DNA contacts stimulate catalysis by a poxvirus topoisomerase

Synthesis of 5'-Thio-3'-O-ribonucleoside Phosphoramidites

The chemical synthesis of phosphoramidite derivatives of all four 5'-deoxy-5'-thioribonucleosides is described. These phosphoramidites contained trityl (A, G, C, and U), dimethoxytrityl (A and G), or tert-butyldisulfanyl (G) as the 5'-S-protecting group. The application of several of these phosphoramidites for solid-phase synthesis of oligoribonucleotides containing a 2'-O-photocaged 5'-S-phosphorothiolate linkage or 5'-thiol-labeled RNAs is also further investigated.

Insights from the structure of a smallpox virus topoisomerase-DNA transition state mimic

Poxviruses encode their own type IB topoisomerases (TopIBs), which release superhelical tension generated by replication and transcription of their genomes. To investigate the reaction catalyzed by viral TopIBs, we have determined the structure of a variola virus topoisomerase-DNA complex trapped as a vanadate transition state mimic. The structure reveals how the viral TopIB enzymes are likely to position the DNA duplex for ligation following relaxation of supercoils and identifies the sources of friction observed in single-molecule experiments that argue against free rotation. The structure also identifies a conformational change in the leaving group sugar that must occur prior to cleavage and reveals a mechanism for promoting ligation following relaxation of supercoils that involves an Asp-minor groove interaction. Overall, the new structural data support a common catalytic mechanism for the TopIB superfamily but indicate distinct methods for controlling duplex rotation in the small versus large enzyme subfamilies.

Variola virus topoisomerase: DNA cleavage specificity and distribution of sites in Poxvirus genomes

Topoisomerase enzymes regulate superhelical tension in DNA resulting from transcription, replication, repair, and other molecular transactions. Poxviruses encode an unusual type IB topoisomerase that acts only at conserved DNA sequences containing the core pentanucleotide 5'-(T/C)CCTT-3'. In X-ray structures of the variola virus topoisomerase bound to DNA, protein-DNA contacts were found to extend beyond the core pentanucleotide, indicating that the full recognition site has not yet been fully defined in functional studies. Here we report quantitation of DNA cleavage rates for an optimized 13 bp site and for all possible single base substitutions (40 total sites), with the goals of understanding the molecular mechanism of recognition and mapping topoisomerase sites in poxvirus genome sequences. The data allow a precise definition of enzyme-DNA interactions and the energetic contributions of each. We then used the resulting "action matrix" to show that favorable topoisomerase sites are distributed all along the length of poxvirus DNA sequences, consistent with a requirement for local release of superhelical tension in constrained topological domains. In orthopox genomes, an additional central cluster of sites was also evident. A negative correlation of predicted topoisomerase sites was seen relative to early terminators, but no correlation was seen with early or late promoters. These data define the full variola virus topoisomerase recognition site and provide a new window on topoisomerase function in vivo.

Regulation of catalysis by the smallpox virus topoisomerase

The poxvirus type IB topoisomerases catalyze relaxation of supercoiled DNA by cleaving and rejoining DNA strands via a pathway involving a covalent phosphotyrosine intermediate. Recently we determined structures of the smallpox virus topoisomerase bound to DNA in covalent and non-covalent DNA complexes using x-ray crystallography. Here we analyzed the effects of twenty-two amino acid substitutions on the topoisomerase activity in vitro in assays of DNA relaxation, single cycle cleavage, and equilibrium cleavage-religation. Alanine substitutions at 14 positions impaired topoisomerase function, marking a channel of functionally important contacts along the protein-DNA interface. Unexpectedly, alanine substitutions at two positions (D168A and E124A) accelerated the forward rate of cleavage. These findings and further analysis indicate that Asp(168) is a key regulator of the active site that maintains an optimal balance among the DNA cleavage, religation, and product release steps. Finally, we report that high level expression of the D168A topoisomerase in Escherichia coli, but not other alanine-substituted enzymes, prevented cell growth. These findings help elucidate the amino acid side chains involved in DNA binding and catalysis and provide guidance for designing topoisomerase poisons for use as smallpox antivirals.

