B2 but not B1 cells can contribute to CD4+ T-cell-mediated clearance of rotavirus in SCID mice.

Studies utilizing various immunodeficient mouse models of rotavirus (RV) infection demonstrated significant roles of RV-specific secretory immunoglobulin A (IgA), CD4+ T cells, and CD8+ T cells in the clearance of RV and protection from secondary infection. Secretion of small but detectable amounts of IgA in RV-infected alphabeta T-cell receptor knockout mice (11) and distinctive anatomical localization and physiology of B1 cells suggested that B1 cells might be capable of producing RV-specific intestinal IgA in a T-cell-independent fashion and, therefore, be responsible for ablation of RV shedding. We investigated the role of B1 cells in the resolution of primary RV infection using a SCID mouse model. We found that the adoptive transfer of unseparated peritoneal exudate cells ablates RV shedding and leads to the production of high levels of RV-specific intestinal IgA. In contrast, purified B1 cells do not ablate RV shedding and do not induce a T-cell-independent or T-cell-dependent, RV-specific IgA response but do secrete large amounts of polyclonal (total) intestinal IgA. Cotransfer of mixtures of purified B1 cells and B1-cell-depleted peritoneal exudate cells differing in IgA allotypic markers also demonstrated that B2 cells (B1-cell-depleted peritoneal exudate cells) and not B1 cells produced RV-specific IgA. To our knowledge, this is the first observation that B1 cells are unable to cooperate with CD4+ T cells and produce virus-specific intestinal IgA antibody. We also observed that transferred CD4+ T cells alone are capable of resolving RV shedding, although no IgA is secreted. These data suggest that RV-specific IgA may not be obligatory for RV clearance but may protect from reinfection and that effector CD4+ T cells alone can mediate the resolution of primary RV infection. Reconstitution of RV-infected SCID mice with B1 cells results in the outgrowth of contaminating, donor CD4+ T cells that are unable to clear RV, possibly because their oligoclonal specificities may be ineffective against RV antigens.

Hypertrophy, hyperplasia, and infectious virus in gut-associated lymphoid tissue of mice after oral inoculation with simian-human or bovine-human reassortant rotaviruses.

Oral inoculation of infants with a vaccine that contains simian-human reassortant rotaviruses has been found to be a rare cause of intussusception. Because intussusception can be associated with enlargement of gut-associated lymphoid tissue, we studied the capacity of simian-human and bovine-human reassortant rotaviruses to cause lymphoid hypertrophy and hyperplasia of Peyer's patches (PP) of adult BALB/c mice. Neither hypertrophy nor hyperplasia was detected in PP after oral inoculation with simian-human or bovine-human reassortant rotaviruses. However, infectious virus was detected in PP and mesenteric lymph nodes after oral inoculation with simian, but not bovine, reassortant rotaviruses. Implications of these findings on the pathogenesis of intussusception are discussed.

Circulating rotavirus-specific antibody-secreting cells (ASCs) predict the presence of rotavirus-specific ASCs in the human small intestinal lamina propria.

Rotaviruses are the most important cause of infectious diarrhea in children throughout the world. Protection is most likely mediated by small-intestinal virus-specific IgA. However, neither fecal nor serum virus-specific IgA clearly correlates with protection against challenge. The capacity of rotavirus-specific antibodies and rotavirus-specific antibody-secreting cells (ASCs) in the circulation to predict the presence of ASCs in the intestines of children was evaluated. Mononuclear cells from intestinal biopsy samples and blood from 21 children were enriched for CD38, a marker of terminally differentiated B cells, and evaluated for the presence of virus-specific and total IgA- and IgG-secreting cells, by ELISPOT assay. Serum virus-specific IgA and IgG levels were determined by ELISA. The ratio of virus-specific to total IgA-secreting cells in the blood correlated with that found in the small, but not large, intestine. In contrast, serum rotavirus-specific IgA correlated less well with the presence of virus-specific ASCs in the small intestine.

Effect of water-based microencapsulation on protection against EDIM rotavirus challenge in mice.

