Synthesis and Properties of DNA Dumbbells Containing Chemically Active Substituted Pyrophosphate Internucleotide Groups

Abstract

DNA dumbbells with substituted pyrophosphate groups at a definite position of the sugar-phosphate backbone were synthesized by condensation of terminal 5′-phosphomonester- and 3′-methylphosphodiester groups in nicked dumbbells. N-(3-dimethylaminopropyl)-N′-ethylcarbodiimide was used as a condensing agent. An efficient method for producing extended oligonucleotides carrying an O-methyl-substitued 3′-phosphate group was developed. Properties of the modified DNA-dumbbells were investigated. The substituted pyrophosphate group in the DNA dumbbells was efficiently cleaved under the action of N-methylimidazole or ethylendiamine aqueous solutions at pH 8.0.     

Footprinting of Chlorella virus DNA ligase bound at a nick in duplex DNA.

The 298-amino acid ATP-dependent DNA ligase of Chlorella virus PBCV-1 is the smallest eukaryotic DNA ligase known. The enzyme has intrinsic specificity for binding to nicked duplex DNA. To delineate the ligase-DNA interface, we have footprinted the enzyme binding site on DNA and the DNA binding site on ligase. The size of the exonuclease III footprint of ligase bound a single nick in duplex DNA is 19-21 nucleotides. The footprint is asymmetric, extending 8-9 nucleotides on the 3'-OH side of the nick and 11-12 nucleotides on the 5'-phosphate side. The 5'-phosphate moiety is essential for the binding of Chlorella virus ligase to nicked DNA. Here we show that the 3'-OH moiety is not required for nick recognition. The Chlorella virus ligase binds to a nicked ligand containing 2',3'-dideoxy and 5'-phosphate termini, but cannot catalyze adenylation of the 5'-end. Hence, the 3'-OH is important for step 2 chemistry even though it is not itself chemically transformed during DNA-adenylate formation. A 2'-OH cannot substitute for the essential 3'-OH in adenylation at a nick or even in strand closure at a preadenylated nick. The protein side of the ligase-DNA interface was probed by limited proteolysis of ligase with trypsin and chymotrypsin in the presence and absence of nicked DNA. Protease accessible sites are clustered within a short segment from amino acids 210-225 located distal to conserved motif V. The ligase is protected from proteolysis by nicked DNA. Protease cleavage of the native enzyme prior to DNA addition results in loss of DNA binding. These results suggest a bipartite domain structure in which the interdomain segment either comprises part of the DNA binding site or undergoes a conformational change upon DNA binding. The domain structure of Chlorella virus ligase inferred from the solution experiments is consistent with the structure of T7 DNA ligase determined by x-ray crystallography.     

Functional dissection of the DNA interface of the nucleotidyltransferase domain of chlorella virus DNA ligase

Chlorella virus DNA ligase (ChVLig) has pluripotent biological activity and an intrinsic nick-sensing function. ChVLig consists of three structural modules that envelop nicked DNA as a C-shaped protein clamp: a nucleotidyltransferase (NTase) domain and an OB domain (these two are common to all DNA ligases) as well as a distinctive β-hairpin latch module. The NTase domain, which performs the chemical steps of ligation, binds the major groove flanking the nick and the minor groove on the 3'-OH side of the nick. Here we performed a structure-guided mutational analysis of the NTase domain, surveying the effects of 35 mutations in 19 residues on ChVLig activity in vivo and in vitro, including biochemical tests of the composite nick sealing reaction and of the three component steps of the ligation pathway (ligase adenylylation, DNA adenylylation, and phosphodiester synthesis). The results highlight (i) key contacts by Thr-84 and Lys-173 to the template DNA strand phosphates at the outer margins of the DNA ligase footprint; (ii) essential contacts of Ser-41, Arg-42, Met-83, and Phe-75 with the 3'-OH strand at the nick; (iii) Arg-176 phosphate contacts at the nick and with ATP during ligase adenylylation; (iv) the role of Phe-44 in forming the protein clamp around the nicked DNA substrate; and (v) the importance of adenine-binding residue Phe-98 in all three steps of ligation. Kinetic analysis of single-turnover nick sealing by ChVLig-AMP underscored the importance of Phe-75-mediated distortion of the nick 3'-OH nucleoside in the catalysis of DNA 5'-adenylylation (step 2) and phosphodiester synthesis (step 3). Induced fit of the nicked DNA into a distorted conformation when bound within the ligase clamp may account for the nick-sensing capacity of ChVLig.     

