Transcriptional repression of the mouse dihydrofolate reductase gene during muscle cell commitment

BAC TG-EMBED: one-step method for high-level, copy-number-dependent, position-independent transgene expression

Chromosome position effects combined with transgene silencing of multi-copy plasmid insertions lead to highly variable and usually quite low expression levels of mini-genes integrated into mammalian chromosomes. Together, these effects greatly complicate obtaining high-level expression of therapeutic proteins in mammalian cells or reproducible expression of individual or multiple transgenes. Here, we report a simple, one-step procedure for obtaining high-level, reproducible mini-gene expression in mammalian cells. By inserting mini-genes at different locations within a BAC containing the DHFR housekeeping gene locus, we obtain copy-number-dependent, position-independent expression with chromosomal insertions of one to several hundred BAC copies. These multi-copy DHFR BAC insertions adopt similar large-scale chromatin conformations independent of their chromosome integration site, including insertions within centromeric heterochromatin. Prevention of chromosome position effects, therefore, may be the result of embedding the mini-gene within the BAC-specific large-scale chromatin structure. The expression of reporter mini-genes can be stably maintained during continuous, long-term culture in the presence of drug selection. Finally, we show that this method is extendable to reproducible, high-level expression of multiple mini-genes, providing improved expression of both single and multiple transgenes.

Replication-independent MCB gene induction and deoxyribonucleotide accumulation at G1/S in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, many genes encoding enzymes involved in deoxyribonucleotide synthesis are expressed preferentially near the G1/S boundary of the cell cycle. The relationship between the induction of deoxyribonucleotide-synthesizing genes, deoxyribonucleoside triphosphate levels, and replication initiation was investigated using factor-synchronized wild-type yeast or dbf4 yeast that are temperature-sensitive for replication initiation. Neither the timing nor extent of gene induction was inhibited when factor-arrested dbf4 cells were released into medium containing the ribonucleotide reductase inhibitor hydroxyurea, which blocks replication fork progression, or were released at 37 degrees C, which blocks replication origin firing. Thus, the induction of deoxyribonucleotide-synthesizing genes at G1/S was fully independent of DNA chain elongation or initiation. Deoxyribonucleoside triphosphate levels increased severalfold at G1/S in wild-type cells and in dbf4 mutants incubated at the non-permissive temperature. Thus, deoxyribonucleoside triphosphate accumulation, like the induction of deoxyribonucleotide-synthesizing genes, was not dependent on replication initiation. Deoxyribonucleoside triphosphate accumulation at G1/S was suppressed in cells lacking Swi6, a transcription factor required for normal cell cycle regulation of deoxyribonucleotide-synthesizing genes. The results suggest that cells use gene induction at G1/S as a mechanism to pre-emptively, rather than reflexively, increase the synthesis of DNA precursors to meet the demand of the replication forks for deoxyribonucleotides.

Fundamental cellular processes do not require vertebrate-specific sequences within the TATA-binding protein

The 180-amino acid core of the TATA-binding protein (TBPcore) is conserved from Archae bacteria to man. Vertebrate TBPs contain, in addition, a large and highly conserved N-terminal region that is not found in other phyla. We have generated a line of mice in which the tbp allele is replaced with a version, tbp(Delta N), which lacks 111 of 135 N-terminal amino acid residues. Most tbp(Delta N/Delta N) fetuses die in midgestation. To test whether a disruption of general cellular processes contributed to this fetal loss, primary fibroblast cultures were established from +/+, Delta N/+, and Delta N/Delta N fetuses. The cultures exhibited no genotype-dependent differences in proliferation or in expression of the proliferative markers dihydrofolate reductase (DHFR) mRNA (S phase-specific) and cdc25B mRNA (G(2)-specific). The mutation had no effect on transcription initiation site fidelity by either RNA polymerase II (pol II) or pol III. Moreover, the mutation did not cause differences in levels of U6 RNA, a pol III-dependent component of the splicing machinery, in mRNA splicing efficiency, in expression of housekeeping genes from either TATA-containing or TATA-less promoters, or in global gene expression. Our results indicated that general eukaryotic cell functions are unaffected by deletion of these vertebrate-specific sequences from TBP. Thus, all activities of this polypeptide domain must either be compensated for by redundant activities or be restricted to situations that are not represented by primary fibroblasts.

Thioredoxin reductase-dependent inhibition of MCB cell cycle box activity in Saccharomyces cerevisiae

Mlu1 cell cycle box (MCB) elements are found near the start site of yeast genes expressed at G1/S. Basal promoters dependent on the elements for upstream activating sequence activity are inactive in Deltaswi6 yeast. Yeast were screened for mutations that activated MCB reporter genes in the absence of Swi6. The mutations identified a single complementation group. Functional cloning revealed the mutations were alleles of the TRR1 gene encoding thioredoxin reductase. Although deletion of TRR1 activated MCB reporter genes, high copy expression did not suppress reporter gene activity. The trr1 mutations strongly (20-fold) stimulated MCB- and SCB (Swi4/Swi6 cell cycle box)-containing reporter genes, but also weakly (3-fold) stimulated reporter genes that lacked these elements. The trr1 mutations did not affect the level or periodicity of three endogenous MCB gene mRNAs (TMP1, RNR1, and SWI4). Deletion of thioredoxin genes TRX1 and TRX2 recapitulated the stimulatory effect of trr1 mutations on MCB reporter gene activity. Conditions expected to oxidize thioredoxin (exposure to H2O2) induced MCB gene expression, whereas conditions expected to conserve thioredoxin (exposure to hydroxyurea) inhibited MCB gene expression. The results suggest that thioredoxin oxidation contributes to MCB element activation and suggest a link between thioredoxin-oxidizing processes such as ribonucleotide reduction and cell cycle-specific gene transcription.