We determined the capacity of microcapsules formed by the combination of sodium alginate, an aqueous anionic polymer, and spermine hydrochloride, an aqueous cationic amine, to enhance protection against rotavirus challenge in mice. Adult BALB/c mice were orally inoculated with either free or microencapsulated rotavirus (simian rotavirus strain RRV) and challenged 6 or 16 weeks later with murine rotavirus strain EDIM. Virus-specific humoral immune responses were determined at the time of challenge and 4 days after challenge by intestinal fragment culture. We found that spermine-alginate microcapsules enhanced protection against challenge 16 weeks after immunization but not 6 weeks after immunization. Quantities of virus-specific immunoglobulin A produced by small intestinal lamina propria lymphocytes were correlated with the degree of protection against challenge afforded by spermine-alginate microcapsules. Possible mechanisms by which microcapsules enhance protection against rotavirus challenge are discussed.

Relative importance of rotavirus-specific effector and memory B cells in protection against challenge.

Adult BALB/c mice were orally inoculated with murine (strain EDIM), simian (strain RRV), or bovine (strain WC3) rotavirus. Six or 16 weeks after inoculation, mice were challenged with EDIM. At the time of challenge and in the days immediately following challenge, production of rotavirus-specific immunoglobulin A (IgA), IgG, and IgM by small intestinal lamina propria lymphocytes (LPL) was determined by fragment culture, and quantities of virus-specific antibodies at the intestinal mucosal surface were determined by intestinal lavage. Mice immunized with EDIM were completely protected against EDIM challenge both 6 and 16 weeks after immunization. Protection was associated with production of high levels of IgA by LPL and detection of virus-specific IgA at the intestinal mucosal surface. In addition, animals immunized and later challenged with EDIM did not develop a boost in antibody responses, suggesting that they were also not reinfected. We also found that in mice immunized with nonmurine rotaviruses, (i) quantities of virus-specific IgA generated following challenge were greater 16 weeks than 6 weeks after immunization, (ii) immunization enhanced the magnitude but did not hasten the onset of production of high quantities of virus-specific IgA by LPL after challenge, and (iii) immunization induced partial protection against challenge; however, protection was not associated with either production of virus-specific antibodies by LPL or detection of virus-specific antibodies at the intestinal mucosal surface.

Effect of microencapsulation on immunogenicity of a bovine herpes virus glycoprotein and inactivated influenza virus in mice.

We previously found that aqueous-based spermine-alginate or spermine-chondroitin sulfate microcapsules enhanced rotavirus-specific humoral immune responses after intramuscular inoculation of mice. To extend our observations with whole, infectious rotavirus to vaccine strategies which include inactivated virus and purified proteins, we determined the capacity of aqueous-based microcapsules to enhance virus-specific immune responses to bovine herpes virus type 1 glycoprotein D (BHV-1-gD) or ether-treated influenza virus. We found that spermine-alginate microcapsules decreased the quantity of BHV-1-gD necessary to induce protein-specific antibodies about 5000-fold. However, spermine-alginate microcapsules did not enhance influenza virus-specific antibody responses. Microcapsules composed of spermine-chondroitin sulfate did not enhance either BHV-1-gD or influenza virus-specific immune responses. Possible mechanisms of enhancement of virus-specific antibody responses by microencapsulation are discussed.

Immunologic correlates of protection against rotavirus challenge after intramuscular immunization of mice.

The capacity of intramuscular (i.m.) inoculation of mice with homologous or heterologous host rotaviruses to induce protection from challenge was evaluated. i.m. inoculation with live, wild-type rotavirus (murine strain EDIM) induced complete protection from viral shedding after challenge for at least 6 weeks after inoculation; protection was correlated with production of virus-specific immunoglobulin A (IgA) by lamina propria (LP) lymphocytes. i.m. inoculation with inactivated EDIM, cell culture-adapted EDIM, or simian strain RRV was associated with partial protection, characterized by reduced viral shedding after challenge. Partial protection after challenge was not associated with production of virus-specific IgA by LP lymphocytes. The mechanisms by which i.m. inoculation induces virus-specific humoral immune responses in the small intestinal LP were examined.

