Effect of molecular crowding on DNA polymerase activity

Live cells contain high concentrations of macromolecules, but almost all experimental biochemical data have been generated from dilute solutions that do not reflect conditions in vivo. To understand biomolecular behavior in vivo, properties studied in vitro are extrapolated to conditions in vivo; however, the molecular conditions within live cells are inherently crowded. The present study investigates the effect of molecular crowding on DNA polymerase activity using polyethylene glycol PEG of various molecular weights as a crowding agent. Polymerase activity assays under various conditions demonstrated that the activities of T7 and Taq DNA polymerases depend on the molecular weight and concentration of the crowding agent. Furthermore, equilibrium and kinetic analyses demonstrated that the binding affinity and catalytic activity of the polymerase increase and decrease, respectively, with increasing PEG concentrations. Based on quantitative parameters of the polymerase reactions, we improved the efficiency of PCR amplification under conditions of molecular crowding. These results suggest that quantitative measurements of biomolecular structure and function are useful for understanding the behavior of biomolecules in vivo and for biotechnology applications in vitro.     

Effect of the antitumor antibiotic bleomycin on DNA polymerase activity

Treatment with bleomycin activates considerably a repair synthesis of DNA in rat liver chromatin in vitro and can cause loosening of the nucleoprotein complex, which facilitates the accessibility or repair enzymes for lesions in chromatin DNA. The bleomycin action on DNA-template increases severalfold the rate of synthesis catalyzed by DNA polymerase beta inhibits the activity of DNA polymerase I from Escherichia coli and suppresses severalfold the activity of DNA polymerase alpha and DNA polymerase of bacteriophage T4. The effect of bleomycin consists in a prevailing increase of nicks and minimal gaps in DNA as compared to the rise of moderate gaps, thus suggesting that bleomycin is a gamma-mimetic.     

Increased mitochondrial DNA and RNA polymerase activity in ethylene-treated potato tubers

A purified mitochondrial fraction was isolated from potato (Solanum tuberosum L.) tubers respiring normally at 23°C or at an accelerated rate in response to treatment with ethylene (10 microliters per liter).

A pronounced increase in various mitochondrial enzymic activities was observed in response to exposure of the whole tubers to ethylene. Cytochrome c oxidase activity increased more than 50%, DNA polymerase activity increased about 2-fold, and RNA polymerase activity increased 2.5-fold. Moreover, DNA or RNA polymerase activities of mitochondria isolated from tubers not treated with ethylene were not affected by ethylene treatment in vitro. Respiratory control ratios decreased from 2.84 to 1.50 with increasing periods of ethylene treatment from 0 to 15 hours. None of these changes were observed in untreated tubers. It is concluded that the stimulation of respiration by ethylene in potato tubers is accompanied in vivo by an enhancement of mitochondrial enzymic activity of both membrane-associated enzymes which participate in the mitochondrial oxidative electron transport as well as soluble enzymes which are not directly involved in respiration.

     

Effect of polyamines on the activity of malarial alpha-like DNA polymerase

DNA polymerase from the malarial parasite Plasmodium falciparum required Mg2+ for activity, Putrescine (1 mM) caused a twofold increase in enzyme activity in the presence of a suboptimal concentration of MgCl2 (2 mM). Spermidine (1.5-2.0 mM) or spermine (0.1-0.3 mM) increased the activity of malarial DNA polymerase, in the presence of 2 mM MgCl2, by factors of 6 and 3-5, respectively. The activity of DNA polymerase from calf thymus or from NIH 3T3 cells transformed by the ras oncogene were not stimulated by these polyamines to the same extent. These findings suggest that in malaria-infected erythrocytes, polyamines, at physiological concentrations, serve as a cofactor for the parasitic alpha-like DNA polymerase. Malarial parasites grown in cultured human erythrocytes did not synthesize DNA after treatment with alpha-difluoromethylornithine, which caused polyamine depletion in the infected cells. DNA synthesis was resumed after adding putrescine to the polyamine-depleted cultures. DNA synthesis was also initiated when actinomycin D was added along with putrescine to polyamine-depleted cells. It thus appears that polyamines are essential for the translation of the DNA polymerase mRNA and that polyamines play an important role in regulating the cell cycle of the malarial parasite.     

