Marker rescue transformation by linear plasmid DNA in Bacillus subtilis

Viral SPP1 DNA is infectious in naturally competent Bacillus subtilis cells: inter- and intramolecular recombination pathways

A proteolyzed bacteriophage (phage) might release its DNA into the environment. Here, we define the recombination functions required to resurrect an infective lytic phage from inactive environmental viral DNA in naturally competent Bacillus subtilis cells. Using phage SPP1 DNA, a model that accounts for the obtained data is proposed (i) the DNA uptake apparatus takes up environmental SPP1 DNA, fragments it, and incorporates into the cytosol different linear single-stranded (ss) DNA molecules shorter than genome-length; (ii) the SsbA-DprA mediator loads RecA onto any fragmented linear SPP1 ssDNA, but negative modulators (RecX and RecU) promote a net RecA disassembly from these ssDNAs not homologous to the host genome; (iii) single strand annealing (SSA) proteins, DprA and RecO, anneal the SsbA- or SsbB-coated complementary strands, yielding tailed SPP1 duplex intermediates; (iv) RecA polymerized on these tailed intermediates invades a homologous region in another incomplete molecule, and in concert with RecD2 helicase, reconstitutes a complete linear phage genome with redundant regions at the ends of the molecule; and (v) DprA, RecO or viral G35P SSA, may catalyze the annealing of these terminally redundant regions, alone or with the help of an exonuclease, to produce a circular unit-length duplex viral genome ready to initiate replication.

Degradation and Deactivation of Bacterial Antibiotic Resistance Genes during Exposure to Free Chlorine, Monochloramine, Chlorine Dioxide, Ozone, Ultraviolet Light, and Hydroxyl Radical

This work investigated degradation (measured by qPCR) and biological deactivation (measured by culture-based natural transformation) of extra- and intracellular antibiotic resistance genes (eARGs and iARGs) by free available chlorine (FAC), NH₂Cl, O₃, ClO₂, and UV light (254 nm), and of eARGs by ^•OH, using a chromosomal ARG ( blt) of multidrug-resistant Bacillus subtilis 1A189. Rate constants for degradation of four 266-1017 bp amplicons adjacent to or encompassing the acfA mutation enabling blt overexpression increased in proportion to #AT+GC bps/amplicon, or in proportion to #5'-GG-3' or 5'-TT-3' doublets/amplicon, with respective values ranging from 0.59 to 2.3 (×10¹¹ M^-1 s^-1) for ^•OH, 1.8-6.9 (×10⁴ M^-1 s^-1) for O₃, 3.9-9.2 (×10³ M^-1 s^-1) for FAC, 0.35-1.2(×10¹ M^-1 s^-1) for ClO₂, and 2.0-8.8 (×10^-2 cm²/mJ) for UV at pH 7, and from 1.7-4.4 M^-1 s^-1 for NH₂Cl at pH 8. For FAC, NH₂Cl, O₃, ClO₂, and UV, ARG deactivation paralleled degradation of amplicons approximating a ∼800-1000 bp acfA-flanking sequence required for natural transformation in B. subtilis, whereas deactivation outpaced degradation for ^•OH. At practical disinfectant exposures, eARGs and iARGs were ≥90% degraded/deactivated by FAC, O₃, and UV, but recalcitrant to NH₂Cl and ClO₂. iARG degradation/ deactivation always lagged cell inactivation. These findings provide a quantitative framework for evaluating ARG fate during disinfection/oxidation, and support using qPCR as a proxy for tracking ARG deactivation under carefully selected circumstances.

The cell pole: the site of cross talk between the DNA uptake and genetic recombination machinery

Natural transformation is a programmed mechanism characterized by binding of free double-stranded (ds) DNA from the environment to the cell pole in rod-shaped bacteria. In Bacillus subtilis some competence proteins, which process the dsDNA and translocate single-stranded (ss) DNA into the cytosol, recruit a set of recombination proteins mainly to one of the cell poles. A subset of single-stranded binding proteins, working as "guardians", protects ssDNA from degradation and limit the RecA recombinase loading. Then, the "mediators" overcome the inhibitory role of guardians, and recruit RecA onto ssDNA. A RecA·ssDNA filament searches for homology on the chromosome and, in a process that is controlled by "modulators", catalyzes strand invasion with the generation of a displacement loop (D-loop). A D-loop resolvase or "resolver" cleaves this intermediate, limited DNA replication restores missing information and a DNA ligase seals the DNA ends. However, if any step fails, the "rescuers" will repair the broken end to rescue chromosomal transformation. If the ssDNA does not share homology with resident DNA, but it contains information for autonomous replication, guardian and mediator proteins catalyze plasmid establishment after inhibition of RecA. DNA replication and ligation reconstitute the molecule (plasmid transformation). In this review, the interacting network that leads to a cross talk between proteins of the uptake and genetic recombination machinery will be placed into prospective.

