Effect of Initiation Timing of Drought Stress on Carbohydrate Content and Vegetative Growth in Japanese Apricot (Prunus mume Sieb. et Zucc.) ‘Nanko’

Tsuchida, Yasuhisa; Negoro, Keiichi; Hishiike, Masashi

doi:10.2503/jjshs1.80.19

Cited by 10 publications

(10 citation statements)

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“…6). Our previous study showed that physiological fruit drop in the beginning of May occurs as a result of severe competition between shoot and fruits for currently synthesized carbohydrates (Tsuchida et al, 2011a) and that drought stress around May strongly inhibits vegetative growth (Tsuchida et al, 2011b). These findings confirm that growth of new organs above ground in May of the following year depends on currently assimilated rather than reserve carbohydrates.…”

Section: Discussionsupporting

confidence: 61%

Organ-dependent seasonal dynamism of three forms of carbohydrates in Japanese apricot

Tsuchida¹,

Yakushiji

Jomura³

et al. 2015

Scientia Horticulturae

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Section: Discussionsupporting

confidence: 61%

Organ-dependent seasonal dynamism of three forms of carbohydrates in Japanese apricot

Tsuchida¹,

Yakushiji

Jomura³

et al. 2015

Scientia Horticulturae

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“…Previous reports clarified that water stress reduces the 13 C translocation rate in the shoots of pear trees (Teng et al, 1999) and the satsuma mandarin (Yakushiji and Morinaga, 1998), and that drought stress inhibits the accumulation of carbohydrates in the branches and roots of the Japanese apricot tree (Tsuchida et al, 2011). In the present experiment, the 13 C concentration in the twigs, fine roots, middle roots, and large roots of the drought-stressed trees at 34°C was low (Fig.…”

Section: Discussionmentioning

confidence: 58%

“…This result can be attributed to the short period (2 months) of stress application. Tsuchida et al (2011) demonstrated that the dry weight of Japanese apricot trees declined over approximately a 3-month period of drought stress; therefore, a period of drought stress longer than 2 months is likely to cause visible tree growth inhibition. However, in this investigation, root 6.…”

Section: Discussionmentioning

confidence: 99%

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Effect of High Temperature and Drought Stress on Carbohydrate Translocation in Japanese Apricot ‘Nanko’ Trees

Tsuchida¹,

Yakushiji

2017

Hortic J

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With the continuing trend of global warming, the adverse impact of high temperature and the inevitably accompanying drought stress on the growth of Japanese apricot trees (Prunus mume Siebold et Zucc.) are of concern. Therefore, the effects of these factors on photosynthesis and carbohydrate translocation were analyzed. An investigation was conducted at average daytime temperatures of 24°C, 30°C, and 34°C under both irrigated and drought conditions. The 34°C temperature was higher than the open air temperature by 5°C. Stable isotope 13 C was administered to trees to determine carbohydrate positioning. Under the drought stress condition, the photosynthetic rate declined accompanied by temperature elevation, and at the highest temperature of 34°C, 13C concentrations in the twigs and roots were lower than those in the irrigated trees at 24°C. Two-way analysis of variance revealed a trend of 13 C translocation to the young organs above ground, and old organs, while roots were affected by water status, temperature, and their combination, respectively. In the irrigated trees, the photosynthetic rate reduction was not detected, even at higher temperatures. However, translocation incompetence reflecting a decline in 13 C concentration in the roots was observed at 34°C. These results indicate that the permissible diurnal average temperature during summer for the growth of Japanese apricot trees is approximately up to 30°C, and in the temperature range around this irrigation is helpful to facilitate regular functioning of carbohydrate translocation under drought stress conditions.

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“…showed drought stress damaged not only shoot and fruit growth but also reduced reserve starch in the tree that will be used for the resumption of the next spring (Tsuchida et al, 2011). In Japanese pear, drought tolerance is also one of the most important characters for productivity of fruit.…”

Section: ) Research On Drought Tolerancementioning

confidence: 99%

Recent Advances in Research on Japanese Pear Rootstocks

Tamura

2012

J. Japan. Soc. Hort. Sci.

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In this paper, I review recent advances in research on Japanese pear rootstocks. Several clones of Pyrus betulaefolia and P. calleryana seedlings have been identified based on their ability to induce dwarfing scion growth, and their use in the future as dwarfing rootstock is anticipated. Among the various rootstock species, P. betulaefolia exhibits good adaptability to different environmental conditions, with high tolerance to drought, cold, and salt. This is due, in part, to P. betulaefolia's superior ability to regulate osmotic potential and ability to maintain a high degree of unsaturation in fatty acids in biological membranes during cold hardening. P. calleryana exhibits not only a relatively high drought tolerance but also the highest flood tolerance. This tolerance depends on the ability of P. calleryana to shift to alcohol fermentation under anaerobic conditions and to expel the ethanol thus generated. These two rootstock species are highly effective in preventing fruit-hardening disorders. While P. betulaefolia exhibits high salt tolerance among native Asian Pyrus species, it is exceeded in this respect by two native Mediterranean species, P. amygdaliformis and P. elaeagrifolia, with a mechanism to inhibit the transport of salts from the roots to above-ground plant parts. Furthermore, P. xerophila exhibits superior Fe 3+ -chelate reductase activity in roots, endowing the species with tolerance to alkaline soils.

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Effect of Initiation Timing of Drought Stress on Carbohydrate Content and Vegetative Growth in Japanese Apricot (Prunus mume Sieb. et Zucc.) ‘Nanko’

Cited by 10 publications

References 27 publications

Organ-dependent seasonal dynamism of three forms of carbohydrates in Japanese apricot

Organ-dependent seasonal dynamism of three forms of carbohydrates in Japanese apricot

Effect of High Temperature and Drought Stress on Carbohydrate Translocation in Japanese Apricot ‘Nanko’ Trees

Recent Advances in Research on Japanese Pear Rootstocks

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