Jeff DeJong

Identification of a General Transcription Factor TFIIAα/β Homolog Selectively Expressed in Testis

In this paper we describe the isolation of a cDNA that encodes a human TFIIAα/β-likefactor (ALF). The open reading frame of ALF predicts a protein of 478 amino acids that contains characteristic N- and C-terminal conserved domains separated by an internal nonconserved domain. In addition, a rare ALF-containing cDNA, which possesses an extended N terminus (Stoned B/TFIIAα/β-like factor; SALF) has also been identified. The results of Northern and dot blot analyses show that ALF is expressed almost exclusively in testis; in contrast, TFIIAα/β and TFIIAγ are enriched in testis but are also widely expressed in other human tissues. Recombinant ALF (69 kDa) and TFIIAγ (12 kDa) polypeptides produced in Escherichia coli form an ALF/γ complex that can stabilize TBP-TATA interactions in an electrophoretic mobility shift assay. The ALF/γ complex is also able to restore transcription from the adenovirus major late promoter using HeLa cell nuclear extracts that have been depleted of TFIIA. Overall, the data show that ALF is a functional homolog of human general transcription factor TFIIAα/β that may be uniquely important to testis biology.

TFIIAα/β-Like Factor Is Encoded by a Germ Cell-Specific Gene Whose Expression Is Up-Regulated with Other General Transcription Factors During Spermatogenesis in the Mouse

Abstract TFIIAα/β-like factor (ALF) is a testis-specific counterpart of the large subunit of human general transcription factor TFIIA. Northern analysis shows that ALF mRNA first appears in mouse testis at Postnatal Day 14. Similarly, expression of the general transcription factors TBP, TRF2, TFIIAα/β, TFIIAγ, and TFIIIB90 is also increased beginning at Postnatal Day 14, suggesting that there is a coordinated induction of many general transcription factors during male germ cell differentiation. Analysis of male germ cells separated by Staput sedimentation shows that ALF is present in pachytene spermatocytes and haploid spermatids. In addition, in situ hybridization experiments with adult mouse testis shows that ALF is present in haploid spermatids. Searches of the human genome sequence database using the basic local alignment search tool reveal that the ALF and TFIIAα/β (GTF2A1) genes are both composed of nine exons, whereas the TFIIAγ (GTF2A2) gene is composed of five exons. Furthermore, nucleotide and amino acid comparisons among human and mouse ALF, TFIIAα/β, and TFIIAγ cDNA sequences show that ALF has diverged more rapidly than either TFIIAα/β or TFIIAγ. Finally, the ALF and SBLF (Stoned B-Like Factor) sequences present in the chimeric SALF cDNA are both present on human chromosome 2, and an analysis of the corresponding genes suggests a model for the formation of SALF.

A Short Core Promoter Drives Expression of the ALF Transcription Factor in Reproductive Tissues of Male and Female Mice

Abstract The control of gene expression in reproductive tissues involves a number of unique germ cell-specific transcription factors. One such factor, ALF (TFIIAτ), encodes a protein similar to the large subunit of general transcription factor TFIIA. To understand how this factor is regulated, we characterized transgenic mice that contain the ALF promoter linked to either β-galactosidase or green fluorescent protein (GFP) reporters. The results show that as little as 133 base pairs are sufficient to drive developmentally accurate and cell-specific expression. Transgene DNA was methylated and inactive in liver, but could be reactivated in vivo by system administration of 5-aza, 2′-deoxycytidine. Fluorescence-activated cell sorting allowed the identification of male germ cells that express the GFP transgene and provides a potential method to collect cells that might be under the control of a nonsomatic transcription system. Finally, we found that transcripts from the endogenous ALF gene and derived transgenes can also be detected in whole ovary and in germinal vesicle-stage oocytes of female mice. The ALF sequence falls into a class of germ cell promoters whose features include small size, high GC content, numerous CpG dinucleotides, and an apparent TATA-like element. Overall, the results define a unique core promoter that is active in both male and female reproductive tissues, and suggest mouse ALF may have a regulatory role in male and female gametogenic gene expression programs.

Microsomal GST-I: genomic organization, expression, and alternative splicing of the human gene.

