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研究生:張致盛
研究生(外文):CHIH-SHENG CHANG
論文名稱:巨峰葡萄植株生長與樹體活力之關係
論文名稱(外文):Relationship between Plant Growth and Tree Vigor in Kyoho Grapevines
指導教授:楊耀祥楊耀祥引用關係李金龍李金龍引用關係
指導教授(外文):Yau-Shiang YangChing-Lung Lee
學位類別:博士
校院名稱:國立中興大學
系所名稱:園藝學系
學門:農業科學學門
學類:園藝學類
論文種類:學術論文
論文出版年:2001
畢業學年度:89
語文別:中文
論文頁數:127
中文關鍵詞:根系低溫催芽水分栽培
外文關鍵詞:root systemchillingbud forcingwaterculture
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中文摘要
葡萄在台灣一年多收栽培模之下,第二收植株生長勢較弱、花穗長度較短、生產的葡萄果粒較小等問題存在已久,本研究之目的為在一年二收栽培模式之下,探討葡萄植株生長與樹體活力之變化,並調查栽培管理對根系生長之影響,期能在台灣地區特殊栽培模式下建立葡萄植株生長與樹體活力之關係。除可作為改進植株生理狀態及栽培管理技術之基礎資料外,並可供日後進行其他落葉果樹在高溫環境下栽培之參考,茲將試驗結果敘述如下:
利用挖掘與根箱法觀察一年二收栽培模式之下不同生育時期'巨峰’葡萄根系之生長,結果顯示在春天枝條萌芽之前,地下部新根已開始生長。由不同生育時期新根的生長量及在根箱壁之面積計算,第一收栽培時硬核期之後,當枝條生長減緩後,新根才開始大量生長,於第二收修剪後萌芽期之初新根的生長停頓,直到硬核期才開始另一次生長高峰,但第二收新根之生長量較第一收為低。又試驗結果顯示新根與地上部新梢的生長呈交互之關係,而在第一收與第二收果實採收後根系並沒有另一次生長高峰,此與溫帶地區一年一收栽培,果實採收後根系有另一次生長高峰的模式不同。
由一年二收栽培模式下不同生育時期植株生長特性之調查,顯示枝梢生長以第一收長度較長、葉數較多,枝之直徑亦在第一收時增加較多。葡萄葉片光合成速率在開花期至硬核期之調查較高,著色期之後降低,而總葉綠素含量則至成熟期才降低。第一收及第二收根與枝條活性在萌芽期後開始上升,於著果期達到高峰,成熟期之後下降,相同生育時期以第一收之活性較高。分析植體碳水化合物含量,第一收修剪生長初期之全可溶性糖、澱粉含量較第二收高,植體中以根含量較地上部高,而在第二收生育末期植株澱粉含量逐漸增加,其中以根之含量較高。游離胺基酸及可溶性蛋白質含量亦以根部之含量較高,生育初期游離胺基酸含量以第一收含量較高,可溶性蛋白質含量則兩收差異不大。
夏季以5℃進行不同時數冷藏處理,結果顯示以5℃低溫300小時處理可促進第二收葡萄萌芽及新梢生長,延長低溫處理時間並無法提早萌芽,但亦可促進萌芽後新梢之生長。夏季低溫處理可提高植株TTC活力,而萌芽前調查植株TTC活力亦以低溫處理或氰胺處理較高。夏季(7∼8月)低溫處理可提高第二收葡萄修剪後及萌芽前全可溶性糖含量,唯澱粉含量降低,可溶性蛋白質含量降低,游離胺基酸則在低溫處理初期下降,但處理延長至900小時後上升。
控制土壤含水量於30%調查一年二收栽培模式根部之吸水量,由連續二年之調查結果顯示根部吸水量隨新梢生長量之增加而上升,第一收根部吸水量高峰在6月下旬∼7月上旬果實成熟前,在第二收修剪後吸水量下降,但隨第二收新梢生長而上升,在10月上旬達第二收之高峰,隨後逐漸下降。比較二收根部吸水量之差異,第一收之吸水量較高,而第二收吸水量較低,第一收吸水量高峰期可持續較長的時間,而第二收吸水量高峰則因氣溫降低而很快下降。
調查一年一收栽培模式根系生長模式結果,具有硬核期至著色期之間及採收後二次生長高峰,與一年二收栽培模式不同。結果量影響成熟期根系之生長,新根面積與結果量呈負相關,但與新梢總長度呈正相關。控制土壤含水量為30%、26%及22%時,在2∼3月植株新梢生長停止之時三種處理根部吸水量並無差異,但當萌芽後新梢長度與葉面積逐漸增加,植株吸水量亦逐漸提高,土壤含水量較高之植株吸水量較多,而土壤含水量較高之植株生長量增加,相同土壤含水量之下,第一收總水量較第二收高50∼83%。催芽處理後初期對吸水量影響不大,但催芽後第18∼19日之後,催芽處理之植株隨著新梢生長吸水量增加。
綜合本研究之結果,地上部與地下部相互影響,在一年二收栽培模式下巨葡萄根與新梢呈現交互生長之情形。由於生長初期植體碳水化合物含量以第一收較高,而低溫有助於不溶性碳水化合物之轉變,更利於植株新梢初期之生長,因此第一收地上部與地下部之生長量都較第二收高,TTC活力測定及根部吸水量亦以第一收較高。低溫使萌芽提早並促進萌芽後新梢之生長,其原因應是低溫可促進澱粉分解為可溶性糖,而有助於萌芽後新梢之生長活力。
Summary
The grape production in Taiwan has multiple harvest in a year. But in the second harvest, tree vigor was decreased, inflorescence was shorter and the berry size was smaller. In order to understand the relationships between plant growth and tree vigor of this unique cultural model in Taiwan, the variation of physiology of root growth and tree growth vigor in two harvest crops were investigated, and the influence of vineyard management on the root growth was discussed in this study. It will provide the information for the improvement on the plant physiological condition and vineyard management technique, and serves as reference for the plant physiological research of other deciduous fruit tree that grew in high temperature area.
