ABSTRACT
The cyanobacterium Anabaena has both symbiotic and free-living forms. The genetic diversity of Anabaena strains symbiotically associated with the aquatic fern Azolla and the evolutionary relationships among these symbionts were evaluated by means of RFLP (restriction fragment length polymorphism) experiments. Three DNA fragments corresponding to nif genes were cloned from the free-living cyanobacterium Anabaena PCC 7120 and used as probes. A mixture of Azolla, Anabaena and bacterial DNA was extracted from Azolla fronds and digested with two restriction enzymes. Single-copy RFLP signals were detected with two of the probes in all Azolla Anabaena examined. Multiple-copy RFLP signals were obtained from the third probe which corresponded to a part of the nif N gene. A total of 46 probe/enzyme combinations were scored as present or absent and used to calculate pairwise Nei's genetic distances among symbiotic Anaebaena strains. Phylogenetic trees summarizing phenetic and cladistic relationships among strains were generated according to three different evolutionary scenarios: parsimony, UPGMA and neighbour joining. All trees revealed identical phylogenetic relationships. Principal component analysis was also used to evaluate genetic similarities and revealed three groups: group one contains the cyanobacteria associated with plants from the Azolla section, group two contains those associated with plants from the pinnata species and group three contains those associated with plants from the nilotica species. The same groups had already been identified earlier in a random amplified polymorphic DNA (RAPD) analysis of Azolla-Anbaena DNA complexes, suggesting that the present Azolla taxonomy should be revised. We now suggest a taxonomy of Anabaena azollae that is parallel to such a revised Azolla taxonomy. An Azolla chloroplast DNA sequence derived from Oryza sativa was also used as an RFLP probe on Azolla DNA to confirm the presence of plant DNA in the total genomic DNA extracted from ferns with or without the symbiont. Our results also suggest that total DNA extracted from the Azolla-Anabaena complexes includes both plant and symbiont DNA and can be used equally well for RFLP analysis of host plant or symbiotic cyanobacteria.
ABSTRACT
The polymerase chain reaction was used to amplify random sequences of DNA from 25 accessions of Azolla to evaluate the usefulness of this technique for identification and phylogenetic analysis of this aquatic fern. Accessions were selected to represent all known species within the genus Azolla and to encompass the world-wide distribution of the fern. Primers of 10 nucleotides with 70% G + C content were used to generate randomly amplified polymorphic DNA from the symbiotic Azolla-Anabaena complex. Twenty-two primers were used and each primer gave 4-10 bands of different molecular weights for each accession. Bands were scored as present or absent for each accession and variation among accessions was quantified using Nei's genetic distances. A dendrogram summarizing phenetic relationships among the 25 accessions was generated using the unweighted pair-group method with arithmetic mean. Principal component analysis was also used to evaluate genetic similarities. Three distinct groups were identified: group 1 contains five species, group 2 contains the pinnata species, and group 3 contains the nilotica species. The analysis demonstrates that the major groups of Azolla species can be easily distinguished from one an other and, in addition, that closely related accessions within species can be identified. We further found that using 10 primers, a phylogeny that is essentially the same as that derived from 22 primers can be constructed. Our results suggest that total DNA extracted from the Azolla-Anabaena symbionts is useful for classification and phylogenetic studies of Azolla.
