Kinetics and Effect of Salts and Polyamines on T4 Polynucleotide Ligase

Raae, Arnt J.; Kleppe, Ruth K.; Kleppe, Kjell

doi:10.1111/j.1432-1033.1975.tb21021.x

Cited by 61 publications

(37 citation statements)

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“…In the past, the pyrophosphate exchange reaction catalyzed by these enzymes have been studied, and the apparent K m values for ATP in the DNA-joining reaction on different DNA substrates have been determined (4,5,8,9). X-ray structures of the related enzymes, T7 DNA ligase and mRNA capping enzyme from Chlorella virus PBCV-1 in complex with the nucleoside triphosphate as well as the enzyme-adenylylate complex of DNA ligase from Chlorella virus PBCV-1 have been solved (10 -12).…”

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Kinetic Mechanism of the Mg2+-dependent Nucleotidyl Transfer Catalyzed by T4 DNA and RNA Ligases

Cherepanov

Vries

2002

Journal of Biological Chemistry

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The Mg 2؉ -dependent adenylylation of the T4 DNA and RNA ligases was studied in the absence of a DNA substrate using transient optical absorbance and fluorescence spectroscopy. The concentrations of Mg 2؉ , ATP, and pyrophosphate were systematically varied, and the results led to the conclusion that the nucleotidyl transfer proceeds according to a two-metal ion mechanism. According to this mechanism, only the di-magnesiumcoordinated form Mg 2 ATP 0 reacts with the enzyme forming the covalent complex E⅐AMP. DNA and RNA ligases from the bacteriophage T4 are ATPdependent enzymes that catalyze the formation of the phosphodiester bond between the adjacent 3Ј-OH and 5Ј-PO 4 ends of two nucleic acid fragments. The first step of catalysis requires a divalent metal cofactor and consists of the binding of ATP with the subsequent formation of the ligase-AMP complex and the release of pyrophosphate (1, 2). This reaction is reversible (3-5). In the bound state the ␣-phosphate of the nucleotide is attached to a conserved lysine residue of the enzyme, forming an (⑀-amino)-linked adenosine monophosphoramidate (6, 7).Although the T4 DNA ligase (EC 6.5.1.1) and T4 RNA ligase (EC 6.5.1.3) have been first purified more than 30 years ago, relatively few studies have been performed on the interaction between the ligase, ATP, pyrophosphate, and Mg 2ϩ . In the past, the pyrophosphate exchange reaction catalyzed by these enzymes have been studied, and the apparent K m values for ATP in the DNA-joining reaction on different DNA substrates have been determined (4,5,8,9). X-ray structures of the related enzymes, T7 DNA ligase and mRNA capping enzyme from Chlorella virus PBCV-1 in complex with the nucleoside triphosphate as well as the enzyme-adenylylate complex of DNA ligase from Chlorella virus PBCV-1 have been solved (10 -12). It was shown that the nucleotide is oriented in the binding cleft of the ligase by stacking interactions and by hydrogen bonding with the adenine ring, the ribose moiety, and the ␣-phosphate. However, the position of the metal cofactor in complex with the nucleoside triphosphate and ligase or its stoichiometry remained unknown.A steady-state kinetic analysis of the nucleotidyl transfer reaction catalyzed by T4 RNA ligase has been performed by previous researchers (13). On the basis of isotope equilibration studies of the Mg 2ϩ -dependent pyrophosphate exchange reaction, these authors proposed a two-metal ion mechanism in which the di-magnesium-coordinated forms of ATP and pyrophosphate would be the true catalytic substrates.In this report we present a pre-steady-state kinetic analysis of the interactions of T4 DNA ligase and T4 RNA ligase with ATP, pyrophosphate, and Mg 2ϩ . By varying the experimental conditions we were able to isolate individual steps of the binding reaction. Using dATP and dCTP instead of ATP we could observe the nucleotide-binding step without the subsequent covalent attachment of the nucleotide to the ligase. In the case of ATP, addition of pyrophosphate to the reaction mixture allowed us to s...

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Kinetic Mechanism of the Mg2+-dependent Nucleotidyl Transfer Catalyzed by T4 DNA and RNA Ligases

Cherepanov

Vries

2002

Journal of Biological Chemistry

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“…In the present work, the action of Tq polynucleotide ligase on synthetic triple-stranded DNAs has been investigated. In a previous publication from this laboratory, the mechanism of action of T4 polynucleotide ligase on synthetic double-stranded DNA has been described in detail (Raae et al, 1975a). The results of the present work suggest that this enzyme can also carry out joining of phosphodiester linkages on some triplestranded nucleic acids.…”

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confidence: 57%

“…W e have previously shown that low concentrations of the polyamines putrescine, cadaverine, and TiME ( m i d spermidine (up to 1 mM) give a small activation of T4 polynucleotide ligase catalyzed joining of dTlo in a double-stranded substrate (Raae et al, 1975a). A t higher concentrations, however, a marked inhibition was obtained.…”

