Publications

Schistosomiasis is one of the most common causes of pulmonary arterial hypertension worldwide, but the pathogenic mechanism by which the host inflammatory response contributes to vascular remodeling is unknown. We sought to identify signaling pathways that play protective or pathogenic roles in experimental Schistosoma-induced pulmonary vascular disease via whole-lung transcriptome analysis. Wild-type mice were experimentally exposed to Schistosoma mansoni ova by intraperitoneal sensitization followed by tail-vein augmentation, and the phenotype was assessed by right ventricular catheterization and tissue histology, as well as RNA and protein analysis. Whole-lung transcriptome analysis by microarray and RNA sequencing was performed, and RNA sequencing was analyzed according to two bioinformatics methods. Functional testing of the candidate IL-6 pathway was determined using IL-6 knockout mice and the signal transducers and activators of transcription protein-3 (STAT3) inhibitor S3I-201. Wild-type mice exposed to S. mansoni demonstrated increased right ventricular systolic pressure and thickness of the pulmonary vascular media. Whole-lung transcriptome analysis determined that the IL-6-STAT3-nuclear factor of activated T cells c2(NFATc2) pathway was up-regulated, as confirmed by PCR and the immunostaining of lung tissue from S. mansoni-exposed mice and patients who died of the disease. Mice lacking IL-6 or treated with S3I-201 developed pulmonary hypertension, associated with significant intima remodeling after exposure to S. mansoni. Whole-lung transcriptome analysis identified the up-regulation of the IL-6-STAT3-NFATc2 pathway, and IL-6 signaling was found to be protective against Schistosoma-induced intimal remodeling.

Presensitization with Mtb-derived trehalose 6,6'-dimycolate (TDM; cord factor) followed by challenge with the same glycolipid species resulted in elicitation of stronger inflammatory responses than when mice were similarly challenged with M. bovis-derived TDM. Mice presensitized to the homologous Mtb-derived TDM demonstrated cachexic over a 6 day period, whereas similarly presensitized mice challenged with the M. bovis-derived TDM, or with emulsion control, did not experience weight loss. Examination of inflammatory responses demonstrated increased lung histopathology in the Mtb-derived TDM challenged group, evidenced by severe tissue disruption, cellular influx, vascular occlusion and lymphocytic cuffing, and endothelial cell damage. Histological analysis demonstrated that lung pathology in the M. bovis challenged group was strikingly similar to that of the acute model challenge. Examination of proinflammatory mediators also showed findings consistent with histological manifestation, with significantly elevated TNF-α and IL-1β, as well as IFN-γ, in the homologous TDM challenged group relative to all other groups. Overall, these findings indicate a difference in hypersensitive immune responses to TDM derived from different mycobacterial strains. Development of specific adaptive immune responses to the Mtb-derived TDM were demonstrated that had limited cross-reactivity to that of M. bovis, thus strongly suggesting the presence of hypersensitive epitopes exclusive to Mtb TDM not present on M. bovis-derived TDM.