The effect of the 3',5' thiophosphoryl linkage on the exonuclease activities of T4 polymerase and the Klenow fragment

An exonuclease-resistant chain-terminating nucleotide analogue targeting the SARS-CoV-2 replicase complex

Nucleotide analogues (NA) are currently employed for treatment of several viral diseases, including COVID-19. NA prodrugs are intracellularly activated to the 5'-triphosphate form. They are incorporated into the viral RNA by the viral polymerase (SARS-CoV-2 nsp12), terminating or corrupting RNA synthesis. For Coronaviruses, natural resistance to NAs is provided by a viral 3'-to-5' exonuclease heterodimer nsp14/nsp10, which can remove terminal analogues. Here, we show that the replacement of the α-phosphate of Bemnifosbuvir 5'-triphosphate form (AT-9010) by an α-thiophosphate renders it resistant to excision. The resulting α-thiotriphosphate, AT-9052, exists as two epimers (RP/SP). Through co-crystallization and activity assays, we show that the Sp isomer is preferentially used as a substrate by nucleotide diphosphate kinase (NDPK), and by SARS-CoV-2 nsp12, where its incorporation causes immediate chain-termination. The same -Sp isomer, once incorporated by nsp12, is also totally resistant to the excision by nsp10/nsp14 complex. However, unlike AT-9010, AT-9052-RP/SP no longer inhibits the N-terminal nucleotidylation domain of nsp12. We conclude that AT-9052-Sp exhibits a unique mechanism of action against SARS-CoV-2. Moreover, the thio modification provides a general approach to rescue existing NAs whose activity is hampered by coronavirus proofreading capacity.

E. coli DNA Polymerase I and the Klenow Fragment

Escherichia coli DNA Pol I can carry out three enzymatic reactions: It possesses 5' → 3' DNA polymerase activity and 3' → 5' and 5' → 3' exonuclease activity. Pol I can be cleaved by mild treatment with subtilisin into two fragments; the larger fragment is known as the Klenow fragment. The Klenow fragment retains the polymerizing activity and the 3' → 5' exonuclease of the holo-enzyme but lacks its powerful 5' → 3' exonuclease activity. These enzymes and their applications in molecular cloning are introduced here.

A single mutation in human mitochondrial DNA polymerase Pol gammaA affects both polymerization and proofreading activities of only the holoenzyme

Common causes of human mitochondrial diseases are mutations affecting DNA polymerase (Pol) gamma, the sole polymerase responsible for DNA synthesis in mitochondria. Although the polymerase and exonuclease active sites are located on the catalytic subunit Pol gammaA, in holoenzyme both activities are regulated by the accessory subunit Pol gammaB. Several patients with severe neurological and muscular disorders were reported to carry the Pol gammaA substitutions R232G or R232H, which lie outside of either active site. We report that Arg(232) substitutions have no effect on independent Pol gammaA activities but show major defects in the Pol gammaA-Pol gammaB holoenzyme, including decreased polymerase and increased exonuclease activities, the latter with decreased selectivity for mismatches. We show that Pol gammaB facilitates distinguishing mismatched from base-paired primer termini and that Pol gammaA Arg(232) is essential for mediating this regulatory function of the accessory subunit. This study provides a molecular basis for the disease symptoms exhibited by patients carrying those substitutions.

Twenty years hunting for sulfur in DNA

Here we tell a 20-year long story. It began with an easily overlooked DNA degradation (Dnd) phenomenon during electrophoresis and eventually led to the discovery of an unprecedented DNA sulfur modification governed by five dnd genes. This unusual DNA modification, called phosphorothioation, is the first physiological modification identified on the DNA backbone, in which the nonbridging oxygen is replaced by sulfur in a sequence selective and stereo-specific manner. Homologous dnd gene clusters have been identified in diverse and distantly related bacteria and thus have drawn immediate attention of the entire microbial scientific community. Here, we summarize the progress in chemical, genetic, enzymatic, bioinformatical and analytical aspects of this novel postreplicative DNA modification. We also discuss perspectives on the physiological functions of the DNA phosphorothioate modification in bacteria and their implications.

