DNA Shuttling Between Plasmid Vectors and a Genome Vector: Systematic Conversion and Preservation of DNA Libraries Using the Bacillus subtilis Genome (BGM) Vector

Direct cloning strategies for large genomic fragments: A review

Mining large-scale functional regions of the genome helps to understand the essence of cellular life. The rapid accumulation of genomic information provides a wealth of material for genomic functional, evolutionary, and structural research. DNA cloning technology is an important tool for understanding, analyzing, and manipulating the genetic code of organisms. As synthetic biologists engineer greater and broader genetic pathways and expand their research into new organisms, efficient tools capable of manipulating large-scale DNA will offer momentum to the ability to design, modify, and construct engineering life. In this review, we discuss the recent advances in the field of direct cloning of large genomic fragments, particularly of 50-150 kb genomic fragments. We specifically introduce the technological advances in the targeted release and capture steps of these cloning strategies. Additionally, the applications of large fragment cloning in functional genomics and natural product mining are also summarized. Finally, we further discuss the challenges and prospects for these technologies in the future.

Development of a Bacillus subtilis genome vector system that can transmit synthesized genomes

Cloning of small DNA segments has been established using Escherichia coli plasmids. The cloned DNA can be transferred to various cells using transformation. In contrast, cloning of large DNA segments of more than several hundred kilobase pairs has been limited to the Bacillus subtilis genome cloning system. The advantage of giant DNA cloned by B. subtilis is that all kinds of gene editing can be implemented by the high and strict natural transformation ability of the host. However, the following transfer step of giant synthesized and edited genomes to different cell systems requires a special system by avoiding exposure in liquid. The use of a conjugational plasmid pLS20 that was developed for 20 years improves the B. subtilis genome vector establishment process from scratch. The use of the unique B. subtilis genome vector system from synthesis to transmitting genomes is now being manipulated and summarized for the first time.

Relationship between oriT length and efficiency of RP4-mediated conjugation from Escherichia coli to Gram-positive bacteria

In RP4 conjugation, approximately 350 bp of the origin of transfer (oriT) is required for transfer. Within this oriT, there are binding regions for the transfer-related proteins TraI, TraK, and TraJ. We investigated the influence of deleting each protein-binding region within oriT on transfer efficiency in Escherichia coli, Streptomyces lividans, and Bacillus subtilis. The deletion of the TraI-binding region completely abolished transfer in all species. The partial deletion of the TraK-binding region had a minimal impact when targeting but affected efficiency when targeting B. subtilis. The deletion of the TraJ-binding region completely abolished transfer in E. coli and B. subtilis but only reduced efficiency in S. lividans. This is the first report to investigate the influence of each region within oriT on transfer efficiency in S. lividans and B. subtilis, suggesting that the length of oriT required for effective RP4 conjugation varies when targeting Gram-positive bacteria.

Integrated conjugal plasmid pLS20 in the Bacillus subtilis genome produced 850-kbp circular subgenomes transmissible to another B. subtilis

Bacillus subtilis was engineered to produce circular subgenomes that are directly transmittable to another B. subtilis. The conjugational plasmid pLS20 integrated into the B. subtilis genome supported not only subgenome replication but also transmission to another B. subtilis species. The subgenome system developed in this study completes a streamlined platform from the synthesis to the transmission of giant DNA by B. subtilis.

Conversion of Escherichia coli into Mixotrophic CO2 Assimilation with Malate and Hydrogen Based on Recombinant Expression of 2-Oxoglutarate:Ferredoxin Oxidoreductase Using Adaptive Laboratory Evolution

We report the mixotrophic growth of Escherichia coli based on recombinant 2-oxoglutarate:ferredoxin oxidoreductase (OGOR) to assimilate CO₂ using malate as an auxiliary carbon source and hydrogen as an energy source. We employ a long-term (~184 days) two-stage adaptive evolution to convert heterotrophic E. coli into mixotrophic E. coli. In the first stage of evolution with serine, diauxic growth emerges as a prominent feature. At the end of the second stage of evolution with malate, the strain exhibits mixotrophy with CO₂ as an essential substrate for growth. We expect this work will open new possibilities in the utilization of OGOR for microbial CO₂ assimilation and future hydrogen-based electro-microbial conversion.

