Biogenesis of multisubunit RNA polymerases.

Gene transcription in the nucleus of eukaryotic cells is carried out by three related multisubunit RNA polymerases, Pol I, Pol II and Pol III. Although the structure and function of the polymerases have been studied extensively, little is known about their biogenesis and their transport from the cytoplasm (where the subunits are synthesized) to the nucleus. Recent studies have revealed polymerase assembly intermediates and putative assembly factors, as well as factors required for Pol II nuclear import. In this review, we integrate the available data into a model of Pol II biogenesis that provides a framework for future analysis of the biogenesis of all RNA polymerases.

Mechanical loading induces the expression of a Pol I regulon at the onset of skeletal muscle hypertrophy.

The main goal of the present study was to investigate the regulation of ribosomal DNA (rDNA) gene transcription at the onset of skeletal muscle hypertrophy. Mice were subjected to functional overload of the plantaris by bilateral removal of the synergist muscles. Mechanical loading resulted in muscle hypertrophy with an increase in rRNA content. rDNA transcription, as determined by 45S pre-rRNA abundance, paralleled the increase in rRNA content and was consistent with the onset of the hypertrophic response. Increased transcription and protein expression of c-Myc and its downstream polymerase I (Pol I) regulon (POL1RB, TIF-1A, PAF53, TTF1, TAF1C) was also consistent with the increase in rRNA. Similarly, factors involved in rDNA transcription, such as the upstream binding factor and the Williams syndrome transcription factor, were induced by mechanical loading in a corresponding temporal fashion. Chromatin immunoprecipitation revealed that these factors, together with Pol I, were enriched at the rDNA promoter. This, in addition to an increase in histone H3 lysine 9 acetylation, demonstrates that mechanical loading regulates rRNA synthesis by inducing a gene expression program consisting of a Pol I regulon, together with accessory factors involved in transcription and chromatin remodeling at the rDNA promoter. Altogether, these data indicate that transcriptional and epigenetic mechanisms take place in the regulation of ribosome production at the onset of muscle hypertrophy.

High-cell density shake-flask expression and rapid purification of the large fragment of Thermus aquaticus DNA polymerase I using a new chemically and temperature inducible expression plasmid in Escherichia coli.

We have developed a new expression vector, pcI(ts) ind(+), based upon the powerful rightward promoter of bacteriophage lambda, which is controlled by a temperature-sensitive and chemically-inducible version of the lambda repressor on the same plasmid. Locating the repressor gene on the plasmid makes this vector "portable" in that it can be used to transform any strain of Escherichia coli. Hence, control over strains, induction conditions, and harvest times can be used to optimize yields of heterologous proteins. To provide a proof of concept, we show that E. coli recA(+) and recA(-) host cells transformed with pcI(ts) ind(+) modKlenTaq1 (a modified version of the large fragment of Thermus aquaticus DNA polymerase I) could be grown to high cell densities in multiple shake-flasks. A mutant version of modKlenTaq1 (V649C) could be induced by simply raising the thermostat setting from 30 to 37 degrees C and (in the case of recA(+) cells) adding nalidixic acid to achieve full induction (12-13% of the total cellular protein). Using a rapid, two-step purification process, it was possible to purify nearly 300 mg of modKlenTaq1 V649C from six 2.8-L baffle-bottomed shake-flasks each holding 1.5L of culture for a final yield of approximately 33 mg per liter or 3mg of purified enzyme per gram of cells wet weight.

Involvement of proliferating cell nuclear antigen (cyclin) in DNA replication in living cells.

