The ancient tropical rainforest tree Symphonia globulifera L. f. (Clusiaceae) was not restricted to postulated Pleistocene refugia in Atlantic Equatorial Africa.

Understanding the history of forests and their species' demographic responses to past disturbances is important for predicting impacts of future environmental changes. Tropical rainforests of the Guineo-Congolian region in Central Africa are believed to have survived the Pleistocene glacial periods in a few major refugia, essentially centred on mountainous regions close to the Atlantic Ocean. We tested this hypothesis by investigating the phylogeographic structure of a widespread, ancient rainforest tree species, Symphonia globulifera L. f. (Clusiaceae), using plastid DNA sequences (chloroplast DNA [cpDNA], psbA-trnH intergenic spacer) and nuclear microsatellites (simple sequence repeats, SSRs). SSRs identified four gene pools located in Benin, West Cameroon, South Cameroon and Gabon, and São Tomé. This structure was also apparent at cpDNA. Approximate Bayesian Computation detected recent bottlenecks approximately dated to the last glacial maximum in Benin, West Cameroon and São Tomé, and an older bottleneck in South Cameroon and Gabon, suggesting a genetic effect of Pleistocene cycles of forest contraction. CpDNA haplotype distribution indicated wide-ranging long-term persistence of S. globulifera both inside and outside of postulated forest refugia. Pollen flow was four times greater than that of seed in South Cameroon and Gabon, which probably enabled rapid population recovery after bottlenecks. Furthermore, our study suggested ecotypic differentiation-coastal or swamp vs terra firme-in S. globulifera. Comparison with other tree phylogeographic studies in Central Africa highlighted the relevance of species-specific responses to environmental change in forest trees.

Nuclear microsatellites for Pinus pinea (Pinaceae), a genetically depauperate tree, and their transferability to P. halepensis.

PREMISE OF THE STUDY: Pinus pinea is one of the few widespread plant species that are also genetically depauperate. It is also an important commercial species with high market value seeds. A deeper knowledge of the existing population genetic variation was needed. METHODS AND RESULTS: Twelve nuclear microsatellites were isolated from genomic and cDNA sequences and screened for variability in 729 individuals from 33 natural populations. Low level of genetic variability was confirmed with average expected heterozygosity of 0.11. Hardy-Weinberg equilibrium expectations were not met in only ∼10% of the possible locus/population combinations. All loci were in linkage equilibrium, and the frequency of null alleles was very low (≤1% in 332 out of 396 locus/population combinations). Nine out of the 12 microsatellites were successfully transferred to P. halepensis. CONCLUSIONS: Despite low polymorphism, these new markers will be useful to resolve population structure and hold potential for seed origin identification and traceability.