5 chemical constituents were determined in the laboratory We use

5 chemical constituents were determined in the laboratory. We used three different mixed-effects models (single-constituent model, constituent-PM2.5 joint model and constituent residual model) controlling for potential confounders to estimate the effects of PM2.5 chemical

constituents on circulatory biomarkers.\n\nResults: We found consistent positive associations between the following biomarkers and PM2.5 chemical constituents across different models: TNF-alpha with secondary organic carbon, chloride, zinc, molybdenum and stannum; fibrinogen with magnesium, iron, titanium, cobalt and cadmium; PAI-1 with titanium, cobalt and manganese; t-PA with cadmium and selenium; 3-deazaneplanocin A vWF with aluminum. We also found consistent inverse associations of vWF with nitrate, chloride and sodium, and sP-selectin with manganese. Two positive associations of zinc with TNF-alpha and of cobalt with fibrinogen, and two inverse associations of nitrate with vWF, and of manganese with sP-selectin, were independent of the other constituents in two-constituent models using constituent residual data. We only found weak air pollution effects

on hs-CRP and tHcy.\n\nConclusions: Our results provide clues for the potential roles that PM2.5 chemical constituents may play in the biological mechanisms through which air pollution may influence the cardiovascular system.”
“Specific interactions between host genotypes and learn more pathogen genotypes (GxG interactions) are commonly observed in invertebrate systems. Such specificity challenges our current understanding of invertebrate defenses against pathogens because it contrasts the limited discriminatory power of known invertebrate immune responses. Lack of a mechanistic explanation, however, has questioned the nature of host factors underlying GxG interactions. In this study, we aimed to determine whether GxG interactions observed between dengue viruses and their Aedes aegypti vectors in nature can be mapped to discrete loci

in the mosquito genome and to document their genetic architecture. We developed an innovative genetic mapping strategy to survey GxG interactions using outbred mosquito families that were experimentally exposed to genetically distinct isolates of two dengue virus serotypes derived from human patients. Genetic loci associated with vector competence indices were P505-15 detected in multiple regions of the mosquito genome. Importantly, correlation between genotype and phenotype was virus isolate-specific at several of these loci, indicating GxG interactions. The relatively high percentage of phenotypic variation explained by the markers associated with GxG interactions (ranging from 7.8% to 16.5%) is consistent with large-effect host genetic factors. Our data demonstrate that GxG interactions between dengue viruses and mosquito vectors can be assigned to physical regions of the mosquito genome, some of which have a large effect on the phenotype.

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