Proliferating cell nuclear antigen (PCNA) (also called cyclin) is known to stimulate the activity of DNA polymerase delta but not the other DNA polymerases in vitro. We injected a human autoimmune antibody against PCNA into unfertilized eggs of Xenopus laevis and examined the effects of this antibody on the replication of injected plasmid DNA as well as egg chromosomes. The anti-PCNA antibody inhibited plasmid replication by up to 67%, demonstrating that PCNA is involved in plasmid replication in living cells. This result further implies that DNA polymerase delta is necessary for plasmid replication in vivo. Anti-PCNA antibody alone did not block plasmid replication completely, but the residual replication was abolished by coinjection of a monoclonal antibody against DNA polymerase alpha. Anti-DNA polymerase alpha alone inhibited plasmid replication by 63%. Thus, DNA polymerase alpha is also required for plasmid replication in this system. In similar studies on the replication of egg chromosomes, the inhibition by anti-PCNA antibody was only 30%, while anti-DNA polymerase alpha antibody blocked 73% of replication. We concluded that the replication machineries of chromosomes and plasmid differ in their relative content of DNA polymerase delta. In addition, we obtained evidence through the use of phenylbutyl deoxyguanosine, an inhibitor of DNA polymerase alpha, that the structure of DNA polymerase alpha holoenzyme for chromosome replication is significantly different from that for plasmid replication.

Replication of DNA minicircles in kinetoplasts isolated from Crithidia fasciculata: structure of nascent minicircles.

We have previously described an isolated kinetoplast system from Crithidia fasciculata capable of ATP-dependent replication of kinetoplast DNA minicircles (L. Birkenmeyer and D.S. Ray, J. Biol. Chem. 261: 2362-2368, 1986). We present here the identification of two new minicircle species observed in short pulse-labeling experiments in this system. The earliest labeled minicircle species (component A) contains both nascent H and L strands and is heterogeneous in sedimentation and electrophoretic migration. Component A has characteristics consistent with a Cairns-type structure in which the L strand is the leading strand and the H strand is the lagging strand. The other new species (component B) has a nascent 2.5-kilobase linear L strand with a single discontinuity that mapped to either of two alternative origins located 180 degrees apart on the minicircle map. Component B could be repaired to a covalently closed form by Escherichia coli polymerase I and T4 ligase but not by T4 polymerase and T4 ligase. Even though component B has a single gap in one strand, it had an electrophoretic mobility on an agarose gel (minus ethidium bromide) similar to that of a supercoiled circle with three supertwists. Treatment of component B with topoisomerase II converted it to a form that comigrated with a nicked open circular form (replicative form II). These results indicate that component B is a knotted topoisomer of a kinetoplast DNA minicircle with a single gap in the L strand.

Induction of beta-polymerase mRNA by DNA-damaging agents in Chinese hamster ovary cells.

Only a few of the genes involved in DNA repair in mammalian cells have been isolated, and induction of a DNA repair gene in response to DNA damage has not yet been established. DNA polymerase beta (beta-polymerase) appears to have a synthetic role in DNA repair after certain types of DNA damage. Here we show that the level of beta-polymerase mRNA is increased in CHO cells after treatment with several DNA-damaging agents.

The general control activator protein GCN4 is essential for a basal level of ARO3 gene expression in Saccharomyces cerevisiae.

The ARO3 gene encodes one of two 3-deoxy-D-arabino-heptulosonate-7-phosphate isoenzymes in Saccharomyces cerevisiae catalyzing the first step in the biosynthesis of aromatic amino acids. The ARO3-encoded 3-deoxy-D-arabino-heptulosonate-7-phosphate synthase (EC 4.1.2.15) is feedback inhibited by phenylalanine; its isoenzyme, the ARO4 gene product, is inhibited by tyrosine. Both genes ARO3 and ARO4 are strongly regulated under the general control regulatory system. Cells carrying only one intact isogene are phenotypically indistinguishable from a wild-type strain when grown on minimal medium. The complete functional ARO3 promoter comprises 231 base pairs and contains only one TGACTA binding site for the general control activator protein GCN4. Mutating this element to TTACTA inhibits binding of GCN4 and results in a decreased basal level of ARO3 gene product and slow growth of a strain defective in its isogene ARO4. In addition, ARO3 gene expression cannot be elevated under amino acid starvation conditions. An ARO3 aro4 strain with gcn4 genetic background has the same phenotype of low ARO3 gene expression and slow growth. The amount of GCN4 protein present in repressed wild-type cells therefore seems to contribute to a basal level of ARO3 gene expression. The general control activator GCN4 has thus two functions: (i) to maintain a basal level of ARO3 transcription (basal control) in the presence of amino acids and (ii) to derepress the ARO3 gene to a higher transcription rate under amino acid starvation (general control).