Effect of Food Processing on the Fate of DNA with Regard to Degradation and Transformation Capability in Bacillus subtilis

Soymilk, tofu, corn masa, and cooked potato were produced from transgenic raw materials and the effect of processing on the degradation of DNA was studied. Major degrading factors were for soymilk and tofu the mechanical treatment of soaked soybeans and for corn masa and cooked potatoes the thermal treatment. In the processed foods no DNA fragments > 1.1 kb were detected. We included in our studies the effect of the size of donor DNA and length of the homologous sequence on the marker rescue transformation of B. subtilis LTH 5466, which was monitored by restoration of deleted nptII. When DNA fragments (168, 414, 658, and 792 bp) of nptII and linearized plasmid DNA (pGEM-T-1, 3168 bp and pGEM-T-2, 3792 bp) containing the 168 bp or 792 bp fragments, respectively, were used as donor DNA, it was observed that the efficiency of marker rescue decreased with decreasing length of homologous sequence. The use of a larger plasmid (pMR2, 5786 bp) containing the 792 bp fragment revealed higher efficiency of marker rescue compared to pGEM-T-2. The nptII fragments resulted in lower efficiencies compared to plasmid DNA containing the same fragment. For the 792 bp fragment and the linearized plasmid pMR2 a first-order dependency of the frequency of marker rescue transformation on the DNA concentration was observed. Based on the acquired data, the hypothetical frequency of transformation of transgenic DNA to B. subtilis in cooked potatoes was calculated to be equal to 8.5 x 10(-19) and 1.2 x 10(-27) for homologous and illegitimate recombination, respectively. These data permit to roughly estimate the time after which a person (10(8) years) or the world population (15 days) is exposed to one transformant generated by homologous recombination event, when the daily consumption per person is 130 g of cooked potatoes.

Bacterial gene transfer by natural genetic transformation in the environment

Natural genetic transformation is the active uptake of free DNA by bacterial cells and the heritable incorporation of its genetic information. Since the famous discovery of transformation in Streptococcus pneumoniae by Griffith in 1928 and the demonstration of DNA as the transforming principle by Avery and coworkers in 1944, cellular processes involved in transformation have been studied extensively by in vitro experimentation with a few transformable species. Only more recently has it been considered that transformation may be a powerful mechanism of horizontal gene transfer in natural bacterial populations. In this review the current understanding of the biology of transformation is summarized to provide the platform on which aspects of bacterial transformation in water, soil, and sediments and the habitat of pathogens are discussed. Direct and indirect evidence for gene transfer routes by transformation within species and between different species will be presented, along with data suggesting that plasmids as well as chromosomal DNA are subject to genetic exchange via transformation. Experiments exploring the prerequisites for transformation in the environment, including the production and persistence of free DNA and factors important for the uptake of DNA by cells, will be compiled, as well as possible natural barriers to transformation. The efficiency of gene transfer by transformation in bacterial habitats is possibly genetically adjusted to submaximal levels. The fact that natural transformation has been detected among bacteria from all trophic and taxonomic groups including archaebacteria suggests that transformability evolved early in phylogeny. Probable functions of DNA uptake other than gene acquisition will be discussed. The body of information presently available suggests that transformation has a great impact on bacterial population dynamics as well as on bacterial evolution and speciation.

Homologous recombination between plasmid and chromosomal DNA in Bacillus subtilis requires approximately 70 bp of homology

To determine the minimal DNA sequence homology required for recombination in Bacillus subtilis, we developed a system capable of distinguishing between homologous and illegitimate recombination events during plasmid integration into the chromosome. In this system the recombination frequencies were measured between ts pE194 derivatives carrying segments of the chromosomal beta-gluconase gene (bglS) of various lengths and the bacterial chromosome, using selection for erythromycin resistance at the non-permissive temperature. Homologous recombination events, resulting in disruption of the bglS gene, were easily detected by a colorimetric assay for beta-gluconase activity. A linear dependence of recombination frequency on homology length was observed over an interval of 77 bp. It was found that approximately 70 bp of homology is required for detectable homologous recombination. Homologous recombination was not detected when only 25 bp of homology between plasmid and chromosome were provided. The data indicate that homology requirements for recombination in B. subtilis differ from those in Escherichia coli.

Streptococcus pneumoniae DNA polymerase I lacks 3'-to-5' exonuclease activity: localization of the 5'-to-3' exonucleolytic domain

The Streptococcus pneumoniae polA gene was altered at various positions by deletions and insertions. The polypeptides encoded by these mutant polA genes were identified in S. pneumoniae. Three of them were enzymatically active. One was a fused protein containing the first 11 amino acid residues of gene 10 from coliphage T7 and the carboxyl-terminal two-thirds of pneumococcal DNA polymerase I; it possessed only polymerase activity. The other two enzymatically active proteins, which contained 620 and 351 amino acid residues from the amino terminus, respectively, lacked polymerase activity and showed only exonuclease activity. These two polymerase-deficient proteins and the wild-type protein were hyperproduced in Escherichia coli and purified. In contrast to the DNA polymerase I of Escherichia coli but similar to the corresponding enzyme of Thermus aquaticus, the pneumococcal enzyme appeared to lack 3'-to-5' exonuclease activity. The 5'-to-3' exonuclease domain was located in the amino-terminal region of the wild-type pneumococcal protein. This exonuclease activity excised deoxyribonucleoside 5'-monophosphate from both double- and single-stranded DNAs. It degraded oligonucleotide substrates to a decameric final product.