DNA template requirements for human mismatch repair in vitro

The human mismatch repair pathway is competent to correct DNA mismatches in a strand-specific manner. At present, only nicks are known to support strand discrimination, although the DNA end within the active site of replication is often proposed to serve this role. We therefore tested the competence of DNA ends or gaps to direct mismatch correction. Eight G.T templates were constructed which contained a nick or gap of 4, 28, or approximately 200 nucleotides situated approximately 330 bp away in either orientation. A competition was established in which the mismatch repair machinery had to compete with gap-filling replication and ligation activities for access to the strand discontinuity. Gaps of 4 or 28 nucleotides were the most effective strand discrimination signals for mismatch repair, whereas double strand breaks did not direct repair to either strand. To define the minimal spatial requirements for access to either the strand signal or mismatch site, the nicked templates were linearized close to either site and assayed. As few as 14 bp beyond the nick supported mismatch excision, although repair synthesis failed using 5'-nicked templates. Finally, asymmetric G.T templates with a remote nick and a nearby DNA end were repaired efficiently.     

Chemical reactions in double-helical nucleic acids. VIII. Assembly of hybrid RNA-DNA-duplexes using water soluble condensing agents

Condensation of oligonucleotides containing ribonucleotide segments (from mononucleotide to full sequence) on DNA-template was studied, with cyanogen bromide and 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide as condensing agents. Efficiency of the chemical ligation of RNA oligomers was much lower than that of DNA analogues. The yield of chemical ligation products was found to depend on the position of RNA segment in the hybrid duplexes and on the position of the phosphate group in the nick. The oligoribonucleotide's length does not affect the yield of condensation products. A nick in 5S RNA loop was repaired by means of the chemical ligation method.     

Specificity and fidelity of strand joining by Chlorella virus DNA ligase.

Chlorella virus PBCV-1 DNA ligase seals nicked duplex DNA substrates consisting of a 5'-phosphate-terminated strand and a 3'-hydroxyl-terminated strand annealed to a bridging template strand, but cannot ligate a nicked duplex composed of two DNAs annealed on an RNA template. Whereas PBCV-1 ligase efficiently joins a 3'-OH RNA to a 5'-phosphate DNA, it is unable to join a 3'-OH DNA to a 5'-phosphate RNA. The ligase discriminates at the substrate binding step between nicked duplexes containing 5'-phosphate DNA versus 5'-phosphate RNA strands. PBCV-1 ligase readily seals a nicked duplex DNA containing a single ribonucleotide substitution at the reactive 5'-phosphate end. These results suggest a requirement for a B-form helical conformation of the polynucleotide on the 5'-phosphate side of the nick. Single base mismatches at the nick exert disparate effects on DNA ligation efficiency. PBCV-1 ligase tolerates mismatches involving the 5'-phosphate nucleotide, with the exception of 5'-A:G and 5'-G:A mispairs, which reduce ligase activity by two orders of magnitude. Inhibitory configurations at the 3'-OH nucleotide include 3'-G:A, 3'-G:T, 3'-T:T, 3'-A:G, 3'-G:G, 3'-A:C and 3'-C:C. Our findings indicate that Chlorella virus DNA ligase has the potential to affect genome integrity by embedding ribonucleotides in viral DNA and by sealing nicked molecules with mispaired ends, thereby generating missense mutations.     

