TY - JOUR

T1 - Plastic responses to past environments shape adaptation to novel selection pressures

AU - Coates, Sarah

AU - Comeault, Aaron

AU - Wood, Daniel P.

AU - Fay, Michael F.

AU - Creer, Simon

AU - Osborne, Owen

AU - Dunning, Luke T.

AU - Papadopulos, Alexander S. T.

PY - 2025/1/30

Y1 - 2025/1/30

N2 - Phenotypic plasticity may pave the way for rapid adaptation to newly encountered environments. Although it is often contested, there is growing evidence that initial plastic responses of ancestral populations to new environmental cues may promote subsequent adaptation. However, we do not know whether plasticity to cues present in the ancestral habitat (past-cue plasticity) can facilitate adaptation to novel cues. Conceivably, this could occur if plastic responses are coincidentally optimal to both past and novel cues (i.e., are preadaptive) or if they are transferred to novel cues during adaptation. Past plastic phenotype values could also become fixed during adaptation to the new environment. To uncover the role of past-cue plasticity in adaptation, we tested gene expression plasticity responses of two parallel mine-waste-adapted Silene uniflora populations and their closest coastal relatives. Plants were exposed to the past and novel cues of salt and zinc, which revealed that during adaptation to mine waste, plasticity to salt diminishes. Despite this, our results show that ancestral plasticity to salt has a substantial impact on subsequent adaptation to zinc. For a third of genes that have evolved zinc plasticity in mine populations, salt plasticity has been transferred to the zinc response. Furthermore, a quarter of fixed expression differences between mine and coastal populations were similar to ancestral salt responses. Alongside evidence that ancestral plasticity to novel cues can facilitate adaptation, our results provide a clear indication that ancestral past-cue plasticity can also play a key role in rapid, parallel adaptation to novel habitats.

AB - Phenotypic plasticity may pave the way for rapid adaptation to newly encountered environments. Although it is often contested, there is growing evidence that initial plastic responses of ancestral populations to new environmental cues may promote subsequent adaptation. However, we do not know whether plasticity to cues present in the ancestral habitat (past-cue plasticity) can facilitate adaptation to novel cues. Conceivably, this could occur if plastic responses are coincidentally optimal to both past and novel cues (i.e., are preadaptive) or if they are transferred to novel cues during adaptation. Past plastic phenotype values could also become fixed during adaptation to the new environment. To uncover the role of past-cue plasticity in adaptation, we tested gene expression plasticity responses of two parallel mine-waste-adapted Silene uniflora populations and their closest coastal relatives. Plants were exposed to the past and novel cues of salt and zinc, which revealed that during adaptation to mine waste, plasticity to salt diminishes. Despite this, our results show that ancestral plasticity to salt has a substantial impact on subsequent adaptation to zinc. For a third of genes that have evolved zinc plasticity in mine populations, salt plasticity has been transferred to the zinc response. Furthermore, a quarter of fixed expression differences between mine and coastal populations were similar to ancestral salt responses. Alongside evidence that ancestral plasticity to novel cues can facilitate adaptation, our results provide a clear indication that ancestral past-cue plasticity can also play a key role in rapid, parallel adaptation to novel habitats.

U2 - 10.1073/pnas.2409541122

DO - 10.1073/pnas.2409541122

M3 - Article

VL - 122

JO - PNAS

JF - PNAS

SN - 0027-8424

IS - 5

M1 - e2409541122

ER -