Deoxyribonucleic Acid Polymerase of Rous Sarcoma Virus: Studies on the Mechanism of Double-Stranded Deoxyribonucleic Acid Synthesis

The deoxyribonucleic acid (DNA) polymerase of Rous sarcoma virus synthesizes both single- and double-stranded DNA, utilizing the ribonucleic acid (RNA) of the viral genome as the initial template. Results of pulse-chase experiments indicate that the single-stranded DNA serves as unconserved template and precursor for the synthesis of double-stranded DNA. The latter reaction is apparently initiated in association with the viral RNA and may involve a partially double-stranded intermediate form.     

Deoxyribonucleic Acid Polymerases of Rous Sarcoma Virus: Kinetics of Deoxyribonucleic Acid Synthesis and Specificity of the Products

The deoxyribonucleic acid (DNA) polymerase(s) of Rous sarcoma virus synthesizes two principal products-single-stranded DNA in the form of a DNA:ribonucleic acid (RNA) hybrid and double-stranded DNA. All of the single-stranded product and 50% of the double-stranded product can be hybridized to 70S viral RNA. These results, in combination with data obtained by analysis of the kinetics of double-stranded DNA synthesis, indicate that the synthesis of double-stranded DNA is a sequel to the synthesis of single-stranded DNA and is dependent upon the latter for the provision of initial template.     

Role of Adenovirus Structural Proteins in the Cessation of Host-Cell Biosynthetic Functions

Two of the adenovirus capsid proteins, the fiber and the hexon, complexed with either KB cell or type 5 adenovirus deoxyribonucleic acid (DNA). Maximal binding occurred at 0.01 m NaCl; increasing the ionic strength of the reaction mixture to 0.2 m NaCl resulted in a decrease in the association of either antigen to DNA. Variations of pH between 6.3 and 8.4 did not affect the binding of fiber antigen to DNA. Below pH 7.5, however, there was a small decrease in the ability of the hexon to bind nucleic acid. The association between the adenovirus structural proteins and DNA was reversible and was independent of whether the DNA was native or denatured. The fiber or hexon protein inhibited the DNA-dependent ribonucleic acid (RNA) polymerase and the DNA polymerase from KB cells. On a weight basis, the fiber protein inhibited enzymatic activity to a greater extent than the hexon. Increasing the template DNA concentration decreased this inhibition. The inhibition of the DNA-dependent RNA polymerase activity by either antigen could be reversed by increasing the ionic strength of the reaction mixture. After infection of KB cells with type 5 adenovirus, the levels of DNA and RNA polymerases remained unchanged for 15 to 20 hr. Thereafter, the specific activity of both enzymes decreased. By 30 hr postinfection, the polymerase activities were only about 30% of the enzyme activities in uninfected cells.     

Inhibition of chicken myeloblastosis RNA polymerase II activity by adriamycin.

In vitro RNA synthesis by isolated RNA polymerase II of chicken myeloblastosis cells was shown to be highly sensitive to adriamycin inhibition. The template activity of the single-stranded DNA, purified by chromatography of denatured calf thymus DNA through hydroxylapatite columns, was found to be equally as sensitive to the inhibition as denatured calf thymus DNA. However, contrary to denatured DNA, the single-stranded DNA thus purified showed no significant binding to adriamycin as analyzed by cosedimentation of the drug and DNA through a sucrose gradient. This indicated that inhibition of RNA synthesis on a single-stranded DNA template might involve a mechanism other than DNA intercalation. Kinetic studies of the inhibition showed that the inhibition of RNA synthesis by adriamycin could not be reversed by increasing the concentrations of RNA polymerase and four nucleoside triphosphates, but it could be reversed by increasing DNA concentrations. Analysis of the size of RNA synthesized indicated that the ultimate size of the product RNA was not altered by adriamycin, suggesting that the drug may inhibit RNA synthesis by reducing RNA chain initiation.     

Effect of aflatoxin B1 on chromatin-bound ribonucleic acid polymerase and nucleic acid and protein synthesis in germinating maize seeds.

The treatment of germinating maize seeds (cv. Ganga 2) with aflatoxin B1 resulted in suppression of ribonucleic acid (RNA), protein, and deoxyribonucleic acid (DNA) synthesis at 3, 4, and 5 h, respectively. At or below the concentrations inhibitory for these in vivo syntheses, the toxin inhibited chromatin-bound DNA-dependent RNA polymerase activity. The synthesis of both polyadenylated and non-polyadenylated RNA was inhibited, but the effect on the former was more pronounced. Equilibrium dialysis and difference spectral and viscometric analyses showed a binding of aflatoxin B1 to DNA isolated from the seeds. It is proposed that the inhibition of RNA synthesis in maize seeds by the toxin is due to the interference with the RNA polymerase activity, which seems, at least partially, due to the impairment of DNA template functions.     

Effect of aflatoxin B1 on chromatin-bound ribonucleic acid polymerase and nucleic acid and protein synthesis in germinating maize seeds

The treatment of germinating maize seeds (cv. Ganga 2) with aflatoxin B1 resulted in suppression of ribonucleic acid (RNA), protein, and deoxyribonucleic acid (DNA) synthesis at 3, 4, and 5 h, respectively. At or below the concentrations inhibitory for these in vivo syntheses, the toxin inhibited chromatin-bound DNA-dependent RNA polymerase activity. The synthesis of both polyadenylated and non-polyadenylated RNA was inhibited, but the effect on the former was more pronounced. Equilibrium dialysis and difference spectral and viscometric analyses showed a binding of aflatoxin B1 to DNA isolated from the seeds. It is proposed that the inhibition of RNA synthesis in maize seeds by the toxin is due to the interference with the RNA polymerase activity, which seems, at least partially, due to the impairment of DNA template functions.     