Minimizing loss of sequence information in SAGE ditags by modulating the temperature dependent 3' --> 5' exonuclease activity of DNA polymerases on 3'-terminal isoheptyl amino groups

Numerous steps are required to prepare a sequencing library for serial analysis of gene expression (or SAGE) from an original mRNA sample. The presence of inefficiencies, however, can lead to a cumulative loss of sample during processing which can yield a library of short sequence tags (SSTs) that represents only a minute fraction of the original starting sample, potentially compromising the quality of the analysis and necessitating relatively large amounts of starting material. We show here that commonly observed higher molecular weight (HMW) amplification products observed following the PCR amplification of ditags are a direct result of the presence of HMW ligation products created during ditag formation. Using model tags, we demonstrate that the formation of these HMW ligation products becomes permissible following the release of the 3'-terminal isoheptyl amine (3'-IHA) from the SST during the fill-in reaction with the Klenow fragment (KF) of DNA polymerase (DNAP) I and is mediated by its 3' --> 5' exonuclease activity. We further show that the incorporation of SSTs into HMW ligation products can lead to a loss of sequence information from SAGE analysis, potentially skewing sequencing results away from the true distribution in the original sample. By modifying fill-in conditions through the use of Vent DNAP at 12 degrees C and by including terminal phosphorothioate linkages within the SAGE adaptors to specifically inhibit exonucleolytic removal of the 3'-terminal amine, we are able to maximize the yield of ditags and bypass the need for gel purification via PAGE following PCR. The modifications described here, combined with the modifications described previously by our group for adaptor ligation, ensure that the full sequence information content in SSTs derived from the transcriptome is preserved in the pool of amplified ditags prior to the creation of a SAGE library.

Single base extension (SBE) with proofreading polymerases and phosphorothioate primers: improved fidelity in single-substrate assays

Model single base extension (SBE) genotyping reactions with individual deoxy-, dideoxy- and acyclonucleoside triphosphates are monitored by MALDI-TOF mass spectrometry. Three non-proofreading DNA polymerases display remarkably high misincorporation (up to 64% of correct incorporation) when extending primers with single substrates at saturating concentrations. Introduction of one phosphorothioate (PS) linkage into the primer 3' terminus reduces misincorporation by these enzymes an average 1.4-fold (range 0- to 3.5-fold) versus correct incorporation. Combined use of 3'-PS primers with strongly proofreading DNA polymerases yields order of magnitude improvements in SBE fidelity over those produced by the equivalent non-proofreading enzymes. Errors are reduced to below MALDI-TOF detectable levels in almost all cases. The Sp diastereomer of the 3'-PS primer, which can be prepared in situ by incubation with proofreading polymerase, is stable to 3'-exonuclease activity over periods longer than 16 h. Products of correct extension by T7 DNAP are retained over 30-60 min during idling turnover at a dNTP concentration of 2.5 micro M, indicating that the assay can be applied over a broad range of substrate concentrations. These results suggest that the use of PS primers and proofreading polymerases will offer a simple and cost-effective means to improve fidelity in a range of single-substrate SBE assay formats.

Modified oligonucleotides: synthesis and strategy for users

Synthetic oligonucleotide analogs have greatly aided our understanding of several biochemical processes. Efficient solid-phase and enzyme-assisted synthetic methods and the availability of modified base analogs have added to the utility of such oligonucleotides. In this review, we discuss the applications of synthetic oligonucleotides that contain backbone, base, and sugar modifications to investigate the mechanism and stereochemical aspects of biochemical reactions. We also discuss interference mapping of nucleic acid-protein interactions; spectroscopic analysis of biochemical reactions and nucleic acid structures; and nucleic acid cross-linking studies. The automation of oligonucleotide synthesis, the development of versatile phosphoramidite reagents, and efficient scale-up have expanded the application of modified oligonucleotides to diverse areas of fundamental and applied biological research. Numerous reports have covered oligonucleotides for which modifications have been made of the phosphodiester backbone, of the purine and pyrimidine heterocyclic bases, and of the sugar moiety; these modifications serve as structural and mechanistic probes. In this chapter, we review the range, scope, and practical utility of such chemically modified oligonucleotides. Because of space limitations, we discuss only those oligonucleotides that contain phosphate and phosphate analogs as internucleotidic linkages.

Structural principles for the inhibition of the 3'-5' exonuclease activity of Escherichia coli DNA polymerase I by phosphorothioates