Chemical synthesis of oligodeoxynucleotide dumbbells

The chemical synthesis of DNA dumbbells is investigated by using two sequences, cyclo-d(GCG-T4-CGCCGC-T4-GCG) and cyclo-d(TTCC-T4-GGAATTCC-T4-GGAA). This method readily and inexpensively yields multimicromole quantities of circular DNA, allowing detailed structural and physical studies to be carried out. Linear oligomers of sequence d(GCG-T4-CGCCGC-T4-GCG) having either 3'- or 5'-phosphates were cyclized in 40% and 67% isolated yield, respectively, by using 1-[3-(dimethylamino)propyl]-3-ethylcarbodiimide. Formation of the circular product is confirmed by a 28 degrees C increase in the optical melting temperature, anomalously rapid electrophoretic migration, sequential nuclear Overhauser enhancements between protons of G1 and G20, and observed nuclear coupling between the ligated phosphorus and protons of both G1 and G20. cyclo-d(TTCC-T4-GGAATTCC-T4-GGCC) was synthesized from the corresponding linear 3'-phosphate in 80% yield by the same procedure. Chemical ligation is most effective for 3'-phosphorylated nick sites flanked by two purine bases.     

Site-specific nicking at the avian retrovirus LTR circle junction by the viral pp32 DNA endonuclease.

The avian retrovirus pp32 DNA endonuclease prefers to nick supercoiled DNA containing long terminal repeat (LTR) circle junction sequences at one or the other of two sites, each which mapped two nucleotides back from the circle junction. The sequence at the sites of nicking was (sequence: see text) where increases indicates the positions of the two alternative nicked sites. This site-specific nicking was observed when the circle junction LTR DNA was present in supercoiled form, the divalent metal ion was Mg2+ and the molar ratio of protein to DNA was low. The majority of other LTR DNA sites nicked by pp32 in the presence of Mg2+ were adjacent to or within the dinucleotide CA.     

Substrate recognition and fidelity of strand joining by an archaeal DNA ligase.

We have previously identified a DNA ligase (LigTk) from a hyperthermophilic archaeon, Thermococcus kodakaraensis KOD1. The enzyme is the only characterized ATP-dependent DNA ligase from a hyperthermophile, and allows the analysis of enzymatic DNA ligation reactions at temperatures above the melting point of the substrates. Here we have focused on the interactions of LigTk with various DNA substrates, and its specificities toward metal cations. LigTk could utilize Mg2+, Mn2+, Sr2+ and Ca2+ as a metal cation, but not Co2+, Zn2+, Ni2+, or Cu2+. The enzyme displayed typical Michaelis-Menten steady-state kinetics with an apparent Km of 1.4 microm for nicked DNA. The kcat value of the enzyme was 0.11*s-1. Using various 3' hydroxyl group donors (L-DNA) and 5' phosphate group donors (R-DNA), we could detect ligation products as short as 16 nucleotides, the products of 7 + 9 nucleotide or 8 + 8 nucleotide combinations at 40 degrees C. An elevation in temperature led to a decrease in reaction efficiency when short oligonucleotides were used, suggesting that the formation of a nicked, double-stranded DNA substrate preceded enzyme-substrate recognition. LigTk was not inhibited by the addition of excess duplex DNA, implying that the enzyme did not bind strongly to the double-stranded ligation product after nick-sealing. In terms of reaction fidelity, LigTk was found to ligate various substrates with mismatched base-pairing at the 5' end of the nick, but did not show activity towards the 3' mismatched substrates. LigTk could not seal substrates with a 1-nucleotide or 2-nucleotide gap. Small amounts of ligation products were detected with DNA substrates containing a single nucleotide insertion, relatively more with the 5' insertions. The results revealed the importance of proper base-pairing at the 3' hydroxyl side of the nick for the ligation reaction by LigTk.     

Site-directed modification of DNA duplexes by chemical ligation.

The efficiency of chemical ligation method have been demonstrated by assembling a number of DNA duplexes with modified sugar phosphate backbone. Condensation on a tetradecanucleotide template of hexa(penta)- and undecanucleotides differing only in the terminal nucleoside residue have been performed using water-soluble carbodiimide as a condensing agent. As was shown by comparing the efficiency of chemical ligation of single-strand breaks in those duplexes, the reaction rate rises 70 or 45 times if the 3'-OH group is substituted with an amino or phosphate group (the yield of products with a phosphoramidate or pyrophosphate bond is 96-100% in 6 d). Changes in the conformation of reacting groups caused by mismatched base pairs (A.A, A.C) as well as the hybrid rU.dA pair or an unpaired base make the template-directed condensation less effective. The thermal stability of DNA duplexes was assayed before and after the chemical ligation. Among all of the modified duplexes, only the duplex containing 3'-rU in the nick was found to be a substrate of T4 DNA ligase.     