The growth of root system in different growth stages of two harvests ‘Kyoho’ grapevines(Vitis vinifera L. ×Vitis labruscana Bailey cv. Kyoho) was observed by means of excavated method and glass-walled rhizotron method. The results showed that the young roots were began to grow before budbreaking in the spring. The growth amount of young roots was measured the area of the young roots on the glass face was also calculated at different growth stages. It revealed that a mass growth of root system in first harvest was occurred often the slowdown of the shoot growth at the varison stage, and the flush growth of young roots was observed at the berry coloration stage. The young roots ceased to grow at the budbreaking stage that followed the pruning for the second harvest, another flush growth was started at the varison stage, whereas the growth amount was lower than that of in the first harvest. According to the investigation of this experiment, a correlative relationship is existed between the growth of the young roots and the shoots, and neither the first nor the second harvest had flush growth in the post-harvest periods. This result was different from the one-harvest per year in the temperate-zone area.
The growth physiology in different growth stages of two harvest grapevines was investigated. The results showed that the first harvest had longer shoot length and more leaves, and thicker shoot diameter than that of second harvest. The leaf photosynthetic rate was higher during flowering stage to varison stage and declined after coloration, whereas the chlorophyll content was decreased till maturation stage. Both in the first and the second harvest, the physiological activities of root and shoot were increased following budbreaking, and reached the peak at fruit-setting stage, declined after maturation, the physiological activities in the first harvest were higher as comparing in the same growing stage. In the analysis of plant carbohydrates, the contents of total soluble sugar and starch in the early growing stage after pruning were higher for the first harvest than the second harvest, and the contents were higher in the roots than in the above part. The plant starch content was gradually increased in the late growing stages in the second harvest, in which the root had the higher content. The contents of free amino acids and soluble protein were also higher in the root, the contents of free amino acids in the early growing stages in the first harvest were higher, whereas there was no difference in the contents of soluble protein between two harvests.
The plants were treated with different duration of chilling in 5℃ in the summer. The results showed that treatment of 5℃ chilling for 300 hours could promoted the budbreaking and shoot growth in the second harvest, prolong the chilling duration could not accelerate the budbreaking but enhanced the shoot growth after budbreaking. Chilling treatment in the summer could increase the plant physiological activities, and the activities in the pre-budbreaking stage were higher in treatment with chilling or hydrogen cyanamide. Chilling treatment in the summer, from July to August, could increase the content of total soluble sugars after pruning to budbreaking in the second harvest, and decreased the starch content. The content of soluble protein was decreased, and the content of free amino acids decreased at the early stage of chilling, but increased as the chilling was prolong to 900 hours.
