Transcription and RNA processing of mammalian genes in Saccharomyces cerevisiae

Copy-number variation introduced by long transgenes compromises mouse male fertility independently of pachytene checkpoints

Long transgenes are often used in mammalian genetics, e.g., to rescue mutations in large genes. In the course of experiments addressing the genetic basis of hybrid sterility caused by meiotic defects in mice bearing different alleles of Prdm9, we discovered that introduction of copy-number variation (CNV) via two independent insertions of long transgenes containing incomplete Prdm9 decreased testicular weight and epididymal sperm count. Transgenic animals displayed increased occurrence of seminiferous tubules with apoptotic cells at 18 days postpartum (dpp) corresponding to late meiotic prophase I, but not at 21 dpp. We hypothesized that long transgene insertions could cause asynapsis, but the immunocytochemical data revealed that the adult transgenic testes carried a similar percentage of asynaptic pachytene spermatocytes as the controls. These transgenic spermatocytes displayed less crossovers but similar numbers of unrepaired meiotic breaks. Despite slightly increased frequency of metaphase I spermatocytes with univalent chromosome(s) and reduced numbers of metaphase II spermatocytes, cytological studies did not reveal increased apoptosis in tubules containing the metaphase spermatocytes, but found an increased percentage of tubules carrying apoptotic spermatids. Sperm counts of subfertile animals inversely correlated with the transcription levels of the Psmb1 gene encoded within these two transgenes. The effect of the transgenes was dependent on sex and genetic background. Our results imply that the fertility of transgenic hybrid animals is not compromised by the impaired meiotic synapsis of homologous chromosomes, but can be negatively influenced by the increased expression of the introduced genes.

A Mutation of the Prdm9 Mouse Hybrid Sterility Gene Carried by a Transgene

PRDM9 is a protein with histone-3-methyltransferase activity, which specifies the sites of meiotic recombination in mammals. Deficiency of the Prdm9 gene in the laboratory mouse results in complete arrest of the meiotic prophase of both sexes. Moreover, the combination of certain PRDM9 alleles from different mouse subspecies causes hybrid sterility, e.g., the male-specific meiotic arrest found in the (PWD/Ph × C57BL/6J)F1 animals. The fertility of all these mice can be rescued using a Prdm9-containing transgene. Here we characterized a transgene made from the clone RP24-346I22 that was expected to encompass the entire Prdm9 gene. Both (PWD/Ph × C57BL/6J)F1 intersubspecific hybrid males and Prdm9-deficient laboratory mice of both sexes carrying this transgene remained sterile, suggesting that Prdm9 inactivation occurred in the Tg(RP24-346I22) transgenics. Indeed, comparative qRT-PCR analysis of testicular RNAs from transgene-positive versus negative animals revealed similar expression levels of Prdm9 mRNAs from the exons encoding the C-terminal part of the protein but elevated expression from the regions coding for the N-terminus of PRDM9, indicating that the transgenic carries a new null Prdm9 allele. Two naturally occurring alternative Prdm9 mRNA isoforms were overexpressed in Tg(RP24-346I22), one formed via splicing to a 3'-terminal exon consisting of short interspersed element B2 and one isoform including an alternative internal exon of 28 base pairs. However, the overexpression of these alternative transcripts was apparently insufficient for Prdm9 function or for increasing the fertility of the hybrid males.

Isolation of Sporothrix schenckii GDA1 and functional characterization of the encoded guanosine diphosphatase activity

Sporothrix schenckii is a fungal pathogen of humans and the etiological agent of sporotrichosis. In fungi, proper protein glycosylation is usually required for normal composition of cell wall and virulence. Upon addition of precursor oligosaccharides to nascent proteins in the endoplasmic reticulum, glycans are further modified by Golgi-glycosyl transferases. In order to add sugar residues to precursor glycans, nucleotide diphosphate sugars are imported from the cytosol to the Golgi lumen, the sugar is transferred to glycans, and the resulting nucleoside diphosphate is dephosphorylated by the nucleoside diphosphatase Gda1 before returning to cytosol. Here, we isolated the open reading frame SsGDA1 from a S. schenckii genomic DNA library. In order to confirm the function of SsGda1, we performed complementation assays in a Saccharomyces cerevisiae gda1∆ null mutant. Our results indicated that SsGDA1 restored the nucleotide diphosphatase activity to wild-type levels and therefore is a functional ortholog of S. cerevisiae GDA1.

Fine haplotype structure of a chromosome 17 region in the laboratory and wild mouse

Extensive linkage disequilibrium among classical laboratory strains represents an obstacle in the high-resolution haplotype mapping of mouse quantitative trait loci (QTL). To determine the potential of wild-derived mouse strains for fine QTL mapping, we constructed a haplotype map of a 250-kb region of the t-complex on chromosome 17 containing the Hybrid sterility 1 (Hst1) gene. We resequenced 33 loci from up to 80 chromosomes of five mouse (sub)species. Trans-species single-nucleotide polymorphisms (SNPs) were rare between Mus m. musculus (Mmmu) and Mus m. domesticus (Mmd). The haplotypes in Mmmu and Mmd differed and therefore strains from these subspecies should not be combined for haplotype-associated mapping. The haplotypes of t-chromosomes differed from all non-t Mmmu and Mmd haplotypes. Half of the SNPs and SN indels but only one of seven longer rearrangements found in classical laboratory strains were useful for haplotype mapping in the wild-derived M. m. domesticus. The largest Mmd haplotype block contained three genes of a highly conserved synteny. The lengths of the haplotype blocks deduced from 36 domesticus chromosomes were in tens of kilobases, suggesting that the wild-derived Mmd strains are suitable for fine interval-specific mapping.

