Yosuke Hirayama scite author profile

ABSTRACTFunctional analysis ofBifidobacteriumgenes is essential for understanding host-Bifidobacteriuminteractions with beneficial effects on human health; however, the lack of an effective targeted gene inactivation system in bifidobacteria has prevented the development of functional genomics in this bacterium. Here, we report the development of a markerless gene deletion system involving a double crossover inBifidobacterium longum. Incompatible plasmid vectors were used to facilitate a second crossover step. The conditional replication vector pBS423-ΔrepA, which lacks the plasmid replication generepA, was integrated into the target gene by a first crossover event. Subsequently, the replicative plasmid pTBR101-CM, which harborsrepA, was introduced into this integrant to facilitate the second crossover step and subsequent elimination of the excised conditional replication vector from the cells by plasmid incompatibility. The proposed system was confirmed to work as expected inB. longum105-A using the chromosomal full-length β-galactosidase gene as a target. Markerless gene deletion was tested using theagagene, which encodes α-galactosidase, whose substrates include raffinose. Almost all the pTBR101-CM-transformed strains became double-crossover recombinants after subculture, and 4 out of the 270 double-crossover recombinants had lost the ability to assimilate raffinose. Genotype analysis of these strains revealed markerless gene deletion ofaga. Carbohydrate assimilation analysis and α-galactosidase activity measurement were conducted using both the representative mutant and a plasmid-basedaga-complemented strain. These functional analyses revealed thatagais the only gene encoding a functional α-galactosidase enzyme inB. longum105-A.

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Functional analysis of bifidobacterial promoters in Bifidobacterium longum and Escherichia coli using the α-galactosidase gene as a reporter

Sakanaka

Tamai

Hirayama

et al. 2014

Journal of Bioscience and Bioengineering

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Technological Advances in Bifidobacterial Molecular Genetics: Application to Functional Genomics and Medical Treatments

Fukiya

Hirayama

Sakanaka

et al. 2012

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Bifidobacteria are well known as beneficial intestinal bacteria that exert health-promoting effects in humans. In addition to physiological and immunological investigations, molecular genetic technologies have been developed and have recently started to be applied to clarify the molecular bases of host-Bifidobacterium interactions. These technologies include transformation technologies and Escherichia coli-Bifidobacterium shuttle vectors that enable heterologous gene expression. In this context, a plasmid artificial modification method that protects the introduced plasmid from the restriction system in host bifidobacteria has recently been developed to increase transformation efficiency. On the other hand, targeted gene inactivation systems, which are vital for functional genomics, seemed far from being practically applicable in bifidobacteria. However, remarkable progress in this technology has recently been achieved, enabling functional genomics in bifidobacteria. Integrated use of these molecular genetic technologies with omics-based analyses will surely boost characterization of the molecular basis underlying beneficial effects of bifidobacteria. Applications of recombinant bifidobacteria to medical treatments have also progressed.

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Isolation and transposition properties of ISBlo11, an active insertion sequence belonging to the IS3 family, from Bifidobacterium longum 105-A

Sakanaka

Fukiya

Kobayashi

et al. 2015

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Transposon mutagenesis systems are still under development in bifidobacteria, partly because intrinsic active insertion sequences are not well characterized in bifidobacteria. Here, we isolated an active insertion sequence, ISBlo11, from Bifidobacterium longum 105-A using a sacB-based counterselection system, which is generally used to screen for active insertion sequences from bacterial genomes. ISBlo11 is 1432 bp long and belongs to the IS3 family. It has a single ORF encoding a transposase and 25-bp inverted repeats at its termini. Full-length copies of ISBlo11 are specifically conserved among certain B. longum genomes and exist in different sites. Transposition analysis of an artificial ISBlo11 transposon using an Escherichia coli conjugation system revealed that ISBlo11 has adequate transposition activity, comparable to the reported activity of IS629, another IS3 family element initially isolated from Shigella sonnei. ISBlo11 also showed low transposition selectivity for non-conserved 3- or 4-bp target sequences. These characteristics of ISBlo11 seem suitable for the development of a new transposon mutagenesis system in bifidobacteria.

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Yosuke Hirayama

Development of a Double-Crossover Markerless Gene Deletion System in Bifidobacterium longum: Functional Analysis of the α-Galactosidase Gene for Raffinose Assimilation

Functional analysis of bifidobacterial promoters in Bifidobacterium longum and Escherichia coli using the α-galactosidase gene as a reporter

Technological Advances in Bifidobacterial Molecular Genetics: Application to Functional Genomics and Medical Treatments

Isolation and transposition properties of ISBlo11, an active insertion sequence belonging to the IS3 family, from Bifidobacterium longum 105-A

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