Molecular cloning of Drosophila mus308, a gene involved in DNA cross-link repair with homology to prokaryotic DNA polymerase I genes.

Mutations in the Drosophila mus308 gene confer specific hypersensitivity to DNA-cross-linking agents as a consequence of defects in DNA repair. The mus308 gene is shown here to encode a 229-kDa protein in which the amino-terminal domain contains the seven conserved motifs characteristic of DNA and RNA helicases and the carboxy-terminal domain shares over 55% sequence similarity with the polymerase domains of prokaryotic DNA polymerase I-like enzymes. This is the first reported member of this family of DNA polymerases in a eukaryotic organism, as well as the first example of a single polypeptide with homology to both DNA polymerase and helicase motifs. Identification of a closely related gene in the genome of Caenorhabditis elegans suggests that this novel polypeptide may play an evolutionarily conserved role in the repair of DNA damage in eukaryotic organisms.

Expression analysis using DNA microarrays demonstrates that E2F-1 up-regulates expression of DNA replication genes including replication protein A2.

The transcription factor E2F-1 plays a pivotal role in the regulation of G1/S transition in higher eukaryotes cell cycle. We used a cell line containing an inducible E2F-1 and oligonucleotide microarray analysis to identify novel E2F target genes. We show that E2F-1 up-regulates the expression of a number of genes coding for components of the DNA replication machinery. Among them is the gene coding for the 32 Kd subunit of replication protein A (RPA2). Replication protein A is the most abundant single strand DNA binding complex and it is essential for DNA replication. We demonstrate that RPA2 is a novel E2F target gene whose expression can be directly regulated by E2F-1 via E2F binding sites in its promoter. In addition, expression of Topoisomerase IIalpha and subunit IV of DNA polymerase alpha is also up-regulated upon E2F-1 induction. Taken together, these results provide novel links between components of the DNA replication machinery and the cell growth regulatory pathway involving the Rb tumor suppressor and E2F.

Levels and size complexity of DNA polymerase beta mRNA in rat regenerating liver and other organs.

A cDNA probe encoding DNA polymerase beta (beta-pol) was used to study the level and size complexity of beta-pol mRNA in regenerating rat liver and other rat tissues. An almost 2-fold increase in beta-pol mRNA was observed 18-24 h after partial hepatectomy. In most adult rat tissues (liver, heart, kidney, stomach, spleen, thymus, lung and brain) the abundance of beta-pol mRNA was low. In contrast, young brain and testes exhibited beta-pol mRNA levels 5- and 15-times higher, respectively. The observed changes in the level of beta-pol mRNA in regenerating rat liver and in developing brain are correlated with reported changes in DNA polymerase beta activity. Four different (4.0, 2.5, 2.2, 1.4 kb) transcripts hybridizing to beta-pol probe were found in all tissues examined. The 4.0 kb transcript was dominant for young and adult brain, whereas the 1.4 kb transcript was dominant for testes. The significance of these transcripts is discussed.

Polymerase-specific differences in the DNA intermediates of frameshift mutagenesis. In vitro synthesis errors of Escherichia coli DNA polymerase I and its large fragment derivative.

The sequences of more than 600 frameshift mutations produced as a consequence of in vitro DNA replication on an oligonucleotide-primed, single-stranded DNA template by the Escherichia coli polymerase I enzyme (PolI) or its large fragment derivative (PolLF) were compared. Four categories of mutants were found: (1) single-base deletions, (2) base substitutions, (3) multiple-base deletions and (4) complex frameshift mutations that change both the base sequence and the number of bases in a concerted mutational process. The template sequence 5'-Py-T-G-3', previously identified as a PolLF hotspot for single-base deletions opposite G, is also a hotspot for PolI. A PolI-specific warm spot for single-base deletions was identified. Among base substitutions, transitions were more frequent than transversions. Transversions were mediated by (template)G.G, (template)G.A, and (template)C.T mispairs. Multiple-base deletions were found only after PolI replication. Although each of these deletions can be explained by a misalignment mediated by directly repeated DNA sequences, deletion frequencies were often different for repeats of the same length. Both PolI and PolLF produced many complex frameshift mutants. The new sequences at the mutant sites are exactly complementary to nearby DNA sequences in the newly synthesized DNA strand. In each case, palindromic complementarity could mediate the misalignment needed to initiate the mutational process. The misaligned DNA synthesis accounts for the nucleotide changes at the mutant site and for homology that could direct realignment of the DNA onto the template. Most of the complex mutant sequences could be initiated by either intramolecular misalignments involving fold-back structures in newly synthesized DNA or by strand-switching during strand-displacement synthesis. The striking differences between the specificities of complex frameshift mutations and multiple-base deletions by PolI and PolLF identify the existence of polymerase-specific determinants that influence the frequency and specificity of misalignment-mediated frameshifts and deletions.

