Maternal stress increases risk of allergic lung inflammation in adult mice.

BACKGROUND: Allergies are increasing worldwide. The presence of atopic diseases in the mother propagates the onset of allergic diseases in the offspring with a considerably stronger penetrance than atopic diseases of the father. Such observation challenges genetic predispositions as the sole cause of allergic diseases. Epidemiological studies suggest that caregiver stress in the perinatal period may predispose offspring to asthma. Only one group has studied the link between prenatal stress and neonatal asthma susceptibility in a murine model. OBJECTIVES: We aimed to study if the neonatal increased risk of developing allergic lung inflammation persists after puberty and if there are sex differences in susceptibility. METHODS: Pregnant BALB/c mice were subjected to a single restraint stress exposure at day 15 of gestation. Pups were separated by gender and subjected to a well-known sub-optimal asthma model after puberty. RESULTS: Adult mice born to stressed dams were more susceptible to developing allergic pulmonary inflammation since an increase in the number of eosinophils in bronchoalveolar lavage (BAL), a greater peribronchial and perivascular infiltrate, a higher proportion of mucus-producing cells, and increased IL-4 and IL-5 levels in BAL were detected compared to control mice. These effects were more profound in females than males. Moreover, only females from stressed dams showed an increase in IgE levels. CONCLUSIONS: Increased litter susceptibility to develop allergic lung inflammation induced by maternal stress persists after puberty and is more potent in females than in male mice.

Contribution of Kazal-Like Domains of the Serine Protease Inhibitor-1 from Toxoplasma gondii in Asthma Therapeutic Vaccination Effectiveness.

BACKGROUND: We have previously showed rTgPI-1 tolerogenic adjuvant properties in asthma treatment, turning it a promising candidate for allergen-specific immunotherapy. This therapy is an alternative treatment to control asthma that still presents several concerns related to its formulation. rTgPI-1 contains independent inhibitory domains able to inhibit trypsin and neutrophil elastase, both involved in asthma pathology. OBJECTIVES: In view of the need to design rational therapies, herein we investigated the contribution of the different inhibitory domains in rTgPI-1 therapeutic effectiveness. METHODS: BALB/c mice were rendered allergic by intraperitoneal OVA-alum sensitization and airway challenged. Once the asthmatic phenotype was achieved, mice were intranasally treated with OVA combined with the full-length recombinant protein rTgPI-1 or its truncated versions, Nt (containing trypsin-inhibitory domains) or Ct (containing neutrophil elastase-inhibitory domains). Afterward, mice were aerosol re-challenged. RESULTS: Asthmatic mice treated with the neutrophil elastase- or the trypsin-inhibitory domains separately failed to improve allergic lung inflammation. Only when all inhibitory domains were simultaneously administered, an improvement was achieved. Still, a better outcome was obtained when mice were treated with the full-length rTgPI-1. CONCLUSIONS: Adjuvant ability depends on the presence of all its inhibitory domains in a single entity, so it should be included in potential asthma treatment formulations as a full-length protein.

Chronic infection with the protozoan Toxoplasma gondii prevents the development of experimental atopic dermatitis in mice.

BACKGROUND: Supporting the hypothesis thatT. gondii infection protects against allergy in humans we previously demonstrated that this infection can modulate not only the susceptibility to develop respiratory allergies in mice but also suppresses allergic responses at systemic level. This latter finding suggests that T. gondii infection could prevent the onset of other allergic diseases, such as atopic dermatitis. At present, few studies have investigated the modulation of atopic dermatitis by parasite infections. OBJECTIVE: Here, we sought to investigate whether chronic infection with T. gondii is capable of modulating the development of atopic dermatitis. METHODS: Chronically infected mice were sensitized by repeated epicutaneous ovalbumin administration. Skin histopathology, humoral response, cytokine production and innate type-II lymphoid cells (ILC2) were assessed. RESULTS: A marked reduction in epidermal thickness and dermal inflammatory infiltrate along with a reduction in mast cell count was observed in infected mice compared to non-infected mice. These results correlated with a diminished TH2 and TH1 allergen specific response. Reduced type-II IL-4 and IL-5 cytokines were already detected during the first 24 h of allergen sensitization in splenocytes and draining lymph nodes from infected mice. Moreover, this reduced type-II profile in chronically infected animals correlated with diminished ILC2 number in draining lymph nodes. CONCLUSION: Chronic infection withT. gondii prevents the development of atopic dermatitis. The diminished susceptibility seems to result from changes in type-II innate immune response that may lead to the induction of a deficient TH2 response and consequently to a lower susceptibility to develop atopic dermatitis.

Genotyping of Toxoplasma gondii: The advantages of variable number tandem repeats within coding regions.

Toxoplasma gondii is an intracellular protozoan which is widely distributed. Infection occurs as a result of ingestion of uncooked meat and exposure to cat feces. Immunocompetent individuals are generally asymptomatic, while severe disease may occur in immunocompromised subjects and in congenital toxoplasmosis, which is caused by transplacental acquisition of T. gondii. Genetic diversity of T. gondii has often been studied using a PCR-RFLP scheme based on nine molecular markers. These studies led to the description of a clonal population structure with three main lineages (I, II and III) in North America and Europe and higher genetic diversity in South America. The aim of this study was to develop molecular markers that could allow the discrimination of genetic variants within each clonal lineage. We analyzed the genome of T. gondii to identify genes containing variable number tandem repeats (VNTRs). The coding sequences of T. gondii ME49 genome were processed with Tandem Repeat Finder software. A panel of candidate markers was selected based on the following parameters: the repeat unit size (>9 bp) and composition (to avoid single and dinucleotide runs), the number of copies (<20), and the absence of introns within the repeat region. The selected panel of eight molecular markers was analyzed in PRU and RH strains. As a first step, the variability of the sequence size allowed us to differentiate PRU from ME49 (two type II strains) and RH from GT1 (two type I strains). Additionally, amplification products from PRU and RH strains were sequenced to study intra-lineage variability. Aside from size polymorphisms in the amplification products we were able to identify sequence variability in polymorphic markers.