Inhibition of HIV-1 integrase by modified oligonucleotides derived from U5' LTR.

Retroviral integrase catalyzes integration of double-stranded viral DNA into the host chromosome by a process that has become an attractive target for drug design. In the 3' processing reaction, two nucleotides are specifically cleaved from both 3' ends of viral DNA yielding a 5' phosphorylated dimer (pGT). The resulting recessed 3' hydroxy groups of adenosine provide the attachment sites to the host DNA in the strand transfer reaction. Here, we studied the effect of modified double-stranded oligonucleotides mimicking both the unprocessed (21-mer oligonucleotides) and 3' processed (19-mer oligonucleotides) U5 termini of proviral DNA on activities of HIV-1 integrase in vitro. The inhibitions of 3' processing and strand transfer reactions were studied using 21-mer oligonucleotides containing isopolar, nonisosteric, both conformationally flexible and restricted phosphonate internucleotide linkages between the conservative AG of the sequence CAGT, and using a 21-mer oligonucleotide containing 2'-fluoroarabinofuranosyladenine. All modified 21-mer oligonucleotides competitively inhibited both reactions mediated by HIV-1 integrase with nanomolar IC50 values. Our studies with 19-mer oligonucleotides showed that modifications of the 3' hydroxyl significantly reduced the strand transfer reaction. The inhibition of integrase with 19-mer oligonucleotides terminated by (S)-9-(3-hydroxy-2-phosphonomethoxypropyl)adenine, 9-(2-phosphonomethoxyethyl)adenine, and adenosine showed that proper orientation of the 3' OH group and the presence of the furanose ring of adenosine significantly influence the strand transfer reaction.     

A high-throughput assay for the adenylation reaction of bacterial DNA ligase

DNA ligase catalyzes the closure of single-strand nicks in double-stranded DNA that arise during replication and recombination. Inhibition of bacterial ligase is expected to cause chromosome degradation and cell death, making it an attractive target for new antibacterials. The prototypical bacterial ligase couples the hydrolysis of NAD(+) to phosphodiester bond formation between an adjacent 3'OH and 5'-terminal phosphate of nicked duplex DNA. The first step is the reversible formation of a ligase-adenylate from the reaction between apoenzyme and NAD(+). Inhibitors that compete with NAD(+) are expected to be bacterial specific because eukaryotic DNA ligases use ATP and differ in the sequence composition of their adenylation domain. We report here a high-throughput assay that measures the adenylation reaction specifically by monitoring ligase-AMP formation via scintillation proximity technologies. Escherichia coli DNA ligase was biotinylated in vivo; after reaction with radiolabeled NAD(+), ligase-[(3)H]AMP could be captured onto the streptavidin-coated surface of the solid scintillant. The method was ideal for high-throughput screening because it required minimal manipulations and generated a robust signal with minimal scatter. Certain adenosine analogs were found to inhibit the adenylation assay and had similar potency of inhibition in a DNA ligation assay.     

Characterization of an ATP-dependent DNA ligase encoded by Chlorella virus PBCV-1.

We report that Chlorella virus PBCV-1 encodes a 298-amino-acid ATP-dependent DNA ligase. The PBCV-1 enzyme is the smallest member of the covalent nucleotidyl transferase superfamily, which includes the ATP-dependent polynucleotide ligases and the GTP-dependent RNA capping enzymes. The specificity of PBCV-1 DNA ligase was investigated by using purified recombinant protein. The enzyme catalyzed efficient strand joining on a singly nicked DNA in the presence of magnesium and ATP (Km, 75 microM). Other nucleoside triphosphates or deoxynucleoside triphosphates could not substitute for ATP. PBCV-1 ligase was unable to ligate across a 2-nucleotide gap and ligated poorly across a 1-nucleotide gap. A native gel mobility shift assay showed that PBCV-1 DNA ligase discriminated between nicked and gapped DNAs at the substrate-binding step. These findings underscore the importance of a properly positioned 3' OH acceptor terminus in substrate recognition and reaction chemistry.     

