Helmuth van Es

Arrayed adenoviral expression libraries for functional screening.

With the publication of the sequence of the human genome, we are challenged to identify the functions of an estimated 70,000 human genes and the much larger number of proteins encoded by these genes. Of particular interest is the identification of gene products that play a role in human disease pathways, as these proteins include potential new targets that may lead to improved therapeutic strategies. This requires the direct measurement of gene function on a genomic scale in cell-based, functional assays. We have constructed and validated an individually arrayed, replication-defective adenoviral library harboring human cDNAs, termed PhenoSelect library. The adenoviral vector guarantees efficient transduction of diverse cell types, including primary cells. The arrayed format allows screening of this library in a variety of cellular assays in search for gene(s) that, by overexpression, induce a particular disease-related phenotype. The great majority of phenotypic assays, including morphological assays, can be screened with arrayed libraries. In contrast, pooled-library approaches often rely on phenotype-based isolation or selection of single cells by employing a flow cytometer or screening for cell survival. An arrayed placental PhenoSelect library was screened in cellular assays aimed at identifying regulators of osteogenesis, metastasis, and angiogenesis. This resulted in the identification of known regulators, as well as novel sequences that encode proteins hitherto not known to play a role in these pathways. These results establish the value of the PhenoSelect platform, in combination with cellular screens, for gene function discovery.

Rapid determination of adenoviral vector titers by quantitative real-time PCR

Replication defective adenoviruses have been used as vectors in a variety of settings including gene transfer, gene manipulation, and functionality studies. A quantitative real-time PCR-based assay is described for rapid determination of physical titers of recombinant adenovirus vectors. This method is based on amplification of a 77 bp fragment located near the left end of the adenovirus type 5 genome. Evaluation of this method demonstrated that it is simple, sensitive and reproducible, and has a dynamic range of quantitation over 5 logs. This assay is applicable to purified adenovirus as well as vectors prepared by simple cell lysis procedure, requiring only a small amount of starting material. The simplicity and short turn-around time of this assay should facilitate rapid titer determination for a large collection of adenoviral vectors.

Biology calls the targets: combining RNAi and disease biology.

Target-based drug discovery starts with the identification of target genes and their respective protein products (associated with or controlling a disease-relevant phenotype) that, when inhibited or activated, ameliorate the associated disease. To identify disease-relevant genes, robust tools are needed to allow biology-driven target discovery and validation. Moreover, insight into the underlying biology of a disease is essential to model a disease in vitro. Key questions are: What are the disease hallmarks? What are, from a biological point of view, the best points for therapeutic intervention? How can scientists model these points in vitro? What is the desired target profile? The closer the cellular models resemble the disease situation, the better the target profile will be. The profile is the set of biological data needed to accept the target for drug discovery. In this review, a focused approach for target discovery and validation is presented. Arrayed adenoviral siRNA libraries and disease-based cellular models are used that generate high-quality and functionally validated targets.

Improved lipid profile through liver-specific knockdown of liver X receptor alpha in KKAy diabetic mice.

Nuclear hormone receptors liver X receptor (LXRalpha and LXRbeta) ligands are attractive approaches for the treatment of dyslipidemia and atherosclerosis. To further elucidate the function of LXRalpha in liver lipid metabolism in a disease-relevant animal model, the KKAy mouse, we used adenoviral vectors to selectively knock down LXRalpha gene expression. Out of five different short hairpin RNAs (shRNAs) that were tested in vitro, one construct was selected for detailed analysis of LXRalpha knockdown in vivo. Reduction of LXRalpha transcript levels to 48 +/- 13% compared with control virus transduction resulted in a significant downregulation of the LXRalpha-regulated lipogenic genes sterol-regulatory element binding protein-1c (SREBP1c) and stearoyl CoA desaturase 1 in vivo. Interestingly, ABCA1 and phoshoenolpyruvate carboxykinase 1 expression was not affected, whereas lipoprotein lipase (LPL) expression was found to be increased. In addition, 8 days after virus transduction, both plasma and liver triglycerides (TGs) were reduced by about 50%. Changes in TG levels were not due to reduced food intake in virus-treated animals, because pair-fed mice showed unchanged TG levels. Taken together, liver-specific knockdown of LXRalpha in vivo by shRNA reduced expression of lipogenic master genes, like SREBP1c, and improved the lipid profile of hypertriglyceridemic KKAy mice.