Replicative enzymes and ageing: importance of DNA polymerase alpha function to the events of cellular ageing.

A hallmark of cellular ageing is the failure of senescing cells to initiate DNA synthesis and transition from G1 into S phase of the cell cycle. This transition is normally dependent on or concomitant with expression of a set of genes specifying cellular proteins, some of which directly participate in DNA replication. Deregulation of this gene expression may play a pivotal role in the ageing process. The number of known enzymes and co-factors required to maintain integrity of the genome during eukaryotic DNA replication has increased significantly in the past few years, and includes proteins essential for DNA replication and repair, as well as for cell cycle regulation. In eukaryotic cells, ranging from yeast to man, a replicative enzyme essential for initiation of transcription is DNA polymerase alpha (pol alpha), the activity of which is coordinately regulated with the initiation of DNA synthesis. DNA pol alpha, by means of its primase subunit, has the unique ability to initiate de novo DNA synthesis, and as a consequence, is required for the initiation of continuous (leading-strand) DNA synthesis at an origin of replication, as well as for initiation of discontinuous (lagging-strand) DNA synthesis. The dual role of the pol alpha-primase complex makes it a potential interactant with the regulatory mechanisms controlling entry into S phase. The purpose of this review is to address the regulation and/or modulation of DNA pol alpha during ageing that may play a key role in the cascade of events which ultimately leads to the failure of old cells to enter or complete S phase of the cell cycle.

Production of antibody-tagged enzymes by myeloma cells: application to DNA polymerase I Klenow fragment.

Myeloma DNA expression systems can be used for the synthesis and secretion of antibody/enzyme recombinant molecules. Here we describe the construction of a myeloma cell-line that secretes a hapten-specific antibody/enzyme hybrid molecule, in which the antibody Fc portion has been replaced by the Klenow fragment of Escherichia coli DNA polymerase I (PolIk). This Fab-PolIk hybrid molecule is secreted in good yield from the myeloma transfectants, can be purified to homogeneity in a single step on hapten-Sepharose columns, and exhibits PolIk activity as judged by its use in dideoxy nucleotide sequencing. Thus Fab-PolIk can be used for the same purposes as conventional PolIk but has the advantage that it is easily purified to homogeneity in a one-step purification from culture medium.

Cloning and complete sequence of the DNA polymerase-encoding gene (BstpolI) and characterisation of the Klenow-like fragment from Bacillus stearothermophilus.

A fragment of the DNA polymerase I-encoding gene (polI) from Bacillus stearothermophilus (Bst) was obtained by PCR. This was used as a probe to obtain a full-length gene from a Bst genomic DNA (gDNA) plasmid library. Comparison of the sequence to B. caldotenax (Bca) showed about 93% homology at the amino acid (aa) level. A Klenow-like (BstpolIk) clone was developed and the recombinant protein displayed DNA polymerase activity similar to the wild-type BstPolI enzyme.

Construction and expression of a chimeric gene encoding human terminal deoxynucleotidyltransferase and DNA polymerase beta.

