RT Conference Proceedings
T1 Population genomics and gene functional analyses reveal the genetic basis of climate adaptation in woodland strawberry
A1 Hytönen, Timo
A1 Toivainen, Tuomas
A1 Koskela, Elli
A1 Guangxun, Fan
A1 Andrés, Javier
A1 Samad, Samia
A1 Sargent, Daniel
A1 Edger, Patrick
A1 Kurokura, Takeshi
A1 Smolander, Olli-Pekka
A1 Paulin, Lars
A1 Posé-Padilla, David
K1 Fresas
AB Understanding the genetic basis of climate adaptation on the warming globe is an urgent question from ecological, agricultural and forestry perspectives. Woodland strawberry, the member of the most economically important family of perennial fruit and berry crops, the Rosaceae, is an ideal model to explore perennial climate adaptation: it has strong environmental responses, available molecular tools and wide geographical distribution in Europe. We have gathered a unique collection of over 200 woodland strawberry accessions covering the full geographical distribution of the species in Europe and sequenced their genomes. Population structure clearly separates European woodland strawberry to eastern and western groups that are growing in different climatic zones. Clear latitudinal and longitudinal clines are found in the photoperiodic and temperature regulation of flowering and vegetative development demonstrating the local adaptation of woodland strawberry populations. Fst analysis (fixation index) reveals the allelic differentiation of flowering time genes along east-west and north-south axes, and some of these genes have been targets of natural selection. Furthermore, gene ontology (GO) categories associated with the regulation of cell cycle are highly differentiated between populations from northern Norway and southern Finland, and phenotypic analyses reveal that faster developmental rate partially explains early flowering in the northern populations. To understand the genetic and molecular basis of adaptation in more detail, we are carrying out QTL mapping, gene expression analyses using RNAseq and Nanostring assays, and functional studies using CRISPR-Cas9 gene editing. Our research in crop’s wild relative will speed up existing and future breeding programs in the Rosaceae and open new avenues to understand climatic adaptation in perennials.
YR 2020
FD 2020-12-09
LK https://hdl.handle.net/10630/23575
UL https://hdl.handle.net/10630/23575
LA eng
DS RIUMA. Repositorio Institucional de la Universidad de Málaga
RD 21 ene 2026