Manipulating ATP supply improves in situ CO2 recycling by reductive TCA cycle in engineered Escherichia coli

The reductive tricarboxylic acid (rTCA) cycle was reconstructed in Escherichia coli by introducing pGETS118KAFS, where kor (encodes α-ketoglutarate:ferredoxin oxidoreductase), acl (encodes ATP-dependent citrate lyase), frd (encodes fumarate reductase), and sdh (encodes succinate dehydrogenase) were tandemly conjugated by the ordered gene assembly in Bacillus subtilis (OGAB). E. coli MZLF (E. coli BL21(DE3) Δzwf, Δldh, Δfrd) was employed so that the C-2/C-1 [(ethanol + acetate)/(formate + CO₂)] ratio can be used to investigate the effectiveness of the recombinant rTCA for in situ CO₂ recycling. It has been shown that supplying ATP through the energy pump (the EP), where formate donates electron to nitrate to form ATP, elevates the C-2/C-1 ratio from 1.03 ± 0.00 to 1.49 ± 0.02. Similarly, when ATP production is increased by the introduction of the heterologous ethanol production pathway (pLOI295), the C-2/C-1 ratio further increased to 1.79 ± 0.02. In summary, the ATP supply is a rate-limiting step for in situ CO₂ recycling by the recombinant rTCA cycle. The decrease in C-1 is significant, but the destination of those recycled C-1 is yet to be determined.

Efficient delivery of large DNA from Escherichia coli to Synechococcus elongatus PCC7942 by broad-host-range conjugal plasmid pUB307

Synechococcus elongatus PCC7942, a cyanobacterium that uses light and carbon dioxide to grow, has a high ability to incorporate DNA by transformation. To assess the effective delivery of large DNA in plasmid form, we cloned the endogenous plasmid pANL (46.4 kbp) into a BAC vector of Escherichia coli. The plasmid p38ANL (54.3 kbp) replaced the native plasmid. To assess the delivery of larger DNA into PCC7942, p38ANL was fused to the broad-host-range conjugal transfer plasmid pUB307IP (53.5 kbp). The resulting plasmid pUB307IP501 (107.9 kbp) was transmitted from E. coli to PCC7942 by simple mixing of donor and recipient cultures. PCC7942 transcipients possessed only pUB307IP501, replacing the preexisting pANL. In contrast, the pUB307IP501 plasmid was unable to transform PCC7942, indicating that natural transformation of DNA may be restricted by size limitations. The ability to deliver large DNA by conjugation may lead to genetic engineering in PCC7942.

A Family of Single Copy repABC-Type Shuttle Vectors Stably Maintained in the Alpha-Proteobacterium Sinorhizobium meliloti

A considerable share of bacterial species maintains segmented genomes. Plant symbiotic α-proteobacterial rhizobia contain up to six repABC-type replicons in addition to the primary chromosome. These low or unit-copy replicons, classified as secondary chromosomes, chromids, or megaplasmids, are exclusively found in α-proteobacteria. Replication and faithful partitioning of these replicons to the daughter cells is mediated by the repABC region. The importance of α-rhizobial symbiotic nitrogen fixation for sustainable agriculture and Agrobacterium-mediated plant transformation as a tool in plant sciences has increasingly moved biological engineering of these organisms into focus. Plasmids are ideal DNA-carrying vectors for these engineering efforts. On the basis of repABC regions collected from α-rhizobial secondary replicons, and origins of replication derived from traditional cloning vectors, we devised the versatile family of pABC shuttle vectors propagating in Sinorhizobium meliloti, related members of the Rhizobiales, and Escherichia coli. A modular plasmid library providing the elemental parts for pABC vector assembly was founded. The standardized design of these vectors involves five basic modules: (1) repABC cassette, (2) plasmid-derived origin of replication, (3) RK2/RP4 mobilization site (optional), (4) antibiotic resistance gene, and (5) multiple cloning site flanked by transcription terminators. In S. meliloti, pABC vectors showed high propagation stability and unit-copy number. We demonstrated stable coexistence of three pABC vectors in addition to the two indigenous megaplasmids in S. meliloti, suggesting combinability of multiple compatible pABC plasmids. We further devised an in vivo cloning strategy involving Cre/lox-mediated translocation of large DNA fragments to an autonomously replicating repABC-based vector, followed by conjugation-mediated transfer either to compatible rhizobia or E. coli.