Genetic competence in Bacillus subtilis

Genetic competence may be defined as a physiological state enabling a bacterial culture to bind and take up high-molecular-weight exogenous DNA (transformation). In Bacillus subtilis, competence develops postexponentially and only in certain media. In addition, only a minority of the cells in a competent culture become competent, and these are physiologically distinct. Thus, competence is subject to three regulatory modalities: growth stage specific, nutritionally responsive, and cell type specific. This review summarizes the present state of knowledge concerning competence in B. subtilis. The study of genes required for transformability has permitted their classification into two broad categories. Late competence genes are expressed under competence control and specify products required for the binding, uptake, and processing of transforming DNA. Regulatory genes specify products that are needed for the expression of the late genes. Several of the late competence gene products have been shown to be membrane localized, and others are predicted to be membrane associated on the basis of amino acid sequence data. Several of these predicted protein sequences show a striking resemblance to gene products that are involved in the export and/or assembly of extracellular proteins and structures in gram-negative organisms. This observation is consistent with the idea that the late products are directly involved in transport of DNA and is equally consistent with the notion that they play a morphogenetic role in the assembly of a transport apparatus. The competence regulatory apparatus constitutes an elaborate signal transduction system that senses and interprets environmental information and passes this information to the competence-specific transcriptional machinery. Many of the regulatory gene products have been identified and partially characterized, and their interactions have been studied genetically and in some cases biochemically as well. These include several histidine kinase and response regulator members of the bacterial two-component signal transduction machinery, as well as a number of known transcriptionally active proteins. Results of genetic studies are consistent with the notion that the regulatory proteins interact in a hierarchical way to make up a regulatory pathway, and it is possible to propose a provisional scheme for the organization of this pathway. It is remarkable that almost all of the regulatory gene products appear to play roles in the control of various forms of postexponential expression in addition to competence, e.g., sporulation, degradative-enzyme production, motility, and antibiotic production. This has led to the notion of a signal transduction network which transduces environmental information to determine the levels and timing of expression of the ultimate products characteristic of each of these systems.

Inhibition of growth of Bacillus subtilis by recombinant plasmid pCED3

The present study deals with the mechanism by which plasmid pCED3 interferes with the growth of Bacillus subtilis. Plasmid pCED3 was constructed from pUB110 and pBR322 and contains the lacZ gene attached to the B. subtilis tms promoter. Plasmid derivatives that contain mutations in the tms promoter were used to examine the effect of promoter strength on cell growth, plasmid stability, the amount of plasmid DNA per cell and the activities of plasmid-encoded enzymes, i.e., beta-galactosidase and kanamycin nucleotidyltransferase (KNT). Efficient lacZ transcription directed from the tms promoter resulted in reduction in growth rate and plasmid stability without an increase in beta-galactosidase activity. The amount of plasmid DNA varied between 6.6 and 12.9 pmol per mg cell protein and showed no clear correlation with the strength of the tms promoter. Transcription from the tms promoter inhibited the expression of the plasmid-encoded kanamycin resistance gene resulting in the reduction of both beta-galactosidase activity and growth rate in the presence of kanamycin. These results suggest that the negative effect on B. subtilis growth exerted by pCED3 results at least partly from a decrease in kanamycin resistance by plasmid-bearing cells.

Effect of ermC leader region mutations on induced mRNA stability

Induction of translation of the ermC gene product in Bacillus subtilis occurs upon exposure to erythromycin and is a result of ribosome stalling in the ermC leader peptide coding sequence. Another result of ribosome stalling is stabilization of ermC mRNA. The effect of leader RNA secondary structure, methylase translation, and leader peptide translation on induced ermC mRNA stability was examined by constructing various mutations in the ermC leader region. Analysis of deletion mutations showed that ribosome stalling causes induction of ermC mRNA stability in the absence of methylase translation and ermC leader RNA secondary structure. Furthermore, deletions that removed much of the leader peptide coding sequence had no effect on induced ermC mRNA stability. A leader region mutation was constructed such that ribosome stalling occurred in a position upstream of the natural stall site, resulting in induced mRNA stability without induction of translation. This mutation was used to measure the effect of mRNA stabilization on ermC gene expression.

Novel plasmid marker rescue transformation system for molecular cloning in Bacillus subtilis enabling direct selection of recombinants

A versatile plasmid marker rescue transformation system was developed for homology-facilitated cloning in Bacillus subtilis. It is based on the highly efficient host-vector system 6GM15-pHPS9, which allows the direct selection of recombinants by means of beta-galactosidase alpha-complementation. The system offers several advantages over previously described cloning systems: (1) the convenient direct selection of recombinants; (2) the ability to effectively transform B. subtilis competent cells with plasmid monomers, which allows the forced cloning of DNA fragments with high efficiency; (3) the availability of 6 unique target sites, which can be used for direct clone selection, SphI, NdeI, NheI, BamHI, SmaI and EcoRI; and (4) the rapid segregational loss of the helper plasmid from the transformed cells.

