The temperature-sensitive BHK21 hamster cell line tsBN67 ceases to proliferate at the nonpermissive temperature after a lag of one to a few cell divisions, and the arrested cells display a gene expression pattern similar to that of serum-starved cells. The temperature-sensitive phenotype is reversible and results from a single missense mutation-proline to serine at position 134-in HCF, a cellular protein that, together with the viral protein VP16, activates transcription of herpes simplex virus (HSV) immediate-early genes. The tsBN67 HCF mutation also prevents VP16 activation of transcription at the nonpermissive temperature. The finding that the same point mutation in HCF disrupts both VP16 function and the cell cycle suggests that HCF plays a role in cell-cycle progression in addition to VP16-dependent transcription.[Key Words: tsBN67; HCF protein,-VP16 function,-GQ/GI cell cycle arrest; transcription] Received November 14, 1996; accepted in revised form February 7, 1997.Conditional mutations, particularly temperature-sensitive mutations, have been valuable tools for clarifying cell-cycle regulation in yeast as well as mammalian cells (for review, see Marcus et al. 1985). Previously, we have isolated a series of temperature-sensitive cell-proliferation mutants from the hamster BHK21 cell line (Nishimoto and Basilico 1978;Nishimoto et al. 1982). Following mutagenesis with N-methyl-N'-nitro-JV-nitrosoguanidine, mutants that proliferate at the permissive temperature of 33.5°C but not at the nonpermissive temperature of 39.5°C were concentrated through multiple rounds of negative selection with the cytotoxic base analog 5-fluoro-2-deoxyuridine to eliminate proliferating cells at the elevated temperature. Based on the ability of hybrid cells created by the fusion of different mutant lines to grow at the nonpermissive temperature, these temperature-sensitive lines have been classified into 25 complementation groups (Nishimoto and Basilico 1978;Nishimoto et al. 1982).To identify the genes affected by these mutations, human DNA has been used to complement the hamsterPresent address:
The establishment and maintenance of spermatogenesis in mammals requires specialized networks of gene expression programs in the testis. The gonad-specific TAF4b component of TFIID (formerly TAF II 105) is a transcriptional regulator enriched in the mouse testis. Herein we show that TAF4b is required for maintenance of spermatogenesis in the mouse. While young Taf4b-null males are initially fertile, Taf4b-null males become infertile by 3 mo of age and eventually exhibit seminiferous tubules devoid of germ cells. At birth, testes of Taf4b-null males appear histologically normal; however, at post-natal day 3 gonocyte proliferation is impaired and expression of spermatogonial stem cell markers c-Ret, Plzf, and Stra8 is reduced. Together, these data indicate that TAF4b is required for the precise expression of gene products essential for germ cell proliferation and suggest that TAF4b may be required for the regulation of spermatogonial stem cell specification and proliferation that is obligatory for normal spermatogenic maintenance in the adult. Spermatogenesis is a complex process requiring the specialized function of multiple cell types including somatic and germ cells that collectively results in the continuous production of functional sperm in adult males. The unlimited production of male gametes is largely accomplished through the ability of spermatogonial stem cells to self-renew in the adult testis. These complex and multifaceted events are dependent on appropriate expression and action of specific genes at multiple stages of germ cell and testicular development (Matzuk and Lamb 2002;McLaren 2003). The precise temporal and spatial expression of specific transcription factors is also essential for proper execution of spermatogenesis (SassoneCorsi 1997). Emerging evidence now suggests that in addition to gonad-specific transcription factors, specialized components of the basal RNA Polymerase II machinery are also critical for the execution of gonad-specific programs of gene expression (Hochheimer and Tjian 2003).The TFIID complex is a core RNA polymerase complex that contains the TATA-binding protein (TBP) and 14 TBP-associated factors (TAFs) that function in core promoter recognition and activator-dependent RNA Polymerase II recruitment (Verrijzer and Tjian 1996). While most TFIID subunits are expressed and function broadly in most cell types, there are selective TFIID subunits that apparently have evolved to function in the specification of gonadal-specific programs of gene expression. In the mouse, TAF4b is a component of TFIID that is highly enriched in gonadal tissues and is required for ovarian follicle development (Freiman et al. 2001). TAF4b is similar in structure to its broadly expressed paralog TAF4 (TAF II 130). While TAF4 and TAF4b display overlapping expression patterns in certain cell types, TAF4b is essential for regulating the selective expression of ovarian-specific gene expression patterns required for female fertility (Freiman et al. 2001).Several other members of the basal transcription mac...
