17 research outputs found
<i>C</i>. <i>parvum</i> priming enhances Th1-type cytokine responses to re-challenge in protein malnourished mice.
<p>(A) Ileal inflammatory mediators and chemokines and (B) cytokines measured three days after 10<sup>7</sup> <i>C</i>. <i>parvum</i> challenge in previously uninfected (PBS) compared with mice primed with 10<sup>6</sup> <i>C</i>. <i>parvum</i> (Cp10<sup><i>6</i></sup>) 20 days prior to re-challenge. *<i>P</i><0.05, **<i>P</i><0.01, ***<i>P</i><0.001.</p
<i>C</i>. <i>parvum</i> priming leads to sustained changes in ileal tissue chemokine and cytokine profiles during protein malnutrition.
<p>Mice were conditioned on PD for 5 days prior to infection with 10<sup>6</sup> <i>C</i>. <i>parvum</i> (Cp10<sup>6</sup>). Luminex was performed for measurement of chemokines and cytokines in ileal tissues at. day 3 (D3) and day 23 (D23) post challenge compared to uninfected controls (PBS) (n = 3-4/group). (A) Primary <i>C</i>. <i>parvum</i> infection led to increases in CXCL9, CXCL10, CCL-3, CCL-5, and CCL11 on D3. On D23, TNFα, IL1β, and IL-8 were diminished in infected mice relative to uninfected controls, however, CCL-5 continued to be elevated and other chemokines had returned to baseline. (B) Only IL12p40 and IL-13 were modestly elevated three days after primary <i>C</i>. <i>parvum</i> challenge. There was a relative decrease in all Th2-type cytokines through 23 days post-<i>C</i>. <i>parvum</i> compared with uninfected controls. (n = 3-4/group). *<i>P</i><0.05 for PBS vs Cp10<sup>6</sup> as indicated; #<i>P</i><0.05 for Cp10<sup>6</sup> D3 vs Cp10<sup>6</sup> D23 as indicated.</p
Protein malnutrition alters basal immune responses to primary <i>C</i>. <i>parvum</i> exposure, but secondary responses are intact.
<p>Immunologic responses to two different recombinant <i>Cryptosporidium</i> sporozoite antigens (CApy and Cp15) were performed at 13–15 days post <i>C</i>. <i>parvum</i> challenge in mice fed either control-diet (<i>C</i>. <i>parvum</i><sup>CD</sup>) or protein-deficient diet (<i>C</i>. <i>parvum</i><sup>pd</sup>) and results were compared with naïve age and diet-matched uninfected controls (PBS<sup>CD</sup> and PBS<sup>pd</sup>). Mice began respective diets 12 days prior to <i>C</i>. <i>parvum</i> challenge and remained on the same diets post-challenge. (A) Cytokine secretion in splenocytes of naïve (uninfected) CD or PD-fed mic after stimulation with <i>Cryptosporidium</i> antigens. (B) Serum antibody production as anti-CApy or anti-Cp15 IgG titer (<i>*P<</i>0.05). (C) Cytokines secreted after CApy or Cp15 antigen stimulation in (C) mesenteric lymph nodes. (D) Cytokine secretion in splenocytes expressed as fold change relative to CD-fed uninfected controls. (*<i>P</i><0.05 as indicated). Data is representative of pooled individual responses from two separate tissue harvests (n = 4-5/group).</p
Schematic of non-specific (<i>S</i>. Typhi and CpG) and specific (<i>C</i>. <i>parvum</i> priming) mucosal exposures that modulate host immunity and protect against cryptosporidiosis during malnutrition.
