Contribution of Noncanonical Antigens to Virulence and Adaptive Immunity in Human Infection with Enterotoxigenic E. coli.

Enterotoxigenic Escherichia coli (ETEC) contributes significantly to the substantial burden of infectious diarrhea among children living in low- and middle-income countries. In the absence of a vaccine for ETEC, children succumb to acute dehydration as well as nondiarrheal sequelae related to these infections, including malnutrition. The considerable diversity of ETEC genomes has complicated canonical vaccine development approaches defined by a subset of ETEC pathovar-specific antigens known as colonization factors (CFs). To identify additional conserved immunogens unique to this pathovar, we employed an "open-aperture" approach to capture all potential conserved ETEC surface antigens, in which we mined the genomic sequences of 89 ETEC isolates, bioinformatically selected potential surface-exposed pathovar-specific antigens conserved in more than 40% of the genomes (n = 118), and assembled the representative proteins onto microarrays, complemented with known or putative colonization factor subunit molecules (n = 52) and toxin subunits. These arrays were then used to interrogate samples from individuals with acute symptomatic ETEC infections. Surprisingly, in this approach, we found that immune responses were largely constrained to a small number of antigens, including individual colonization factor antigens and EtpA, an extracellular adhesin. In a Bangladeshi cohort of naturally infected children <2 years of age, both EtpA and a second antigen, EatA, elicited significant serologic responses that were associated with protection from symptomatic illness. In addition, children infected with ETEC isolates bearing either etpA or eatA genes were significantly more likely to develop symptomatic disease. These studies support a role for antigens not presently targeted by vaccines (noncanonical) in virulence and the development of adaptive immune responses during ETEC infections. These findings may inform vaccine design efforts to complement existing approaches.

Risk factors for transmission of carbapenem-resistant Enterobacterales to healthcare personnel gloves and gowns in the USA.

BACKGROUND: Hospitals are sources for acquisition of carbapenem-resistant Entero-bacterales (CRE), and it is believed that the contamination of healthcare personnel (HCP) hands and clothing play a major role in patient-to-patient transmission of antibiotic-resistant bacteria. AIM: The aim of this study was to determine which HCP types, HCP-patient interactions, and patient characteristics are associated with greater transmission of CRE to HCP gloves and gowns in the hospital. METHODS: This was a prospective observational cohort study that enrolled patients with recent surveillance or clinical cultures positive for CRE at five hospitals in four states in the USA. HCP gloves and gown were cultured after patient care. Samples were also obtained from patients' stool, perianal area, and skin of the chest and arm to assess bacterial burden. FINDINGS: Among 313 CRE-colonized patients and 3070 glove and gown cultures obtained after patient care, HCP gloves and gowns were found to be contaminated with CRE 7.9% and 4.3% of the time, respectively. Contamination of either gloves or gowns occurred in 10.0% of interactions. Contamination was highest (15.3%) among respiratory therapists (odds ratio: 3.79; 95% confidence interval: 1.61-8.94) and when any HCP touched the patient (1.52; 1.10-2.12). Associations were also found between CRE transmission to HCP gloves or gown and: being in the intensive care unit, having a positive clinical culture, and increasing bacterial burden on the patient. CONCLUSION: CRE transmission to HCP gloves and gown occurred frequently. These findings may inform evidence-based policies about what situations and for which patients contact precautions are most important.

Identification of DNA sequences from a second pathogenicity island of uropathogenic Escherichia coli CFT073: probes specific for uropathogenic populations.

Uropathogenic Escherichia coli is the leading cause of urinary tract infection and hospital visits in North America. Cystitis and acute pyelonephritis, infection of the bladder and kidney, respectively, are the two most common syndromes encountered in patients with urinary tract infection. We sequenced and annotated 71,684 bases of a previously unidentified pathogenicity-associated island (PAI) from E. coli strain CFT073. This PAI contained 89 open-reading frames encoding a pap operon, iron-regulated genes, mobile genetic elements, and a large proportion of unknown or unidentified open-reading frames. Dot blot analysis with 11 DNA sequences from this PAI demonstrated that 7 sequences were more prevalent among uropathogens: 2 probes were more prevalent among cystitis and pyelonephritis isolates, 2 among pyelonephritis isolates only, and 3 among cystitis isolates only than among fecal isolates. These data suggest that groups of uropathogens have genetic differences that may be responsible for the different clinical outcomes.