The investigation of water absorption in two-harvest model was carried out under the control of 30% soil water content. The results of two years showed that the amount of root absorption was increased with the shoot growth. The peak root absorption of the first harvest occurred in late June to early July, right before ripening, and decreased after pruning of the second harvest. The absorption decreased as the shoot growth of the second harvest, the second peak absorption was reached at early October, and decreased thereafter. Comparing the difference of the amount of water absorption between the two harvests, the first harvest was higher than the second harvest. The peak absorption of the first harvest lasted longer whereas the peak absorption of the second harvest decreased sharply owing to the decrease of temperature.
The result of the investigation on the model of root growth in one harvest showed that two flush growths were appeared in varison stage and post-harvest, which was different from two-harvest. The root growth during maturation stage was affected by the yield of the fruit, the area of young roots have negative correlation with the yield. The root water absorption amount during plant growth ceasing period from February to March had no difference among three soil water content, 30%, 26% and 22%. Following by the increase in shoot growth and leaf area after budbreaking, the plant water absorption was increased gradually, the plants in higher soil water content had high absorption amount and thus increasing vine growth. In the same soil water content, the total water absorption was 50-83% higher in the first harvest than that of the second harvest. The influence of bud-forcing on water absorption was low at the early period, but the absorption in the bud-forced plant was higher at 18-19days after bud-forcing.
Based on the results of this study, the growth of above part and the root were mutually co-related, an alternation of growth appeared between the root and the shoot in two harvest ‘Kyoho’ grapevines. As the plant carbohydrate contents at early growth stage was higher in the first harvest, thus the winter chilling could help the conversion of the insoluble carbohydrate and the early shoot growth. Therefore, the growth of the above part and the root were both higher in the first harvest than that of the second harvest, and higher TTC viability and root water absorption were also occurred in the first harvest. The chilling condition could enhanced budbreaking and the shoot growth. The probable reason is that the chilling accelerate the decomposition of starch into soluble sugars thus enhance the plant vigor after budbreaking.
封面
目錄
中文摘要
第一章緒言
第二章前人研究
第三章葡萄根系之生長
前言
材料及方法
結果
討論
摘要
第四章一年二收栽培模式樹體活力之變化
前言
材料及方法
結果
討論
摘要
第五章栽培管理對植株生長之影響
前言
材料及方法
