Peptidoglycan from Bacillus cereus mediates commensalism with rhizosphere bacteria from the Cytophaga-Flavobacterium group

Previous research in our laboratory revealed that the introduction of Bacillus cereus UW85 can increase the populations of bacteria from the Cytophaga-Flavobacterium (CF) group of the Bacteroidetes phylum in the soybean rhizosphere, suggesting that these rhizosphere microorganisms have a beneficial relationship (G. S. Gilbert, J. L. Parke, M. K. Clayton, and J. Handelsman, Ecology 74:840-854, 1993). In the present study, we determined the frequency at which CF bacteria coisolated with B. cereus strains from the soybean rhizosphere and the mechanism by which B. cereus stimulates the growth of CF rhizosphere strains in root exudate media. In three consecutive years of sampling, CF strains predominated among coisolates obtained with B. cereus isolates from field-grown soybean roots. In root exudate media, the presence of B. cereus was required for CF coisolate strains to reach high population density. However, rhizosphere isolates from the phylum Proteobacteria grew equally well in the presence and absence of B. cereus, and the presence of CF coisolates did not affect the growth of B. cereus. Peptidoglycan isolated from B. cereus cultures stimulated growth of the CF rhizosphere bacterium Flavobacterium johnsoniae, although culture supernatant from B. cereus grown in root exudate media did not. These results suggest B. cereus and CF rhizosphere bacteria have a commensal relationship in which peptidoglycan produced by B. cereus stimulates the growth of CF bacteria.     

Zwittermicin A resistance gene from Bacillus cereus.

Zwittermicin A is a novel aminopolyol antibiotic produced by Bacillus cereus that is active against diverse bacteria and lower eukaryotes (L.A. Silo-Suh, B.J. Lethbridge, S.J. Raffel, H. He, J. Clardy, and J. Handelsman, Appl. Environ. Microbiol. 60:2023-2030, 1994). To identify a determinant for resistance to zwittermicin A, we constructed a genomic library from B. cereus UW85, which produces zwittermicin A, and screened transformants of Escherichia coli DH5alpha, which is sensitive to zwittermicin A, for resistance to zwittermicin A. Subcloning and mutagenesis defined a genetic locus, designated zmaR, on a 1.2-kb fragment of DNA that conferred zwittermicin A resistance on E. coli. A DNA fragment containing zmaR hybridized to a corresponding fragment of genomic DNA from B. cereus UW85. Corresponding fragments were not detected in mutants of B. cereus UW85 that were sensitive to zwittermicin A, and the plasmids carrying zmaR restored resistance to the zwittermicin A-sensitive mutants, indicating that zmaR was deleted in the zwittermicin A-sensitive mutants and that zmaR is functional in B. cereus. Sequencing of the 1.2-kb fragment of DNA defined an open reading frame, designated ZmaR. Neither the nucleotide sequence nor the predicted protein sequence had significant similarity to sequences in existing databases. Cell extracts from an E. coli strain carrying zmaR contained a 43.5-kDa protein whose molecular mass and N-terminal sequence matched those of the protein predicted by the zmaR sequence. The results demonstrate that we have isolated a gene, zmaR, that encodes a zwIttermicin A resistance determinant that is functional in both B. cereus and E. coli.     

Biological activities of two fungistatic antibiotics produced by Bacillus cereus UW85.

Cultures and culture filtrates of Bacillus cereus UW85 suppress damping-off of alfalfa caused by Phytophthora medicaginis. We studied the role in disease suppression of two antibiotics from culture filtrates of UW85 that reversibly inhibited growth of P. medicaginis. We purified the two antibiotics by cation-exchange chromatography and high-voltage paper electrophoresis and showed that one of them, designated zwittermicin A, was an aminopolyol of 396 Da that was cationic at pH 7.0; the second, designated antibiotic B, appeared to be an aminoglycoside containing a disaccharide. Both antibiotics prevented disease of alfalfa seedlings caused by P. medicaginis. Purified zwittermicin A reversibly reduced elongation of germ tubes derived from cysts of P. medicaginis, and antibiotic B caused swelling of the germ tubes. Mutants generated with Tn917 or mitomycin C treatment were screened either for antibiotic accumulation in an agar plate diffusion assay or for the ability to suppress damping-off disease of alfalfa. Of 2,682 mutants screened for antibiotic accumulation, 5 mutants were substantially reduced in antibiotic accumulation and disease-suppressive activity. Of the 1,700 mutants screened for disease-suppressive activity, 3 mutants had reduced activity and they accumulated less of both antibiotics than did the parent strain. The amount of antibiotic accumulated by the mutants was significantly correlated with the level of disease suppression. Addition of either zwittermicin A or antibiotic B to alfalfa plants inoculated with a culture of a nonsuppressive mutant resulted in disease suppression. These results demonstrate that B. cereus UW85 produces two fungistatic antibiotics that contribute to suppression of damping-off disease of alfalfa.     