A domain substitution experiment was carried out between the structurally related DNA-polymerizing enzymes Pol beta and TdT to investigate the region of Pol beta required for template utilization. Site-directed mutagenesis and recombinant DNA procedures were used for construction of a gene encoding a chimeric form of the two enzymes and termed TDT::POLB, in which the DNA region encoding amino acids (aa) 154-212 of TdT was replaced by the corresponding region encoding aa 1-60 of POL beta. The construction was confirmed by restriction analysis and DNA sequencing. Since this region of POL beta represents most of the N-terminal domain of the enzyme possessing single-stranded DNA (ssDNA)-binding activity, it was hypothesized that the chimeric protein, unlike TdT, might possess template-dependent DNA polymerase activity. The chimeric gene product was produced in Escherichia coli, purified and subjected to preliminary enzymological characterization. The finding that the chimeric TdT::Pol beta protein possessed significant template-dependent polymerase activity suggests that aa 1-60 of Pol beta are involved in template utilization during the polymerization reaction, as suggested by the previous finding that the 8-kDa N-terminal domain of Pol beta possesses ssDNA-binding activity [Kumar et al., J. Biol. Chem. 265 (1990a) 2124-2131; Kumar et al., Biochemistry 29 (1990b) 7156-7159; Prasad et al., J. Biol. Chem. 268 (1993) 22746-22755].

The bovine DNA polymerase beta promoter: cloning, characterization and comparison with the human core promoter.

The core promoter of the human DNA polymerase beta (beta Pol)-encoding gene (POL beta) is regulated through cis-elements for the ATF/CREB protein(s), and GC box-binding and initiation-site-binding proteins. The mechanism of promoter regulation has been studied using a nuclear extract transcription system from HeLa cells [Narayan et al., J. Biol. Chem. 269 (1994) 12755-12763]. To study the homologous promoter (ppol beta) in a bovine system, we cloned and characterized the 5'-flanking region of the bovine gene (pol beta). A 15.3-kb fragment of bovine genomic DNA containing the first two exons and 11 kb of 5'-flanking region was isolated from a testis library in bacteriophage lambda EMBL3. S1 nuclease mapping and primer extension analysis of the 5'-end of the pol beta mRNA identified the major transcription start point (tsp), which is located 142-bp 5' of the translational start codon. In transient expression assays using a bovine cell line, analysis of various 5'-deletion mutants demonstrated that a fragment of only 91-bp 5' of the tsp had promoter activity similar to that of a 1.37-kb fragment, so that cis-elements for basal transcription are located within this approx. 100-bp core promoter, as in the human promoter (pPOL beta). Comparison of the core promoters from the bovine and human genes revealed striking similarity, including an almost precise match of the tsp, the ATF/CREB-binding and Sp1-binding sites, and the spacing separating them.

Isolation and characterization of ten mutator alleles of the mitochondrial DNA polymerase-encoding MIP1 gene from Saccharomyces cerevisiae.

Ten mutator alleles of MIP1, the gene encoding mitochondrial (mt) DNA polymerase, have been isolated after in vitro random mutagenesis. Five mutations causing a 100-400-fold increase in the frequency of erythromycin-resistant (ErR) mt mutants in yeast mapped to the 3'-5' exonuclease (Exo) domain, and mainly to the three conserved motifs Exo1, Exo2 and Exo3 of this domain, highlighting the importance of proofreading in accurate mt DNA replication. The essential role of the invariant glutamate at the Exo1 site was confirmed and the participation of four amino acids (aa) in the 3'-5' Exo function revealed. Another mutation that is located between the Exo1 and Exo2 sites produced an extremely strong mutator phenotype associated with impaired DNA replication, but could be assigned neither to a conserved aa nor to a conserved portion of the 3'-5' exonuclease domain. The importance of the polymerization domain in accurate mt DNA replication was pointed out by three mutator mutations. Two of these severely impaired mt DNA replication and were assigned to a subdomain of the polymerase which probably corresponds to the 'fingers' module of the Klenow (large) fragment of Escherichia coli DNA polymerase I (PolIk). The third, which did not alter the efficiency of DNA replication, was located at the active center of the polymerization reaction. Finally, the mutation, R1001I, mapped to the C-terminal part of the MIP1 protein which has no counterpart in prokaryotic DNA polymerases.

DNA repair enzyme expression in chronic lymphocytic leukemia vis-à-vis nitrogen mustard drug resistance.