Release and Constancy of an Antibiotic Resistance Gene in Seawater under Grazing Stress by Ciliates and Heterotrophic Nanoflagellates

Extracellular DNA (exDNA) is released from bacterial cells through various processes. The antibiotic resistance genes (ARGs) coded on exDNA may be horizontally transferred among bacterial communities by natural transformation. We quantitated the released/leaked tetracycline resistance gene, tet(M) over time under grazing stress by ciliates and heterotrophic nanoflagellates (HNFs), and found that extracellular tet(M) (ex-tetM) increased with bacterial grazing. Separate microcosms containing tet(M)-possessing bacteria with ciliates or HNFs were prepared. The copy number of ex-tetM in seawater in the ciliate microcosm rapidly increased until 3 d after the incubation, whereas that in the HNF microcosm showed a slower increase until 20 d. The copy number of ex-tetM was stable in both cases throughout the incubation period, suggesting that extracellular ARGs are preserved in the environment, even in the presence of grazers. Additionally, ARGs in bacterial cells were constant in the presence of grazers. These results suggest that ARGs are not rapidly extinguished in a marine environment under grazing stress.

In vitro bioconversion of chitin to pyruvate with thermophilic enzymes

Chitin is the second most abundant organic compound on the planet and thus has been regarded as an alternative resource to petroleum feedstocks. One of the key challenges in the biological conversion of biomass-derived polysaccharides, such as cellulose and chitin, is to close the gap between optimum temperatures for enzymatic saccharification and microbial fermentation and to implement them in a single bioreactor. To address this issue, in the present study, we aimed to perform an in vitro, one-pot bioconversion of chitin to pyruvate, which is a precursor of a wide range of useful metabolites. Twelve thermophilic enzymes, including that for NAD⁺ regeneration, were heterologously produced in Escherichia coli and semi-purified by heat treatment of the crude extract of recombinant cells. When the experimentally decided concentrations of enzymes were incubated with 0.5 mg mL^-1 colloidal chitin (equivalent to 2.5 mM N-acetylglucosamine unit) and an adequate set of cofactors at 70°C, 0.62 mM pyruvate was produced in 5 h. Despite the use of a cofactor-balanced pathway, determination of the pool sizes of cofactors showed a rapid decrease in ATP concentration, most probably due to the thermally stable ATP-degrading enzyme(s) derived from the host cell. Integration of an additional enzyme set of thermophilic adenylate kinase and polyphosphate kinase led to the deceleration of ATP degradation, and the final product titer was improved to 2.1 mM.

Integrative bacterial artificial chromosomes for DNA integration into the Bacillus subtilis chromosome

Bacillus subtilis is a well-characterized model bacterium frequently used for a number of biotechnology and synthetic biology applications. Novel strategies combining the advantages of B. subtilis with the DNA assembly and editing tools of Escherichia coli are crucial for B. subtilis engineering efforts. We combined Gibson Assembly and λ red recombineering in E. coli with RecA-mediated homologous recombination in B. subtilis for bacterial artificial chromosome-mediated DNA integration into the well-characterized amyE target locus of the B. subtilis chromosome. The engineered integrative bacterial artificial chromosome iBAC(cav) can accept any DNA fragment for integration into B. subtilis chromosome and allows rapid selection of transformants by B. subtilis-specific antibiotic resistance and the yellow fluorescent protein (mVenus) expression. We used the developed iBAC(cav)-mediated system to integrate 10kb DNA fragment from E. coli K12 MG1655 into B. subtilis chromosome. iBAC(cav)-mediated chromosomal integration approach will facilitate rational design of synthetic biology applications in B. subtilis.

An inducible recA expression Bacillus subtilis genome vector for stable manipulation of large DNA fragments

BACKGROUND

The Bacillus subtilis genome (BGM) vector is a novel cloning system based on the natural competence that enables B. subtilis to import extracellular DNA fragments into the cell and incorporate the recombinogenic DNA into the genome vector by homologous recombination. The BGM vector system has several attractive properties, such as a megabase cloning capacity, stable propagation of cloned DNA inserts, and various modification strategies using RecA-mediated homologous recombination. However, the endogenous RecA activity may cause undesirable recombination, as has been observed in yeast artificial chromosome systems. In this study, we developed a novel BGM vector system of an inducible recA expression BGM vector (iREX), in which the expression of recA can be controlled by xylose in the medium.

RESULTS

We constructed the iREX system by introducing the xylose-inducible recA expression cassette followed by the targeted deletion of the endogenous recA. Western blot analysis showed that the expression of recA was strictly controlled by xylose in the medium. In the absence of xylose, recA was not expressed in the iREX, and the RecA-mediated recombination reactions were greatly suppressed. By contrast, the addition of xylose successfully induced RecA expression, which enabled the iREX to exploit the same capacities of transformation and gene modifications observed with the conventional BGM vector. In addition, an evaluation of the stability of the cloned DNA insert demonstrated that the DNA fragments containing homologous sequences were more stably maintained in the iREX by suppressing undesirable homologous recombination.