Nonpolar nucleobase analogs illuminate requirements for site-specific DNA cleavage by vaccinia topoisomerase

Vaccinia DNA topoisomerase forms a covalent DNA-(3'-phosphotyrosyl)-enzyme intermediate at a specific target site 5'-C(+5)C(+4)C(+3)T(+2)T(+1)p downward arrow N(-1) in duplex DNA. Here we study the effects of nonpolar pyrimidine isosteres difluorotoluene (F) and monofluorotoluene (D) and the nonpolar purine analog indole at individual positions of the scissile and nonscissile strands on the rate of single-turnover DNA transesterification and the cleavage-religation equilibrium. Comparison of the effects of nonpolar base substitution to the effects of abasic lesions reported previously allowed us to surmise the relative contributions of base-stacking and polar edge interactions to the DNA transesterification reactions. For example, the deleterious effects of eliminating the +2T base on the scissile strand were rectified by introducing the nonpolar F isostere, whereas the requirement for the +1T base was not elided by F substitution. We impute a role for +1T in recruiting the catalytic residue Lys-167 to the active site. Topoisomerase is especially sensitive to suppression of DNA cleavage upon elimination of the +4G and +3G bases of the nonscissile strand. Indole provided little or no gain of function relative to abasic lesions. Inosine substitutions for +4G and +3G had no effect on transesterification rate, implying that the guanine exocyclic amine is not a critical determinant of DNA cleavage. Prior studies of 2-aminopurine and 7-deazaguanine effects had shown that the O6 and N7 of guanine were also not critical. These findings suggest that either the topoisomerase makes functionally redundant contacts with polar atoms (likely via Tyr-136, a residue important for precleavage active site assembly) or that it relies on contacts to N1 or N3 of the purine ring. The cleavage-religation equilibrium is strongly skewed toward trapping of the covalent intermediate by elimination of the +1A base of the nonscissile strand; the reaction equilibrium is restored by +1 indole, signifying that base stacking flanking the nick is critical for the religation step. Our findings highlight base isosteres as valuable tools for the analysis of proteins that act on DNA in a site-specific manner.

Structural basis for specificity in the poxvirus topoisomerase

Although smallpox has been eradicated from the human population, it is presently feared as a possible agent of bioterrorism. The smallpox virus codes for its own topoisomerase enzyme that differs from its cellular counterpart by requiring a specific DNA sequence for activation of catalysis. Here we present crystal structures of the smallpox virus topoisomerase enzyme bound both covalently and noncovalently to a specific DNA sequence. These structures reveal the basis for site-specific DNA recognition, and they explain how catalysis is likely activated by formation of a specific enzyme-DNA interface. Unexpectedly, the poxvirus enzyme uses a major groove binding alpha helix that is not present in the human enzyme to recognize part of the core recognition sequence and activate the enzyme for catalysis. The topoisomerase-DNA complex structures also provide a three-dimensional framework that may facilitate the rational design of therapeutic agents to treat poxvirus infections.

Individual nucleotide bases, not base pairs, are critical for triggering site-specific DNA cleavage by vaccinia topoisomerase

