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. 1986 Nov 25;14(22):8905–8917. doi: 10.1093/nar/14.22.8905

Deletion and rearrangement of plasmid DNA during transformation of Escherichia coli with linear plasmid molecules.

E C Conley, V A Saunders, J R Saunders
PMCID: PMC311919  PMID: 3024124

Abstract

When E. coli was transformed with linearized pBR322 DNA, many transformants contained recircularized plasmids bearing deletions and other rearrangements. Most aberrant molecules were less than monomeric length and had lost the restriction site used for linearization, with the deleted region extending mono- (type Ia) or bi-directionally (type Ib). Type II deletants were greater than monomeric but less than dimeric and contained the pBR322 sequence in direct repeat with deletion at one or both junctions (type IIa) or in inverted repeat with loss of sequence at both junctions (type IIb). Type III deletants were greater than dimeric but less than trimeric, consisting of pBR322 sequences in both direct and inverse repeat with deletions at two or more junctions. Transformation frequencies for linear DNA were drastically reduced in xth-1- bacteria with type IIb deletants predominating in transformants. This indicates that exonuclease III is important for perfect recyclization of plasmids and the generation of type I deletants. In vivo recyclization of in vitro ligation products explains many of the aberrant DNA molecules that are encountered during gene cloning.

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Selected References

These references are in PubMed. This may not be the complete list of references from this article.

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