Effect of neocarzinostatin-induced strand scission on the template activity of DNA for DNA polymerase I.

Neocarzinostatin (NCS), an antitumor protein antibiotic that causes strand scissions of DNA both in vitro and in vivo, is shown to lower the template activity of DNA for DNA polymerase Iin vitro. There is a correlation between the extent of strand scission and the degree of inhibition, maximal inhibition of the polymerase reaction being obtained under conditions promoting maximal strand scission. These effects can be related to the concentrations of NCS and of 2-mercaptoethanol and are maximized by pretreatment of the DNA with drug. Results from polymerase assays in which the amount of drug-treated DNA template was varied at a constant level of the enzyme suggest that the sites associated with NCS-induced breaks are nonfunctional in DNA synthesis but bind DNA polymerase I. The binding of the enzyme to the inactive sites is further confirmed using [203 Hg] polymerase. It is shown that the lowering of the template activity of DNA by NCS under conditions of strand scission is due to the generation of a large number of inactive sites that block, competitively, the binding of DNA polymerase to the active sites on the template. Furthermore, the inhibition of DNA synthesis, which depends on the extent of strand breakage and on the relative amounts of template and enzyme, can be reversed by increasing the levels of template or polymerase. The finding that DNA synthesis directed by poly [d(A-T)] is much more sensitive to NCS than that primed by poly [d(G-C)] suggests that the drug preferentially interacts at regions containing adenine and/or thymine residues.     

The role of sulfhydryl groups in the functioning of DNA-dependent RNA-polymerase

Sulfhydryl groups of Escherichia coli DNA-dependent RNA polymerase were chemically modified with alkylating and mercuric-containing compounds. Iodoacetic acid and iodoacetamide were shown not to affect the enzymatic activity, whereas N-ethylmaleimide and mercuric-containing compounds completely inhibit the RNA synthesis. RNA polymerase modified with mercuric ions looses the ability of binding with promoter--containing DNA fragments. Moreover, mercuric ions inhibit the RNA elongation stage. Suggestion is made the Cys residues of RNA polymerase play a key role in double-stranded DNA unwinding. It is shown that SH-groups of beta- and beta'-subunits participate in the binding with double-stranded fragments of DNA.     

Influence of template inactivators on the binding of DNA polymerase to DNA

The agents daunomycin, ethidium bromide, distamycin A and cytochrome c inhibit DNA dependent DNA polymerase I (E. coli) reaction competitively to DNA. The influence of these template inactivators on the binding of DNA polymerase to native as well as denatured DNA has been determined by affinity chromatography. Cytochrome c blocks the binding of the enzyme to double-stranded and to single-stranded DNA Sepharose. In contrast to these results daunomycin, ethidium bromide or distamycin A reduce the binding affinity only with denatured DNA Sepharose as matrix. These data are discussed with respect to the modification by template inactivators of the affinity of DNA to the different binding sites of the DNA polymerase.     

Template specificities of Aclacinomycin B on the inhibition of DNA-dependent RNA synthesis in vitro

Summary The effect of Aclacinomycin B (ACM-B), an anthracycline antitumor antibiotic, on the DNA-dependent RNA synthesis using single- and double-stranded DNAs of known base content and sequence is studied. The data show that ACM-B effectively inhibits the double-stranded DNA-directed RNA synthesis with a preference of poly[d(A-T)] > poly[d(G-C)] > poly[d(I-C)]. In contrast, it has no inhibitory effect on the template function of single-stranded DNA (e.g. poly dA, poly dT, and poly dC). These results suggest that the mechanism of ACM-13 inhibition, like other anthracycline antibiotics, is by intercalation. In addition to the base specificity, there are also dramatic differences in inhibition depending on the base sequence in the DNA template. Thus, ACM-13 preferentially inhibits the alternating double-stranded copolymers over the double-stranded homopolymers; e.g. poly [d(A-T)] is inhibited to a greater extent than poly dA · poly dT and poly [d(G-C)] is inhibited more than poly dG · poly dC. Since the inhibition by ACM-13 can be totally abolished when assayed in excess amount of DNA, this result suggests that ACM-B inhibition of RNA synthesis is solely on the DNA template (which is in support of the intercalation model), and has ruled out the possibility that ACM-B may also exert an inhibitory effect on the activity of RNA polymerase per se.     

Plasmid rolling circle replication: identification of the RNA polymerase-directed primer RNA and requirement for DNA polymerase I for lagging strand synthesis.

Plasmid rolling circle replication involves generation of single-stranded DNA (ssDNA) intermediates. ssDNA released after leading strand synthesis is converted to a double-stranded form using solely host proteins. Most plasmids that replicate by the rolling circle mode contain palindromic sequences that act as the single strand origin, sso. We have investigated the host requirements for the functionality of one such sequence, ssoA, from the streptococcal plasmid pLS1. We used a new cell-free replication system from Streptococcus pneumoniae to investigate whether host DNA polymerase I was required for lagging strand synthesis. Extracts from DNA polymerase I-deficient cells failed to replicate, but this was corrected by adding purified DNA polymerase I. Efficient DNA synthesis from the pLS1-ssoA required the entire DNA polymerase I (polymerase and 5'-3' exonuclease activities). ssDNA containing the pLS1-ssoA was a substrate for specific RNA polymerase binding and a template for RNA polymerase-directed synthesis of a 20 nucleotide RNA primer. We constructed mutations in two highly conserved regions within the ssoA: a six nucleotide conserved sequence and the recombination site B. Our results show that the former seemed to function as a terminator for primer RNA synthesis, while the latter may be a binding site for RNA polymerase.