Transcription factor TFIID, composed of TBP and TAFII subunits, is a central component of the RNA polymerase II machinery. Here, we report that the tissue-selective TAFII105 subunit of TFIID is essential for proper development and function of the mouse ovary. Female mice lacking TAFII105 are viable but infertile because of a defect in folliculogenesis correlating with restricted expression of TAFII105 in the granulosa cells of the ovarian follicle. Gene expression profiling has uncovered a defective inhibin-activin signaling pathway in TAFII105-deficient ovaries. Together, these studies suggest that TAFII105 mediates the transcription of a subset of genes required for proper folliculogenesis in the ovary and establishes TAFII105 as a cell type-specific component of the mammalian transcriptional machinery.
von Recklinghausen neurofibromatosis (NF1) is a common hereditary disorder characterized by neural crest-derived tumors, particularly benign neurofibromas whose malignant transformation to neurofibrosarcomas can be fatal. The NF1 gene has been mapped to a small region of chromosome 17q, but neither the nature of the primary defect nor the mechanisms involved in tumor progression are understood. We have tested whether NF1 might be caused by the inactivation of a tumor suppressor gene on 17q, analogous to that on chromosome 22 in NF2, by searching for deletions of chromosome 17 in NF1-derived tumor specimens. Both neurofibrosarcomas from patients with "atypical" NF and 5 of 6 neurofibrosarcomas from NF1 patients displayed loss of alleles for polymorphic DNA markers on chromosome 17. However, the common region of deletion was on 17p and did not include the NF1 region of 17q. Since no loss of markers on chromosome 17 was observed in any of 30 benign tumors from NF1 patients, the 17p deletions seen in neurofibrosarcomas are probably associated with tumor progression and/or malignancy. This region contains a candidate gene for tumor progression, p53, which has recently been implicated in the progression of a broad array of human cancers. In a preliminary search for p53 aberrations by direct sequencing of polymerase chain reaction-amplified DNA from 7 neurofibrosarcomas, 2 tumors that contained point mutations in exon 4 of the p53 gene were found, suggesting a role for this gene in at least some neurofibrosarcomas. Thus the formation of malignant neurofibrosarcomas may result from several independent genetic events including mutation of the NF1 gene, whose mechanism of tumorigenesis remains uncertain, and subsequent loss of a "tumor suppressor" gene on 17p, most likely p53.
The herpes simplex virus (HSV) regulatory protein VP16 activates HSV immediate-early gene transcription through formation of a multiprotein-DNA complex on viral promoters that includes the preexisting nuclear proteins HCF and Oct-1. The HCF protein is a complex of amino-and carboxy-terminal polypeptides derived from a large (ϳ2,000-amino-acid) precursor by proteolytic processing. Here we show that a 361-residue amino-terminal region of HCF is sufficient to bind VP16, stabilize VP16-induced complex assembly with Oct-1 and DNA, and activate transcription in vivo. This VP16 interaction region contains six kelch-like repeats, a degenerate repeat motif that is likely to fold as a distinctive -propeller structure. The third HCF kelch repeat includes a proline residue (P134) that is mutated to serine in hamster tsBN67 cells, resulting in a temperaturesensitive defect in cell proliferation. This missense mutation also prevents direct association between HCF and VP16, suggesting that VP16 mimics a cellular factor required for cell proliferation. Rescue of the tsBN67 cell proliferation defect by HCF, however, requires both the VP16 interaction domain and an adjacent basic region, indicating that HCF utilizes multiple regions to promote cell cycle progression.Lytic infection by herpes simplex virus (HSV) is characterized by a cascade of sequential gene expression initiated by the virion protein VP16. Upon infection, VP16 (also known as Vmw65 or ␣TIF) is released into the cell, whereupon it promotes the formation of a multiprotein-DNA complex with two cellular factors, HCF (also known as C1, VCAF, or CFF) and Oct-1. VP16 associates with HCF independently of DNA (14,17,44), which stabilizes the association of VP16 with Oct-1 