結果
討論
摘要
第六章綜合討論
參考文獻
英文摘要
附錄
參考文獻
王乃霖、楊耀祥。1984。夏季及冬季巨峰葡萄種子數。興大園藝9:17-22。
林嘉興。1986。葡萄栽培及產期調節技術。台灣省政府農林編印。農民淺說362A-園藝78.
林嘉興。1988。植物生長調節劑在葡萄栽培上之應用。植物生長調節劑在園藝作物之應用研討會專集 p:203-214(台中區農業改良場特刊12號)。
林嘉興、張林仁。1988。葡萄新梢生長量對著果與果實品質之影響。葡萄產業研究與發展研討會專集 p:34-41(農試所特刊24號)。
林嘉興、張林仁、蔡宜峰。1990。葡萄之土壤及其肥培管理。果樹營養與果園土壤管理研討會專集 p:215-231(台中區農業改良場特刊20號)。
洪素芬。1995。巨峰葡萄催芽後生理反應之探討。國立中興大學園藝研究所碩士論文。
康有德。1974。葡萄栽培新技術一年收穫三次。豐年 24(7):22-23。
康有德。1976。臺灣巨峰葡萄果芽的形成。中國園藝 22(2):49-57。
高景輝。1993。植物生長與分化。茂昌圖書有限公司。台北市。
張明聰、陳清義。1991。土壤水分條件影響芒果生理特性之研究。中國園藝 37(2):100-113。
張明聰、楊耀祥。1985。葡萄芽體休眠與碳水化合物之關係。興大園藝 10:11-18。
張致盛、張林仁。1998。兩種速測法在果樹葉片葉綠素含量測定之應用。台中區農業改良場研究彙報 59:37-45。
張致盛、楊耀祥。1993。GA3及Fulmet對巨峰葡萄花穗發育之影響。興大園藝 18:45-59。
張致盛、楊耀祥。1994。GA3及Fulmet對黑后葡萄花穗發育之影響。台中區農業改良場研究彙報 44:35-44。
陳秉訓。1997。改良三苯基氯化四唑還原法平評估蓮霧葉片活力。興大園藝 22(2):39-45。
陳秉訓、楊耀祥。1989。GA3及KT-30對冬季巨峰葡萄果實生長之影響。興大園藝 14:15-30。
黃子彬、李金龍、楊耀祥。1984。巨峰葡萄一年收對果實品質之影響。中國園藝 30(2):111-119。
黃子彬、楊耀祥。1983。疏果對巨峰葡萄果實品質之影響。興大園藝 9:41-48。
楊耀祥。1984a。葡萄催芽劑氰氨基化鈣製法之研究。興大園藝9:7-16。
楊耀祥。1984b。葡萄催芽劑氰氨基化鈣使用方法之研究。農林學報 33:97-116。
楊耀祥、堀裕。1981。除根對葡萄新梢初期生長之影響。興大園藝 6:41-49。
楊耀祥、林嘉興、廖萬正。1982。氰氨基化鈣及Merit液肥對打破'巨峰’葡萄休眠之影響。興大園藝 7:21-29。
歐鍚坤。1994。'巨峰’葡萄不同生產模式之生理研究。中華農業研究 43(2):173-181。
中川昌一。1972。ブドウの促成栽培と周年栽培への提言。農業および園藝 47(6):59-63。
小野俊朗。1996。二期作。In:日本ブドウ學p:414-423. 堀內昭作、松井弘之編集。養賢堂。東京市。
山下尚若、陳正寬、木曾則子、島村和夫。1974。ブドウ二期作關する研究(第2報)BAならびにBA+尿素處理が花穗の發育および收量に及ばす影響。日本園藝學會昭和49年春季發表要旨:122-123。
久保田尚浩、江川俊之、島村和夫。1987。加溫時期の異なるブドウ'マスカット.オブ.アレキサンドリア’の根生長及ぼすその活性に及ぼす地溫の影響。園學雜 56(3):280-286。
久保田尚浩、片山友孝、前田明。1993。ブドウ'ピオ-ネ’における二期作の事例。農業および園藝 68(5):74-78。
日野昭、天野勝司、澤村泰則、佐佐木專治、倉岡唯行。1974。果樹の光合成作用に關する研究(第2報)光合成速度の季節的變化。園學雜 43(3):209-214。
岡本五郎。2000。根之形態及生長周期。In:ブドウ 果樹園藝大百科3. 農文協出版。東京市。
高木敏彥。1998。果樹。In:根の事典。p:197-199. 根の事典編輯委員會編。朝倉書店。東京市。
高木伸友、井上襄吉。1982。ブドウ'マスカット.オブ.アレキサンドリア’の果粒の生長と葉における光合成速度の季節的變化。園學雜51(3):286-292。
堀內昭作、中川昌一、加藤彰宏。1981。ブドウの休眠の一般的特徵。園學雜 50(2):176-184。
前田明、片山友孝、久保田尚浩。1992a。ブドウ'ピオ-ネ’の二期作に關する研究(第1報)施設ならびに栽培の概要。園學雜 61(2):178-179。
前田明、片山友孝、久保田尚浩。1992b。ブドウ'ピオ-ネ’の二期作に關する研究(第2報)作期による新梢生長の違い。園學雜 61(2):180-181。
間島正典。1990。ルビ─オクヤマの發見と-ブラジルでの栽培。山梨の果樹 38(8):38-41。
Allan, P., G. Rufus, G. C. Linsley-Noakes, and G. W. Matthee. 1995. Winter chill models in a mild subtropical area and effects of constant 6℃ chilling on peach budbreak. Acta Hort. 409:9-17.
Alleweldt, G., R. Eibach, and E. Ruel. 1982. Investigations on gas exchange in grapevine. I. Influence of temperature, leaf age and daytime on net photosynthesis and transpiration. Vitis 21:93-100.
Anderson, L. E. and S. D. Seeley. 1992. Modeling strategy in pomology: Development of the Utah models. Acta Hort. 313:297-306.
Antciff, A. J. and P. May. 1961. Dormancy and bud burst in Sultana vines. Vitis 3:1-14.
Araujo, F. J. and L. E. Williams. 1988. Dry matter and nitrogen partitioning and root growth of young field-grown Thompson Seedless grapevines. Vitis 27:21-32.