CONCLUSIONS

We developed a novel BGM vector with inducible recA expression system, iREX, which enables us to manipulate large DNA fragments more stably than the conventional BGM vector by suppressing undesirable recombination. In addition, we demonstrate that the iREX can be applied to handling the DNA, which has several homologous sequences, such as multiple-reporter expression cassettes. Thus, the iREX expands the utility of the BGM vector as a platform for engineering large DNA fragments.

Assembly and multiple gene expression of thermophilic enzymes in Escherichia coli for in vitro metabolic engineering

In vitro reconstitution of an artificial metabolic pathway is an emerging approach for the biocatalytic production of industrial chemicals. However, several enzymes have to be separately prepared (and purified) for the construction of an in vitro metabolic pathway, thereby limiting the practical applicability of this approach. In this study, genes encoding the nine thermophilic enzymes involved in a non-ATP-forming chimeric glycolytic pathway were assembled in an artificial operon and co-expressed in a single recombinant Escherichia coli strain. Gene expression levels of the thermophilic enzymes were controlled by their sequential order in the artificial operon. The specific activities of the recombinant enzymes in the cell-free extract of the multiple-gene-expression E. coli were 5.0-1,370 times higher than those in an enzyme cocktail prepared from a mixture of single-gene-expression strains, in each of which a single one of the nine thermophilic enzymes was overproduced. Heat treatment of a crude extract of the multiple-gene-expression cells led to the denaturation of indigenous proteins and one-step preparation of an in vitro synthetic pathway comprising only a limited number of thermotolerant enzymes. Coupling this in vitro pathway with other thermophilic enzymes including the H2 O-forming NADH oxidase or the malate/lactate dehydrogenase facilitated one-pot conversion of glucose to pyruvate or lactate, respectively.

Fermentation approach for enhancing 1-butanol production using engineered butanologenic Escherichia coli

In this study, engineered butanologenic Escherichia coli T5 constructed by the OGAB method was used for 1-butanol production. The results showed the feasibility of the artificial butanologenic operon, (Promoter Pr)-thil-crt-bcd-etfB-etfA-hbd-adhe1-adhe, where the 1-butanol titer, specific BuOH yield, and BuOH yield were 4.50 mg/L, 4.50 mg-BuOH/g cell, and 0.35 mg-BuOH/g-glucose, respectively. Fermentation conditions of anaerobic, low initial concentrations of carbon sources, low oxidation state of carbon source, pH of 6, addition of glutathione and citrate, had been shown for efficiently improving the 1-butanol production. The premise behind these fermentation approaches can be categorized into two lines of reasoning, either elevated the availability of acetyl-CoA or lowered the intracellular redox state. By comparing the fermentation conditions tested in this study, pH has been shown to be the most efficiency strategies for 1-butanol production while the replacement of glucose with glycerol provides the highest improvement in butanol yield.

Bacillus subtilis genome vector-based complete manipulation and reconstruction of genomic DNA for mouse transgenesis

Background

The Bacillus subtilis genome (BGM) vector is a novel cloning system for large DNA fragments, in which the entire 4.2 Mb genome of B. subtilis functions as a vector. The BGM vector system has several attractive properties, such as a large cloning capacity of over 3 Mb, stable propagation of cloned DNA and various modification strategies using RecA-mediated homologous recombination. However, genetic modifications using the BGM vector system have not been fully established, and this system has not been applied to transgenesis. In this study, we developed important additions to the genetic modification methods of the BGM vector system. To explore the potential of the BGM vector, we focused on the fish-like odorant receptor (class I OR) gene family, which consists of 158 genes and forms a single gene cluster. Although a cis-acting locus control region is expected to regulate transcription, this has not yet been determined experimentally.

Results

Using two contiguous bacterial artificial chromosome clones containing several class I OR genes, we constructed two transgenes in the BGM vector by inserting a reporter gene cassette into one class I OR gene. Because they were oriented in opposite directions, we performed an inversion modification to align their orientation and then fused them to enlarge the genomic structure. DNA sequencing revealed that no mutations occurred during gene manipulations with the BGM vector. We further demonstrated that the modified, reconstructed genomic DNA fragments could be used to generate transgenic mice. Transgenic mice carrying the enlarged transgene recapitulated the expression and axonal projection patterns of the target class I OR gene in the main olfactory system.

