Abstract and Introduction
Abstract
Purpose of review Colonization of the host epithelia by pathogenic Escherichia coli is influenced by the ability of the bacteria to interact with host surfaces. Because the initial step of an E. coli infection is to adhere, invade, and persist within host cells, some strategies used by intestinal and extraintestinal E. coli to infect host cell are presented.
Recent findings This review highlights recent progress understanding how extraintestinal pathogenic E. coli strains express specific adhesins or invasins that allow colonization of the urinary tract or the meninges, while intestinal E. coli strains are able to colonize different regions of the intestinal tract using other specialized adhesins or invasins. Finally, evaluation of different diets and environmental conditions regulating the colonization of these pathogens is discussed.
Summary Discovery of new interactions between pathogenic E. coli and the host epithelial cells unravels the need for more mechanistic studies that can provide new clues regarding how to combat these infections.
Introduction
Escherichia coli are commonly found as part of the gut flora, in which it is the predominant aerobic organism, living in symbiosis with its vertebrate host. However, there are several categories of E. coli strains that have acquired the ability to cause pathogenic processes in the host. These E. coli strains can cause intestinal (enteritis, diarrhea, or dysentery), or extraintestinal diseases [urinary tract infections (UTIs), sepsis, or meningitis]. To cause infection, pathogenic E. coli interact with the mucosa, by either attaching to the epithelial cells and, in some instances, invading the target host cells. Because bacterial adhesion and/or invasion to or into host cells are the first steps during infection, it is necessary to understand at a molecular level the mechanisms mediating these initial interactions. This article focuses on reviewing recent progress on the understanding of the adhesion or invasion mechanisms used by intestinal and extraintestinal pathogenic E. coli during colonization of the host cells.
Enterohemorrhagic Escherichia coli
Enterohemorrhagic E. coli (EHEC) are a category of pathogenic E. coli that colonize the human large intestine and which can cause bloody diarrhea, or a systemic process known as hemolytic uremic syndrome. EHEC strains are characterized by the production of Shiga toxin and the formation of attaching and effacing intestinal lesions (Fig. 1). Cattle are a main reservoir for EHEC strains; however, several vegetables and fruits can serve as vehicles for EHEC outbreaks.
(Enlarge Image)
Figure 1.
Pathogenic Escherichia coli colonization of intestinal epithelial cells and uroepithelium. Adherence and/or invasion of intestinal (EPEC, EHEC, EAEC, ETEC, AIEC) and extraintestinal (UPEC) pathogenic Escherichia coli to epithelial cells (see the text for details). AIEC, adherent and invasive E. coli; EAEC, enteroaggregative E. coli; EHEC, enterohemorrhagic E. coli; EPEC, enteropathogenic E. coli; ETEC, enterotoxigenic E. coli; LT, heat-labile; ST, heat-stable; UPEC, uropathogenic E. coli.
EHEC colonization is impacted by nutrient availability and dietary choice. Zumbrun et al. found that dietary fiber content affects susceptibility to E. coli O157:H7 infection in mice. They treated BALB/c mice with high-fiber diet (10% guar gum) or low-fiber diet (2% guar gum) for 2 weeks, and then mice were challenge with 10 to 10 cfu of E. coli O157:H7. The results showed that mice fed with high-fiber diet had enhanced levels of butyrate that temporally increased the expression of the Shiga toxin receptor Gb3. Therefore, mice exhibited greater E. coli O157:H7 colonization and reduction in resident Escherichia spp. Sheng et al. also showed that cattle fed a hay diet are colonized by EHEC for a longer period of time than grain-fed cattle. Different diets regulate the colonization of E. coli O157:H7 by altering the composition of gastrointestinal tract microbiota, and the study demonstrated that the bacterial SdiA sensor activates genes conferring EHEC acid resistance, increasing efficient colonization of the cattle mucosa.
Modulation of host signals in the intestinal epithelia also affects EHEC colonization. Intestinal epithelial cells produced SIGIRR, a negative regulator of interleukin-1 and toll-like receptor (TLR) signaling, that makes the cells hyporesponsive. To address whether hyporesponsiveness affects enteric host defense, Sham et al. challenged Sigirr-deficient (-/-) mice with the murine pathogen, EHEC-related, Citrobacter rodentium and showed that Sigirr-/- mice are more susceptible to bacterial infection and had a dramatic loss of microbiota. The study showed that this host signaling mechanism promotes commensal dependent resistance to EHEC colonization.
