Purification and properties of Rauscher leukemia virus DNA polymerase and selective inhibition of mammalian viral reverse transcriptase by inorganic phosphate

Influence of the RNase H domain of retroviral reverse transcriptases on the metal specificity and substrate selection of their polymerase domains

Reverse transcriptases from HIV-1 and MuLV respectively prefer Mg²⁺ and Mn²⁺ for their polymerase activity, with variable fidelity, on both RNA and DNA templates. The function of the RNase H domain with respect to these parameters is not yet understood. To evaluate this function, two chimeric enzymes were constructed by swapping the RNase H domains between HIV-1 RT and MuLV RT. Chimeric HIV-1 RT, having the RNase H domain of MuLV RT, inherited the divalent cation preference characteristic of MuLV RT on the DNA template with no significant change on the RNA template. Chimeric MuLV RT, likewise partially inherited the metal ion preference of HIV-1 RT. Unlike the wild-type MuLV RT, chimeric MuLV RT is able to use both Mn.dNTP and Mg.dNTP on the RNA template with similar efficiency, while a 30-fold higher preference for Mn.dNTP was seen on the DNA template. The metal preferences for the RNase H activity of chimeric HIV-1 RT and chimeric MuLV RT were, respectively, Mn²⁺ and Mg²⁺, a property acquired through their swapped RNase H domains. Chimeric HIV-1 RT displayed higher fidelity and discrimination against rNTPs than against dNTPs substrates, a property inherited from MuLV RT. The overall fidelity of the chimeric MuLV RT was decreased in comparison to the parental MuLV RT, suggesting that the RNase H domain profoundly influences the function of the polymerase domain.

Lysine 152 of MuLV reverse transcriptase is required for the integrity of the active site

Comparison of the three-dimensional structure of the active sites of MuLV and HIV-1 reverse transcriptases shows the presence of a lysine residue (K152) in the substrate-binding region in MuLV RT, while its equivalent position in HIV-1 RT is occupied by a glycine (G112). To investigate the role of K152 in the mechanism of the polymerase reaction catalyzed by MuLV RT, four mutant RTs, namely, K152A, K152R, K152E, and K152G, were generated and biochemically characterized. All muteins exhibited reduced polymerase activity on both RNA and DNA template-primers with K152E being the most defective. The template-primer binding affinity and the processivity of DNA synthesis, however, remained unchanged. The steady-state kinetic characterization showed little change in K(m.dNTP) (except for that of K152E) and an approximately 3-10-fold decrease in k(cat) depending upon the template-primer and mutational substitutions. The ddNTP resistance patterns were unchanged for all muteins, suggesting no participation of K152 in ddNTP recognition. The ability of individual muteins to add dNTP on the covalently cross-linked enzyme-template-primer complex was significantly decreased. These results together with the analysis of the ion pairs in the catalytic apparatus of MuLV RT suggest that K152 participates in maintaining the integrity of the active site of MuLV RT. Examination of the prepolymerase ternary complex formation showed that neither the wild type nor any of the K152 muteins of MuLV RT are capable of forming stable ternary complexes. This property is in contrast to that of HIV-1 RT, which readily forms stable ternary complexes under similar conditions. These results further indicate that the catalytic mechanism of MuLV RT is significantly different from that of HIV-1 RT, despite the presence of a number of conserved motifs and amino acid residues.

Tyrosine 222, a member of the YXDD motif of MuLV RT, is catalytically essential and is a major component of the fidelity center

