Disentangling the effects of isolation-by-distance and isolation-by-environment on genetic differentiation among <Emphasis Type="Italic">Rhododendron</Emphasis> lineages in the subgenus <Emphasis Type="Italic">Tsutsusi</Emphasis>

Ecological speciation has long been noted as a central topic in the field of evolutionary biology, and investigation into the relative importance of ecological and geographical factors is becoming increasingly emphasized. We surveyed genetic variation of 277 samples from 25 populations of nine Rhododendron species within Tsutsusi subgenus in Taiwan using simple sequence repeats of expressed sequence tags. Bayesian clustering revealed four genetic lineages: (1) the Rhododendron simsii, Rhododendron kanehirai, and Rhododendron nakaharae lineage (lineage 1); (2) the Rhododendron longiperulatum, Rhododendron breviperulatum, and Rhododendron noriakianum lineage (lineage 2); (3) the Rhododendron rubropilosum lineage (lineage 3); and (4) the Rhododendron oldhamii lineage (lineage 4). Asymmetric introgressions were found from lineage 3 into lineages 1 and 2 (introgressed lineages). Genetic admixture of non-R. oldhamii species was also revealed by a neighbor-joining tree. Variation partitioning showed that environment explained much larger portions of genetic variation than geography between non-introgressed lineages (i.e., between R. oldhamii and other lineages). However, the Mantel and partial Mantel tests and the multiple matrix regression with randomization found that isolation-by-distance played a more important role than isolation-by-environment (IBE) in contributing to genetic variation in most between lineage comparisons. Nevertheless, strong IBE was found when compared between non-introgressed lineages of R. oldhamii and R. rubropilosum, suggesting post-speciation ecological divergence. Several environmental variables, including annual mean temperature, aspect, isothermality, seasonal precipitation, slope, and soil pH, could be important ecological drivers involved in reproductive isolation between R. oldhamii and non-R. oldhamii species within the Tsutsusi subgenus.     

Complete chloroplast genome sequence of <Emphasis Type="Italic">Capsicum</Emphasis><Emphasis Type="Italic">baccatum</Emphasis> var. <Emphasis Type="Italic">baccatum</Emphasis>

Molecular markers derived from the complete chloroplast genome can provide effective tools for species identification and phylogenetic resolution. Complete chloroplast (cp) genome sequences of Capsicum species have been reported. We herein report the complete chloroplast genome sequence of Capsicum baccatum var. baccatum, a wild Capsicum species. The total length of the chloroplast genome is 157,145 bp with 37.7 % overall GC content. One pair of inverted repeats, 25,910 bp in length, was separated by a small single-copy region (17,974 bp) and large single-copy region (87,351 bp). This region contains 86 protein-coding genes, 30 tRNA genes, 4 rRNA genes, and 11 genes contain one or two introns. Pair-wise alignments of chloroplast genome were performed for genome-wide comparison. Analysis revealed a total of 134 simple sequence repeat (SSR) motifs and 282 insertions or deletions variants in the C. baccatum var. baccatum cp genome. The types and abundances of repeat units in Capsicum species were relatively conserved, and these loci could be used in future studies to investigate and conserve the genetic diversity of the Capsicum species.     

Development and validation of genomic simple sequence repeat markers in <Emphasis Type="Italic">Erianthus arundinaceus</Emphasis>

Erianthus arundinaceus, a member of the Saccharum complex, is of interest as a potential resource for sugarcane improvement and as a bioenergy crop. Genetic analyses of germplasm collections of E. arundinaceus are being used increasingly. To expand the genomic resources in E. arundinaceus, we aimed at developing simple sequence repeat markers. Using pyrosequencing on the 454 GS FLX system, we sequenced genomic DNA from “JW630” collected in Japan. A total of 1682 candidate loci were used to design the primers, and 1234 primer pairs amplified fragments of the expected size in the primer screening with three wild E. arundinaceus accessions (JW630, “JW4,” and “IJ76-349”). The efficiency of genotyping was validated with a subset of 174 primer pairs and 8 E. arundinaceus accessions. Of these primer pairs, 171 amplified fragments in all accessions tested and 162 detected polymorphic loci. The average values of genetic parameters were estimated as 0.30 (range, 0.09–0.49) for polymorphic information content, 1.65 (0.00–5.87) for marker index, and 2.78 (0.00–8.75) for resolving power. Using these parameters, we selected 61 primer pairs with large discriminatory power for the analyzed loci. Of the 174 primer pairs, 45 (25.9%) were also applicable to Saccharum and 33 (19.0%) to Miscanthus species. These markers would provide a valuable tool for estimating genetic diversity and constructing linkage maps in E. arundinaceus, which would be useful for genetic study and breeding.     

Conservation genetics of the highly endangered Azorean endemics <Emphasis Type="Italic">Euphrasia azorica</Emphasis> and <Emphasis Type="Italic">Euphrasia grandiflora</Emphasis> using new SSR data

In the Azores Islands, two Euphrasia L. (Orobanchaceae) endemic species are recognized: Euphrasia azorica H.C.Watson, an annual herb, in Flores and Corvo, and Euphrasia grandiflora Hochst. ex Seub., a semi-shrub, in Pico, São Jorge and Terceira. Both species are highly endangered and protected by the Bern Convention and Habitats Directive. A population genetics study was conducted with new microsatellite primer pairs in 159 individuals of E. azorica and E. grandifolia, sampled from populations in Flores, Corvo, Pico and São Jorge. Allele sizing suggested that E. azorica is a diploid while E. grandiflora is a tetraploid. Euphrasia grandiflora revealed higher genetic diversity then E. azorica. The E. grandiflora population of Morro Pelado in São Jorge, displayed higher genetic diversity when compared with all others, while the E. azorica population of Madeira Seca in Corvo, showed the lowest. Private and less common bands were also overall higher in E. grandiflora populations. Population genetic structure analysis confirmed a distinctiveness between the two Azorean endemic Euphrasia, in addition to island-specific genetic patterns in E. azorica. The genetic structure obtained for E. grandiflora was complex with the populations of Cabeço do Mistério in Pico Island and of Pico da Esperança in São Jorge sharing the same genetic group, while a putative spatial barrier to gene flow was still retrieved between both islands. Although some populations of both species might benefit from propagation actions, studies are needed on plant host species and translocations between islands or between some populations of a same island should be avoided, due to the occurrence of putative ESUs. Eradication of invasive species and control of grazing will be fundamental to promote in situ restauration.