheets. The central cleft represents the active site of the enzyme that is crucial for substrate recognition and catalysis. Alanine-scanning mutagenesis of the two substrate peptides has shown that AspP1′ contributes the most and that the residues at P4-P2′ also contribute to the recognition of the major substrate peptide by ZHE1, whereas GluP3′ and the hydrophobic residues at P4-P2, P2′, and P5′ contribute significantly to the recognition of the minor substrate peptide by ZHE1. Molecular models of these two substrate peptides bound to ZHE1 have been built based on the crystal structure of a transition-state analog inhibitor bound to astacin. In substrate-recognition models, the AspP1′ in the major substrate peptide forms a salt bridge with Arg182 of ZHE1, while the GluP3′ in the minor substrate peptide instead forms a salt bridge with Arg182. Thus, these two substrate peptides would be differently recognized by ZHE1. The shapes and electrostatic potentials of the substrate-binding clefts of ZHE1 and the structurally similar proteins astacin and bone morphogenetic protein 1 are significantly dissimilar due to different side chains, which would confer their distinctive substrate preferences.     

Insights into Cleavage Specificity from the Crystal Structure of Foot-and-Mouth Disease Virus 3C Protease Complexed with a Peptide Substrate

Picornavirus replication is critically dependent on the correct processing of a polyprotein precursor by 3C protease(s) (3C^pro) at multiple specific sites with related but non-identical sequences. To investigate the structural basis of its cleavage specificity, we performed the first crystallographic structural analysis of non-covalent complexes of a picornavirus 3C^pro with peptide substrates. The X-ray crystal structure of the foot-and-mouth disease virus 3C^pro, mutated to replace the catalytic Cys by Ala and bound to a peptide (APAKQ|LLNFD) corresponding to the P5-P5′ region of the VP1-2A cleavage junction in the viral polyprotein, was determined up to 2.5 Å resolution. Comparison with free enzyme reveals significant conformational changes in 3C^pro on substrate binding that lead to the formation of an extended interface of contact primarily involving the P4-P2′ positions of the peptide. Strikingly, the deep S1′ specificity pocket needed to accommodate P1′-Leu only forms when the peptide binds. Substrate specificity was investigated using peptide cleavage assays to show the impact of amino acid substitutions within the P5-P4′ region of synthetic substrates. The structure of the enzyme-peptide complex explains the marked substrate preferences for particular P4, P2 and P1 residue types, as well as the relative promiscuity at P3 and on the P′ side of the scissile bond. Furthermore, crystallographic analysis of the complex with a modified VP1-2A peptide (APAKE|LLNFD) containing a Gln-to-Glu substitution reveals an identical mode of peptide binding and explains the ability of foot-and-mouth disease virus 3C^pro to cleave sequences containing either P1-Gln or P1-Glu. Structure-based mutagenesis was used to probe interactions within the S1′ specificity pocket and to provide direct evidence of the important contribution made by Asp84 of the Cys-His-Asp catalytic triad to proteolytic activity. Our results provide a new level of detail in our understanding of the structural basis of polyprotein cleavage by 3C^pro.     

Atomic resolution crystal structure of VcLMWPTP-1 from Vibrio cholerae O395: Insights into a novel mode of dimerization in the low molecular weight protein tyrosine phosphatase family

Low molecular weight protein tyrosine phosphatase (LMWPTP) is a group of phosphotyrosine phosphatase ubiquitously found in a wide range of organisms ranging from bacteria to mammals. Dimerization in the LMWPTP family has been reported earlier which follows a common mechanism involving active site residues leading to an enzymatically inactive species. Here we report a novel form of dimerization in a LMWPTP from Vibrio cholera 0395 (VcLMWPTP-1). Studies in solution reveal the existence of the dimer in solution while kinetic study depicts the active form of the enzyme. This indicates that the mode of dimerization in VcLMWPTP-1 is different from others where active site residues are not involved in the process. A high resolution (1.45 Å) crystal structure of VcLMWPTP-1 confirms a different mode of dimerization where the active site is catalytically accessible as evident by a tightly bound substrate mimicking ligand, MOPS at the active site pocket. Although being a member of a prokaryotic protein family, VcLMWPTP-1 structure resembles very closely to LMWPTP from a eukaryote, Entamoeba histolytica. It also delineates the diverse surface properties around the active site of the enzyme.