<p>Strategies to enhance immune defenses against <i>Cryptosporidium</i> infection during malnutrition were investigated in a protein deficient murine model that replicates clinical features of childhood cryptosporidiosis. Whereas the well-nourished host (black) clears <i>Cryptosporidium</i> with little evidence of a secondary immune response (dark blue), mucosal vaccination with <i>Cryptosporidium</i> antigens expressed in an <i>S</i>. Typhi vector can elicit strongly boosted IFNγ-predominant immune responses to subsequent challenge (light blue). Vaccine attenuates the mild disease caused by <i>Cryptosporidium</i> in well-nourished hosts. In protein malnourished hosts (light grey) there is ongoing depletion of mucosal lymphocytes including Th1-type effectors. This results in enhanced disease after primary <i>C</i>. <i>parvum</i> challenge with a response characterized by decreased IFNγ but increased IL13 and tendency toward Th2-type cytokines (red). Unlike in nourished hosts, vaccine does not further enhance IFNγ to primary <i>C</i>. <i>parvum</i> challenge, but rather the <i>S</i>. Typhi vector alone drives increased IL17A and partially attenuates disease severity similar to the TLR9 agonist CpG (yellow). <i>C</i>. <i>parvum</i> priming, however, leverages a robust secondary Th1-type response to <i>C</i>. <i>parvum</i> during protein malnutrition, and even at low-doses in this model establishes a mucosal imprinted population of CD8<sup>+</sup> T-cells along with protective immunity to subsequent re-challenge (dark grey).</p
Cross-modulation of pathogen-specific pathways enhances malnutrition during enteric co-infection with <i>Giardia lamblia</i> and enteroaggregative <i>Escherichia coli</i>
<div><p>Diverse enteropathogen exposures associate with childhood malnutrition. To elucidate mechanistic pathways whereby enteric microbes interact during malnutrition, we used protein deficiency in mice to develop a new model of co-enteropathogen enteropathy. Focusing on common enteropathogens in malnourished children, <i>Giardia lamblia</i> and enteroaggregative <i>Escherichia coli</i> (EAEC), we provide new insights into intersecting pathogen-specific mechanisms that enhance malnutrition. We show for the first time that during protein malnutrition, the intestinal microbiota permits persistent <i>Giardia</i> colonization and simultaneously contributes to growth impairment. Despite signals of intestinal injury, such as IL1α, <i>Giardia</i>-infected mice lack pro-inflammatory intestinal responses, similar to endemic pediatric <i>Giardia</i> infections. Rather, <i>Giardia</i> perturbs microbial host co-metabolites of proteolysis during growth impairment, whereas host nicotinamide utilization adaptations that correspond with growth recovery increase. EAEC promotes intestinal inflammation and markers of myeloid cell activation. During co-infection, intestinal inflammatory signaling and cellular recruitment responses to EAEC are preserved together with a <i>Giardia</i>-mediated diminishment in myeloid cell activation. Conversely, EAEC extinguishes markers of host energy expenditure regulatory responses to <i>Giardia</i>, as host metabolic adaptations appear exhausted. Integrating immunologic and metabolic profiles during co-pathogen infection and malnutrition, we develop a working mechanistic model of how cumulative diet-induced and pathogen-triggered microbial perturbations result in an increasingly wasted host.</p></div
Viable <i>C</i>. <i>parvum</i> priming provides greater protection against re-challenge than either CpG-ODN or <i>S</i>. Typhi.
