Functional interaction of the retinoblastoma and Ini1/Snf5 tumor suppressors in cell growth and pituitary tumorigenesis

The Ini1 subunit of the SWI/SNF chromatin remodeling complex suppresses formation of malignant rhabdoid tumors in humans and mice. Transduction of Ini1 into Ini1-deficient tumor-derived cell lines has indicated that Ini1 arrests cell growth, controls chromosomal ploidy, and suppresses tumorigenesis by regulating components of the retinoblastoma (Rb) signaling pathway. Furthermore, conditional inactivation of Ini1 in mouse fibroblasts alters the expression of various Rb-E2F-regulated genes, indicating that endogenous Ini1 levels may control Rb signaling in cells. We have reported previously that loss of one allele of Ini1 in mouse fibroblasts results only in a 15% to 20% reduction in total Ini1 mRNA levels due to transcriptional compensation by the remaining Ini1 allele. Here, we examine the effects of Ini1 haploinsufficiency on cell growth and immortalization in mouse embryonic fibroblasts. In addition, we examine pituitary tumorigenesis in Rb-Ini1 compound heterozygous mice. Our results reveal that heterozygosity for Ini1 up-regulates cell growth and immortalization and that exogenous Ini1 down-regulates the growth of primary cells in a Rb-dependent manner. Furthermore, loss of Ini1 is redundant with loss of Rb function in the formation of pituitary tumors in Rb heterozygous mice and leads to the formation of large, atypical Rb(+/-) tumor cells lacking adrenocorticotropic hormone expression. These results confirm in vivo the relationship between Rb and Ini1 in tumor suppression and indicate that Ini1 plays a role in maintaining the morphologic and functional differentiation of corticotrophic cells

An essential role for Dicer in adipocyte differentiation

Dicer is a cellular enzyme required for the processing of pre-miRNA molecules into mature miRNA, and Dicer and miRNA biogenesis have been found to play important roles in a variety of physiologic processes. Recently, reports of alterations in miRNA expression levels in cultured pre-adipogenic cell lines during differentiation and findings of differences between the miRNA expression signatures of white and brown adipose have suggested that miRNA molecules might regulate adipocyte differentiation and the formation of adipose tissue. However, direct evidence that miRNAs regulate adipogenesis is lacking. To determine if Dicer and mature miRNA govern adipocyte differentiation, we utilized primary cells isolated from mice bearing Dicer-conditional alleles to study adipogenesis in the presence or absence of miRNA biogenesis. Our results reveal that Dicer is required for adipogenic differentiation of mouse embryonic fibroblasts and primary cultures of pre-adipocytes. Furthermore, the requirement for Dicer in adipocyte differentiation is not due to miRNA-mediated alterations in cell proliferation, as deletion of the Ink4a locus and the prevention of premature cellular senescence normally induced in primary cells upon Dicer ablation fails to rescue adipogenic differentiation in fibroblasts and pre-adipocytes

Dicer is required for the formation of white but not brown adipose tissue

Dicer, an enzyme involved in microRNA maturation, is required for proper embryo gastrulation and tissue morphogenesis during mammalian development. Using primary cultures of fibroblasts and pre-adipocytes, we have previously shown that Dicer is essential for early stages of adipogenic cell differentiation. In this present study, we have utilized Dicer-conditional mice to explore a role for Dicer and microRNA biogenesis in the terminal differentiation of adipocytes in vivo and in the formation of white and brown adipose tissue. Deletion of Dicer in differentiated adipocytes in Dicer-conditional, aP2-Cre transgenic mice reduced the level of various adipogenic-associated transcripts and inhibited lipogenesis in white adipocytes, resulting in a severe depletion of white adipose tissue in mice. In contrast, Dicer was not required in vivo for lipogenesis in brown adipose or for brown fat formation. However, Dicer deletion in brown adipose did decrease the expression of genes involved in thermoregulation. The results of our study provide genetic evidence of a role for microRNA molecules in regulating adipogenesis and reveal distinct requirements for Dicer in the formation of white and brown adipose tissue. (c) 2010 Wiley-Liss, Inc

SWI/SNF chromatin remodeling enzyme ATPases promote cell proliferation in normal mammary epithelial cells

The ATPase subunits of the SWI/SNF chromatin remodeling enzymes, Brahma (BRM) and Brahma-related gene 1 (BRG1), can induce cell cycle arrest in BRM and BRG1 deficient tumor cell lines, and mice heterozygous for Brg1 are pre-disposed to breast tumors, implicating loss of BRG1 as a mechanism for unregulated cell proliferation. To test the hypothesis that loss of BRG1 can contribute to breast cancer, we utilized RNA interference to reduce the amounts of BRM or BRG1 protein in the nonmalignant mammary epithelial cell line, MCF-10A. When grown in reconstituted basement membrane (rBM), these cells develop into acini that resemble the lobes of normal breast tissue. Contrary to expectations, knockdown of either BRM or BRG1 resulted in an inhibition of cell proliferation in monolayer cultures. This inhibition was strikingly enhanced in three-dimensional rBM culture, although some BRM-depleted cells were later able to resume proliferation. Cells did not arrest in any specific stage of the cell cycle; instead, the cell cycle length increased by approximately 50%. Thus, SWI/SNF ATPases promote cell cycle progression in nonmalignant mammary epithelial cells

IFITM-2 and IFITM-3 but Not IFITM-1 Restrict Rift Valley Fever Virus

We show that interferon-induced transmembrane protein 1 (IFITM-1), IFITM-2, and IFITM-3 exhibit a broad spectrum of antiviral activity against several members of the Bunyaviridae family, including Rift Valley fever virus (RVFV), La Crosse virus, Andes virus, and Hantaan virus, all of which can cause severe disease in humans and animals. We found that RVFV was restricted by IFITM-2 and -3 but not by IFITM-1, whereas the remaining viruses were equally restricted by all IFITMs. Indeed, at low doses of alpha interferon (IFNα), IFITM-2 and -3 mediated more than half of the antiviral activity of IFNα against RVFV. IFITM-2 and -3 restricted RVFV infection mostly by preventing virus membrane fusion with endosomes, while they had no effect on virion attachment to cells, endocytosis, or viral replication kinetics. We found that large fractions of IFITM-2 and IFITM-3 occupy vesicular compartments that are distinct from the vesicles coated by IFITM-1. In addition, although overexpression of all IFITMs expanded vesicular and acidified compartments within cells, there were marked phenotypic differences among the vesicular compartments occupied by IFITMs. Collectively, our data provide new insights into the possible mechanisms by which the IFITM family members restrict distinct viruses