Experimental surgery to create subgenomes of Bacillus subtilis 168

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.

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.

The Second Chromosome Promotes the Adaptation of the Genus Flammeovirga to Complex Environments

Approximately 10% of bacterial strains contain more than one chromosome; however, in contrast to the primary chromosomes, the mechanisms underlying the formation of the second chromosomes and the significance of their existence remain unclear. Species of the genus Flammeovirga are typical polysaccharide-degrading bacteria, and herein, we report complete genome maps of this genus. These genomes all had multireplicons and second chromosomes. The second chromosome, much larger than plasmids and even megaplasmids, had rRNA and a disparity of 1% relative to the main chromosome in guanine-cytosine (GC) content. The largest chromosomes carried core genes for cellular processes, while the second chromosomes were enriched with genes involved in the transport and metabolism of inorganic ions and carbohydrates, particularly genes encoding glycoside hydrolases and polysaccharide lyases, which constituted the genetic basis for the strains’ excellent capabilities to utilize polysaccharides. The second chromosomal evolution had a higher mutation rate than the primary chromosomes. Furthermore, the second chromosomes were also enriched in horizontal transfer genes and duplicated genes. The primary chromosomes were more evolutionarily conserved, while the second chromosomes were more plastic, which might be related to their different roles in the bacterial survival process. This study can be used as an example to explain possible formation mechanisms and functions of the second chromosomes, providing a reference for peer research on the second chromosomes. In particular, the second chromosomes were enriched in polysaccharide-degrading enzymes, which will provide theoretical support for using genomic data to mine tool-type carbohydrase resources.

IMPORTANCE For decades, the typical bacterial genome has been thought to contain a single chromosome and a few small plasmids carrying nonessential genes. However, an increasing number of secondary chromosomes have been identified in various bacteria (e.g., plant symbiotic bacteria and human pathogens). This study reported three complete genomes of the polysaccharide-degrading marine bacterial genus Flammeovirga, revealed that they harbor two chromosomes, and further identified that the presence of a multireplicon system is a characteristic of complete Flammeovirga genomes. These sequences will add to our knowledge on secondary chromosomes, especially within Bacteroidetes. This study indicated that the second chromosomes of the genus Flammeovirga initially originated from an ancestral plasmid and subsequently expanded by gene duplication or by obtaining heterologous genes with functions, thus promoting host strains to adapt to complex living environments (e.g., to degrade more diverse polysaccharides from marine environments). These findings will promote the understanding of the evolution and function of bacteria with multireplicon systems.

The Large pBS32/pLS32 Plasmid of Ancestral Bacillus subtilis

The ancestral strain of Bacillus subtilis NCIB3610 (3610) bears a large, low-copy-number plasmid, called pBS32, that was lost during the domestication of laboratory strain derivatives. Selection against pBS32 may have been because it encodes a potent inhibitor of natural genetic competence (ComI), as laboratory strains were selected for high-frequency transformation. Previous studies have shown that pBS32 and its sibling, pLS32 in Bacillus subtilis subsp. natto, encode a replication initiation protein (RepN), a plasmid partitioning system (AlfAB), a biofilm inhibitor (RapP), and an alternative sigma factor (SigN) that can induce plasmid-mediated cell death in response to DNA damage. Here, we review the literature on pBS32/pLS32, the genes found on it, and their associated phenotypes.

Exception to the exception rule: synthetic and naturally occurring single chromosome Vibrio cholerae

The genome of Vibrio cholerae, the etiological agent of cholera, is an exception to the single chromosome rule found in the vast majority of bacteria and has its genome partitioned between two unequally sized chromosomes. This unusual two-chromosome arrangement in V. cholerae has sparked considerable research interest since its discovery. It was demonstrated that the two chromosomes could be fused by deliberate genome engineering or forced to fuse spontaneously by blocking the replication of Chr2, the secondary chromosome. Recently, natural isolates of V. cholerae with chromosomal fusion have been found. Here, we summarize the pertinent findings on this exception to the exception rule and discuss the potential utility of single-chromosome V. cholerae to address fundamental questions on chromosome biology in general and DNA replication in particular.

Programmed chromosome fission and fusion enable precise large-scale genome rearrangement and assembly

The design and creation of synthetic genomes provide a powerful approach to understanding and engineering biology. However, it is often limited by the paucity of methods for precise genome manipulation. Here, we demonstrate the programmed fission of the Escherichia coli genome into diverse pairs of synthetic chromosomes and the programmed fusion of synthetic chromosomes to generate genomes with user-defined inversions and translocations. We further combine genome fission, chromosome transplant, and chromosome fusion to assemble genomic regions from different strains into a single genome. Thus, we program the scarless assembly of new genomes with nucleotide precision, a key step in the convergent synthesis of genomes from diverse progenitors. This work provides a set of precise, rapid, large-scale (megabase) genome-engineering operations for creating diverse synthetic genomes.

