Insertion Mutation of Play an Important Role in Resistance of to Mycobacteriophage SWU1.

Purpose: Phage is a new choice for the treatment of multi-drug-resistant bacteria, and phage resistance is also an issue of concern. SWU1 is a mycobacteriophage, and the mechanism of its resistance remain poorly understood.

Methods: The mutant strains which were stably resistant to SWU1 were screened by transposon mutation library. The stage of phage resistance was observed by transmission electron microscope (TEM). The insertion site of transposon was identified by thermal asymmetric interlaced PCR (TAIL-PCR). The possible relationship between insertion site and phage resistance was verified by gene knockout technique. The fatty acid composition of bacterial cell wall was analyzed by Gas Chromatography-Mass Spectrometer (GC-MS). Through the amplification and sequencing of target genes and gene complement techniques to find the mechanism of SWU1 resistance.

Results: The transposon mutant M12 which was stably resistant to mycobacteriophage SWU1 was successfully screened. It was confirmed that resistance occurred in the adsorption stage of bacteriophage. It was verified that the insertion site of the transposon was located in the gene, but after knocking out the gene in the wild type mc2 155, the resistance of the knockout strain to SWU1 was not observed. Through the amplification and sequencing of the target gene , it was found that there was an adenine insertion mutation at position 817. After complementing in M12, it was found that M12 returned to sensitivity to SWU1.

Conclusion: We confirmed that the resistance of M12 to SWU1 was related to the functional inactivation of and this phenomenon may be caused by the change of cell wall of .