Studies on invitro DNA synthesis: II. Isolation of a protein which stimulates deoxynucleotide incorporation catalyzed by DNA polymerases of E.coli

Purified RNA polymerase, DNA polymerase III and unwinding protein of $\text{Escherichia}\text{coli}$ catalyze limited rifampicin sensitive fd or ØX 174 DNA-dependent DNA synthesis. A protein has been partially purified from $\text{E.}\text{coli}$ which stimulates rifampicin sensitive dXMP incorporation in this system 20 to 30 fold. This protein also stimulates DNA synthesis catalyzed by DNA polymerases I and II; the stimulation occurs in reactions primed with natural and synthetic DNAs as well as RNA-DNA hybrids. The protein is not a product of the known dna genes. In contrast to the above system of purified enzymes, rifampicin sensitive dXMP incorporation in crude extracts of $\text{E.}\text{coli}$ is specifically dependent on fd but not ØX 174 DNA. An additional factor has been isolated from extracts of $\text{E.}\text{coli}$ which restores specificity to the purified rifampicin sensitive system by preventing ØX 174 DNA from serving as a template.     

1,10-Phenanthroline-cuprous ion complex, a potent inhibitor of DNA and RNA polymerases.

The inhibition by 1,10-phenanthroline of $\text{E. coli}$ DNA polymerase I has recently been attributed to the formation in the assay mixtures of a unique and effective inhibitor, the 2:1 1,10-phenanthroline-cuprous ion complex (1). We have now found that this coordination complex is also an effective inhibitor of $\text{E. coli}$ DNA dependent RNA polymerase, Micrococcus luteus DNA dependent DNA polymerase, and T-4 DNA dependent DNA polymerase. This conclusion is based either on the requirement of a thiol for 1,10-phenanthroline inhibition or on the reversal of 1,10-phenanthroline inhibition by the non-inhibitory cuprous ion specific chelating agent 2,9-dimethyl-1,10-phenanthroline. 2,2′,2″-Terpyridine is also very effective at relieving 1,10-phenanthroline inhibition. The reversal of 1,10-phenanthroline inhibition should be attempted before it is claimed that 1,10-phenanthroline inhibits any polymerases by coordinating a zinc ion at the active site.     

Differential effect of neomycin on DNA dependent -DNA and RNA synthesis in vitro

Neomycin inhibits $\text{in vitro}$ DNA dependent DNA and RNA synthesis catalyzed by DNA polymerase I and RNA polymerase from $\text{E. coli}$. The effect of the antibiotic is more pronounced towards DNA synthesis. The inhibition of DNA synthesis is competitive with template DNA, does not reverse with excess deoxynucleoside triphosphate, Mg²⁺ or enzyme $\text{E. coli}$ DNA polymerase I. Neomycin does not reduce the number of potential 3′ -OH end or primer. It seems to shorten the size of the newly formed polynucleotide.     

The effect of 5-azacytidine on E. coli DNA methylase.

5-Azacytidine, when added to growing $\text{E.}$$\text{coli}$ K12, causes a decrease in DNA methylation assayed $\text{in}$$\text{vitro}$. This decrease is greater when $\text{E.}$$\text{coli}$ DNA is used as substrate than when calf thymus DNA is used. The decrease in activity is not due to the inhibition of protein synthesis caused by this drug, since neither chloramphenicol nor rifampin causes a decrease in enzyme activity. The effect is specific for the DNA(cytosine-5)methylase; the methylation of adenine is not affected. The concentration of drug that inhibits the DNA methylase by 50% is the same concentration that inhibits cell growth by 50%.     

Inhibition of exonuclease V after infection of E. coli by bacteriophage T7

Exonuclease V ($\text{recBC}$ DNase) is inactivated in $\text{E. coli}$ between 4 and 7 min after infection by T7. This process requires protein sythesis. The inactivation does not occur when T7 is deficient for its RNA polymerase and thus does not express the genes involved in DNA replication and phage maturation. Some implications of this new function of T7 are discussed with respect to the processes of infection and DNA replication.     

Inhibition of E. coli DNA polymerase I by 1,10-phenanthroline.

A 1,10-phenanthroline-cuprous ion complex is a potent reversible inhibitor of $\text{E. coli}$ DNA polymerase I yielding 50% inhibition in the micromolar concentration range. The 2:1 1,10-phenanthroline-cuprous ion complex is most probably the inhibitory species. Complexes of cupric ion and 1,10-phenanthroline have no apparent kinetic effect. The previously reported inhibition of the enzyme by 1,10-phenanthroline (1,2) is most likely due to the formation of this complex from thiols normally added to the assay mixtures and trace amounts of cupric ion invariably present notwithstanding reasonable precaution. The reversible and instantaneous 1,10-phenanthroline inhibition observed for other polymerases may be due to this unique inhibitory species and not coordination of a catalytically important zinc ion at the active site by the chelating agent.     

