Genes required for both gliding motility and development in Myxococcus xanthus

Myxococous xanthus cells can glide both as individual cells, dependent on A dventurous motility (A motility), and as groups of cells, dependent upon S ocial motility (S motility), Tn5-lac mutagenesis was used to generate 16 new A^- and nine new S^- mutations. In contrast with previous results, we find that subsets of A^- mutants are defective in fruiting body morphogenesis and/or myxospore differentiation. All S^- mutants are defective in fruiting body morphogenesis, consistent with previous results. Whereas some S^- mutants produce a wild-type complement of spores, others are defective in the differentiation of myxospores. Therefore, a subset of the A genes and all of the S genes are critical for fruiting body morphogenesis. Subsets of both A and S genes are essential for sporulation. Three S::Tn5–lac insertions result in surprising phenotypes. Colonies of two S^- mutants glide on ‘swim’ (0.35% agar) plates to form fractal patterns. These S^- mutants are the first examples of a bacterium in which mutations result in fractal patterns of colonial spreading. An otherwise wild-type strain with one S^- insertion resembles the frz^- sglA1^- mutants upon development, suggesting that this S^- gene defines a new chemotaxis component in M. xanthus.     

Genetics of gliding motility in Myxococcus xanthus (Myxobacterales): Two gene systems control movement

Summary A large number of motility mutants of the gliding bacterium Myxococcus xanthus have been isolated and analyzed by transduction. Almost all nonmotile mutants are found to be double mutants. This is explained by the existence of two parallel and almost independent multi-gene systems controlling motility, in which case at least one mutation in each system would be required eliminate motility. Only one locus, called mgl, has been found to be shared by both systems. Wild type cells move singly and in groups. Single cells move if they carry a complete gene system A, the genes of which are described in the preceding paper. Groups of cells can move if they carry a complete gene system S, but single A^–S⁺ cells do not move. Linkage analysis reveals at least 9 different loci in system S. One class of S^– mutants, those mutated in the locus tgl, are conditional mutants which, after contact with tgl ⁺ cells, become temporarily motile as cell groups. Most system A mutations have little effect on fruiting but many system S mutations block it, suggesting that system S plays a role in the fruiting process.     

Genetics of gliding motility in Myxococcus xanthus: Molecular cloning of the mgl locus

Summary Wild-type Myxococcus xanthus cells move across solid surfaces by gliding. However no locomotory organelles for gliding have as yet been identified. Two sets of genes are required for gliding in M. xanthus: Gene System A is necessary for the gliding of isolated cells and Gene System S comes into play when cells are close together. The product of the mgl locus is required for both types of gliding and therefore may be a structural component of the gliding organelle. To begin to investigate the function of mgl in gliding a 12 kb segment of M. xanthus DNA containing the locus was cloned in Escherichia coli and returned to Myxococcus by specialized transduction with coliphage P1. In M. xanthus the chimeric plasmid integrates into the chromosome by recombination between the cloned segment and its homolog in the recipient chromosome forming a tandem duplication of the cloned segment with the vector sequences at the novel joint. The construction of partial diploids in this manner facilitated dominance tests and interallelic crosses with ten mgl alleles. We also describe a method for the analysis of tandem duplications that precisely maps alleles to a specific copy of the duplicated sequences. This method provides evidence for the dominance of mgl ⁺ over the mgl ^- alleles. It also reveals what appears to be gene conversion at this locus during recombination between a cloned mgl sequence and its homolog in the chromosome.     

Resource Level Affects Relative Performance of the Two Motility Systems of Myxococcus xanthus

