Your search keyword '"Li-Xin, Tian"' showing total 4 results

1. Positive and negative selection using the tetA-sacB cassette: recombineering and P1 transduction in Escherichia coli.

Author

Li XT, Thomason LC, Sawitzke JA, Costantino N, and Court DL

Subjects

Culture Media, Escherichia coli Proteins genetics, Gene Fusion, Sucrose metabolism, Antiporters genetics, Bacterial Proteins genetics, Escherichia coli genetics, Genetic Engineering methods, Hexosyltransferases genetics, Recombination, Genetic, Transduction, Genetic

Abstract

The two-step process of selection and counter-selection is a standard way to enable genetic modification and engineering of bacterial genomes using homologous recombination methods. The tetA and sacB genes are contained in a DNA cassette and confer a novel dual counter-selection system. Expression of tetA confers bacterial resistance to tetracycline (Tc(R)) and also causes sensitivity to the lipophillic chelator fusaric acid; sacB causes sensitivity to sucrose. These two genes are introduced as a joint DNA cassette into Escherichia coli by selection for Tc(R). A medium containing both fusaric acid and sucrose has been developed, in which, coexpression of tetA-sacB is orders of magnitude more sensitive as a counter-selection agent than either gene alone. In conjunction with the homologous recombination methods of recombineering and P1 transduction, this powerful system has been used to select changes in the bacterial genome that cannot be directly detected by other counter-selection systems.

Published

2013

2. Bacterial DNA polymerases participate in oligonucleotide recombination.

Author

Li XT, Thomason LC, Sawitzke JA, Costantino N, and Court DL

Subjects

Bacteriophage lambda genetics, DNA Ligase ATP, DNA Ligases metabolism, Escherichia coli genetics, DNA Polymerase I metabolism, DNA Polymerase III metabolism, DNA, Bacterial metabolism, Escherichia coli enzymology, Oligonucleotides metabolism, Recombination, Genetic

Abstract

Synthetic single-strand oligonucleotides (oligos) with homology to genomic DNA have proved to be highly effective for constructing designed mutations in targeted genomes, a process referred to as recombineering. The cellular functions important for this type of homologous recombination have yet to be determined. Towards this end, we have identified Escherichia coli functions that process the recombining oligo and affect bacteriophage λ Red-mediated oligo recombination. To determine the nature of oligo processing during recombination, each oligo contained multiple nucleotide changes: a single base change allowing recombinant selection, and silent changes serving as genetic markers to determine the extent of oligo processing during the recombination. Such oligos were often not incorporated into the host chromosome intact; many were partially degraded in the process of recombination. The position and number of these silent nucleotide changes within the oligo strongly affect both oligo processing and recombination frequency. Exonucleases, especially those associated with DNA Polymerases I and III, affect inheritance of the silent nucleotide changes in the oligos. We demonstrate for the first time that the major DNA polymerases (Pol I and Pol III) and DNA ligase are directly involved with oligo recombination., (Published 2013. This article is a U.S. Government work and is in the public domain in the USA.)

Published

2013

3. Probing cellular processes with oligo-mediated recombination and using the knowledge gained to optimize recombineering.

Author

Sawitzke JA, Costantino N, Li XT, Thomason LC, Bubunenko M, Court C, and Court DL

Subjects

Escherichia coli growth & development, Escherichia coli metabolism, Plasmids, DNA Repair, DNA Replication, DNA, Single-Stranded genetics, Escherichia coli genetics, Oligonucleotides pharmacology, Recombination, Genetic

Abstract

Recombination with single-strand DNA oligonucleotides (oligos) in Escherichia coli is an efficient and rapid way to modify replicons in vivo. The generation of nucleotide alteration by oligo recombination provides novel assays for studying cellular processes. Single-strand exonucleases inhibit oligo recombination, and recombination is increased by mutating all four known exonucleases. Increasing oligo concentration or adding nonspecific carrier oligo titrates out the exonucleases. In a model for oligo recombination, λ Beta protein anneals the oligo to complementary single-strand DNA at the replication fork. Mismatches are created, and the methyl-directed mismatch repair (MMR) system acts to eliminate the mismatches inhibiting recombination. Three ways to evade MMR through oligo design include, in addition to the desired change (1) a C·C mismatch 6 bp from that change; (2) four or more adjacent mismatches; or (3) mismatches at four or more consecutive wobble positions. The latter proves useful for making high-frequency changes that alter only the target amino acid sequence and even allows modification of essential genes. Efficient uptake of DNA is important for oligo-mediated recombination. Uptake of oligos or plasmids is dependent on media and is 10,000-fold reduced for cells grown in minimal versus rich medium. Genomewide engineering technologies utilizing recombineering will benefit from both optimized recombination frequencies and a greater understanding of how biological processes such as DNA replication and cell division impact recombinants formed at multiple chromosomal loci. Recombination events at multiple loci in individual cells are described here., (Published by Elsevier Ltd.)

Published

2011

4. Identification of factors influencing strand bias in oligonucleotide-mediated recombination in Escherichia coli.

Author

Li XT, Costantino N, Lu LY, Liu DP, Watt RM, Cheah KS, Court DL, and Huang JD

Subjects

Adenosine Triphosphatases genetics, Amino Acid Sequence, Bacterial Proteins genetics, Base Pair Mismatch, Base Sequence, DNA Repair, DNA, Single-Stranded genetics, DNA, Single-Stranded metabolism, DNA-Binding Proteins genetics, Endodeoxyribonucleases genetics, Escherichia coli Proteins genetics, Molecular Sequence Data, MutL Proteins, MutS DNA Mismatch-Binding Protein, Mutation, Oligonucleotides genetics, Plasmids genetics, Signal Transduction genetics, Transcription, Genetic genetics, DNA Repair Enzymes, Escherichia coli genetics, Oligonucleotides metabolism, Recombination, Genetic

Abstract

Recombinogenic engineering methodology, also known as recombineering, utilizes homologous recombination to create targeted changes in cellular DNA with great specificity and flexibility. In Escherichia coli, the Red recombination system from bacteriophage lambda has been used successfully to modify both plasmid and chromosomal DNA in a highly efficient manner, using either a linear double-stranded DNA fragment or a synthetic single-stranded oligonucleotide (SSO). The current model for Red/SSO-mediated recombination involves the SSO first annealing to a transient, single-stranded region of DNA before being incorporated into the chromosome or plasmid target. It has been observed previously, in both eukaryotes and prokaryotes, that mutations in the two strands of the DNA double helix are 'corrected' by complementary SSOs with differing efficiencies. Here we investigate further the factors that influence the strand bias as well as the overall efficiency of Red/SSO-mediated recombination in E.coli. We show that the direction of DNA replication and the nature of the SSO-encoded mismatch are the main factors dictating the recombinational strand bias. However, the influence that the SSO-encoded mismatch exerts upon the recombinational strand bias is abolished in E.coli strains that are defective in mismatch repair (MMR). This reflects the fact that different base-base mispairs are corrected by the mutS/H/L-dependent MMR pathway with differing efficiencies. Furthermore, our data indicate that transcription has negligible influence on the strand bias. These results demonstrate for the first time that the interplay between DNA replication and MMR has a major effect on the efficiency and strand bias of Red/SSO-mediated recombination in E.coli.

Published

2003