Mark Paetzel

Crystal structure of a bacterial signal peptidase in complex with a beta-lactam inhibitor

The signal peptidase (SPase) from Escherichia coli is a membrane-bound endopeptidase with two amino-terminal transmembrane segments and a carboxy-terminal catalytic region which resides in the periplasmic space. SPase functions to release proteins that have been translocated into the inner membrane from the cell interior, by cleaving off their signal peptides. We report here the X-ray crystal structure of a catalytically active soluble fragment of E. coli SPase (SPase Δ2–75),. We have determined this structure at 1.9 Å resolution in a complex with an inhibitor, a β-lactam (5S,6S penem),, which is covalently bound as an acyl-enzyme intermediate to the γ-oxygen of a serine residue at position 90, demonstrating that this residue acts as the nucleophile in the hydrolytic mechanism of signal-peptide cleavage. The structure is consistent with the use by SPase of Lys 145 as a general base in the activation of the nucleophilic Ser 90, explains the specificity requirement at the signal-peptide cleavage site, and reveals a large exposed hydrophobic surface which could be a site for an intimate association with the membrane. As enzymes that are essential for cell viability, bacterial SPases present a feasible antibacterial target: our determination of the SPase structure therefore provides a template for the rational design of antibiotic compounds.

Unconventional serine proteases: Variations on the catalytic Ser/His/Asp triad configuration

Serine proteases comprise nearly one‐third of all known proteases identified to date and play crucial roles in a wide variety of cellular as well as extracellular functions, including the process of blood clotting, protein digestion, cell signaling, inflammation, and protein processing. Their hallmark is that they contain the so‐called “classical” catalytic Ser/His/Asp triad. Although the classical serine proteases are the most widespread in nature, there exist a variety of “nonclassical” serine proteases where variations to the catalytic triad are observed. Such variations include the triads Ser/His/Glu, Ser/His/His, and Ser/Glu/Asp, and include the dyads Ser/Lys and Ser/His. Other variations are seen with certain serine and threonine peptidases of the Ntn hydrolase superfamily that carry out catalysis with a single active site residue. This work discusses the structure and function of these novel serine proteases and threonine proteases and how their catalytic machinery differs from the prototypic serine protease class.

Novel Avian Influenza H7N3 Strain Outbreak, British Columbia

Genome sequences of chicken (low pathogenic avian influenza [LPAI] and highly pathogenic avian influenza [HPAI]) and human isolates from a 2004 outbreak of H7N3 avian influenza in Canada showed a novel insertion in the HA0 cleavage site of the human and HPAI isolate. This insertion likely occurred by recombination between the hemagglutination and matrix genes in the LPAI virus.

Crystal structure of LexA: a conformational switch for regulation of self-cleavage.

LexA repressor undergoes a self-cleavage reaction. In vivo, this reaction requires an activated form of RecA, but it occurs spontaneously in vitro at high pH. Accordingly, LexA must both allow self-cleavage and yet prevent this reaction in the absence of a stimulus. We have solved the crystal structures of several mutant forms of LexA. Strikingly, two distinct conformations are observed, one compatible with cleavage, and the other in which the cleavage site is approximately 20 A from the catalytic center. Our analysis provides insight into the structural and energetic features that modulate the interconversion between these two forms and hence the rate of the self-cleavage reaction. We suggest RecA activates the self-cleavage of LexA and related proteins through selective stabilization of the cleavable conformation.

The structure and mechanism of bacterial type I signal peptidases. A novel antibiotic target.

Type I signal peptidases are essential membrane-bound serine proteases that function to cleave the amino-terminal signal peptide extension from proteins that are translocated across biological membranes. The bacterial signal peptidases are unique serine proteases that utilize a Ser/Lys catalytic dyad mechanism in place of the classical Ser/His/Asp catalytic triad mechanism. They represent a potential novel antibiotic target at the bacterial membrane surface. This review will discuss the bacterial signal peptidases that have been characterized to date, as well as putative signal peptidase sequences that have been recognized via bacterial genome sequencing. We review the investigations into the mechanism of Escherichia coli and Bacillus subtilis signal peptidase, and discuss the results in light of the recent crystal structure of the E. coli signal peptidase in complex with a beta-lactam-type inhibitor. The proposed conserved structural features of Type I signal peptidases give additional insight into the mechanism of this unique enzyme.