Localization of the structural gene for the ' subunit of RNA polymerase in Escherichia coli

A minicell-producing strain of $\text{E.}$$\text{coli}$ carrying an F′ factor, KLF10-1, forms minicells that contain plasmid but not chromosomal DNA. These minicells were found to synthesize two polypeptides corresponding precisely to the β and β′ subunits of RNA polymerase in SDS-polyacrylamide gel electrophoresis. In contrast, minicells obtained from an isogenic strain carrying F13-1 do not synthesize these proteins under similar conditions. These results indicate that the structural genes for the β′ as well as β subunits of the polymerase are located on the chromosomal segment (78 to 81 min on the standard genetic map of $\text{E.}$$\text{coli}$) carried by KLF10-1.     

Electron microscopic studies of the binding of Escherichia coli RNA polymerase to DNA: II. Formation of multiple promoter-like complexes at non-promoter sites

The interactions between Escherichia coli RNA polymerase holoenzyme and a 3800 base-pair restriction fragment of bacteriophage T7 DNA (Mbo-IC) have been examined by electron microscopy. In addition to exhibiting weak, non-specific interactions (K_a ～ 10⁴ M^?1), RNA polymerase is able to form up to 15 to 20 relatively stable complexes with this template (K_a est 10⁹ M^?1). Only one of these complexes is formed at the T7 promoter E, that maps at 92.2 ± 1% on the conventionalgenome. The remaining complexes seem to be situated non-randomly on this fragment and possibly involve interactions with specific DNA sequences. The association kinetics of formation have been examined and give rise to a second-order rate constant of ～ 10⁵ M^?1s^?1. Formation of these complexes is markedly reduced at low temperatures. Under standard binding conditions (50 mM-NaCl) the dissociation rate of these complexes is slow ($\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext><mtext>\; ~\; 30\; </mtext><mtext>min</mtext>}}$), but increases rapidly with increasing salt concentration and at reduced temperatures. It is unaffected by the presence of heparin up to 5 μg/ml. Thus it appears that E. coli RNA polymerase can form complexes with promoter-like properties at many different sites on T7 DNA.     

Inhibition of RNA chain initiation in E. coli core RNA polymerase with 2-hydroxy-5-nitrobenzyl bromide

The modification of $\text{E. coli}$ core RNA polymerase with 2-hydroxy-5-nitrobenzyl bromide (Koshland's Reagent) resulted in the benzylation of 6 out of 13 cysteines, and 10 out of 20 tryptophans in the polymerase, and occurred with an 8% decrease in its [θ]₂₂₀. The modification resulted in a maximal inhibition of 60% of the RNA chains on both calf thymus and micrococcal DNA templates. γ-³²P-ATP studies showed the inhibition occurred at RNA chain initiation. This study raises the possibility that the modified core polymerase may synthesize specific RNA(s).     

A new eukaryotic RNA polymerase factor: a factor from chicken myeloblastosis cells which stimulates transcription of denatured DNA

A heat-stable protein factor, capable of stimulating RNA synthesis by nuclear RNA polymerase II, was found in isolated nuclei of chicken myeloblastosis cells. It is adsorbed to a DEAE-Sephadex column used for RNA polymerase purification and then is eluted with 0.1 M ammonium sulfate. This factor appears to differ from previously reported eukaryotic RNA polymerase factors in its property of stimulating the activity of denatured (or single-stranded) DNA template. When heated, this factor contains no detectable endonuclease or exonuclease activity. The degree of stimulation is greater with chicken myeloblastosis RNA polymerase IIb than IIa and is most efficient when homologous DNA is used as template. This factor causes no stimulation of $\text{E. coli}$ RNA polymerase.     

Pyridoxal 5' phosphate: a selective inhibitor of oncornaviral DNA polymerases.

Pyridoxal 5′ phosphate at concentrations < 0.5 mM inhibits $\text{polymerization}$ of deoxynucleoside triphosphate catalysed by variety of DNA polymerases isolated from type C RNA tumor viruses, as well as $\text{E.}\text{coli}$, but $\text{does}\text{not}$ affect the polymerase associated RNase H activity. Both phosphate and aldehyde groups of pyridoxal phosphate are essential for the inhibition which appears to be mediated through the reversible Schiff base.     