Stable mutants of restriction-deficient/modification-proficient Bacillus subtilis 168: hub strains for giant DNA engineering

Bacillus subtilis 168 has been explored as a platform for the synthesis and transmission of large DNA. Two inherent DNA incorporation systems, natural transformation and pLS20-based conjugation transfer, enable rapid handling of target DNA. Both systems are affected by the Bsu restriction-modification system that recognizes and cleaves unmethylated XhoI sites, limiting the choice of target DNA. We constructed B. subtilis 168 with stable mutation for restriction-deficient and modification-proficient (r-m+). It was demonstrated that the r-m+ strains can incorporate and transfer synthesized DNA with multiple XhoI sites. These should be of value as hub strains to integrate and disseminate giant DNA between B. subtilis 168 derivatives.

The first high frequency of recombination-like conjugal transfer from an integrated origin of transfer sequence in Bacillus subtilis 168

Bacillus subtilis 168 was developed as a genome vector to manipulate large DNA fragments. The system is based on the inherent natural transformation (TF) activity. However, DNA size transferred by TF is limited up to approximately 100 kb. A conjugal transfer system capable of transferring DNA fragments considerably larger than those transferred by TF was developed. A well-defined oriT¹¹⁰ sequence and a cognate relaxase gene from the pUB110 plasmid were inserted into the xkdE gene of the B. subtilis genome. Transfer of antibiotic resistance markers distant from the oriT¹¹⁰ locus to the recipient B. subtilis occurred only in the presence of pLS20, a helper plasmid that provides a type IV secretion system. Marker transmission was consistent with the orientation of oriT¹¹⁰ and required a recA-proficient recipient. The first conjugal transfer system of genomic DNA should provide a valuable alternative genetic tool for editing the B. subtilis genome.

The Divided Bacterial Genome: Structure, Function, and Evolution

Approximately 10% of bacterial genomes are split between two or more large DNA fragments, a genome architecture referred to as a multipartite genome. This multipartite organization is found in many important organisms, including plant symbionts, such as the nitrogen-fixing rhizobia, and plant, animal, and human pathogens, including the genera Brucella, Vibrio, and Burkholderia. The availability of many complete bacterial genome sequences means that we can now examine on a broad scale the characteristics of the different types of DNA molecules in a genome. Recent work has begun to shed light on the unique properties of each class of replicon, the unique functional role of chromosomal and nonchromosomal DNA molecules, and how the exploitation of novel niches may have driven the evolution of the multipartite genome. The aims of this review are to (i) outline the literature regarding bacterial genomes that are divided into multiple fragments, (ii) provide a meta-analysis of completed bacterial genomes from 1,708 species as a way of reviewing the abundant information present in these genome sequences, and (iii) provide an encompassing model to explain the evolution and function of the multipartite genome structure. This review covers, among other topics, salient genome terminology; mechanisms of multipartite genome formation; the phylogenetic distribution of multipartite genomes; how each part of a genome differs with respect to genomic signatures, genetic variability, and gene functional annotation; how each DNA molecule may interact; as well as the costs and benefits of this genome structure.

DNA Replication in Engineered Escherichia coli Genomes with Extra Replication Origins

The standard outline of bacterial genomes is a single circular chromosome with a single replication origin. From the bioengineering perspective, it appears attractive to extend this basic setup. Bacteria with split chromosomes or multiple replication origins have been successfully constructed in the last few years. The characteristics of these engineered strains will largely depend on the respective DNA replication patterns. However, the DNA replication has not been investigated systematically in engineered bacteria with multiple origins or split replicons. Here we fill this gap by studying a set of strains consisting of (i) E. coli strains with an extra copy of the native replication origin (oriC), (ii) E. coli strains with an extra copy of the replication origin from the secondary chromosome of Vibrio cholerae (oriII), and (iii) a strain in which the E. coli chromosome is split into two linear replicons. A combination of flow cytometry, microarray-based comparative genomic hybridization (CGH), and modeling revealed silencing of extra oriC copies and differential timing of ectopic oriII copies compared to the native oriC. The results were used to derive construction rules for future multiorigin and multireplicon projects.

Coevolution of the Organization and Structure of Prokaryotic Genomes

The cytoplasm of prokaryotes contains many molecular machines interacting directly with the chromosome. These vital interactions depend on the chromosome structure, as a molecule, and on the genome organization, as a unit of genetic information. Strong selection for the organization of the genetic elements implicated in these interactions drives replicon ploidy, gene distribution, operon conservation, and the formation of replication-associated traits. The genomes of prokaryotes are also very plastic with high rates of horizontal gene transfer and gene loss. The evolutionary conflicts between plasticity and organization lead to the formation of regions with high genetic diversity whose impact on chromosome structure is poorly understood. Prokaryotic genomes are remarkable documents of natural history because they carry the imprint of all of these selective and mutational forces. Their study allows a better understanding of molecular mechanisms, their impact on microbial evolution, and how they can be tinkered in synthetic biology.