The adventurous (A) and social (S) motility systems of the microbial predator Myxococcus xanthus show differential swarming performance on distinct surface types. Under standard laboratory conditions, A-motility performs well on hard agar but poorly on soft agar, whereas the inverse pattern is shown by S-motility. These properties may allow M. xanthus to swarm effectively across a greater diversity of natural surfaces than would be possible with one motility system alone. Nonetheless, the range of ecological conditions under which dual motility enhances effective swarming across distinct surfaces and how ecological parameters affect the complementarity of A-motility and S-motility remain unclear. Here we have examined the role of nutrient concentration in determining swarming patterns driven by dual motility on distinct agar surfaces, as well as the relative contributions of A-motility and S-motility to these patterns. Swarm expansion rates of dually motile (A⁺S⁺), solely A-motile (A⁺S⁻), and solely S-motile (A⁻S⁺) strains were compared on hard and soft agar across a wide range of casitone concentrations. At low casitone concentrations (0–0.1%), swarming on soft agar driven by S-motility is very poor, and is significantly slower than swarming on hard agar driven by A-motility. This reverses at high casitone concentration (1–3.2%) such that swarming on soft agar is much faster than swarming on hard agar. This pattern greatly constrained the ability of M. xanthus to encounter patches of prey bacteria on a soft agar surface when nutrient levels between the patches were low. The swarming patterns of a strain that is unable to produce extracellular fibrils indicate that these appendages are responsible for the elevated swarming of S-motility at high resource levels. Together, these data suggest that large contributions by S-motility to predatory swarming in natural soils may be limited to soft, wet, high-nutrient conditions that may be uncommon. Several likely benefits of S-motility to the M. xanthus life cycle are discussed, including synergistic interactions with A-motility across a wide variety of conditions.     

The cloning and transposon Tn5 mutagenesis of the glnA region of Klebsiella pneumoniae: identification of glnR, a gene involved in the regulation of the nif and hut operons

Summary A 15 kilobase HindIII fragment of Klebsiella pneumoniae DNA containing the glnA gene was cloned into the plasmid vector pACYC184. The resulting plasmid, pFB51, complements glnA ^- mutations in Escherichia coli and K. pneumoniae. pFB51 also complements the GlnR phenotype of a Klebsiella pneumoniae gln regulatory mutant (KP5060) defined by the restoration of Hut⁺ and Nif⁺ (histidine utilization and nitrogen fixation) phenotypes to this strain. Three recombinant plasmids containing subsegments of the 15 kb HindIII fragment were derived from pFB51. Plasmid pFB514 which contains a spontaneous 4 kb delection of K. pneumoniae DNA from pFB51 is more stable than pFB51 and is still able to complement glnA ^- mutations and the GlnR^- phenotype of KP5060. Plasmids pFB53 and pFB54, which contain a 6.5 kb SalI DNA fragment from pFB51 recloned into pACYC184 in opposite orientations, complement glnA ^- mutations but not the GlnR^- phenotype of KP5060. Plasmids pFB514 and pFB53 were mutagenized by transposon Tn5 resulting in a total of 92 Tn5 insertions in the cloned fragments. Utilizing these insertion mutations, a correlated physical and genetic map was constructed by determining the physical location of each Tn5 insertion and by analyzing the ability of each Tn5 mutated plasmid to complement a glnA ^- strain of E. coli and a glnA ^- GlnR^- strain of K. pneumoniae. Two classes of Tn5 insertions with an altered Gln phenotpye were obtained. One cluster of insertions spanning a 1.3 kb region abolished complementation of the glnA ^- mutations. A second 2 kb cluster of Tn5 insertions, immediately adjacent to the first cluster, abolished the ability of pFB514 plasmid to complement the GlnR^- phenotype, while glnA ^- complementation was unaffected. We propose that the second cluster of Tn5 insertions define a DNA region coding for a positive regulatory factor for nitrogen fixation (nif) and histidine utilization (hut) genes (glnR).     

Isolation and properties of Tn10 insertions in the rac locus of Escherichia coli

Summary Two Tn10 insertions that are in the rac locus of the chromosome of Escherichia coli have been isolated and characterized. These insertions are located at min 29.7 and min 30.0. The insertions are stable when an F123 rac::Tn10 episome is transferred to an F^- rac ⁺ recipient, but they are lost at a high frequency when transferred to an F^- rac ^- recipient. This latter condition has been previously, demonstrated to cause the excision of the rac locus. The Tn10 insertions are also lost at a high frequency when strains containing them are lysogenized with reverse. If the lysogens that have lost the Tn10 insertion are subsequently cured of reverse, the cells no longer contain sequences homologous with rac locus DNA. These strains were rac ^- when tested for recombination activation (Low 1973), and this procedure consequently provides a simple means to make isogenic rac ^- and rac ^- strains.     