Tyrosine 222 of MuLV RT is an invariant residue of the highly conserved YXDD motif in the reverse transcriptase class of enzymes. The residue X is Met 184 in HIV-1 RT and Val 223 in MuLV RT. This residue has been implicated in the fidelity of DNA synthesis, whereas the role of the preceding tyrosine in this aspect, as well as in the catalytic mechanism of MuLV RT, remains to be elucidated. We have substituted Tyr 222 with Phe, Ser, and Ala by site-directed mutagenesis and have characterized the properties of the individual mutant enzymes. The results show that Tyr-->Phe substitution did not affect the polymerase activity of the enzyme, while Tyr-->Ser and Tyr-->Ala substitutions significantly reduced the polymerase activity. The pyrophosphorolysis activities of these mutants showed the same trend as the polymerase activities, suggesting an essential role for Y222 in the catalytic mechanism of MuLV RT. One of the most interesting observations of Y-->F substitution was the significantly increased fidelity of DNA synthesis on RNA templates. In addition, a limited extent of ribonucleotide incorporation on RNA template that was consistently noted with the wild-type enzyme was reduced with the Y222F mutant. The resistance to all four ddNTPs, however, persisted in the wild type and Y222 mutants on the RNA template. A ternary complex model of MuLV RT shows that (a) the aromatic ring of Tyr/Phe is positioned between the terminal and penultimate primer bases and (b) the phenolic OH group is seen within hydrogen bonding distance with the base moieties of two template and penultimate primer nucleotides. We propose that the base stacking interaction of Tyr 222 stabilizes the primer terminus position which is essential for the catalytic reaction. However, the weaker stacking interaction of Y compared to F, due to polarization of the pi-charge toward the phenoxyl-OH as well as the resonating character of its H-bond center, may provide slight flexibility to the position of the template base which may be responsible for the error-proneness of MuLV RT.

An enzymatically active chimeric HIV-1 reverse transcriptase (RT) with the RNase-H domain of murine leukemia virus RT exists as a monomer

The existence of retroviral reverse transcriptases as monomers or dimers is rather intriguing. A classical example of the former is murine leukemia virus reverse transcriptase (MuLV RT), while human immunodeficiency virus type 1 (HIV-1) RT represents the latter. A careful scrutiny of the amino acid sequence alignment of the two enzymes pinpoints the region tentatively responsible for this phenomenon. We report here the construction of a chimeric enzyme containing the first 425 amino acid residues from the N-terminal domain of HIV-1 RT and 200 amino acid residues from the C-terminal domain of MuLV RT. The chimeric enzyme exists as a monomer with intact DNA polymerase and RNase-H functions.

Elucidation of the role of Arg 110 of murine leukemia virus reverse transcriptase in the catalytic mechanism: biochemical characterization of its mutant enzymes

Based on the projected three-dimensional equivalence of conserved amino acids in the catalytic domains of DNA polymerases, we propose Arg 110 of MuLV RT to be an important participant in the catalytic mechanism of MuLV RT. In order to obtain evidence to support this proposition and to assess the functional importance of Arg 110, we carried out site directed mutagenesis of Arg 110 and replaced it with Lys, Ala, and Glu. The mutant enzymes were characterized with respect to their kinetic parameters, ability to bind template-primers, and the mode of DNA synthesis. All the three substitutions at 110 position resulted in severe loss of polymerase activity without any significant effect on the RNase H function. In spite of an approximately 1000-fold reduction in kcat of polymerase activity with three mutant enzymes, no significant reduction in the affinities for either template-primer or dNTP substrates was apparent. Mutant enzymes also did not exhibit significant sulfur elemental effect, implying that the chemical step, i.e., phosphodiester bond formation, was not defective. Examination of the mode of DNA synthesis by the mutant enzymes indicated a shift from processive to the distributive mode of synthesis. The mutants of R110 also displayed significant loss of pyrophosphorolysis activity. Furthermore, the time course of primer extension with mutant enzymes indicated severe reduction in the rates of addition of the first nucleotide and even further reduction in the addition of the second nucleotide. These results suggest that the rate limiting step for the mutant enzymes may be before and after the phosphodiester bond formation. Based on these results, we propose that Arg 110 of MuLV RT participates in the conformational change steps prior to and after the chemical step of polymerase reaction.