A Bacillus subtilis regulatory gene product for genetic competence and sporulation resembles sensor protein members of the bacterial two-component signal-transduction systems

A Bacillus subtilis gene, required for genetic competence, was identified immediately upstream from the previously characterized gene comA. The comA gene product has been found to exhibit amino acid sequence similarity to the so-called effector class of signal-transduction proteins. DNA sequencing of the new determinant, named comP, revealed that the carboxy-terminal domain of the predicted ComP protein is similar in amino acid sequence to that of several sensor members of the bacterial two-component signal-transduction systems. The predicted amino-terminal domain contains several hydrophobic segments, postulated to be membrane-spanning. In vitro-derived comP disruptions are epistatic on the expression of all late competence genes tested, including comG, comC, comD, and comE, but not on expression of the early gene comB. Although comA has its own promoter, some transcription of comA, especially later in growth, occurs via readthrough from comP sequences. A roughly twofold epistatic effect of a comP disruption was noted on the downstream comA determinant, possibly due to interruption of readthrough transcription from comP to comA. Overexpression of comA fully restored competence to a comP mutant, providing evidence that ComA acts after ComP, and consistent with a role for the latter protein in activation of the former, possibly by phosphorylation. ComP probably is involved in transmitting information concerning the nutritional status of the medium, particularly the presence of nitrogen- and carbon-containing nutrients. ComP was also shown to play a role in sporulation, at least partly interchangeable with that of SpoIIJ, another putative sensor protein.

Transformation of Bacillus polymyxa with plasmid DNA

A plasmid transformation system was developed for Bacillus polymyxa ATCC 12321 and derivatives of this strain. The method utilizes a penicillin-treated-cell technique to facilitate uptake of the plasmid DNA. Low-frequency transformation (10(-6) per recipient cell) of plasmids pC194, pBD64, and pBC16 was accomplished with this method. Selection for the transformants was accomplished on both hypertonic and nonhypertonic selective media, with the highest rates of recovery occurring on a peptone-glucose-yeast extract medium containing 0.25 M sucrose. Several additional plasmids were shown to be capable of transferring their antibiotic resistance phenotypes to B. polymyxa through the use of a protoplast transformation procedure which allowed for a more efficient transfer of the plasmid DNA. However, cell walls could not be regenerated on the transformed protoplasts, and the transformants could not be subcultured from the original selective media.

Sequence and transcription mapping of Bacillus subtilis competence genes comB and comA, one of which is related to a family of bacterial regulatory determinants

The complete nucleotide sequences of the comA and comB loci of Bacillus subtilis were determined. The products of these genes are required for the development of competence in B. subtilis and for the expression of late-expressing competence genes. The major 5' termini of both the comA and comB transcripts were determined. The inferred promoters of both comA and comB contained sequences that were similar to those found at the -10 and -35 regions of promoters that are used by sigma A-RNA polymerase, the primary form of this enzyme in vegetative cells. The comB gene was located approximately 3 kilobase pairs upstream of the comA gene and encoded a 409-amino-acid protein with a predicted molecular weight of 46,693. The comA locus contained two open reading frames (ORFs) and comB contained one ORF. The predicted amino acid sequence of the comA ORF1 gene product consisted of 214 amino acids, with an aggregate molecular weight of 24,132. The ORF1 product was required for competence, while ORF2, which was cotranscribed with ORF1 and encoded a predicted protein of 126 amino acids, was not. The predicted protein sequence of the comA ORF1 gene product was found to be similar to that of several members of the effector class of procaryotic signal transducers. The C-terminal portion of the predicted comA sequence contained a possible helix-turn-helix motif, which is characteristic of DNA-binding proteins. comA ORF1 was cloned on a multicopy plasmid and was shown to complement the competence-deficient phenotype caused by the comA124 insertion of Tn917lac. Also, the presence of comA ORF1 in multiple copies interfered with sporulation. Anti-peptide antibodies raised to the predicted product of comA ORF1 reacted strongly with a single protein band of about 24,000 daltons in immunoblots. The possible roles of multiple signal transduction systems in triggering the development of competence are discussed.

Identification of plasmid and Bacillus subtilis chromosomal recombination sites used for pE194 integration

The plasmid pE194 (3.7 kilobases) is capable of integrating into the genome of the bacterial host Bacillus subtilis in the absence of the major homology-dependent RecE recombination system. Multiple recombination sites have been identified on both the B. subtilis chromosome and pE194 (J. Hofemeister, M. Israeli-Reches, and D. Dubnau, Mol. Gen. Genet. 189:58-68, 1983). The B. subtilis chromosomal recombination sites were recovered by genetic cloning, and these sites were studied by nucleotide sequence analysis. Recombination had occurred between regions of short nucleotide homology (6 to 14 base pairs) as indicated by comparison of the plasmid and the host chromosome recombination sites with the crossover sites of the integration products. Recombination between the homologous sequences of the plasmid and the B. subtilis genome produced an integrated pE194 molecule which was bounded by direct repeats of the short homology. These results suggest a recombination model involving a conservative, reciprocal strand exchange between the two recombination sites. A preferred plasmid recombination site was found to occur within a 70-base-pair region which contains a GC-rich dyad symmetry element. Five of seven pE194-integrated strains analyzed had been produced by recombination at different locations within this 70-base-pair interval, located between positions 860 and 930 in pE194. On the basis of these data, mechanisms are discussed to explain the recombinational integration of pE194.

Transformation-deficient mutants of piliated Neisseria gonorrhoeae

Seven transformation-deficient mutants of piliated, competent Neisseria gonorrhoeae were isolated by screening them for their inability to be transformed by chromosomal DNA after chemical mutagenesis. Three distinct classes of mutants were obtained, each of which was piliated, as determined by electron microscopy. One class exhibited abnormal colony morphology and was unable to take up DNA into a DNase-resistant state. A second class was morphologically normal and took up DNA into a DNase-resistant state normally, but was deficient in both chromosomal and plasmid transformation; mutations in these mutants may affect entry of DNA into the cell proper. A third class was similar to the second but was fully competent for plasmid transformation, suggesting that there was a defect in a late stage of chromosomal transformation.

