Whole-genome expression profiling revealed Escherichia coli MG1655 genes induced by growth on mucus, conditions designed to mimic nutrient availability in the mammalian intestine. Most were nutritional genes corresponding to catabolic pathways for nutrients found in mucus. We knocked out several pathways and tested the relative fitness of the mutants for colonization of the mouse intestine in competition with their wild-type parent. We found that only mutations in sugar pathways affected colonization, not phospholipid and amino acid catabolism, not gluconeogenesis, not the tricarboxylic acid cycle, and not the pentose phosphate pathway. Gluconate appeared to be a major carbon source used by E. coli MG1655 to colonize, having an impact on both the initiation and maintenance stages. N-acetylglucosamine and N-acetylneuraminic acid appeared to be involved in initiation, but not maintenance. Glucuronate, mannose, fucose, and ribose appeared to be involved in maintenance, but not initiation. The in vitro order of preference for these seven sugars paralleled the relative impact of the corresponding metabolic lesions on colonization: gluconate > N-acetylglucosamine > N-acetylneuraminic acid ؍ glucuronate > mannose > fucose > ribose. The results of this systematic analysis of nutrients used by E. coli MG1655 to colonize the mouse intestine are intriguing in light of the nutrientniche hypothesis, which states that the ecological niches within the intestine are defined by nutrient availability. Because humans are presumably colonized with different commensal strains, differences in nutrient availability may provide an open niche for infecting E. coli pathogens in some individuals and a barrier to infection in others.
Escherichia coli MG1655 acid-inducible genes were identified by whole-genome expression profiling. Cultures were grown to the mid-logarithmic phase on acidified glucose minimal medium, conditions that induce glutamate-dependent acid resistance (AR), while the other AR systems are either repressed or not induced. A total of 28 genes were induced in at least two of three experiments in which the gene expression profiles of cells grown in acid (pH 5.5 or 4.5) were compared to those of cells grown at pH 7.4. As expected, the genes encoding glutamate decarboxylase, gadA and gadB, were significantly induced. Interestingly, two acid-inducible genes code for small basic proteins with pIs of >10.5, and six code for small acidic proteins with pIs ranging from 5.7 to 4.0; the roles of these small basic and acidic proteins in acid resistance are unknown. The acid-induced genes represented only five functional grouping categories, including eight genes involved in metabolism, nine associated with cell envelope structures or modifications, two encoding chaperones, six regulatory genes, and six unknown genes. It is unlikely that all of these genes are involved in the glutamate-dependent AR. However, nine acid-inducible genes are clustered in the gadA region, including hdeA, which encodes a putative periplasmic chaperone, and four putative regulatory genes. One of these putative regulators, yhiE, was shown to significantly increase acid resistance when overexpressed in cells that had not been preinduced by growth at pH 5.5, and mutation of yhiE decreased acid resistance; yhiE could therefore encode an activator of AR genes. Thus, the acid-inducible genes clustered in the gadA region appear to be involved in glutatmate-dependent acid resistance, although their specific roles remain to be elucidated.
SummaryCommensal and pathogenic strains of Escherichia coli possess three inducible acid resistance systems that collaboratively protect cells against acid stress to pH 2 or below. The most effective system requires glutamate in the acid challenge media and relies on two glutamate decarboxylases (GadA and B) combined with a putative glutamate: g g g g -aminobutyric acid antiporter (GadC). A complex network of regulators mediates induction of this system in response to various media, pH and growth phase signals. We report that the LuxR-like regulator GadE (formerly YhiE) is required for expression of gadA and gadBC regardless of media or growth conditions. This protein binds directly to the 20 bp GAD box sequence found in the control regions of both loci. Two previously identified AraC-like regulators, GadX and GadW, are only needed for gadA/BC expression under some circumstances. Overexpression of GadX or GadW will not overcome a need for GadE. However, overexpression of GadE can supplant a requirement for GadX and W. Data provided also indicate that GadX and GadE can simultaneously bind the area around the GAD box region and probably form a complex. The gadA , gadBC and gadE genes are all induced by low pH in exponential phase cells grown in minimal glucose media. The acid induction of gadA/BC results primarily from the acid induction of gadE . Constitutive expression of GadE removes most pH control over the glutamate decarboxylase and antiporter genes. The small amount of remaining pH control is governed by GadX and W. The finding that gadE mutations also diminish the effectiveness of the other two acid resistance systems suggests that GadE influences the expression of additional acid resistance components. The number of regulatory proteins (five), sigma factors (two) and regulatory feedback loops focused on gadA/BC expression make this one of the most intensively regulated systems in E. coli .