Archer, E. and H. C. Strauss. 1985. Effect of plant on root distribution of three-year-old grafted 99 Richter grapevines. S. Afr. J. Enol. Vitic. 6(2):25-30.
Arnold, M. A. and E. Young. 1990. Growth and protein content of apple in response to root and shoot temperature following chilling. HortScience 25(12):1583-1588.
Atkinson, D. 1972. Seasonal periodicity of black currant root growth and the influence of simulated mechanical harvesting. J. Hort. Sci. 47:165-172.
Atkinson, D. 1973. Seasonal changes in the length of white unsuberized root on raspberry plants grown under irrigated conditions. J. Hort. Sci. 48:413-419.
Atkinson, D. 1980. The distribution and effectiveness of the roots of tree crops. Hort. Rev. 2:424-490.
Bachelard, E. P. and F. Wightman. 1973. Biochemical and physiological studies on dormancy release in tree buds. I. Changes in degree of dormancy, respiratory capacity, and major cell constituents in overwintering vegetative buds of Populus balsamifera. Can. J. Bot. 51:2315-2326.
Balander, P., R. Rageau, M. Gendraud, M. Bonhomme, and E. Parisot. 1995. Dormancy in peach tree under the tropical climate of reunion island: biological and biochemical approaches. Acta Hort. 409:39-45.
Balasubrahmanyam, V. R., J. Eifert, and L. Diofasi. 1978. Nutrient reserves in grapevine canes as influenced by cropping levels. Vitis 17:23-29.
Bammi, R. K. and G. S. Randhawa. 1968. Viticulture in the tropical regions of India. Vitis 7:124-129.
Bevington, K. B and W. S. Castle. 1985. Annual root growth pattern of young citrus trees in relation to shoot growth, soil temperature, and soil water content. J. Amer. Soc. Hort. Sci. 110(6):840-845.
Bhar, D. S., G. F. Mason, and R. J. Hilton. 1970. In situ observations on plum root growth. J. Amer. Soc. Hort. Sci. 95(2):237-239.
Birkhold, K. T. and R. L. Darnell. 1993. Contribution of storage and currently assimilated nitrogen to vegetative and reproductive growth of rabbiteye blueberry. J. Amer. Soc. Hort. Sci.118(1):101-108.
Bohn, W. 1979. Methods of studying root systems. Springer-Verlag Heidelberg, New York.
Box, Jr. J. E. 1996. Modern methods for root investigations. In: Plant Roots, The hidden half. Y. Waisel et al., (eds.)p.193-238. Marcel Dekker, Inc., New York.
Bravdo, B. A., I. Levin, and R. Assaf. 1992. control of root size and root environment of fruit trees for optimal fruit production. J. Plant Nutrition 15(6-7):699-712.
Bravdo, B., S. Lavee and R. M. Samish. 1972. Analysis of water consumption of various grapevine cultivars. Vitis 10:279-291.
Brown, C. S., E. Young, and D. M. Pharr. 1985. Rootstock and scion effects on the seasonal distribution of dry weight and carbohydrates in young apple trees. J. Amer. Soc. Hort. Sci. 110(5):696-701.
Buttrose, M. S. 1966. The effect of reducing leaf area on the growth of roots, stems and berries of Gordo grapevines. Vitis 5:455-464.
Buttrose, M. S. and C. R. Hale. 1971. Effects of temperature on accumulation of starch or lipid in chloroplasts of grapevine. Planta 101:166-170.
Caldwell, C. R. 1993. Estimation and analysis of cucumber (Cucumis sativus L.) leaf cellular heat sensitivity. Plant Physiol. 103:939-945.
Candolfi-vasconcelos, M. C. and W. Koblet. 1990. Yield, fruit quality, bud fertility and starch reserves of the wood as a function of leaf removal in Vitis vinifera. Evidence of compensation and stress recovering. Vitis 29:199-221.
Candolfi-Vasconcelos, M. C.,W. Koblet, G. S. Howell and W. Zweifel. 1994a. Influence of defoliation, rootstock, training system, and leaf position on gas exchange of 'Pinot Noir ’grapevines. Am. J. Enol. Vitic. 45(2):173-180.
Candolfi-Vasconcelos, M. C., M. P. Candolfi, and W. Koblet. 1994b. Retranslocation of carbon reserves from the woody storage tissues into the fruit as a response to defoliation stress during the ripening period in Vitis vinifera L. Planta 192:567-573.
