Parental characteristics, somatic fetal growth, and season of birth influence innate and adaptive cord blood cytokine responses.

BACKGROUND: Immunologic responses at birth likely relate to subsequent risks for allergic diseases and wheezing in infancy; however, the influences of parental characteristics and prenatal factors on neonatal immune responses are incompletely understood. OBJECTIVE: This study investigates potential correlations between urban parental, prenatal, and perinatal factors on innate and adaptive stimuli-induced cytokine responses. METHODS: Five hundred sixty and 49 children of parents with and without allergic disease or asthma, respectively, were enrolled into a prospective birth cohort study (Urban Environment and Childhood Asthma). Cord blood mononuclear cells were incubated with innate and adaptive immune stimuli, and cytokine responses (ELISA) were compared with season of birth, parental characteristics, in utero stressors, and fetal growth. RESULTS: Many cytokine responses varied by season of birth, including 2-fold to 3-fold fluctuations with specific IFN-alpha and IFN-gamma responses. Birth weight was inversely associated with IFN-gamma responses to respiratory syncytial virus (R = -0.16), but positively associated with IL-8 responses to a variety of innate stimuli (R = 0.08-0.12). Respiratory syncytial virus-induced cytokine responses were 21% to 54% lower in children of mothers with asthma. Cytokine responses were generally lower in babies born to parents with allergy/asthma. CONCLUSIONS: Innate cytokine responses are associated with parental allergic or airway disease, somatic fetal growth, ethnicity, and season of birth. Collectively, these findings suggest that urban prenatal exposures and familial factors affect the development of the fetal immune system.

Peptide induces CD4(+)CD25+ and IL-10+ T cells and protection in airway allergy models.

The purpose of this study was to evaluate whether a single peptide containing a major T cell epitope might induce peripheral tolerance in a complex allergen model. C57BL/6 mice were sensitized by intraperitoneal injection of house dust mite extract (HDM), and exposed to antigen via trachea instillation. Der p 1 peptide was administered by i.v. before or after sensitization. Lung lavage fluids were analyzed for cellular infiltration. Respiratory exposure of sensitized mice to antigen results in airway inflammation and eosinophilia. Intravenous administration of a single peptide protected sensitized mice from these changes. Further, the emergence of antigen-specific CD25(+)CD4+ and IL-10 secreting cell populations in DO11.10 mice was demonstrated after peptide administration. Thus, intravenous delivery of a single peptide epitope is capable of inducing peripheral tolerance and protection in a complex allergy model, possibly through regulatory T cells and bystander suppression.

An antigen-independent but not antigen-specific T(H)1 response provides protection in the murine airway inflammation model.

BACKGROUND: Atopic disorders are associated with an imbalanced T(H) cell response biased toward a strong T(H)2 type, resulting in excessive production of IgE antibodies, eosinophil recruitment and activation, and mast cell degranulation. Restoring the T(H)1-T(H)2 balance by increasing the antigen-specific T(H)1 response has been pursued for specific allergy immunotherapy. Synthetic oligodeoxynucleotides containing unmethylated CG dinucleotides (CpG) are strong T(H)1 adjuvants and are being investigated for allergy immunotherapy. OBJECTIVE: This study was designed to investigate the protective role of antigen-specific T(H)1 responses induced by epidermal powder immunization with ovalbumin (OVA) and CpG in a murine airway inflammation model. METHODS: An allergy model was used in which BALB/c mice were sensitized and then challenged with OVA. Mice received prophylactic or therapeutic immunizations with OVA, CpG, or both. After challenge, pulmonary inflammation and cell infiltration were measured on the basis of BAL cell counts and lung histology. Immune response was determined by measuring the levels of lavage cytokines and serum antibodies. RESULTS: Coadministration of OVA and CpG by means of subcutaneous injection or epidermal powder immunization, although inducing a strong T(H)1 response, neither suppressed T(H)2 cytokines nor offered protection against pulmonary eosinophilia and histopathology in a mouse challenge model. However, when CpG was used as a stand-alone treatment of previously sensitized animals, protection against allergic airway inflammation was observed. After challenge with OVA, eosinophilia was suppressed in the lungs of the CpG-treated mice. CONCLUSION: This finding argues against the approach of boosting an allergen-dependent T(H)1 response and favors induction of an antigen-independent T(H)1 response for allergy immunotherapy.

Human urinary bladder epithelial cells lacking wild-type p53 function are deficient in the repair of 4-aminobiphenyl-DNA adducts in genomic DNA.

The effect of the tumor suppressor gene TP53 on repair of genomic DNA damage was examined in human urinary bladder transitional cell carcinoma (TCC) cell lines. Utilizing TCC10 containing wild-type p53 (wt-p53) as the parental line, an isogenic set of cell lines was derived by retroviral infection that expressed a transdominant mutant p53 (Arg --> His at codon 273, TDM273-TCC10), or the human papilloma virus 16-E6 oncoprotein (E6-TCC10). 32P-postlabeling analyses were performed on DNA from TCC cultures obtained after treatment with N-hydroxy-4-aminobiphenyl (N-OH-ABP), N-hydroxy-4-acetylaminobiphenyl (N-OH-AABP) and N-acetoxy-4-acetylaminobiphenyl (N-OAc-AABP). The major adduct was identified as N-(deoxyguanosin-8-yl)-4-aminobiphenyl (dG-C8-ABP) with all three chemicals. The amount of adducts in urothelial DNA ranged between 0.1 and 20 per 10(6) nucleotides, N-OAc-AABP yielding the highest levels, followed by N-OH-ABP and N-OH-AABP. To determine, if the functional status of p53 affects the rate of repair of dG-C8-ABP in genomic DNA, TCC10 and the TDM273-TCC10 and E6-TCC10 isotypes were exposed to N-OH-AABP for 12h and the DNA damage was allowed to repair up to 24h. The adduct levels were quantified and compared between the TCC10 isotypes. The amounts of dG-C8-ABP that remained in genomic DNA from E6-TCC10 and TDM273-TCC10 were approximately two-fold higher, as compared to the parental TCC10. At the dose used for DNA repair studies, N-OH-AABP or N-OAc-AABP did not induce apoptosis in TCC10. However, N-OAc-AABP at high doses (>5 microM) induced apoptosis, as evidenced by DNA fragmentation analyses. Furthermore, N-OAc-AABP-mediated apoptosis was independent of the functional status of wt-p53, since both E6-TCC10 and the parental TCC10 exhibited DNA fragmentation following treatment. These results suggest that p53 might modulate the repair of DNA adducts generated from the human bladder carcinogen ABP in its target human uroepithelial cells. This implies that in p53 null cells the unrepaired DNA damage could cause accumulation of mutation, which might contribute to increased genomic instability and neoplastic progression.