Correction: Crystal structure of a bacterialsignal peptidase in complex with a β-lactam inhibitor

This corrects the article DOI: 10.1038/24196

Crystal Structure of the Class D Beta-Lactamase OXA-10.

We report the crystal structure of a class D β-lactamase, the broad spectrum enzyme OXA-10 from Pseudomonas aeruginosa at 2.0 Å resolution. There are significant differences between the overall fold observed in this structure and those of the evolutionarily related class A and class C β-lactamases. Furthermore, the structure suggests the unique, cation mediated formation of a homodimer. Kinetic and hydrodynamic data shows that the dimer is a relevant species in solution and is the more active form of the enzyme. Comparison of the molecular details of the active sites of the class A and class C enzymes with the OXA-10 structure reveals that there is no counterpart in OXA-10 to the residues proposed to act as general bases in either of these enzymes (Glu 166 and Tyr 150, respectively). Our structures of the native and chloride inhibited forms of OXA-10 suggest that the class D enzymes have evolved a distinct catalytic mechanism for β-lactam hydrolysis. Clinical variants of OXA-10 are also discussed in light of the structure.

Crystal structure of Escherichia coli BamB, a lipoprotein component of the β-barrel assembly machinery complex.

In Gram-negative bacteria, the BAM (β-barrel assembly machinery) complex catalyzes the essential process of assembling outer membrane proteins. The BAM complex in Escherichia coli consists of five proteins: one β-barrel membrane protein, BamA, and four lipoproteins, BamB, BamC, BamD, and BamE. Despite their role in outer membrane protein biogenesis, there is currently a lack of functional and structural information on the lipoprotein components of the BAM complex. Here, we report the first crystal structure of BamB, the largest and most functionally characterized lipoprotein component of the BAM complex. The crystal structure shows that BamB has an eight-bladed β-propeller structure, with four β-strands making up each blade. Mapping onto the structure the residues previously shown to be important for BamA interaction reveals that these residues, despite being far apart in the amino acid sequence, are localized to form a continuous solvent-exposed surface on one side of the β-propeller. Found on the same side of the β-propeller is a cluster of residues conserved among BamB homologs. Interestingly, our structural comparison study suggests that other proteins with a BamB-like fold often participate in protein or ligand binding, and that the binding interface on these proteins is located on the surface that is topologically equivalent to where the conserved residues and the residues that are important for BamA interaction are found on BamB. Our structural and bioinformatic analyses, together with previous biochemical data, provide clues to where the BamA and possibly a substrate interaction interface may be located on BamB.

The bacterial outer membrane β-barrel assembly machinery

β‐Barrel proteins found in the outer membrane of Gram‐negative bacteria serve a variety of cellular functions. Proper folding and assembly of these proteins are essential for the viability of bacteria and can also play an important role in virulence. The β‐barrel assembly machinery (BAM) complex, which is responsible for the proper assembly of β‐barrels into the outer membrane of Gram‐negative bacteria, has been the focus of many recent studies. This review summarizes the significant progress that has been made toward understanding the structure and function of the bacterial BAM complex.

Crystal Structure of the Major Periplasmic Domain of the Bacterial Membrane Protein Assembly Facilitator YidC.

The essential bacterial membrane protein YidC facilitates insertion and assembly of proteins destined for integration into the inner membrane. It has homologues in both mitochondria and chloroplasts. Here we report the crystal structure of the Escherichia coli YidC major periplasmic domain (YidCECP1) at 2.5Å resolution. This domain is present in YidC from Gram-negative bacteria and is more than half the size of the full-length protein. The structure reveals that YidCECP1 is made up of a large twisted β-sandwich protein fold with a C-terminal α-helix that packs against one face of the β-sandwich. Our structure and sequence analysis reveals that the C-terminal α-helix and the β-sheet that it lays against are the most conserved regions of the domain. The region corresponding to the C-terminal α-helix was previously shown to be important for the protein insertase function of YidC and is conserved in other YidC-like proteins. The structure reveals that a region of YidC that was previously shown to be involved in binding to SecF maps to one edge of the β-sandwich. Electrostatic analysis of the molecular surface for this region of YidC reveals a predominantly charged surface and suggests that the SecF-YidC interaction may be electrostatic in nature. Interestingly, YidCECP1 has significant structural similarity to galactose mutarotase from Lactococcus lactis, suggesting that this domain may have another function besides its role in membrane protein assembly.