Can Metabolite- and Transcript-Based Selection for Drought Tolerance in Solanum tuberosum Replace Selection on Yield in Arid Environments?

Manuela Haas; Heike Sprenger; Ellen Zuther; Rolf Peters; Sylvia Seddig; Dirk Walther; Joachim Kopka; Dirk K Hincha; Karin I Köhl

doi:10.3389/fpls.2020.01071

Can Metabolite- and Transcript-Based Selection for Drought Tolerance in Solanum tuberosum Replace Selection on Yield in Arid Environments?

Front Plant Sci. 2020 Jul 21:11:1071. doi: 10.3389/fpls.2020.01071. eCollection 2020.

Authors

Manuela Haas¹, Heike Sprenger¹, Ellen Zuther¹, Rolf Peters², Sylvia Seddig³, Dirk Walther¹, Joachim Kopka¹, Dirk K Hincha¹, Karin I Köhl¹

Affiliations

¹ Max Planck Institute of Molecular Plant Physiology, Potsdam-Golm, Germany.
² Versuchsstation Dethlingen, Landwirtschaftskammer Niedersachsen, Munster, Germany.
³ Federal Research Centre for Cultivated Plants, Institute for Resistance Research and Stress Tolerance, Julius-Kühn Institut, Sanitz, Germany.

Abstract

Climate models predict an increased likelihood of drought, demanding efficient selection for drought tolerance to maintain yield stability. Classic tolerance breeding relies on selection for yield in arid environments, which depends on yield trials and takes decades. Breeding could be accelerated by marker-assisted selection (MAS). As an alternative to genomic markers, transcript and metabolite markers have been suggested for important crops but also for orphan corps. For potato, we suggested a random-forest-based model that predicts tolerance from leaf metabolite and transcript levels with a precision of more than 90% independent of the agro-environment. To find out how the model based selection compares to yield-based selection in arid environments, we applied this approach to a population of 200 tetraploid Solanum tuberosum ssp. tuberosum lines segregating for drought tolerance. Twenty-four lines were selected into a phenotypic subpopulation (PP_t) for superior tolerance based on relative tuber starch yield data from three drought stress trials. Two subpopulations with superior (MP_t) and inferior (MP_s) tolerance were selected based on drought tolerance predictions based on leaf metabolite and transcript levels from two sites. The 60 selected lines were phenotyped for yield and drought tolerance in 10 multi-environment drought stress trials representing typical Central European drought scenarios. Neither selection affected development or yield potential. Lines with superior drought tolerance and high yields under stress were over-represented in both populations selected for superior tolerance, with a higher number in PP_t compared to MP_t. However, selection based on leaf metabolites may still be an alternative to yield-based selection in arid environments as it works on leaves sampled in breeder's fields independent of drought trials. As the selection against low tolerance was ineffective, the method is best used in combination with tools that select against sensitive genotypes. Thus, metabolic and transcript marker-based selection for drought tolerance is a viable alternative to the selection on yield in arid environments.

Keywords: drought tolerance; least absolute shrinkage and selection operator models; marker-assisted selection; metabolite profiling; multi-environment trials; phenotyping; potato; transcript profiling.