ABSTRACT
Objective To construct a highly efficient approach to the introduction of the single-base mutation in a plasmid containing the adenovirus whole genome larger than 40 kb.Methods The target DNA with a mutation site was achieved by over-lapping PCR.The large plasmid with adenovirus genome and target DNA were co-transformed into Escherichia coli strain DY330 carrying a high rate Red recombination system.The positive clone was selected via colony PCR in combination with enzyme identification.The site-mutation large plasmid was transformed into E.coli strain DH10B in which the backbone of the large plasmid remained was stable.Results Two mutations were continuously introduced into the adenovirus genome,the location of which was pos.9171 and pos.24410 respectively.The integrality and stability of the plasmid backbone were verified by enzyme cutting identification.The two mutations on the plasmid were verified by DNA sequencing.Conclusion An efficient approach to the introduction of the single-base mutation in positions 9171 and 24410 from the adenovirus genome which was integrated into a plasmid is successfully established.The positive selection efficiency ranges from 5%to 15%.The construction of the approach will facilitate the study of adenovirus infection mechanism.
ABSTRACT
Red in vivo recombination is a new kind of genetic engineering technique based on homologous recombination. In this work, plasmid pKD46 which expresses Red recombination proteins is transferred into Escherichia coli strain DH5?.The kanamycine resistant gene is generated by PCR by using primers with homology to hisDCB gene of E.coli chromosome. Thus, the hisDCB gene was replaced with kanamycine resistant gene by the plasmid recombination system, then the resistant gene was eliminated by a helper plasmid encoding the FLP recombinase. At last, a E.coli histidine auxotroph which is sensitive to kanamycine was got. The results indicate that Red in vivo recombination is a convenient method to construct auxotrophs.