Bradyrhizobium japonicum mutants defective in root-nodule bacteroid development and nitrogen fixation

The genome of the slow-growing Bradyrhizobium japonicum (strain 110) was mutagenized with transposon Tn5. A total of 1623 kanamycin/streptomycin resistant derivatives were screened in soybean infection tests for nodulation (Nod) and symbiotic nitrogen fixation (Fix). In this report we describe 14 strains possessing a stable, reproducible Nod⁺Fix^- phenotype. These strains were also grown under microaerobic culture conditions to test them for free-living nitrogen fixation activity (Nif). In addition to strains having reduced Fix and Nif activities, there were also strains that had reduced symbiotic Fix activity but were Nif⁺ ex planta.Analysis of the genomic structure revealed that the majority of the strains had a single Tn5 insertion without any further apparent physical alteration. A few strains had additional insertions (by Tn5 or IS50), or a deletion, or had cointegrated part of the vector used for Tn5 mutagenesis. One of the insertions was found in a known nif gene (nifD) whereas all other mutations seem to affect different, hitherto unknown genes or operons.Several mutant strains had an altered nodulation phenotype, inducing numerous, small, widely distributed nodules. Light and electron microscopy revealed that most of these mutants were defective in different stages of bacteroid development and/or bacteroid persistence. The protein patterns of the mutants were inspected by two-dimensional gel electrophoresis after labelling microaerobic cultures with l-(³⁵S)methionine. Of particular interest were mutants lacking a group of proteins the synthesis of which was known to be under oxygen control. Such strains can be regarded as potential regulatory mutants.     

Transposition and insertion of intact, deleted and enlarged ampicillin transposon Tn3 from mini-R1 (Rsc) plasmids into transfer factors

Summary The miniR1-(Rsc)-plasmids which derive from the copy mutant R1drd-19B2 (pKN102) are nonconjugative extrachromosomal elements which can not be co-transferred by various transfer factors to recipient strains under standard mating conditions. The attempts to mobilize Rsc11 by F'lac lead to transconjugants carrying F'lac::Tn3 with Tn3 mainly inserted into the lac operon. In addition it can be shown that Rsc11 can become inserted as a complete unit into the transfer factor giving rise to rather unstable recombinant intermediates. Dissociation of these intermediates may lead to alterations of the original plasmids.The Tn3 part of Rsc13 can be enlarged or deleted by in vitro manipulations. In vitro insertion of EcoRI-fragments into an EcoRI⁺ site of Tn3 leads to new transposable units which can be transposed to the RTF part of R1. This new genetic entity can be stably integrated into the chromosome of E. coli by integrative suppression of a dnaA^ts-mutation.Deletions at one end or the central region of Tn3 abolish the capability of transposition. However, the Rsc-plasmids containing the deleted Tn3 can still be inserted into the transfer factor as complete units. The resulting recombinants are unstable leading after dissociation in some cases to new plasmids with altered properties.     

Mapping of mglB, the structural gene of the galactose-binding protein of Escherichia coli

Summary The tetracycline resistance transposon Tn10 was inserted into the E. coli chromosome near mglB550, a structural gene for the galactose-binding protein. P1 transductions established the position of these Tn10 insertions (zee-700, 701, 702::Tn10) close to the genes ptsF, fpk, cdd, mglB550, his, and gatA with 85%–95%, 85%, 36%, 20%–40%, 12%–15%, and 0.5% contransduction frequency. Three factor crosses revealed the relative sequence of the genes as: mglB550, zee-700::Tn10, ptsF, fpk, cdd, his. gatA was found to be 1.3% cotransducible with mglB550. Two Tn10 insertions near gatA were isolated and characterized. One, zef-704::Tn10, was 3% cotransducible with fpk, 8% with mglB550, and 42% with gatA. The other, zef-703::Tn10, was 98% cotransducible with gatA but not with mglB550 or fpk. Neither of these two Tn10 insertions was cotransducible with cdd. Four factor crosses revealed the sequence gatA, zef-704::Tn10, mglB550, fpk.Neither zee-700::Tn10 nor zef-703::Tn10 showed any (0/300) contransduction with either glpT or gyrA. The clockwise order of genes is then: his, cdd, fpk, ptsF, zee-700::Tn10, mglB550, zef-704::Tn10, gatA. With a fix-point for his at 44 min, fpk would be placed at 45 min and mglB550 at 45.5 min. During the course of this work we noticed that the cotransduction frequency between Tn10 insertions and nearby markers tended to increase when new P1 lysates were prepared from freshly reisolated strains. This may indicate loss of nonessential genes adjacent to Tn10 insertions. Using insertion zee-702::Tn10, we isolated deletions extending into an mgl gene other than mglB. Crosses between such a deletion mutant and an mglB550 mutant were done. The analysis of the periplasmic proteins of these as well as other transductants or recombinants involving the mglB550 or the mglB551 gene revealed the existence of strains synthesizing both the wild-type as well as the corresponding mutant protein. Strains containing both proteins exhibit either wild-type or mutant phenotype. These strains appeared unstable. Upon reisolation from purified stock cultures kept in glycerol at-20°C, colonies could be isolated that carried only mutant or wild-type protein.     

