Real-time fluorescence loop-mediated isothermal amplification for the diagnosis of hemorrhagic enteritis virus.

Suspected cases of hemorrhagic enteritis associated with hemorrhagic enteritis virus (HEV) are becoming more frequent among yellow chickens in the Guangdong Province of China. In this study, we have developed a one-step, ecumenical, real-time fluorescence loop-mediated isothermal amplification (RealAmp) assay for the rapid diagnosis of HEV. The RealAmp assay was performed at 63°C and reduced the assay time to 15min, using a simple and portable device, the ESE-Quant Tube Scanner. The detection limit of DNA was 1fg/µl, and the detection was specific only to HEV. We also used nested PCR to evaluate the application of the RealAmp assay. The coincidence rate of the two methods was 100%. Our data indicated that the RealAmp assay provides a sensitive, specific, and user-friendly diagnostic tool for the identification and quantification of HEV for field diagnosis and in laboratory research.

The MYC, TERT, and ZIC1 genes are common targets of viral integration and transcriptional deregulation in avian leukosis virus subgroup J-induced myeloid leukosis.

UNLABELLED: The integration of retroviruses into the host genome following nonrandom genome-wide patterns may lead to the deregulation of gene expression and oncogene activation near the integration sites. Slow-transforming retroviruses have been widely used to perform genetic screens for the identification of genes involved in cancer. To investigate the involvement of avian leukosis virus subgroup J (ALV-J) integration in myeloid leukosis (ML) in chickens, we utilized an ALV-J insertional identification platform based on hybrid capture target enrichment and next-generation sequencing (NGS). Using high-definition mapping of the viral integration sites in the chicken genome, 241 unique insertion sites were obtained from six different ALV-J-induced ML samples. On the basis of previous statistical definitions, MYC, TERT, and ZIC1 genes were identified as common insertion sites (CIS) of provirus integration in tumor cells; these three genes have previously been shown to be involved in the malignant transformation of different human cell types. Compared to control samples, the expression levels of all three CIS genes were significantly upregulated in chicken ML samples. Furthermore, they were frequently, but not in all field ML cases, deregulated at the mRNA level as a result of ALV-J infection. Our findings contribute to the understanding of the relationship between multipathotypes associated with ALV-J infection and the molecular background of tumorigenesis. IMPORTANCE: ALV-Js have been successfully eradicated from chicken breeding flocks in the poultry industries of developed countries, and the control and eradication of ALV-J in China are now progressing steadily. To further study the pathogenesis of ALV-J infections, it will be necessary to elucidate the in vivo viral integration and tumorigenesis mechanism. In this study, 241 unique insertion sites were obtained from six different ALV-J-induced ML samples. In addition, MYC, TERT, and ZIC1 genes were identified as the CIS of ALV-J in tumor cells, which might be a putative "driver" for the activation of the oncogene. In addition, the CIS genes showed deregulated expression compared to nontumor samples. These results have potentially important implications for the mechanism of viral carcinogenesis.