<p>(A, B) Comparison of protective immunity following priming with either viable and heat-inactivated (Δ) <i>C</i>. <i>parvum</i> 10<sup>6</sup>. (A) Growth of PD-fed mice through 23 days post-priming with either 4x10<sup>6</sup> viable (<i>C</i>. <i>parvum</i>) or 4x10<sup>6</sup> heat-inactivated (Δ<i>C</i>. <i>parvum</i>). Mice were challenged with viable 4<i>x</i>10<sup>7</sup> <i>C</i>. <i>parvum</i> oocysts on day 20 post-priming. *<i>P</i><0.05 for Δ<i>C</i>. <i>parvum-C</i>. <i>parvum</i> vs. <i>C</i>. <i>parvum</i>-<i>C</i>. <i>parvum</i> (d3 and d23); ^^<i>P</i><0.01 for <i>C</i>. <i>parvum</i>-PBS vs PBS-<i>C</i>. <i>parvum</i> (d23); <sup>###</sup><i>P</i><0.001 for <i>C</i>. <i>parvum</i>-<i>C</i>. <i>parvum</i> vs. PBS-<i>C</i>. <i>parvum</i> (d23). (B) RT-PCR of <i>Cryptosporidium</i> stool shedding on experimental days 21 and 23 (day 1 and day 3 after <i>C</i>. <i>parvum</i> 10<sup>7</sup> challenge, respectively). *<i>P</i><0.05 and *<i>P</i><0.01 for <i>C</i>. <i>parvum</i>-<i>C</i>. <i>parvum</i> vs either PBS-<i>C</i>. <i>parvum</i> or Δ<i>C</i>. <i>parvum-C</i>. <i>parvum</i>. (C,D) 3-week-old C57Bl/6 mice were conditioned on PD for 7 days prior to orogastric inoculation with 10<sup>6</sup> <i>C</i>. <i>parvum</i>, intranasal (i.n.) 10<sup>9</sup> <i>S</i>. Typhi 908<i>htr</i>, i.n. CpG-ODN 1668 (100 mcg), or PBS (100 mcl) as indicated (n = 10/group). On day 21, mice were re-challenged with either PBS or <i>C</i>. <i>parvum</i> 10<sup>7</sup>. (C) Growth as percentage of initial weight, normalized to the day of 10<sup>7</sup> <i>C</i>. <i>parvum</i> challenge (Day 0). The group labeled “All uninfected” includes animals that received either PBS during both inoculations, CpG followed by PBS, or <i>S</i>. Typhi followed by PBS (n = 5/group x 3 = 15) given all three groups grew similarly and were never exposed to <i>C</i>. <i>parvum</i> (<a href="http://www.plosntds.org/article/info:doi/10.1371/journal.pntd.0004820#pntd.0004820.s004" target="_blank">S4 Fig</a>). *<i>P</i><0.05, **<i>P</i><0.01, ***<i>P</i><0.001 for PBS–<i>C</i>.<i>p</i>.10<sup>7</sup> (red) vs <i>C</i>.<i>p</i>.10<sup>6-</sup><i>C</i>.<i>p</i>.10<sup>7</sup>, ^<i>P</i><0.05 for CpG-<i>C</i>.<i>p</i>.10<sup>7</sup> (yellow) vs <i>C</i>.<i>p</i>.10<sup>6-</sup><i>C</i>.<i>p</i>.10<sup>7</sup>, and <sup>#</sup><i>P</i><0.05 for <i>S</i>. Typhi-<i>C</i>.<i>p</i>.10<sup>7</sup> (green) vs <i>C</i>.<i>p</i>.10<sup>6-</sup><i>C</i>.<i>p</i>.10<sup>7</sup>). Horizontal lines designate significant differences at <i>P</i><0.05 between CpG-<i>C</i>.<i>p</i>.10<sup>7</sup> (yellow), <i>S</i>. Typhi-<i>C</i>.<i>p</i>.10<sup>7</sup> (green), and PBS-<i>C</i>.<i>p</i>.10<sup>7</sup> (red) vs. All uninfected controls, respectively. (D) Parasite fecal shedding in serial fecal pellets collected on indicated experimental days post <i>C</i>. <i>parvum</i> 10<sup>7</sup> challenge. *<i>P</i><0.05 for PBS–<i>C</i>.<i>p</i>.10<sup>7</sup> vs. <i>C</i>.<i>p</i>.10<sup>6-</sup><i>C</i>.<i>p</i>.10<sup>7</sup>, ^<i>P</i><0.05 for CpG-<i>C</i>.<i>p</i>.10<sup>7</sup> vs <i>C</i>.<i>p</i>.10<sup>6-</sup><i>C</i>.<i>p</i>.10<sup>7</sup>, and <sup>#</sup><i>P</i><0.05 for <i>S</i>. Typhi-<i>C</i>.<i>p</i>.10<sup>7</sup> vs <i>C</i>.<i>p</i>.10<sup>6-</sup><i>C</i>.<i>p</i>.10<sup>7</sup>. Data is representative of two replicate experiments.</p
Protein malnutrition interferes with vaccine-boosted immunity, but the <i>S</i>. Typhi vector improves recovery after <i>C</i>. <i>parvum</i> challenge.