An important feature of Escherichia coli pathogenesis is an ability to withstand extremely acidic environments of pH 2 or lower. This acid resistance property contributes to the low infectious dose of pathogenic E. coli species. One very efficient E. coli acid resistance system encompasses two isoforms of glutamate decarboxylase (gadA and gadB) and a putative glutamate:␥-amino butyric acid (GABA) antiporter (gadC). The system is subject to complex controls that vary with growth media, growth phase, and growth pH. Previous work has revealed that the system is controlled by two sigma factors, two negative regulators (cyclic AMP receptor protein [CRP] and H-NS), and an AraC-like regulator called GadX. Earlier evidence suggested that the GadX protein acts both as a positive and negative regulator of the gadA and gadBC genes depending on environmental conditions. New data clarify this finding, revealing a collaborative regulation between GadX and another AraC-like regulator called GadW (previously YhiW). GadX and GadW are DNA binding proteins that form homodimers in vivo and are 42% homologous to each other. GadX activates expression of gadA and gadBC at any pH, while GadW inhibits GadX-dependent activation. Regulation of gadA and gadBC by either regulator requires an upstream, 20-bp GAD box sequence. Northern blot analysis further indicates that GadW represses expression of gadX. The results suggest a control circuit whereby GadW interacts with both the gadA and gadX promoters. GadW clearly represses gadX and, in situations where GadX is missing, activates gadA and gadBC. GadX, however, activates only gadA and gadBC expression. CRP also represses gadX expression. It does this primarily by repressing production of sigma S, the sigma factor responsible for gadX expression. In fact, the acid induction of gadA and gadBC observed when rich-medium cultures enter stationary phase corresponds to the acid induction of sigma S production. These complex control circuits impose tight rein over expression of the gadA and gadBC system yet provide flexibility for inducing acid resistance under many conditions that presage acid stress.
Acid in the stomach is thought to be a barrier to bacterial colonization of the intestine. Escherichia coli, however, has three systems for acid resistance, which overcome this barrier. The most effective of these systems is dependent on transport and decarboxylation of glutamate. GadX regulates two genes that encode isoforms of glutamate decarboxylase critical to this system, but additional genes associated with the glutamate-dependent acid resistance system remained to be identified. The gadX gene and a second downstream araC-like transcription factor gene, gadW, were mutated separately and in combination, and the gene expression profiles of the mutants were compared to those of the wild-type strain grown in neutral and acidified media under conditions favoring induction of glutamate-dependent acid resistance. Cluster and principal-component analyses identified 15 GadX-regulated, acid-inducible genes. Reverse transcriptase mapping demonstrated that these genes are organized in 10 operons. Analysis of the strain lacking GadX but possessing GadW confirmed that GadX is a transcriptional activator under acidic growth conditions. Analysis of the strain lacking GadW but possessing GadX indicated that GadW exerts negative control over three GadX target genes. The strain lacking both GadX and GadW was defective in acid induction of most but not all GadX target genes, consistent with the roles of GadW as an inhibitor of GadX-dependent activation of some genes and an activator of other genes. Resistance to acid was decreased under certain conditions in a gadX mutant and even more so by combined mutation of gadX and gadW. However, there was no defect in colonization of the streptomycin-treated mouse model by the gadX mutant in competition with the wild type, and the gadX gadW mutant was a better colonizer than the wild type. Thus, E. coli colonization of the mouse does not appear to require glutamatedependent acid resistance.
