Sortase-catalysed anchoring of surface proteins to the cell wall of Staphylococcus aureus

Many surface proteins of Gram-positive bacteria are anchored to the cell wall envelope by a transpeptidation mechanism, requiring a C-terminal sorting signal with a conserved LPXTG motif. Sortase, a membrane protein of Staphylococcus aureus, cleaves polypeptides between the threonine and the glycine of the LPXTG motif and catalyses the formation of an amide bond between the carboxyl-group of threonine and the amino-group of peptidoglycan cross-bridges. S. aureus mutants lacking the srtA gene fail to anchor and display some surface proteins and are impaired in the ability to cause animal infections. Sortase acts on surface proteins that are initiated into the secretion (Sec) pathway and have their signal peptide removed by signal peptidase. The S. aureus genome encodes two sets of sortase and secretion genes. It is conceivable that S. aureus has evolved more than one pathway for the transport of 20 surface proteins to the cell wall envelope.     

Anchoring of surface proteins to the cell wall of Staphylococcus aureus. III. Lipid II is an in vivo peptidoglycan substrate for sortase-catalyzed surface protein anchoring

Surface proteins of Staphylococcus aureus are anchored to the cell wall peptidoglycan by a mechanism requiring a C-terminal sorting signal with an LPXTG motif. Surface proteins are first synthesized in the bacterial cytoplasm and then transported across the cytoplasmic membrane. Cleavage of the N-terminal signal peptide of the cytoplasmic surface protein P1 precursor generates the extracellular P2 species, which is the substrate for the cell wall anchoring reaction. Sortase, a membrane-anchored transpeptidase, cleaves P2 between the threonine (T) and the glycine (G) of the LPXTG motif and catalyzes the formation of an amide bond between the carboxyl group of threonine and the amino group of cell wall cross-bridges. We have used metabolic labeling of staphylococcal cultures with [(32)P]phosphoric acid to reveal a P3 intermediate. The (32)P-label of immunoprecipitated surface protein is removed by treatment with lysostaphin, a glycyl-glycine endopeptidase that separates the cell wall anchor structure. Furthermore, the appearance of P3 is prevented in the absence of sortase or by the inhibition of cell wall synthesis. (32)P-Labeled cell wall anchor species bind to nisin, an antibiotic that is known to form a complex with lipid II. Thus, it appears that the P3 intermediate represents surface protein linked to the lipid II peptidoglycan precursor. The data support a model whereby lipid II-linked polypeptides are incorporated into the growing peptidoglycan via the transpeptidation and transglycosylation reactions of cell wall synthesis, generating mature cell wall-linked surface protein.     

The human commensal Bacteroides fragilis binds intestinal mucin

The mammalian gastrointestinal tract harbors a vast microbial ecosystem, known as the microbiota, which benefits host biology. Bacteroides fragilis is an important anaerobic gut commensal of humans that prevents and cures intestinal inflammation. We wished to elucidate aspects of gut colonization employed by B. fragilis. Fluorescence in situ hybridization was performed on colonic tissue sections from B. fragilis and Escherichia coli dual-colonized gnotobiotic mice. Epifluorescence imaging reveals that both E. coli and B. fragilis are found in the lumen of the colon, but only B. fragilis is found in the mucosal layer. This observation suggests that physical association with intestinal mucus could be a possible mechanism of gut colonization by B. fragilis. We investigated this potential interaction using an in vitro mucus binding assay and show here that B. fragilis binds to murine colonic mucus. We further demonstrate that B. fragilis specifically and quantitatively binds to highly purified mucins (the major constituent in intestinal mucus) using flow cytometry analysis of fluorescently labeled purified murine and porcine mucins. These results suggest that interactions between B. fragilis and intestinal mucin may play a critical role during host-bacterial symbiosis.     

Structures of sortase B from Staphylococcus aureus and Bacillus anthracis reveal catalytic amino acid triad in the active site

Surface proteins attached by sortases to the cell wall envelope of bacterial pathogens play important roles during infection. Sorting and attachment of these proteins is directed by C-terminal signals. Sortase B of S. aureus recognizes a motif NPQTN, cleaves the polypeptide after the Thr residue, and attaches the protein to pentaglycine cross-bridges. Sortase B of B. anthracis is thought to recognize the NPKTG motif, and attaches surface proteins to m-diaminopimelic acid cross-bridges. We have determined crystal structure of sortase B from B. anthracis and S. aureus at 1.6 and 2.0 A resolutions, respectively. These structures show a beta-barrel fold with alpha-helical elements on its outside, a structure thus far exclusive to the sortase family. A putative active site located on the edge of the beta-barrel is comprised of a Cys-His-Asp catalytic triad and presumably faces the bacterial cell surface. A putative binding site for the sorting signal is located nearby.     

The zebrafish dyrk1b gene is important for endoderm formation

Nodal‐signaling is required for specification of mesoderm, endoderm, establishing left–right asymmetry, and craniofacial development. Wdr68 is a WD40‐repeat domain‐containing protein recently shown to be required for endothelin‐1 (edn1) expression and subsequent lower jaw development. Previous reports detected the Wdr68 protein in multiprotein complexes containing mammalian members of the dual‐specificity tyrosine‐regulated kinase (dyrk) family. Here we describe the characterization of the zebrafish dyrk1b homolog. We report the detection of a physical interaction between Dyrk1b and Wdr68. We also found perturbations of nodal signaling in dyrk1b antisense morpholino knockdown (dyrk1b‐MO) animals. Specifically, we found reduced expression of lft1 and lft2 (lft1/2) during gastrulation and a near complete loss of the later asymmetric lft1/2 expression domains. Although wdr68‐MO animals did not display lft1/2 expression defects during gastrulation, they displayed a near complete loss of the later asymmetric lft1/2 expression domains. While expression of ndr1 was not substantially effected during gastrulation, ndr2 expression was moderately reduced in dyrk1b‐MO animals. Analysis of additional downstream components of the nodal signaling pathway in dyrk1b‐MO animals revealed modestly expanded expression of the dorsal axial mesoderm marker gsc while the pan‐mesodermal marker bik was largely unaffected. The endodermal markers cas and sox17 were also moderately reduced in dyrk1b‐MO animals. Notably, and similar to defects previously reported for wdr68 mutant animals, we also found reduced expression of the pharyngeal pouch marker edn1 in dyrk1b‐MO animals. Taken together, these data reveal a role for dyrk1b in endoderm formation and craniofacial patterning in the zebrafish. genesis 48:20–30, 2010. © 2009 Wiley‐Liss, Inc.     

A program of Yersinia enterocolitica type III secretion reactions is activated by specific signals

Successful establishment of Yersinia infections requires the type III machinery, a protein transporter that injects virulence factors (Yops) into macrophages. It is reported here that the Yersinia type III pathway responds to environmental signals by transporting proteins to distinct locations. Yersinia enterocolitica cells sense an increase in extracellular amino acids (glutamate, glutamine, aspartate, and asparagine) that results in the activation of the type III pathway. Another signal, provided by serum proteins such as albumin, triggers the secretion of YopD into the extracellular medium. The third signal, a decrease in calcium concentration, appears to be provided by host cells and causes Y. enterocolitica to transport YopE and presumably other virulence factors across the eukaryotic plasma membrane. Mutations in several genes encoding regulatory molecules (lcrG, lcrH, tyeA, yopD, yopN, yscM1, and yscM2) bypass the signal requirement of the type III pathway. Together these results suggest that yersiniae may have evolved distinct secretion reactions in response to environmental signals.