T4 polynucleotide ligase catalyzed joining of short synthetic DNA duplexes at base-paired ends

The self-complementary octanucleotide dT-A-G-T-A-C-T-A has been synthesized and its sequence confirmed by two-dimensional fingerprinting. Under conditions used for the T4 polynucleotide ligase reaction, this oligonucleotide forms a dimeric duplex which shows a Tm of 18 degrees C. The optimal rate of joining of the 32P-labeled duplex occurs between 12 and 15 degrees C. The rate is highly concentration dependent, as expected for a bimolecular process. Polyacrylamide gel electrophoretic analysis of this reaction shows the presence of products up to 120 nucleotides in length. In a denaturing gel, each product appears as a double band due to the presence of its 5'-adenylylated activated intermediate. Substrates larger than eight base pairs are utilized more rapidly than the eight base pair duplex, indicating that the T4 ligase has a higher affinity for longer substrates. The low level of nicked intermediates suggests that the joining of both strands requires two steps, the rates of which must be similar.     

Use of the T4 polynucleotide ligase in the joining of flush-ended DNA segments generated by restriction endonucleases.

Double-stranded DNA segments with completely base-paired ends were obtained by the action of various restriction endonucleases on phage and plasmid DNAs. These segments were joined covalently by the T4 polynucleotide ligase. The joining was monitored by the electron microscopy count of intramolecularly circularized segments. The highest extent of joining, close to 75%, was observed at 15-25 degrees C with the segments resulting from the action of the Bacillus subtilis (strain R) restriction endonuclease Bsu on the DNA of bacteriophage SPPI or of the plasmid pSC 101. The joining of double-stranded termini required about 10 times more enzyme than the short single-stranded termini produced by the Escherichia coli restriction endonuclease EcoRI. A shortened purification of the T4 ligase was found to give an enzyme devoid of interfacing nucleases.     

Purification and electrophoretic assay of T4-induced polynucleotide ligase for the in vitro construction of recombinant DNA molecules

A facile method for the determination of bacteriophage T4-induced polynucleotide ligase joining activity is described. The assay is based on the ability of polynucleotide ligase to join the cohesive termini of bacteriophage λ DNA covalently. The observance of this activity is greatly facilitated if λ DNA is previously cleaved with the restriction endonuclease EcoRI and the reaction products subsequently analyzed by electrophoresis in ethidium bromide-agarose gel. A purification scheme is presented which offers a reduction in the number of steps required to purify polynucleotide ligase compared to a previously published procedure and yields an enzyme preparation which is suitable for use in in vitro construction of recombinant DNA molecules.     

Impact of DNA ligase IV on the fidelity of end joining in human cells

A DNA ligase IV (LIG4)-null human pre-B cell line and human cell lines with hypomorphic mutations in LIG4 are significantly impaired in the frequency and fidelity of end joining using an in vivo plasmid assay. Analysis of the null line demonstrates the existence of an error-prone DNA ligase IV-independent rejoining mechanism in mammalian cells. Analysis of lines with hypomorphic mutations demonstrates that residual DNA ligase IV activity, which is sufficient to promote efficient end joining, nevertheless can result in decreased fidelity of rejoining. Thus, DNA ligase IV is an important factor influencing the fidelity of end joining in vivo. The LIG4-defective cell lines also showed impaired end joining in an in vitro assay using cell-free extracts. Elevated degradation of the terminal nucleotide was observed in a LIG4-defective line, and addition of the DNA ligase IV–XRCC4 complex restored end protection. End protection by DNA ligase IV was not dependent upon ligation. Finally, using purified proteins, we demonstrate that DNA ligase IV–XRCC4 is able to protect DNA ends from degradation by T7 exonuclease. Thus, the ability of DNA ligase IV–XRCC4 to protect DNA ends may contribute to the ability of DNA ligase IV to promote accurate rejoining in vivo.     

Purification and properties of bacteriophage T4-induced RNA ligase

RNA ligase has been extensively purified by a new procedure in high yield from T4-infected Escherichia coli. The enzyme consists of a single polypeptide chain of molecular weight 47,000. It catalyzes the formation of a phosphodiester bond between a 5′-PO₄-terminated oligonucleotide and a 3′-OH terminated oligonucleotide. The purified enzyme catalyzes both the intramolecular formation of single-stranded circles with longer oligonucleotides of the type pAp(Ap)_nA_?OH, where n is about 15 or greater and the intermolecular joining of pAp(Ap)₃A_OH (where the 5′-PO₄-terminated oligonucleotide is short enough to prevent apposition of its 3′ and 5′ ends) to UpUpU_OH when high concentrations of the 3′-OH-terminated acceptor oligonucleotide are present. Preparations of RNA ligase at all stages of purification show an unusual dependence of specific activity of the enzyme on the concentration of enzyme present in the assay. However, when care is taken to determine meaningful specific activities at each step, the ligase is found to be very stable during chromatography on various ion-exchange columns and may be purified by conventional techniques.     

