Klein Marie C, Meng Zi, Bailey-Bale Jack, Milner Suzanne, Shi Peicai, Muchero Wellington, Chen Jin-Gui, Tschaplinski Timothy J, Jacobson Daniel, Lagergren John, Lane Matthew, O'Brien Chris, Chhetri Hari, Abeyratne Chanaka Roshan, Shu Mengjun, Freer-Smith Peter, Buckley Thomas N, Magney Troy S, Monroe J Grey, Tuskan Gerald A, Taylor Gail
Department of Plant Sciences, University of California Davis, Davis, CA, 95616, USA.
Biosciences Division and the Center for Bioenergy Innovation, Oak Ridge National Laboratory, Oak Ridge, TN, 37831, USA.
New Phytol. 2025 Sep;247(6):2647-2664. doi: 10.1111/nph.70343. Epub 2025 Jul 29.
We investigated adaptive genetic variation in Populus trichocarpa, a potential biofuel feedstock crop, to better understand how physiological traits may influence tolerance to water limitation. Our study focused on leaf and stomatal traits, given their roles in plant-water relations and adaptation. Using a diversity panel of over 1300 genotypes, we measured 14 leaf and stomatal traits under control (well-watered) and drought (water-limited) conditions. We conducted genome-wide association studies (GWAS), climate association analyses, and transcriptome (RNA-seq) profiling to identify genetic loci associated with phenotypic variation and adaptation. Stomatal traits, including size and density, were correlated with the climate of origin, with genotypes from more arid regions tending to have smaller but denser stomata. GWAS identified multiple loci associated with trait variation, including a major-effect region on chromosome 10 linked to stomatal size and abaxial contact angle. This locus overlapped with a tandem array of 3-ketoacyl-CoA synthase (KCS) genes and showed strong allele-climate and gene expression associations. Our findings reveal genetic and phenotypic variation consistent with local adaptation and suggest that future climates may favor alleles associated with smaller stomata, particularly under increasing aridity. This work provides insights into climate adaptation and breeding strategies for resilience in perennial crops.
我们研究了毛果杨(一种潜在的生物燃料原料作物)的适应性遗传变异,以更好地了解生理性状如何影响对水分限制的耐受性。鉴于叶片和气孔性状在植物与水分关系及适应性方面的作用,我们的研究聚焦于此。利用一个包含1300多个基因型的多样性群体,我们在对照(水分充足)和干旱(水分受限)条件下测量了14种叶片和气孔性状。我们进行了全基因组关联研究(GWAS)、气候关联分析和转录组(RNA测序)分析,以确定与表型变异和适应性相关的基因位点。气孔性状,包括大小和密度,与起源地的气候相关,来自更干旱地区的基因型往往具有更小但更密集的气孔。GWAS鉴定出多个与性状变异相关的位点,包括位于第10号染色体上与气孔大小和叶背接触角相关的一个主要效应区域。该位点与一个3-酮脂酰辅酶A合酶(KCS)基因的串联阵列重叠,并显示出强烈的等位基因-气候和基因表达关联。我们的研究结果揭示了与局部适应性一致的遗传和表型变异,并表明未来气候可能有利于与较小气孔相关的等位基因,特别是在干旱加剧的情况下。这项工作为多年生作物的气候适应性和抗逆性育种策略提供了见解。