Genetic and physical studies of restriction-deficient mutants of the Inc FIV plasmids R124 and R124/3

Summary R124 and R124/3 are R plasmids that carry the genes for two different restriction and modification systems. The phenotype of strains carrying either of these plasmids along with the F'lac ⁺ plasmid, is restriction-deficient (Res^-). The Res^- phenotype is not due to selection of preexisting mutants but rather to a complex mutational event caused by the F plasmid. Restriction-deficient mutants carry extensive deletions and other DNA rearrangements. Tn7 insertion is used to locate the restriction gene. Many of the Res^- mutants are genetically unstable and revert at exceptionally high frequencies. Reversion is accompanied by DNA rearrangements which result in a net gain of 9 kb of DNA. F derivates of F⁺ which do not cause restriction-deficiency but do cause deletion were used to distinguish between the DNA rearrangements associated with restriction-deficiency and those associated with deletion. From Res⁺ revertants of strains carrying F'lac ⁺ and R124 or R124/3 we have isolated F plasmids that now carry the genes for the R124 or R124/3 restriction and modification systems. It is suggested that interaction between part of the F plasmid and that segment of the R plasmid which controls the switch in Res-Mod specificity which has been observed (Glover et al. 1983) is responsible for the production of restriction-deficiency.     

Bacterial motility complexes require the actin‐like protein,MreB and the Ras homologue,MglA

Gliding motility in the bacterium Myxococcus xanthus uses two motility engines: S‐motility powered by type‐IV pili and A‐motility powered by uncharacterized motor proteins and focal adhesion complexes. In this paper, we identified MreB, an actin‐like protein, and MglA, a small GTPase of the Ras superfamily, as essential for both motility systems. A22, an inhibitor of MreB cytoskeleton assembly, reversibly inhibited S‐ and A‐motility, causing rapid dispersal of S‐ and A‐motility protein clusters, FrzS and AglZ. This suggests that the MreB cytoskeleton is involved in directing the positioning of these proteins. We also found that a ΔmglA motility mutant showed defective localization of AglZ and FrzS clusters. Interestingly, MglA–YFP localization mimicked both FrzS and AglZ patterns and was perturbed by A22 treatment, consistent with results indicating that both MglA and MreB bind to motility complexes. We propose that MglA and the MreB cytoskeleton act together in a pathway to localize motility proteins such as AglZ and FrzS to assemble the A‐motility machineries. Interestingly, M. xanthus motility systems, like eukaryotic systems, use an actin‐like protein and a small GTPase spatial regulator.     

Identification of Gene Clusters Associated with Host Adaptation and Antibiotic Resistance in Chinese Staphylococcus aureus Isolates by Microarray-Based Comparative Genomics

A comparative genomic microarray comprising 2,457 genes from two whole genomes of S. aureus was employed for the comparative genome hybridization analysis of 50 strains of divergent clonal lineages, including methicillin-resistant S. aureus (MRSA), methicillin-susceptible S. aureus (MSSA), and swine strains in China. Large-scale validation was confirmed via polymerase chain reaction in 160 representative clinical strains. All of the 50 strains were clustered into seven different complexes by phylogenetic tree analysis. Thirteen gene clusters were specific to different S. aureus clones. Ten gene clusters, including seven known (vSa3, vSa4, vSaα, vSaβ, Tn5801, and phage ϕSa3) and three novel (C8, C9, and C10) gene clusters, were specific to human MRSA. Notably, two global regulators, sarH2 and sarH3, at cluster C9 were specific to human MRSA, and plasmid pUB110 at cluster C10 was specific to swine MRSA. Three clusters known to be part of SCCmec, vSa4 or Tn5801, and vSaα as well as one novel gene cluster C12 with homology with Tn554 of S. epidermidis were identified as MRSA-specific gene clusters. The replacement of ST239-spa t037 with ST239-spa t030 in Beijing may be a result of its acquisition of vSa4, phage ϕSa1, and ϕSa3. In summary, thirteen critical gene clusters were identified to be contributors to the evolution of host specificity and antibiotic resistance in Chinese S. aureus.     