Repression of bacterial motility by a novel fimbrial gene product.

Proteus mirabilis is a common uropathogen in patients with long-term catheterization or with structural or functional abnormalities in the urinary tract. The mannose-resistant, Proteus-like (MR/P) fimbriae and flagellum are among virulence factors of P.mirabilis that contribute to its colonization in a murine model of ascending urinary tract infection. mrpJ, the last of nine genes of the mrp operon, encodes a 107 amino acid protein that contains a putative helix-turn-helix domain. Using transcriptional lacZ fusions integrated into the chromosome and mutagenesis studies, we demonstrate that MrpJ represses transcription of the flagellar regulon and thus reduces flagella synthesis when MR/P fimbriae are produced. The repression of flagella synthesis by MrpJ is confirmed by electron microscopy. However, a gel mobility shift assay indicates that MrpJ does not bind directly to the regulatory region of the flhDC operon. The isogenic mrpJ null mutant of wild-type P.mirabilis strain HI4320 is attenuated in the murine model. Our data also indicate that PapX encoded by a pap (pyelonephritis- associated pilus) operon of uropathogenic Escherichia coli is a functional homolog of MrpJ.

Helicobacter pylori from asymptomatic hosts expressing heptoglycan but lacking Lewis O-chains: Lewis blood-group O-chains may play a role in Helicobacter pylori induced pathology.

Helicobacter pylori is a widespread Gram-negative bacterium responsible for the onset of various gastric pathologies and cancers in humans. A familiar trait of H. pylori is the production of cell-surface lipopolysaccharides (LPSs; O-chain --> core --> lipid A) with O-chain structures analogous to some mammalian histo-blood-group antigens, those being the Lewis determinants (Lea, Leb, Lex, sialyl Lex, Ley) and blood groups A and linear B. Some of these LPS antigens have been implicated as autoimmune, adhesion, and colonization components of H. pylori pathogenic mechanisms. This article describes the chemical structures of LPSs from H. pylori isolated from subjects with no overt signs of disease. Experimental data from chemical- and spectroscopic-based studies unanimously showed that these H. pylori manufactured extended heptoglycans composed of 2- and 3-linked D-glycero-alpha-D-manno-heptopyranose units and did not express any blood-group O-antigen chains. The fact that another H. pylori isolate with a similar LPS structure was shown to be capable of colonizing mice indicates that H. pylori histo-blood-group structures are not an absolute prerequisite for colonization in the murine model also. The absence of O-chains with histo-blood groups may cause H. pylori to become inept in exciting an immune response. Additionally, the presence of elongated heptoglycans may impede exposure of disease-causing outer-membrane antigens. These factors may render such H. pylori incapable of creating exogenous contacts essential for pathogenesis of severe gastroduodenal diseases and suggest that histo-blood groups in the LPS may indeed play a role in inducing a more severe H. pylori pathology.

Lewis antigen expression by Helicobacter pylori.

Although Helicobacter pylori express Lewis antigens as a component in the lipopolysaccharide, their role in the infectious process is not well understood. Lewis antigen expression with growth phase was investigated, as well as the distribution of Lewis antigens among isolates from asymptomatic and symptomatic individuals. Lewis antigens are expressed by H. pylori in a growth phase-dependent manner, with the greatest expression occurring in the logarithmic phase of growth. As growth proceeds, an increasing amount of Lewis antigens are shed into the culture supernatant. Lewis antigen expression among H. pylori isolates from asymptomatic individuals is characterized by an absence of type I Lewis antigens, a decrease in Le(x) expression, and an increase in nontypeable H. pylori, as compared with that among H. pylori isolates from symptomatic patients. The data support a role for Lewis antigens in the pathogenesis associated with symptomatic H. pylori infection in colonized individuals.

Synthesis of mono- and di-fucosylated type I Lewis blood group antigens by Helicobacter pylori.

