Structure and Function of the T4 Spackle Protein Gp61.3.

The bacteriophage T4 genome contains two genes that code for proteins with lysozyme activity-e and 5. Gene e encodes the well-known T4 lysozyme (commonly called T4L) that functions to break the peptidoglycan layer late in the infection cycle, which is required for liberating newly assembled phage progeny. Gene product 5 (gp5) is the tail-associated lysozyme, a component of the phage particle. It forms a spike at the tip of the tail tube and functions to pierce the outer membrane of the Escherichia coli host cell after the phage has attached to the cell surface. Gp5 contains a T4L-like lysozyme domain that locally digests the peptidoglycan layer upon infection. The T4 Spackle protein (encoded by gene 61.3) has been thought to play a role in the inhibition of gp5 lysozyme activity and, as a consequence, in making cells infected by bacteriophage T4 resistant to later infection by T4 and closely related phages. Here we show that (1) gp61.3 is secreted into the periplasm where its N-terminal periplasm-targeting peptide is cleaved off; (2) gp61.3 forms a 1:1 complex with the lysozyme domain of gp5 (gp5Lys); (3) gp61.3 selectively inhibits the activity of gp5, but not that of T4L; (4) overexpression of gp5 causes cell lysis. We also report a crystal structure of the gp61.3-gp5Lys complex that demonstrates that unlike other known lysozyme inhibitors, gp61.3 does not interact with the active site cleft. Instead, it forms a "wall" that blocks access of an extended polysaccharide substrate to the cleft and, possibly, locks the enzyme in an "open-jaw"-like conformation making catalysis impossible.

Stereoselective [3,3]-sigmatropic rearrangement promoted by the metal [1,3]-shift of binuclear Fischer carbene complexes.

Reaction of chiral homobinuclear Fischer chromium carbene complexes with allyl alcohol in the presence of NaH and the following oxidative demetalation gave alpha-allyl esters in up to 97% ee via [3,3]-sigmatropic rearrangement reaction promoted by the metal 1,3-shift. On the other hand, chiral heterobinuclear tungsten carbene complexes with arene chromium complexes afforded alpha-allyl-beta-hydroxy esters as a major product in up to 92/8 dr by the same reaction sequence.

Structure and properties of the C-terminal ß-helical domain of VgrG protein from Escherichia coli O157.

The bacterial Type 6 secretion system (T6SS) translocates protein toxins (also called effectors) from the cytosol of a T6SS-carrying cell to a target cell by a syringe-like supramolecular complex resembling a contractile tail of bacteriophages. Valine-glycine repeat protein G (VgrG) proteins, which are the homologues of the gp27-gp5 (gene product) cell puncturing complex of bacteriophage T4, are considered to be located at the attacking tip of the bacterial T6SS apparatus. Here, we over-expressed six VgrG proteins from pathogenic Escherichia coli O157 and CFT073 strains. Purified VgrG1 of E. coli O157 and c3393 of E. coli CFT073 form trimer in solution and are rich in ß-structure. We also solved the crystal structure of a trypsin-resistant C-terminal fragment of E. coli O157 VgrG1 (VgrG1C(G561)) at 1.95 Å resolution. VgrG1C(G561) forms a three-stranded antiparallel ß-helix which is structurally similar to the ß-helix domain of the central spike protein (gp138) of phi92 phage, indicating a possible evolutional relationship. Comparison of four different three-stranded ß-helix proteins shows how their amino acid composition determines the protein fold.