A two-metal-ion catalytic mechanism has previously been proposed for several phosphoryl-transfer enzymes. In order to extend the structural basis of this mechanism, crystal structures of three single-stranded DNA substrates bound to the 3'-5' exonucleolytic active site of the large fragment of DNA polymerase I from Escherichia coli have been elucidated. The first is a 2.1 A resolution structure of a Michaelis complex between the large fragment (or Klenow fragment, KF) and a single-stranded DNA substrate, stabilized by low pH and flash-freezing. The positions and identities of the catalytic metal ions, a Zn2+ at site A and a Mg2+ at site B, have been clearly established. The structural and kinetic consequences of sulfur substitutions in the scissile phosphate have been explored. A complex with the Rp isomer of phosphorothioate DNA, refined at 2.2 A resolution, shows Zn2+ bound to both metal sites and a mispositioning of the substrate and attacking nucleophile. The complex with the Sp phosphorothioate at 2. 3 A resolution reveals that metal ions do not bind in the active site, having been displaced by a bulky sulfur atom. Steady-state kinetic experiments show that catalyzed hydrolysis of the Rp isomer was reduced only about 15-fold, while no enzyme activity could be detected with the Sp phosphorothioate, consistent with the structural observations. Furthermore, Mn2+ could not rescue the activity of the exonuclease on the Sp phosphorothioate. Taken together, these studies confirm and extend the proposed two-metal-ion exonuclease mechanism and provide a structural context to explain the effects of sulfur substitutions on this and other phosphoryl-transfer enzymes. These experiments also suggest that the possibility of metal-ion exclusion be taken into account when interpreting the results of Mn2+ rescue experiments.

A method for sequence-specific deletion mutagenesis

We describe a novel procedure for the construction of deletion mutants. Existing exonuclease-based protocols are efficient at producing randomly positioned deletions over large regions of DNA, but are of limited use in targetted mutagenesis due to their inherent sequence-specificity. We have taken advantage of the Exonuclease III-resistant nature of alpha-thio-dNTPs, incorporated into the target DNA template by a primer extension reaction, to generate base-specific alpha-thio-dNTP terminated products. Following removal of the 5' overhanging strands, the products can be cloned to generate a nested set of deletions with single base-pair increments. We demonstrate the utility of this technique by isolating multiple deletions over a 40bp region of the human beta-interferon promoter.

Phosphorothioates in molecular biology

The observation that phosphorothioate analogues of the nucleoside triphosphates are substrates for DNA- and RNA-polymerases has proven a boon for the molecular biologist. As these phosphorothioate-containing polymers are stable to degradation by nucleases and the sulfur atom confers many favourable chemical properties, several applications in molecular biology have been developed, including new methods for site-directed mutagenesis and DNA sequencing.

Inhibition of deoxyribonucleases by phosphorothioate groups in oligodeoxyribonucleotides

The Rp- and Sp-diastereomers of the phosphorothioate-containing oligonucleotide d[ApAp(S)ApA] have been synthesized. They and the tetramer d[ApApApA] were tested as substrates for staphylococcal nuclease, DNase II and spleen phosphodiesterase. For digestions with DNase I these oligonucleotides were converted to the 5'-phosphorylated derivates. The reactions with the nucleases were analysed by HPLC. The phosphorothioate groups of both diastereomers were resistant to the action of staphylococcal nuclease, DNase I and DNase II. While the phosphorothioate group of the Rp-diastereomer was resistant to the action of spleen phosphodiesterase, the Sp-diastereomer was hydrolysed at an estimated rate 1/100 the rate of cleavage of the unmodified tetramer. The presence of the phosphorothioate group in the center of the molecule affected the rate of hydrolysis of neighbouring phosphate groups for some enzymes. In particular, very slow release of 3'-dAMP from the Rp-diastereomer occurred on incubation with staphylococcal nuclease but the Sp-diastereomer was completely resistant. DNase II produced 3'-dAMP quite rapidly from both diastereomers of d[ApAp(S)ApA] and DNase I released 5'-dAMP from both diastereomers of d[pApAp(S)ApA] only slowly.

C4-methyldeoxythymidine replacing deoxythymidine in poly[d(A-T)] renders the polymer resistant to the 3'----5' exonuclease activity of the Klenow and T4 DNA polymerases

We previously reported that O4-alkyl dTTPs could replace, for short times, dTTP in polymer synthesis [Singer et al., PNAS 83, 26-32, 1986]. The reasons for such early termination of synthesis could be either proofreading or the eventual formation of weakly paired primer termini. Utilizing the known 3'----5' exonucleolytic activity of polymerases, in the absence of dNTPs, enabled us to conclude that, in contrast to the digestibility of poly[d(A-T)] which yielded the expected 3'-mononucleotides, the polymerizing enzymes did not digest O4-methyl dT or its neighbors. The presence of the resistant alpha-phosphorothionate linkage did not prevent measurable digestion of poly[d(A-T)] by the Klenow fragment. This, together with evidence that polymerization of O4-methyl dTTP is favored at low temperatures, supports the model proposed by Ollis et al. [Nature 313, 762-766, 1985] showing independent domains for the two activities in the Klenow fragment.