The identification of Helicobacter pylori isolates that expresses exclusively type I Lewis antigens is necessary to determine the biosynthetic pathway of these antigens. Fast-atom bombardment MS provides evidence that the H. pylori isolate UA1111 expresses predominantly Leb, with H type I and Lea in lesser amounts. Cloning and expression of the H. pylori fucosyltransferases (FucTs) allow comparisons with previously identified H. pylori enzymes and determination of the enzyme specificities. Although all FucTs, one alpha(1,2) FucT and two alpha(1,3/4) FucTs, appear to be functional in this isolate, their activities are lower and enzyme specificities are different to other H. pylori FucTs previously characterized. Studies of the cloned enzyme activities and mutational analysis indicate that Lea acts as the substrate for the synthesis of Leb. This is different from the human Leb biosynthetic pathway, but analogous to the biosynthetic pathway utilized by H. pylori for the production of Ley.

Lewis antigens in Helicobacter pylori: biosynthesis and phase variation.

The lipopolysaccharides (LPS) of most Helicobacter pylori strains contain complex carbohydrates known as Lewis antigens that are structurally related to the human blood group antigens. Investigations on the genetic determinants involved in the biosynthesis of Lewis antigens have led to the identification of the fucosyltransferases of H. pylori, which have substrate specificities distinct from the mammalian fucosyltransferases. Compared with its human host, H. pylori utilizes a different pathway to synthesize the difucosylated Lewis antigens, Lewis y. and Lewis b. Unique features in the H. pylori fucosyltransferase genes, including homopolymeric tracts mediating slipped-strand mispairing and the elements regulating translational frameshifting, enable H. pylori to produce variable LPS epitopes on its surface. These new findings have provided us with a basis to further examine the roles of molecular mimicry and phase variation of H. pylori Lewis antigen expression in both persistent infection and pathogenesis of this important human gastric pathogen.

Lewis antigen expression and stability in Helicobacter pylori isolated from serial gastric biopsies.

The expression of Lewis antigens by the gastric pathogen Helicobacter pylori in serial biopsy isolates was investigated to assess antigen distribution and stability. A total of 26 asymptomatic subjects were given various doses of 3' sialyllactose for up to 56 days. Gastric biopsies were performed during the dosing period, as well as 30 days after dosing, which provided 127 H. pylori isolates that were examined by use of ELISA and immunoblot. A large proportion of subjects (14/26) yielded sequential H. pylori isolates, which appeared genetically identical but had variable Lewis antigen expression. The proportion of subjects with H. pylori isolates not expressing any Lewis antigens was greater than that previously reported (10/26). Thus, the expression of the Lewis antigens by H. pylori does not appear to be a requirement for colonization, whereas the antigen expression after human infection is more variable than the previously reported rate observed with in vitro cultures.

Cloning and characterization of the alpha(1,3/4) fucosyltransferase of Helicobacter pylori.

The gastric pathogen Helicobacter pylori can express the histo blood group antigens, which are on the surface of many human cells. Most H. pylori strains express the type II carbohydrates, Lewis X and Y, whereas a small population express the type I carbohydrates, Lewis A and B. The expression of Lewis A and Lewis X, as in the case of H. pylori strain UA948, requires the addition of fucose in alpha1,4 and alpha1,3 linkages to type I or type II carbohydrate backbones, respectively. This work describes the cloning and characterization of a single H. pylori fucosyltransferase (FucT) enzyme, which has the ability to transfer fucose to both of the aforementioned linkages in a manner similar to the human fucosyltransferase V (Fuc-TV). Two homologous copies of the fucT gene have been identified in each of the genomes sequenced. The characteristic adenosine and cytosine tracts in the amino terminus and repeated regions in the carboxyl terminus are present in the DNA encoding the two UA948fucT genes, but these genes also contain differences when compared with previously identified H. pylori fucTs. The UA948fucTa gene encodes an approximately 52-kDa protein containing 475 amino acids, whereas UA948fucTb does not encode a full-length FucT protein. In vitro, UA948FucTa appears to add fucose with a greater than 5-fold preference for type II chains but still retains significant activity using type I acceptors. The addition of the fucose to the type II carbohydrate acceptors, by UA948FucTa, does not appear to be affected by fucosylation at other sites on the carbohydrate acceptor, but the rate of fucose transfer is affected by terminal fucosylation of type I acceptors. Through mutational analysis we demonstrate that only FucTa is active in this H. pylori isolate and that inactivation of this enzyme eliminates expression of all Lewis antigens.