Chemical modifications of aminonaphthalenesulfonic acid derivatives increase effectivity and specificity of reverse transcriptase inhibition and change mode of action of reverse transcriptase and DNA polymerase alpha inhibition

The reverse transcriptase (RT) inhibition and the specificity of 15 aminonaphthalenesulfonic acid derivatives were examined with RT of a simian immunodeficiency virus derived from an African green monkey (SIVagmTYO-7). The two compounds with the strongest RT inhibition (NF415) or the highest specificity (NF345), together with suramin, were evaluated against polymerase alpha-primase complex from calf thymus. We have also compared the kinetics of inhibition of the viral and the cellular polymerase by these three compounds. While RT inhibition followed a mixed competitive and non-competitive mechanism, inhibition of the DNA polymerase alpha was competitive for suramin and non-competitive for NF415 and NF345. Certain structural characteristics appeared to be common for specific RT inhibitors.

Rapid inactivation of infectious pathogens by chlorhexidine-coated gloves

OBJECTIVE

Gloves containing chlorhexidine gluconate in an instant-release matrix on their inner surface (CHG gloves) were tested to determine their ability to rapidly inactivate infectious pathogens that may permeate or leak through the latex surface.

DESIGN

CHG gloves were exposed for 1 to 10 minutes to blood or media containing infectious pathogens (e.g., bacteria, fungi, parasites, and viruses) as well as to lymphocytes and macrophages that are known to be the primary carriers of human immunodeficiency virus (HIV). Inactivation of pathogens was determined either by in vitro assay or in vivo infectivity. Stressed control and CHG glove fingers were submerged in a viral pool (retrovirus or bacteriophage) and after a set time, the glove interiors were checked for presence of permeated virions.

RESULTS

CHG gloves rapidly inactivate all the pathogens tested including retrovirus and hepatitis B virus (90% to 100%). In the stressed glove fingers, live virus was detected in 26% of the control group but not in any of the CHG group.

CONCLUSIONS

The use of CHG gloves may reduce the risk of exposure to infectious fluid-borne pathogens should the integrity of the latex barrier be compromised by overt failure or by permeation of viruses. Rapid destruction of lymphocytes and macrophages may facilitate inactivation of HIV associated with these cells. Tests have shown that CHG coating does not alter physical properties of the glove, and, furthermore, CHG gloves do not show potential for dermal irritation or sensitization.

Partial purification and characterization of the reverse transcriptase of the simian immunodeficiency virus TYO-7 isolated from an African green monkey

The reverse transcriptase (RT) was partially purified by a newly developed procedure from the simian immunodeficiency virus TYO-7 isolated from an African green monkey (SIVagmTYO-7). The method comprised lysis of the virus with nonionic detergent followed by two centrifugations in isopycnic sucrose density gradients and one velocity sedimentation in a glycerol gradient. The enzyme exhibited a purity of 70-80% and showed an exceptional high specific activity of 135 nmol incorporation of dTMP per milligram of protein in 1 h with poly(rA).oligo(dT) as template-primer (TP). The molecular weight of the native enzyme was estimated by velocity sedimentation analysis as 120K-130K. Investigation of the RT by SDS-polyacrylamide gel electrophoresis (SDS-PAGE) showed that the active enzyme is a heterodimer composed of a 64- and a 50-kDa subunit. The two subunits were identified to be RT specific by Western blot analysis. In activity gels, both subunits exhibited enzymatic activity, whereby the 64-kDa subunit showed the predominant activity. The RT preferred the TP poly(rA).oligo(dT) over poly(rC).oligo(dG). With poly(rCm).oligo(dG), only marginal activity was detected, and no activity was measured with poly(dA).oligo(dT). The TP specificity was influenced by the reaction temperature. The highest activity was measured around the melting temperature of the TP used. Furthermore, the enzyme activity was more thermolabile when measured with poly(rA).oligo(dT) than with poly(rC).oligo(dG). To compare the specificity of RT inhibitors, their inhibition efficiency (IE) was defined as the ratio of the 50% inhibiting concentration (ID50) obtained with the RT in viral lysates to the ID50 of purified RT.