Cappiello, P. E. and G. J. Kling. 1994. Changes in growth regulator and carbohydrate levels in roots and shoot tips of Cornus sericea during cold storage and emergence from dormancy. J. Amer. Soc. Hort. Sci. 119(4):785-788.
Cockroft,B. and K.A. Olsson 1972. Pattern of new root production in peach trees under irrigation. Austral. J. Agr. Res. 23:1021-1025.
Couvillon, G. A. 1995. Temperature and stress effects on rest in fruit trees: A review. Acta Hort. 395:11-19.
Davis, T. J. and D. Sparks. 1974. Assimilation and translocation patterns of 14C in the shoot of fruiting pecan trees, Carya illinoiensis. J. Amer. Soc. Hort. Sci.99:468-480.
Dennis, F. G. Jr. 1987. Producing temperate-zone fruit at low latitudes: An overview. HortScience 22(6):1226-1231.
Dunn, G. 1974. A model for starch breakdown in higher plants. Phytochemistry 13:1341-1346.
During, H. 1979. Effects of air and soil humidity on vegetative growth and water relationships of grapevines. Vitis 18:211-220.
During, H. and P. R. Dry. 1995. Osmoregulation in water stressed roots: Responses of leaf conductance and photosynthesis. Vitis 34(1):15-17.
Edwards, G. R. 1987. Producing temperate-zone fruit at low latitudes: Avoiding rest and the chilling requirement. HortScience 22(6):1236-1246.
Erez, A. 1987. Chemical control of bud break. HortScience 22:1240-1243.
Faust, M., D. Liu, M. M. Millard, and G. W. Stutte. 1991. Bound versus free water in dormant apple buds-A theory for endodormancy. HortScience 26(7)887-890.
Flore, J. A. and A. N. Lakso. 1989. Environmental and physiological regulation of photosynthesis in fruit crops. Hort. Rev. 11:111-158.
Freeman, B. M. and R. E. Smart. 1976. A root observation laboratory for studies with grapevines. Am. J. Enol. Vitic. 27(1):36-39.
Fuchigami, L. H. and C. C. Nee. 1987. Degree of growth stage model and rest-breaking mechanisms in temperate woody perennials. HotrScience 22(5):836-845.
Fujii, J. A. and R. A. Kennedy. 1985. Seasonal changes in the photosynthetic rate in apple trees. Plant Physiol. 78:519-524.
Gardea, A. A., Y. M. Moreno, A. N. Azarenko, P. B. Lombard, L. S. Daley, and R. S. Criddle. 1994. Changes in metabolic properties of grape buds during development. J. Amer. Soc. Hort. Sci. 119(4):756-760.
Glenn, D. M. and W. V. Welker. 1993. Root development patterns in field grown peach trees. J. Amer. Soc. Hort. Sci. 118(3):362-365.
Hale, C. R. and R. J. Weaver. 1962. The effect of developmental stage on direction of translocation of photosynthate in Vitis vinifera. Hilgardia 33(3):89-131.
Hamman, R. A. Jr. and I. E. Dami. 2000. Effects of irrigation on wine grape growth and fruit quality. HortTechnology 10(1):162-168.
Hansen, P. 1971. 14C-studies on apple trees: Ⅶ. The early seasonal growth in leaves, flower, and shoots as dependant upon current photosynthesis and existing reserves. Physiol. Plant. 25:469-473.
Hardie, W. J. and J. A. Considine. 1976. Response of grapes to water-deficit stress in particular stages of development. Am. J. Enol. Vitic. 27: 55-61.
Hansen, P. and J. Grauslund. 1978. Leaves of sorbitol in bleeding sap and in xylem sap in relation to leaf mass and assimilate demand in apple trees. Physiol. Plant. 42:129-133.
Hassan, M. M., A. A. Abdel-Kawj, and A. Rifay. 1984. Effects of nitrogen fertilization on growth, yield and root distribution of grapevines. Egypt J. Hort. 11(2):209-213.
Head, G. C. 1967. Effects of seasonal changes in shoot growth on the amount of unsuberized root on apple and plum trees. J. Hort. Sci. 42:169-180.
Head, G. C. 1968. Seasonal changes in the amounts of white unsuberized root on pear trees on quince rootstock. J. Hort. Sci. 43:49-58.