Lipopolysaccharide structures of Helicobacter pylori genomic strains 26695 and J99, mouse model H. pylori Sydney strain, H. pylori P466 carrying sialyl Lewis X, and H. pylori UA915 expressing Lewis B classification of H. pylori lipopolysaccharides into glycotype families.

This study describes the molecular makeup of the cell-wall lipopolysaccharides (LPSs) (O-chain polysaccharide-->core oligosaccharide-->lipid A) from five Helicobacter pylori strains: H. pylori 26695 and J99, the complete genome sequences of which have been published, the established mouse model Sydney strain (SS1), and the symptomatic strains P466 and UA915. All chemical and serological experiments were performed on the intact LPSs. H. pylori 26695 and SS1 possessed either a low-Mr semi-rough-form LPS carrying mostly a single Ley type-2 blood-group determinant in the O-chain region covalently attached to the core oligosaccharide or a high-Mr smooth-form LPS, as did strain J99, with an elongated partially fucosylated type-2 N-acetyllactosamine (polyLacNAc) O-chain polymer, terminated mainly by a Lex blood-group determinant, connected to the core oligosaccharide. In the midst of semi-rough-form LPS glycoforms, H. pylori 26695 and SS1 also expressed in the O-chain region a difucosylated antigen, alpha-L-Fucp(1-3)-alpha-L-Fucp(1-4)-beta-D-GlcpNAc, and the cancer-cell-related type-1 or type-2 linear B-blood-group antigen, alpha-D-Galp(1-3)-beta-D-Galp(1-3 or 4)-beta-D-GlcpNAc. The LPS of H. pylori strain P466 carried the cancer-associated type-2 sialyl Lex blood-group antigen, and the LPS from strain UA915 expressed a type-1 Leb blood-group unit. These findings should aid investigations that focus on identifying and characterizing genes responsible for LPS biosynthesis in genomic strains 26695 and J99, and in understanding the role of H. pylori LPS in animal model studies. The LPSs from the H. pylori strains studied to date were grouped into specific glycotype families.

Molecular genetic basis for the variable expression of Lewis Y antigen in Helicobacter pylori: analysis of the alpha (1,2) fucosyltransferase gene.

Helicobacter pylori lipopolysaccharides (LPS) express human oncofetal antigens Lewis X and Lewis Y. The synthesis of Lewis Y involves the actions of alpha (1,3) and alpha (1,2) fucosyltransferases (FucTs). Here, we report the molecular cloning and characterization of genes encoding H. pylori alpha (1,2) FucT (Hp fucT2) from various H. pylori strains. We constructed Hp fucT2 knock-out mutants and demonstrated the loss of Lewis Y production in these mutants by enzyme-linked immunosorbent assay (ELISA) and immunoelectron microscopy. The Hp fucT2 gene contains a hypermutable sequence [poly (C) and TAA repeats], which provides a possibility of frequent shifting into and out of coding frame by a polymerase slippage mechanism. Thus, the Hp fucT2 gene displays two major genotypes, consisting of either a single full-length open reading frame (ORF; as in the strain UA802) or truncated ORFs (as in the strain 26695). In vitro expression of Hp fucT2 genes demonstrated that both types of the gene have the potential to produce the full-length protein. The production of the full-length protein by the 26695 fucT2 gene could be attributed to translational-1 frameshifting, as a perfect translation frameshift cassette resembling that of the Escherichia coli dnaX gene is present. Examination of the strain UA1174 revealed that its fucT2 gene has a frameshifted ORF at the DNA level, which cannot be compensated by translation frameshifting, accounting for its Lewis Y off phenotype. In another strain, UA1218, the fucT2 gene is apparently turned off because of the loss of its promoter. Based on these data, we proposed a model for the variable expression of Lewis Y by H. pylori, in which regulation at the level of replication slippage (mutation), transcription and translation of the fucT2 gene may all be involved.