The pathophysiology of murine retrovirus-induced leukemias

Murine leukemia viruses (MuLVs) are retroviruses which induce a broad spectrum of hematopoietic malignancies. In contrast to the acutely transforming retroviruses, MuLVs do not contain transduced cellular genes, or oncogenes. Nonetheless, MuLVs can cause leukemias quickly (4 to 6 weeks) and efficiently (up to 100% incidence) in susceptible strains of mice. The molecular basis of MuLV-induced leukemia is not clear. However, the contribution of individual viral genes to leukemogenesis can be assayed by creating novel viruses in vitro using recombinant DNA techniques. These genetically engineered viruses are tested in vivo for their ability to cause leukemia. Leukemogenic MuLVs possess genetic sequences which are not found in nonleukemogenic viruses. These sequences control the histologic type, incidence, and latency of disease induced by individual MuL Vs.

Observations on the suramin-mediated inhibition of cellular and viral DNA polymerases

We have examined the sensitivity of various cellular and viral DNA polymerases to Suramin, an antitrypanosomal drug, which has been reported to exhibit antireverse transcriptase activity. We find that Suramin is a nonspecific inhibitor of all the viral and cellular DNA polymerases, including terminal deoxynucleotidyl transferase, and that the inhibition is most readily reversed by the addition of serum albumin. The drug appears to bind to all the enzyme proteins with no apparent selectivity. Binding of Suramin to enzyme has been found to result in the loss of both substrate and templateprimer binding abilities of various enzymes, confirming the nonspecific nature of protein-Suramin interaction.

Mechanism of o-phenanthroline mediated inhibition of E. coli DNA polymerase I : formation of template-primer-metal-phenanthroline complexes with resultant loss of catalytic activity

Inhibition of E. coli DNA polymerase I activity by 1,10 phenanthroline in the absence of reducing agents requires a high concentration of inhibitor (1-10 mM) depending upon the template primer used to direct the synthesis. We find that o-phenanthroline, unlike its non-chelating analogue, forms a divalent cation mediated complex with template-primers. Enzyme bound to such complexes is unable to catalyse either polymerization or nuclease functions.

Effects of exogenous polyamine and trypanocides on the DNA polymerase activities from Trypanosoma brucei brucei, mouse thymus and murine leukemia virus

The effects of exogenously added spermine on activated (gapped) DNA-directed and poly(dC) . (dG)12-18-directed DNA synthesis were tested on the chromatographically separated DNA polymerase activities of Trypanosoma brucei brucei. Activated DNA-directed DNA synthesis by the Peak I (eluting from DNA-agarose at 0.15 M KCl) and Peak II (eluting at 0.3 M KCl) polymerase was consistently inhibited or stimulated, respectively, by exogenous spermine. Kinetic analysis revealed that inhibition of the Peak I enzyme with respect to template DNA occurred by a mixed mechanism, while a major factor in the stimulation of the Peak II enzyme by spermine appeared to be the polyamine-mediated reversal of "substrate inhibition' by DNA at concentrations above 10 micrograms/ml. The apparent Km values of Peak I and Peak II DNA polymerase for activated DNA were determined to be 5 and 0.5 microgram/ml, respectively. In contrast to the results observed with activated DNA, activation of Peak II-enzyme-catalyzed poly(dC)-directed DNA synthesis was similar at all template-primer concentrations. Peak I enzyme-catalyzed poly(dG) synthesis was either inhibited or slightly stimulated by spermine, depending upon the presence or absence of heteropolymeric DNA, respectively. Dose-dependent inhibition of DNA-directed DNA synthesis catalyzed by T. b. brucei DNA polymerases, murine thymus DNA polymerase alpha, and Rauscher murine leukemia virus reverse transcriptase by trypanocides was examined to determine a possible mechanism of selective toxicity by such agents. The drugs Antrycide (quinapyramine), pentamidine, imidocarb, Berenil (diminazene aceturate), WR-199-385-[2,5-bis(4-guanylphenyl)furan . 2HCl] and isometamidium inhibited DNA polymerases of the eucaryotic cells at approximately the same degree, and at similar concentrations. The presence of spermine in reaction mixtures did not spare any drug inhibition. Stimulation of reverse transcriptase activity was observed in the presence of Antrycide and imidocarb, however, this could be negated by stimulatory amounts of spermine present in the reaction mixture. The results, obtained using an activated DNA-directed assay system, suggest that trypanosomal DNA polymerases are not the selective target of trypanocidal drugs currently available.