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.     

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.     

DNA helicases displace streptavidin from biotin-labeled oligonucleotides

Helicases are enzymes that use energy derived from nucleoside triphosphate hydrolysis to unwind double-stranded (ds) DNA, a process vital to virtually every phase of DNA metabolism. The helicases used in this study, gp41 and Dda, are from the bacteriophage T4, an excellent system for studying enzymes that process DNA. gp41 is the replicative helicase and has been shown to form a hexamer in the presence of ATP. In this study, protein cross-linking was performed in the presence of either linear or circular single-stranded (ss) DNA substrates to determine the topology of gp41 binding to ssDNA. Results indicate that the hexamer binds ssDNA by encircling it, in a manner similar to that of other hexameric helicases. A new assay was developed for studying enzymatic activity of gp41 and Dda on single-stranded DNA. The rate of dissociation of streptavidin from various biotinylated oligonucleotides was determined in the presence of helicase by an electrophoretic mobility shift assay. gp41 and Dda were found to significantly enhance the dissociation rate of streptavidin from biotin-labeled oligonucleotides in an ATP-dependent reaction. Helicase-catalyzed dissociation of streptavidin from the 3'-end of a biotin-labeled 62-mer oligonucleotide occurred with a first-order rate of 0.17 min-1, which is over 500-fold faster than the spontaneous dissociation rate of biotin from streptavidin. Dda activity leads to even faster displacement of streptavidin from the 3' end of the 62-mer, with a first-order rate of 7.9 s-1. This is more than a million-fold greater than the spontaneous dissociation rate. There was no enhancement of streptavidin dissociation from the 5'-biotin-labeled oligonucleotide by either helicase. The fact that each helicase was capable of dislodging streptavidin from the 3'-biotin label suggests that these enzymes are capable of imparting a force on a molecule blocking their path. The difference in displacement between the 5' and 3' ends of the oligonucleotide is also consistent with the possibility of a 5'-to-3' directional bias in translocation on ssDNA for each helicase.     

Thermus scotoductus and Rhodothermus marinus DNA ligases have higher ligation efficiencies than thermus thermophilus DNA ligase

To mimic large numbers of nicked DNA duplexes we used a technique that produces nicked duplex DNA substrates by hybridization of complementary oligonucleotides, adjacent to an initiating primer, which are ligated together by a thermostable DNA ligase. Sequential ligation of nonanucleotides to this primary duplex results in the formation of polymers that can be analyzed by gel electrophoresis. The extent of polymerization is a measure of the efficiency of ligation. We determined the efficiency of ligation of nonanucleotides, using various length initiating primers, with three thermostable DNA ligases: Thermus thermophilus (Tth), Thermus scotoductus (Ts), and Rhodothermus marinus (Rm). Analysis of the effect of temperature for each ligase, and for each directing primer length, revealed that at 37 and 41 degrees C there was variation between ligase efficiency in the order Rm > or = Ts > or = Tth. The higher temperature of 46 degrees C was optimal for polymerization with each of the ligases and Rm ligase was the most efficient. Analysis of directionality of the ligations reactions suggests that for each of the Thermus ligases we tested, there was a bias to polymerization of nonanucleotides in a 5'-3' direction.     

Characterization of an ATP-dependent DNA ligase encoded by Haemophilus influenzae.

We report that Haemophilus influenzae encodes a 268 amino acid ATP-dependent DNA ligase. The specificity of Haemophilus DNA ligase was investigated using recombinant protein produced in Escherichia coli. The enzyme catalyzed efficient strand joining on a singly nicked DNA in the presence of magnesium and ATP (Km = 0.2 microM). Other nucleoside triphosphates or deoxynucleoside triphosphates could not substitute for ATP. Haemophilus ligase reacted with ATP in the absence of DNA substrate to form a covalent ligase-adenylate intermediate. This nucleotidyl transferase reaction required a divalent cation and was specific for ATP. The Haemophilus enzyme is the first example of an ATP-dependent DNA ligase encoded by a eubacterial genome. It is also the smallest member of the covalent nucleotidyl transferase superfamily, which includes the bacteriophage and eukaryotic ATP-dependent polynucleotide ligases and the GTP-dependent RNA capping enzymes.     

