Yuhui Du scite author profile

Background Members of the genus Bacillus are important plant growth-promoting rhizobacteria that serve as biocontrol agents. Bacillus paralicheniformis MDJK30 is a PGPR isolated from the peony rhizosphere and can suppress plant-pathogenic bacteria and fungi. To further uncover the genetic mechanism of the plant growth-promoting traits of MDJK30 and its closely related strains, we used comparative genomics to provide insights into the genetic diversity and evolutionary relationship between B. paralicheniformis and B. licheniformis. Results A comparative genomics analysis based on B. paralicheniformis MDJK30 and 55 other previously reported Bacillus strains was performed. The evolutionary position of MDJK30 and the evolutionary relationship between B. paralicheniformis and B. licheniformis were evaluated by studying the phylogeny of the core genomes, a population structure analysis and ANI results. Comparative genomic analysis revealed various features of B. paralicheniformis that contribute to its commensal lifestyle in the rhizosphere, including an opening pan genome, a diversity of transport and the metabolism of the carbohydrates and amino acids. There are notable differences in the numbers and locations of the insertion sequences, prophages, genomic islands and secondary metabolic synthase operons between B. paralicheniformis and B. licheniformis . In particular, we found most gene clusters of Fengycin, Bacitracin and Lantipeptide were only present in B. paralicheniformis and were obtained by horizontal gene transfer (HGT), and these clusters may be used as genetic markers for distinguishing B. paralicheniformis and B. licheniformis . Conclusions This study reveals that MDJK30 and the other strains of lineage paralicheniformis present plant growth-promoting traits at the genetic level and can be developed and commercially formulated in agriculture as PGPR. Core genome phylogenies and population structure analysis has proven to be a powerful tool for differentiating B. paralicheniformis and B. licheniformis . Comparative genomic analyses illustrate the genetic differences between the paralicheniformis-licheniformis group with respect to rhizosphere adaptation. Electronic supplementary material The online version of this article (10.1186/s12864-019-5646-9) contains supplementary material, which is available to authorized users.

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Genome shuffling of Lactococcus lactis subspecies lactis YF11 for improving nisin Z production and comparative analysis

Zhang¹,

Liu²,

et al. 2014

Journal of Dairy Science

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Nisin has been widely used in the food industry as a safe and natural preservative to increase the shelf time of many foods. In this study, genome shuffling was applied to improve nisin Z production of Lactococcus lactis ssp. lactis YF11 (YF11) via recursive protoplast fusion. Ultraviolet irradiation and diethyl sulfate mutagenesis were used to generate parental strains for genome shuffling. After 4 rounds of genome shuffling, the best-performing strain F44 was obtained, which showed dramatic improvements in tolerance to both glucose (ranging from 8 to 15% (wt/vol) and nisin (ranging from 5,000 to 14,000 IU/mL). Fed-batch fermentation showed that the nisin titer of F44 was up to 4,023 IU/mL, which was 2.4 times that of the starting strain YF11. Field emission scanning electron microscope micrographs of YF11 and F44 revealed the apparent differences in cell morphology. Whereas YF11 displayed long and thin cell morphology, F44 cells were short and thick and with a raised surface in the middle of the cell. With the increasing glucose and nisin content in the medium, cells of both YF11 and F44 tended to become shrunken; however, alterations in YF11 cells were more pronounced than those of F44 cells, especially when cultured in tolerance medium containing both nisin and glucose. Nuclear magnetic resonance analysis demonstrated that the structure of nisin from YF11 and F44 was the same. Expression profiling of nisin synthesis related genes by real-time quantitative PCR showed that the transcription level of nisin structural gene nisZ and immunity gene nisI of F44 was 48 and 130% higher than that of the starting strain YF11, respectively. These results could provide valuable insights into the molecular basis underlying the nisin overproduction mechanism in L. lactis, thus facilitating the future construction of industrial strains for nisin production.

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Yuhui Du

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Comparative genomic analysis of Bacillus paralicheniformis MDJK30 with its closely related species reveals an evolutionary relationship between B. paralicheniformis and B. licheniformis

Genome shuffling of Lactococcus lactis subspecies lactis YF11 for improving nisin Z production and comparative analysis

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