Genetic diversity of indigenous Rhizobium leguminosarum bv. viciae isolates nodulating two different host plants during soil restoration with alfalfa.

A total of 360 Rhizobium leguminosarum bv. viciae strains was isolated from three brown-coal mining restoration fields of different age and plant cover (without and in the first and second year of alfalfa, Medicago sativa, cultivation) using two host species (Vicia hirsuta and Pisum sativum) as capture plants. The strains were genetically typed by restriction fragment length polymorphism analysis of polymerase chain reaction (PCR)-generated 16S-23S ribosomal DNA intergenic spacer regions (IGS-RFLP) and characterized by plasmid profiles and RFLP analysis of amplified nodABC genes. The R. leguminosarum bv. viciae population was dominated by the same group of strains (irrespective of the trap plant used). According to type richness, the genetic diversity of indigenous R. leguminosarum in the second year of restoration was lower than in the first year and it resembled that of the fallow field, except for plasmid types, in which it was higher than that of the fallow field. Some of the less frequent nodABC genotypes were associated with distinct chromosomal IGS genotypes and symbiotic plasmids (pSyms) of different sizes, indicating that horizontal transfer and rearrangements of pSym can occur in natural environments. However, the dominant pSym and chromosomal genotypes were strictly correlated suggesting a genetically stable persistence of the prevailing R. leguminosarum bv. viciae genotypes in the absence of its host plant.

Symbiotic plasmid rearrangement in Rhizobium leguminosarum bv. viciae VF39SM.

A rearrangement between the symbiotic plasmid (pRleVF39d) and a nonsymbiotic plasmid (pRleVF39b) in Rhizobium leguminosarum bv. viciae VF39 was observed. The rearranged derivative showed the same plasmid profile as its parent strain, but hybridization to nod, fix, and nif genes indicated that most of the symbiotic genes were now present on a plasmid corresponding in size to pRleVF39b instead of pRleVF39d. On the other hand, some DNA fragments originating from pRleVF39b now hybridized to the plasmid band at the position of pRleVF39d. These results suggest that a reciprocal but unequal DNA exchange between the two plasmids had occurred.

The Sinorhizobium meliloti insertion sequence (IS) element ISRm14 is related to a previously unrecognized IS element located adjacent to the Escherichia coli locus of enterocyte effacement (LEE) pathogenicity island.

ISRm14 is 2695 basepairs (bp) in size and bordered by 22 bp imperfect inverted repeats (IRs). A 9-bp target sequence is duplicated upon ISRm14 transposition. The DNA strand that putatively encodes the transposase enzyme carries three open reading frames (ORFs) designated ORFs1 to 3, which specify putative proteins of 15. 9 kDa, 13.1 kDa, and 61.1 kDa, respectively. According to its structural characteristics, ISRm14 belongs to the recently proposed IS66 family of IS elements. The ORFs1 to 3 encoded putative proteins displayed significant similarities to ORFs of the previously unrecognized IS element ISEc8, which is inserted adjacent to the locus of enterocyte effacement (LEE) pathogenicity island of Escherichia coli EDL933. Analyses of the distribution of ISRm14 in a natural S. meliloti population showed its widespread occurrence in 66% of the strains tested with a copy number ranging from 1 to 6.

The insertion sequence element ISRm2011-2 belongs to the IS630-Tc1 family of transposable elements and is abundant in Rhizobium meliloti.

The insertion sequence (IS) element ISRm2011-2 of Rhizobium meliloti (Rm) is characterized by 19-bp imperfect terminal inverted repeats (three mismatches) and a size of 1053 bp. Upon transposition, ISRm2011-2 generates a putative target duplication of 2 bp. ISRm2011-2 carries two major overlapping open reading frames (ORFA and B) with a coding capacity of 135 and 201 amino acids (aa), respectively. A potential translational frameshifting window (5'-AAAAAAAG) is located in the overlapping region of both ORFs. The putative fusion product of both proteins, which probably represents the mature transposase, has a predicted molecular mass of 35.8 kDa and a pI of 10.5. Comparison of the deduced aa sequence of ORFA with database entries revealed homology to putative transposases of some IS elements of the IS3 family, as well as to eukaryotic transcription factors. The protein encoded by ORFB shows homology to transposases (Tps) of the recently proposed IS630-Tc1 family which includes Tps of both prokaryotic and eukaryotic transposable elements. Analyses of the distribution of ISRm2011-2 in natural Rm populations showed that this IS element is abundant in Rm strains.

Isolation and characterization of insertion sequence elements from gram-negative bacteria by using new broad-host-range, positive selection vectors.

On the basis of an RSF1010-derived broad-host-range vector, three different systems which enable positive detection and isolation of insertion sequence (IS) elements from gram-negative bacteria were constructed. Vectors pSUP104-pheS, pSUP104-rpsL, and pSUP104-sac were used successfully in a number of Rhizobium strains and in Xanthomonas campestris. More than 20 different IS elements were isolated and characterized. The 16 IS elements from Rhizobium meliloti were further used to characterize various R. meliloti strains by hybridization. The resulting hybridization patterns were different for every strain and gave a clear and definite IS fingerprint of each strain. These IS fingerprints can be used to identify and characterize R. meliloti strains rapidly and unequivocally, as they proved to be relatively stable. Some of the IS elements were found to be identical when the IS fingerprints from a given strain were compared. This method of IS fingerprinting can also establish whether IS elements are the same, related, or different.