Undesigned selection for replication termination of bacterial chromosomes

The oriC DNA replication origin in bacterial chromosomes, the location of which appears to be physically identified, is genetically regulated by relevant molecular machinery. In contrast, the location of the terminus remains obscure for many bacterial replicons, except for terC, the proposed and well-studied chromosome termination site in certain bacteria. The terC locus, which is composed of specific sequences for its binding protein, is located at a site opposite from oriC, exhibiting a symmetric structure around the oriC-terC axis. Here, we investigated Bacillus subtilis 168 strains whose axes were hindered and found that the native terC function was robust. However, eradication of terminus region specific binding protein resulted in the natural terC sites not being used for termination; instead, new termini were selected at a location exactly opposite to oriC. We concluded that replication generally terminates at the loci where the two approaching replisomes meet. This site was automatically selected, and two replisomes moving at the same rate supported symmetrical chromosome structures relative to oriC. The rule, which was even validated by artificial chromosomes irrespective of oriC, should be general for replicons administered by two replisomes.

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.

Genome engineering in Vibrio cholerae: a feasible approach to address biological issues

Although bacteria with multipartite genomes are prevalent, our knowledge of the mechanisms maintaining their genome is very limited, and much remains to be learned about the structural and functional interrelationships of multiple chromosomes. Owing to its bi-chromosomal genome architecture and its importance in public health, Vibrio cholerae, the causative agent of cholera, has become a preferred model to study bacteria with multipartite genomes. However, most in vivo studies in V. cholerae have been hampered by its genome architecture, as it is difficult to give phenotypes to a specific chromosome. This difficulty was surmounted using a unique and powerful strategy based on massive rearrangement of prokaryotic genomes. We developed a site-specific recombination-based engineering tool, which allows targeted, oriented, and reciprocal DNA exchanges. Using this genetic tool, we obtained a panel of V. cholerae mutants with various genome configurations: one with a single chromosome, one with two chromosomes of equal size, and one with both chromosomes controlled by identical origins. We used these synthetic strains to address several biological questions--the specific case of the essentiality of Dam methylation in V. cholerae and the general question concerning bacteria carrying circular chromosomes--by looking at the effect of chromosome size on topological issues. In this article, we show that Dam, RctB, and ParA2/ParB2 are strictly essential for chrII origin maintenance, and we formally demonstrate that the formation of chromosome dimers increases exponentially with chromosome size.

Mobility of plasmids

Plasmids are key vectors of horizontal gene transfer and essential genetic engineering tools. They code for genes involved in many aspects of microbial biology, including detoxication, virulence, ecological interactions, and antibiotic resistance. While many studies have decorticated the mechanisms of mobility in model plasmids, the identification and characterization of plasmid mobility from genome data are unexplored. By reviewing the available data and literature, we established a computational protocol to identify and classify conjugation and mobilization genetic modules in 1,730 plasmids. This allowed the accurate classification of proteobacterial conjugative or mobilizable systems in a combination of four mating pair formation and six relaxase families. The available evidence suggests that half of the plasmids are nonmobilizable and that half of the remaining plasmids are conjugative. Some conjugative systems are much more abundant than others and preferably associated with some clades or plasmid sizes. Most very large plasmids are nonmobilizable, with evidence of ongoing domestication into secondary chromosomes. The evolution of conjugation elements shows ancient divergence between mobility systems, with relaxases and type IV coupling proteins (T4CPs) often following separate paths from type IV secretion systems. Phylogenetic patterns of mobility proteins are consistent with the phylogeny of the host prokaryotes, suggesting that plasmid mobility is in general circumscribed within large clades. Our survey suggests the existence of unsuspected new relaxases in archaea and new conjugation systems in cyanobacteria and actinobacteria. Few genes, e.g., T4CPs, relaxases, and VirB4, are at the core of plasmid conjugation, and together with accessory genes, they have evolved into specific systems adapted to specific physiological and ecological contexts.

Muropeptide rescue in Bacillus subtilis involves sequential hydrolysis by beta-N-acetylglucosaminidase and N-acetylmuramyl-L-alanine amidase

