Sequencing of the Hepatitis D Virus RNA WHO International Standard.

BACKGROUND: Well-characterized, stable calibration materials are essential to standardize quantitative viral reporting. The preferred calibration materials are the WHO International Standards and secondary standards derived from them. In 2013, the 1st WHO International Standard for Hepatitis D Virus (HDV) RNA became available. During the course of assay development in our laboratory, differences between the published sequence (GenBank ID: HQ005371) and sequence we generated from the WHO HDV Standard were identified. OBJECTIVES: We sought to sequence the entire genome of the WHO HDV Standard and compare the results to the published sequence. STUDY DESIGN: RNA extracted from the WHO HDV Standard was used to generate five overlapping PCR products, including one covering the entire HDV genome, which were Sanger sequenced using standard dye-terminator chemistry. Total RNA from the WHO HDV Standard was also converted to a cDNA library generating 2.1 million sequencing reads on a NextSeq500 instrument. RESULTS: Sanger sequencing produced 32 overlapping, partial sequences of the HDV genome. RNA-seq resulted in 8100 HDV sequences covering the viral genome an average of 645-fold. Sanger and RNA-seq consensus sequences had 100% agreement and showed 89.0% nucleotide identity with the published WHO HDV Standard sequence. BLAST analysis revealed HQ005369 as the closest match with 99.2% nucleotide identity. CONCLUSIONS: HQ005369 was deposited in GenBank along with HQ005371 and seven others from a study of nine Turkish patients. A sample mix-up or clerical error may have resulted in the incorrect association of identifier and sequence. The correct nucleic acid sequence for standards is critical for test accuracy, optimization, calibration, and troubleshooting.

Simple sequence repeat marker development and genetic mapping in quinoa (Chenopodium quinoa Willd.).

Quinoa is a regionally important grain crop in the Andean region of South America. Recently quinoa has gained international attention for its high nutritional value and tolerances of extreme abiotic stresses. DNA markers and linkage maps are important tools for germplasm conservation and crop improvement programmes. Here we report the development of 216 new polymorphic SSR (simple sequence repeats) markers from libraries enriched for GA, CAA and AAT repeats, as well as 6 SSR markers developed from bacterial artificial chromosome-end sequences (BES-SSRs). Heterozygosity (H) values of the SSR markers ranges from 0.12 to 0.90, with an average value of 0.57. A linkage map was constructed for a newly developed recombinant inbred lines (RIL) population using these SSR markers. Additional markers, including amplified fragment length polymorphisms (AFLPs), two 11S seed storage protein loci, and the nucleolar organizing region (NOR), were also placed on the linkage map. The linkage map presented here is the first SSR-based map in quinoa and contains 275 markers, including 200 SSR. The map consists of 38 linkage groups (LGs) covering 913 cM. Segregation distortion was observed in the mapping population for several marker loci, indicating possible chromosomal regions associated with selection or gametophytic lethality. As this map is based primarily on simple and easily-transferable SSR markers, it will be particularly valuable for research in laboratories in Andean regions of South America.

Determination of the non-ionic detergent insolubility and phosphoprotein associations of glycosylphosphatidylinositol-anchored proteins expressed on T cells.

Glycosylphosphatidylinositol (GPI)-anchored proteins are poorly solublized in non-ionic detergents such as Triton X-100 and Nonidet P40, but are easily solublized by detergents with high critical micelle concentrations such as octylglucoside. This solubility profile has been suggested to be due to the localization of GPI-anchored proteins to lipid microdomains rich in cholesterol and sphingolipids. Additionally, GPI-anchored proteins expressed on haemopoietic cells have been shown to associate with src-family tyrosine kinases and heterotrimeric G proteins. Despite these observations, the non-ionic detergent insolubility of GPI-anchored proteins on haemopoietic cells has not been quantified nor has a relationship between the non-ionic detergent insolubility of these proteins and their association with signal-transduction molecules been identified. Here we show that GPI-anchored proteins found on T-cell tumours and activated T cells, although significantly more insoluble then transmembrane proteins, are not uniform in their detergent insolubility. Whereas CD59 was between 4% and 13% soluble, CD48 was between 13% and 25% soluble, CD55 was between 20% and 30% soluble, and CD109 was between 34% and 75% soluble. The ability of these GPI-anchored proteins to associate with phosphoproteins was correlated with their detergent insolubility: the more detergent-insoluble that a GPI-anchored protein was, the greater the level of phosphoprotein associations. These experiments reveal a relationship between non-ionic detergent insolubility and association with signal-transduction molecules and suggest a cause-and-effect relationship between these two properties. In total, these experiments support the hypothesis that the association of GPI-anchored proteins with signalling molecules is due to their sorting to lipid microdomains.

The nature of membrane anchorage determines kinase association and detergent solubility of CD4.

The presence of a glycosylphosphatidylinositol (GPI) anchor on a membrane protein is thought to influence aspects of the protein's biochemistry. While it has been demonstrated that a GPI-anchor is sufficient for altering the detergent solubility of integral membrane proteins, it has not been shown that the anchor is sufficient for changing the phosphoprotein associations of membrane proteins. In order to define the influence of GPI-anchors on the biochemistry of membrane proteins we compared the phosphoprotein associations and detergent solubility of wild-type and GPI-anchored CD4 expressed on HSB cell transfectants. While wild-type CD4 was mostly associated with lck kinase, GPI-anchored CD4 was associated with the 'GPI-anchored pattern of phosphoproteins'. The Triton X-100 solubilities of the two forms of CD4 were also distinct: wild-type CD4 was > 95% soluble, whereas GPI-anchored CD4 was only 65% soluble. These results underscore the deterministic role of the GPI-anchor in the properties associated with GPI-anchored proteins.