A new method of DNA sequencing using deoxynucleoside alpha-thiotriphosphates

A new procedure for determining DNA nucleotide sequences is reported. In the first step of the method, four DNAs, each separately substituted with a different deoxynucleoside phosphorothioate in place of the corresponding monophosphate, are prepared by template-directed polymerization catalyzed by DNA polymerase. In the second step, these DNAs are subjected to stringent exonuclease III treatment, which produces only fragments terminating with a phosphorothioate internucleotide linkage. These can then be separated by standard gel electrophoresis techniques and the sequence can be read directly as in presently used sequencing methods.

Mechanism of the idling-turnover reaction of the large (Klenow) fragment of Escherichia coli DNA polymerase I

The mechanism of the idling-turnover reaction catalyzed by the large (Klenow) fragment of Escherichia coli DNA polymerase I has been investigated. The reaction cycle involved is one of excision/incorporation, in which the 3' deoxynucleotide residue of the primer DNA strand is partitioned into its 5'-mono- and 5'-triphosphate derivatives, respectively. Mechanistic studies suggest the 5'-monophosphate product is formed in the first step by simple 3'----5' exonucleolytic cleavage. Rapid polymerization follows with the concomitant release of inorganic pyrophosphate. In the second step, the 5'-triphosphate product is generated by a pyrophosphorolysis reaction, which, despite the low concentration of pyrophosphate that has accumulated, occurs at a rate that is comparable with that of the parallel 3'----5' hydrolysis reaction.

The use of phosphorothioate-modified DNA in restriction enzyme reactions to prepare nicked DNA

The RF IV form of M13 DNA was synthesized enzymatically in vitro, using the viral (+)strand as template, to contain phosphorothioate-modified internucleotidic linkages of the Rp configuration on the 5' side of every base of a particular type in the newly-synthesized (-)strand. Twenty nine restriction enzymes were then tested for their reactions with the appropriate modified DNA types having a phosphorothioate linkage placed exactly at the cleavage site(s) of these enzymes in the (-)strand. Eleven of the seventeen restriction enzymes tested that had recognition sequences of five bases or more could be used to convert the phosphorothioate DNA entirely into the nicked form, either by simply allowing the reaction to go to completion with excess enzyme (Ava I, Ava II, Ban II, Hind II, Nci I, Pst I or Pvu I) or by stopping the reaction at the appropriate time before the nicked DNA is linearized (Bam HI, Bgl I, Eco RI or Hind III). Only modification of the exact cleavage site in the (-)strand could block linearization by the first class of enzymes. The results presented imply that the restriction enzyme-directed nicking of phosphorothioate M13 DNA occurs exclusively in the (+)strand.

Stereochemical course of the 3'----5'-exonuclease activity of DNA polymerase I

(Sp)-2'-Deoxyadenosine 5'-O-[1-17O,1-18O,1,2-18O]triphosphate has been synthesized by desulfurization of (Sp)-2'-deoxyadenosine 5'-O-(1-thio[1,1-18O2]diphosphate) with N-bromosuccinimide in [17O]water, followed by phosphorylation with phosphoenolpyruvate-pyruvate kinase. A careful characterization of the product using high-resolution 31P NMR revealed that the desulfurization reaction proceeded with approximately 88% direct in-line attack at the alpha-phosphorus and 12% participation by the beta-phosphate to form a cyclic alpha,beta-diphosphate. The latter intermediate underwent hydrolysis by a predominant nucleophilic attack on the beta-phosphate. This complexity of the desulfurization reaction, however, does not affect the stereochemical integrity of the product but rather causes a minor dilution with nonchiral species. The usefulness of the (Sp)-2'-deoxyadenosine 5'-O-[1-17O,1-18O,1,2-18O]triphosphate in determining the stereochemical course of deoxyribonucleotidyl-transfer enzymes is demonstrated by using it to delineate the stereochemical course of the 3'----5'-exonuclease activity of DNA polymerase I. Upon incubation of this oxygen-chiral substrate with Klenow fragment of DNA polymerase I in the presence of poly[d(A-T)] and Mg2+, a quantitative conversion into 2'-deoxyadenosine 5'-O-[16O,17O,18O]monophosphate was observed. The stereochemistry of this product was determined to be Rp. Since the overall template-primer-dependent conversion of a deoxynucleoside triphosphate into the deoxynucleoside monophosphate involves incorporation into the polymer followed by excision by the 3'----5'-exonuclease activity and since the stereochemical course of the incorporation reaction is known to be inversion, it can be concluded that the stereochemical course of the 3'----5'-exonuclease is also inversion.