A review of the allozyme data set for the Canarian endemic flora: causes of the high genetic diversity levels and implications for conservation.

Background and Aims Allozyme and reproductive data sets for the Canarian flora are updated in order to assess how the present levels and structuring of genetic variation have been influenced by the abiotic island traits and by phylogenetically determined biotic traits of the corresponding taxa; and in order to suggest conservation guidelines. Methods Kruskal-Wallis tests are conducted to assess the relationships of 27 variables with genetic diversity (estimated by A, P, Ho and He) and structuring (GST) of 123 taxa representing 309 populations and 16 families. Multiple linear regression analyses (MLRAs) are carried out to determine the relative influence of the less correlated significant abiotic and biotic factors on the genetic diversity levels. Key Results and Conclusions The interactions between biotic features of the colonizing taxa and the abiotic island features drive plant diversification in the Canarian flora. However, the lower weight of closeness to the mainland than of (respectively) high basic chromosome number, partial or total self-incompatibility and polyploidy in the MLRAs indicates substantial phylogenetic constraint; the importance of a high chromosome number is feasibly due to the generation of a larger number of linkage groups, which increase gametic and genotypic diversity. Genetic structure is also more influenced by biotic factors (long-range seed dispersal, basic chromosome number and partial or total self-incompatibility) than by distance to the mainland. Conservation-wise, genetic structure estimates (FST/GST) only reflect endangerment under intensive population sampling designs, and neutral genetic variation levels do not directly relate to threat status or to small population sizes. Habitat protection is emphasized, but the results suggest the need for urgent implementation of elementary reproductive studies in all cases, and for ex situ conservation measures for the most endangered taxa, even without prior studies. In non-endangered endemics, multidisciplinary research is needed before suggesting case-specific conservation strategies. The molecular information relevant for conservation should be conserved in a standardized format to facilitate further insight.

The molecular phylogeny of Matthiola R. Br. (Brassicaceae) inferred from ITS sequences, with special emphasis on the Macaronesian endemics.

Matthiola (Brassicaceae) is a genus that is widespread in the Mediterranean and Irano-Turanian regions and includes two species that are endemic to the archipelagos of Madeira and the Canaries in Macaronesia, which is an insular oceanic hotspot of biodiversity harboring many radiating endemic plant lineages. Sequence analyses of the nuclear ITS-1 and ITS-2 regions in a comprehensive geographical sample of Matthiola, encompassing all the endemic Macaronesian populations known to date, suggest independent Mediterranean and NW African origins of the taxa in Madeira and the Canaries, respectively. These molecular data reveal a complex evolutionary landscape that converges with morphological analyses in the recognition of two new Madeiran species. The data also suggest that the Canarian infra-specific endemic taxa described thus far have high (but non-diagnostic) levels of morphological and genetic diversity, and should be included in the single endemic Matthiola bolleana. In agreement with earlier investigations that revealed a high genetic differentiation between the populations of Matthiola in Fuerteventura and Lanzarote, our phylogeny supports independent founder events from the same mainland congener to either island. The consistently derived position of the Moroccan populations within a mostly Canarian clade suggests a further back-colonization of the continent. Notably, the ITS sequence resolution offered by Matthiola is higher than that found in many of the radiating Canarian endemic lineages for which molecular phylogenetic studies abound. Hence, our research discovers largely unexplored pathways to understand plant diversification in this oceanic insular hotspot through the investigation of non-speciose endemics.

Characterization of Pasteurella multocida associated with pneumonia in bighorn sheep.

Pasteurella multocida is a highly diverse group of bacteria recognized as important pathogens. Although P. multocida is not ordinarily associated with disease in Rocky Mountain bighorn sheep (Ovis canadensis canadensis), numerous isolates were cultured in high numbers from free-ranging bighorn sheep in the Hells Canyon area of Idaho, Washington, and Oregon (USA) during the winter of 1995-96. Animals captured in Hells Canyon and held in captivity, and their offspring, also harbored P. multocida. Biochemical utilization tests on 90 isolates identified three subspecies: P. multocida multocida a (n = 54); P. multocida multocida b (n = 13); and P. multocida gallicida (n = 15); and a non-speciated biotype, U6 (n = 8). Genomic DNA digestion with restriction endonuclease Hha I separated the isolates into 62 unique restriction fragment length polymorphism profiles. Capsular type A was predominant (72% of isolates). Only one isolate type, which may have been transmitted from a feral goat, was capsular type D, possessed the structural gene, toxA, for dermonecrotoxin detected by polymerase chain reaction, and produced toxin as determined by monoclonal antibody immunoblot. In conclusion, bighorn sheep in this study carried diverse types of generally non-toxigenic P. multocida associated with epizootic pneumonia.