28 research outputs found

    Study of avidity of antigen-specific antibody as a means of understanding development of long-term immunological memory after Vibrio cholerae O1 infection

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    The avidity of antibodies to specific antigens and the relationship of avidity to memory B cell responses to these antigens have not been studied in patients with cholera or those receiving oral cholera vaccines. We measured the avidity of antibodies to cholera toxin B subunit (CTB) and Vibrio cholerae O1 lipopolysaccharide (LPS) in Bangladeshi adult cholera patients (n = 30), as well as vaccinees (n = 30) after administration of two doses of a killed oral cholera vaccine. We assessed antibody and memory B cell responses at the acute stage in patients or prior to vaccination in vaccinees and then in follow-up over a year. Both patients and vaccinees mounted CTB-specific IgG and IgA antibodies of high avidity. Patients showed longer persistence of these antibodies than vaccinees, with persistence lasting in patients up to day 270 to 360. The avidity of LPS-specific IgG and IgA antibodies in patients remained elevated up to 180 days of follow-up. Vaccinees mounted highly avid LPS-specific antibodies at day 17 (3 days after the second dose of vaccine), but the avidity waned rapidly to baseline by 30 days. We examined the correlation between antigen-specific memory B cell responses and avidity indices for both antigens. We found that numbers of CTB- and LPS-specific memory B cells significantly correlated with the avidity indices of the corresponding antibodies (P < 0.05; Spearman's ρ = 0.28 to 0.45). These findings suggest that antibody avidity after infection and immunization is a good correlate of the development and maintenance of memory B cell responses to Vibrio cholerae O1 antigens

    A Complete Pathway Model for Lipid A Biosynthesis in Escherichia coli.

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    Lipid A is a highly conserved component of lipopolysaccharide (LPS), itself a major component of the outer membrane of Gram-negative bacteria. Lipid A is essential to cells and elicits a strong immune response from humans and other animals. We developed a quantitative model of the nine enzyme-catalyzed steps of Escherichia coli lipid A biosynthesis, drawing parameters from the experimental literature. This model accounts for biosynthesis regulation, which occurs through regulated degradation of the LpxC and WaaA (also called KdtA) enzymes. The LpxC degradation signal appears to arise from the lipid A disaccharide concentration, which we deduced from prior results, model results, and new LpxK overexpression results. The model agrees reasonably well with many experimental findings, including the lipid A production rate, the behaviors of mutants with defective LpxA enzymes, correlations between LpxC half-lives and cell generation times, and the effects of LpxK overexpression on LpxC concentrations. Its predictions also differ from some experimental results, which suggest modifications to the current understanding of the lipid A pathway, such as the possibility that LpxD can replace LpxA and that there may be metabolic channeling between LpxH and LpxB. The model shows that WaaA regulation may serve to regulate the lipid A production rate when the 3-deoxy-D-manno-oct-2-ulosonic acid (KDO) concentration is low and/or to control the number of KDO residues that get attached to lipid A. Computation of flux control coefficients showed that LpxC is the rate-limiting enzyme if pathway regulation is ignored, but that LpxK is the rate-limiting enzyme if pathway regulation is present, as it is in real cells. Control also shifts to other enzymes if the pathway substrate concentrations are not in excess. Based on these results, we suggest that LpxK may be a much better drug target than LpxC, which has been pursued most often

    Toll-like receptor 7 is reduced in severe asthma and linked to altered microRNA profile

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    RATIONALE:Asthma is one of the commonest chronic diseases worldwide and severe asthma sufferers experience recurrent exacerbations. Exacerbations are predominantly viral-associated and have been linked to defective airway interferon responses. Ascertaining the molecular mechanisms underlying this deficiency is a major research goal in order to identify new therapeutic targets.OBJECTIVES:We investigated the hypothesis that reduced toll-like receptor (TLR) 7-derived signalling was driving the impaired interferon responses to rhinovirus by asthmatic alveolar macrophages (AMs) and molecular mechanisms underlying this deficiency were explored.METHODS:AMs were recovered from bronchoalveolar lavage from healthy and severe asthma subjects. Expression of pattern-recognition receptors and microRNAs was evaluated by quantitative PCR and western blotting. A TLR7-luciferase reporter construct was created to evaluate binding of microRNAs to the 3'UTR of TLR7. Interferon production was measured by quantitative PCR and ELISA.MEASUREMENTS AND MAIN RESULTS:The expression of TLR7 was significantly reduced in severe asthma AMs and was associated with reduced rhinovirus and imiquimod-induced interferon responses by these cells compared to healthy AMs. Severe asthma AMs also expressed increased levels of 3 microRNAs that we showed are able to directly reduce TLR7 expression. Ex vivo knock-down of these microRNAs restored TLR7 expression with concomitant augmentation of virus-induced interferon production
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