Fidelity of the human mitochondrial DNA polymerase

We have quantified the fidelity of polymerization of DNA by human mitochondrial DNA polymerase using synthetic DNA oligonucleotides and recombinant holoenzyme and examining each of the possible 16-base pair combinations. Although the kinetics of incorporation for all correct nucleotides are similar, with an average Kd of 0.8 microM and an average k(pol) of 37 s(-1), the kinetics of misincorporation vary widely. The ground state binding Kd of incorrect bases ranges from a low of 25 microM for a dATP:A mispair to a high of 360 microM for a dCTP:T mispair. Similarly, the rates of incorporation of incorrect bases vary from 0.0031 s(-1) for a dCTP:C mispair to 1.16 s(-1) for a dGTP:T mispair. Due to the variability in the kinetic parameters for misincorporation, the estimates of fidelity range from 1 error in 3563 nucleotides for dGTP:T to 1 error in 2.3 x 10(6) nucleotides for dCTP:C. Interestingly, the discrimination against a dGTP:T mismatch is 16.5 times lower than that of a dTTP:G mismatch due to a tighter Kd for ground state binding and a faster rate of incorporation of the dGTP:T mismatch relative to the dTTP:G mismatch. We calculate an average fidelity of 1 error in 440,000 nucleotides.     

Effect of specific inhibitors on mitochondrial DNA replication in HeLa cells

The crystal structure of an orthorhombic form of 2′-0-methyl cytidine was determined from three dimensional X-ray diffraction data. The two molecules in each asymmetric unit have C2-$\text{endo}$ C3-$\text{exo}$ puckered furanose rings. This differs from the C3-$\text{endo}$ puckering observed for cytidine (1) and it may have some relevance to the kinks that appear at the two 2′-0-methylated nucleotides in the anticodon phosphate ester backbone of the phe tRNA structure (2). This work and other studies (3,4) show that the presence of a 2′-0-methyl group does not prevent the furanose moiety from adopting its most commonly observed configurations. 2′-0-methyl nucleotides make up a small percentage of the residues in HnRNA, rRNA, tRNA and mRNA and therefore their conformational nuances are of interest.     

Effects of the Xenopus laevis mitochondrial single-stranded DNA-binding protein on the activity of DNA polymerase gamma

The single-stranded DNA-binding protein from Xenopus laevis oocyte mitochondria, which has been found associated with the D loop, binds to ssDNA in stoichiometric amounts and can under certain conditions stimulate the activity of the DNA polymerase gamma. Its properties suggest that it is involved in strand displacement during the replication of the mitochondrial genome.     

Effect of the Y955C mutation on mitochondrial DNA polymerase nucleotide incorporation efficiency and fidelity

The human mitochondrial DNA polymerase (pol γ) is responsible for the replication of the mitochondrial genome. Mutation Y955C in the active site of pol γ results in early onset progressive external ophthalmoplegia, premature ovarian failure, and Parkinson's disease. In single-turnover kinetic studies, we show that the Y955C mutation results in a decrease in the maximal rate of polymerization and an increase in the K(m) for correct incorporation. The mutation decreased the specificity constant for correct incorporation of dGTP, TTP, and ATP to values of 1.5, 0.35, and 0.044 μM(-1) s(-1), respectively, representing reductions of 30-, 110-, and 1300-fold, respectively, relative to the value for the wild-type enzyme. The fidelity of incorporation was reduced 6-130-fold, largely because of the significant decrease in the specificity constant for correct dATP:T incorporation. For example, k(cat)/K(m) for forming a TTP:T mismatch was decreased 10-fold from 0.0002 to 0.00002 μM(-1) s(-1) by the Y955C mutant, but the 1300-fold slower incorporation of the correct dATP:T relative to that of the wild type led to a 130-fold lower fidelity. While correct incorporation of 8-oxo-dGTP was largely unchanged, the level of incorporation of 8-oxo-dG with dA in the template strand was reduced 500-fold. These results support a role for Y955 in stabilizing A:T base pairs at the active site of pol γ and suggest that the severe clinical symptoms of patients with this mutation may be due, in part, to the reduced efficiency of incorporation of dATP opposite T, and that the autosomal dominant phenotype may arise from the resulting higher mutation frequency.     

A nuclear mutant of Saccharomyces cerevisiae deficient in mitochondrial DNA replication and polymerase activity

We have isolated a thermosensitive mutant which is transformed into a population of cells devoid of mitochondrial DNA (rho 0 cells) at 35 degrees C and is deficient in mitochondrial (mt) DNA polymerase activity. A single recessive nuclear mutation (mip1) is responsible for rho 0 phenotype and mtDNA polymerase deficiency in vitro. At 25 degrees C (or 30 degrees C) a dominant suppressor mutation (SUP) masks the deficiency in vivo. The meiotic segregants (mip1 sup) which do not harbor the suppressor have a rho 0 phenotype both at 25 and 35 degrees C. They have no mtDNA polymerase activity, in contrast with MIP rho 0 mutants of mitochondrial inheritance which do exhibit mtDNA polymerase activity. In the thermosensitive mutant (mip1 SUP), the replication of mtDNA observed in vivo at 30 degrees C is completely abolished at 35 degrees C. In the meiotic segregants (mip1 sup), no mtDNA replication takes place at 30 and 35 degrees C. The synthesis of nuclear DNA is not affected. DNA polymerases may have replicative and/or repair activity. There is no evidence that mip mutants are deficient in mtDNA repair. In contrast the MIP gene product is strictly required for the replication of mtDNA and for the expression of the mtDNA polymerase activity. This enzyme might be the replicase of mtDNA.     