Aqueous-based microencapsulation enhances virus-specific humoral immune responses in mice after parenteral inoculation.

Vaccines are commonly administered by the parenteral route. Therefore, adjuvant strategies which include parenteral immunization may improve the efficacy of a number of current vaccines. The capacity of aqueous-based microencapsulation to enhance virus-specific IgG responses in mice inoculated intramuscularly with small quantities of antigen was evaluated. Mice were inoculated with either 10(4), 10(3), or 10(2) p.f.u. of microencapsulated rotavirus (bovine strain WC3), placebo microcapsules plus free virus, or virus alone. Mice were subsequently bled 1, 2, 4, 6, and 9 months after inoculation. Microencapsulation of rotavirus enhanced virus-specific humoral immune responses. In addition, virus-containing microcapsules composed of spermine-chondroitin sulfate induced levels of virus-specific antibodies greater than those found after inoculation with virus-containing microcapsules composed of spermine-alginate. Mechanisms by which microencapsulation may enhance virus-specific humoral immunity are discussed.

Oral inoculation of mice with low doses of microencapsulated, noninfectious rotavirus induces virus-specific antibodies in gut-associated lymphoid tissue.

The capacity of an aqueous-based system of microencapsulation to enhance virus-specific humoral immune responses was evaluated in mice orally inoculated with noninfectious rotavirus (simian rotavirus strain RRV). Mice were orally inoculated with 1.75 or 0.35 microgram of inactivated RRV (iRRV) or microencapsulated iRRV. Sera, intestinal contents, and organ cultures of gut-associated lymphoid tissues (GALT) were tested for the presence of rotavirus-specific antibodies. Virus-specific IgA was produced by small intestine lamina propria lymphocytes in animals inoculated with 1.75 or 0.35 microgram of microencapsulated virus, but not in mice inoculated with unencapsulated virus. Virus-specific IgA in sera and intestinal contents were not predictive of intestinal organ culture responses. Microencapsulation may be an efficient way of inducing virus-specific immune responses in GALT after oral inoculation with small quantities of viral antigen. In addition, delayed release of virus from microcapsules may obviate the need for booster immunizations.

Enhancement by microencapsulation of rotavirus-specific intestinal immune responses in mice assessed by enzyme-linked immunospot assay and intestinal fragment culture.

The capacity of microencapsulation to enhance the humoral immune response to rotavirus in the gut-associated lymphoid tissue (GALT) of mice was determined by using a system of microencapsulation based on the ionic linkage of aqueous anionic polymers and an aqueous amine. Inoculation of mice with microencapsulated rotavirus enhanced the frequencies of virus-specific IgA-secreting cells in the lamina propria as well as the quantities of virus-specific IgA produced in GALT. In addition, an enhanced virus-specific immune response was associated with enhanced production of presumably polyclonal, non-rotavirus-specific antibodies in GALT. The mechanism by which microencapsulation enhances the humoral immune response remains to be determined.

Enhancement of rotavirus immunogenicity by microencapsulation.

It was determined whether microencapsulation of rotavirus enhanced virus-specific immunity in mice. Combinations of several water-soluble anionic polymers and amines were tested for their capacity to form microcapsules which were stable in the presence of simulated gastric acid. Using the combinations of sodium alginate and spermine hydrochloride or sodium chondroitin sulfate and spermine hydrochloride we found that microcapsules (1) captured infectious rotavirus, (2) penetrated into the persisted in gut-associated lymphoid tissue (GALT) after oral inoculation, (3) delivered rotavirus antigen to GALT at levels greater than those detected after oral inoculation with free virus, and (4) enhanced the virus-specific humoral immune response after oral or parenteral immunization.

[Botulism: apropos of a local epidemic]. / Botulisme: à propos d'une épidémie locale.

The authors report a small outbreak of botulism in a family following the consumption of homedried ham. Diagnosis was based on clinical pictures and isolation of the toxin. The epidemiology, physiopathology and recent advances in knowledge of this rare disease are reviewed.