Further characterization of a ribonucleotide-polymerizing enzyme from Histoplasma capsulatum. II. Possible role in cellular metabolism

An enzyme, ribonucleotide polymerase, isolated from the yeast phase of a fungus, $\text{Histoplasma capsulatum}$ has been found to stimulate the incorporation of dTMP in the reaction catalysed by DNA polymerase from $\text{H. capsulatum}$ and $\text{E. coli}$. The stimulation is dependent on the amount of ribonucleotide polymerase added. The data indicate that protein-protein interaction is responsible for the increase in DNA synthesis. It is suggested that ribonucleotide polymerase may be involved in supplying short RNA primers for DNA polymerase.     

A comparison of DNA content between two substrains of Escherichia coli B/r.

The average DNA content per cell was measured in steady-state cultures of two substrains of $\text{E. coli}\text{B}\text{r}$ growing at various rates at 37°C. The DNA content of substrain $\text{B}\text{r}$ F was consistently lower than that of substrain $\text{B}\text{r}$ A. It is suggested that the differences in DNA contents are consequences of strain-specific differences in the relationship between chromosome replication and the division cycle of $\text{E. coli.}$     

Clustering of tRNA cistrons in Escherichia coli DNA

Characterization of tRNA:DNA hybrids reveals that many, perhaps most, of the tRNA genes in $\text{E. coli}$ DNA are clustered. Density and double-isotope measurements show that 3–4 molecules of tRNA can hybridize with DNA fragments that are only 4–5 times larger than a mature tRNA. Treatment of the hybrids with a single-strand-specific endonuclease results in the solubilization of 30–35% of the DNA and the formation of monocistronic hybrids.     

Non-random segregation of DNA strands in Escherichia coli B-r

The segregation of DNA strands during growth of Escherichia coli$\text{B}\text{r}$ has been studied under conditions in which the chromosomal configuration and the ancestry of the cells during growth and division were known. Cells containing either one or two replicating chromosomes were pulse-labeled with [³H]thymidine, and the location of the radioactivity within chains of cells formed by growth in methylcellulose was determined by autoradiography. The locations of the radioactive cells within chains obtained after the second, third and fourth divisions were consistent with the co-segregation of only one of the replicating strands of each chromosome and a fixed region of the cell into daughter cells. The attachment of this strand to the region appeared to become permanent at the time the strand was used for the first time as a template. It is concluded that the segregation of DNA molecules into daughter cells is non-random in E. coli B/r.     

Studies on the mechanism of enzymatic DNA elongation by Escherichia coli DNA polymerase II.

The mechanism of enzymatic elongation by Escherichia coli DNA polymerase II of a DNA primer, which is annealed to a unique position on the bacteriophage fd viral DNA, has been studied. The enzyme is found to dissociate from the substrate at specific positions on the genome which act as “barriers” to further primer extension. It is believed these are sites of secondary structure in the DNA. When the template is complexed with E. coli DNA binding protein many of these barriers are eliminated and the enzyme remains associated with the same primer-template molecule during extensive intervals of DNA synthesis. Despite the presence of E. coli DNA binding protein, at least one barrier on the fd genome remains rate-limiting to chain extension and disturbs the otherwise processive mechanism of DNA synthesis. This barrier is overcome by increasing the concentration of enzyme.In contrast, it is found that DNA polymerase I is not rate-limited by structural barriers in the template, however, it exhibits a non-processive mechanism of elongation.These findings provide a framework for understanding the necessity for participation of proteins other than a DNA polymerase in chain extension during chromosomal replication.     

Excision of thymine dimers by proteolytic and amber fragments of E. coli DNA polymerase I

Excision of thymine dimers from specifically incised ultraviolet irradiated DNA by $\text{E. coli}$ DNA polymerase I is stimulated by concurrent DNA synthesis. The 36,000 molecular-weight “small fragment” obtained by limited proteolysis of DNA polymerase I, which retains only the 5′ → 3′ exonuclease activity, also excises thymine dimers, but at one-tenth the rate of the intact enzyme. However, the rate of excision is increased by addition of the “large” 76,000-molecular weight fragment. With the further addition of the 4 deoxynucleoside triphosphates, permitting DNA synthesis to occur, excision approaches rates observed with the intact enzyme. The same result was obtained with a fragment of DNA polymerase I with 5′ → 3′ exonuclease activity that is present uniquely in polymerase I $\text{amber}$ mutants.