High sequence fidelity in a non-enzymatic DNA autoligation reaction.

The success of oligonucleotide ligation assays in probing specific sequences of DNA arises in large part from high enzymatic selectivity against base mismatches at the ligation junction. We describe here a study of the effect of mismatches on a new non-enzymatic, reagent-free method for ligation of oligonucleotides. In this approach, two oligonucleotides bound at adjacent sites on a complementary strand undergo autoligation by displacement of a 5'-end iodide with a 3'-phosphorothioate group. The data show that this ligation proceeds somewhat more slowly than ligation by T4 ligase, but with substantial discrimination against single base mismatches both at either side of the junction and a few nucleotides away within one of the oligonucleotide binding sites. Selectivities of >100-fold against a single mismatch are observed in the latter case. Experiments at varied concentrations and temperatures are carried out both with the autoligation of two adjacent linear oligonucleotides and with intramolecular autoligation to yield circular 'padlock' DNAs. Application of optimized conditions to discrim-ination of an H- ras codon 12 point mutation is demonstrated with a single-stranded short DNA target.     

Joining of short DNA oligonucleotides with base pair mismatches by T4 DNA ligase

Oligonucleotide-directed mutagenesis is a widely used method for studying enzymes and improving their properties. The number of mutants that can be obtained with this method is limited by the number of synthetic 25-30mer oligonucleotides containing the mutation mismatch, becoming impracticably large with increasing size of a mutant library. To make this approach more practical, shorter mismatching oligonucleotides (7-12mer) might be employed. However, the introduction of these oligonucleotides in dsDNA poses the problem of sealing a DNA nick containing 5'-terminal base pair mismatches. In the present work we studied the ability of T4 DNA ligase to catalyze this reaction. It was found that T4 DNA ligase effectively joins short oligonucleotides, yielding dsDNA containing up to five adjacent mismatches. The end-joining rate of mismatching oligonucleotides is limited by the formation of the phosphodiester bond, decreasing with an increase in the number of mismatching base pairs at the 5'-end of the oligonucleotide substrate. However, in the case of a 3 bp mismatch, the rate is higher than that obtained with a 2 bp mismatch. Increasing the matching length with the number of mismatching base pairs fixed, or moving the mismatching motif downstream with respect to the joining site increases the rate of ligation. The ligation rate increases with the molar ratio [oligonucleotide:dsDNA]; however, at high excess of the oligonucleotide, inhibition of joining was observed. In conclusion, 9mer oligonucleotides containing a 3 bp mismatch are found optimal substrates to introduce mutations in dsDNA, opening perspectives for the application of T4 DNA ligase in mutagenesis protocols.     

Dynamic mechanism of nick recognition by DNA ligase.

DNA ligases are the enzymes responsible for the repair of single-stranded and double-stranded nicks in dsDNA. DNA ligases are structurally similar, possibly sharing a common molecular mechanism of nick recognition and ligation catalysis. This mechanism remains unclear, in part because the structure of ligase in complex with dsDNA has yet to be solved. DNA ligases share common structural elements with DNA polymerases, which have been cocrystallized with dsDNA. Based on the observed DNA polymerase-dsDNA interactions, we propose a mechanism for recognition of a single-stranded nick by DNA ligase. According to this mechanism, ligase induces a B-to-A DNA helix transition of the enzyme-bound dsDNA motif, which results in DNA contraction, bending and unwinding. For non-nicked dsDNA, this transition is reversible, leading to dissociation of the enzyme. For a nicked dsDNA substrate, the contraction of the enzyme-bound DNA motif (a) triggers an opened-closed conformational change of the enzyme, and (b) forces the motif to accommodate the strained A/B-form hybrid conformation, in which the nicked strand tends to retain a B-type helix, while the non-nicked strand tends to form a shortened A-type helix. We propose that this conformation is the catalytically competent transition state, which leads to the formation of the DNA-AMP intermediate and to the subsequent sealing of the nick.     