Tn951: A new transposon carrying a lactose operon

Summary A new transposon, Tn951, is described, which derives from plasmid pGC1, originally isolated from Yersinia enterocolitica. Tn951 is 16.6 kb long and presumably flanked by small inverted repeats. It carries the lac genes i, z and y. This lac system is homologous to the E. coli lac operon. However, homology is restricted to 5.6 kb. The DNA sequences surrounding the lac operons on Tn951 and E. coli are nonhomologous. This leads to speculations about the origin of the E. coli lac operon itself.     

Early transfer of genes determining transfer functions by some Hfr strains in Escherichia coli K12

Summary Sixty-eight Hfr strains were examined for their ability to transfer early in conjugation the transfer genes carried by the integrated sex factor. This was measured by mating these strains with F^- phenocopied recipient cultures of strains carrying transfer-deficient Flac ⁺ factors, and then measuring the ability of the recipient strains to transfer lac ⁺ to a further recipient strain. Most Hfr strains did not complement the missing transfer functions, though in some strains complementation was observed. It is concluded that on the sex factors of different Hfr strains either the site at which integration occurs or the origin of transfer must vary.     

Evidence for a common mechanism for the insertion of the Tn10 transposon and for the generation of Tn10-stimulated deletions

Summary Mutations in and near the Salmonella typhimurium histidine transport operon were generated by insertion of the translocatable tetracycline-resistance element Tn10. Deletion mutants affecting histidine transport genes were subsequently isolated in several of the Tn10-containing strains. Tn10 insertions in hisJ occurred preferentially at one site, designated site A. This same site was also the preferential endpoint of deletions originating from Tn10 insertions at two neighboring sites. Thus, Tn10 insertion and Tn10-stimulated deletion formation appear to involve a common DNA-recogition step.     

Tn5 insertion mutants of Pseudomonas sp. 267 defective in siderophore production and their effect on clover (Trifolium pratense) nodulated with Rhizobium leguminosarum bv. trifolii

Pseudomonas sp. strain 267 isolated from soil promoted growth of different plants under field conditions and enhanced symbiotic nitrogen fixation in clover under gnotobiotic conditions. This strain produced pyoverdine-like compound under low-iron conditions and secreted vitamins of the B group. The role of fluorescent siderophore production in the beneficial effect of strain 267 on nodulated clover plants was investigated. Several non-fluorescent (Pvd^-) Tn5 insertion mutants of Pseudomonas sp. strain 267 were isolated and characterized. The presence of Tn5 insertions was confirmed by Southern analysis of EcoRI digested genomic DNA of each derivative strain. The siderophore-negative mutants were compared to the parental strain with respect to their growth promotion of nodulated clover infected with Rhizobium leguminosarum bv. trifolii 24.1. We found that all isolated Pvd^- mutants stimulated growth of nodulated clover plants in a similar manner to the parental strain. No consistent differences were observed between strain 267 and Pvd^- derivatives strains with respect to their plant growth promotion activity under gnotobiotic conditions.Dr Deryto died in august 1994     

Operon fusions of Mu d1(Ap,lac) to thel-proline biosynthetic genes ofescherichia coli K-12

Operon fusions to the promoter of either theproA,proB, orproC genes of the proline biosynthetic pathway were obtained by the use of the Mu d1(Ap,lac) bacteriophage. These fusions were further stabilized by transformation with plasmid pGW600 containing the wildtype Mu repressor gene or by transduction with phage pSG1. The level of -galactosidase in the fusion strains was not affected by the presence of exogenously addedl-proline or high concentrations of NaCl in the growth medium. A Tn5 insertion nearproBA increased -galactosidase expression 140- to 200-fold in strains carrying theproA-lac andproB-lac fusions, but the level of this enzyme was unaltered in strains carrying theproC-lac fusion. The Tn5 insertion increased intracellular proline concentrations 8- to 10-fold, suggesting that mechanisms other than allosteric inhibition may regulate proline biosynthesis, but did not confer osmotolerance to cells growing in a medium with a high concentration of salt.     