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confidence: 97%

“…Using the equation obtained for native double-stranded DNA, relating sedimentation coefficient to molecular weight, ~2 0 ,~ = 0.0882M0.346 (Studier, 1965), a molecular weight of 1.08 X lo6 was obtained for the peak fraction of the 1 :I complex. Assuming that the same equation also is valid for a triple-stranded DNA, the molecular weight of the peak fraction a : 0 2 a The analvses were carried out essentiallv as described bv Raae et al (1975a).…”

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confidence: 99%

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T₄ polynucleotide ligase catalyzed joining on triple-stranded nucleic acids

Raae¹,

Kleppe²

1978

Biochemistry

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dT1O will form triple-stranded complexes with dAn and these complexes can serve as substrate for T4 polynucleotide ligase (EC 6.5.1.1). The rate of phosphodiester formation was found to be approximately the same as for the double-stranded complex and, furthermore, the rate appears to be similar on the two strands in the complex. Joining of dT1O also took place in the presence of the double-stranded complexes dAn.dTn and dAn.rUn. Polyamines increase the rate of joining catalyzed by T4 polynucleotide ligase under certain conditions.

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“…These occur not only under the influence of polyamines or polyanions such as heparin (9,11,12), but also when the reactions are subjected to promoters, repressors, and other physiologically important factors (7,13,14). One can postulate that most of the protein factors behave as polyelectrolytes, promoting and suffering from modifications of the local electrostatic potential and therefore of the local concentration of protons, pKs(4,) and, finally, catalytic activity.…”

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Ionic regulation in genetic translation systems.

Douzou¹,

Maurel²

1977

Proc. Natl. Acad. Sci. U.S.A.

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The polyelectrolyte theory can provide an interpretation of the interdependence of pH, ionic strength, and polyamines one observes in the activity of ribonuclease acting on RNA. According to this theory:(i) A nucleic acid-enzyme complex and the suspending medium may be considered as two phases in equilibrium, even though within limits, the complex is soluble in water.(ii) The enzymatic catalysis is under tight control of the electrostatic potential generated by the system. Consequently, modification in electrostatic potential will induce a concomitant change in activity.(iii) The electrostatic potential can be modified through action on the system of "modulators", either "external" (ionic strength, pH, temperature, etc.) or "internal" (specific ligands, substrates, protein factors, etc.).Similarities between the reaction of ribonuclease (ribonucleate 3'-pyrimidino-oligonucdeotidohydrolase; EC 3.1.4.22) and RNA and those observed with highly organized systems catalyzing DNA, RNA, and protein synthesis suggest that the electrostatic potential also provides an important regulatory mechanism in genetic translation. In this view, an essential function of nucleic acids is to provide their enzyme partners with polyanionic microenvironments within which their catalytic activities are controlled by variation in physicochemical parameters, including the proton concentration induced through "modulation" of the local electrostatic potential.The ionic environment plays an essential role in promoting and maintaining functional states of highly organized systems for genetic translation. Relatively mild changes following the addition of mono-, di-, and even polyvalent cations markedly affect activity. Activity response to ionic strength can be of two general types. As indicated in Fig. 1 We became familiar with the "catalytic implications of electrostatic potentials" in studying the characteristic behavior of several enzyme systems functioning within polyanionic environments on biomembranes and felt that they could be of interest for the investigation of the systems for genetic translation (1, 2). 1013The common features of such systems include the close interaction of their functional and/or structural proteins with polyanions such as DNA template, mRNA, and tRNA. According to the polyelectrolyte theory, these polyanions promote, in their immediate vicinity, strong electrostatic potentials that can be modulated and that are important at the level of protein and/or enzyme activity. The hydrolysis of RNA by ribonuclease A provides a simplified model that allows successful interpretation in qualitative terms of the characteristic responses depicted in Fig. 1. We could furthermore monitor the conversion of type I into type II using the polyamines, spermidine and putrescine that specifically bind nucleic acids as "internal modulators".This preliminary paper will be followed by a detailed report published elsewhere.MATERIALS AND METHODS Materials. Ribonuclease (type IA) (ribonucleate 3'-pyrimidino-oligonucleotidohydrolase; E...

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Kinetics and Effect of Salts and Polyamines on T4 Polynucleotide Ligase

Cited by 61 publications

References 21 publications

Kinetic Mechanism of the Mg2+-dependent Nucleotidyl Transfer Catalyzed by T4 DNA and RNA Ligases

Kinetic Mechanism of the Mg2+-dependent Nucleotidyl Transfer Catalyzed by T4 DNA and RNA Ligases

T₄ polynucleotide ligase catalyzed joining on triple-stranded nucleic acids

Ionic regulation in genetic translation systems.

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Kinetics and Effect of Salts and Polyamines on T4 Polynucleotide Ligase

Cited by 61 publications

References 21 publications

Kinetic Mechanism of the Mg2+-dependent Nucleotidyl Transfer Catalyzed by T4 DNA and RNA Ligases

Kinetic Mechanism of the Mg2+-dependent Nucleotidyl Transfer Catalyzed by T4 DNA and RNA Ligases

T4 polynucleotide ligase catalyzed joining on triple-stranded nucleic acids

Ionic regulation in genetic translation systems.

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T₄ polynucleotide ligase catalyzed joining on triple-stranded nucleic acids