Ribonucleotides in closed circular mitochondrial DNA from HeLa cells

Closed circular mitochondrial DNA from HeLa cells is sensitive to both alkali and ribonucleases. The kinetics of ring opening in alkali suggest at least two classes of molecules. One class undergoes rapid breakdown, ultimately to fragments smaller than unit length, in contrast to the second class, which is more resistant to alkaline cleavage and is converted in large part to unit length single strands. Ribonucleases A, T₁ and H relax the supercoiled molecules, indicating that the alkali susceptibility is due to the presence of ribonucleotides in the DNA. By comparison with the rate of hydrolysis of RNA, the alkali-resistant class of mitochondrial DNA molecules is estimated to contain approximately 3 ribonucleotides and the alkalisensitive class 10–18.     

Promoter search by Escherichia coli RNA polymerase on a circular DNA template

Using the rapid-mixing/photocross-linking technique developed in our laboratory, we have investigated the kinetics of interaction between Escherichia coli RNA polymerase and pAR1319, a recombinant plasmid DNA containing the bacteriophage T7 A2 early promoter. By monitoring the time-dependent density of bound RNA polymerase along the relaxed circular DNA molecule using this technique, we have been able to demonstrate kinetic evidence for linear diffusion of RNA polymerase along DNA in a different system from that previously described (Park, C. S., Hillel, Z., and Wu, C.-W. (1982) J. Biol. Chem. 251, 6950-6956). The nonspecific association rate constant kon was measured to be 7.7 x 10(4) M-1 s-1 at a DNA chain concentration of 22.4 nM. By taking advantage of the fact that rapid mixing displaces bound protein molecules from DNA, but leaves them within the domain of the DNA, the rate of intradomain binding of RNA polymerase to pAR1319 DNA was determined to be 8.2 s-1. Since the plasmid is described by a radius of gyration of 0.22 microns, the intradomain concentration of base pairs could be calculated. Using this concentration (180 microM), the rate constant for intradomain nonspecific association of RNA polymerase to pAR1319 DNA was estimated to be 4.6 x 10(4) M-1 s-1. In addition, a mathematical model has been used to fit the other two important rate constants to the experimental data: koff, which describes the dissociation of RNA polymerase from nonspecific binding sites, and D1, the one-dimensional diffusion coefficient of the enzyme along the DNA molecule. In this model, the circular DNA molecule is described as a ring of interconnected binding sites which together comprise a DNA "domain." RNA polymerase, which enters the domain via three-dimensional diffusion and binds to each site, is allowed to diffuse linearly between adjacent sites and three-dimensionally on and off the DNA molecule. The rate equations for the time-dependent occupancy of each site by RNA polymerase could be written, based on general principles. By solving the resulting family of differential equations, koff and D1 were determined to be 0.3 s-1 and 1.5 x 10(-9) cm2 s-1, respectively.     

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 denaturation of DNA template on activity of RNA polymerase of class B

The effect of the denaturation of homologous and calf thymus DNA on the RNA polymerase B activity purified from rat liver and spleen and Ehrlich ascites cells, was investigated in presence of either Mn2+ or Mg2+ and in presence or absence of alpha-amanitin. On the basis of the results here reported, we suggest: 1) denatured DNA is more effective than native as template for polymerase B; 2) denatured DNA template and cations might play a role in determining the extent of the reaction alpha-amanitin-polymerase B.     

Bridging PNAs can bind preferentially to a deleted mitochondrial DNA template but replication by mitochondrial DNA polymerase gamma in vitro is not impaired

Mutations in mitochondrial DNA (mtDNA) are an important cause of neurological and other human pathologies. In the vast majority of cases, supportive care only is available. Mutated and wild-type mtDNAs often coexist in the same cell. A strategy for treatment has been proposed whereby replication of mutated mtDNA is inhibited by selective hybridisation of a nucleic acid derivative, allowing propagation of the wild-type genome and correction of the associated respiratory chain defect. Peptide nucleic acid molecules (PNAs) can be designed to selectively target pathogenic mtDNA with single point mutations. Molecules harbouring deletions present a complex problem. Deletions often occur between two short repeat sequences (4-13 residues), one of which is retained in the deleted molecule. With the more common large repeats, it is therefore difficult to design an antigenomic molecule that will bind selectively under physiological conditions. Following limited success with antigenomic oligodeoxynucleotides (ODNs), we have repeated these studies with a series of bridging PNAs. Molecules complementary to the sequence flanking either side of the 13 bp 'common deletion' were synthesised. The PNAs demonstrated markedly greater affinity for the delete than to the wild-type template. In runoff assays using Klenow fragment, these PNAs selectively inhibited replication of the delete template. However, no selective inhibition was observed when a polymerase gamma-containing mitochondrial fraction was used.     

The presence of nucleosomes on a DNA template prevents initiation by RNA polymerase II in vitro

RNA was synthesized in vitro using HeLa cell nuclear extracts and circular DNA templates onto which varying numbers of nucleosomes had been reconstituted with Xenopus oocyte extracts. We found that fully reconstituted templates supported no specific initiation by RNA polymerase II; however, DNA exposed to the reconstitution extracts under conditions which did not allow nucleosome deposition was transcribed normally. A set of successively less reconstituted templates was also transcribed. No initiation occurred on reconstitutes with more than two-thirds of the physiological nucleosome density; reconstitutes with less than one-third of the physiological nucleosome density were transcribed as efficiently as naked DNA.