Head, G. C. 1969a. The effects of fruiting and defoliation on seasonal trends in new root production on apple trees. J. Hort. Sci. 44:175-181.
Head, G. C. 1969b. The effects of mineral fertilizer on seasonal changes in the amount of white root on apple trees in grass. J. Hort. Sci. 44:183-187.
Hiroyasu, T. 1961. Nutritional and physiological studies on the grapevine. J. Japan. Soc. Hort. Sci. 30:111-116.
Hunter, J. J. and D. J. LE Roux. 1992. The effect of partial defoliation on development and distribution of roots of Vitis vinifera L. cv. 'Caberent Sauvignon’ grafted onto rootstock 99 Richter. Amer. J. Enol. Vitic. 43(1):71-79.
Jesko, T. 1992. The root as an integral part of the plant. In: Physiology of the Plant Root System. J. Kolek and V. Kozinka, (eds.), p.1-30. Kluwer Academic Publishers, Netherlands.
Kang, S. M., K. C. Ko, and J. S. Titus. 1982. Mobilization and metabolism of protein and soluble nitrogen during spring growth of apple trees. J. Amer. Soc. Hort. Sci. 107(2):209-213.
Khandu, S. D. 1968. Fruiting potential of grapevine. Indian Horticulture Apr.-Jun.:5-7.
Kirchhof, G., J. Blackwell, and R. E. Smart. 1991. Growth of vineyard roots into segmentally ameliorated acidic subsoils. In: Plant-Soil Interactions at low pH. R. J. Wright et al., (Eds) p:447-452.
Kliewer, W. M. 1967. Annual cyclic changes in the concentration of free amino acids in grapevines. Amer. J. Enol. Vitic. 18(3):126-137.
Kliewer, W. M. and J. A. Cook. 1971. Arginine and total free amino acid as indictors of the nitrogen status of grapevines. J. Amer. Soc. Hort. Sci. 96:581-587.
Kliewer, W. M. and R. D. Fuller. 1973. Effect of time and severity of defoliation on growth of roots, trunk, and shoot of 'Thompson Seedless’ grapevines. Am. J. Enol. Vitiv. 24:59-64.
Kriedemann, P. E. 1968. Photosynthesis in vine leaves as a function of light intensity, temperature, and leaf age. Vitis 7:213-220.
Lang, G. A. 1987. Dormancy: A new universal terminology. HortScience 22(5):817-820.
Lavee, S. 2000. Grapevine(Vitis vinifera) growth and performance in warm climates. In: Temperature Fruit Crops in Warm Climates. A. Erez, (eds.), p.343-366. Kluwer Academic Publishers, Netherlands.
Lin, C. H. 1987. Chemical induction of multiple cropping of grape in Taiwan. Acta Hort. 199:91-99.
Liu, D., M. Faust, M. M. Millard, M. J. Line, and G. W. Stutte. 1985. States of water in summer-dormant apple buds determined by proton magnetic resonance imaging. J. Amer. Soc. Hort. Sci. 118(6):769-774.
Lockwook, D. W. and D. Sparks. 1978. Translocation of 14C from tops and root of pecan in the spring following assimilation of 14CO2 during previous growing season. J. Amer. Soc. Hort. Sci. 103(1):45-49.
Loescher, W. H., T. McCamant, and J. D. Keller. 1990. Carbohydrate reserves, translocation, and storage in woody plant roots. HortScience 25(3):274-281.
McArtney, S. J. and D. C. Ferree. 1999. Root and cane pruning affect vegetative development, fruiting, and dry-matter accumulation of grapevines. HortScience 34(4):617-621.
Miller, D. E. 1986. Root systems in relation to stress tolerance. HortScience 21(4):963-970.
Morano, L. and W. M. Kliewer. 1994. Root distribution of three grapevine rootstocks grafted to 'Cabernet Sauvignon’ grown on a very gravelly clay loam soil in Oakville, California. Amer. J. Enol. Vitic. 45(3):345-349.
Mowat, A. D., A. P. George, and R. J. Collins. 1995. Cultivation of persimmon (Diospyros kaki L.) under tropical conditions. Acta Hort. 409:141-149.
Mullins, M. G., A. Bouquct, and L. E. Williams. 1992. Biology of the gapevines. Cambridge University Press, Cambridge.
Nassar, A. R. and W. M. Kliewer. 1966. Free amino acids in various parts of Vitis vinifera at different stages of development. J. Amer. Soc. Hort. Sci. 89:281-294.