Lack of correlation between Lewis antigen expression by Helicobacter pylori and gastric epithelial cells in infected patients.

BACKGROUND & AIMS: Lewis antigens are expressed by both human gastric epithelial tissue and Helicobacter pylori. We examined Lewis antigens expressed by gastric epithelium and by H. pylori isolated from the corresponding biopsy tissue. METHODS: H. pylori Lewis expression was determined by enzyme immunoassays, and immunoelectron microscopy was used to confirm the Lewis antigens on some H. pylori cells and in some biopsy specimens. Histopathology using identical monoclonal antibodies specific for Lewis A, B, X, and Y antigens was used to detect these antigens in 24 gastric biopsy specimens. RESULTS: We identified Lewis Y in 100%, Lewis X and Lewis B in 95.8%, and Lewis A in 87.5% of biopsy specimens. In H. pylori, 87.5% expressed Lewis Y, 79.2% Lewis X, and 4.2% (one strain) Lewis B. No Lewis A was detected. Antibody specific for Lewis X labeled the bacteria and associated adhesion pedestal. The cagA gene was present in 92% of strains. CONCLUSIONS: There was no direct relationship between Lewis antigen expression by H. pylori and gastric epithelial cells in infected patients. Expression of Lewis X and Lewis Y by H. pylori suggests the possibility of their requirement for establishment and/or maintenance of infection. An immunoelectron micrograph of H. pylori interaction with the gastric epithelial adhesion pedestal suggests a tentative role for Lewis X in the adhesion process.

Simultaneous expression of type 1 and type 2 Lewis blood group antigens by Helicobacter pylori lipopolysaccharides. Molecular mimicry between h. pylori lipopolysaccharides and human gastric epithelial cell surface glycoforms.

Previous structural investigations performed on the lipopolysaccharides (LPSs) from the human gastric pathogen Helicobacter pylori have revealed that these cell surface glycan molecules express type 2 partially fucosylated, glucosylated, or galactosylated N-acetyllactosamine O antigen chains (O-chains) of various lengths, which may or may not be terminated at the nonreducing end by Lewis X (Lex) and/or Ley blood group epitopes in mimicry of human cell surface glycoconjugates and glycolipids. Subsequently, serological experiments with commercially available Lewis-specific monoclonal antibodies also have recognized the presence of Lex and Ley blood group antigens in H. pylori but, in addition, have indicated the presence of type 1 chain Lea, Leb, and Led (H-type 1) blood group epitopes in some H. pylori strains. To confirm their presence, structural studies and additional serological experiments were undertaken on H. pylori strains suspected of carrying type 1 chain epitopes. These investigations revealed that the O-chain region of H. pylori strain UA948 carried both Lea (type 1) and Lex (type 2) blood group determinants. The O-chain from H. pylori UA955 LPS expressed the terminal Lewis disaccharide (type 1 chain) and Lex and Ley antigens (type 2). The O-chain of H. pylori J223 LPS carried the type 1 chain precursor Lec, the H-1 epitope (Led, type 1 chain) and an elongated nonfucosylated type 2 N-acetyllactosamine chain (i antigen). Thus, O-chains from H. pylori LPSs can also express fucosylated type 1 sequences, and the LPS from a single H. pylori strain may carry O-chains with type 1 and 2 Lewis blood groups simultaneously. That monoclonal antibodies putatively specific for the Leb determinant can detect glycan substructures (Le disaccharide, Lec, and Led) of Leb indicates their nonspecificity. The expression of both type 1 and 2 Lewis antigens by H. pylori LPSs mimics the cell surface glycomolecules present in both the gastric superficial (which expresses mainly type 1 determinants) and the superficial and glandular epithelium regions (both of which express predominantly type 2 determinants). Therefore, each H. pylori strain may have a different niche within the gastric mucosa, and each individual LPS blood group antigen may have a dissimilar role in H. pylori adaptation.