Intestinal pathogenic Escherichia coli represents a global health problem for mammals, including humans. At present, diarrheagenic E. coli bacteria are grouped into seven major pathotypes that differ in their virulence factor profiles, severity of clinical manifestations, and prognosis. In this study, we developed and evaluated a one-step multiplex PCR (MPCR) for the straightforward differential identification of intestinal pathotypes of E. coli. The specificity of this novel MPCR was validated by using a subset of reference strains and further confirmed by PCR-independent pheno-and genotypic characterization. Moreover, we tested 246 clinical E. coli isolates derived from diarrhea patients from several distinct geographic regions. Interestingly, besides strains belonging to the defined and well-described pathotypes, we identified five unconventional strains expressing intermediate virulence factor profiles. These strains have been further characterized and appear to represent intermediate strains carrying genes and expressing factors associated with enteropathogenic E. coli, Shiga toxin-producing E. coli, enterotoxigenic E. coli, and enteroaggregative E. coli alike. These strains represent further examples of the extraordinary plasticity of the E. coli genome. Moreover, this implies that the important identification of specific pathotypes has to be based on a broad matrix of indicator genes. In addition, the presence of intermediate strains needs to be accounted for.
Coronavirus gene expression involves proteolytic processing of the gene 1-encoded polyprotein(s), and a key enzyme in this process is the viral 3C-like proteinase. In this report, we describe the biosynthesis of the human coronavirus 229E 3C-like proteinase in Escherichia coli and the enzymatic properties, inhibitor profile, and substrate specificity of the purified protein. Furthermore, we have introduced single amino acid substitutions and carboxyl-terminal deletions into the recombinant protein and determined the ability of these mutant 3C-like proteinases to catalyze the cleavage of a peptide substrate. Using this approach, we have identified the residues Cys-3109 and His-3006 as being indispensable for catalytic activity. Our results also support the involvement of His-3127 in substrate recognition, and they confirm the requirement of the carboxyl-terminal extension found in coronavirus 3C-like proteinases for enzymatic activity. These data provide experimental evidence for the relationship of coronavirus 3C-like proteinases to other viral chymotrypsin-like enzymes, but they also show that the coronavirus proteinase has additional, unique properties.
SummaryCell-permeable proteins, also called cell-penetrating peptides (CPPs), have the ability to cross cellular membranes, either alone or in association with bioactive cargo. We identified the Yersinia protein YopM as a novel bacterial cell-permeable protein. Here, we describe the ability of isolated recombinant YopM to enter host cells without a requirement for additional factors. This autonomous translocation of YopM was confirmed in several cell types, indicating that it is an intrinsic property of YopM. Using truncated versions of YopM, we show that either of the two N-terminal -helices of YopM mediates translocation into the cells. Furthermore, the two -helices are also able to deliver heterologous cargo, such as GFP or YopE. In addition, we found that, after entering the cells, YopM is functional and efficiently downregulates the transcription of pro-inflammatory cytokines (such as tumor necrosis factor- and interleukins 12, 15 and 18). This finding suggests the potential use of YopM as a tool for protein delivery. Furthermore, it can lead to important advances in understanding and evaluating the intracellular and molecular function of YopM without the need for infection with Yersinia.
Yersinia enterocolitica is an enteric pathogen that has served as a model system for the study of microbial pathogenesis. Numerous virulence gene have been identified both on the virulence plasmid and on the chromosome. One of the chromosomal genes that is highly correlated with virulence is ail, a gene identified along with inv in a screen for Y. enterocolitica genes that could confer an invasive phenotype to Escherichia coli. Ail also promotes serum resistance in both E. coli and Y. enterocolitica. Several virulence factors homologous to Ail have been identified in other pathogens, yet very little is known about what constitutes the functional domain(s) of these proteins. Proteins in this family are predicted to consist of eight transmembrane β‐sheets and four cell surface‐exposed loops. We constructed and characterized a number of insertion, deletion and point mutations in the regions of ail predicted to encode the cell surface loops. The results from the analysis of these mutants indicate that cell surface loops one and four do not directly promote invasion or serum resistance, whereas mutations in loop three appear to modulate both phenotypes. Analysis of mutations in loop 2 suggests that this surface‐exposed loop contains sequences required for serum resistance and invasion. In addition, a peptide derived from the sequence of loop 2 was able specifically to inhibit Ail‐mediated invasion in a dose‐dependent manner. These results suggest that Ail directly promotes invasion and that loop 2 contains an active site, perhaps a receptor‐binding domain. Analyses of the mutations also suggest that the serum resistance and invasion phenotypes may be separable, because there are numerous mutations that affect one phenotype but not the other.
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