In this paper we report the genomic organization of the human microsomal GST-I gene. This gene spans 18 kb, and contains seven exons. Sequences that encode the 155 amino acid open reading frame are present in Exons II, III, IV, the 5-untranslated region is present in Exons Ia, Ib, Ic, Id, and II, and the 3-untranslated region is present in Exon IV. Exons Ia, Ib, Ic, Id, and III are alternatively spliced to generate at least six different mGST-I transcripts. The results of EST and PCR analysis show that most mGST-I transcripts terminate within Exon Ib, and primer extension analysis shows these transcripts initiate at three major sites located at 79, 81, and 88 nucleotides upstream of the ATG initiation codon. Sequences surrounding the putative initiation sites are G-C rich, and several Sp1 consensus binding sites were identified. Northern analysis shows that the human GST-I gene is preferentially expressed as a 1.0 kb transcript in liver, and in several other tissues. Finally, a comparison of the mGST-I and PIG12 sequences with those of FLAP, LTC4 synthase, mGST-II, and mGST-III suggests that these proteins are the related products of a dispersed microsomal GST gene superfamily.

Regulation of ALF Promoter Activity in Xenopus Oocytes

Background In this report we evaluate the use of Xenopus laevis oocytes as a matched germ cell system for characterizing the organization and transcriptional activity of a germ cell-specific X. laevis promoter. Principal Findings The promoter from the ALF transcription factor gene was cloned from X. laevis genomic DNA using a PCR-based genomic walking approach. The endogenous ALF gene was characterized by RACE and RT-PCR for transcription start site usage, and by sodium bisulfite sequencing to determine its methylation status in somatic and oocyte tissues. Homology between the X. laevis ALF promoter sequence and those from human, chimpanzee, macaque, mouse, rat, cow, pig, horse, dog, chicken and X. tropicalis was relatively low, making it difficult to use such comparisons to identify putative regulatory elements. However, microinjected promoter constructs were very active in oocytes and the minimal promoter could be narrowed by PCR-mediated deletion to a region as short as 63 base pairs. Additional experiments using a series of site-specific promoter mutants identified two cis-elements within the 63 base pair minimal promoter that were critical for activity. Both elements (A and B) were specifically recognized by proteins present in crude oocyte extracts based on oligonucleotide competition assays. The activity of promoter constructs in oocytes and in transfected somatic Xenopus XLK-WG kidney epithelial cells was quite different, indicating that the two cell types are not functionally equivalent and are not interchangeable as assay systems. Conclusions Overall the results provide the first detailed characterization of the organization of a germ cell-specific Xenopus promoter and demonstrate the feasibility of using immature frog oocytes as an assay system for dissecting the biochemistry of germ cell gene regulation.

Expression of human TFIIA subunits in Saccharomyces cerevisiae identifies regions with conserved and species-specific functions

The transcription factor TFIIA stabilizes the interaction between the TATA-binding protein (TBP) and promoter DNA and facilitates activator function. In yeast, TFIIA is composed of large (TOA1) and small (TOA2) subunits that interact to form a beta-barrel domain and a helix bundle domain. Here we report plasmid shuffle experiments showing that the human subunits (TFIIAalpha/beta, ALF, and TFIIAgamma) are not able to support growth in yeast and that the failure is associated with morphological abnormalities related to cell division. To determine the regions responsible for species specificity, we examined a series of chimeric yeast-human subunits. The results showed that yeast-human hybrids that contained the N-termini of TFIIAgamma or TFIIAalpha/beta were viable, presumably because they could form a functional interspecies alpha-helical bundle. Likewise, a TOA1 hybrid that contained the nonconserved internal region from TFIIAalpha/beta also had no effect on TFIIA function. However, hybrids that contained the acidic region III or C-terminal region IV from TFIIAalpha/beta grew more slowly than the wild-type TOA1 subunit, and if both regions were exchanged, this effect was far more severe. Although these hybrids exchanged sequences which are involved in beta-barrel formation and interactions with TBP, they were all active in a TBP-dependent mobility shift assay. The results suggest that the growth phenotypes of these hybrids might be due to a failure to interact with components of the yeast transcription machinery other than TBP. Finally, we show that sequences from region III of TFIIA large subunits fall into classes that are either highly acidic or that are divergent and nonacidic, and provide the first evidence to suggest that, at least in yeast, this region is important for TFIIA function.