Conclusion

We offer a complete genetic modification method for the BGM vector system, including insertion, deletion, inversion and fusion, to engineer genomic DNA fragments without any trace of modifications. In addition, we demonstrate that this system can be used for mouse transgenesis. Thus, the BGM vector system can be an alternative platform for engineering large DNA fragments in addition to conventional systems such as bacterial and yeast artificial chromosomes. Using this system, we provide the first experimental evidence of a cis-acting element for a class I OR gene.

Serial assembly of Thermus megaplasmid DNA in the genome of Bacillus subtilis 168: a BAC-based domino method applied to DNA with a high GC content

Bacillus subtilis is the only bacterium-based host able to clone giant DNA above 1000 kbp. DNA previously handled by this host was limited to that with GC content similar to or lower than that of the B. subtilis genome. To expand the target DNA range to higher GC content, we tried to clone a pTT27 megaplasmid (257 kbp, 69% of G+C) from Thermus thermophilus. To facilitate the reconstruction process, we subcloned pTT27 in a bacterial artificial chromosome (BAC) vector of Escherichia coli. Owing to the ability of BAC to carry around 100 kbp DNA, only 4 clones were needed to cover the pTT27 and conduct step-by-step assembly in the B. subtilis genome. The full length of 257 kbp was reconstructed through 3 intermediary lengths (108, 153, and 226 kbp), despite an unexpected difficulty in the maintenance of DNA >200 kbp. Retrieval of these four pTT27 segments from the B. subtilis genome by genetic transfer to a plasmid pLS20 was attempted. A stable plasmid clone was obtained only for the 108 and 153 kbp intermediates. The B. subtilis genome was demonstrated to accommodate large DNA with a high GC content, but may be restricted to less than 200 kbp by unidentified mechanisms.

Integration of stable extracellular DNA released from Escherichia coli into the Bacillus subtilis genome vector by culture mix method

The stable cloning of giant DNA is a necessary process in the production of recombinant/synthetic genomes. Handling DNA molecules in test tubes becomes increasingly difficult as their size increases, particularly above 100 kb. The need to prepare such large DNA molecules in a regular manner has limited giant DNA cloning to certain laboratories. Recently, we found stable plasmid DNA of up to 100 kb in Escherichia coli culture medium during the infection and propagation of lambda phage. The extracellular plasmid DNA (excpDNA) released from lysed E. coli was demonstrably stable enough to be taken up by competent Bacillus subtilis also present in the medium. ExcpDNA transfer, induced by simply mixing E. coli lysate with recipient B. subtilis, required no biochemical purification of the DNA. Here, this simple protocol was used to integrate excpDNA into a B. subtilis genome, designated the ‘BGM vector’. A slightly modified protocol for DNA cloning in BGM is presented for DNA fragments >100 kb. This technique should facilitate giant DNA cloning in the BGM vector and allow its application to other hosts that can undergo natural transformation.

Designed horizontal transfer of stable giant DNA released from Escherichia coli

DNA in the environment is a source to mediate horizontal gene transfer (HGT). Present molecular cloning methods are based on this HGT principle. However, DNA in the extracellular environment, particularly with high molecular-weight, is thought to be prone to shearing or digestion by nucleases. Here we discovered that extracellular plasmid DNA released from lysed Escherichia coli remained intact and stable. Furthermore, it was demonstrated that plasmids up to 100 kb in size were taken up by co-present competent Bacillus subtilis cells. The detailed kinetics of the process together with sensitivity to added DNase I indicated that plasmid DNA released from lysed E. coli into the culture medium was stable enough for quantitative efficacy in the transformation of B. subtilis. Our results will be useful for the development of methods to transfer giant DNAs from general host E. coli without their biochemical purification.

Genetic connection of two contiguous bacterial artificial chromosomes using homologous recombination in Bacillus subtilis genome vector

A Bacillus subtilis genome (BGM) vector system using homologous recombination was applied to connect two contiguous BAC clones covering the entire 355-kb transcription unit of the mouse jumonji genomic region. Results from the convenient genomic manipulation indicated that the BGM system facilitates the connection of DNAs from a BAC library without exchange and deletion of original sequence, which can expand large-sized DNA construction beyond BAC-building in Escherichia coli.