Plasmid marker rescue transformation proceeds by breakage-reunion in Bacillus subtilis

Bacillus subtilis carrying a plasmid which replicates with a copy number of about 1 was transformed with linearized homologous plasmid DNA labeled with the heavy isotopes 2H and 15N, in the presence of 32Pi and 6-(p-hydroxyphenylazo)-uracil to inhibit DNA replication. Plasmid DNA was isolated from the transformed culture and fractionated in cesium chloride density gradients. The distribution of total and donor plasmid DNA was examined, using specific hybridization probes. The synthesis of new DNA, associated with the integration of donor moiety, was also monitored. Donor-specific sequences were present at a density intermediate between that of light and hybrid DNA. This recombinant DNA represented 1.4% of total plasmid DNA. The latter value corresponded well with the transforming activity (1.7%) obtained for the donor marker. Newly synthesized material associated with plasmid DNA at the recombinant density amounted to a minor portion of the recombinant plasmid DNA. These data suggest that, like chromosomal transformation, plasmid marker rescue transformation does not require replication for the integration of donor markers and, also like chromosomal transformation, proceeds by a breakage-reunion mechanism. The extent of donor DNA replacement of recipient DNA per plasmid molecule of 54 kilobases (27 kilobase pairs) was estimated as 16 kilobases.

Linearization of donor DNA during plasmid transformation in Neisseria gonorrhoeae

We examined the fate of plasmid DNA after uptake during transformation in Neisseria gonorrhoeae. An 11.5-kilobase plasmid, pFA10, was processed to linear double-stranded DNA during uptake by competent cells, but cleavage of pFA10 was not site specific. A minority of pFA10 entered as open circles. A 42-kilobase plasmid, pFA14, was degraded into small fragments during uptake; no intracellular circular forms of pFA14 were evident. Since pFA10 DNA linearized by a restriction enzyme was not further cut during uptake, the endonucleolytic activity associated with entry of plasmid DNA appeared to act preferentially on circular DNA. Although linear plasmid DNA was taken up into a DNase-resistant state as efficiently as circular DNA, linear plasmid DNA transformed much less efficiently than circular plasmid DNA. These data suggest that during entry transforming plasmid DNA often is processed to double-stranded linear molecules; transformants may arise when some molecules are repaired to form circles. Occasional molecules which enter as intact circles may also lead to transformants.

Construction of isogenic gonococcal strains varying in the presence of a 4.2-kilobase cryptic plasmid

A 4.2-kilobase (kb) cryptic plasmid is present in 96% of isolates of Neisseria gonorrhoeae. An inability to construct isogenic derivatives which vary in the presence of the 4.2-kb plasmid has prevented the study of its function. We report a method to deliver an intact 4.2-kb plasmid into plasmidless gonococcal strains. The method involved transformation with novel 15.7-kb hybrid penicillinase-producing (Pcr) plasmids, which were cointegrates containing two copies of the 4.2-kb plasmid arranged in tandem direct repeat plus one copy of the 7.2-kb Pcr plasmid pFA3. When the 15.7-kb hybrid Pcr plasmids were introduced into a gonococcal recipient lacking evident plasmids, they dissociated at a relatively high frequency into plasmids identical to their parents: the 4.2-kb cryptic plasmid and pFA10 (a stable 11.5-kb plasmid containing one copy of each of the 7.2-kb Pcr plasmid pFA3 and the 4.2-kb cryptic plasmid pFA1). Curing strains of their Pcr plasmids resulted in isogenic strains which varied only in the presence of the 4.2-kb plasmid. The presence of the autonomously replicating 4.2-kb plasmid did not affect a number of tested phenotypes, including auxotype, antibiotic sensitivity, and frequencies of variation of outer membrane protein II. The interpretation of the functional significance of the 4.2-kb plasmid was complicated, however, by the additional finding that each of three tested plasmid-free strains contained a chromosomal fragment of about 1.6 kb that hybridized under moderate stringency with a 1.65-kb HinfI fragment of the 4.2-kb plasmid.

Homology-facilitated plasmid transfer in Haemophilus influenzae

The 8 kbp plasmid pAT4 transformed Haemophilus influenzae Rd cells at low frequencies. Transformation was increased up to 100 times, however, when the recipient cells carried a DNA segment in either their chromosome or in a resident plasmid that was homologous to at least part of plasmid pAT4. Linearized plasmid DNA molecules did not transform cells without DNA homology; they efficiently transformed homology recipients, but only when the cuts had been made in the region of shared homology. In most cases examined the circular donor plasmid had been reconstituted from the transforming DNA; in some cases the reconstituted plasmid carried a mutation initially present in the recipient chromosome, provided the transforming plasmid had been linearized in the region of shared homology. Plasmid reconstitution was not observed in recA1 cells. We conclude that homology-facilitated plasmid transformation (transfer) is similar to that reported for Bacillus subtilis and Streptococcus pneumoniae.