Nitrogen mustard resistance in B-cell chronic lymphocytic leukemia (B-CLL) has been associated with enhanced DNA repair and increased expression of DNA repair enzymes. Lymphocytes from patients with nitrogen mustard resistant B-CLL displayed a fivefold increase in resistance to melphalan in vitro as compared to those from untreated patients concordant with our definition of clinical resistance. We have performed Northern analysis using a cohort consisting of 11 untreated and 12 treated-resistant patients. Increased expression of ERCC-1 was not found to be associated with nitrogen mustard resistance, nor did we find altered expression of the DNA repair enzymes: ERCC-2, DNA polymerase beta, or topoisomerase I. There was also no difference in the levels of ERCC-1 protein between melphalan sensitive and resistant B-CLL lymphocytes. Analysis of genes involved in nitrogen mustard detoxification revealed that metallothionein was weakly expressed, while transcripts encoding glutathione-S-transferase alpha were undetectable. Thus, it is unlikely either of these proteins plays a role in the resistance. The results of the cytotoxicity assay validate the use of B-CLL as a model to study nitrogen mustard resistance. This model allows us to perform in vitro studies using a tumor which develops resistance in vivo. The results of this study suggest that nucleotide excision repair, as represented by ERCC-1 and ERCC-2, is not the limiting step in B-CLL nitrogen mustard resistance.

Dual cis-acting negative regulatory elements located upstream of the mouse DNA polymerase beta gene.

A 2,200 base pair (bp) fragment containing the 5'-flanking region of the mouse DNA polymerase beta gene was placed adjacent to and upstream of the chloramphenicol acetyl transferase (CAT)-coding region of the CAT vector. A transient expression assay of CAT activity in mouse NIH/3T3 cells transfected with this recombinant plasmid or a set of its 5'-deletion derivatives was carried out to identify a cis-acting regulatory element(s) for DNA polymerase beta gene expression. Depending on the extent of the deletion, CAT activity was dramatically increased, indicating the existence of a negative regulatory region which could be divided into two distinct domains: removal of the first domain (NRE-I), nucleotides -1860 to -1580 (+1 denotes the position of 5'-most proximal transcription initiation site), caused two to three-fold stimulation of CAT activity, and removal of the second domain (NRE-II), nucleotides -828 to -456, stimulated CAT expression another two to three-fold. When an 1,864-bp segment containing these negative regulatory elements (-2190 to -327) was inserted in the plasmid carrying the simian virus 40 early promoter and enhancer-directed CAT gene, it inhibited the CAT expression relatively independently of the orientation of insertion and the distance from the promoter-enhancer. We also mapped the promoter element of the DNA polymerase beta gene to within a 133-bp DNA fragment from nucleotide position -100 to +33. Either the NRE-I region or the NRE-II region alone can inhibit DNA polymerase beta gene promoter function.

Molecular cloning of a gene (poIA) coding for an unusual DNA polymerase I from Treponema pallidum.

The gene coding for the DNA polymerase I from Treponema pallidum, Nichols strain, was cloned and sequenced. Depending on which of the two alternative initiation codons was used, the protein was either 997 or 1015 amino acids long and the predicted protein had a molecular mass of either 112 or 114 kDa. Sequence comparisons with other polA genes showed that all three domains expected in the DNA polymerase I class of enzymes were present in the protein (5'-3' exonuclease, 3'-5' exonuclease and polymerase domains). Additionally, there were four unique insertions of 20-30 amino acids each, not seen in other DNA polymerase I enzymes. Two of the inserts were near the boundary of the two exonuclease domains and the other two interrupted the 3'-5' exonuclease domain which is involved in proofreading. The predicted amino-acid sequence had an exceptionally high content of cysteine (2.4% compared with <0.05% for most other sequenced DNA polymerase I enzymes). The polA gene was further cloned into pProEXHTa for expression and purification. The transformants expressed a protein of 115 kDa. Antibodies raised against synthetic peptide fragments of the putative DNA polymerase I recognised the 115-kda band in Western blot analysis. No DNA synthesis activity could be demonstrated on a primed single-stranded template. Although significant quantities of the protein were produced in the host Escherichia coli carrying the plasmid, it was not capable of complementing a polA(-) mutant in the replication of a polA-dependent plasmid.