Pathogenic bacteria experience wide fluctuations in fluid shear levels during the natural course of infection, ranging from 4 to 50 dynes/cm 2 along blood vessel walls (7) to less than 1 dyne/cm 2 in utero and between the brush border microvilli of epithelial cells (1,5,6,15,24). While fluid shear has been reported to affect bacterial gene expression, physiology, and pathogenesis (3,4,19,25,26,31,32), the mechanism(s) by which this mechanical stimulation affects the response of bacterial pathogens has not been elucidated and has not been considered in the vast majority of studies. The principal limitation in the study of microbial response to fluid shear forces has been the lack of a model system to quantify variations in the fluid shear experienced during growth of planktonic (suspended) microbial cultures. Understanding multiscale biophysical phenomena, such as the mechanism behind the fluid shear response of cells, requires a multidisciplinary approach that incorporates the use of mathematical modeling to relate biological effects at large length scales to those at the cellular and subcellular levels. A rigorous combination of numerical modeling and well-characterized experimental microbial systems holds the potential to enhance our knowledge of bacterial pathogenesis and may lead to the identification of novel targets for vaccine and therapeutic development.We report the development of a novel model system wherein we mathematically modeled the fluid shear within a modified rotating wall vessel (RWV) bioreactor and evaluated the response of planktonic cultures of Salmonella enterica serovar Typhimurium to quantified ranges of physiological fluid shear. The design of the RWV bioreactor permits cell growth in suspension culture (9,17,20,32) and minimizes the fluid shear levels encountered by cells. The RWV is a rotating bioreactor in which cells are maintained in suspension in a gentle fluid orbit that creates a sustained low-fluid-shear environment for cell growth (Fig. 1A) (16, 20). The principal design of these reactors is based upon a cylindrical culture vessel, which is completely filled with medium (i.e., all bubbles are removed to reduce shear) and creates a solid body rotation as the vessel is rotated on its axis that is parallel to the ground. The solid body rotation of the media allows the organism to remain suspended at a constant terminal velocity and offsets the sedimentation of the bacteria in the reactor (13,16,27,28). Under these culture conditions, the cells are maintained in suspension in a gentle fluid orbit as the RWV is rotated and a sustained low-fluidshear environment for cell growth is achieved (Fig. 1B). A gas-permeable membrane on one side of the RWV allows * Corresponding author. Mailing
Background: Extra-cellular shear force is an important environmental parameter that is significant both medically and in the space environment. Escherichia coli cells grown in a low-shear modeled microgravity (LSMMG) environment produced in a high aspect rotating vessel (HARV) were subjected to transcriptional and physiological analysis.
The process of N2 fixation in the filamentous cyanobacterium Anabaena sp. PCC 7120 is known to occur in terminally differentiated cells called heterocysts. This study is concerned with a morphological and immunocytochemical analysis of the developing heterocysts. The heterocysts continue a developmental process after synthesis of the specialized cell wall and the formation of the proheterocyst. The initial stages were described by Wilcox et al. (1973) and designated stages 1 through 7, with stages 5–7 associated with the maturing heterocyst. We now designate a stage 8 as the postmaturation stage, based on physiological and ultrastructural evidence. Immunocytochemistry to detect the nitrogenase protein NifH and the nonribosomally synthesized polypeptide cyanophycin demonstrated a complementary accumulation of these polypeptides. Accumulation of the nitrogenase protein was greatest at stages 5 and 6 and then declined precipitously. Cyanophycin was more prevalent after late stage 6 and was primarily associated with the polar nodule (polar plug) and the neck connecting the heterocyst with the adjoining vegetative cell. We suggest that the cyanophycin‐containing polar plug is a key intermediate in the storage of fixed nitrogen in the heterocyst, a result consistent with the suggestion first made by Carr (1988) that cyanophycin exists as a dynamic reservoir of fixed nitrogen within the heterocysts.
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