Chlorella virus DNA ligase: nick recognition and mutational analysis.

Chlorella virus PBCV-1 DNA ligase seals nicked DNA substrates consisting of a 5'-phosphate-terminated strand and a 3'-hydroxyl-terminated strand annealed to a bridging DNA template strand. The enzyme discriminates at the DNA binding step between substrates containing a 5'-phosphate versus a 5'-hydroxyl at the nick. Mutational analysis of the active site motif KxDGxR (residues 27-32) illuminates essential roles for the conserved Lys, Asp and Arg moieties at different steps of the ligase reaction. Mutant K27A is unable to form the covalent ligase-(Lys-straightepsilonN-P)-adenylate intermediate and hence cannot activate a nicked DNA substrate via formation of the DNA-adenylate intermediate. Nonetheless, K27A catalyzes phosphodiester bond formation at a pre-adenylated nick. This shows that the active site lysine is not required for the strand closure reaction. K27A binds to nicked DNA-adenylate, but not to a standard DNA nick. This suggests that occupancy of the AMP binding pocket of DNA ligase is important for nick recognition. Mutant D29A is active in enzyme-adenylate formation and binds readily to nicked DNA, but is inert in DNA-adenylate formation. R32A is unable to catalyze any of the three reactions of the ligation pathway and does not bind to nicked DNA.     

Mechanistic and kinetic study of the ATP-dependent DNA ligase of Neisseria meningitidis

The gene from Neisseria meningitidis serogroup A, encoding a putative, secreted ATP-dependent DNA ligase was cloned and overexpressed, and the soluble protein was purified. Mass spectrometry indicated that the homogeneous protein was adenylated as isolated, and sedimentation velocity experiments suggested that the enzyme exists as a monomer in solution. The 31.5 kDa protein can catalyze the ATP-dependent ligation of a singly nicked DNA duplex but not blunt-end joining. The first step of the overall reaction, the ATP-dependent formation of an adenylated ligase, was studied by measuring the formation of the covalent intermediate and isotope exchange between [alpha-32P] ATP and PPi. Mg2+ was absolutely required for this reaction and was the best divalent cation to promote catalysis. Electrophoretic gel mobility shift assays revealed that the enzyme bound both unnicked and singly nicked double stranded DNA with equivalent affinity (Kd approximately 50 nM) but cannot bind single stranded DNA. Preadenylated DNA was synthesized by transferring the AMP group from the enzyme to the 5'-phosphate of a 3'-dideoxy nicked DNA. The rate of phosphodiester bond formation at the preadenylated nick was also Mg(2+)-dependent. Kinetic data showed that the overall rate of ligation, which occurred at 0.008 s(-1), is the result of three chemical steps with similar rate constants (approximately 0.025 s(-1)). The Km values for ATP and DNA substrates, in the overall ligation reaction, were 0.4 microM and 30 nM, respectively.     

The use of BrCN for assembling modified DNA duplexes and DNA-RNA hybrids; comparison with water-soluble carbodiimide.

Both cyanogen bromide (BrCN) and 1-ethyl-3-(3'-dimethylaminopropyl) carbodiimide may be used as coupling reagents for the template-directed assembly of DNA duplexes containing the sugar-phosphate backbone modification. Both reagents show similar ligation site structure-specific trend. Practical recommendations are given for selection of the condensing reagent depending on the properties of the duplex. Based on 31P NMR spectroscopy data, a scheme is suggested for BrCN activation of the nucleotide phosphomonoester group. Using both condensing reagents, we studied the condensation of oligonucleotides containing ribo-segments (from mononucleotide residue to full sequence) on the DNA template. Efficiency of the chemical ligation of RNA oligomers was shown to be much lower than that of DNA analogues. The coupling yield depends on the position of the RNA segment in the hybrid duplexes and on the position of the phosphate group in the nick.     