Transformation in cyanobacteria

The lack of any known transduction or indigenous conjugation systems has left transformation as the major means for genetic manipulations in cyanobacteria. Studies of transformation in cyanobacteria generally have dealt with one of two distinct areas. The first area is genomic transformation where internalized donor DNA recombines with chromosomally located genes. Chromosomal transformation can be a powerful tool for genetic mapping and mutagenesis. The second area is plasmid transformation where internalized plasmid donor DNA becomes established as an independent replicon in the recipient cyanobacterium. This second area has received a great deal of attention because it allows the generation of merodiploids for studies of genetic regulation and control and because it potentially allows the expression of foreign genes in an oxygenic photoautotroph. This article will attempt to describe the development of our current understanding of these two types of genetic transformation in cyanobacteria.

Integration of linear, heterologous DNA molecules into the Bacillus subtilis chromosome: mechanism and use in induction of predictable rearrangements

Linear DNA molecules composed of a central region nonhomologous with the Bacillus subtilis chromosome and two flanking regions homologous with the chromosome can integrate into the chromosome, provided that the homologous regions have the same relative orientation. The resulting chromosome can be maintained in a haploid or in a merodiploid cell together with a parental chromosome. This can most easily be explained by supposing that the integration occurs by crossing over at each homologous region and that a part of the chromosome between these regions is deleted and replaced by the central nonhomologous region of the integrating molecule. If no essential genes were replaced during that process a haploid cell would be obtained; if essential genes were replaced a merodiploid cell would be obtained. The use of appropriate linear molecules therefore should allow the induction of deletions, extending from a given chromosomal site in a predetermined direction, and defined duplications in the B. subtilis chromosome.

Analysis of plasmid deletional instability in Bacillus subtilis

Using a model system, we have studied deletion formation in Bacillus subtilis. When the staphylococcal plasmids pSA2100 (7.1 kilobases) and pUB110 (4.5 kilobases) were ligated to one another at their unique XbaI sites and transformed into either rec+ or recE4 strains of B. subtilis, an intramolecular recombination event usually occurred. Two plasmids, one of 2.6 kilobases and the other of 9.0 kilobases, were consistently isolated and shown by restriction enzyme analysis to be derived by recombination occurring in the pSA2100-pUB110 cointegrate. Analysis of the sequence of the junctions of the recombinant plasmids and of the crossover regions of the parental plasmids suggested that a reciprocal, conservative, intramolecular recombination event had occurred between short 18-base-pair homologous sequences that were oriented as direct repeats and bounded by regions of dyad symmetry. Evidence is presented that the above illegitimate recombination event is biased to occur intramolecularly and that randomly chosen direct repeats of either 22 or 29 base pairs are not sufficient to support recombination. The recombination event occurs in recA1, recB2, recD3, recE5, recL16, recM13, polA59, polA13, uvr-22, uvr-13, and stb mutants of B. subtilis and does not require that the competent state be established.

Translationally coupled initiation of protein synthesis in Bacillus subtilis

The neomycin phosphotransferase gene (neo) from Transposon Tn5 is active in Gram-negative bacteria but silent in B. subtilis since it lacks an appropriate ribosome binding site for Gram-positive bacteria. Neo translation could be reactivated by coupling its initiation to the translational termination of the highly expressed beta-lactamase gene (penP) from B. licheniformis. This initiation occurred at the authentic neo start codon. Its efficiency was independent of the nucleotide sequence 5 to the neo gene, but strongly affected by the distance between the termination and initiation codon. It was the highest if both codons overlapped in the sequence ATGA. In B. licheniformis, a translationally coupled neo gene was inducible expressed as the penP gene demonstrating the potential of the technique to monitor the activity of expression units for which no direct assays exists.

Insertion of eukaryotic DNA into the Bacillus subtilis genome by means of a temperature-sensitive plasmid vector

A hybrid temperature-sensitive plasmid capable of integration into the Bacillus subtilis genome was constructed. By using this vector, we inserted a 3.2-kb fragment of eukaryotic DNA (wheat 'Chinese Spring') into the bacterial genome. The fragment of wheat DNA was stably retained and replicated as a part of the bacterial genome. The position of the integrated plasmid in the B. subtilis genome was mapped, as was the site in wheat DNA insert on plasmid at which the integration occurred.

A new sensitive method for qualitative and quantitative assay of neomycin phosphotransferase in crude cell extracts

A general method is described for the detection and quantification of low amounts of neomycin phosphotransferase in crude cell extracts. The assay is based on the electrophoretic separation of the enzyme from other interfering proteins and detection of its enzymatic activity by in situ phosphorylation of the antibiotic kanamycin. Both kanamycin and [gamma-32P]ATP acting as substrates are embedded in an agarose gel placed on the polyacrylamide gel containing the separated proteins. After the enzymatic reaction, the phosphorylated kanamycin is transferred to P81 phosphocellulose ion exchange paper and the radiolabeled kanamycin is visualised by autoradiography. With this method 1 ng of active enzyme can easily be detected. Both prokaryotic and eukaryotic cell extracts can be examined, and changes in the size of enzymatically active proteins can be determined.