Kinetics and effect of salts and polyamines on T4 polynucleotide ligase.

The kinetics of T4 polynucleotide ligase has been investigated at pH 8,20 degrees C and using the double-stranded DNA substrate (dA)n - [(dT)10]n/10. Double-reciprocal plots of initial rates vs substrate concentrations as well as product inhibition studies have indicated that the enzyme reacts according to a ping-pong mechanism. The overall mechanism was found to be non-processive. The true Km for the DNA substrate was 0.6 muM and that of ATP 100 muM. Several attempts were made to reverse the T4 polynucleotide ligase joining reaction using 32-p-labelled (dA)n - [(DT)40]n/40 as substrate. No breakdown of this DNA could be detected. The joining reaction was inhibited by high concentrations, i.e. above approximately 70mM, of salts such as KCl, NaCl, NH4Cl and CsCl. At a concentration of 200 mM almost 100% inhibition was observed. Polyamines also caused inhibition of the enzyme, the most efficient inhibitor being spermine followed by spermidine. At a concentration of 1 mM spermine, virtually no joining took place. Addition of salts or polyamines resulted in a large increase in the apparent Km for the DNA substrate whereas the apparent Km for ATP remained unchanged. It is suggested that the affinity of the enzyme for the DNA substrate is decreased in the presence of inhibiting agents.     

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.     

A novel DNA joining activity catalyzed by T4 DNA ligase.

The use of T4 and E. coli DNA ligases in genetic engineering technology is usually associated with nick-closing activity in double stranded DNA or ligation of 'sticky-ends' to produce recombinant DNA molecules. We describe in this communication the ability of T4 DNA ligase to catalyze intramolecular loop formation between annealed oligodeoxyribonucleotides wherein Watson-Crick base pairing is absent on one side of the ligation site. Enzyme concentration, loop size, substrate specificity, and base composition were explored in an effort to maximize yield. Amounts of T4 DNA ligase in large molar excess to DNA template and ligated product are necessary to achieve high yields.     

A new procedure for the simultaneous large-scale purification of bacteriophage-T4-induced polynucleotide kinase, DNA ligase, RNA ligase and DNA polymerase

A procedure for simultaneous large-scale purification of the bacteriophage-T4-induced polynucleotide kinase, DNA ligase, RNA ligase and DNA polymerase has been developed. The method involves bacterial cell disruption by sonication, fractionation of cell extract with polymin P, salt elution from the polymin pellets, ammonium sulfate precipitation, and subsequent column chromatography purification of the enzymes. To enrich the enzyme content highly in the initial source non-permissive Escherichia coli B-23 cells infected with T4 amN82 phage were used. The procedure described is rapid, reproducible, high in yield, and able to handle preparations using from 1 g to 200 g cell paste. It can be easily scaled up. The method results in large amounts of the enzymes with very high specific activities, good stability essential lacking exonuclease and endonuclease contamination. The final enzyme preparations were efficiently used in DNA sequencing and in multiple experiments on construction of various recombinant DNAs for cloning and expression in vivo.     

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.     

Biomolecular response of oxanine in DNA strands to T4 polynucleotide kinase, T4 DNA ligase, and restriction enzymes

Oxanine (Oxa), generated from guanine (Gua) by NO- or HNO₂-induced nitrosative oxidation, has been thought to cause mutagenic problems in cellular systems. In this study, the response of Oxa to different enzymatic functions was explored to understand how similarly it can participate in biomolecular reactions compared to the natural base, Gua. The phosphorylation efficiency of the T4 polynucleotide kinase was highest when Oxa was located on the 5′-end of single stranded DNAs compared to when other nucleobases were in this position. The order of phosphorylation efficiency was as follows; Oxa > Gua > adenine (Ade) ∼ thymine (Thy) > cytosine (Cyt). Base-pairing of Oxa and Cyt (Oxa:Cyt) between the ligation fragment and template was found to influence the ligation performance of the T4 DNA ligase to a lesser degree compared to Gua:Cyt. In addition, EcoRI and BglII showed higher cleavage activities on DNA substrates containing Oxa:Cyt than those containing Gua:Cyt, while BamHI, HindIII and EcoRV showed lower cleavage activity; however, this decrease in activity was relatively small.