Hepatitis C virus NS3 and simian virus 40 T antigen helicases displace streptavidin from 5'-biotinylated oligonucleotides but not from 3'-biotinylated oligonucleotides: evidence for directional bias in translocation on single-stranded DNA

Helicases are enzymes that use energy from nucleoside triphosphate hydrolysis to unwind double-stranded (ds) DNA, a process vital to virtually every phase of DNA metabolism. Helicases have been classified as either 5'-to-3' or 3'-to-5' on the basis of their ability to unwind duplex DNA adjacent to either a 5' or 3' single-stranded (ss) DNA overhang. However, there has been debate as to whether this substrate preference is indicative of unidirectional translocation on ssDNA. We developed an assay that monitors the ability of a helicase to displace streptavidin from biotinylated oligonucleotides [Morris, P. D., and Raney, K. D. (1999) Biochemistry 38, 5164-5171]. Two helicases identified as having 5'-to-3' polarity displaced streptavidin from the 3'-end of biotinylated oligonucleotides but not from the 5'-end. We performed similar experiments using the 3'-to-5' helicases from the hepatitis C virus (NS3) and SV40 virus (SV40 T antigen). NS3 and SV40 T antigen were able to displace streptavidin from a 5'-biotinylated oligonucleotide but not from a 3'-biotinylated oligonucleotide. NS3 and SV40 T antigen enhanced the spontaneous rate of dissociation of streptavidin from biotin 340-fold and 1700-fold, respectively. The ssDNA binding protein, gp32, did not enhance dissociation of streptavidin from either end of an oligonucleotide. For NS3, the rate of displacement was faster from a 5'-biotinylated 60mer than from a 5'-biotinylated 30mer. The strong directional bias in streptavidin displacement activity exhibited by each helicase is consistent with a directional bias in translocation on ssDNA. The dependence of the reaction with NS3 on the oligonucleotide length suggests that multiple NS3 monomers are necessary for optimal activity.     

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.     

DNA ligase III is recruited to DNA strand breaks by a zinc finger motif homologous to that of poly(ADP-ribose) polymerase. Identification of two functionally distinct DNA binding regions within DNA ligase III.

Mammalian DNA ligases are composed of a conserved catalytic domain flanked by unrelated sequences. At the C-terminal end of the catalytic domain, there is a 16-amino acid sequence, known as the conserved peptide, whose role in the ligation reaction is unknown. Here we show that conserved positively charged residues at the C-terminal end of this motif are required for enzyme-AMP formation. These residues probably interact with the triphosphate tail of ATP, positioning it for nucleophilic attack by the active site lysine. Amino acid residues within the sequence RFPR, which is invariant in the conserved peptide of mammalian DNA ligases, play critical roles in the subsequent nucleotidyl transfer reaction that produces the DNA-adenylate intermediate. DNA binding by the N-terminal zinc finger of DNA ligase III, which is homologous with the two zinc fingers of poly(ADP-ribose) polymerase, is not required for DNA ligase activity in vitro or in vivo. However, this zinc finger enables DNA ligase III to interact with and ligate nicked DNA at physiological salt concentrations. We suggest that in vivo the DNA ligase III zinc finger may displace poly(ADP-ribose) polymerase from DNA strand breaks, allowing repair to occur.     

