A novel reverse transduction adenoviral array for the functional analysis of shRNA libraries.

BACKGROUND: The identification of novel drug targets by assessing gene functions is most conveniently achieved by high-throughput loss-of-function RNA interference screening. There is a growing need to employ primary cells in such screenings, since they reflect the physiological situation more closely than transformed cell lines do. Highly miniaturized and parallelized approaches as exemplified by reverse transfection or transduction arrays meet these requirements, hence we verified the applicability of an adenoviral microarray for the elucidation of gene functions in primary cells. RESULTS: Here, we present microarrays of infectious adenoviruses encoding short hairpin RNA (shRNA) as a new tool for gene function analysis. As an example to demonstrate its application, we chose shRNAs directed against seven selected human protein kinases, and we have performed quantitative analysis of phenotypical responses in primary human umbilical vein cells (HUVEC). These microarrays enabled us to infect the target cells in a parallelized and miniaturized procedure without significant cross-contamination: Viruses were reversibly immobilized in spots in such a way that the seeded cells were confined to the area of the viral spots, thus simplifying the subsequent addressing of genetically modified cells for analysis. Computer-assisted image analysis of fluorescence images was applied to analyze the cellular response after shRNA expression. Both the expression level of knock-down target proteins as well as the functional output as measured by caspase 3 activity and DNA fractionation (TUNEL) were quantified. CONCLUSION: We have developed an adenoviral microarray technique suitable for miniaturized and parallelized analysis of gene function. The practicability of this technique was demonstrated by the analysis of several kinases involved in the activation of programmed cell death, both in tumor cells and in primary cells.

Expressing engineered thymidylate kinase variants in human cells to improve AZT phosphorylation and human immunodeficiency virus inhibition.

The triphosphorylated form of the nucleoside analogue AZT (AZTTP) acts as a chain terminator during reverse transcription of the human immunodeficiency virus (HIV) genome. The bottleneck in the conversion of AZT to AZTTP is the phosphorylation of AZT monophosphate (AZTMP) by cellular thymidylate kinase. Human thymidylate kinase was engineered to exhibit highly improved activity for AZTMP to AZTDP conversion. It was demonstrated here that genetically modified human cells transiently expressing these enzyme variants show more than 10-fold higher intracellular concentrations of AZTDP and AZTTP. Stable clones expressing these enzymes appear to phosphorylate AZTMP less efficiently, but first experiments indicate they are still more potent in HIV inhibition than the parental cells. It was proposed that the concept of introducing into human cells a catalytically improved human enzyme, rather than an enzyme of viral, bacterial or yeast origin, may serve as a paradigm for ameliorating the metabolic activation of an established drug.

Kirrel2, a novel immunoglobulin superfamily gene expressed primarily in beta cells of the pancreatic islets.

A novel immunoglobulin superfamily (Igsf) protein gene was discovered by computational analysis of human draft genomic DNA, and multiple cDNA clones were obtained. The protein encoded by this gene contains five Ig domains, one transmembrane domain, and an intracellular domain. It has significant similarity with several known Igsf proteins, including Drosophila RST (irregular chiasm C-roughest) protein and mammalian KIRREL (kin of irregular chiasm C-roughest), NEPH1, and NPHS1 (nephrin) proteins. All these proteins have multiple Ig domains, possess properties of cell adhesion molecules, and play important roles in organ development. RT-PCR and Northern blot results indicate this gene is predominantly expressed in pancreas, and public sequence databases indicate there is also expression in the nervous system. We have named this gene Kirrel2 (kin of irregular chiasm-like 2), to reflect its similarity to irregular chiasm C-roughest and Kirrel. Four splice forms of Kirrel2 were observed, including two that we cloned from pancreas mRNA as well as two GenBank entries, one from the brain and one from a retinoblastoma cell line. A partial cDNA clone of the mouse orthologue was obtained by RT-PCR from mouse brain, and the inferred protein sequence has 85% sequence identity to the human protein. Immunohistochemical staining results indicate that the KIRREL2 protein is conserved from rodents to primates, and it is highly expressed in pancreatic islets. RT-PCR results on mouse pancreatic cell lines indicate that expression in the pancreas is restricted to beta cells. Thus, KIRREL2 protein is a beta-cell-expressed Ig domain protein and may be involved in pancreas development or beta cell function.