Primate testicular histone H1t genes are highly conserved and the human H1t gene is located on chromosome 6

Testis-specific transcriptional control

In the testis, tissue-specific transcription is essential for proper expression of the genes that are required for the reproduction of the organism. Many testis-specific genes are required for mitotic proliferation of spermatogonia, spermatocytes undergoing genetic recombination and meiotic divisions, and differentiation of haploid spermatids. In this article we describe some of the genes that are transcribed in male germinal cells and in non-germinal testis cells. Because significant progress has been made in examination of promoter elements and their cognate transcription factors that are involved in controlling transcription of the testis-specific linker histone H1t gene in primary spermatocytes, this work will be reviewed in greater detail. The gene is transcriptionally active in spermatocytes and repressed in all other germinal and non-germinal cell types and, therefore, it serves as a model for study of regulatory mechanisms involved in testis-specific transcription.

Transcriptional repression of the testis-specific histone H1t gene mediated by an element upstream of the H1/AC box

The testis-specific histone H1t gene is transcribed exclusively in primary spermatocytes and may be important for chromatin structure, transcription, and DNA repair during this stage of spermatogenesis. Transcriptional repression of the gene in other cell types is mediated in part by specific proximal and distal promoter elements and in some cell types by methylation of CpG dinucleotides within the promoter. Our laboratory identified a distal promoter element located between 948 and 780 bp upstream from the transcription initiation site and another laboratory identified a GC-rich region between the TATA box and transcription initiation site that contribute to repression. In this article we address transcriptional repression of the histone H1t gene by an element within the proximal promoter. We report discovery of an element designated H1t promoter repressor element (RE) located between -130 and -106 bp that contributes to repression. The findings support the hypothesis that multiple mechanisms are involved in transcriptional repression of the H1t gene. Transcriptional repression mediated by the RE element in NIH 3T3 cells appears to differ significantly from the mechanism mediated by the GC-rich region. Furthermore, binding proteins that form the RE complex are not present in rat testis where the gene is actively transcribed. Our findings provide a molecular basis for histone H1t gene repression.

Sp1 and Sp3 activate the testis-specific histone H1t promoter through the H1t/GC-box

The testis-specific linker histone H1t gene is transcribed exclusively in mid to late pachytene primary spermatocytes. Tissue specific expression of the gene is mediated in large part through elements located within the proximal promoter. Previous work in transgenic animals showed that a unique 40 bp promoter element designated H1t/TE is essential for spermatocyte-specific expression. The H1t/TE element contains a GC-box, which is a perfect consensus binding site for members of the Sp family of transcription factors. We have shown that Sp1 and Sp3 are present in testis cells from 9-day-old and adult rats and in pachytene primary spermatocytes and early spermatids and that they can bind to the H1t/GC-box. Mutagenesis of the GC-box reduced H1t promoter activity. Furthermore, a CpG dinucleotide within the GC-box was totally unmethylated in rat testis primary spermatocytes where the gene is transcribed but it was methylated in liver where the gene is silenced. These previous studies supported the importance of the GC-box and suggested that Sp transcription factors contribute to expression of the H1t gene. In this study, we show that co-transfection of Sp1 and Sp3 expression vectors leads to an upregulation of histone H1t promoter activity in several cell lines including testis GC-2spd cells. However, very low H1t promoter activity is seen in GC-2spd cells grown at 39 degrees C, which correlates with lower levels of Sp1 and Sp3 in these cells grown at this elevated temperature. Upregulation of the H1t promoter by Sp1 and Sp3 was also seen in cotransfected NIH3T3 and C127I cell lines. On the other hand, co-transfection of the Sp1 and Sp3 expression vectors does not lead to upregulation of activity of the cell-cycle dependent histone H1d promoter.

Mice with a targeted disruption of the H1t gene are fertile and undergo normal changes in structural chromosomal proteins during spermiogenesis

H1t is an H1 histone variant unique to late spermatocytes and early spermatids. Using gene targeting and embryonic stem cell technologies, we have produced mice with a disrupted H1t gene. Homozygous H1t-null mice have normal fertility and show no obvious phenotypic consequence due to the lack of this histone. Biochemical and immunohistochemical approaches were used to show that normal changes in chromosomal proteins occurred during spermatid development, including the appearance and disappearance of transition proteins 1 and 2. Both protamines 1 and 2 are present in normal amounts in sonication-resistant spermatid nuclei from H1t-null mice. Analysis of H1 histones by quantitative gel electrophoresis in enriched populations of pachytene spermatocytes and round spermatids showed that the lack of H1t is only partially compensated for by somatic H1s, so that the chromatin of these cells is H1 deficient. Because H1t is thought to create a less tightly compacted chromatin environment, it may be that H1-deficient chromatin is functionally similar to chromatin with H1t present, at least with respect to permitting spermatogenesis to proceed.

