SummaryBacterial lipopolysaccharides (LPS) are unique and complex glycolipids that provide characteristic components of the outer membranes of Gram-negative bacteria. In LPS of the Enterobacteriaceae, the core oligosaccharide links a highly conserved lipid A to the antigenic O-polysaccharide. Structural diversity in the core oligosaccharide is limited by the constraints imposed by its essential role in outer membrane stability and provides a contrast to the hypervariable O-antigen. The genetics of core oligosaccharide biosynthesis in Salmonella and Escherichia coli K-12 have served as prototypes for studies on the LPS and lipo-oligosaccharides from a growing range of bacteria. However, despite the wealth of knowledge, there remains a number of unanswered questions, and direct experimental data are not yet available to define the precise mechanism of action of many gene products. Here we present a comparative analysis of the recently completed sequences of the major core oligosaccharide biosynthesis gene clusters from the five known core types in E. coli and the Ra core type of Salmonella enterica serovar Typhimurium and discuss advances in the understanding of the related biosynthetic pathways. Differences in these clusters reflect important structural variations in the outer core oligosaccharides and provide a basis for ascribing functions to the genes in these model clusters, whereas highly conserved regions within these clusters suggest a critical and unalterable function for the inner region of the core.
The success of Staphylococcus aureus as a pathogen is partly attributable to its ability to thwart host innate immune responses, which includes resisting the antimicrobial functions of phagocytes. Here, we have studied the interaction of methicillin-resistant S. aureus (MRSA) strain USA300 with murine RAW 264.7 and primary human macrophages using molecular imaging and single cell analysis to obtain an unprecedented understanding of the interaction between the macrophage and MRSA. Herein we demonstrate that macrophages fail to control intracellular infection by MRSA USA300 despite trafficking the bacteria into mature phagolysosomes. Using fluorescence-based proliferation assays we also show that intracellular staphylococci proliferate and that replication commences while the bacteria are residing in mature phagolysosomes hours after initial phagocytosis. Finally, live-cell fluorescence video microscopy allowed for unprecedented visual insight into the escape of MRSA from macrophages, demonstrating that the macrophages die through a pathway characterized by membrane blebbing and activation of caspase-3 followed by acquisition of the vital dye propidium iodide. Moreover, cell death precedes the emergence of MRSA from infected macrophages, and these events can be ablated by prolonged exposure of infected phagocytes to gentamicin.
The waaY, waaQ, and waaP genes are located in the central operon of the waa (formerly rfa) locus on the chromosome of Escherichia coli. This locus contains genes whose products are involved in the assembly of the core region of the lipopolysaccharide molecule. In the R1 core prototype strain, E. coli F470, there are nine genes in this operon, and all but waaY, waaQ, and waaP have been assigned function. In this study, the waaY, waaQ, and waaP genes were independently mutated by insertion of a non-polar antibiotic resistance cassette, and the structures of the resulting mutant core oligosaccharides were determined by chemical analyses and phosphorus-nuclear magnetic resonance spectroscopy. All three of these mutations were shown to affect the modification of the heptose region of the core, a region whose structure is critical to outer membrane stability. Mutation of waaY resulted in a core oligosaccharide devoid of phosphate on HepII. Mutation of waaQ resulted in loss of the branch HepIII residue on HepII and impeded the activity of WaaY. Mutation of waaP resulted in loss of phosphoryl substituents on HepI and obviated WaaQ and WaaY activity. Only mutation of waaP resulted in hypersensitivity to novobiocin and sodium dodecyl sulfate, a characteristic of deep-rough mutations.
Iron is a versatile redox-active catalyst and a required cofactor within a diverse array of biological processes. To almost all organisms, iron is both essential and potentially toxic, where homeostatic concentrations must be stringently maintained. Within the iron-restricted host, the survival and proliferation of microbial invaders is contingent upon exploiting the host iron pool. Bacteria express a multitude of complex, and often redundant means of acquiring iron, including surface-associated heme-uptake pathways, high affinity iron-scavenging siderophores and transporters of free inorganic iron. Within the last decade, our understanding of iron acquisition by Gram-positive pathogens has expanded substantively, from the discovery of the iron-regulated surface-determinant pathway and numerous unique siderophores through to the detailed elucidation of heme-iron extraction, and heme and siderophore coordination and transfer. This review provides a comprehensive summary of the iron acquisition strategies of notorious Gram-positive pathogens and highlights how both conserved and distinct tactics for acquiring iron contribute to the pathophysiology of these bacteria. Further, a focus on recent structural and mechanistic studies details how these iron acquisition systems may be exploited in the development of novel therapeutics.