Vaccinia DNA topoisomerase forms a covalent DNA-(3'-phosphotyrosyl)-enzyme intermediate at a specific target site 5'-C(+5)C(+4)C(+3)T(+2)T(+1)p downward arrow N(-1) in duplex DNA. Here we study the effects of abasic lesions at individual positions of the scissile and nonscissile strands on the rate of single-turnover DNA transesterification and the cleavage-religation equilibrium. The rate of DNA incision was reduced by factors of 350, 250, 60, and 10 when abasic sites replaced the -1N, +1T, +2T, and +4C bases of the scissile strand, but abasic lesions at +5C and +3C had little or no effect. Abasic lesions in the nonscissile strand in lieu of +4G, +3G, +2A, and +1A reduced the rate of cleavage by factors of 130, 150, 10, and 5, whereas abasic lesions at +5G and -1N had no effect. The striking positional asymmetry of abasic interference on the scissile and nonscissile strands highlights the importance of individual bases, not base pairs, in promoting DNA cleavage. The rate of single-turnover DNA religation by the covalent topoisomerase-DNA complex was insensitive to abasic sites within the CCCTT sequence of the scissile strand, but an abasic lesion at the 5'-OH nucleoside (-1N) of the attacking DNA strand slowed the rate of religation by a factor of 600. Nonscissile strand abasic lesions at +1A and -1N slowed the rate of religation by factors of approximately 140 and 20, respectively, and strongly skewed the cleavage-religation equilibrium toward the covalent complex. Thus, abasic lesions immediately flanking the cleavage site act as topoisomerase poisons.

Benzo[c]phenanthrene adducts and nogalamycin inhibit DNA transesterification by vaccinia topoisomerase

Vaccinia DNA topoisomerase forms a covalent DNA-(3'-phosphotyrosyl)-enzyme intermediate at a specific target site 5'-C(+5)C(+4)C(+3)T(+2)T(+1)p downward arrow N(-1) in duplex DNA. Here we study the effects of position-specific DNA intercalators on the rate and extent of single-turnover DNA transesterification. Chiral C-1 R and S trans-opened 3,4-diol 1,2-epoxide adducts of benzo[c]phenanthrene (BcPh) were introduced at single N2-deoxyguanosine and N6-deoxyadenosine positions within the 3'-G(+5)G(+4)G(+3)A(+2)A(+1)T(-1)A(-2) sequence of the nonscissile DNA strand. Transesterification was unaffected by BcPh intercalation between the +6 and +5 base pairs, slowed 4-fold by intercalation between the +5 and +4 base pairs, and virtually abolished by BcPh intercalation between the +4 and +3 base pairs and the +3 and +2 base pairs. Intercalation between the +2 and +1 base pairs by the +2R BcPh dA adduct abolished transesterification, whereas the overlapping +1S BcPh dA adduct slowed the rate of transesterification by a factor of 2700, with little effect upon the extent of the reaction. Intercalation at the scissile phosphodiester (between the +1 and -1 base pairs) slowed transesterification by a factor of 450. BcPh intercalation between the -1 and -2 base pairs slowed cleavage by two orders of magnitude, but intercalation between the -2 and -3 base pairs had little effect. The anthracycline drug nogalamycin, a non-covalent intercalator with preference for 5'-TG dinucleotides, inhibited the single-turnover DNA cleavage reaction of vaccinia topoisomerase with an IC50 of 0.7 microM. Nogalamycin was most effective when the drug was pre-incubated with DNA and when the cleavage target site was 5'-CCCTT/G instead of 5'-CCCTT/A. These findings demarcate upstream and downstream boundaries of the functional interface of vaccinia topoisomerase with its DNA target site.

Site-specific DNA transesterification by vaccinia topoisomerase: effects of benzo[alpha]pyrene-dA, 8-oxoguanine, 8-oxoadenine and 2-aminopurine modifications