Characterization of anf genes specific for the alternative nitrogenase and identification of nif genes required for both nitrogenases in Rhodobacter capsulatus

To identify Rhodobacter capsulatus nif genes necessary for the alternative nitrogenase, strains carrying defined mutations in 32 genes and open reading frames of nif region A, B or C were constructed. The ability of these mutants to grow on nitrogen-free medium with molybdenum (Nif phenotype) or in a nifHDK deletion background on medium without molybdenum (Anf phenotype) was tested. Nine nif genes and nif-associated coding regions are absolutely essential for the alternative nitrogenase. These genes comprise nifV and nifB, the nif-specific ntr system (nifR1, R2, R4) and four open reading frames, which exhibit no homology to known genes. In addition, a significantly reduced activity of both the alternative nitrogenase and the molybdenum-dependent nitrogenase was found for fdxN mutants. By random Tn5 mutagenesis of a nifHDK deletion strain 42 Anf^? mutants were isolated. Southern hybridization experiments demonstrated that 17 of these Tn5 mutants were localized in at least 13 different restriction fragments outside of known nif regions. Ten different Anf^? Tn5 mutations are clustered on a 6 kb DNA fragment of the chromosome designated anf region A. DNA sequence analysis revealed that this region contained the structural genes of the alternative nitrogenase (anfHDGK). The identification of several Tn5 insertions mapping outside of anf region A indicated that at least 10 genes specific for the alternative nitrogenase are present in R. capsulatus.     

Genetic suppression and phenotypic masking of a Myxococcus xanthus frzF- defect

An insertion of transposon Tn5-lac, ω4519, generates a lacZ fusion with a Myxococcus xanthus promoter expressed during both vegetative growth and development. Sequence analysis of the junction of ω4519 with M. xanthus DNA shows that the insertion is in frzF, a homologue of cheR from Salmonella typhimurium. When frzF^- (or frzCD^-) cells are starved for nutrients at modest densities, they aggregate to form a radial pattern and produce fewer than 1% of the wild-type complement of spores. At higher densities, frzF::ω519 cells form‘frizzy’aggregates and produce 80–90% of the wild-type complement of spores. In contrast, when cells with both a frzF^- (or frzCD^-) and an sgtA1 mutation are allowed to develop at either low or high cell densities, they produce frizzy aggregates containing a near wild-type complement of heat-resistant spores. In addition to suppressing the density dependence of fruiting-body morphogenesis, the sglA1 mutation also suppresses the sporulation defect caused by two different frzF^- mutations and a frzCD^- mutation. In contrast, a mutation in a different S motility gene, sglG1, does not suppress the frz^- mutations. Thus, the suppression of frz^- mutations by sgl^- mutations is allele-specific, and depends on the sgl allele, but not the frz allele. Because the phenotypes of frz^- mutations have been determined in a (suppressing) sglA1 genetic background, the frz genes may play more central roles in development than initially recognized.     

Isolation of symbiotically defective mutants in Rhizobium leguminosarum by insertion of the transposon Tn5 into a transmissible plasmid

Summary Selection was made for the transposition of the kanamycin resistance transposon Tn5 from a location on the chromosome of R. leguminosarum into a transmissible, bacteriocinogenic plasmid that also carries genes required for the induction of nitrogen-fixing nodules on peas.One hundred and sixty independent insertions into transmissible plasmids were isolated. When these plasmids were transferred by conjugation into a non-nodulating strain, which carries a deletion in one of its resident plasmids, of the 160 isolates tested 14 yielded transconjugants that formed nodules that did not fix nitrogen (Fix^-) and in a further 15 cases the transconjugants were unable to form nodules (were Nod^-). When transferred to a symbiotically proficient strain (i.e. Nod⁺ Fix⁺) none of the transconjugants was symbiotically defective; thus the mutations were not dominant.When kan was transduced from the clones that generated Fix^- transconjugants into a Fix⁺ recipient the majority of transductants inherited Fix^- indicating that the insertion of Tn5 had induced the symbiotic mutations. Transduction of kan, from the clones that failed to donate Nod⁺ by conjugation to strain 6015, occurred at barely detectable frequencies and it was not possible to demonstrate transduction of Nod^-. kan was co-transduced with Nod⁺ from some of the clones and some of these transductants also inherited the ability to produce medium bacteriocin and to transfer at high frequency by conjugation. Thus the genes for all these characters are closely linked.