Effect of Canavanine from Alfalfa Seeds on the Population Biology of Bacillus cereus

Bacillus cereus UW85 suppresses diseases of alfalfa seedlings, although alfalfa seed exudate inhibits the growth of UW85 in culture (J. L. Milner, S. J. Raffel, B. J. Lethbridge, and J. Handelsman, Appl. Microbiol. Biotechnol. 43:685–691, 1995). In this study, we determined the chemical basis for and biological role of the inhibitory activity. All of the alfalfa germ plasm tested included seeds that released inhibitory material. We purified the inhibitory material from one alfalfa cultivar and identified it as canavanine, which was present in the cultivar Iroquois seed exudate at a concentration of 2 mg/g of seeds. Multiple lines of evidence suggested that canavanine activity accounted for all of the inhibitory activity. Both canavanine and seed exudate inhibited the growth of UW85 on minimal medium; growth inhibition by either canavanine or seed exudate was prevented by arginine, histidine, or lysine; and canavanine and crude seed exudate had the same spectrum of activity against B. cereus, Bacillus thuringiensis, and Vibrio cholerae. The B. cereus UW85 populations surrounding canavanine-exuding seeds were up to 100-fold smaller than the populations surrounding non-canavanine-exuding seeds, but canavanine did not affect the growth of UW85 on seed surfaces. The spermosphere populations of canavanine-resistant mutants of UW85 were larger than the spermosphere populations of UW85, but the mutants and UW85 were similar in spermoplane colonization. These results indicate that canavanine exuded from alfalfa seeds affects the population biology of B. cereus.     

Bacteriocin and antibiotic resistance plasmids in Bacillus cereus and Bacillus subtilis.

A number of plasmids have been isolated as covalently closed circular DNAs from strains of Bacillus cereus and B. subtilis. From 12 out of 15 strains of B. cereus, plasmids could be isolated. Most of the B. cereus strains contained two or more plasmids. Their molecular weights ranged from 1.6 X 10(6) to 105 X 10(6). Bacteriocin production could be attributed to a 45 X 10(6)-dalton plasmid (pBC7) from B. cereus DSM 336, and tetracycline resistance to a 2.8 X 10(6) plasmid (pBC16) from B. cereus GP7. Two streptomycin-resistant strains of B. subtilis harbored plasmids of 5.2 X 10(6) and 9 X 10(6), respectively, which were, however, not correlated with the antibiotic resistance. The plasmid carrying resistance to tetracycline, pBC16, which was originally isolated from B. cereus, could be subsequently transformed in B. subtilis, where it is stably maintained.     

Zwittermicin A-producing strains of Bacillus cereus from diverse soils.

Bacillus cereus UW85 produces a novel aminopolyol antibiotic, zwittermicin A, that contributes to the ability of UW85 to suppress damping-off of alfalfa caused by Phytophthora medicaginis. UW85 produces a second antibiotic, provisionally designated antibiotic B, which also contributes to suppression of damping-off but has not been structurally defined yet and is less potent than zwittermicin A. The purpose of this study was to isolate genetically diverse strains of B. cereus that produce zwittermicin A and suppress disease. We found that most isolates of B. cereus that were sensitive to phage P7 or inhibited the growth of Erwinia herbicola produced zwittermicin A; therefore, phage typing and E. herbicola inhibition provided indirect, but rapid screening tests for identification of zwittermicin A-producing isolates. We used these tests to screen a collection of 4,307 B. cereus and Bacillus thuringiensis isolates obtained from bacterial stock collections and from diverse soils collected in Honduras, Panama, Australia, The Netherlands, and the United States. A subset of the isolates screened by the P7 sensitivity and E. herbicola inhibition tests were assayed directly for production of zwittermicin A, leading to the identification of 57 isolates that produced zwittermicin A; 41 of these isolates also produced antibiotic B. Eight isolates produced antibiotic B but not zwittermicin A. The assay for phage P7 sensitivity was particularly useful because of its simplicity and rapidity and because 22 of the 23 P7-sensitive isolates tested produced zwittermicin A. However, not all zwittermicin A-producing isolates were sensitive to P7, and the more labor-intensive E. herbicola inhibition assay identified a larger proportion of the zwittermicin A producers.(ABSTRACT TRUNCATED AT 250 WORDS)     

Production of kanosamine by Bacillus cereus UW85.

