Drought-induced growth phenotypes are associated with genetic variation across a white pine hybrid zone.

Abstract

Understanding relationships among warming climate, increased drought severity, and the genetic architecture of hybrid drought resilience is necessary for forest conservation and management. We calculated three drought-related tree-ring-growth indices (dendrophenotypes) using tree-ring data from hybrid P. strobiformis – P. flexilis study trees at nine sites across Colorado, New Mexico, Arizona, and Texas. Along with hybrid index (percentage of P. strobiformis ancestry inherited by a single tree), and climate variables, we used dendrophenotypes to (Q1) examine relationships among climate and hybrid index, (Q2) examine relationships between dendrophenotypes and hybrid index, and (Q3) conduct a genotype-phenotype analysis. We observed significant correlation between hybrid index and dendrophenotypes resulting from high-temperature drought in addition to significant correlation between those dendrophenotypes and our dataset of single-nucleotide polymorphisms (SNPs). We conclude that P. strobiformis – P. flexilis trees exhibiting higher hybrid indices are more resilient to high-temperature drought events and encourage future research that identifies genetic linkage between relevant loci and their conferred physiological benefits.