Kinetics and thermodynamics of nick sealing by T4 DNA ligase.

T4 DNA ligase is an Mg2+-dependent and ATP-dependent enzyme that seals DNA nicks in three steps: it covalently binds AMP, transadenylates the nick phosphate, and catalyses formation of the phosphodiester bond releasing AMP. In this kinetic study, we further detail the reaction mechanism, showing that the overall ligation reaction is a superimposition of two parallel processes: a 'processive' ligation, in which the enzyme transadenylates and seals the nick without dissociating from dsDNA, and a 'nonprocessive' ligation, in which the enzyme takes part in the abortive adenylation cycle (covalent binding of AMP, transadenylation of the nick, and dissociation). At low concentrations of ATP (<10 microM) and when the DNA nick is sealed with mismatching base pairs (e.g. five adjacent), this superimposition resolves into two kinetic phases, a burst ligation (approximately 0.2 min(-1)) and a subsequent slow ligation (approximately 2x10(-3) min(-1)). The relative rate and extent of each phase depend on the concentrations of ATP and Mg2+. The activation energies of self-adenylation (16.2 kcal.mol(-1)), transadenylation of the nick (0.9 kcal.mol(-1)), and nick-sealing (16.3-18.8 kcal.mol(-1)) were determined for several DNA substrates. The low activation energy of transadenylation implies that the transfer of AMP to the terminal DNA phosphate is a spontaneous reaction, and that the T4 DNA ligase-AMP complex is a high-energy intermediate. To summarize current findings in the DNA ligation field, we delineate a kinetic mechanism of T4 DNA ligase catalysis.     

Optimizing splinted ligation of highly structured small RNAs

The synthesis of highly structured small RNAs containing nonstandard nucleotides is of high interest for structural and functional investigations. A general approach is the joining, by T4 DNA ligase-mediated splinted ligation, of two or more RNA fragments, each of which may contain its own set of modified nucleotides. The RNA fragments hybridize with a complementary DNA splint to form a ternary ligation-competent-complex (LCC), which is then turned over by the DNA ligase. We studied the formation of the LCC and its precursors using size exclusion chromatography combined with a fluorescence detector. The spatial proximity of two cyanine-dye-labeled RNA fragments in LCCs was detected by monitoring FRET. An observed correlation of LCC formation and ligation yields suggests the use of long splints to stabilize LCCs. Splint oligos of increasing length, which in general appear to reduce the number of different hybridization intermediate species found in a reaction mixture, were applied to the synthesis by T4-DNA-ligation of two highly structured target molecules, one a 73 mer tRNA, the other a 49 mer synthetic ribozyme. A stable LCC could be isolated and turned over with>95% ligation efficiency. In conclusion, the use of long splints presents a generally applicable means to overcome the low propensity of highly structured RNAs for hybridization, and thus to significantly improve ligation efficiencies.     

Mapping of eukaryotic DNA topoisomerase I catalyzed cleavage without concomitant religation in the vicinity of DNA structural anomalies

Sensitive sites for covalent trapping of eukaryotic topoisomerase I at DNA structural anomalies were mapped by a new method using purified enzyme and defined DNA substrates. To insure that the obtained topoisomerase I trapping patterns were not influenced by DNA sequence variations, a single DNA imperfection was placed centrally within a homonucleotide track. Mapping of topoisomerase I-mediated irreversible cleavage sites on homopolymeric DNA substrates containing mismatches showed trapping of the enzyme in several positions in close vicinity of the DNA imperfection, with a strong preference for the 5' junction between the duplex DNA and the base-pairing anomaly. On homopolymeric DNA substrates containing a nick, sites of topoisomerase I-mediated cleavage on the intact strand were located just opposite to the nick and from one to ten nucleotides 5' to the nick. Sites of enzyme-mediated cleavage next to a nick and an immobile single-stranded branch were located 5' to the strand interruption in distances of two to six nucleotides and two to ten nucleotides, respectively. Taken together these findings suggest that covalent trapping of topoisomerase I proceeds at positions adjacent to mismatches, nicks and single-stranded branches, where the cleavage reaction is allowed and the ensuing ligation reaction prevented. In principle, the developed interference method might be of general utility to define topoisomerase-DNA interactions relative to different types of structural anomalies.     