We identified a pathway in Bacillus subtilis that is used for recovery of N-acetylglucosamine (GlcNAc)-N-acetylmuramic acid (MurNAc) peptides (muropeptides) derived from the peptidoglycan of the cell wall. This pathway is encoded by a cluster of six genes, the first three of which are orthologs of Escherichia coli genes involved in N-acetylmuramic acid dissimilation and encode a MurNAc-6-phosphate etherase (MurQ), a MurNAc-6-phosphate-specific transcriptional regulator (MurR), and a MurNAc-specific phosphotransferase system (MurP). Here we characterized two other genes of this cluster. The first gene was shown to encode a cell wall-associated beta-N-acetylglucosaminidase (NagZ, formerly YbbD) that cleaves the terminal nonreducing N-acetylglucosamine of muropeptides and also accepts chromogenic or fluorogenic beta-N-acetylglucosaminides. The second gene was shown to encode an amidase (AmiE, formerly YbbE) that hydrolyzes the N-acetylmuramyl-L-Ala bond of MurNAc peptides but not this bond of muropeptides. Hence, AmiE requires NagZ, and in conjunction these enzymes liberate MurNAc by sequential hydrolysis of muropeptides. NagZ expression was induced at late exponential phase, and it was 6-fold higher in stationary phase. NagZ is noncovalently associated with lysozyme-degradable particulate material and can be released from it with salt. A nagZ mutant accumulates muropeptides in the spent medium and displays a lytic phenotype in late stationary phase. The evidence for a muropeptide catabolic pathway presented here is the first evidence for cell wall recovery in a Gram-positive organism, and this pathway is distinct from the cell wall recycling pathway of E. coli and other Gram-negative bacteria.

Functional analysis of the stability determinant AlfB of pBET131, a miniplasmid derivative of bacillus subtilis (natto) plasmid pLS32

Bacillus subtilis plasmid pBET131 is a derivative of pLS32, which was isolated from a natto strain of Bacillus subtilis. The DNA region in pBET131 that confers segregational stability contains an operon consisting of three genes, of which alfA, encoding an actin-like ATPase, and alfB are essential for plasmid stability. In this work, the alfB gene product and its target DNA region were studied in detail. Transcription of the alf operon initiated from a sigma(A)-type promoter was repressed by the alfB gene product. Overproduction of AlfA was inhibitory to cell growth, suggesting that the repression of the alf operon by AlfB is important for maintaining appropriate levels of AlfA. An electrophoretic mobility shift assay and footprinting analysis with purified His-tagged AlfB showed that it bound to a DNA region containing three tandem repeats of 8-bp AT-rich sequence (here designated parN), which partially overlaps the -35 sequence of the promoter. A sequence alteration in the first or third repeat did not affect the AlfB binding and plasmid stability, whereas that in the second repeat resulted in inhibition of these phenomena. The repression of alfA-lacZ expression was observed in the constructs carrying a mutation in either the first or third repeat, but not in the second repeat, indicating a correlation between plasmid stability, AlfB binding, and repression. It was also demonstrated by the yeast two-hybrid system that AlfA and AlfB interact with each other and among themselves. From these results, it was concluded that AlfB participates in partitioning pBET131 by forming a complex with AlfA and parN, the mode of which is typified by the type II partition mechanism.

The organization of the bacterial genome

Many bacterial cellular processes interact intimately with the chromosome. Such interplay is the major driving force of genome structure or organization. Interactions take place at different scales-local for gene expression, global for replication-and lead to the differentiation of the chromosome into organizational units such as operons, replichores, or macrodomains. These processes are intermingled in the cell and create complex higher-level organizational features that are adaptive because they favor the interplay between the processes. The surprising result of selection for genome organization is that gene repertoires change much more quickly than chromosomal structure. Comparative genomics and experimental genomic manipulations are untangling the different cellular and evolutionary mechanisms causing such resilience to change. Since organization results from cellular processes, a better understanding of chromosome organization will help unravel the underlying cellular processes and their diversity.

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.

Targeting the Bacillus subtilis genome: An efficient and clean method for gene disruption

A method to disrupt multiple Bacillus subtilis genes is described. A resistance cassette is used to interrupt an amplified target sequence from the B. subtilis chromosome. The cassette is composed of a gene conferring resistance to chloramphenicol (Cm) or spectinomycin (Sp) flanked by two directly oriented beta cognate sites (six site) (SCS or SSS, respectively). The linearized construct is used to transform B. subtilis competent cells with selection for Cm or Sp resistance. Transformants with the desired gene disrupted by the SCS or SSS cassette, integrated by a double cross-over event, were confirmed by PCR analysis. A segregationally unstable plasmid-borne beta site-specific recombinase is transferred into the background. Protein beta catalyzes excision of the intervening sequence between the two six sites leading to a target gene disrupted only by a six site. This site has an internal promoter capable of reading downstream genes. To generate multiple disruptions, the cycle can be repeated many times provided that two six sites are separated by about a 70-kb interval.