Vaccinia DNA topoisomerase forms a covalent DNA-(3'-phosphotyrosyl)-enzyme intermediate at a specific target site 5'-C+5C+4C+3T+2T+1p downward arrow N-1 in duplex DNA. Here we study the effects of base modifications on the rate and extent of single-turnover DNA transesterification. Chiral trans opened C-10 R and S adducts of benzo[a]pyrene (BP) 7,8-diol 9,10-epoxide were introduced at single N6-deoxyadenosine (dA) positions within the 3'-G+5G+4G+3A+2A+1T-1A-2 sequence of the nonscissile DNA strand. The R and S BPdA adducts intercalate from the major groove on the 5' and 3' sides of the modified base, respectively, and perturb local base stacking. We found that R and S BPdA modifications at +1A reduced the transesterification rate by a factor of 700-1000 without affecting the yield of the covalent topoisomerase-DNA complex. BPdA modifications at +2A reduced the extent of transesterification and elicited rate decrements of 200- and 7000-fold for the S and R diastereomers, respectively. In contrast, BPdA adducts at the -2 position had no effect on the extent of the reaction and relatively little impact on the rate of cleavage. A more subtle probe of major groove contacts entailed substituting each of the purines of the nonscissile strand with its 8-oxo analog. The +3 oxoG modification slowed transesterification 35-fold, whereas other 8-oxo modifications were benign. 8-Oxo substitutions at the -1 position in the scissile strand slowed single-turnover cleavage by a factor of six but had an even greater slowing effect on religation, which resulted in an increase in the cleavage equilibrium constant. 2-Aminopurine at positions +3, +4, or +5 in the nonscissile strand had no effect on transesterification per se but had synergistic effects when combined with 8-oxoA at position -1 in the scissile strand. These findings illuminate the functional interface of vaccinia topoisomerase with the DNA major groove.

Vaccinia topoisomerase mutants illuminate conformational changes during closure of the protein clamp and assembly of a functional active site

We present a mutational analysis of vaccinia topoisomerase that highlights the contributions of five residues in the catalytic domain (Phe-88 and Phe-101 in helix alpha1, Ser-204 in alpha5, and Lys-220 and Asn-228 in alpha6) to the DNA binding and transesterification steps. When augmented by structural information from exemplary type IB topoisomerases and tyrosine recombinases in different functional states, the results suggest how closure of the protein clamp around duplex DNA and assembly of a functional active site might be orchestrated by internal conformational changes in the catalytic domain. Lys-220 is a constituent of the active site, and a positive charge at this position is required for optimal DNA cleavage. Ser-204 and Asn-228 appear not to be directly involved in reaction chemistry at the scissile phosphodiester. We propose that (i) Asn-228 recruits the Tyr-274 nucleophile to the active site by forming a hydrogen bond to the main chain of the tyrosine-containing alpha8 helix and that (ii) contacts between Ser-204 and the DNA backbone upstream of the cleavage site trigger a separate conformational change required for active site assembly. Mutations of Phe-88 and Phe-101 affect DNA binding, most likely at the clamp closure step, which we posit to entail a distortion of helix alpha1.

Rapid microtiter assays for poxvirus topoisomerase, mammalian type IB topoisomerase and HIV-1 integrase: application to inhibitor isolation

We have developed microtiter assays for detecting catalysis by type IB topoisomerases and retroviral integrases. Each assay employs model DNA substrates containing biotin in one strand and digoxigenin in another. In each case action of the enzyme results in the formation of a single DNA strand containing both groups. This allows the reaction product to be quantified by capturing biotinylated product DNA on avidin-coated plates followed by detection using an anti-digoxigenin ELISA. The order of addition of reactants and inhibitors can be varied to distinguish effects of test compounds on different steps in the reaction. These assays were used to screen compound libraries for inhibitors active against mammalian topoisomerase or HIV integrase. We identified (-)-epigallocatechin 3-O:-gallate, as a potent inhibitor of religation by mammalian topoisomerase (IC(50) of 26 nM), potentially explaining the anti-cancer properties previously attributed to this compound. New integrase inhibitors were also identified. A similar strategy may be used to develop microtiter assays for many further DNA modifying enzymes.