Elimination of male germ cells in transgenic mice by the diphtheria toxin A chain gene directed by the histone H1t promoter

Expression of the diphtheria toxin A-chain gene was directed to the male germ line by fusion to 1 kilobase of the 5'-flanking DNA of the rat histone H1t gene. Two independent lines of mice were established that expressed the toxic transgene. Female carriers were fertile; males were sterile although otherwise apparently normal. Adult transgenic males had very small testes that were virtually devoid of germ cells. A developmental study showed that germ cells survived until late fetal life but that testes of 3-day-old transgenic mice were severely depleted of prospermatogonia. During postnatal development of transgenic animals, remaining germ cells progressed to the pachytene stage of meiosis in 10% to 30% of tubular cross sections but degenerated before the completion of meiosis. By 3 mo of age the residual germ cells had almost completely disappeared. These transgenic lines demonstrate the complete tissue specificity of the H1t promoter and reveal a period of its activity just prior to formation of the definitive adult spermatogonial stem cell population. Whereas full expression of H1t occurs only in mid to late pachytene spermatocytes, one or more of the factors that impart tissue specificity to its expression must be transiently activated in the neonatal germ line. This report discusses the possibility that this genetic technique for eliminating germ cells may have practical application in making recipients for spermatogonial stem cell transplantation.

Growth regulation of human variant histone genes and acetylation of the encoded proteins

The family of human histone genes consists of replication-dependent and independent subtypes. The replication-independent histone genes, also known as variants, give rise to distinct mRNAs, whose expression is regulated depending on the growth state of the cell, tissue type and developmental stage. In turn, the histone variants are differentially synthesized and modified by acetylation. Consequently, chromatin structure is altered resulting in complex changes in gene expression. The high conservation among histone protein subtypes suggests that they are indispensable. In addition, conservation of the positions of acetylation within subtypes suggests that the location of these sites is functionally important for the eukaryotic cell. For example, the structures of transcriptionally active and repressed chromatin are different depending on the acetylation state of histone proteins [1-3]. In addition, transcriptionally active and repressed chromatin contains distinct histone variants [4]. Specialized histone variants are targeted to the centromere of the chromosome, where they are essential for chromosome segregation [5]. Other specialized histones exist that are essential for development [6]. Changes in histone acetylation have been implicated in the down-regulation of a tumour suppressor gene in human breast cancer [7]. Acetylation also plays an important role in X chromosome inactivation as well as hormone-mediated transcriptional regulation [8, 9]. We propose here a novel model for histone variant gene regulation at the post-transcriptional level, which provides the groundwork to define the pathways regulating the synthesis of these variants.

The TE promoter element of the histone H1t gene is essential for transcription in transgenic mouse primary spermatocytes

Transcriptional activation of the testis-specific histone H1t gene occurs in pachytene primary spermatocytes during spermatogenesis. Specific binding of testis nuclear proteins to a rat histone H1t promoter sequence, designated the H1t/TE element, correlates with the onset of transcription. This element, located between the H1t/AC box and the H1t/CCAAT box, contains inverted repeats of a shorter element. When the native rat H1t gene along with flanking sequences, including 2453 base pairs (bp) upstream and 3784 bp downstream from the coding region, was microinjected into mouse embryos, the offspring of the resulting transgenic mice transcribed the transgene in a tissue-specific manner and only in primary spermatocytes. In the present study the TE promoter element was deleted and replaced with a heterologous stuffer DNA fragment. When the mutant rat DNA fragment was used to create transgenic mice, offspring of the mice bearing the promoter mutation did not transcribe the rat H1t gene in any tissue. On the other hand, transcription of the rat H4t transgene, which is located approximately 1.5 kilobases downstream from the H1t gene, occurred in these animals. Therefore, these studies support the hypothesis that the TE element is essential for enhanced testis-specific transcription of the H1t gene in primary spermatocytes.

The testis-specific histone H1t gene is strongly repressed by a G/C-rich region just downstream of the TATA Box

H1t is a testis-specific histone 1 variant restricted to the male germ line and expressed only in pachytene spermatocytes. Understanding the regulation of the H1t gene is an interesting challenge as its promoter shares all of the recognized control elements of standard somatic H1 genes, yet H1t is not expressed in somatic or in early spermatogenic cells. To investigate the mechanism of this apparent repression, we exchanged three promoter subregions between H1t and a major somatic H1 gene (H1d) by introduction of suitable restriction sites just 5' of the TATA box and 3' of the conserved H1 AC box. Hybrid promoters were joined to a lacZ reporter gene and assayed by transient transfection in NIH3T3 fibroblasts. In this system the wild type H1d promoter was 20-fold stronger than the H1t promoter. Much of this difference in activity was traced to inhibitory sequences immediately downstream of the TATA box in H1t, although sequences upstream of the H1t AC box and within the H1t 5'-untranslated region played some role as well. A series of deletions and short oligonucleotide mutations scanned across the region between the TATA box and cap site identified two tracts of C (GC box 2) as the inhibitory sequences. While both Sp1 and Sp3 bind to this region weakly in vitro, they are unlikely to be responsible for the inhibitory effect of GC box 2, and additional binding proteins (CTB-4 and CTB-5) were identified by electrophoretic mobility shift assays as better candidates for mediating the repressive effect. When repression of the H1t promoter was relieved by mutation of GC box 2, additional mutations introduced into GC box 1 upstream of the CAAT box led to a large decrease in activity, indicating that these two G/C-rich elements have opposite effects on promoter activity.

