Grapevine bud fertility and number of berries per bunch are determined by water and nitrogen stress around flowering in the previous year

•Water and N stress affect the formation of grapevine inflorescences and the resulting grape load.•A critical period was identified between 400 and 700°Cd after grapevine budburst.•During the critical period water and N stress drove bud fertility and berry number.•Water and N stress in one season de...

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Bibliographic Details
Published in:European journal of agronomy 2014-03, Vol.54, p.9-20
Main Authors: Guilpart, Nicolas, Metay, Aurélie, Gary, Christian
Format: Article
Language:English
Subjects:
Agronomy. Soil science and plant productions
Berry number per bunch
Biological and medical sciences
Bud fertility
Fundamental and applied biological sciences. Psychology
Life Sciences
Nitrogen stress
Vitis vinifera L
Water stress
Yield formation
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Summary:•Water and N stress affect the formation of grapevine inflorescences and the resulting grape load.•A critical period was identified between 400 and 700°Cd after grapevine budburst.•During the critical period water and N stress drove bud fertility and berry number.•Water and N stress in one season determined 65–70% of grapevine yield in the next season.•Our results provide clues to improve control of grapevine yield over two years. Grapevine yield formation extends over two consecutive years (seasons 1 and 2). The inflorescence formation (around flowering in season 1) is crucial as it is involved in the formation of both the bunch number per vine and the berry number per bunch in season 2, that account for about 60% and 30% of year-to-year yield variation of grapevine, respectively. Light, temperature, water and nitrogen availability are known to affect this early stage. The aims of this work were to determine the critical periods during which inflorescence formation is sensitive to water and nitrogen stress and quantify their effects on it. To address these issues, we used a 3-year (2010–2012) field experiment (cv. Shiraz) in combination with a water balance simulation model (WaLIS) and a 6-year field experiment (cv. Aranel). In both experiments, different treatments were applied to create a gradient of water and nitrogen supply (treatments involved cover cropping, irrigation and fertilization). The grapevine yield and its components were recorded. Water and nitrogen status of grapevine were monitored throughout the season. Inflorescence formation was sensitive to water and nitrogen stress during a critical period that occurred between 400 and 700°Cd after budburst in season 1. Bud fertility (number of bunches per shoot) and berry number per bunch in season 2 were significantly correlated with the fraction of transpirable soil water (FTSW), predawn leaf water potential and leaf nitrogen content at that time for both cultivars. Water and nitrogen stress during the critical period of season 1 determined 65–70% of grapevine yield in season 2. Our results show that the maximum yield that can be reached in season 2 is determined during the critical period of season 1 and they provide clues to estimate it. These results may help grape growers to adapt their practices (i) in season 1 to ensure a sufficient maximum yield for season 2 and (ii) to actually obtain the targeted yield in season 2 depending on the maximum yield determined in season 1.
ISSN:1161-0301
1873-7331
DOI:10.1016/j.eja.2013.11.002