Phenotypic and genotypic characterization of mutants of the virginiamycin producing strain 899 and its relatedness to the type strain of Streptomyces virginiae.

A representative set of 19 mutants, with a known genealogy, of the virginiamycin producing strain Streptomyces virginiae 899 was investigated phenotypically and genotypically. Colour of the aerial and substrate mycelium were very variable both among spontaneous variants and those obtained after induced mutagenesis. At genotypic level, all mutants showed nearly identical BOX patterns, not reflecting the phenotypic heterogeneity observed. More than 40 years of forced mutational pressure did not cause huge chromosomal distortions but was most likely limited to base substitutions. The species S. virginiae, including besides producers of virginiamycin the type strain and non-type strains producing other bioactive compounds, is genomically heterogeneous on the basis of BOX-PCR fingerprinting and DNA-DNA hybridizations. The virginiamycin producing strain 899 does not belong to the species S. virginiae despite its phenotypic similarity to the latter.

The bacterial microflora of witloof chicory (Cichorium intybus L. var.foliosum Hegi) leaves.

The bacterial flora on the heads of four different witloof chicory varieties was examined. The 590 isolates were characterized by their SDS-PAGE protein profiles; they revealed 149 different protein fingerprint types. The fluorescentPseudomonas fingerprint type CH001 was abundantly found on all heads examined. Fourteen other fingerprint types occurred in high densities more than twice. Among these, the following were identified: fluorescentPseudomonas, nonfluorescentPseudomonas sp.,Erwinia herbicola, Erwinia sp., andFlavobacterium sp. The majority of the fingerprint types (90%) was found only once. It was also our objective to isolate bacteria applicable in the biological control of chicory phytopathogens. Isolates of all fingerprint types were tested for in vitro antagonistic activity and for possible deleterious effect on plant growth. FluorescentPseudomonas andSerratia liquefaciens isolates were antagonistic against fungi. Among the 161 fluorescentPseudomonas strains, five were able to produce disease symptoms on chicory leaves upon inoculation. Comparison of the results of this study with those obtained in two previous analyses revealed that the leaf microflora showed some similarities with the bacterial flora of chicory roots. The chicory seed microflora differed from that of both leaves and roots.

Composition of the microflora of witloof chicory seeds.

The bacterial microflora of nine varieties of witloof chicory (Cichorium intybus L. var.foliosum Hegi) seeds was studied. The 184 isolates were characterized by protein profiles determined by SDS-protein polyacrylamide gel electrophoresis of the total cell proteins. Isolates with identical protein profiles were grouped into one fingerprint type. Sixty-seven fingerprint types were distinguished. Two quantitatively major fingerprint types,Erwinia herbicola and an arthrobacter, represented 52% of the total number of isolates and were found on different chicory varieties. The latter organism was inhibited at seed germination. Other isolates, i.e.,Xanthomonas maltophilia, Pseudomonas paucimobilis, Agrobacterium radiobacter, Pseudomonas syringae, and a fluorescentPseudomonas, were only occasionally found. A minority were gram-positive isolates, i.e.,Bacillus sp.,Streptomyces sp., and coryneforms. In vitro activity of the isolates was tested against five fungi. Isolates with strong antifungal activity were found amongErwinia herbicola andBacillus sp.

Rhizobacteria of maize and their antifungal activities.

During the growing season of 1984, the rhizobacteria (including organisms from the rhizosphere soil, the rhizoplane, and internal root zones) of 47 maize plants (two varieties) sampled from different locations in France and at different growth stages were inventoried. Isolates were characterized by sodium dodecyl sulfate-polyacrylamide gel electrophoresis of their total cell proteins and were found to represent 352 different protein electrotypes. Maize seedlings were initially colonized by a small number of different strains. Densities reached up to 10 CFU/g of root. Later in the season, the population density decreased but the heterogeneity of the rhizobacterial populations increased. Fluorescent pseudomonads represented up to 35% of the total rhizobacterial population and comprised 43 different electrotypes. Other bacteria regularly present were Xanthomonas maltophilia, Serratia liquefaciens, Pseudomonas paucimobilis, and Bacillus spp. There was a very low similarity between rhizobacterial populations of plants of the same cultivar (LG5) within one field at different growth stages and also between rhizobacterial populations of the cultivars LG5 and BRIO42 on the same field. Most electrotypes (76%) were found on a single occasion. None of the 352 electrotypes was present on all plants. In the 1985 analysis the rhizobacteria of maize seedlings (one variety) sampled from one field were characterized. They represented 236 different protein electrotypes. Thirty-three isolates showed antifungal activity against major maize pathogens; they comprised four Pseudomonas cepacia strains, producing pyrrolnitrin as well as another unknown antifungal compound.

Differentiation between Xanthomonas campestris pv. oryzae, Xanthomonas campestris pv. oryzicola and the bacterial 'brown blotch' pathogen on rice by numerical analysis of phenotypic features and protein gel electrophoregrams.

