Association of the polioviral RNA polymerase complex with phospholipid membranes.

Polioviral RNA polymerase complex, which consists of enzyme, template, and nascent RNA, is membrane bound in vivo. The solubilized RNA polymerase complex associated spontaneously in vitro with phospholipid bilayer membranes (liposomes) of defined composition. The degree of association at 37 degrees C was greater for those membranes that were more fluid, suggesting that the binding involves the interaction of the RNA polymerase complex with the hydrocarbon chains in the interior of the lipid bilayer. The polymerase activity was not enhanced by addition of the lipid; in fact, the addition of some of the longer-chain lipids resulted in up to a 40% inhibition of the polymerase activity. Spin-label electron paramagnetic resonance experiments, which measured the membrane fluidity, and kinetic experiments on the rate of incorporation of tritiated UTP into RNA by the polymerase were performed as a function of temperature. The results indicated that the activity of the polymerase was not affected by the physical state of the phospholipid membrane and that its active site was not intimately associated with the membrane. Analysis of both the viral and host polypeptides associated with the smooth membrane-bound polymerase indicated that X was the primary viral polypeptide present. In addition, host polypeptides of molecular weight 86,000, 62,000, 54,000, and 46,000 were also present. If the membrane was disrupted with detergent, polypeptide X was released from the polymerase activity, suggesting that X may play a role in binding the polymerase to the membrane. In an analogous manner, polypeptide X associated spontaneously with phospholipid membranes to a greater extent than the capsid polypeptides. Analysis of both the host and viral polypeptides associated with the viral RNA polymerase purified by precipitation in 2 M LiCl indicated that host polypeptides of molecular weight 106,000, 38,000, 33,000, and 14,000 were the major constituents, whereas relatively small amounts of the viral polypeptides were present. It was confirmed that of the viral polypeptides found, polypeptide 4 was present in the largest amount.     

Pea chloroplast DNA primase: characterization and role in initiation of replication

A DNA primase activity was isolated from pea chloroplasts and examined for its role in replication. The DNA primase activity was separated from the majority of the chloroplast RNA polymerase activity by linear salt gradient elution from a DEAE-cellulose column, and the two enzyme activities were separately purified through heparin-Sepharose columns. The primase activity was not inhibited by tagetitoxin, a specific inhibitor of chloroplast RNA polymerase, or by polyclonal antibodies prepared against purified pea chloroplast RNA polymerase, while the RNA polymerase activity was inhibited completely by either tagetitoxin or the polyclonal antibodies. The DNA primase activity was capable of priming DNA replication on single-stranded templates including poly(dT), poly(dC), M13mp19, and M13mp19_+ 2.1, which contains the AT-rich pea chloroplast origin of replication. The RNA polymerase fraction was incapable of supporting incorporation of ³H-TTP in in vitro replication reactions using any of these single-stranded DNA templates. Glycerol gradient analysis indicated that the pea chloroplast DNA primase (115–120 kDa) separated from the pea chloroplast DNA polymerase (90 kDa), but is much smaller than chloroplast RNA polymerase. Because of these differences in size, template specificity, sensitivity to inhibitors, and elution characteristics, it is clear that the pea chloroplast DNA primase is an distinct enzyme form RNA polymerase. In vitro replication activity using the DNA primase fraction required all four rNTPs for optimum activity. The chloroplast DNA primase was capable of priming DNA replication activity on any single-stranded M13 template, but shows a strong preference for M13mp19+2.1. Primers synthesized using M13mp19+2.1 are resistant to DNase I, and range in size from 4 to about 60 nucleotides.     

Single-stranded-DNA-dependent ATPase from HeLa cells that stimulates DNA polymerase alpha-primase activity: purification and characterization of the ATPase

A single-stranded DNA-dependent ATPase that cofractionates during the early stages of purification of a multiprotein DNA polymerase alpha complex from HeLa cells has been purified to homogeneity. The ATPase is part of a 16S multienzyme DNA polymerase alpha complex that is fully active in SV40 DNA replication in vitro. The ATPase hydrolyzes ATP to ADP in a reaction that is completely dependent on the presence of DNA. DNA in single-stranded form is strongly preferred as a cofactor, and polydeoxynucleotides with adenine or thymidine residues are highly effective. Glycerol gradient sedimentation showed that the purified ATPase sedimented at an s20,w of 7 S, and polyacrylamide gel electrophoresis under denaturing conditions reveals two polypeptides with relative molecular weights of 83,000 and 68,000. Both of these polypeptides have purine nucleotide binding sites as revealed by photoaffinity cross-linking experiments. ATP binds to the two subunits more efficiently than GTP, and CTP or UTP does not cross-link with the two polypeptides. DNA synthesis catalyzed by purified HeLa cell DNA polymerase alpha-primase is stimulated in the presence of ATPase and ATP at an optimum concentration of 2 mM. Analysis of the DNA product by gel electrophoresis indicates that with poly(dT) but not phage M13 DNA as template the ATPase overcomes a lag and decreases the length of nascent DNA chains synthesized by the DNA polymerase alpha-primase complex.     

Selective inhibition of phiX RFII compared with fd RFII DNA synthesis in vitro. II. Resolution of discrimination reaction into multiple steps.

In the presence of RNA polymerase, RNase H, discriminatory factors alpha and beta, Escherichia coli binding protein, DNA elongation factor I, DNA elongation factor II preparation, DNA polymerase III, and ATP, UTP, GTP, CTP, dATP, dTTP, dGTP, and dCTP, fd viral DNA can be quantitatively converted to RFII containing a unique gap in the linear minus strand. This gap, mapped with the aid of restriction endonucleases HinII and HpaII, is located within Fragment Hpa-H of the fd genome. The discrimination reaction has been resolved into two steps: Step A, fd viral DNA, E. coli binding protein, and discriminatory factors alpha and beta form a protein DNA complex; Step B, the complex isolated by agarose gel filtration selectively forms fd RFII when supplemented with RNase H, RNA polymerase, and the DNA elongation proteins. The omission of any of the proteins described above during the first reaction resulted in either no discrimination or a decrease in discrimination when the missing protein was added during the second step. Results are presented which indicate that E. coli binding protein, discriminatory factors alpha and beta, and RNase H must be present during the time RNA synthesis occurs in order to selectively form RFII from fd DNA and not phiX RFII. The amount of fd and phiX174 RNA-DNA hybrid formed in vitro is directly related to the DNA synthesis observed. Thus, under discriminatory conditions, only fd viral DNA leads to fd RNA-DNA complexes and no phiX RNA-DNA hybrid is formed. Under nondiscriminatory conditions, both DNAs yield RNA-DNA hybrids and DNA synthesis. In the absence of discriminatory factor alpha, no RNA-DNA hybrid is formed with either DNA, and in turn, no DNA synthesis is detected with either DNA template.