Sporulating bacteria prefers predation to cannibalism in mixed cultures

Predatory behavior, a property associated with ecosystems, is not commonly observed in microorganisms. However, cannibalistic tendencies have been observed in microorganisms under stress. For example, pure culture of Bacillus subtilis exhibits cannibalism under nutrient limitation. It has been proposed that a fraction of cells in the population produce Spo0A, a regulatory protein that is responsible for delaying sporulation. Cells containing spo0A would produce a killing factor by activating skf operon and an associated pump to export the factor. Cells that do not contain spo0A in the population are lysed. However in addition to the competition among the cells of B. subtilis, these cells also compete with other organisms for the limited nutrients. In this work, we report the cannibalistic behavior of B. subtilis in presence of Escherichia coli under severe nutritional limitation. We demonstrate that B. subtilis lyses cells of E. coli using an antibacterial factor under the regulation of Spo0A. Our experiments also suggest that B. subtilis prefers predation of E. coli to cannibalism in mixed cultures. B. subtilis also demonstrated predation in mixed cultures with other soil microorganisms, such as, Xanthomonas campestris, Pseudomonas aeruginosa and Acinetobactor lwoffi. This may offer B. subtilis a niche to survive in an environment with limited nutrients and under competition from other microorganisms.

Multiple large segment deletion method for Corynebacterium glutamicum

A precise and scarless genome excision method, employing the Cre/loxP system in concert with double-strand break (DSB)-stimulated intramolecular recombination was developed. The DSBs were mediated by the restriction endonuclease, I-SceI. It permitted multiple deletions of independent 14-, 43-, and 10-kb-long genomic regions on the Corynebacterium glutamicum genome. Accuracy of deletion was confirmed by the loss of marker genes, PCR, and sequencing of new genome joints. Eleven, 58, and 4 genes were predicted on the 14-, 43-, and 10-kb deleted regions, respectively. Although the resultant mutant lost a total of 67 kb encoding 73 genes, it still exhibited normal growth under standard laboratory conditions. Such a large segment deletion method in which multiple, successive deletions are possible is useful for genome engineering.

Combining two genomes in one cell: stable cloning of the Synechocystis PCC6803 genome in the Bacillus subtilis 168 genome

Cloning the whole 3.5-megabase (Mb) genome of the photosynthetic bacterium Synechocystis PCC6803 into the 4.2-Mb genome of the mesophilic bacterium Bacillus subtilis 168 resulted in a 7.7-Mb composite genome. We succeeded in such unprecedented large-size cloning by progressively assembling and editing contiguous DNA regions that cover the entire Synechocystis genome. The strain containing the two sets of genome grew only in the B. subtilis culture medium where all of the cloning procedures were carried out. The high structural stability of the cloned Synechocystis genome was closely associated with the symmetry of the bacterial genome structure of the DNA replication origin (oriC) and its termination (terC) and the exclusivity of Synechocystis ribosomal RNA operon genes (rrnA and rrnB). Given the significant diversity in genome structure observed upon horizontal DNA transfer in nature, our stable laboratory-generated composite genome raised fundamental questions concerning two complete genomes in one cell. Our megasize DNA cloning method, designated megacloning, may be generally applicable to other genomes or genome loci of free-living organisms.

Characterization of the replication region of plasmid pLS32 from the Natto strain of Bacillus subtilis

Plasmid pL32 from the Natto strain of Bacillus subtilis belongs to a group of low-copy-number plasmids in gram-positive bacteria that replicate via a theta mechanism of replication. We studied the DNA region encoding the replication protein, RepN, of pLS32, and obtained the following results. Transcription of the repN gene starts 167 nucleotides upstream from the translational start site of repN. The copy number of repN-coding plasmid pHDCS2, in which the repN gene was placed downstream of the IPTG (isopropyl-1-thio-beta-D-galactopyranoside)-inducible Pspac promoter, was increased 100 fold by the addition of IPTG. Histidine-tagged RepN bound to a specific region in the repN gene containing five 22-bp tandem repeats (iterons) with partial mismatches, as shown by gel retardation and foot printing analyses. Sequence alterations in the first three iterons resulted in an increase in plasmid copy number, whereas those in either the forth or fifth iteron resulted in the failure of plasmid replication. The iterons expressed various degrees of incompatibility with an incoming repN-driven replicon pSEQ243, with the first three showing the strongest incompatibility. Finally, by using a plasmid, pHDMAEC21, carrying the sequence alterations in all the five iterons in repN and thus unable to replicate but encoding intact RepN, the region necessary for replication was confined to a 96-bp sequence spanning the 3'-terminal half of the fourth iteron to an A+T-rich region located downstream of the fifth iteron. From these results, we conclude that the iterons in repN are involved in both the control of plasmid copy number and incompatibility, and we suggest that the binding of RepN to the last two iterons triggers replication by melting the A+T-rich DNA sequence.

MicroReview: Divided genomes: negotiating the cell cycle in prokaryotes with multiple chromosomes

Historically, the prokaryotic genome was assumed to consist of a single circular replicon. However, as more microbial genome sequencing projects are completed, it is becoming clear that multipartite genomes comprised of more than one chromosome are not unusual among prokaryotes. Chromosomes are distinguished from plasmids by the presence of essential genes as well as characteristic cell cycle-linked replication kinetics; unlike plasmids, chromosomes initiate replication once per cell cycle. The existence of multipartite prokaryotic genomes raises several questions regarding how multiple chromosomes are replicated and segregated during the cell cycle. These divided genomes also introduce questions regarding chromosome evolution and genome stability. In this review, we discuss these and other issues, with particular emphasis on the cholera pathogen Vibrio cholerae.

