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Role of Exonuclease and β Protein of Phage λ in Genetic Recombination, V. Recombination of λ DNA in Vitro

Role of Exonuclease and β Protein of Phage λ in Genetic Recombination, V. Recombination of λ... The sequential action of λ exonuclease and polynucleotide ligase upon redundant joint molecules is sufficient to produce intact polynucleotide chains and heat-stable, biologically active molecules of λ DNA, whereas the action of ligase alone is insufficient. These results (a) confirm the previously described mechanism of single-strand assimilation, including a subsidiary mechanism by which the further action of λ exonuclease is arrested when a redundant strand is completely assimilated, and (b) represent a simulation of the steps in genetic recombination that follow the formation of biparental complexes (synapsis). λ exonuclease is postulated to catalyze a concerted reaction that includes exposure of complementary sequences, formation of heteroduplex regions, and elimination of redundant branches. http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png Proceedings of the National Academy of Sciences PNAS

Role of Exonuclease and β Protein of Phage λ in Genetic Recombination, V. Recombination of λ DNA in Vitro

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Role of Exonuclease and β Protein of Phage λ in Genetic Recombination, V. Recombination of λ DNA in Vitro

Cassuto, Era; Lash, Terry; Sriprakash, K. S.; Radding, Charles M.
Proceedings of the National Academy of Sciences , Volume 68 (7): 1639 – Jul 1, 1971

Abstract

The sequential action of λ exonuclease and polynucleotide ligase upon redundant joint molecules is sufficient to produce intact polynucleotide chains and heat-stable, biologically active molecules of λ DNA, whereas the action of ligase alone is insufficient. These results (a) confirm the previously described mechanism of single-strand assimilation, including a subsidiary mechanism by which the further action of λ exonuclease is arrested when a redundant strand is completely assimilated, and (b) represent a simulation of the steps in genetic recombination that follow the formation of biparental complexes (synapsis). λ exonuclease is postulated to catalyze a concerted reaction that includes exposure of complementary sequences, formation of heteroduplex regions, and elimination of redundant branches.

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Publisher
PNAS
Copyright
Copyright ©2009 by the National Academy of Sciences
ISSN
0027-8424
eISSN
1091-6490
Publisher site
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Abstract

The sequential action of λ exonuclease and polynucleotide ligase upon redundant joint molecules is sufficient to produce intact polynucleotide chains and heat-stable, biologically active molecules of λ DNA, whereas the action of ligase alone is insufficient. These results (a) confirm the previously described mechanism of single-strand assimilation, including a subsidiary mechanism by which the further action of λ exonuclease is arrested when a redundant strand is completely assimilated, and (b) represent a simulation of the steps in genetic recombination that follow the formation of biparental complexes (synapsis). λ exonuclease is postulated to catalyze a concerted reaction that includes exposure of complementary sequences, formation of heteroduplex regions, and elimination of redundant branches.

Journal

Proceedings of the National Academy of SciencesPNAS

Published: Jul 1, 1971

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