The influence of environment and life-history traits on the distribution of genes and individuals: a comparative study of 11 rainforest trees.

This study investigates patterns of genetic connectivity among 11 co-distributed tropical rainforest tree species from the genus Elaeocarpus across a biogeographic barrier, the Black Mountain Corridor (BMC) in the Australian Wet Tropics (AWT). We analysed a combination of allelic and flanking region sequence data from microsatellite markers, and evaluated the relative influence of environmental preferences and functional traits on genetic diversity and gene flow. The results indicate that only in three species geographic structuring of haplotype distribution reflects a north vs. south of the BMC pattern. Environmental factors linked with altitude were recognized as affecting genetic trends, but the selective processes operating on upland species appear to be associated with competitiveness and regeneration opportunities on poor soil types rather than climate variables alone. In contrast to previous observations within southeastern Australian rainforests, genetic differentiation in the AWT appears to be associated with small-fruited rather than large-fruited species, highlighting how external factors can influence the dispersal dimension. Overall, this study emphasizes the importance of considering functional and environmental factors when attempting generalizations on landscape-level patterns of genetic variation. Understanding how plant functional groups respond to environmental and climatic heterogeneity can help us predict responses to future change.

The evolution of the atpbeta-rbcL intergenic spacer in the epacrids (Ericales) and its systematic and evolutionary implications.

Sequence data from the noncoding region separating the plastid genes atpbeta and rbcL were gathered for 27 epacrid taxa, representing all previously recognized infrafamilial groups, and four outgroup taxa (Ericaceae), to address several persistent phylogenetic questions in the group. Parsimony analyses were conducted on these data, as well as on a complementary rbcL sequence dataset assembled from the literature and the combined dataset. The atpbeta-rbcL spacer was notable for the high frequency of insertion-deletion mutations (indels); their distributions were coded as binary characters and included as a adjunct matrix in some of the analyses. The phylogenetic patterns derived from the spacer and rbcL data and the combined analyses, both including and excluding the indel data, concur in resolving seven major lineages corresponding to the tribes of Crayn et al. (1998, Aust. J. Bot. 46, 187-200), viz. Prionoteae, Archerieae, Oligarrheneae, Cosmelieae, Richeeae, Epacrideae, and Styphelieae. The relationships of the tribes and within Styphelieae, however, are not convincingly resolved. Minor conflicts in the positions of some taxa between the spacer and the rbcL trees are poorly supported. Among epacrids, the spacer region provided more cladistically informative characters than rbcL and resulted in trees with lower homoplasy. Further, the spacer data, when analyzed alone and when combined with rbcL, resolved several clades that could not be retrieved on rbcL data alone and provided increased support for many other relationships. The evolution of a putative three-base inversion associated with a hairpin secondary structure in the spacer region is discussed in the light of the inferred phylogeny.

Phylogenetic analyses of Andromedeae (Ericaceae subfam. Vaccinioideae).

Phylogenetic relationships within the Andromedeae and closely related taxa were investigated by means of cladistic analyses based on phenotypic (morphology, anatomy, chromosome number, and secondary chemistry) and molecular (rbcL and matK nucleotide sequences) characters. An analysis based on combined molecular and phenotypic characters indicates that the tribe is composed of two major clades-the Gaultheria group (incl. Andromeda, Chamaedaphne, Diplycosia, Gaultheria, Leucothoë, Pernettya, Tepuia, and Zenobia) and the Lyonia group (incl. Agarista, Craibiodendron, Lyonia, and Pieris). Andromedeae are shown to be paraphyletic in all analyses because the Vaccinieae link with some or all of the genera of the Gaultheria group. Oxydendrum is sister to the clade containing the Vaccinieae, Gaultheria group, and Lyonia group. The monophyly of Agarista, Lyonia, Pieris, and Gaultheria (incl. Pernettya) is supported, while that of Leucothoë is problematic. The close relationship of Andromeda and Zenobia is novel and was strongly supported in the molecular (but not morphological) analyses. Diplycosia, Tepuia, Gaultheria, and Pernettya form a well-supported clade, which can be diagnosed by the presence of fleshy calyx lobes and methyl salicylate. Recognition of Andromedeae is not reflective of our understanding of geneological relationships and should be abandoned; the Lyonia group is formally recognized at the tribal level.

Rosid affinities of Surianaceae: molecular evidence.

Nucleotide sequences of the chloroplast gene, rbcL, were obtained for Suriana maritima, Cadellia pentastylis, Guilfoylia monostylis, Stylobasium australe, Quassia amara, Brucea mollis, Cupaniopsis anacardioides, Mangifera indica, Connarus conchocarpus, and Comesperma ericinum. Phylogenetic analyses of these, along with published sequences of representatives of rosid families, support the monophyly of the Surianaceae sensu Cronquist and provide evidence of an affinity with the Polygalaceae and Fabaceae. These conclusions are discussed in the light of available morphological data.