Targeted isolation of a designated region of the Bacillus subtilis genome by recombinational transfer

A method for positional cloning of the Bacillus subtilis genome was developed. The method requires a set of two small DNA fragments that flank the region to be copied. A 38-kb segment that carries genes ppsABCDE encoding five enzymes for antibiotic plipastatin synthesis and another genome locus as large as 100 kb including one essential gene were examined for positional cloning. The positional cloning vector for ppsABCDE was constructed using a B. subtilis low-copy-number plasmid that faithfully copied the precise length of the 38-kb DNA in vivo via the recombinational transfer system of this bacterium. Structure of the copied DNA was confirmed by restriction enzyme analyses. Furthermore, the unaltered structure of the 38-kb DNA was demonstrated by complementation of a ppsABCDE deletion mutant.

migS, a cis-acting site that affects bipolar positioning of oriC on the Escherichia coli chromosome

During replication of the Escherichia coli chromosome, the replicated Ori domains migrate towards opposite cell poles, suggesting that a cis-acting site for bipolar migration is located in this region. To identify this cis-acting site, a series of mutants was constructed by splitting subchromosomes from the original chromosome. One mutant, containing a 720 kb subchromosome, was found to be defective in the bipolar positioning of oriC. The creation of deletion mutants allowed the identification of migS, a 25 bp sequence, as the cis-acting site for the bipolar positioning of oriC. When migS was located at the replication terminus, the chromosomal segment showed bipolar positioning. migS was able to rescue bipolar migration of plasmid DNA containing a mutation in the SopABC partitioning system. Interestingly, multiple copies of the migS sequence on a plasmid in trans inhibited the bipolar positioning of oriC. Taken together, these findings indicate that migS plays a crucial role in the bipolar positioning of oriC. In addition, real-time analysis of the dynamic morphological changes of nucleoids in wild-type and migS mutants suggests that bipolar positioning of the replicated oriC contributes to nucleoid organization.

Physical and gene maps of Agrobacterium biovar 2 strains and their relationship to biovar 1 chromosomes

Diverse types of genomic DNA organization have been found in Rhizobiaceae, especially among Agrobacterium species. Previous studies of Agrobacterium concentrated mainly on biovar 1 strains. Little attention has been given to biovar 2 strains. The biovar 2 genome consists of a large, circular chromosome and second megabase-sized replicon, as well as several plasmids. In this study two biovar 2 strains were analysed, A. rhizogenes (A. radiobacter) K84 and A. rhizogenes A4, by constructing physical maps of their chromosomes and mega-replicons. The maps revealed that in both strains their chromosomes consist of approximately 3.7 Mbp, while the mega-replicons are 2.6 Mbp circular DNAs. Gene mapping and comparative genomic analysis were performed based on the physical maps using Southern hybridization. It was found that rDNA, as well as analysed virulence and virulence-related genes, are present only on the chromosomes. The inter-chromosomal relationship between biovar 1 and biovar 2 strains was also analysed. Interestingly, there was a high similarity between the chromosomes of biovar 2 and the circular chromosomes of biovar 1, whereas similarity among the smaller megabase-sized replicons was restricted to each biovar. Based on these observations the possible relationship among large replicons in Agrobacterium biovars 1 and 2 is discussed.

Molecular characterization of Brucella abortus chromosome II recombination

Large-scale genomic rearrangements including inversions, deletions, and duplications are significant in bacterial evolution. The recently completed Brucella melitensis 16M and Brucella suis 1330 genomes have facilitated the investigation of such events in the Brucella spp. Suppressive subtractive hybridization (SSH) was employed in identifying genomic differences between B. melitensis 16M and Brucella abortus 2308. Analysis of 45 SSH clones revealed several deletions on chromosomes of B. abortus and B. melitensis that encoded proteins of various metabolic pathways. A 640-kb inversion on chromosome II of B. abortus has been reported previously (S. Michaux Charachon, G. Bourg, E. Jumas Bilak, P. Guigue Talet, A. Allardet Servent, D. O'Callaghan, and M. Ramuz, J. Bacteriol. 179:3244-3249, 1997) and is further described in this study. One end of the inverted region is located on a deleted TATGC site between open reading frames BMEII0292 and BMEII0293. The other end inserted at a GTGTC site of the cyclic-di-GMP phosphodiesterase A (PDEA) gene (BMEII1009), dividing PDEA into two unequal DNA segments of 160 and 977 bp. As a consequence of inversion, the 160-bp segment that encodes the N-terminal region of PDEA was relocated at the opposite end of the inverted chromosomal region. The splitting of the PDEA gene most likely inactivated the function of this enzyme. A recombination mechanism responsible for this inversion is proposed.

