Structure of a replication intermediate in the synthesis of Rous sarcoma virus DNA in vivo

Intermediates in the synthesis of Rous sarcoma virus DNA in vivo contain a short second strand of DNA (plus strong-stop DNA) synthesized by using the region near the 5' end of the first (minus) strand of DNA as the template. In this report, we show that the 3' end of plus strong-stop DNA is extended about 15 to 20 nucleotides beyond the 5' end of the minus-strand DNA template, probably copying a portion of the tRNATrp molecule that serves as primer for synthesis of the minus strand of DNA. The extra sequences present in plus strong-stop DNA may play a central role in the generation of the long terminal repeat present in mature forms of viral DNA.     

Poly(dG-dC) in the Z-form inhibits E. coli DNA polymerase I and AMV DNA polymerase activity

The effect of Z-conformation of DNA on its template activity in DNA synthesis reactions in vitro has been studied. Normal poly(dG-dC) in the B-form, brominated and unbrominated in the Z-form have been compared for their template activity in DNA synthesis reactions mediated by AMV DNA polymerase and E. coli DNA polymerase I. The results indicate that poly(dG-dC) in the Z-form is totally inactive as a template for DNA synthesis and further that it is a strong competitive inhibitor of copying of the B-form DNA.     

Effect of single-stranded DNA binding proteins on template/primer-independent DNA synthesis in the presence of nicking endonuclease Nt.BspD6I

In the presence of the Nt.BspD6I nicking endonuclease DNA polymerase Bst stimulates intensive template/primer-independent DNA synthesis. Template/primer-independent DNA synthesis could be the reason for appearing nonspecific DNA products in many DNA amplification reactions particularly in the reactions with using nicking endonucleases. Search of the modes for inhibition template/primer-independent DNA synthesis becomes an urgent task because of broadening the DNA amplification methods with using nicking endonucleases. We report here that the E. coli single-stranded DNA binding protein has no effect on the template/primer-independent DNA synthesis. In the absence of the nicking endonuclease the single-stranded DNA binding protein encoded by bacteriophage T4 gene 32 completely inhibits template/primer-independent DNA synthesis. This protein does not inhibit synthesis of specific DNA product in the presence of nicking endonuclease but remarkably decreases the amount of nonspecific products.     

Analysis of bacteriophage phi X174 gene A protein-mediated termination and reinitiation of phi X DNA synthesis. I. Characterization of the termination and reinitiation reactions

The phi X174 (phi X) gene A protein-mediated termination and reinitiation of single-stranded circular (SS(c] phi X viral DNA synthesis in vitro were directly and independently analyzed. Following incubation together with purified DNA replication enzymes from Escherichia coli, ATP, [alpha-32P]dNTPs, and either the phi X A protein and phi X replicative form I (RF I) DNA, or the purified RF II X A complex, the phi X A protein was detected covalently linked to newly synthesized 32P-labeled DNA. Formation of the phi X A protein-[32P]DNA covalent complex required all the factors necessary for phi X (+) SS(c) DNA synthesis in vitro. Thus, it was a product of the reinitiation reaction and an intermediate of the replication cycle. Identification of this complex provided direct evidence that reinitiation of phi X (+) strand DNA synthesis involved regeneration of the RF II X A complex. Substitution of 2',3'-dideoxyguanosine triphosphate (ddGTP) for dGTP in reaction mixtures resulted in the formation of covalent phi X A protein 32P-oligonucleotide complexes; these complexes were trapped analogues of the regenerated RF II X A complex. They could not act catalytically due to the presence of ddGMP residues at the 3'-termini of the oligonucleotide moieties. Reaction mixtures containing ddGTP also yielded nonradioactive (+) SS(c) DNA products derived from circularization of the displaced (+) strand of the input parental template DNA. The formation of the phi X A protein-32P-oligonucleotide complexes and nonradioactive (+) SS(c) DNA were used to assay both reinitiation and termination reactions, respectively. Both reactions required DNA synthesis from the 3'-hydroxyl primer at nucleotide residue 4305 which was formed by cleavage of phi X RF I DNA by the phi X A protein. Elongation of this primer by 18, but not 11 nucleotides was sufficient to support each reaction. Reinitiation reactions proceeded rapidly and were essentially complete after 90 s. In contrast, when ddGTP was replaced with dGTP in reaction mixtures, DNA synthesis proceeded with linear kinetics for up to 10 min. These results suggested that in the presence of all four dNTPs, active templates supported more than 40 rounds of DNA synthesis.     

