Local climate and vernalization requirements explain the latitudinal patterns of flowering initiation in the crop wild relative Linum bienne

Background and Aims: Days to flowering initiation in species with large geographic distributions often correlate with latitude. Latitude reflects climatic gradients, but it is unclear if large-scale differentiation in flowering results from adaptation to local climate, and whether adaptation to local climate could constrain shifts in distribution and colonization of new environments. Methods: In its Western range in Europe, L. bienne populations were surveyed to describe latitudinal patterns of flowering initiation and determine its correlation with the local climate of populations. This was measured under standardized greenhouse conditions, with a vernalization experiment to learn if chilling advances flowering, and with a reciprocal transplant experiment at three sites along the latitudinal gradient, recording flowering at the central site and plant survival in all sites. Also, genetic differentiation of populations along the latitudinal range was studied using microsatellite markers. Key Results: Flowering initiation varied with latitude, with southern populations flowering earlier than northern populations. Latitude also predicted population response to vernalization, with chilling inducing a greater advance of flowering initiation in northern than southern populations. In general, plant survival in the reciprocal transplant experiment decreased with the geographic distance of populations to the experimental site and, at the central site, flowering initiation varied with latitude of origin. However, across experiments, the local climate of populations better predicted the differentiation in flowering initiation and vernalization response than latitude of origin. Finally, the microsatellite data revealed genetic differentiation of populations forming two groups that agree with a Mediterranean and Atlantic lineage. Conclusions: The consistent result across experiments of a latitudinal cline in flowering initiation and in the vernalization response suggests that flowering is under genetic regulation and yet dependent on particular environmental and climatic cues at local scale. However, the genetic differentiation suggests that past population history might influenced the flowering initiation patterns detected.

Microbiome restructuring: dominant coral bacterium Endozoicomonas species display differential adaptive capabilities to environmental changes

Bacteria in the coral microbiome play a crucial role in determining coral health and fitness, and the coral host often restructures its microbiome composition in response to external factors. An important but often neglected factor determining this microbiome restructuring is the capacity of microbiome members to adapt to a new environment. To address this issue, we examined how the microbiome structure of Acropora muricata corals changed over 9 months following a reciprocal transplant experiment. Using a combination of metabarcoding, genomics, and comparative genomics approaches, we found that coral colonies separated by a small distance harbored different dominant Endozoicomonas related phylotypes belonging to two different species, including a novel species, Candidatus Endozoicomonas penghunesis 4G, whose chromosome level (complete) genome was also sequenced in this study. Furthermore, the two dominant Endozoicomonas species showed varied adaptation capabilities when coral colonies were transplanted in a new environment. The differential adaptation capabilities of dominant members of the microbiome can a) provide distinct advantages to coral hosts when subjected to changing environmental conditions and b) have positive implications for future reefs.

The ecological, genetic and genomic architecture of local adaptation and population differentiation in Boechera stricta

Differential local adaptation restricts gene flow between populations inhabiting distinct environments, resulting in isolation by adaptation. In addition to the statistical inferences of genotype–environment associations, an integrative approach is needed to investigate the effect of local adaptation on population divergence at the ecological, genetic and genomic scale. Here, we combine reciprocal transplant, genome–environment association and QTL mapping to investigate local adaptation in Boechera stricta (Drummond's rockcress). With reciprocal transplant experiment, we found local genetic groups exhibit phenotypic characteristics corresponding to the distinct selection forces from different water availability. At the genetic level, the local allele of a major fitness QTL confers higher and sturdier flowering stalks, maximizing the fecundity fitness component under sufficient water supply, and its genetic variation is associated with precipitation across the landscape. At the genomewide scale, we further showed that multiple loci associated with precipitation are highly differentiated between genetic groups, suggesting that local adaptation has a widespread effect on reducing gene flow. This study provides one of the few comprehensive examples demonstrating how local adaptation facilitates population divergence at the trait, gene and genome level.