Simple sequence repeats and compositional bias in the bipartite Ralstonia solanacearum GMI1000 genome

BACKGROUND

Ralstonia solanacearum is an important plant pathogen. The genome of R. solananearum GMI1000 is organised into two replicons (a 3.7-Mb chromosome and a 2.1-Mb megaplasmid) and this bipartite genome structure is characteristic for most R. solanacearum strains. To determine whether the megaplasmid was acquired via recent horizontal gene transfer or is part of an ancestral single chromosome, we compared the abundance, distribution and composition of simple sequence repeats (SSRs) between both replicons and also compared the respective compositional biases.

RESULTS

Our data show that both replicons are very similar in respect to distribution and composition of SSRs and presence of compositional biases. Minor variations in SSR and compositional biases observed may be attributable to minor differences in gene expression and regulation of gene expression or can be attributed to the small sample numbers observed.

CONCLUSIONS

The observed similarities indicate that both replicons have shared a similar evolutionary history and thus suggest that the megaplasmid was not recently acquired from other organisms by lateral gene transfer but is a part of an ancestral R. solanacearum chromosome.

Engineering a reduced Escherichia coli genome

Our goal is to construct an improved Escherichia coli to serve both as a better model organism and as a more useful technological tool for genome science. We developed techniques for precise genomic surgery and applied them to deleting the largest K-islands of E. coli, identified by comparative genomics as recent horizontal acquisitions to the genome. They are loaded with cryptic prophages, transposons, damaged genes, and genes of unknown function. Our method leaves no scars or markers behind and can be applied sequentially. Twelve K-islands were successfully deleted, resulting in an 8.1% reduced genome size, a 9.3% reduction of gene count, and elimination of 24 of the 44 transposable elements of E. coli. These are particularly detrimental because they can mutagenize the genome or transpose into clones being propagated for sequencing, as happened in 18 places of the draft human genome sequence. We found no change in the growth rate on minimal medium, confirming the nonessential nature of these islands. This demonstration of feasibility opens the way for constructing a maximally reduced strain, which will provide a clean background for functional genomics studies, a more efficient background for use in biotechnology applications, and a unique tool for studies of genome stability and evolution.

Recombinational transfer of 100-kilobase genomic DNA to plasmid in Bacillus subtilis 168

Transformation of Bacillus subtilis by a plasmid requires a circular multimeric form. In contrast, linearized plasmids can be circularized only when homologous sequences are present in the host genome. A recombinational transfer system was constructed with this intrinsic B. subtilis recombinational repair pathway. The vector, pGETS103, a derivative of the theta-type replicating plasmid pTB19 of thermophilic Bacillus, had the full length of Escherichia coli plasmid pBR322. A multimeric form of pGETS103 yielded tetracycline-resistant transformants of B. subtilis. In contrast, linearized pGETS103 gave tetracycline-resistant transformants only when the recipient strain had the pBR322 sequence in the genome. The efficiency and fidelity of the recombinational transfer of DNAs of up to 90 kb are demonstrated.

Functional and evolutionary roles of long repeats in prokaryotes

Most recently published complete bacterial genomes have revealed unexpectedly high numbers of long strict repeats. In this article we discuss the various functional and evolutionary roles of these repeats, focusing in particular on their role in terms of genome stability, gene transfer, and antigenic variation.

Fate of unstable Bacillus subtilis subgenome: re-integration and amplification in the main genome

The plastic Bacillus subtilis genome was dissected into two physically separate genomes, the 3.9 Mb main genome and the 0.3 Mb subgenome. DNA replication of the main genome was initiated from the normal replication origin (oriC) and that of the subgenome was from a 7.2 kb oriN-containing fragment artificially inserted. When the 7.2 kb fragment was shortened to a 1.5 kb fragment that contains oriN but lacks the segregational function, the subgenome became unstable and was rapidly lost from the cell, producing inviable cells due to the loss of essential genes carried by the subgenome. Stable survivors were isolated in which the subgenome had re-integrated and multiplied in the main genome. These results suggest that a reduced genetic stability of the subgenome induces size variation of the B. subtilis genome.

The diverse and dynamic structure of bacterial genomes

Bacterial genome sizes, which range from 500 to 10,000 kbp, are within the current scope of operation of large-scale nucleotide sequence determination facilities. To date, 8 complete bacterial genomes have been sequenced, and at least 40 more will be completed in the near future. Such projects give wonderfully detailed information concerning the structure of the organism's genes and the overall organization of the sequenced genomes. It will be very important to put this incredible wealth of detail into a larger biological picture: How does this information apply to the genomes of related genera, related species, or even other individuals from the same species? Recent advances in pulsed-field gel electrophoretic technology have facilitated the construction of complete and accurate physical maps of bacterial chromosomes, and the many maps constructed in the past decade have revealed unexpected and substantial differences in genome size and organization even among closely related bacteria. This review focuses on this recently appreciated plasticity in structure of bacterial genomes, and diversity in genome size, replicon geometry, and chromosome number are discussed at inter- and intraspecies levels.