Effects of inhibitors and activators on the activity of two diaphorases from Drosophila virilis

The effect of some inhibitors and activators of mammalian DT-diaphorase on diaphorase-1 (DIA-1) and diaphorase-2′ (DIA-2′) purified from Drosophila virilis was studied. The inhibitors and activators changed the activity of these diaphorases in a different way, revealing a similarity between mammalian DT-diaphorase and D. virilis DIA-1 on the one hand and on the other between the D. virilis DIA-1 and the diaphorase purified from Bombyx mori eggs. These effects also confirm the independent genetic control of DIA-1 and DIA-2′ in D. virilis and make possible the differentiation of these diaphorase activities in crude enzyme extracts.     

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.     

A phylogenetic study on vertebrate mitochondrial DNA polymerase.

We have started a phylogenetic survey for the mitochondrial DNA polymerase and present in this study the results obtained for all the different classes for the vertebrates. The operating conditions include the purification of mitochondria, the analysis of the DNA polymerase activity in the extract and the determination of the sedimentation coefficient on sucrose gradients. The utilization of digitonin for removing the external membrane of the organelle and contaminating proteins has been generalized since this detergent shows no effect on the activities of either DNA polymerases alpha or gamma. The results obtained for the mitochondria of different classes of vertebrates show that the activity responding to the specific assay of DNA polymerase gamma tended invariably to increase during purification while that of DNA polymerase alpha tended to decrease. Furthermore in almost all the cases the gamma-polymerase represented the only DNA polymerase activity found in the mitochondria after digitonin treatment. The analysis of the sedimentation patterns of the mitochondrial DNA polymerase strongly suggests the presence of a single type of DNA polymerase showing the typical properties of the gamma-polymerase. It is concluded that the vertebrate mitochondria contain a well-defined and unique form of DNA polymerase which corresponds to the DNA polymerase gamma.     

Exonuclease proofreading by human mitochondrial DNA polymerase

We have examined the ability of the human mitochondrial DNA polymerase to correct errors in DNA sequence using single turnover kinetic methods. The rate of excision of single-stranded DNA ranged from 0.07 to 0.17 x s(-1), depending on the identity of the 3'-base. Excision of the 3'-terminal base from correctly base paired DNA occurred at a rate of 0.05 x s(-1), indicating that the cost of proofreading is minimal, as defined by the ratio of the k(exo) for correctly base-paired DNA divided by the rate of forward polymerization (0.05/37 = 0.14%). Excision of duplex DNA containing 1-7 mismatches was biphasic, and the rate and amplitude of the fast phase increased with the number of mismatches, reaching a maximum of 9 x s(-1). We showed that transfer of DNA from the polymerase to the exonuclease active site and back again occurs through an intramolecular reaction, allowing for a complete cycle of reactions for error correction. For DNA containing a buried mismatch (T:T followed by C:G base pairs), the 3' base was removed at a rate of 3 x s(-1). The addition of nucleotide to the reaction that is identical to the 3' base increased the rate of excision 7-fold to 21 x s(-1). We propose that the free nucleotide enhances the rate of transfer of the DNA to the exonuclease active site by interrupting the correct 3' base pair through interaction with the template base. The exonuclease contribution to fidelity is minimal if the calculation is based on hydrolysis of a single mismatch: (k(exo) + k(pol,over))/(k(pol,over)) = 10, but this value increases to approximately 200 when examining error correction in the presence of nucleotides.     

Effect of the polymerase activity of DNA polymerase I on the development of moderate bacteriophages Mu, lambda red- and lambda red-gam-. II. The effect of the polymerase activity of DNA polymerase I on the development of bacteriophage Mu

The paper reports on the influence of polymerizing activity of DNA-polymerase I on different developmental stages of temperate bacteriophage Mu in Escherichia coli K-12 cells. This activity is shown to be necessary for optimization of phage Mu primary integration into cell chromosomes. The relative frequency of Mu integration into bacterial chromosomes is 5-6 times lower in polA cells than in isogenic polA+ control strains, the phage yield from cells being delayed during the phage infectious development, but not in the course of induction from the prophage state. Data have been obtained that show the process of phage Mu DNA integration into the plasmid pRP1 .2 and the process of Mu transposition from the cell chromosome into the plasmid to be independent of the polymerizing activity of DNA-polymerase I.