ABSTRACT
Host cell invasion by Toxoplasma gondii is crucial for the survival and proliferation of parasite. The process of T. gondii tachyzoite invasion requires interaction between parasite proteins and receptors on the surface of host cells. Sialic acid is one of the important receptors for host cell invasion by T. gondii. However, the parasite-derived proteins interacting with sialic acid have not been well characterized. In this study, a novel protein named putative TCP-1 chaperonin (TGME49_318410) in T. gondii (TgTCP-1) was targeted and characterized. TgTCP-1 protein colocalized with MIC3 protein, which could be secreted from T. gondii tachyzoites, and this protein showed a specific binding activity to sialic acid, and DC and Vero cells in vitro. The binding of TgTCP-1 protein to DC and Vero cells were inhibited by either pre-incubation with free sialic acid or neuraminidase treatment of the cells. Moreover, a significant reduction of T. gondii invasion in Vero cells was observed after pre-incubation of the cells with recombinant TgTCP-1 protein. These results illustrated that TgTCP-1 is an important molecule involved in sialic acid-dependent host cell invasion by T. gondii.
ABSTRACT
Neonatal respiratory distress is a major mortality factor in cloned animals, but the pathogenesis of this disease is rarely investigated. In this study, four neonatal cloned cattle, born after full-term gestation, exhibited symptoms of neonatal respiratory distress syndrome (NRDS), which included symptoms of hyaline membrane disease as well as disordered surfactant homeostasis in their collapsed lungs. No differences in DNA methylation or histone modifications correlated with the suppressed SPB and SPC transcription observed in the cloned cattle group (p > 0.05), whereas TTF-1 occupancy at SPB and SPC promoter regions in cloned cattle was significantly reduced to 24% and 20% that of normal lungs, respectively (SPB, p < 0.05; SPC, p < 0.01). Decreased TTF1 expression, dysregulation of SPB and SPC transcription by TTF-1, and disordered proteolytic processing of Surfactant protein B precursor together potentially contribute to the disruption of surfactant homeostasis and NRDS in bovine clones. Elucidation of the associated mechanisms should facilitate the development of novel preventive or therapeutic strategies to reduce the mortality rate of cloned animals and to improve the efficiency of SCNT technology.