Bacillus cereus UW85 produces two antibiotics that contribute to its ability to suppress certain plant diseases (L. Silo-Suh, B. Lethbridge, S. J. Raffel, H. He, J. Clardy, and J. Handelsman, Appl. Environ. Microbiol. 60:2023-2030, 1994). To enhance the understanding of disease suppression by UW85, we determined the chemical structure, regulation, and the target range of one of the antibiotics. The antibiotic was identified as 3-amino-3-deoxy-D-glucose, also known as kanosamine. Kanosamine was highly inhibitory to growth of plant-pathogenic oomycetes and moderately inhibitory to certain fungi and inhibited few bacterial species tested. Maximum accumulation of kanosamine in B. cereus UW85 culture supernatants coincided with sporulation. Kanosamine accumulation was enhanced by the addition of ferric iron and suppressed by addition of phosphate to rich medium. Kanosamine accumulation was also enhanced more than 300% by the addition of alfalfa seedling exudate to minimal medium.     

Enhancement of soybean nodulation by Bacillus cereus UW85 in the field and in a growth chamber.

Seed treatments with Bacillus cereus UW85 increased nodulation of soybeans in three field seasons and in three different sterilized soils in the growth chamber. In the field, 28 and 35 days after planting, UW85-treated plants had 31 to 133% more nodules than untreated plants. From 49 days after planting until seed harvest, there were no significant differences between nodulation of UW85-treated plants and untreated control plants. In the growth chamber, in sterilized soil-vermiculite mixtures, at 28 days after planting, UW85 seed treatments enhanced nodulation by 34 to 61%, indicating that the increase in nodulation was not dependent on the soil flora.     

Enhancement of soybean nodulation by Bacillus cereus UW85 in the field and in a growth chamber.

Seed treatments with Bacillus cereus UW85 increased nodulation of soybeans in three field seasons and in three different sterilized soils in the growth chamber. In the field, 28 and 35 days after planting, UW85-treated plants had 31 to 133% more nodules than untreated plants. From 49 days after planting until seed harvest, there were no significant differences between nodulation of UW85-treated plants and untreated control plants. In the growth chamber, in sterilized soil-vermiculite mixtures, at 28 days after planting, UW85 seed treatments enhanced nodulation by 34 to 61%, indicating that the increase in nodulation was not dependent on the soil flora.     

Influence of tomato genotype on growth of inoculated and indigenous bacteria in the spermosphere

We previously demonstrated a genetic basis in tomato for support of the growth of a biological control agent, Bacillus cereus UW85, in the spermosphere after seed inoculation (K. P. Smith, J. Handelsman, and R. M. Goodman, Proc. Natl. Acad. Sci. USA 96:4786-4790, 1999). Here we report results of studies examining the host effect on the support of growth of Bacillus and Pseudomonas strains, both inoculated on seeds and recruited from soil, using selected inbred tomato lines from the recombinant inbred line (RIL) population used in our previous study. Two tomato lines, one previously found to support high and the other low growth of B. cereus UW85 in the spermosphere, had similar effects on growth of each of a diverse, worldwide collection of 24 B. cereus strains that were inoculated on seeds and planted in sterilized vermiculite. In contrast, among RILs that differed for support of B. cereus UW85 growth in the spermosphere, we found no difference for support of growth of the biocontrol strains Pseudomonas fluorescens 2-79 or Pseudomonas aureofaciens AB254. Thus, while the host effect on growth extended to all strains of B. cereus examined, it was not exerted on other bacterial species tested. When seeds were inoculated with a marked mutant of B. cereus UW85 and planted in soil, RIL-dependent high and low support of bacterial growth was observed that was similar to results from experiments conducted in sterilized vermiculite. When uninoculated seeds from two of these RILs were planted in soil, changes in population levels of indigenous Bacillus and fluorescent Pseudomonas bacteria differed, as measured over time by culturing and direct microscopy, from growth patterns observed in the inoculation experiments. Neither RIL supported detectable levels of growth of indigenous Bacillus soil bacteria, while the line that supported growth of inoculated B. cereus UW85 supported higher growth of indigenous fluorescent pseudomonads and total bacteria. The vermiculite system used in these experiments was predictive for growth of B. cereus UW85 inoculated on seeds and grown in soil, but the patterns of growth of inoculated strains-both Bacillus and Pseudomonas spp.-did not reflect host genotype effects on indigenous microflora recruited from soil to the spermosphere.     