Type III secretion system (TTSS) is required for EHEC colonization and attaching and effacing lesion formation. This syringe-like structure used to inject virulence factors into the host cell is exquisitely regulated. Hansen et al. revealed that tyrosine phosphorylation in EHEC mediates signaling of virulence properties, including the TTSS. SspA is a known regulator of the TTSS, and a phosphorylated tyrosine residue of this protein positively affects expression and secretion of TTSS proteins. Branchu et al. also found a new regulator of the TTSS known as the nitric oxide-sensor regulator, NsrR. Nitric oxide reduced EHEC adherence to intestinal epithelial cells, by causing the detachment of the NsrR activator from the TTSS-encoding operons (LEE1/4/5), limiting colonization.
Enteropathogenic Escherichia coli
Enteropathogenic E. coli (EPEC) isolates colonize the small intestine and are one of the leading causes of infantile fatal diarrhea. In industrialized countries, there are sporadic diarrheal cases in daycare facilities. As for EHEC, EPEC uses the TTSS to form attaching and effacing lesions (Fig. 1). EPEC strains are subdivided into typical (tEPEC) and atypical EPEC (aEPEC) based on the presence of EPEC adherence factor plasmid associated with the tEPEC localized adherence pattern. Some aEPEC form diffuse or aggregative adherence pattern and Hernandes et al. found that the diffuse adherence pattern is associated with the type three secretion system, and it is suggested that the translocon serves as the diffuse adherence adhesin.
Regarding the TTSS, recent studies have evaluated the role of the effector protein NleB in pathogenesis. Deletion of nleB1 in C. rodentium caused significant reduction in murine intestinal colonization, and NleB has also been shown to modulate the host innate immune system by suppressing tumor necrosis factor-mediated nuclear factor kappa-light-chain-enhancer of activated B cells (NF-κB) activation. Three studies have investigated the role of NleB1 in EPEC. Gao et al. focused on how NleB interfere with NF-κB. A proteomic screen was used to identify the host GAPDH as NleB-interacting protein, which results in modification of GAPDH and inhibition of NF-κB-dependent innate immune responses. The other two groups discovered that NleB blocks host death receptor signaling, by interacting with two death receptor-signaling proteins, TRADD and FADD. NleB is the first known bacterial virulence factor to target death receptor signaling and it has been suggested that blocking this signaling mechanism may facilitate EPEC and EHEC colonization.
Other studies evaluated ways to reduce EPEC adhesion to host cells. Pan et al. expressed synthetic tetrameric-branched peptide that enhanced the expression of Mucin 3. They found that Mucin 3 interacted with EPEC and EHEC and reduced their binding to epithelial cells. In another study, Salcedo et al. showed that the combination of gangliosides and sialic acid was able to interfere with EPEC and EHEC adhesion to Caco-2 cells.
Enterotoxigenic Escherichia coli
Enterotoxigenic E. coli (ETEC) colonizes the human small intestine and is responsible for neonatal diarrhea in developing countries as well as 'travelers' diarrhea'. ETEC adherence to the intestinal mucosa is mainly mediated by diverse adhesive structures known as colonization factors, which in combination with the heat-labile and/or heat-stable enterotoxins, causes disruption of fluid homeostasis in the host, resulting in diarrhea (Fig. 1).
Guevara et al. recently investigated one colonization factor, the CS21 pilus, and its role in adherence and pathogenesis in vivo. They found that ETEC CS21 (Longus) adherence to primary intestinal cells was inhibited by anti-LngA sera and the purified LngA protein. In-vivo intrastomach administration of CS21-expressing ETEC strain contributes to 100% lethality of newborn mice, which was reduced in the lngA mutant. A separate study investigated the role of the heat-labile toxin in ETEC colonization. The authors observed enhanced adherence to IPEC-J2 cells by various isogenic ETEC constructs carrying different forms of the heat-labile toxin [K88/heat-labile wild type, attenuated toxin form (K88/LTR192G) and expressing just the B subunit (K88/LTB)], in contrast to the attenuated phenotype of the heat-labile-negative construct. Heat-labile strains blocking binding of wild type ETEC strain to IPEC-J2 cells suggested that heat-labile-driven adherence alters net surface charge on epithelial cells. Another study evaluated the transcriptional pattern of 214 genes at different time points following interaction of prototype ETEC E24377A with epithelial cells. The study found a prominent alteration of genes associated with motility, adhesion, toxin production, and global regulatory mechanisms, such as those linked to cAMP receptor protein and c-di-GMP, upon ETEC–host interaction, which suggested that ETEC coordinated its responses to the host environment by sequential activation of different virulence factors.