Divalent cation-dependent pyridoxal 5'-phosphate inhibition of Rauscher leukemia virus DNA polymerase: characterization and mechanism of action

We have shown that pyridoxal 5'-phosphate is an effective inhibitor of Rauscher leukemia virus DNA polymerase (Biochemistry 15 (1976) 3620). Detailed studies of this inhibition revealed that, in addition to the phosphate and aldehyde groups of pyridoxal phosphate, the presence of a divalent cation is essential for the inhibitory action. The synthesis directed by template primers containing GC base-pairs exhibited more resistance to pyridoxal phosphate inhibition than did that directed by AT base-paired templates. Maximal inhibitory activity of pyridoxal phosphate, however, is noted in the presence of Mn2+, irrespective of which template-primer is used to direct the DNA synthesis. The action of pyridoxal phosphate on the substrate binding site may be deduced from the observations that: (a) only the substrate triphosphate is able to reverse the pyridoxal phosphate-mediated inhibition; (b) the inhibition kinetics exhibit a classical competitive pattern with the substrate; (c) analogous to substrate deoxynucleoside triphosphates the inhibitor is also accepted only in the form of its divalent metal ion complex; and (d) substrate site-specific labeling of RLV DNA polymerase has been shown to occur by linking covalently the pyridoxal phosphate bound to a lysine residue at the substrate binding site.

Isolation and characterisation of the L cell virion DNA polymerase

The DNA polymerase of the L-cell virion (LCV) was partially purified by chromatography on DEAE cellulose. This enzyme transcribed poly(A) . oligo (dT), poly(C) . oligo(dG), and poly(Cm) . oligo(dG), had a molecular weight of 77,000 daltons and reacted like other murine viral RNA directed DNA polymerases to anti reverse transcriptase specific IgG preparations indicating that it was probably a typical murine viral reverse transcriptase. In addition, like other partially purified mammalian viral reverse transcriptases the LCV DNA polymerase exhibited template independent primer stimulated DNA synthesis. The significance of these results to the unusual endogenous activity of the LCV is discussed.

Isolation and partial characterization of the reverse transcriptases of Rauscher murine leukemia virus, simian sarcoma virus and RD-114 virus

Reverse transcriptases were purified from Rauscher murine leukemia virus, Simian sarcoma virus and RD-114 virus by affinity chromatography using poly(rC)-Sepharose. Molecular weight determinations of the viral enzymes gave values of 80,000 for all three enzyme preparations. Two-dimensional tryptic peptide maps of the purified enzymes showed only a few spots in similar positions.

A micromethod for determination of terminal deoxynucleotidyl transferase (TdT) in the diagnostic evaluation of acute leukemias

A micromethod for the determination of TdT in peripheral leukocytes and bone marrow cells has been developed that allows unequivocal identification and quantitation of TdT in less than 1 X 10(6) leukocytes from ALL patients, i.e., in 1 ml of peripheral blood and/or 0.5 ml of bone marrow obtained during routine clinical sampling. The method involves disruption of cell pellet with high salt and detergent followed by centrifugation of extracts at 12,000 X g and partial purification on phosphocellulose matrix by a batch elution technique using a standard laboratory microcentrifuge. Using this microassay, TdT activities have been determined in 500 samples of peripheral blood and bone marrow of 240 adult patients with acute leukemias (86 ALL, 108 ANLL, 44 blastic CML, two acute leukemias following P. vera). From an analysis of our data based on TdT activity, cell surface markers and growth patterns in soft agar and observations published in the literature, it can be concluded that the frequencies of TdT + phenotypes in the various clinical-morphological diagnostic groups are approximately 95% in ALL, 10% in ANLL, 50% in AUL, and 35% in blastic CML. Since the presence of high TdT activity is clearly associated with clinical response to specific forms of chemotherapy in blastic CML and most probably, also in ANLL, the determination of TdT should be considered in all cases of acute leukemias to objectively define prognostically important subgroups which can not be diagnosed by conventional means.