Developmental testis-specific regulation of mRNA levels and mRNA translational efficiencies for TATA-binding protein mRNA isoforms

Early spermatids contain roughly 1000-fold more TATA-binding protein (TBP) mRNA than do somatic cells. The appearance of TBP-overexpressing spermatids in the developing testis is accompanied by a large increase in whole-organ levels of total RNA and of poly(A)+ RNA per cell. Whereas somatic cells initiate transcription of TBP mRNA at a single promoter/first exon (exon 1C), in adult testis, two additional major promoter/first exons (1D and 1E) are used. We have examined the expression of the somatic and testis-specific TBP mRNA isoforms during rodent testis development. In juvenile testes TBP mRNAs containing either exon 1C or exon 1D, but none containing exon 1E, are detected. At 21 days of age, all TBP mRNA isoforms begin to overaccumulate. The onset of TBP mRNA overaccumulation is marked first by an increase in levels of polysomal TBP mRNA, and later by accumulation of mRNP-associated TBP mRNA. In adult testes, only 30% of the total TBP mRNA is engaged by polysomes; the remainder is sequestered as mRNP particles. All of the TBP mRNA isoforms in adults exist both as free mRNP particles and as polysomes; however, the fraction in polysomes varies from 60% (exon 1C) to 10% (exon 1E). This suggests that sequences within the first exons alter the probability that the mRNA will either assemble into polysomes or into translationally inactive mRNP particles.

High accumulation of components of the RNA polymerase II transcription machinery in rodent spermatids

Levels of mRNA and protein encoded by the TATA-binding protein (tbp) gene are shown to increase dramatically during late spermatogenesis in rodents, culminating in a highly testis-enriched expression pattern. Whereas adult spleen and liver contained roughly 0.7 and 2.3 molecules of TBP mRNA per haploid genome-equivalent, respectively, adult testis contained 80–200 molecules of TBP mRNA per haploid genome-equivalent. Comparison of nuclear and cytoplasmic levels of TBP mRNA in liver and testis suggested that nuclear events (transcription or processing) contribute roughly 12-fold, and cytoplasmic events (mRNA stability) roughly 6-fold, to testis-specific overaccumulation. Levels of nuclear TBP protein in testis cells were, on average, 8- and 11-fold higher than those in liver and spleen cells, respectively. Overexpression of TBP mRNA in testis began about 20 days after birth and reached a plateau around day 40, corresponding to the developmental emergence of haploid cells. Besides TBP, two other components of the general RNA polymerase II machinery, TFIIB and RNA polymerase II, were also overexpressed in testis. By immunostaining, it was found that TBP and RNA polymerase II were particularly rich in round spermatid nuclei. Our results suggest a molecular explanation for how early spermatids are able to accumulate all of the mRNA necessary for the final week of spermiogenesis.

Selective DNA amplification regulates transcript levels in plant mitochondria

Most plant mitochondrial genomes exist as subgenomic-size fragments apparently due to recombination between repetitive sequences. This leads to the possibility that independently replicating subgenomic domains could result in mitochondrial gene copy number variation. We show, through Southern-blot analysis of both restricted and intact mtDNA, that there are gene-specific copy number differences in the monocot Zea mays. Comparison of two different maize genotypes, B37(N) and B37(T), a cytoplasmic male-sterile strain, reveal fewer gene copy number differences for B37(T) than for B37(N). In contrast to maize, significant gene copy number differences are not detected in the dicot Brassica hirta. We also demonstrate that mitochondrial transcriptional rates in both species are apparently dependent on gene copy number since relative rates determined by run-on analysis are proportional to relative gene copy numbers. Thus a direct relationship exists between plant mitochondrial gene copy number and transcriptional rate.

Circadian transcription of the cholesterol 7 alpha hydroxylase gene may involve the liver-enriched bZIP protein DBP

The liver-enriched transcription factor DBP is expressed with a stringent circadian rhythm. We present evidence that DBP is a regulator of the circadian expression of the rat gene encoding cholesterol 7 alpha hydroxylase (C7 alpha H), the rate-limiting enzyme in the conversion of cholesterol to bile acids. As with DBP, C7 alpha H mRNA reaches peak levels in the evening, and its cycling is independent of daily food and light cues. As predicted for a DBP target gene, the primary level of C7 alpha H circadian expression is at the transcriptional level. DBP can activate the C7 alpha H promoter in cotransfection assays through a cognate DNA site centered around -225. In nuclear extracts prepared by a novel method that, in contrast to conventional techniques, yields near-quantitative recovery of DBP and other non-histone proteins, the DNA site required for DBP activation is the predominant site of occupancy by nuclear factors on the C7 alpha H promoter. At this site, the predominant binding activity is an evening-specific complex of which DBP is a component. These data suggest that DBP may play an important role in cholesterol homeostasis through circadian transcriptional regulation of cholesterol 7 alpha hydroxylase.