RESUMEN
Objective To investigate the clinical and gene mutation features of sodium taurocholate cotransporting polypeptide (NTCP) deficiency. Methods A total of 10 children, aged 50%). Second-generation gene sequencing showed that all 10 children had a homozygous mutation of the SLC10A1 gene, i.e., c.800C > T(p.Ser267Phe, chr14∶70245193). Conclusion Although NTCP deficiency often has no symptoms, some of the children may manifest as infant cholestasis in the early stage. The possibility of NTCP deficiency should be considered when there is persistent hypercholanemia and the changing trend of serum TBA is not consistent with that of other liver function parameters.
RESUMEN
Sodium-taurocholate cotransporting polypeptide (NTCP) deficiency is a new hereditary bile acid metabolic disease due to biallelic mutations of the SLC10A1 gene and is not rare in China. Marked and persistent hypercholanemia in childhood is the major clinical feature of NTCP deficiency, and this condition might be involved in the development of neonatal hyperbilirubinemia, cholestasis in early infancy, and cholestasis in pregnancy. At present, there lack specific therapies for NTCP deficiency, but such patients tend to have good prognosis. SLC10A1 gene detection may facilitate the timely and definite diagnosis of this disease and thus avoid unnecessary examinations and interventions.
RESUMEN
Coxsackievirus B3 (CVB3) is a non-enveloped virus that has a single-stranded RNA genome. CVB3 induces myocarditis, and ultimately, dilated cardiomyopathy. A myocarditis variant of CVB3 (CVB3 H3) and its antibody-escape mutant (CVB3 10A1) were studied previously; H3 was found to induce myocarditis and 10A1 was found to be attenuated in infected mice. Although amino acid residue 165, located in a puff region of VP2, was found to be altered (i.e., the H3 asparagine was altered to aspartate in 10A1), the detailed mechanism of attenuation was not clearly elucidated. Here, DNA microarray technology was used to monitor changes in mRNA levels of infected mouse hearts after CVB3 H3 and 10A1 infection. This tool was used to elucidate the pathogenic mechanisms of viral infection by understanding virus-host interactions. We identified several genes, including protein tyrosine kinases, Ddr2 and Ptk2, as well as Clqb and Crry, involved in complement reactions, which may be involved in these viral processes. Thus, gene profiling can provide an opportunity to understand host immune responses to viral infection for gene therapy and may contribute to the identification of the target gene that is modified during treatment of viral myocarditis.