Vaccinia topoisomerase and Cre recombinase catalyze direct ligation of activated DNA substrates containing a 3'-para-nitrophenyl phosphate ester

DNA topoisomerases and DNA site-specific recombinases are involved in a diverse set of cellular processes but both function by making transient breaks in DNA. Type IB topoisomerases and tyrosine recombinases cleave DNA by transesterification of an active site tyrosine to generate a DNA-3'-phosphotyrosyl-enzyme adduct and a free 5'-hydroxyl (5'-OH). Strand ligation results when the 5'-OH attacks the covalent complex and displaces the enzyme. We describe the synthesis of 3'-phospho-(para-nitrophenyl) oligonucleotides (3'-pNP DNAs), which mimic the natural 3'-phosphotyrosyl intermediate, and demonstrate that such pre-activated strands are substrates for DNA ligation by vaccinia topoisomerase and Cre recombinase. Ligation occurs by direct attack of a 5'-OH strand on the 3'-pNP DNA (i.e., without a covalent protein-DNA intermediate) and generates free para-nitrophenol as a product. The chromogenic DNA substrate allows ligation to be studied in real-time and in the absence of competing cleavage reactions and can be exploited for high-throughput screening of topoisomerase/recombinase inhibitors.

Melanoplus sanguinipes entomopoxvirus DNA topoisomerase: site-specific DNA transesterification and effects of 5'-bridging phosphorothiolates

Melanoplus sanguinipes entomopoxvirus (MsEPV) encodes a 328 amino acid polypeptide related to the type I topoisomerases of six other genera of vertebrate and insect poxviruses. The gene encoding MsEPV topoisomerase was expressed in bacteria, and the recombinant protein was purified by ion-exchange chromatography and glycerol gradient sedimentation. MsEPV topoisomerase, a monomeric protein, catalyzed the relaxation of supercoiled plasmid DNA at approximately 0.6 supercoils/s. Like other poxvirus topoisomerases, the MsEPV enzyme formed a covalent adduct with duplex DNA at the target sequence CCCTT downward arrow. The kinetic and equilibrium parameters of the DNA transesterification reaction of MsEPV topoisomerase were k(cl) = 0.3 s(-1) and K(cl) = 0.25. The introduction of a 5'-bridging phosphorothiolate at the scissile phosphate increased the cleavage equilibrium constant from 0.25 to >/=30. Similar phosphorothiolate effects were observed with vaccinia topoisomerase. Kinetic analysis of single-turnover cleavage and religation reactions established that the altered equilibrium was the result of a approximately 10(-4) decrement in the rate of topoisomerase-catalyzed attack of 5'-SH DNA on the DNA-(3'-phosphotyrosyl)-enzyme intermediate. 5'-bridging phosphorothiolates at the scissile phosphate and other positions within the CCCTT element had no significant effect on k(cl).

DNA contacts by protein domains of the molluscum contagiosum virus type-1B topoisomerase

All poxviruses studied encode a type 1B topoisomerase that introduces transient nicks into DNA and thereby relaxes DNA supercoils. Here we present a study of the protein domains of the topoisomerase of the poxvirus molluscum contagiosum (MCV), which allows us to specify DNA contacts made by different domains. Partial proteolysis of the enzyme revealed two stable domains separated by a protease-sensitive linker. A fragment encoding the linker and carboxyl-terminal domain (residues 82-323) was overexpressed in Escherichia coli and purified. MCV topoisomerase (MCV-TOP)(82-323) could relax supercoiled plasmids in vitro, albeit with a slower rate than the wild-type enzyme. MCV-TOP(82-323) was sensitive to sequences in the favored 5'-(T/C)CCTT-3' recognition site and also flanking DNA, indicating that some of the sequence-specific contacts are made by residues 82-323. Assays of initial binding and covalent catalysis by MCV-TOP(82-323) identified the contacts flanking the 5'-CCCTT-3' sequence at +10, +9, -2, and -3 to be important. Tests with substrates containing a 5-bridging phosphorothiolate that trap the cleaved complex revealed that correct contacts to the flanking sequences were important in the initial cleavage step. MCV-TOP(82-323) differed from the full-length protein in showing reduced sensitivity to mutations at a position within the 5'-(T/C)CCTT-3' recognition site, consistent with a model in which the amino-terminal domain contacts this region. These findings provide insight into the division of labor within the MCV-TOP enzyme.