DNA Ligases: Progress and Prospects

DNA ligases seal 5′-PO₄ and 3′-OH polynucleotide ends via three nucleotidyl transfer steps involving ligase-adenylate and DNA-adenylate intermediates. DNA ligases are essential guardians of genomic integrity, and ligase dysfunction underlies human genetic disease syndromes. Crystal structures of DNA ligases bound to nucleotide and nucleic acid substrates have illuminated how ligase reaction chemistry is catalyzed, how ligases recognize damaged DNA ends, and how protein domain movements and active-site remodeling are used to choreograph the end-joining pathway. Although a shared feature of DNA ligases is their envelopment of the nicked duplex as a C-shaped protein clamp, they accomplish this feat by using remarkably different accessory structural modules and domain topologies. As structural, biochemical, and phylogenetic insights coalesce, we can expect advances on several fronts, including (i) pharmacological targeting of ligases for antibacterial and anticancer therapies and (ii) the discovery and design of new strand-sealing enzymes with unique substrate specificities.     

Improving the fidelity of Thermus thermophilus DNA ligase.

The DNA ligase from Thermus thermophilus (Tth DNA ligase) seals single-strand breaks (nicks) in DNA duplex substrates. The specificity and thermostability of this enzyme are exploited in the ligase chain reaction (LCR) and ligase detection reaction (LDR) to distinguish single base mutations associated with genetic diseases. Herein, we describe a quantitative assay using fluorescently labeled substrates to study the fidelity of Tth DNA ligase. The enzyme exhibits significantly greater discrimination against all single base mismatches on the 3'-side of the nick in comparison with those on the 5'-side of the nick. Among all 12 possible single base pair mismatches on the 3'-side of the nick, only T-G and G-T mismatches generated a quantifiable level of ligation products after 23 h incubation. The high fidelity of Tth DNA ligase can be improved further by introducing a mismatched base or a universal nucleoside analog at the third position of the discriminating oligonucleotide. Finally, two mutant Tth DNA ligases, K294R and K294P, were found to have increased fidelity using this assay.     

Novel DNA ligase with broad nucleotide cofactor specificity from the hyperthermophilic crenarchaeon Sulfophobococcus zilligii: influence of ancestral DNA ligase on cofactor utilization

DNA ligases are divided into two groups according to their cofactor requirement to form ligase-adenylate, ATP-dependent DNA ligases and NAD(+)-dependent DNA ligases. The conventional view that archaeal DNA ligases only utilize ATP has recently been disputed with discoveries of dual-specificity DNA ligases (ATP/ADP or ATP/NAD(+)) from the orders Desulfurococcales and Thermococcales. Here, we studied DNA ligase encoded by the hyperthermophilic crenarchaeon Sulfophobococcus zilligii. The ligase exhibited multiple cofactor specificity utilizing ADP and GTP in addition to ATP. The unusual cofactor specificity was confirmed via a DNA ligase nick-closing activity assay using a fluorescein/biotin-labelled oligonucleotide and a radiolabelled oligonucleotide. The exploitation of GTP as a catalytic energy source has not to date been reported in any known DNA ligase. This phenomenon may provide evolutionary evidence of the nucleotide cofactor utilization by DNA ligases. To bolster this hypothesis, we summarize and evaluate previous assertions. We contend that DNA ligase evolution likely started from crenarchaeotal DNA ligases and diverged to eukaryal DNA ligases and euryarchaeotal DNA ligases. Subsequently, the NAD(+)-utilizing property of some euryarchaeotal DNA ligases may have successfully differentiated to bacterial NAD(+)-dependent DNA ligases.     

Development of nonradioactive microtiter plate assays for nuclease activity

We have developed two microtiter plate assays for the detection of DNA cleavage by nucleases, using 3'-biotinylated oligonucleotide substrates. In the covalently linked oligonucleotide nuclease assay (CLONA), the biotinylated substrates are phosphorylated at the 5' end to facilitate their covalent immobilization on CovaLink NH plates. The cleavage of the covalently immobilized substrate by nucleases results in biotin release. The uncleaved substrate molecules are detected with an enzyme-avidin conjugate. The affinity-linked oligonucleotide nuclease assay (ALONA) makes use of substrates with a digoxigenin on the 5' end of the 3'-biotinylated DNA strand. The substrate binds specifically to the wells of streptavidin-coated microtiter plates, in which the nuclease reaction takes place. Uncleaved substrate retains the digoxigenin label, which is detected with an enzyme-labeled anti-digoxigenin antibody. We assessed the efficiency of these two assays by measuring S1 nuclease and DNase I activities, and the inhibitory effect of EDTA and aurintricarboxylic acid on the reaction. Both methods are more convenient than the standard radioactive nuclease assay and are suitable for high-throughput screening of potential nuclease inhibitors, nucleases, and catalytic antibodies. The ALONA assay was found to be more sensitive than the CLONA assay, with a performance similar to that of the standard nuclease assay.     

