How Potato Plants Take the Heat?
| Autor: | Jessica K. Van Harsselaar, Sophia Sonnewald, Uwe Sonnewald, Julia Lorenz, Kirsten Verena Ott |
|---|---|
| Rok vydání: | 2015 |
| Předmět: |
Starch
fungi food and beverages sink-strength Biology Shelf life high temperature assimilate allocation chemistry.chemical_compound Agronomy chemistry Genetic variation Shoot biology.protein General Earth and Planetary Sciences Dormancy Sucrose synthase Cultivar Sugar Potato General Environmental Science |
| Zdroj: | Procedia Environmental Sciences. 29:97 |
| ISSN: | 1878-0296 |
| DOI: | 10.1016/j.proenv.2015.07.178 |
| Popis: | Potato is the third most important food crop in the world after rice and wheat. Because of its widely distributed cultivation and high yields, it is considered a critical species in terms of food security in face of a growing world population. However, potato is particularly vulnerable to high temperature during various stages of its life cycle. Elevated temperatures strongly suppress tuberization, negatively affect storage and shelf life of tubers and reduce fitness of seed potatoes. Breeding new heat-stress tolerant cultivars is therefore an urgent need for sustainable increases in potato production. To achieve this goal an integrated approach combining physiology, biochemistry and molecular genetics is followed to analyze the impact of elevated temperatures on source-sink relations of potato plants, potato tuber development, starch accumulation and tuber quality and tuber dormancy. First results indicate that heat effects source-sink relations by altered expression of the tuber inducing signal FT, by stimulating shade-avoidance responses of the shoot and by decreasing sink-strength of developing tubers. Sink strength of growing potato tubers is mainly regulated by the activity of sucrose synthase. Measuring sucrose synthase expression and activity of heat grown potato tubers revealed a significant down-regulation of the enzyme which is consistent with reduced tuber growth. Interestingly, genetic variation in the activity of sucrose synthase exists, potentially enabling selection of potato varieties with heat-tolerant sucrose synthase isoforms. Although FT seems to play a major role in regulating tuberization, sink-derived and additional source signals are likely to be involved in orchestrating the heat-induced shift in assimilate allocation. This assumption is based on experiments in which soil and air temperatures of pot grown potato plants were independently controlled in growth chambers and transcript as well as sugar and enzyme profiles were recorded. Results of this analysis and their implication to improve heat tolerance of potato plants will be discussed. |
| Databáze: | OpenAIRE |
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