A novel method for the rapid cloning in Escherichia coli of Bacillus subtilis chromosomal DNA adjacent to Tn917 insertions

A rapid and general procedure has been devised for the pBR322-mediated cloning in Escherichia coli of Bacillus subtilis chromosomal DNA extending in a specified direction from any Tn917 insertion. Derivatives of Tn917 have been constructed that contain a pBR322-derived replicon, together with a chloramphenicol-resistance (Cmr) gene of Gram-positive origin (selectable in B. subtilis), inserted by ligation in two orientations into a SalI restriction site located near the center of the transposon. When linearized plasmid DNA carrying such derivatives was used to transform to Cmr B. subtilis bacteria already containing a chromosomal insertion of Tn917, the pBR322 sequences efficiently became integrated into the chromosomal copy of the transposon by homologous recombination. It was then possible to clone chromosomal sequences adjacent to either transposon insertion junction into E. coli, using a selection for ampicillin-resistance, by transforming CaCl2-treated cells with small amounts of insert-containing DNA that had been digested with various restriction enzymes and then ligated at a dilute concentration. Because pBR322 sequences may be inserted by recombination in either orientation with respect to the transposon arms, a single restriction enzyme (such as EcoRI or SphI) that has a unique recognition site in pBR322 DNA may be used to separately clone chromosomal DNA extending in either direction from the site of any transposon insertion. A family of clones generated from the region of an insertional spo mutation (spoIIH::Tn917) was used in Southern hybridization experiments to verify that cloned material isolated with this procedure accurately reflected the arrangement of sequences present in the chromosome. Strategies are discussed for taking advantage of certain properties inherent in the structure of clones generated in this way to facilitate the identification and study of promoters of insertionally mutated genes.

Construction of a cloning site near one end of Tn917 into which foreign DNA may be inserted without affecting transposition in Bacillus subtilis or expression of the transposon-borne erm gene

A 1.3-kb restriction fragment carrying a cat gene derived from Staphylococcus aureus was inserted by ligation in both possible orientations into a HpaI restriction site located less than 300 bp from one end of Tn917. The resulting transposon derivatives were unimpaired in their ability to make and resolve transpositions into the chromosome of Bacillus subtilis and they displayed no detectable defect in expression of the inducible erm gene carried by the transposon. This demonstrates that the HpaI site itself, and perhaps the entire 250- to 300-bp region between the HpaI site and the nearest transposon terminal inverted repeat consists of nonessential DNA, and is there fore available to be modified or used as a cloning site with the expectation that the resulting transposon derivatives should be capable of normal transposition activity. To facilitate such manipulations, the HpaI site was "replaced" by a 24-bp DNA segment which contains a BamHI site flanked on either side by SmaI sites; these BamHI and SmaI sites are unique to the transposon. Several of the plasmid constructions undertaken in the course of this work illustrate ways in which homologous recombination may be used in conjunction with ligation in B. subtilis (and other bacteria, such as Streptococcus pneumoniae, which have similar mechanisms for DNA uptake during competence) to facilitate significantly the recovery of certain kinds of recombinant molecules.

Length of foreign DNA in chimeric plasmids determines the efficiency of its integration into the chromosome of the cyanobacterium Synechococcus R2

The photosynthetic cyanobacterium Synechococcus R2 is efficiently transformed by DNA molecules that contain antibiotic genes from Escherichia coli linked to a segment of Synechococcus R2 chromosomal DNA. Antibiotic-resistant transformants result from integration of donor DNA into the cyanobacterial chromosome by homologous recombination. Foreign DNA interrupting the cyanobacterial sequence in the donor molecule integrates by replacement of homologous recipient DNA with donor DNA containing the foreign insert. Foreign DNA linked to the ends of the cyanobacterial fragment in a circular donor molecule integrates by a reciprocal cross-over between donor and recipient sequences. Using donor molecules that contain different lengths of foreign DNA in both of the above positions, we have determined that the probability of integration decreases by half for each increase of 2 to 3 kb in length of a foreign segment, regardless of its position in the donor molecule. The length of one of the two foreign segments has no effect on the integration of the other. Foreign DNA 20 kb in length is completely stable when it has integrated by the replacement mechanism. The ability to stably introduce large pieces of foreign DNA makes Synechococcus R2 an attractive organism in which to study and modify both native and heterologous genes involved in oxygenic photosynthesis.

Molecular cloning in Bacillus subtilis of a Bacillus licheniformis gene encoding a thermostable alpha amylase

A resident-plasmid cloning system developed for Bacillus subtilis has been used to isolate recombinant plasmids carrying DNA from Bacillus licheniformis which confer alpha-amylase activity on alpha-amylase-negative mutants of B. subtilis. These plasmids contain a 3550-bp insert at the EcoRI site of the plasmid pBD64. Subcloning various lengths of the B. licheniformis DNA has localised the gene to a 2550-bp BclI fragment. We present evidence that the cloned fragment codes for a B. licheniformis heat-stable alpha-amylase with a temperature optimum of 93 degrees C. The foreign gene is expressed efficiently in B. subtilis and is stably maintained.