Genetic transfer of large DNA inserts to designated loci of the Bacillus subtilis 168 genome

It was found that contiguous DNA segments of up to 50 kb can be transferred between Bacillus subtilis genomes when a sufficient length of the flanking genomic region is provided for homologous recombination, although the efficiency of transfer was reduced as the insert size increased. Inserts were translocated to different loci, where appropriate integration sites were created.

Unconventional genomic organization in the alpha subgroup of the Proteobacteria

Pulsed-field gel electrophoresis was used to analyze the genomic organization of 16 bacteria belonging or related to the family Rhizobiaceae of the alpha subgroup of the class Proteobacteria. The number and sizes of replicons were determined by separating nondigested DNA. Hybridization of an rrn gene probe was used to distinguish between chromosomes and plasmids. Members of the genus Agrobacterium all possess two chromosomes, and each biovar has a specific genome size. As previously demonstrated for Agrobacterium tumefaciens C58, the smaller chromosomes of Agrobacterium biovar 1 and Agrobacterium rubi strains appear to be linear. The genomes of Rhizobium strains were all of similar sizes but were seen to contain either one, two, or three megareplicons. Only one chromosome was present in the member of the related genus Phyllobacterium. We found one or two chromosomes in Rhodobacter and Brucella species, two chromosomes in Ochrobactrum anthropi, and one chromosome in Mycoplana dimorpha and Bartonella quintana; all of these genera are related to the Rhizobiaceae. The presence of multiple chromosomes is discussed from a phylogenetic and taxonomic point of view.

Plasmid (1952-1997)

The term "plasmid" was introduced 45 years ago (J. Lederberg, 1952, Physiol. Rev. 32, 403-430) as a generic term for any extrachromosomal genetic particle. It was intended to clarify the classification of agents that had been thought of disjunctively as parasites, symbionts, organelles, or genes. For a decade or more it was confused with "episome," although that was carefully crafted (F. Jacob and E. L. Wollman, 1958, C. R. Acad. Sci. 247, 154-156) to mean agents with traffic in and out of chromosomes. Starting about 1970, plasmids became important reagents in molecular genetic research and biotechnology. They also play a cardinal role in the evolution of microbial resistance and of pathogenicity. The usage of the term has then escalated to its current peak of about 3000 published articles per year. The bedrock of genetic mechanism is no longer mitosis and meiosis of chromosomes; it is template-directed DNA assembly. This is often more readily studied and managed with the use of plasmids, which replicate autonomously outside the chromosomes. Some plasmids are also episomes, namely, they interact with the chromosomal genome, and other mobile elements may be transposed from one chromosomal locus to another without replicating autonomously.

A novel Bacillus natto plasmid pLS32 capable of replication in Bacillus subtilis

Plasmid pLS32 is a relatively large (approximately 70 kbp), cryptic, low copy-number plasmid present in Bacillus natto. We isolated and analyzed the replication region of the plasmid in B. subtilis, and the following results were obtained: the replication region contained an open reading frame encoding a 287-amino acid protein (RepN), whose amino acid sequence was partially homologous with those of the Rep proteins encoded on plasmids pAD1 and pLJ1 isolated from Enterococcus faecalis and Lactobacillus helveticus, respectively; the replication origin (oriN) was located in the repN-coding region; the copy number of a pLS32 derivative, pBET131, was 2 to 3 per chromosome; replication of pBET131 required poll. These features show that pLS32 is a novel plasmid capable of replication in B. subtilis.

Differences in chromosome number and genome rearrangements in the genus Brucella

We have studied the genomic structure and constructed the SpeI, PacI and I-CeuI restriction maps of the four biovars of the pathogenic bacterium Brucella suis. B. suis biovar 1 has two chromosomes of 2.1 Mb and 1.15 Mb, similar to those of the other Brucella species: B. melitensis, B. abortus, B. ovis and B. neotomae. Two chromosomes were also observed in the genome of B. suis biovars 2 and 4, but with sizes of 1.85 Mb and 1.35 Mb, whereas only one chromosome with a size of 3.1 Mb was found in B. suis biovar 3. We show that the differences in chromosome size and number can be explained by rearrangements at chromosomal regions containing the three rrn genes. The location and orientation of these genes confirmed that these rearrangements are due to homologous recombination at the rrn loci. This observation allows us to propose a scheme for the evolution of the genus Brucella in which the two chromosome-containing strains can emerge from an hypothetical ancestor with a single chromosome, which is probably similar to that of B. suis biovar 3. As the genus Brucella is certainly monospecific, this is the first time that differences in chromosome number have been observed in strains of the same bacterial species.