Your search keyword '"Boechera stricta"' showing total 3 results

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

Author

Ya-Ping Lin, Mitchell-Olds, Thomas, and Cheng-Ruei Lee

Subjects

*POPULATION differentiation, *GENE flow, *POPULATION genetics, *WATER supply, *INFERENTIAL statistics, *ARABIDOPSIS

Abstract

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. [ABSTRACT FROM AUTHOR]

Published

2021

2. Phenological shifts of native and invasive species under climate change: insights from the Boechera-Lythrum model.

Author

Colautti, Robert I., Ågren, Jon, and Anderson, Jill T.

Subjects

*PURPLE loosestrife, *GROWTH rate, *FLOWERING time, *OPTIMAL control theory, *ECOLOGY

Abstract

Warmer and drier climates have shifted phenologies of many species. However, the magnitude and direction of phenological shifts vary widely among taxa, and it is often unclear when shifts are adaptive or how they affect long-term viability. Here, we model evolution of flowering phenology based on our long-term research of two species exhibiting opposite shifts in floral phenology: Lythrum salicaria, which is invasive in North America, and the sparse Rocky Mountain native Boechera stricta. Genetic constraints are similar in both species, but differences in the timing of environmental conditions that favour growth lead to opposite phenological shifts under climate change. As temperatures increase, selection is predicted to favour earlier flowering in native B. stricta while reducing population viability, even if populations adapt rapidly to changing environmental conditions. By contrast, warming is predicted to favour delayed flowering in both native and introduced L. salicaria populations while increasing long-term viability. Relaxed selection from natural enemies in invasive L. salicaria is predicted to have little effect on flowering time but a large effect on reproductive fitness. Our approach highlights the importance of understanding ecological and genetic constraints to predict the ecological consequences of evolutionary responses to climate change on contemporary timescales. This article is part of the themed issue 'Human influences on evolution, and the ecological and societal consequences'. [ABSTRACT FROM AUTHOR]

Published

2017

3. Phenotypic plasticity and adaptive evolution contribute to advancing flowering phenology in response to climate change.

Author

Jill T., Anderson, David W., Inouye, Amy M., McKinney, Robert I., Colautti, and Tom, Mitchell-Olds

Subjects

*CLIMATE change, *LIFE history theory, *PHENOTYPIC plasticity, *ANGIOSPERMS, *QUANTITATIVE research, *SURVEYS

Abstract

Anthropogenic climate change has already altered the timing of major life-history transitions, such as the initiation of reproduction. Both phenotypic plasticity and adaptive evolution can underlie rapid phenological shifts in response to climate change, but their relative contributions are poorly understood. Here, we combine a continuous 38 year field survey with quantitative genetic field experiments to assess adaptation in the context of climate change. We focused on Boechera stricta (Brassicaeae), a mustard native to the US Rocky Mountains. Flowering phenology advanced significantly from 1973 to 2011, and was strongly associated with warmer temperatures and earlier snowmelt dates. Strong directional selection favoured earlier flowering in contemporary environments (2010–2011). Climate change could drive this directional selection, and promote even earlier flowering as temperatures continue to increase. Our quantitative genetic analyses predict a response to selection of 0.2 to 0.5 days acceleration in flowering per generation, which could account for more than 20 per cent of the phenological change observed in the long-term dataset. However, the strength of directional selection and the predicted evolutionary response are likely much greater now than even 30 years ago because of rapidly changing climatic conditions. We predict that adaptation will likely be necessary for long-term in situ persistence in the context of climate change. [ABSTRACT FROM AUTHOR]

Published

2012