<p>(A) Timeline for immunization, growth monitoring, infection, and analysis of immune responses. 21 day-old mice acclimated for 4 days prior to weight-matched randomization (n = 8-19/group). Intranasal immunization with <i>S</i>. <i>enterica</i> Typhi 908<i>htr</i> vector expressing either of two recombinant sporozoite antigens, ClyA-Cp15 (<i>S</i>. Typhi<sup>Cp15</sup> (aqua)) or ClyA-CApy (<i>S</i>. Typhi<sup>CApy</sup> (blue)) was administered at two-week intervals. The <i>S</i>. Typhi vector alone (<i>S</i>. Typhi (green)) and a PBS-only (red) treatment served as a double-sham control. Intramuscular injection with rCp15 (<i>S</i>. Typhi<sup>Cp15</sup>), rCApy (<i>S</i>. Typhi<sup>CApy</sup>), the inert NUS peptide (for <i>S</i>. Typhi), or PBS-’sham’ (for PBS only group) combined with 1:1 alum adjuvant occurred two weeks after the second intranasal immunization. Serial weights (*) were obtained throughout the vaccination protocol (<a href="http://www.plosntds.org/article/info:doi/10.1371/journal.pntd.0004820#pntd.0004820.s001" target="_blank">S1 Fig</a>). On day 107 (9 weeks after <i>S</i>. Typhi exposure), mice were transitioned to either PD or CD diets (n = 4-10/group) and continued on respective diets throughout the remainder of the experiment. Mice were challenged with 5x10<sup>7</sup> <i>C</i>. <i>parvum</i> (<i>Cp</i>) on day 119 and followed for 13–15 days post-challenge. (B) Serum geometric mean IgG titers (GMT) in <i>C</i>. <i>parvum</i> challenged groups. (C) IFN-γ and (D) IL-17A cytokine secretion recall responses to homologous vaccinogen as indicated. For (B-D), <i>*P</i><0.05, **<i>P</i><0.01, ***<i>P</i><0.001, One-way ANOVA, Tukey post-test analysis, <sup>#</sup> <i>P</i><0.05 by Student’s <i>t</i>-test. (E) Growth as percentage of weight change on the day of <i>C</i>. <i>parvum</i> infection beginning on the day of transition to either CD (left) or PD (right) diets. (left: *<i>P</i><0.05, <i>S</i>. Typhi<sup>Cp15</sup> vs PBS-<i>Cp</i>; right: colored bars indicate <i>P</i><0.05 for PBS-<i>Cp</i> (red), <i>S</i>. Typhi-<i>Cp</i> (green), <i>S</i>. Typhi<sup>Cp15</sup> (aqua), and <i>S</i>. Typhi<sup>CApy</sup> (blue) vs. uninfected controls, *<i>P</i><0.05 for individual vaccine groups [<i>S</i>. Typhi-<i>Cp</i> (green), <i>S</i>. Typhi<sup>Cp15</sup> (aqua), and <i>S</i>. Typhi<sup>CApy</sup> (blue)] vs. PBS-<i>Cp</i>. (F) Parasite shedding for infected groups: PBS (red), <i>S</i>. Typhi (green, <i>S</i>. Typhi<sup>Cp15</sup> (aqua), and <i>S</i>. Typhi<sup>CApy</sup> (blue). (G) Ileal villus:crypt for CD-fed (left) and PD-fed (right) mice in each <i>C</i>. <i>parvum</i> infected group or combined uninfected controls as indicated. Left: ***<i>P</i><0.001 PBS-<i>Cp</i> vs uninfected controls, <sup>###</sup><i>P</i><0.001 <i>S</i>. Typhi<sup>Cp15</sup> or <i>S</i>. Typhi<sup>CApy</sup> vs <i>S</i>. Typhi; Right: ***<i>P</i><0.001 for PBS-<i>Cp</i>, <i>S</i>. Typhi, or <i>S</i>. Typhi<sup>Cp15</sup> vs uninfected controls, <sup>###</sup><i>P</i><0.001 <i>S</i>. Typhi<sup>CApy</sup> vs PBS-<i>Cp</i>. ^<i>P</i><0.05 for PD-PBS and PD-<i>S</i>. Typhi<sup>Cp15</sup> vs DD-PBS and DD-<i>S</i>. Typhi<sup>Cp15</sup>. ns = not significant vs. uninfected controls.</p
