Laura Leventhal
@lauracleventhal.bsky.social
Plant evolutionary ecologist! PhD candidate in Exposito Alonso lab.
Thanks, Brian!
October 23, 2025 at 8:43 PM
Thanks, Brian!
Thanks, Seema! And yes, here is a working link:
doi.org/10.1101/2025...
doi.org/10.1101/2025...
Simulated climate change magnifies genetic vulnerabilities from mutation load and maladaptation
As climate change intensifies, the genetic diversity and composition of natural populations will become critical for adaptation and survival. Standing genetic diversity within populations differs acro...
doi.org
October 22, 2025 at 10:20 PM
Thanks, Seema! And yes, here is a working link:
doi.org/10.1101/2025...
doi.org/10.1101/2025...
Updated link:
doi.org/10.1101/2025...
doi.org/10.1101/2025...
Simulated climate change magnifies genetic vulnerabilities from mutation load and maladaptation
As climate change intensifies, the genetic diversity and composition of natural populations will become critical for adaptation and survival. Standing genetic diversity within populations differs acro...
doi.org
October 22, 2025 at 10:19 PM
Updated link:
doi.org/10.1101/2025...
doi.org/10.1101/2025...
In A. thaliana and other plant systems, local adaptation is stronger closer to the equatorial edge and load is highest farther from the equator, which highlights a critical vulnerability: under strong selection, these high mutation load and low local adaptation populations may be the most at risk.
October 22, 2025 at 8:54 PM
In A. thaliana and other plant systems, local adaptation is stronger closer to the equatorial edge and load is highest farther from the equator, which highlights a critical vulnerability: under strong selection, these high mutation load and low local adaptation populations may be the most at risk.
We monitored these populations for 3 years, and found that population growth rate decreased as the treatments became more stressful. Further, "high risk" populations (either high load or low local adaptation scores) had a higher stochasticity for recovery after a single year of water stress.
October 22, 2025 at 8:54 PM
We monitored these populations for 3 years, and found that population growth rate decreased as the treatments became more stressful. Further, "high risk" populations (either high load or low local adaptation scores) had a higher stochasticity for recovery after a single year of water stress.
Crucially, we found a significant interaction between load and local adaptation, which grew stronger as the environment became more stressful. This suggests a synergistic decay of fitness resulting from locally adaptive variants, globally maladaptive load, and high water stress environments.
October 22, 2025 at 8:54 PM
Crucially, we found a significant interaction between load and local adaptation, which grew stronger as the environment became more stressful. This suggests a synergistic decay of fitness resulting from locally adaptive variants, globally maladaptive load, and high water stress environments.
We found that populations with a low number of local adaptation alleles or high mutation load had decreased fitness in our highest drought stress environments.
October 22, 2025 at 8:54 PM
We found that populations with a low number of local adaptation alleles or high mutation load had decreased fitness in our highest drought stress environments.
By using data from other A. thaliana common gardens and genomic prediction tools, we created synthetic experimental populations of A. thaliana that varied in their abundance of locally adaptive alleles and also in their mutational load.
October 22, 2025 at 8:54 PM
By using data from other A. thaliana common gardens and genomic prediction tools, we created synthetic experimental populations of A. thaliana that varied in their abundance of locally adaptive alleles and also in their mutational load.
Crucially, we found a significant interaction between load and local adaptation, which grew stronger as the environment became more stressful. This suggests a synergistic decay of fitness resulting from locally adaptive variants, globally maladaptive load, and high water stress environments.
October 22, 2025 at 8:50 PM
Crucially, we found a significant interaction between load and local adaptation, which grew stronger as the environment became more stressful. This suggests a synergistic decay of fitness resulting from locally adaptive variants, globally maladaptive load, and high water stress environments.
We found that populations with a low number of local adaptation alleles or high mutation load had decreased fitness in our highest drought stress environments.
October 22, 2025 at 8:50 PM
We found that populations with a low number of local adaptation alleles or high mutation load had decreased fitness in our highest drought stress environments.
By using data from other A. thaliana common gardens and genomic prediction tools, we created synthetic experimental populations of A. thaliana that varied in their abundance of locally adaptive alleles and also in their mutational load.
October 22, 2025 at 8:50 PM
By using data from other A. thaliana common gardens and genomic prediction tools, we created synthetic experimental populations of A. thaliana that varied in their abundance of locally adaptive alleles and also in their mutational load.
congratulations! can't wait to read it!
October 6, 2025 at 8:54 PM
congratulations! can't wait to read it!