Among those ETEC strains infecting animals, the most common adhesive fimbriae include K88 or K99 (also called F4 and F5). Recently, Zhou et al. demonstrated that deletion of fliC (encoding the major flagellin protein) and/or the faeG (encoding the F4 major fimbrial subunit) from ETEC strain C83902 significantly reduced its ability to adhere to porcine epithelia IPEC-J2 cells, but also impacting biofilm formation and quorum sensing. Interestingly, another study found an alternative way to block the adherence of ETEC K88 to IPEC-J2 by using ETEC antiadhesives, including casein glycomacropeptide, exopolysaccharide, and vegetable extract (locust bean or wheat bran). Finally, studies with human milk and commercial infant formulas found that the main gangliosides (GM3, GD3, GM1) and free sialic acid (Neu5Ac) are able to impede the adhesion of several pathogenic bacteria, including ETEC. Other dietary supplements, such as plantain NSP, also hampered the adherence of ETEC to Caco-2 cells, and it has been suggested that blocking M-cell bacterial translocation can subsequently prevent diarrheal episodes.
Enteroaggregative Escherichia coli
Enteroaggregative E. coli (EAEC) are a major cause of acute and persistent diarrhea in the small intestine of children and adults worldwide, including industrialized countries. EAEC is also responsible for sporadic cases and several outbreaks. At an initial stage of infection, EAEC adhere in a characteristic 'stacked-brick' formation to host intestinal mucosa; forming a thick mucoid biofilm. The adherence process is mainly mediated by fimbrial structures called aggregative adherence fimbriae (AAF) (Fig. 1). Additionally, several EAEC virulence-related genes have been described, but their role in the clinical outcome of infection is not completely defined.
A study recently confirmed a high prevalence, endemicity, and heterogeneity of EAEC strains and found that the plasmid-encoded toxin or AAF/II fimbrial subunit genes were associated significantly with disease. However, this study also demonstrated that the pathophysiology of EAEC infections involves a complex and dynamic modulation of several virulence factors. Another study identified an association of the EAEC virulence-encoded aggR gene (virulence regulator), pCDV432 plasmid, and additional virulence gene products, including dispersin and the Air adhesin in 90% of the diarrheagenic isolates that distinguished them from nondiarrheagenic EAEC strains, suggesting heterogeneity among highly pathogenic EAEC strains.
Another area of study in EAEC pathogenesis is the contribution of the autotransporter proteins. Munera et al. evaluated the role of chromosome-encoded autotransporters in colonization and subsequent induction of diarrheal disease in infant rabbits and found that Shiga toxin-producing EAEC O104:H4 autotransporters, but not its virulence plasmid, are critical for robust colonization and disease. EAEC has also been associated with UTIs. The autotransporter Pic has been defined as a gene marker associated with spreading of infection to the urinary tract. Finally, comparison of EAEC isolates from HIV-positive and non-HIV diarrheal samples showed that HIV-positive isolates are stronger biofilm producers and more resistant to antibiotics than the non-HIV diarrheal isolates, which confirmed the heterogeneity of the EAEC isolates.
Adherent and Invasive Escherichia coli
Inflammatory bowel disease (IBD), particularly Crohn's disease and ulcerative colitis, is the result of alterations in the intestinal microbiota due to a variety of genetic and environmental factors. Interestingly, an increased number of adherent and invasive E. coli (AIEC) have been isolated from IBD patients and more frequently found in ileal-Crohn's disease patients than in healthy controls. AIEC strains have the ability to adhere and invade intestinal epithelial cells and survive within macrophages. Small et al. recently established a chronic infection murine model using prototypical AIEC isolates and demonstrated that AIEC infection stimulates chronic inflammation and fibrosis in mice. This study showed for the first time evidence that an infection with AIEC can cause intestinal symptoms similar to those observed in Crohn's disease patients.