Conjugative transfer of multiple-antibiotic resistance markers in beta-hemolytic group A, B, F, and G streptococci in the absence of extrachromosomal deoxyribonucleic acid

Nine clinical isolates of group A, B, F, and G streptococci resistant to tetracycline, macrolides, lincosamides, and streptogramin B (MLS resistance) and to chloramphenicol were investigated for the conjugative transfer of the antibiotic-resistance markers into streptococcal recipients (groups B and D). The wild donors transferred the resistance markers en bloc, at a low frequency (10^?6 to 10^?8) and only into one of the two recipients tested. In addition, one of the strains transferred only the MLS resistance at a high frequency (10^?3). All attempts to detect extrachromosomal DNA in wild donors or in transconjugants were unsuccessful, except in one transconjugant. This plasmid DNA, designated pIP659, had a molecular weight of 17.5 × 10⁶ and a restriction fingerprint similar to other plasmids determining MLS resistance.     

Zwittermicin A biosynthetic cluster.

The goal of this study was to identify the biosynthetic cluster for zwittermicin A, a novel, broad spectrum, aminopolyol antibiotic produced by Bacillus cereus. The nucleotide sequence of 2.7kb of DNA flanking the zwittermicin A self-resistance gene, zmaR, from B. cereus UW85 revealed three open reading frames (ORFs). Of these ORFs, two had sequence similarity to acyl-CoA dehydrogenases and polyketide synthases, respectively. Insertional inactivation demonstrated that orf2 is necessary for zwittermicin A production and that zmaR is necessary for high-level resistance to zwittermicin A but is not required for zwittermicin A production. Expression of ZmaR was temporally associated with zwittermicin A production. The results suggest that zmaR is part of a cluster of genes that is involved in zwittermicin A biosynthesis, representing the first biosynthetic pathway for an aminopolyol antibiotic.     

Variations in xanthan production by antibiotic-resistant mutants of Xanthomonas campestris

Mutants resistant to different antibiotics (streptomycin, tetracycline, ampicillin and penicillin) were obtained from several strains of Xanthomonas campestris and evaluated for xanthan production. Most of the mutants showed alterations in their polysaccharide production, either increasing, decreasing or totally losing their polymer-production capacity. The existence of two types of antibiotic-resistance mechanisms for the assayed drugs is suggested: one that affects xanthan production and another that does not. Differences in outer-membrane protein patterns of mutants that were simultaneously altered in antibiotic resistance and xanthan production were found, in comparison with their parental strains. These findings suggest the existence of a genetic relationship between antibiotic-resistance mechanisms and xanthan production. Some of the mutants obtained showed significant increases in broth viscosity and xanthan concentration. These results suggest that resistance to streptomycin and ampicillin can be used to obtain improved strains in plate screening assays. Received: 8 January 1997 / Received revision: 13 June 1997 / Accepted: 4 July 1997     

Gene in the major cotransduction gap of the Escherichia coli K-12 linkage map required for the expression of chromosomal resistance to tetracycline and other antibiotics

In Escherichia coli K-12, amplifiable resistance to tetracycline, chloramphenicol, and other unrelated antibiotics was mediated by at least four spatially separated loci. Tetracycline-sensitive mutants were isolated by Tn5 insertional inactivation of an amplified multiply resistant strain. One of these, studied in detail, showed coordinate loss of expression of all other resistance phenotypes. The Tn5 element in this mutant mapped to 34 min on the E. coli K-12 linkage map. We have designated the locus marA (multiple antibiotic resistance). Tetracycline-sensitive mutants containing marA::Tn5 regained all resistance phenotypes at frequencies of 10(-8) to 10(-7) upon precise excision of Tn5. Moreover, a newly described tetracycline efflux system (A. M. George and S. B. Levy, J. Bacteriol. 155:531-540, 1983) was inactivated in tetracycline-sensitive mutants, but recovered in tetracycline-resistant revertants. In merodiploids, F-prime marA+ expressed partial or complete dominance over corresponding mutant chromosomal alleles. Dominance tests also established that a previously amplified host and a mutant marA allele were preconditions for the expression of phenotypic resistances.     