In the lipopolysaccharides of Escherichia coli there are five distinct core oligosaccharide (core OS) structures, designated K-12 and R1 to R4. The objective of this work was to determine the prevalences of these core OS types within the species. Unique sequences in the waa (core OS biosynthesis) gene operon were used to develop a PCR-based system that facilitated unequivocal determination of the core OS types in isolates of E. coli. This system was applied to the 72 isolates in the E. coli ECOR collection, a compilation of isolates that is considered to be broadly representative of the genetic diversity of the species. Fifty (69.4%) of the ECOR isolates contained the R1 core OS, 8 (11.1%) were representatives of R2, 8 (11.1%) were R3, 2 (2.8%) were R4, and only 4 (5.6%) were K-12. R1 is the only core OS type found in all four major phylogenetic groups (A, B1, B2, and D) in the ECOR collection. Virulent extraintestinal pathogenic E. coli isolates tend to be closely related to group B2 and, to a lesser extent, group D isolates. All of the ECOR representatives from the B2 and D groups had the R1 core OS. In contrast, commensal E. coli isolates are more closely related to group A, which contains isolates representing each of the five core OS structures. R3 was the only core OS type found in 38 verotoxigenic E. coli (VTEC) isolates from humans and cattle belonging to the common enterohemorrhagic E. coli serogroups O157, O111, and O26. Although isolates from other VTEC serogroups showed more core OS diversity, the R3 type (83.1% of all VTEC isolates) was still predominant. When non-VTEC commensal isolates from cattle were analyzed, it was found that most possessed the R1 core OS type.The lipopolysaccharides (LPSs) of Escherichia coli consist of (i) a hydrophobic lipid A component that forms the outer leaflet of the outer membrane, (ii) a phosphorylated, nonrepetitive hetero-oligosaccharide known as the core oligosaccharide (core OS), and (iii) a polysaccharide (O-PS) that extends from the cell surface and that forms the O antigen detected in serotyping (37). The smooth LPS (S-LPS) molecules found in most clinical isolates of E. coli are composed of this three-part structure, whereas rough LPS (R-LPS) lacks the O antigen and can have a truncated core OS. The extent of structural diversity in E. coli LPS molecules ranges from the highly conserved lipid A to the extreme variations reflected in more than 170 known O antigens (19). The core OS is conceptually divided into inner and outer core regions. The inner core is composed primarily of L-glycero-D-manno-heptose (heptose) and 3-deoxy-Dmanno-oct-2-ulosonic acid (Kdo) residues, and this part of the core OS is phosphorylated in E. coli. The principal features of the inner core OS structure are conserved among members of the Enterobacteriaceae, presumably reflecting its essential role in outer-membrane stability (16). The inner core OS structure carries additional (often nonstoichiometric) glycosyl substituents, but these vary according to core OS type (16,18). The outer ...
The region upstream of the multiple antibiotic resistance efflux operon mexA-mexB-oprM in Pseudomonas aeruginosa was sequenced, and a gene, mexR, was identified. The predicted MexR product contains 147 amino acids with a molecular mass of 16,964 Da, which is consistent with the observed size of the overexpressed mexR gene product. MexR was homologous to MarR, the repressor of MarA-dependent multidrug resistance in Escherichia coli, and other repressors of the MarR family. A mexR knockout mutant showed a twofold increase in expression of both plasmid-borne and chromosomal mexA-reporter gene fusions compared with the MexR+ parent strain, indicating that the mexR gene product negatively regulates expression of the mexA-mexB-oprM operon. Furthermore, the cloned mexR gene product reduced expression of a plasmid-borne mexA-lacZ fusion in E. coli, indicating that MexR represses mexA-mexB-oprM expression directly. Consistent with the increased expression of the efflux operon in the mexR mutant, the mutant showed an increase (relative to its MexR+ parent) in resistance to several antimicrobial agents. Expression of a mexR-lacZ fusion increased threefold in a mexR knockout mutant, indicating that mexR is negatively autoregulated. OCR1, a nalB multidrug-resistant mutant which overproduces OprM, exhibited a greater than sevenfold increase in expression of a chromosomal mexA-phoA fusion compared with its parent. Introduction of a mexR knockout mutation in strain OCR1 eliminated this increase in efflux gene expression and, as expected, increased the susceptibility of the strain to a variety of antibiotics. The nucleotide sequences of the mexR genes of OCR1 and its parental strain revealed a single base substitution in the former which would cause a predicted substitution of Trp for Arg at position 69 of its mexR product. These data suggest that MexR possesses both repressor and activator function in vivo, the activator form being favored in nalB multidrug-resistant strains.
Pseudomonas aeruginosa strain K437 is defective in the production of a 90kDa ferripyoverdine receptor and is unable to grow in an iron-deficient medium in the presence of the non-metabolizable iron chelator 2,2'-dipyridyl (0.25 mM). An attempt to clone the ferripyoverdine receptor gene was made by complementing this growth defect. A number of clones restoring growth of K437 on dipyridyl-containing medium were obtained and several of these restored moderate expression of the 90 kDa receptor. A 5.5 kb xhoI-HindIII fragment derived from one of these clones was similarly capable of complementing the dipyridyl growth defect although it failed to restore expression of the 90 kDa ferripyoverdine receptor. Nucleotide sequencing of the 5.5 kb fragment revealed two large open reading frames (ORFs), designated ORFA and ORFB, which appeared to form an operon and were capable of encoding products of 41 kDa and 112 kDa, respectively. Using a phage T7-based expression system, products of 42 kDa and c. 108 kDa were produced from the cloned DNA, confirming that the ORFs were, indeed, expressed. The cloned ORFAB operon was inducible under conditions of iron limitation in both P. aeruginosa and Escherichia coli. In addition, mutants expressing ORFAB constitutively were constitutive for pyoverdine and ferripyoverdine receptor production suggesting that components of the pyoverdine-mediated iron-transport system are co-regulated with ORFAB. The predicted products of ORFA and ORFB showed significant homology to the Escherichia coli EnvC and EnvD polypeptides which are reportedly involved in septum formation. In addition, the ORFB product showed moderate homology to the CzcA polypeptide identified as a component of a membrane-associated plasmid-encoded cation efflux system in Alcaligenes eutrophus. Using in vitro mutagenesis and gene replacement, ORFA- and ORFB-deficient mutants of K372, the parent strain of K437, were constructed. These mutants were unable to grow on iron-deficient minimal medium containing 0.25 mM dipyridyl although they expressed the ferripyoverdine receptor and were proficient in pyoverdine-mediated iron uptake. Despite the homology of the ORFA and ORFB products to EnvC and EnvD, respectively, the ORFA-ORFB-deficient mutants were not defective in septum formation.(ABSTRACT TRUNCATED AT 400 WORDS)
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