THE CONTRIBUTION OF SPONTANEOUS MUTATION TO VARIATION IN ENVIRONMENTAL RESPONSES OF ARABIDOPSIS THALIANA: RESPONSES TO LIGHT

It has been hypothesized that new, spontaneous mutations tend to reduce fitness more severely in more stressful environments. To address this hypothesis, we grew plants representing 20 Arabidopsis thaliana mutation-accumulation (M-A) lines, advanced to generation 17, and their progenitor, in differi...

Full description

Saved in:
Bibliographic Details
Published in:Evolution 2005-02, Vol.59 (2), p.266-275
Main Authors: Kavanaugh, Christina M, Shaw, Ruth G
Format: Article
Language:English
Subjects:
Arabidopsis - genetics
Arabidopsis - growth & development
Biomass
Drosophila
Ecological competition
Environment
Evolution
Evolutionary genetics
Flowers & plants
Genetic mutation
Genetic Variation
Genotype
Genotype & phenotype
Genotype-by-environment interaction
Genotypes
Light
light quality
Models, Genetic
Mutation
Mutation - genetics
mutation accumulation
mutational variation
Phenotypic traits
Plants
Quantitative genetics
Regression Analysis
REGULAR ARTICLES
Selection, Genetic
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:It has been hypothesized that new, spontaneous mutations tend to reduce fitness more severely in more stressful environments. To address this hypothesis, we grew plants representing 20 Arabidopsis thaliana mutation-accumulation (M-A) lines, advanced to generation 17, and their progenitor, in differing light conditions. The experiment was conducted in a greenhouse, and two treatments were used: full sun and shade, in which influx of red light was reduced relative to far-red. The shade treatment was considered the more stressful because mean absolute fitness was lower in that treatment, though not significantly so. Plants from generation 17 of M-A developed significantly faster than those from generation 0 in both treatments. A significant interaction between generation and treatment revealed that, counter to the hypothesis, M-A lines tended to have higher fitness on average relative to the progenitor in the shaded conditions, whereas, in full sun, the two generations were similar in fitness. A secondary objective of this experiment was to characterize the contribution of new mutations to genotype Ă— environment interaction. We did not, however, detect a significant interaction between M-A line and treatment. Plots of the line-specific environmental responses indicate no tendency of new mutations to contribute to fitness trade-offs between environments. They also do not support a model of conditionally deleterious mutation, in which a mutant reduces fitness only in a particular environment. These results suggest that interactions between genotype and light environment previously documented for A. thaliana are not explicable primarily as a consequence of steady input of spontaneous mutations having environment-specific effects.
ISSN:0014-3820
1558-5646
DOI:10.1554/04-195