Template-specific requirements for DNA synthesis by the Mason-Pfizer monkey virus DNA polymerase: unique aspects

The biochemical properties of DNA polymerase purified from Mason-Pfizer monkey virus were studied, with respect to synthetic and natural template-primer utilization. Thes studies revealed the following new information about the Mason-Pfizer monkey virus enzyme: (a) Mason-Pfizer monkey virus polymerase was found to prefer template: primer molar nucleotide ratios of 2.5-5: 1 for optimal rates of synthesis with poly(C) .(dG)12-18 as template-primer. (b) Poly(A)-directed synthesis was stimulated by the addition of low concentrations of inorganic phosphate to the reaction mixture. (c) Poly(2' -O-methyl-cytidylate), poly(rCm), was the only template studied for which Mn2+ proved the preferred divalent cation. Combinations of divalent cations stimulated rather than inhibited poly(rCm)-directed poly(dG) synthesis by the Mason-Pfizer monkey virus enzyme. (d) Heteropolymeric regions of rabbit globin mRNA and avian myeloblastosis virus 70 S RNA could be copied by the Mason-Pfizer monkey virus polymerase with oligo(dT), oligo(U) or in the case of avian myeloblastosis virus RNA, endogenous primers. In all such studies, Mg2+ was the preferred divalent cation and a distinct preference for the DNA primer in the reverse transcription of natural RNAs was observed. These new findings necessitated comparative studies with the DNA polymerases from Rauscher murine leukemia virus and murine mammary tumor virus, as representative type C and type B retroviruses. Although the Mason-Pfizer monkey virus enzyme was found to share some properties in common with both type C and type B mammalian viral enzymes, certain of the above properties rendered it unique among the polymerases examined.

A conformational basis for the antiviral inactivity of tetrazole ribonucleosides

The antiviral activity of ribavirin has been associated with its inhibition of the enzyme, IMP dehydrogenase. The ability of ribavirin to inhibit this enzyme has previously been shown to be related to its stability in the high anti glycosidic conformation. The antiviral effectiveness of several analogs of ribavirin have been investigated recently. The evidence indicates their antiviral effectiveness is related to their stability in the high anti conformation. Recently the disposition of purine analogs that pass through the inosine monophosphate branch point has been investigated. The results of these studies are consistent with the concept that the conversion of IMP to XMP requires the high anti conformation and that the conversion of IMP to adenylosuccinate requires some other conformation, possibly the anti conformation.

beta-Lapachone, an inhibitor of oncornavirus reverse transcriptase and eukaryotic DNA polymerase-alpha. Inhibitory effect, thiol dependence and specificity

beta-Lapachone is a naturally occuring compound that can be isolated from a number of tropical trees. It is shown to be a potent inhibitor of reverse transcriptase activity from both avian myeloblastosis virus and Rauscher murine leukaemia virus. In addition, it affects eukaryotic DNA-dependent DNA polymerase-alpha activity: 50% inhibition is reached in 60-min incubation time by about 8 micron beta-lapachone. Enzyme activity is inhibited irrespective of the purity of the enzyme used or of the amount or type of template/primer or substrate present. The inhibitory effect of the drug is only observed in the presence of dithiothreitol. The primary site of action of beta-lapachone appears to be the enzyme protein, as is also borne out by the specificity of its action. Eukaryotic DNA-dependent DNA polymerase-beta, prokaryotic DNA-dependent DNA polymerase I, several other nucleic acid polymerases and some completely unrelated enzymes are not affected. Reverse transcriptase and DNA-dependent DNA polymerase-alpha may be in someway related in possessing similarly exposed '--SH structures' in their active sites. beta-lapachone thus affords a novel means of studying such interrelationships and of further characterizing enzymes.