<i>Firmicutes</i> to <i>Bacteroidetes</i> ratio.
<p><i>Firmicutes</i> to <i>Bacteroidetes</i> ratio in the colon contents (lumen) was significantly higher (ANOVA p = 0.0021, post-tests both p<0.01) in the traditional diet fed group treated with antibiotics compared with either defined nutrient diet with antibiotics.</p
Effects of nutritional status and diets on mortality, disease severity and infection burden in mice challenged with <i>C</i>. <i>difficile</i>.
<p>Effects of nutritional status and diets on mortality, disease severity and infection burden in mice challenged with <i>C</i>. <i>difficile</i>.</p
Defined Nutrient Diets Alter Susceptibility to <i>Clostridium difficile</i> Associated Disease in a Murine Model
<div><p>Background</p><p><i>Clostridium difficile</i> is a major identifiable and treatable cause of antibiotic-associated diarrhea. Poor nutritional status contributes to mortality through weakened host defenses against various pathogens. The primary goal of this study was to assess the contribution of a reduced protein diet to the outcomes of <i>C</i>. <i>difficile</i> infection in a murine model.</p><p>Methods</p><p>C57BL/6 mice were fed a traditional house chow or a defined diet with either 20% protein or 2% protein and infected with <i>C</i>. <i>difficile</i> strain VPI10463. Animals were monitored for disease severity, clostridial shedding and fecal toxin levels. Select intestinal microbiota were measured in stool and <i>C</i>. <i>difficile </i>growth and toxin production were quantified <i>ex vivo </i>in intestinal contents from untreated or antibiotic-treated mice fed with the different diets.</p><p>Results</p><p><i>C</i>. <i>difficile </i>infected mice fed with defined diets, particularly (and unexpectedly) with protein deficient diet, had increased survival, decreased weight loss, and decreased overall disease severity. <i>C</i>. <i>difficile</i> shedding and toxin in the stool of the traditional diet group was increased compared with either defined diet 1 day post infection. Mice fed with traditional diet had an increased intestinal Firmicutes to Bacteroidetes ratio following antibiotic exposure compared with either a 2% or 20% protein defined nutrient diet. <i>Ex vivo</i> inoculation of cecal contents from antibiotic-treated mice showed decreased toxin production and <i>C</i>. <i>difficile</i> growth in both defined diets compared with a traditional diet.</p><p>Conclusions</p><p>Low protein diets, and defined nutrient diets in general, were found to be protective against CDI in mice. Associated diet-induced alterations in intestinal microbiota may influence colonization resistance and clostridial toxin production in a defined nutrient diet compared to a traditional diet, leading to increased survival. However, mechanisms which led to survival differences between 2% and 20% protein defined nutrient diets need to be further elucidated.</p></div