Masking of antibiotic-resistance upon recovery of endophytic bacteria

During studies on internal plant colonization by rhizosphere bacteria and endophytic bacteria over several years, we frequently observed lack of growth of rifampicin-resistant mutants (rif+) on tryptic soy agar amended with rifampicin (RTSA). Following seed treatment of cucumber with 6 species of rif+ rhizosphere bacteria in one experiment, all strains were recoverable on RTSA when external root colonization was monitored. Following trituration of surface-disinfested roots, only one strain grew directly on RTSA; however colonies isolated on tryptic soy agar (TSA) grew within 18 h after transfer to RTSA. We term this temporary loss of the antibiotic-resistant phenotype ‘antibiotic masking’. Antibiotic masking was also observed with isolation of 7 rif+ endophytic bacterial strains from inside stems of cotton and with isolation of mutants of bacterial endophytes resistant to polymyxin B sulfate from cotton plants. Rifampicin-masking was not accounted for in vitro by inhibitory compounds from cotton plant extracts, by bacterial growth on low nutrient agar, or by competition with other bacteria. Collectively, these results suggest that expression of antibiotic-resistance may be altered in planta, although causes for this antibiotic-masking remain to be elucidated, methods for quantifying internal plant colonization by rif+ bacteria should account for this possibility. ei]Section editor: R O D Dixon     

Auxotrophic markers pyrF and proC can replace antibiotic markers on protein production plasmids in high-cell-density Pseudomonas fluorescens fermentation

The use of antibiotic-resistance genes as selectable markers in transgenic organisms is coming under increased scrutiny, for fear that they may spread to human pathogens, thereby reducing the effectiveness of antibiotic therapy. A current Pseudomonas fluorescens protein expression system uses a tetracycline resistance gene (tetR/tetA) to maintain an expression plasmid under control of a repressible promoter and a kanamycin resistance gene (kanR) to maintain a plasmid carrying a repressor gene. We investigated using auxotrophic markers to replace these two antibiotic resistance genes: pyrF (encoding orotidine-5'-phosphate decarboxylase) in place of tetR/tetA and proC (encoding pyrroline-5-carboxylate reductase) in place of kanR, complementing their respective precise chromosomal deletions created by allele exchange using a suicide vector carrying pyrF as a counterselectable marker. The resulting strains, devoid of antibiotic-resistance genes, were shown to achieve high productivity of nitrilase and thermostable alpha-amylase equal to that of the former antibiotic-resistant production host. The production plasmids were stable. The pyrF (uracil-dependent) background of the production host strain also allows us to sequentially alter the genome to incorporate other desired genomic changes, deletions, or insertions using 5'-fluoroorotic acid counterselection, restoring the selectable marker after each step.     

Climatic influence on mesophilic Bacillus cereus and psychrotolerant Bacillus weihenstephanensis populations in tropical, temperate and alpine soil

Bacillus weihenstephanensis strains are psychrotolerant and grow from below 7°C to 38°C. Closely related mesophilic Bacillus cereus strains can grow from above 7°C to 46°C. We classified 1060 B. cereus group isolates from different soil samples with respect to their psychrotolerant and mesophilic genotypes by polymerase chain reaction (PCR) targeting of specific 16S rDNA and cold shock protein A gene signatures. In parallel, growth tests at 7°C were carried out to determine the thermal phenotype. The geographic distribution of psychrotolerant and mesophilic isolates was found to depend significantly on the prevalent annual average temperature. In one tropical, one temperate and two alpine habitats, the proportion of psychrotolerant cspA genotypes was found to be 0%, 45% and 86% and 98%, respectively, with the corresponding annual average temperatures being 28°C, 7°C, 4°C and 1°C. In the tropical habitat, only the mesophilic B. cereus was found, characterized by correspondence of thermal genotype and phenotype. In the alpine habitat, almost only the psychrotolerant B. weihenstephanensis was isolated. In the temperate habitat, mesophilic B. cereus and psychrotolerant B. weihenstephanensis as well as 'intermediate thermal types' occurred, the latter having opposite thermal genotypes and phenotypes or opposing sets of thermal DNA signatures, characterized by the coexistence of mesophilic and psychrotolerant 16S rDNA operon copies within a single isolate. Both sugar utilization and DNA fingerprinting patterns revealed a high, probably non-clonal microsite diversity within the population of the temperate habitat. We interpret our observations in terms of a temperature-dependent selection regime, acting on recombining B. cereus / B. weihenstephanensis populations in soil.     