Synthesis of DNA Dumbbells: Chemical vs. Enzymatic Ligation of Self-Complementary Oligonucleotides

Abstract

The chemical (cyanogen bromide) and enzymatic (T4 DNA ligase) ligation of five different self-complementary oligonucleotide sequences which form 14-or 16-base pair dumbbells are described and compared here. A review of both chemical and enzymatic methods is presented; an improved enzymatic method is described as well. While both methods of ligation are effective, chemical ligation may be preferred since it is faster and less costly.     

Human topoisomerase IIalpha possesses an intrinsic nucleic acid specificity for DNA ligation. Use of 5' covalently activated oligonucleotide substrates to study enzyme mechanism

Despite the importance of topoisomerase II-mediated DNA ligation to the essential physiological functions of the enzyme, the mechanistic details of this important reaction are poorly understood. Because topoisomerase II normally does not release cleaved DNA molecules prior to ligation, it is not known whether all of the nucleic acid specificity of its cleavage/ligation cycle is embodied in DNA cleavage or whether ligation also contributes specificity to the enzyme. All currently available ligation assays require that topoisomerase II cleave the initial DNA substrate before rejoining can be monitored. Consequently, it has been impossible to examine the specificity of DNA ligation separately from that of scission. To address this issue, a cleavage-independent topoisomerase II DNA ligation assay was developed. This assay utilizes a nicked oligonucleotide whose 5'-phosphate terminus at the nick has been activated by covalent attachment to the tyrosine mimic, p-nitrophenol. Human topoisomerase IIalpha and enzymes with active-site mutations that abrogated cleavage activity ligated the activated nick by catalyzing the direct attack of the terminal 3'-OH on the activated 5'-phosphate. Results with different DNA sequences indicate that human topoisomerase IIalpha possesses an intrinsic nucleic acid specificity for ligation that parallels its specificity for DNA cleavage.     

Two DNA-binding and nick recognition modules in human DNA ligase III

Human DNA ligase III contains an N-terminal zinc finger domain that binds to nicks and gaps in DNA. This small domain has been described as a DNA nick sensor, but it is not required for DNA nick joining activity in vitro. In light of new structural information for mammalian ligases, we measured the DNA binding affinity and specificity of each domain of DNA ligase III. These studies identified two separate, independent DNA-binding modules in DNA ligase III that each bind specifically to nicked DNA over intact duplex DNA. One of these modules comprises the zinc finger domain and DNA-binding domain, which function together as a single DNA binding unit. The catalytic core of ligase III is the second DNA nick-binding module. Both binding modules are required for ligation of blunt ended DNA substrates. Although the zinc finger increases the catalytic efficiency of nick ligation, it appears to occupy the same binding site as the DNA ligase III catalytic core. We present a jackknife model for ligase III that posits conformational changes during nick sensing and ligation to extend the versatility of the enzyme.     

Nick recognition by DNA ligases

Phage T7 DNA ligase seals nicked DNA substrates and is a representative member of the ATP-dependent class of DNA ligases. Although the catalytic mechanism of DNA ligases has been delineated, little is known about the nature of nick recognition by these enzymes. Here, we show that T7 ligase discriminates, at the nick-binding step, between nicks containing either a 5'-phosphate or a 5'-OH. T7 ligase binds preferentially to phosphorylated nicks and catalyses the sealing reaction. We also show using DNA footprinting studies, that T7 ligase binds asymmetrically to nicks as a monomer, with the protein interface covering between 12 and 14 bp of DNA. Based on molecular modelling studies we propose a structural model of the ligase-DNA complex consistent with these and other data. Using photo-crosslinking and site-directed mutagenesis we have identified two residues, K238 and K240, critical for the transadenylation and nick-sealing reactions. Sequence conservation and structural analysis supports the premise that these two lysine residues are critical for both nucleotide binding and DNA nick recognition. The implications of these results on the ligation mechanism are discussed.