Stable integration of foreign DNA into the chromosome of the cyanobacterium Synechococcus R2

The blue-green alga, Synechococcus R2, is transformed to antibiotic resistance by chimeric DNA molecules consisting of Synechococcus R2 chromosomal DNA linked to antibiotic-resistance genes from Escherichia coli. Chimeric DNA integrates into the Synechococcus R2 chromosome by homologous recombination. The efficiency of transformation, as well as the stability of integrated foreign DNA, depends on the position of the foreign genes relative to Synechococcus R2 DNA in the chimeric molecule. When the Synechococcus R2 DNA fragment is interrupted by foreign DNA, integration occurs through replacement of chromosomal DNA by homologous chimeric DNA containing the foreign insert; transformation is efficient and the foreign gene is stable. Mutagenesis in some cases attends integration, depending on the site of insertion. Foreign DNA linked to the ends of Synechococcus R2 DNA in a circular molecule, however, integrates less efficiently. Integration results in duplicate copies of Synechococcus R2 DNA flanking the foreign gene and the foreign DNA is unstable. Transformation in Synechococcus R2 can be exploited to modify precisely and extensively the genome of this photosynthetic microorganism.

Intermolecular recombination during transformation of Bacillus subtilis competent cells by monomeric and dimeric plasmids

Bacillus subtilis competent cells harboring plasmid pUB110 were transformed by plasmids unable to replicate in this host but carrying segments of pUB110, 260 to 4500 bp long. Recombinants between the incoming and the resident plasmids were found in the transformed cells. Transforming efficiency of the incoming plasmids depended strongly on their molecular form and the length of their region homologous with the resident plasmid. It increased with the fourth to fifth power of that length for monomers having at least 900 bp of homology. Activity of monomers having less than 900 bp homology was too low to be measured in our experiments. Transforming efficiency of dimers was much greater than that of monomers, and varied with the square of the length of the homologous region. These results indicate that dimeric and monomeric plasmid molecules are processed differently during transformation of B. subtilis competent cells.

Prospects for development and use of recombinant deoxyribonucleic acid techniques with ruminal bacteria

Over the last decade, developments in recombinant deoxyribonucleic acid techniques and molecular biology have revolutionized bacterial genetics, creating vast, new potential uses of bacteria (as well as animal and plant cells) that were not even considered previously. Bacterial production of hormones is but one example. With bacterial species with well developed genetic systems, such as Escherichia coli, it is now possible genetically to "design" or "engineer" bacterial strains having specific characteristics. One reasonable future approach toward improvement of animal agriculture would be manipulation of the rumen ecosystem via the use of genetically modified ruminal bacteria, but significant obstacles exist with this approach. Genetic systems of ruminal and of anaerobic bacteria of the mammalian gastrointestinal tract, in general, have not been studied and are largely unknown. In this paper, the various criteria for possible establishment of recombinant deoxyribonucleic acid systems in ruminal bacteria are outlined. Secondly, applications for utilizing genetically engineered ruminal bacteria to control digestion of specific feedstuffs, to regulate specific fermentation products, and to control growth of specific bacterial species are discussed.

Plasmid marker rescue transformation in Bacillus subtilis

We constructed an 18-megadalton plasmid (pBD221) carrying resistance determinants for kanamycin, chloramphenicol, and erythromycin, as well as the hisH determinant from the Bacillus licheniformis chromosome. This plasmid has a copy number of about one and can be stably maintained in Bacillus subtilis. Linear fragments of pBD221 DNA were used to transform competent cultures carrying mutant variants of the same plasmid. Rescue transformation did not proceed by recircularization and replication of the donor DNA. Rescue transformation exhibited first-order dependence on DNA concentration, and the concentration dependence curve was virtually identical to the curve obtained with chromosomal DNA. The donor DNA molecular weight dependence of plasmid marker rescue transformation obtained by using restriction fragments was not distinguishable from previously published data obtained by using fractionated sheared chromosomal DNA. Plasmid rescue transformation, like chromosomal transformation, was dependent on the recE, recA, recB, and recD gene products. Plasmid rescue transformation, like chromosomal transformation, proceeded with few exchanges. Linkage data obtained with the plasmid rescue system fit a quantitative model based on studies with chromosomal transformation. We conclude that plasmid marker rescue transformation probably proceeds by a mechanism similar to the mechanism used during the formation of chromosomal transformants and hence may be considered an appropriate general model for the study of transformational recombination.

Insertion of foreign functioning DNA into the Bacillus subtilis chromosome

Following the restriction and ligation of pBD12 plasmid and phi 105 phage DNA and subsequent transformation, the insertion of pBD12 DNA into the phi 105 prophage region of the Bacillus subtilis chromosome was achieved. The plasmid markers were linked with the region of prophage immunity and with the markers of the adjacent region of the B. subtilis chromosome. Their behaviour in transformation of cells and protoplasts of rec+ recipients and recE4 mutants was typical of chromosomal markers. The phenotypic expression (resistance to chloramphenicol and kanamycin) of plasmid genes inserted into the chromosome was preserved; however, the resistance levels were reduced.

Direct selection of recombinant plasmids in Bacillus subtilis

A system is described which permits the direct, positive selection of recombinant plasmids in Bacillus subtilis. This system relies on the plasmid pBD214 which confers chloramphenicol (Cm) resistance and carries a thy gene, and on BD393, a highly competent B. subtilis thyA thyB host. Thy- strains are resistant to trimethoprim (Tmp), and Thy+ strains are sensitive. Inactivation of the pBD214 thy determinant by insertion of a DNA fragment permits selection of Cmr Tmpr clones, all of which carry recombinant plasmids. This insertional inactivation can be accomplished using the unique EcoRI, BclI, PvuII, or EcoRV sites, all of which are located within the thy gene on pBD214. Some properties of this selective system are described, and its uses for molecular cloning are discussed.