The functions of molecular chaperones have been extensively investigated biochemically in vitro and genetically in bacteria and yeast. We have embarked on a functional genomic analysis of the Hsp90 chaperone machine in the mouse by disrupting the p23 gene using a gene trap approach. p23 is an Hsp90 cochaperone that is thought to stabilize Hsp90-substrate complexes and, independently, to act as the cytosolic prostaglandin E2 synthase. Gene deletions in budding and fission yeasts and knock-down experiments with the worm have not revealed any clear in vivo requirements for p23. We find that p23 is not essential for overall prenatal development and morphogenesis of the mouse, which parallels the observation that it is dispensable for proliferation in yeast. In contrast, p23 is absolutely necessary for perinatal survival. Apart from an incompletely formed skin barrier, the lungs of p23 null embryos display underdeveloped airspaces and substantially reduced expression of surfactant genes. Correlating with the known function of glucocorticoids in promoting lung maturation and the role of p23 in the assembly of a hormone-responsive glucocorticoid receptor-Hsp90 complex, p23 null fibroblast cells have a defective glucocorticoid response. Thus, p23 contributes a nonredundant, temporally restricted, and tissue-specific function during mouse development.p23 is a small, acidic, ubiquitous protein found in all eukaryotes from yeast through worms to humans. Mouse p23 is ubiquitously expressed in virtually all tissues with the notable exception of striated muscle, where its homolog tsp23 is expressed (reference 16 and data not shown). It was first characterized and named as an essential component of the Hsp90 molecular chaperone complex with the progesterone receptor (29). Since then, it has been shown to be associated with many other Hsp90 clients (15), including other steroid receptors, active telomerase (25), the transcription factor Hsf1, the tyrosine kinase Fes and the Ah receptor (40), and the reverse transcriptase of duck hepatitis virus (26). p23 binds the ATPbound form of Hsp90 and blocks its ATPase activity, thereby stabilizing that state and thus client protein binding (2,15,35,48). In addition, p23 has Hsp90-independent activities. It possesses an autonomous chaperone activity (5, 17) and has been proposed to act as a recycling factor for steroid receptors following their binding to DNA target sequences (18). Surprisingly, p23 also functions as the cytosolic glutathione-dependent prostaglandin E2 synthase (52).The global function of p23 in vivo has yet to be clearly established. It is dispensable for proliferation in budding (4) and fission (39) yeasts. In the worm Caenorhabditis elegans, RNA interference experiments have yielded contradictory results (see data for gene ZC395.10 at http://www.wormbase .org). Thus, despite multiple biochemical studies and the aforementioned limited information from genetic experiments, the functional importance of p23 in a more complex organism has yet to be characterized.In the pres...
