TaqMan® OpenArray® high-throughput transcriptional analysis of human embryonic and induced pluripotent stem cells.

It is widely accepted that somatic cells can be reprogrammed by a set of transcription factors to become embryonic stem cell-like: These reprogrammed cells, induced pluripotent stem cells (iPSCs), are nearly identical to embryonic stem cells (ESCs), because both have the capacity to self-renew and to form all cellular lineages of the body. Transcriptional differences between ESCs, iPSCs, and fibroblasts can be analyzed by quantitative PCR (qPCR) using TaqMan(®) Gene Expression assays, a widely used tool for rapid analysis of different cell types. In this chapter, we describe the OpenArray(®) platform which generates qPCR data from high-throughput instrumentation. We examined the gene signature profiles of ESCs, fibroblasts, and iPSCs with a TaqMan(®) OpenArray(®) Human Stem Cell Panel containing 631 TaqMan(®) Gene Expression assays that represent pathways involved in self-renewal, pluripotency, lineage patterning, transcriptional networks, stem cell differentiation, and development.

The Drosophila U1-70K protein is required for viability, but its arginine-rich domain is dispensable.

The conserved spliceosomal U1-70K protein is thought to play a key role in RNA splicing by linking the U1 snRNP particle to regulatory RNA-binding proteins. Although these protein interactions are mediated by repeating units rich in arginines and serines (RS domains) in vitro, tests of this domain's importance in intact multicellular organisms have not been carried out. Here we report a comprehensive genetic analysis of U1-70K function in Drosophila. Consistent with the idea that U1-70K is an essential splicing factor, we find that loss of U1-70K function results in lethality during embryogenesis. Surprisingly, and contrary to the current view of U1-70K function, animals carrying a mutant U1-70K protein lacking the arginine-rich domain, which includes two embedded sets of RS dipeptide repeats, have no discernible mutant phenotype. Through double-mutant studies, however, we show that the U1-70K RS domain deletion no longer supports viability when combined with a viable mutation in another U1 snRNP component. Together our studies demonstrate that while the protein interactions mediated by the U1-70K RS domain are not essential for viability, they nevertheless contribute to an essential U1 snRNP function.