on VP16-responsive cis-regulatory sites -the TAATGARAT element -within the HSV immediate-early promoters (11, 15). The formation of this VP16-induced complex initiates the cascade of HSV gene expression (reviewed in references 25 and 33).In human cells, HCF comprises a family of 110-to 150-kDa polypeptides (18, 39) derived from a 2,035-amino-acid precursor protein (HCF 300 ) through proteolytic processing: cleavage at any one of a series of six centrally located 26-amino-acid repeats, called the HCF repeats, results in amino-and carboxyterminal HCF fragments which remain associated after cleavage (16,39,41).Although the precise cellular function of HCF has not been established, analysis of a temperature-sensitive hamster cell line, called tsBN67 (24), has revealed that HCF is required for cell proliferation (12). At the nonpermissive temperature, tsBN67 cells undergo a G 0 /G 1 cell cycle arrest, which is due to a proline-to-serine substitution at position 134 (P134S) in the amino-terminal region of HCF (12). HCF stability and processing are not affected by the tsBN67 mutation, but VP16-induced complex formation and VP16 activation of transcription are both disrupted at the nonpermissive temperature (12).Whether the defect in VP16 activity is due to a direct effect on the VP16-HCF interaction or an indi...
Upon infection of human cells, the herpes simplex virus protein VP16 associates with the endogenous cell-proliferation factor HCF. VP16 can also associate with HCFs from invertebrates, suggesting that VP16 mimics a cellular protein whose interaction with HCF has been conserved. Here, we show that VP16 mimics the human basic leucine-zipper protein LZIP, which, through association with HCF, may control cell-cycle progression. VP16 and LZIP share a tetrapeptide motif-D / E HXYused to associate with human HCF. The LZIP-related Drosophila protein BBF-2/dCREB-A contains this HCFbinding motif, indicating that the LZIP-HCF interaction has been conserved during metazoan evolution.
The adult mammalian ovary is devoid of definitive germline stem cells. As such, female reproductive senescence largely results from the depletion of a finite ovarian follicle pool that is produced during embryonic development. Remarkably, the crucial nature and regulation of follicle assembly and survival during embryogenesis is just coming into focus. This developmental pathway involves the coordination of meiotic progression and the breakdown of germ cell cysts into individual oocytes housed within primordial follicles. Recent evidence also indicates that genetic and environmental factors can specifically perturb primordial follicle assembly. Here, we review the cellular and molecular mechanisms by which the mammalian ovarian reserve is established, highlighting the presence of a crucial checkpoint that allows survival of only the highest-quality oocytes.
Chromatin modifications are essential for directing transcription during embryonic development. Bromodomain-containing protein 2 (Brd2; also called RING3 and Fsrg1) is one of four BET (bromodomain and extra terminal domain) family members known to selectively bind acetylated histones H3 and H4. Brd2 associates with multiple subunits of the transcriptional apparatus including the mediator, TFIID and Swi/Snf multi-protein complexes. While molecular interactions of Brd2 are known, the functions of Brd2 in mammalian embryogenesis remain unknown. In developing a mouse model deficient in Brd2, we find that Brd2 is required for the completion of embryogenesis and proper neural tube closure during development. Embryos lacking Brd2 expression survive up to embryonic day 13.5, soon after mid-gestation, and display fully penetrant neurulation defects that largely result in exencephaly of the developing hindbrain. In this study, we find that highest expression of Brd2 is detected in the developing neural tube, correlating with the neural tube defects found in Brd2-null embryos. Additionally, embryos lacking Brd2 expression display altered gene expression programs, including the mis-expression of multiple genes known to guide neuronal development. Together these results implicate essential roles for Brd2 as a critical integrator of chromatin structure and transcription during mammalian embryogenesis and neurogenesis.
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