Project description:Human betaherpesvirus 6A Genome sequencing and assembly

Project description:Human betaherpesvirus 5 Genome sequencing

Project description:Human betaherpesvirus 5 Genome sequencing

Project description:Human betaherpesvirus 5 Genome sequencing

Project description:We report the application of size selection of small RNA species isolated from Jjhan cells harboring the human herpesvirus 6A genome. We ammassed >3.4million reads of sequence from three different sources: Normal Brain cell total RNA, Jjhan total RNA and HHV-6A BAC transfected Jjhan total RNA. Sequences were mapped to the HHV-6A Uganda 1102 strain genome (GenBank: X83413.1) with no less than 100% match for reads >20nt and <23nt. The resulting pool of candidates was mapped to the HHV-6A genome.

Project description:Human betaherpesvirus 5 Raw sequence reads

Project description:We report the application of size selection of small RNA species isolated from Jjhan cells harboring the human herpesvirus 6A genome. We ammassed >3.4million reads of sequence from three different sources: Normal Brain cell total RNA, Jjhan total RNA and HHV-6A BAC transfected Jjhan total RNA. Sequences were mapped to the HHV-6A Uganda 1102 strain genome (GenBank: X83413.1) with no less than 100% match for reads >20nt and <23nt. The resulting pool of candidates was mapped to the HHV-6A genome. Single pass 36nt sequencing of samples either with or without HHV-6a genomes present.

Project description:Human betaherpesvirus 6B Genome sequencing and assembly

Project description:HHV-6A is a human herpesvirus that integrates into human sub telomeric regions to acquire latency. This latent virus frequently reactivates causing numerous diseases. The project was aimed to understand changes in host cell prteomics upon virus reactivation, which might helpin understanding the pathophysiology of virus reactivation.

Project description:Purpose: The RF/6A chorioretinal cell line originally isolated from a fetal rhesus macaque in 1968 is widely used to model human retinal and choroidal endothelial cells in cell culture. We sought to determine the extent to which this line possesses endothelial cell-specific characteristics. Methods: RF/6A cells obtained from American Type Culture Collection were subjected to next-generation RNA sequencing. Transcriptomic-based cell type profiling was conducted using xCell. Validation of endothelial cell-specific marker expression was conducted by qRT-PCR and western blotting. Functional assays of acetylated low density lipoprotein uptake, TNF-?-induced adhesion molecule expression, shear stress alignment, and endothelial tube formation were assessed. Results: RF/6A transcriptomic profiles obtained de novo or from a publically available repository did not correspond to endothelial gene expression signatures. Expression of established endothelial markers (PECAM1, CDH5, KDR, VWF, ICAM2, ENG, or TEK) were very low or undetectable in RF/6A compared to primary human umbilical vein endothelial cells. Compared to primary endothelial cells, RF/6A were unable to uptake acetylated LDL, exhibit induction of E-selectin in response to TNF-? treatment, align in the direction of shear stress, or form regular capillary-like tubes in Matrigel. Conclusions: RF/6A do not exhibit key endothelial cell characteristics or behaviors. Therefore, caution should be employed in designing and interpreting studies using these cells as surrogates for choroidal or retinal endothelial cells.