Anti-allergic effects of Lactobacillus crispatus KT-11 strain on ovalbumin-sensitized BALB/c mice

The definitive version is available at www.blackwell-synergy.comIn this study, we investigated the effects of oral ingestion of Lactobacillus crispatus KT-11 strain (KT-11) on the immune response in an allergic rhinitis mouse model, ovalbumin (OVA)-sensitized BALB/c mice. Sneezing activity in mice that were administered a KT-11-supplemented diet was significantly lower than that in mice administered a KT-11-free diet (control diet) at age 11 weeks. We found that serum OVA-specific immunoglobulin E (IgE) levels and total number of interleukin (IL)-4+CD4+ spleen cells in mice that were administered a KT-11-supplemented diet were significantly lower than in mice administered a control diet. The ratio of spleen interferon-gamma+CD4+/IL-4+CD4+ cells was higher in the mice administered the KT-11-supplemented diet compared to that in mice administered the control or L. rhamnosus GG-supplemented diet. In contrast, the number of CD11b+CD80+ and Fc epsilon RI alpha+CD117+ cells was significantly lower in mice administered the KT-11-supplemented diet. These results suggested that KT-11 reduced OVA-induced allergic symptoms in BALB/c mice via the adjustment of the T helper type 1/T helper type 2 balance, and a decrease in the number of antigen-presenting cells and high affinity IgE receptor-positive mast cells.ArticleANIMAL SCIENCE JOURNAL. 81(6):699-705 (2010)journal articl

FcγRIIb Inhibits Allergic Lung Inflammation in a Murine Model of Allergic Asthma

Allergic asthma is characterized by airway eosinophilia, increased mucin production and allergen-specific IgE. Fc gamma receptor IIb (FcγRIIb), an inhibitory IgG receptor, has recently emerged as a negative regulator of allergic diseases like anaphylaxis and allergic rhinitis. However, no studies to date have evaluated its role in allergic asthma. Our main objective was to study the role of FcγRIIb in allergic lung inflammation. We used a murine model of allergic airway inflammation. Inflammation was quantified by BAL inflammatory cells and airway mucin production. FcγRIIb expression was measured by qPCR and flow cytometry and the cytokines were quantified by ELISA. Compared to wild type animals, FcγRIIb deficient mice mount a vigorous allergic lung inflammation characterized by increased bronchoalveolar lavage fluid cellularity, eosinophilia and mucin content upon ragweed extract (RWE) challenge. RWE challenge in sensitized mice upregulated FcγRIIb in the lungs. Disruption of IFN-γ gene abrogated this upregulation. Treatment of naïve mice with the Th1-inducing agent CpG DNA increased FcγRIIb expression in the lungs. Furthermore, treatment of sensitized mice with CpG DNA prior to RWE challenge induced greater upregulation of FcγRIIb than RWE challenge alone. These observations indicated that RWE challenge upregulated FcγRIIb in the lungs by IFN-γ- and Th1-dependent mechanisms. RWE challenge upregulated FcγRIIb on pulmonary CD14+/MHC II+ mononuclear cells and CD11c+ cells. FcγRIIb deficient mice also exhibited an exaggerated RWE-specific IgE response upon sensitization when compared to wild type mice. We propose that FcγRIIb physiologically regulates allergic airway inflammation by two mechanisms: 1) allergen challenge mediates upregulation of FcγRIIb on pulmonary CD14+/MHC II+ mononuclear cells and CD11c+ cells by an IFN-γ dependent mechanism; and 2) by attenuating the allergen specific IgE response during sensitization. Thus, stimulating FcγRIIb may be a therapeutic strategy in allergic airway disorders

Impact of antibody Fc engineering on translational pharmacology, and safety: insights from industry case studies.

Therapeutic monoclonal antibodies (mAbs) are often designed to not only bind targets via their antigen-binding domains (Fabs) but to also engage with cell surface receptors, FcγRs and FcRn, through their Fc regions, which may result in a variety of functional outcomes, including antibody- dependent cellular cytotoxicity (ADCC), antibody-dependent cellular phagocytosis (ADCP), complement-dependent cytotoxicity (CDC) and alteration of circulating half-lives. Engineering the Fc regions to achieve desirable pharmacology and pharmacokinetics is a widely adopted strategy in drug development. Fc regions can be modified through amino acid substitutions and glycoengineering, resulting in enhanced or reduced effector functions, preferential binding to FcR subtypes, or pH-dependent binding to FcRns. These alterations in binding and effector activities of mAbs may potentially also be accompanied by undesirable effects or safety concerns. Critical assessment of pharmacology and safety in the nonclinical setting is essential before exposing humans to the engineered mAb. For Fc-modified mAbs, the choice of in vitro and in vivo nonclinical pharmacology and safety models need to account for species differences in FcR expression and function, potentially divergent effects of Fc modifications in humans versus nonclinical species, impact of target and cognate ligand expression patterns, and potential impact of emergent anti-drug antibodies directed against the mAb. Using a variety of industry case studies, we highlight key aspects of nonclinical pharmacology and toxicology testing strategies, factors that influence choice of nonclinical models, translatability of findings, input from health authorities and suggest best practice approaches for nonclinical testing of Fc modified mAbs

Preclinical Safety Assessment of a Recombinant Plague Vaccine (rF1V)

A recombinant vaccine (rF1V) is being developed to protect adults 18 to 55 years of age from fatal pneumonic plague caused by aerosolized Yersinia pestis. A comprehensive series of studies was conducted to evaluate the general toxicity and local reactogenicity of the rF1V vaccine prior to first use in humans. Toxicity was evaluated in CD-1 mice vaccinated with control material and three dosage concentrations of rF1V with or without Alhydrogel® by intramuscular (IM) injection on Study Days 1, 29, 57 and 71 in a volume of 0.1 mL. Total immunizing protein given in each dose was 0, 20 or 60 μg/animal. Local reactogenicity was evaluated in mice at the dosages given and in New Zealand white (NZW) rabbits using the same injection volume and formulations (40, 80, 160 and 320 μg/mL total antigen and 0.3% (w/v) Alhydrogel®) intended for human use (0.5 mL). The rF1V vaccine produced no apparent systemic toxicity and only transient edema and erythema at the injection site. Together these results indicated a favorable safety profile for rF1V and supported its use in a Phase 1 clinical trial. </jats:p