Conjugational transfer system to shuttle giant DNA cloned by Bacillus subtilis genome (BGM) vector

The Bacillus subtilis GenoMe (BGM) vector was designed as a versatile vector for the cloning of giant DNA segments. Cloned DNA in the BGM can be retrieved to a plasmid using our Bacillus recombinational transfer (BReT) method that takes advantage of competent cell transformation. However, delivery of the plasmid to a different B. subtilis strain by the normal transformation method is hampered by DNA size-related inefficiency. Therefore, we designed a novel method, conjugational plasmid-mediated DNA retrieval and transfer (CReT) from the BGM vector, and investigated conjugational transmission to traverse DNA between cells to circumvent the transformation-induced size limitation. pLS20, a 65-kb plasmid capable of conjugational transfer between B. subtilis strains, was modified to retrieve DNA cloned in the BGM vector by homologous recombination during normal culture. As the plasmid copy number was estimated to be 3, the retrieval plasmid was selected using increased numbers of marker genes derived from the retrieved DNA. We applied this method to retrieve Synechocystis genome segments up to 90 kb in length. We observed retrieved plasmid transfers between B. subtilis strains by conjugation in the absence of structural alterations in the DNA fragment. Our observations extend DNA transfer protocols over previously exploited size ranges.

Production of the non-ribosomal peptide plipastatin in Bacillus subtilis regulated by three relevant gene blocks assembled in a single movable DNA segment

Methods that allow the assembly of genes in one single DNA segment are of great use in bioengineering and synthetic biology. The biosynthesis of plipastatin, a lipopeptide antibiotic synthesized non-ribosomally by Bacillus subtilis 168, requires three gene blocks at different genome loci, i.e. the peptide synthetase operon ppsABCDE (38-kb), degQ (0.6kb), and sfp (1.0kb). We applied a DNA assembly protocol in B. subtilis, named ordered gene assembly in B. subtilis (OGAB) method, to incorporate those three gene blocks into a one-unit plasmid via one ligation-reaction. High yields of correct assembly, above 87%, allowed us to screen for the plasmid that produced plipastatin at a level approximately 10-fold higher than in the wild-type. In contrast to that recombinogenic technologies used in E. coli require repetitive assembly steps and/or several selection markers, our method features high fidelity and efficiency, is completed in one ligation using only one selection marker associating with plasmid vector, and is applicable to DNA fragments larger than 40kb.

Direct cloning of full-length mouse mitochondrial DNA using a Bacillus subtilis genome vector

The complete mouse mitochondrial genome (16.3 kb) was directly cloned into a Bacillus subtilis genome (BGM) vector. Two DNA segments of 2.06 and 2.14 kb that flank the internal 12 kb of the mitochondrial DNA (mtDNA) were subcloned into an Escherichia coli plasmid. Subsequent integration of the plasmid at the cloning locus of the BGM vector yielded a derivative specific for the targeted cloning of the internal 12-kb mtDNA region. The BGM vector took up mtDNA purified from mouse liver and integrated it by homologous recombination at the two preinstalled mtDNA-flanking sequences. The complete cloned mtDNA in the BGM vector was converted to a covalently closed circular (ccc) plasmid form via gene conversion in B. subtilis. The mtDNA carried on this plasmid was then isolated and transferred to E. coli. DNA sequence fidelity and stability through the BGM vector-mediated cloning process were confirmed.

Experimental Basis for a Stable Plasmid, pLS30, to Shuttle between Bacillus subtilis Species by Conjugational Transfer

The use of Bacillus subtilis 168 as the initial host for molecular cloning and subsequent delivery of the engineered DNA to other Bacillus hosts appears attractive, and would lead to an efficient DNA manipulation system. However, methods of delivery to other Bacillus species are limited due to their inability to develop natural competence. An alternative, unexplored conjugational transfer method drew our attention and a B. subtilis native plasmid, pLS30, isolated from B. subtilis (natto) strain IAM1168 was characterized for this aim. The nucleotide sequence (6,610 bp) contained the mob gene and its recognition sequence, oriT, that features pLS30 as a mobile plasmid between Bacillus species on conjugational transfer. Plasmid pLS3001, a chimera with a pBR322-based plasmid prepared in Escherichia coli to confer an antibiotic resistance marker, showed apparent mobilizing activity in the pLS20-mediated conjugational transfer system recently established. The rep gene and associated palT1-like sequence common to all other pLS plasmids previously sequenced indicated that pLS30 is a typical rolling circle replicating (RCR) type plasmid. Due to the significant stability of pLS30 in IAM1168, application of a mobile plasmid would allow quick propagation to Bacillus species.