The major histocompatibility complex origin

The present review focuses on the history of genes involved in the major histocompatibility complex (MHC), with a special emphasis on class I function in peptide presentation. The MHC class II story is covered in less detail, as it does not have a major impact on the general understanding of the MHC evolution. We first redefine the MHC as the definition evolved over time. We then use phylogenetic analysis to investigate the history of genes involved in the MHC class I process. As not all the genes involved in this process have been phylogenetically analyzed and because new sequences have been recently released in biological databases, we have re-investigated this matter. In the light of the phylogenetic analysis, the functions of the orthologs of the genes involved in MHC processes are examined in species not having an MHC system. We then demonstrate that the emergence of this new function is due to various levels of co-option.

Comparative analysis of the PDCD2–TBP–PSMB1 region in vertebrates

Three orthologous genes encoding programmed cell death 2 (PDCD2), TATA-binding protein (TBP), and proteasomal subunit C5 (PSMB1) proteins have been shown previously to be nonrandomly distributed in both mammalian and invertebrate genomes. Here we analyze a conserved synteny of the PDCD2, TBP, and PSMB1 orthologs in four nonmammalian vertebrates. Homologous genes of the chicken, zebrafish, fugu, and Tetraodon nigroviridis were identified. A chicken cosmid harboring the orthologs of these three genes was completely sequenced. The fish genes were analyzed in silico. In all seven vertebrates thus far investigated, the PDCD2 and TBP genes are located tail-to-tail. In six tested species but the zebrafish, the PSMB1 gene mapped head-to-head or in the close vicinity to the TBP, but even in the zebrafish, all three genes were syntenic. In contrast, a three times reused synteny breakpoint in the 5'-region from PDCD2 was detected. A comparative analysis revealed the distribution of putative matrix-attached regions (MARs), which may affect the synteny conservation.

RNA polymerase II conducts a symphony of pre-mRNA processing activities

RNA polymerase II (RNAP II) and its associated factors interact with a diverse collection of nuclear proteins during the course of precursor messenger RNA synthesis. This growing list of known contacts provides compelling evidence for the existence of large multifunctional complexes, a.k.a. transcriptosomes, within which the biosynthesis of mature mRNAs is coordinated. Recent studies have demonstrated that the unique carboxy-terminal domain (CTD) of the largest subunit of RNAP II plays an important role in recruiting many of these activities to the transcriptional machinery. Throughout the transcription cycle the CTD undergoes a variety of covalent and structural modifications which can, in turn, modulate the interactions and functions of processing factors during transcription initiation, elongation and termination. New evidence suggests that the possibility that interaction of some of these processing factors with the polymerase can affect its elongation rate. Besides the CTD, proteins involved in pre-mRNA processing can interact with general transcription factors (GTFs) and transcriptional activators, which associate with polymerase at promoters. This suggests a mechanism for the recruitment of specific processing activities to different transcription units. This harmonic integration of transcriptional and post-transcriptional activities, many of which once were considered to be functionally isolated within the cell, supports a general model for the coordination of gene expression by RNAP II within the nucleus.

Novel expressed sequences obtained by means of a suppression subtractive hybridisation analysis from the 6q21 region that is frequently deleted in gastric cancer

In our search for genomic regions that are involved in the development of gastric cancer, we recently identified a 2-cM minimal region of overlapping heterozygous deletions in 6q16.3-q23.1. Here, we describe an application of the suppression subtraction method (SSH) to search for genes in this small region of the genome, taking advantage of the fact that many human genes present on yeast artificial chromosomes (YACs) are expressed in yeast. Subtraction was performed with two virtually contiguous YACs that cover a region of approximately 2.5 Mb. Combined forward and reversed subtractions resulted in the identification of 12 clones of human origin, all of which could be confirmed by sequence analysis as originating from the 6q21 region. Expression in human tissues could be confirmed by Northern analysis for two of the clones, one of them showing a high level of expression in stomach tissue.

Transcription and proper splicing of a mammalian gene in yeast

The house mouse strain C57BL/6 harbours 64 copies of the multicopy gene Sp100-rs. Three of these are contained in the yeast artificial chromosome (YAC) clone yMm75. Four Sp100-rs transcripts of 3.0, 2.6, 1.6 and 1.3kb were detected by Northern hybridization in the yMm75-harbouring line of Saccharomyces cerevisiae. Additional and less abundant transcripts were detected by RT-PCR. With one exception, the YAC-derived Sp100-rs transcripts were a subset of those found in the C57BL/6 mouse. This indicates transcription and proper splicing of murine pre-mRNAs in yeast. Analysis of the splice sites shows that the yeast splicing machinery accepts splice sites that deviate from the standard yeast consensus sequences. It may be feasible, therefore, at least in a fair proportion of cases, to exploit the mammalian mRNAs present in transgenic yeast for gene recognition of YAC-inserts.