RNA-Seq Reveals Adaptive Genetic Potential of the Rare Torrey Pine (Pinus torreyana) in the Face of Ips Bark Beetle Outbreaks

Steele, Stephanie; Ryder, Oliver A.; Maschinski, Joyce

doi:10.21203/rs.3.rs-391478/v1

Cited by 1 publication

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“…Given historical and contemporary estimates of effective population size as well as contemporary estimates of expected heterozygosity, our results indicate Torrey pine may not retain the genetic variation within populations needed to adapt to change. Current monitoring within the mainland population suggests a lack of recruitment (personal observation by Lionel Di Santo, July 2017), infestation by Ips beetles (Steele et al, 2021), and climate warming (Diffenbaugh et al, 2015) may increase extinction risk. Thus, for Torrey pine, increased Ne and greater genetic diversity may be required for long‐term persistence.…”

Section: Discussionmentioning

confidence: 99%

Reduced representation sequencing to understand the evolutionary history of Torrey pine (Pinus torreyana parry) with implications for rare species conservation

et al. 2022

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Understanding the contribution of neutral and adaptive evolutionary processes to population differentiation is often necessary for better informed management and conservation of rare species. In this study, we focused on Pinus torreyana Parry (Torrey pine), one of the world's rarest pines, endemic to one island and one mainland population in California. Small population size, low genetic diversity, and susceptibility to abiotic and biotic stresses suggest Torrey pine may benefit from interpopulation genetic rescue to preserve the species' evolutionary potential. We leveraged reduced representation sequencing to tease apart the respective contributions of stochastic and deterministic evolutionary processes to population differentiation. We applied these data to model spatial and temporal demographic changes in effective population sizes and genetic connectivity, to identify loci possibly under selection, and evaluate genetic rescue as a potential conservation strategy. Overall, we observed exceedingly low standing variation within both Torrey pine populations, reflecting consistently low effective population sizes across time, and limited genetic differentiation, suggesting maintenance of gene flow between populations following divergence. However, genome scans identified more than 2000 candidate SNPs potentially under divergent selection. Combined with previous observations indicating population phenotypic differentiation, this indicates natural selection has probably contributed to the evolution of population genetic differences. Thus, while reduced genetic diversity, small effective population size, and genetic connectivity between populations suggest genetic rescue could mitigate the adverse effects of rarity, evidence for adaptive differentiation suggests genetic mixing could disrupt adaptation. Further work evaluating the fitness consequences of inter‐population admixture is necessary to empirically evaluate the trade‐offs associated with genetic rescue in Torrey pine.

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Section: Discussionmentioning

confidence: 99%