NAD+-dependent DNA ligase encoded by a eukaryotic virus.

We report the production, purification, and characterization of an NAD(+)-dependent DNA ligase encoded by the Amsacta moorei entomopoxvirus (AmEPV), the first example of an NAD(+) ligase from a source other than eubacteria. AmEPV ligase lacks the zinc-binding tetracysteine domain and the BRCT domain that are present in all eubacterial NAD(+) ligases. Nonetheless, the monomeric 532-amino acid AmEPV ligase catalyzed strand joining on a singly nicked DNA in the presence of a divalent cation and NAD(+). Neither ATP, dATP, nor any other nucleoside triphosphate could substitute for NAD(+). Structure probing by limited proteolysis showed that AmEPV ligase is punctuated by a surface-accessible loop between the nucleotidyltransferase domain, which is common to all ligases, and the N-terminal domain Ia, which is unique to the NAD(+) ligases. Deletion of domain Ia of AmEPV ligase abolished the sealing of 3'-OH/5'-PO(4) nicks and the reaction with NAD(+) to form ligase-adenylate, but had no effect on phosphodiester formation at a pre-adenylated nick. Alanine substitutions at residues within domain Ia either reduced (Tyr(39), Tyr(40), Asp(48), and Asp(52)) or abolished (Tyr(51)) sealing of a 5'-PO(4) nick and adenylyl transfer from NAD(+) without affecting ligation of DNA-adenylate. We conclude that: (i) NAD(+)-dependent ligases exist in the eukaryotic domain of the phylogenetic tree; and (ii) ligase structural domain Ia is a determinant of cofactor specificity and is likely to interact directly with the nicotinamide mononucleotide moiety of NAD(+).     

Complete protection of antisense oligonucleotides against serum nuclease degradation by an avidin-biotin system.

It has been recently demonstrated that a complex of avidin, a cationic protein, and a monobiotinylated antisense oligonucleotide for the GLUT1 glucose transporter mRNA is taken up by cells in vitro and by organs in vivo via absorptive-mediated endocytosis. In the present study, a GLUT1 biotinylated oligonucleotide-avidin construct showing complete protection against serum 3'-exonuclease-mediated degradation is described. 21-mer antisense oligonucleotides complementary to nucleotides 162-182 and 161-181 of the bovine GLUT1 glucose transporter mRNA were synthesized with a 6-aminodeoxyuridine at positions 3 and 20, respectively, biotinylated with NHS- or NHS-XX-biotin to yield near 5'- or near 3'-biotinylated oligonucleotide (bio-DNA), and 5'- and 3'-end radiolabeled. Serum induced a rapid degradation of unprotected (no avidin) [5'-32P]-5'-bio-DNA (> 95% at 30 min). Avidin partially protected this construct (approximately 31% of intact 21-mer oligo remained at 1 h). Similar results were obtained with the [3'-32P]-5'-bio-DNA; however, no degradation products of varying size were observed, confirming that the degradation is mediated primarily by a 3'-exonuclease. Incubation of the [5'-32P]-3'-bio-DNA with serum showed a rapid conversion to the 20- and 19-mer forms (t1/2 approximately 13 min). Conversely, avidin totally protected this construct against the serum 3'-exonuclease. In conclusion, avidin fully protects antisense oligonucleotides biotinylated at the near 3'-terminus against serum 3'-exonuclease degradation, and this property may be useful for avidin-mediated drug delivery of oligonucleotides to tissues in vivo or to cultured cells in vitro.