Biased Gene Conversion in Rhizobium etli Is Caused by Preferential Double-Strand Breaks on One of the Recombining Homologs

ABSTRACTGene conversion, the nonreciprocal transfer of information during homologous recombination, is the main process that maintains identity between members of multigene families. Gene conversion in the nitrogenase (nifH) multigene family ofRhizobium etliwas analyzed by using a two-plasmid system, where each plasmid carried a copy ofnifH. One of thenifHcopies was modified, creating restriction fragment length polymorphisms (RFLPs) spaced along the gene. Once the modified plasmid was introduced intoR. etli, selection was done for cointegration with a resident plasmid lacking the RFLPs. Most of the cointegrate molecules harbor gene conversion events, biased toward a gain of RFLPs. This bias may be explained under the double-strand break repair model by proposing that thenifHgene lacking the RFLPs suffers a DNA double-strand break, so the incoming plasmid functions as a template for repairing the homolog on the resident plasmid. To support this proposal, we cloned an SceI site into thenifHhomolog that had the RFLPs used for scoring gene conversion.In vivoexpression of the meganuclease I-SceI allowed the generation of a double-strand break on this homolog. Upon introduction of this modified plasmid into anR. etlistrain lacking I-SceI, biased gene conversion still favored the retention of markers on the incoming plasmid. In contrast, when the recipient strain ectopically expressed I-SceI, a dramatic reversal in gene conversion bias was seen, favoring the preservation of resident sequences. These results show that biased gene conversion is caused by preferential double-strand breaks on one of the recombining homologs.IMPORTANCEIn this work, we analyzed gene conversion by using a system that entails horizontal gene transfer followed by homologous recombination in the recipient cell. Most gene conversion events are biased toward the acquisition of the incoming sequences, ranging in size from 120 bp to 800 bp. This bias is due to preferential cutting of resident DNA and can be reversed upon introduction of a double-strand break on the incoming sequence. Since conditions used in this work are similar to those in horizontal gene transfer, it provides evidence that, upon transfer, the resident DNA preferentially acquires gene variants.

Genetic Method To Analyze Essential Genes of Escherichia coli

ABSTRACT The genetic analysis of essential genes has been generally restricted to the use of conditional mutations, or inactivating chromosomal mutations, which require a complementing plasmid that must either be counterselected or lost to measure a phenotype. These approaches are limited because they do not permit the analysis of mutations suspected to affect a specific function of a protein, nor do they take advantage of the increasing abundance of structural and bioinformatics data for proteins. Using the dnaC gene as an example, we developed a genetic method that should permit the mutational analysis of other essential genes of Escherichia coli and related enterobacteria. The method consists of using a strain carrying a large deletion of the dnaC gene, which is complemented by a wild-type copy expressed from a plasmid that requires isopropyl-β-d-thiogalactopyranoside for maintenance. Under conditions in which this resident plasmid is lost, the method measures the function of a dnaC mutation encoded by a second plasmid. This methodology should be widely applicable to the genetic analysis of other essential genes.

Mobilization, Cloning, and Sequence Determination of a Plasmid-Encoded Polygalacturonase from a Phytopathogenic Burkholderia (Pseudomonas) cepacia

Phytopathogenic strains of Burkholderia cepacia (synonym Pseudomonas cepacia) produce endopolygalacturonase, whereas strains of clinical and soil origin do not. Growth of a phytopathogenic strain (ATCC25416) at elevated temperatures resulted in nonpectolytic derivatives that were either cured of a resident plasmid or contained a plasmid of reduced mass. The resident 200-kb plasmid (pPEC320) in strain ATCC25416 was tagged with Tn5-Mob. The pPEC320∷Tn5-Mob (pPEC321) plasmid was mobilized in B. cepacia strains of soil and clinical origin. Transconjugants containing pPEC321 expressed the endopolygalac-turonase and showed differential activity on plant tissue. No evidence for self-transfer of pPEC320 or the tagged derivative was observed. A 2.85-kb cloned fragment from pPEC320 containing the plasmid-borne pehA gene was sequenced and compared to the pehA gene from Erwinia carotovora subsp. carotovora and Ralstonia solanacearum and the polygalacturonase sequence from Lycopersicon esculentum.