Regulation of transcription of the testis-specific histone H1t gene by multiple promoter elements

This is a review of mechanisms that contribute to testis-specific transcription of the histone H1t gene. The mammalian testis-specific histone H1t gene is transcribed only in primary spermatocytes during spermatogenesis. Linker histones bind to DNA and contribute to chromatin condensation by formation of the 30 nm chromatin fiber. Furthermore, linker histones contribute to regulation of transcription of specific genes. Histone H1t, which binds more weakly to DNA than the other six known linker histones, is expressed in cells that are involved in the essential processes of crossing over and mismatch repair of DNA and in cells that undergo a dramatic alteration in gene expression. However, contributions of this linker histone to these processes are unknown. Subtle differences are found in the H1t promoter compared to the other H1 promoters. Nevertheless, several lines of evidence support the hypothesis that a sequence element designated TE that is located within the H1t promoter is essential for enhanced testis-specific transcription of this gene. Transgenic mice bearing a rat H1t transgene which contains a replacement of the TE element with stuffer DNA fail to express rat H1t mRNA. In addition, an upstream sequence appears to function as a silencer element that leads to transcriptional repression of the H1t gene in nongerminal cells. Thus, multiple promoter elements appear to contribute to regulation of transcription of the histone H1t gene.

Cux/CDP homeodomain protein binds to an enhancer in the rat c-mos locus and represses its activity

The c-mos gene is transcribed in male and female germ cells, in differentiating myoblasts and in 3T3 cells from cell-specific promoters. We characterized the rat testis promoter, which contains a TATA-box and one binding site for a testis-specific transcription factor TTF-D, as well as a region which can act as enhancer, which is located approx. 2 kb upstream of the c-mos AUG start codon. It binds three factors at sites I, II and III as determined in DNAse I footprint assays. We demonstrated that a member of the NF-1/CTF family of transcription factors binds site II. Here we report the cloning of the protein that binds to enhancer site III. This protein is the rat homolog of human hCut/CDP, mouse Cux/CDP and canine Clox. hCut/Cux/CDP/Clox (hereafter called Cux/CDP), a 160 kDa protein containing multiple repeats and a homeodomain, negatively regulates the mammalian c-myc, gp91-phox and N-Cam genes. Using bacterially produced murine GST-Cux fusion proteins and GST-Cux deletion mutants, we find that Cux repeat CR3 and the homeodomain are both required for efficient binding to enhancer site III. Mouse lung and testis nuclear Cux/CDP bind to site III as determined in electrophoretic gel mobility supershift assays using two different anti-hCut specific monoclonal antibodies. Transfections of CAT constructs containing the enhancer fragment linked to a minimal promoter demonstrated that Cux/CDP represses c-mos enhancer activity.

Binding of nuclear proteins to a conserved histone H1t promoter element suggests an important role in testis-specific transcription

The testis-specific histone H1t gene is transcribed only in primary spermatocytes during spermatogenesis. Recently, expression of the rat gene was shown to be limited to primary spermatocytes in transgenic mice, revealing that promoter elements sufficient for regulating tissue-specific transcription were present in the cloned rat gene. In this study the mouse histone H1t gene has been cloned, and sequenced and its promoter region has been compared to the rat H1t promoter with regard to conserved elements and protein binding activity. The amino acid sequence of each of the three H1t coding region domains is conserved when compared to the homologous domain in H1t derived from other species. H1t mRNA is found only in testis, where it accumulates to a high steady-state level, and examination of enriched testis cell populations shows that expression is limited to primary spermatocytes. Protein binding assays using nuclear extracts from various mouse tissues reveal testis-specific binding to TE1 and TE2, imperfect inverted repeat elements within the larger TE element. Although the H1t promoter contains an Sp1 consensus motif within the H1t/TE element, binding of testis Sp1 to the motif could not be detected using specific anti-Sp1 antibodies.

Developmentally regulated expression of linker-histone variants in vertebrates

The identification of histone H1 variants in vertebrates suggests that these proteins may have specialized functions. During embryonic development, a correspondence between the expression of each of the linker-histone variants and the proliferative and transcriptional activity of embryonic cells can be observed. Analysis of the developmentally regulated expression of these variants leads to the subdivision of these variants into distinct classes. This subdivision may also provide insight into the significance of the differential expression of variants and the roles individual linker histones have in chromatin structure and function.