Thirty-five Xanthomonas campestris pv. oryzae, fourteen X. campestris pv. oryzicola strains and six 'brown blotch' pathogens of rice, all of different geographical origin, were studied by numerical analysis of 133 phenotype features and gel electrophoregrams of soluble proteins, %G + C determinations and DNA:rRNA hybridizations. The following conclusions were drawn. (i) The Xanthomonas campestris pathovars oryzae and oryzicola display clearly distinct protein patterns on polyacrylamide gels and can be differentiated from each other by four phenotype tests. (ii) Both pathovars are indeed members of Xanthomonas which belongs to a separate rRNA branch of the second rRNA superfamily together with the rRNA branches of Pseudomonas fluorescens, Marinomonas, Azotobacter, Azomonas and Frateuria. (iii) 'Brown blotch' strains are considerably different from X. campestris pv. oryzae and oryzicola. They are not members of the genus Xanthomonas, but are more related to the generically misnamed. Flavobacterium capsulatum, Pseudomonas paucimobilis, Flavobacterium devorans and 'Pseudomonas azotocolligans' belonging in the fourth rRNA superfamily. (iv) No correlation was found between the virulence, pathogenic groups or geographical distribution of X. campestris pv. oryzae or oryzicola strains and any phenotypic or protein electrophoretic property or clustering.

Identification of Acetobacter strains isolated from spoiled lactic acid fermented meat food for pets.

Five Acetobacter isolates from lactic acid fermented meat food for pets were characterized by 177 morphological, physiological and biochemical traits. Four isolates were identified as A. pasteurianus, one as A. aceti. It is emphasized that access of such bacteria to lactic acid fermented foods should be avoided.

Numerical Analysis of Phenotypic Features and Protein Gel Electrophoregrams of a Wide Variety of Acetobacter strains. Proposal for the Improvement of the Taxonomy of the Genus Acetobacter Beijerinck 1898, 215.

Ninety-eight strains, representing all Acetobacter species and subspecies from the Approved Lists of Bacterial Names (Skerman et al., 1980), were examined in a numerical analysis of 177 phenotypic features and compared to ninety-eight Gluconobacter and seven Frateuria strains. Four phenons could be delineated, corresponding to Frateuria (phenon 1), A. aceti subsp. liquefaciens (phenon 2), Gluconobacter (phenon 3) and Acetobacter minus A. aceti subsp. liquefaciens (phenon 4). Acetobacter, Frateuria and Gluconobacter are well- could be distinguished. Comparison of the protein electrophoregrams of Acetobacter strains revealed a fairly high internal homogeneity within phenon 2, subphenons C and D. Strains of the subphenon E gave very divergent protein patterns. The following classificatory changes are proposed within the genus Acetobacter: (1) Acetobacter liquefaciens sp. nov. is proposed for the homogeneous phenon 2, containing all 12 A. aceti subsp. liquefaciens strains (% G + C range of 62.3 to 64.6; IAM 1834 as type strain); (2) for the homogeneous subphenon D containing 8 A. aceti subsp. aceti strains, the name Acetobacter aceti emend, should be retained (% G + C range of 55.9 to 59.5; NCIB 8621 as type strain); (3) for subphenon E, a heterogeneous group, containing a variety of Acetobacter subspecies (all with their type strain) the species name Acetobacter pasteurianus emend, is preserved with LMD 22.1 as type strain; this species has the broad % G + C range of 52.8 to 62.5; (4) for subphenon C, a new species, Acetobacter hansenii sp. nov. is proposed (% G + C range of 58.1 to 62.6, NCIB 8746 as type strain). Minimal descriptions and differentiating keys are provided.

The nitrogen requirements of Gluconobacter, Acetobacter and Frateuria.

The nitrogen requirements of 96 Gluconobacter, 55 Acetobacter and 7 Frateuria strains were examined. Only some Frateuria strains were able to grow on 0.5% yeast extract broth or 0.5% peptone broth. In the presence of D-glucose or D-mannitol as a carbon source, ammonium was used as the sole source of nitrogen by all three genera. With ethanol, only a few Acetobacter strains grew on ammonium as a sole nitrogen source. Single L-amino acids cannot serve as a sole source of carbon and nitrogen for growth of Gluconobacter, Acetobacter or Frateuria. The single L-amino acids which were used by most strains as a sole nitrogen source for growth are: asparagine, aspartic acid, glutamine, glutamic acid, proline and alanine. Some Acetobacter and Gluconobacter strains deaminated alanine, asparagine, glutamic acid, threonine, serine and proline. No Frateuria strain was able to develop on cysteine, glycine, threonine or tryptophan as a sole source of nitrogen for growth. An inhibitory effect of valine may explain the absence of growth on this amino acid. No amino acid is "essential" for Gluconobacter, Acetobacter or Frateuria.

Gluconobacters from honey bees.

Fifty-six Gluconobacter strains and one Acetobacter strain were isolated from honey bees and their environment in three different regions in Belgium and identified phenotypically. Polyacrylamide gel electrophoresis of the soluble cell proteins showed that two different types exist within the Gluconobacter isolates: strains from type A were found in samples of the three regions, whereas strains from type B were only isolated in two of the three regions. Both types could occur in bees from the same region, from several hives of one bee keeper and from one hive. Strains from type A were almost identical with collection strain G. oxydans subsp. suboxydans NCIB 9018, whereas strains from type B constituted a new protein electrophoretic type within the genus Gluconobacter. Although Gluconobacter is apparently associated with honey bees, it is not known whether it is important or required for the bees or any hive product.