Isolation and characterization of the TIGA genes, whose transcripts are induced by growth arrest

We report here the isolation of 44 genes that are upregulated after serum starvation and/or contact inhibition. These genes have been termed TIGA, after Transcript Induced by Growth Arrest. We found that there are two kinds of G0 phases caused by serum starvation, namely, the shallow G0 (or G0/G1) and the deep G0 phases. The shallow G0 is induced by only a few hours of serum starvation, while deep G0 is generated after 3 days of serum starvation. We propose that mammalian cells enter deep G0 through a G0 gate, which is only opened on the third day of serum starvation. TIGA1, one of the uncharacterized TIGA genes, encodes a homolog of cyanate permease of bacteria and localizes in mitochondria. This suggests that Tiga1 is involved in the inorganic ion transport and metabolism needed to maintain the deep G0 phase. Ectopic expression of TIGA1 inhibited not only tumor cell proliferation but also anchorage-independent growth of cancer cell lines. A microsatellite marker, ENDL-1, allowed us to detect loss of heterozygosity around the TIGA1 gene region (5q21–22). Further analysis of the TIGA genes we have identified here may help us to better understand the mechanisms that regulate the G0 phase

Comprehensive DNA Methylation Analysis of Retrotransposons in Male Germ Cells

De novo DNA methylation of retrotransposons is critical for silencing. Here, we use DNA methylation analysis to examine retrotransposons in mouse male germ cells. DNA methylation of long interspersed nuclear elements (LINEs) is dependent on piRNA, and younger LINEs exhibit greater piRNA dependence. In contrast, most long terminal repeat (LTR) retrotransposons produce lower levels of piRNAs and do not show significant piRNA dependence. The relationship between DNA methylation and corresponding piRNA expression of several LTR retrotransposons was reduced in Mili-null cells, but not Miwi2-null cells. These observations raise the possibility of piRNA-dependent DNA methylation without Miwi2. Therefore, it appears that the molecular mechanisms of the gene silencing of retrotransposons are more complicated than previously thought

Relationship between PIWIL4-Mediated H3K4me2 Demethylation and piRNA-Dependent DNA Methylation

Summary: Retrotransposon genes are silenced by DNA methylation because of potential harm due to insertional mutagenesis. DNA methylation of retrotransposon genes is erased and re-established during male germ cell development. Both piRNA-dependent and piRNA-independent mechanisms are active during the re-establishment process, with the piRNA-independent mechanism occurring first. In this study, we analyzed the role of PIWIL4/MIWI2 in the modification of histone H3 and subsequent piRNA-dependent DNA methylation. Dimethylation at H3K4 is highly enriched at piRNA-dependent methylated regions and anti-correlated with de novo DNA methylation during the phase of piRNA-independent DNA methylation. In addition, PIWIL4, which binds the H3K4 demethylases KDM1A and KDM5B, is required for removing H3K4me2 marks. These data show that PIWIL4 plays important roles in histone modification and piRNA-dependent DNA methylation. : Nagamori et al. report that H3K4me2 is enriched at piRNA-dependent regions, such as LINE1s/L1s, in embryonic germ cells. H3K4me2 is subsequently erased in a PIWIL4-dependent manner. They postulate that preferential interaction of PIWIL4 with KDM1A and KDM5B plays a critical role in PIWIL4-dependent methylation erasure. Keywords: germ cell, spermatogenesis, DNA methylation, piRNA, gonocyt

MIWI2 as an Effector of DNA Methylation and Gene Silencing in Embryonic Male Germ Cells

During the development of mammalian embryonic germ cells, global demethylation and de novo DNA methylation take place. In mouse embryonic germ cells, two PIWI family proteins, MILI and MIWI2, are essential for the de novo DNA methylation of retrotransposons, presumably through PIWI-interacting RNAs (piRNAs). Although piRNA-associated MIWI2 has been reported to play critical roles in the process, its molecular mechanisms have remained unclear. To identify the mechanism, transgenic mice were produced; they contained a fusion protein of MIWI2 and a zinc finger (ZF) that recognized the promoter region of a type A LINE-1 gene. The ZF-MIWI2 fusion protein brought about DNA methylation, suppression of the type A LINE-1 gene, and a partial rescue of the impaired spermatogenesis of MILI-null mice. In addition, ZF-MIWI2 was associated with the proteins involved in DNA methylation. These data indicate that MIWI2 functions as an effector of de novo DNA methylation of the retrotransposon

Nuclear regulator Pygo2 controls spermiogenesis and histone H3 acetylation

Mammalian spermiogenesis, a Process where haploid male germ cells differentiate to become mature spermatozoa, entails dramatic Morphological and biochemical changes including remodeling of the germ cell chromatin. Proteins that contain one or more plant homeodomain (PHD) fingers have been implicated in the regulation of chromatin Structure and function. Pygopus 2 (Pygo2) belongs to a family of evolutionarily conserved PHD finger proteins thought to act as co-activators of Wnt signaling effector complexes composed of beta-catenin and LEF/TCF transcription factor. Here we analyze mice containing hypomorphic alleles of pygopus 2 (Pygo2 or mpygo2) and uncover a beta-catenin-independent involvement of the Pygo2 protein in spermiogenesis. Pygo2 is expressed in elongating spermatids at stages when chromatin remodeling occurs, and block of Pygo2 function leads to spermiogenesis arrest and consequent infertility. Analysis of spermiogenesis in Pygo2 mutants reveals reduced expression of select post-meiotic genes including protamines, transition protein 2, and H1fnt, all of which are required for germ cell chromatin condensation, and drastically altered pattern of histone H3 hyperacetylation. These findings suggest that Pygo2 is involved in the chromatin remodeling events that lead to nuclear compaction of male germ cells. (C) 2008 Elsevier Inc. All rights reserved.DOD [W81XWH-04-1-0516]; NIH [R01-AR47320, K02-AR51482