Isolation of a fraction from cauliflower mosaic virus-infected protoplasts which is active in the synthesis of (+) and (-) strand viral DNA and reverse transcription of primed RNA templates

Sub-cellular fractions, isolated from cauliflower mosaic virus (CaMV)-infected turnip protoplasts, are capable of synthesising CaMV DNA in vitro on an endogenous template and of reverse transcribing oligo dT-primed cowpea mosaic virus RNA. The activity was not detected in mock-inoculated protoplasts. In vitro-labelled DNA hybridized to single-stranded M13 clones complementary to the putative origins of (-) and (+) strand CaMV DNA synthesis and to restriction endonuclease fragments encompassing more than 90% of the CaMV genome. The synthesis of (-) and (+) strand DNA appeared asymmetric. The template(s) for in vitro CaMV DNA synthesis are in a partially nuclease-resistant form. Fractions capable of in vitro CaMV DNA synthesis contained CaMV RNA both heterogeneous and as discrete species; they also contained a range of different sizes of CaMV DNA. Several lines of evidence indicate that this range of in vitro-labelled CaMV DNA, extending from 0.6kb to 8.0kb in length, represents elongating (-) strand DNA. These are discussed in relation to their role as possible replicative intermediates.     

The effect of single-stranded DNA binding proteins on template/primer-independent DNA synthesis in the presence of nicking endonuclease Nt.BspD6I

Nt.BspD6I nicking endonuclease stimulates template/primer-independent DNA synthesis by Bst DNA polymerase. Template/primer-independent DNA synthesis may be one of the reasons for the formation of nonspecific products in certain DNA amplification reactions, especially those involving nicking endonucleases. Expansion of the range of DNA amplification procedures performed in the presence of nicking endonucleases makes the search for template/primer-independent DNA synthesis inhibitors highly relevant. The present work has shown that a single-strand DNA binding protein from E. coli does not affect template/primer-independent DNA synthesis regardless of the presence or absence of Nt.BspD6I. A single-stranded DNA-binding protein coded by gene 32 from bacteriophage T4 completely inhibits template/primer-independent DNA synthesis in the absence of nicking endonuclease. If nicking endonuclease is present, the protein does not suppress the synthesis of the specific product but causes a significant decrease of the amount of template/primer-independent DNA synthesis products.     

Influence of template strandedness on in vitro replication of mutagen-damaged DNA

We analyzed the ability of DNA polymerases to bypass damage on single- and double-stranded templates. In vitro DNA synthesis was studied on UV-irradiated and polyaromatic hydrocarbon reacted (benzo[a]pyrenediol epoxide and oxiranylpyrene) double-stranded templates by a protocol involving initiation on a uniquely nicked circular double-stranded template. The template was prepared by treating single-stranded (+)M13mp2 circular strands with mutagen and then hybridizing with restricted M13 RFmp2, followed by isolation of the nicked RFII forms. The protocol permits either (+), (-), or both strands to carry lesions. We found that the rules for termination and bypass of lesions previously observed with single-stranded DNA templates also hold for double-stranded templates. Termination of synthesis occurs primarily one nucleotide 3' to the lesion in the template strand. Bypass of UV-induced lesions can be followed in a series of three partial reactions in the presence of Mn2+ and dGMP, which relax the specificity of nucleotide insertion and 3'----5' exonuclease activity, respectively. There is no evidence for greater permissivity of bypass in double-as opposed to single-stranded templates. As with single-stranded templates, purines and preferentially deoxyadenosine (dA) are inserted opposite lesions. Lesions in the nontemplate strand elicit neither termination nor pausing. The addition of Rec A protein resulted in a measurable increase of bypass in this system.     

Ultra-sensitive detection of Ag(+) ions based on Ag(+)-assisted isothermal exponential degradation reaction

Ag(+) ions are greatly toxic to a lot of algae, fungi, viruses and bacteria, which can also induce harmful side-effects to environments and human health. Herein we report an ultra-sensitive method for the selective detection of Ag(+) ions with electrochemical technique based on Ag(+)-assisted isothermal exponential degradation reaction. In the presence of Ag(+), mismatched trigger DNA can transiently bind to template DNA immobilized on an electrode surface through the formation of C-Ag(+)-C base pair, which then initiates the isothermal exponential degradation reaction. As a result, the mismatched trigger DNA may melt off the cleaved template DNA to trigger rounds of elongation and cutting. After the cyclic degradation reactions, removal of the template DNA immobilized on the electrode surface can be efficiently monitored by using electrochemical technique to show the status of the electrode surface, which can be then used to determine the presence of Ag(+). Further studies reveal that the proposed method can be ultra-sensitive to detect Ag(+) at a picomolar level. The selectivity of the detection can also be satisfactory, thus the proposed method for the Ag(+) ions detection may be potentially useful in the future.