Population Dynamics of Soil Pseudomonads in the Rhizosphere of Potato (Solanum tuberosum L.)

Rhizosphere population dynamics of seven Pseudomonas fluorescens and Pseudomonas putida strains isolated from rhizospheres of various agricultural plants were studied on potato (Solanum tuberosum L.) in field soil under controlled environmental conditions. Rhizosphere populations of two strains (B10 and B4) were quantitatively related to initial seed piece inoculum levels when plants were grown at −0.3 bar matric potential. At a given inoculum level, rhizosphere populations of strain B4 were consistently greater than those of strain B10. In vivo growth curves on 4-cm root tip-proximal segments indicated that both strains grew at similar rates in the potato rhizosphere, but large populations of strain B10 were not maintained at 24°C after 7 h, whereas those of strain B4 were maintained for at least 40 h. Although both strains grew more rapidly in the rhizosphere at 24°C than at 12°C, their rhizosphere populations after seed piece inoculation were generally greater at 12 or 18°C, indicating that in vivo growth did not solely determine rhizosphere populations in these studies. In vitro osmotolerance of seven Pseudomonas strains (including strains B4 and B10) was correlated with their abilities to establish stable populations in the rhizosphere of potato. Stability of rhizosphere populations of the Pseudomonas strains studied here was maximized at low (i.e., 12°C) soil temperatures. These results indicate that Pseudomonas strains differ in their capacity to maintain stable rhizosphere populations in association with potato. This capacity, distinct from the ability to grow in the rhizosphere, may limit the establishment of rhizosphere populations under some environmental conditions.     

Antifungal characteristics of a fluorescent Pseudomonas strain involved in the biological control of Rhizoctonia solani

A plant growth-promoting isolate of a fluorescent Pseudomonas spp. EM85 was found strongly antagonistic to Rhizoctonia solani, a causal agent of damping-off of cotton. The isolate produced HCN (HCN+), siderophore (Sid+), fluorescent pigments (Flu+) and antifungal antibiotics (Afa+). Tn5::lacZ mutagenesis of isolate EM85 resulted in the production of a series of mutants with altered production of HCN, siderophore, fluorescent pigments and antifungal antibiotics. Characterisation of these mutants revealed that the fluorescent pigment produced in PDA and the siderophore produced in CAS agar were not the same. Afa- and Flu- mutants had a smaller inhibition zone when grown with Rhizoctonia solani than the EM85 wild type. Sid- and HCN mutants failed to inhibit the pathogen in vitro. In a pot experiment, mutants deficient in HCN and siderophore production could suppress the damping-off disease by 52%. However, mutants deficient in fluorescent pigments and antifungal antibiotics failed to reduce the disease severity. Treatments with mutants that produced enhanced amounts of fluorescent pigments and antibiotics compared with EM85 wild type, exhibited an increase in biocontrol efficiency. Monitoring of the mutants in the rhizosphere using the lacZ marker showed identical proliferation of mutants and wild type. Purified antifungal compounds (fluorescent pigment and antibiotic) also inhibited the fungus appreciably in a TLC bioassay. Thus, the results indicate that fluorescent pigment and antifungal antibiotic of the fluorescent Pseudomonas spp. EM85 might be involved in the biological suppression of Rhizoctonia-induced damping-off of cotton.     

Phenotypic diversity and antibiotic resistance in soil bacterial communities

The community structure in two different agricultural soils has been investigated. Phenotypic diversity was assessed by applying BIOLOG-profiles on a total of 208 bacterial isolates. Diversity indices were calculated from cluster analysis of the BIOLOG data. The bacterial isolates were also evaluated for resistance towards six different antibiotics, mercury resistance and the presence of plasmids. The presence of tetracycline-resistant determinants class A to E among Gram-negative bacteria was analysed with DNA probes. The distribution of tetracycline resistance markers among colonies growing on non-selective and tetracycline-selective plates were compared. The phenotypic approach demonstrated some difference in the diversity within the two soils. The frequency of antibiotic resistance isolates was high in both soils, whereas the frequency of mercury resistance differed significantly. We found no correlation between plasmid profiles and antibiotic resistance patterns. We found all the tetracycline resistance determinants except class B, indicating that the diversity of the tetracycline resistance determinants was complex in populations of resident soil bacteria under no apparent selective pressure for the genes in question.