AIEC adherence depends on the expression of the type 1 pili, long polar fimbriae and the presence of the carcinoembryonic antigen (CEACAM6) as a host cell receptor (Fig. 1). Crohn's disease patients showed abnormal expression of CEACAM6 and as such, Martinez-Medina et al. used a model of transgenic mice expressing CEACAMs to assess the effects of a high-fat or high-sugar western diet on gut microbiota composition, barrier integrity, and susceptibility to infection. They found that the diet induces changes in gut microbiota composition, altering host homeostasis and promoting AIEC murine gut colonization. With respect to the type 1 pili, a study sequenced the fimH gene (FimH is the adhesin protein located on the tip of the pili) from 45 AIEC strains and 47 non-AIEC E. coli strains. Phylogenetic analysis found that AIEC strains predominantly express FimH with amino acid mutations of a recent evolutionary origin as compared with non-AIEC strains, which represents a feature of pathoadaptive changes in several bacterial pathogens. The accumulation of these mutations confers AIEC the ability to adhere to CEACAM-expressing intestinal epithelial cells and to participate in the development of chronic inflammation in a genetically susceptible host. Finally, it is known that the long polar fimbriae help AIEC to interact with intestinal Peyer's patches and M cells. A recent study analyzed the effect of gastrointestinal conditions on AIEC long polar fimbriae expression. The authors found that bile salts strongly enhanced fimbriae expression, causing a higher level of interaction of AIEC with Peyer's patches and a higher level of translocation through M cell monolayers.
Regarding the clinical implications of AIEC, recent investigation indicates that colonization of AIEC results in chronic colitis in mice lacking the flagellin receptor TLR5. Transient AIEC colonization drove intestinal inflammation that is associated with altering microbiota composition. Proteases and protease inhibitors control microbiota composition, immune response, and intestinal function to maintain gut homeostasis. CYLD is a deubiquitinase that is significantly downregulated in the intestine of Crohn's disease patients. Decreased CYLD expression results in an enhanced intracellular replication of AIEC. Therefore, protection against AIEC during microbiota acquisition might be a strategy to control IBD in genetically susceptible individuals.
Uropathogenic Escherichia coli
Uropathogenic E. coli (UPEC) are among the most prevalent extraintestinal bacteria, accounting for 90% of all UTI. The most predominant chaperone-usher fimbriae in UPEC strains is the type 1 fimbriae, which is an important determinant for pathogenicity, allowing the interaction of UPEC with urinary tract host epithelia. FimH within the type 1 fimbriae bound to α-D-mannosylated uroplakin, facilitating bacterial invasion, colonization, and formation of biofilm-like structures called intracellular bacterial communities (Fig. 1). A high-throughput in-silico analysis and in-vitro binding study discovered that pathoadaptive alleles of FimH, with variant residues outside the binding pocket, affect FimH-mediated acute and chronic pathogenesis of two prototype UPEC strains. The study argues that FimH variants, which maintain a high-affinity conformation, were attenuated during chronic bladder infection, implying that the ability of FimH to switch between conformations is important during pathogenesis.
With respect to the regulatory mechanisms controlling UPEC colonization, Mitra et al. found UvrY as a key regulator modulating phase variation during UPEC pathogenesis, down-regulating the expression of type 1 fimbrial structural genes, and influencing biofilm formation, virulence, and motility in UPEC strain CFT073. Cpx is another key regulator involved in bacterial adhesion. The deletion of cpxRA impaired the ability of UPEC strain UTI89 to invade and colonize bladder epithelial cells, suggesting that the Cpx system is needed for UPEC persistence in the urinary tract. Similarly, mutation in cpxRA and cpxP in CFT073 also greatly reduced virulence tested in the zebrafish infection model. Secondary metabolites are being studied because asiatic acid and ursolic acid decreased expression of P fimbriae and curli fibers, altering cell morphology and adhesion of UPEC to uroepithelial cells. Finally, Rafsanjany et al. also demonstrated antiadhesive effects of various medicinal plant extracts against UPEC strains.