Nee C. C. and L. H. Fuchigami 1992. Overcoming rest at different growth stages with hydrogen cyanamide. Sci. Hort. 50:07-113.
Niimi, Y. and H. Torikata. 1978. Changes in endogenous plant hormones in the xylem sap of grapevines during development. J. Japan. Soc. Hort. Sci. 47(2):181-187.
Olien, W. C., C. P. Hegwood Jr., and J. M. Spiers. 1993. Planting methods affect early growth and root distribution of Muscadine vines. HortScience 28 (11):1089-1091.
Pandey, R. M. and H. L. Farmahan. 1977. Changes in the rate of photosynthesis and respiration in leaves and berries of Vitis vinifera grapevines at various stages of berry development. Vitis 16:106-111.
Pareek, O. P., A. Chandra, and A. K. Godara. 1993. Root systems in fruit crops. In: Advance in Horticulture Vol. 2-Fruit Crops: Part 2. K. L. Chadha and O. P. Pareek. (eds.) p:1031-1053. Malhostra Publishing House, New Delhi.
Pellett, N. E. and D. A. Heleba. 1998. Comparing callus growth discoloration and electrical conductivity as measures of stem injury after freezing woody plants. J. Amer. Soc. Hort. Sci. 123(5):826-831.
Poni, S., C. Intrieri and O. Silvestroni. 1994. Interactions of leaf age, fruiting, and exogenous cytokinins in Sangiovese grapevines under non-irrigated conditions. I. Gas exchange. Amer. J. Enol. Vitic. 45(1):71-78.
Pratt, C. 1979. Shoor and bud development during the prebloom period of Vitis. Vitis 18:1-5.
Probsting, E. L. Jr. and J. E. Middleton. 1980. The behavior of peach and pear trees under extreme drought stress. J. Amer. Soc. Hort. Sci. 105(3):380-385.
Rakngan, J., H. Gemma, and S. Iwahori. 1996. Phenology and carbohydrate metabolism of Japanese pear trees grown under continuously high temperatures. J. Japan. Soc. Hort. Sci. 65(1):55-65.
Ran, Y., B. Bar-Yosef, and A. Erez. 1992. Root volume influence on dry matter production and partioning as related to nitrogen and water uptake rates by peach trees. J. plant Nutrition 15(6-7):713-726.
Richards, D. 1976 Root-Shoot interactions: a functional equilibrium for water uptake in peach [Prunus persica (L.) Batsch.]. Ann. Bot. 41:279-281.
Richards, D. 1983. The grape root system. Hort. Rev. 5:127-168.
Richards, D. 1986. Tree growth and productivity-the role of roots. Acta Hort. 175:26-36.
Richards, D. and J. A. Considine. 1981. Suberization and browning of grapevine roots. In:Structure and function of plant roots. R. Brouwer, et al., (eds.), p.111-115.
Richards, D. and R. N. Rowe. 1977. Root-shoot interactions in peach: The function of the root. Ann. Bot. 41:1211-1216.
Roper, T. R. and R. A. Kennedy. 1986. Photosynthetic characteristics during leaf development in “Bing” sweet cherry. J. Amer. Soc. Hort. Sci. 111(6):938-941.
Sawaf, H. M., S. Senfaz, S. O. Adam, A. K. Azaga, and M. A. Ansari. 1985. Vine root distribution under irrigation and rainfall conditions with supplementary underground irrigation. Acta Hort. 158:187-195.
Scholefield, P. B., T. F. Neales, and P. May. 1978. Carbon balance of the Sultana vine (Vitis vinifera L.) and the effects of autumn defoliation by harvest. Aust. J. Plant Physiol. 5:561-570.
Skene, K. G. M. 1972. Cytokinins in the xylem sap of grapevine canes: changes in activity during cold-storage. Planta 104:89-92.
Smart, R. E. and B. G. Coome. 1983. Water relations of grapevines. In: Water Deficit and Plant Growth. Vol. 7. T. T. Kozlowski, (eds.) p.137-196. Academic Press, New York.
Striegler, R. K. and G. S. Howell, 1991. The influence of rootstock on the cold hardiness of Seyval grapevines I. Primary and secondary effects on growth, canopy development, yield, fruit quality and cold hardiness. Vitis 30:1-10.
Takeda, F., R. Arora, M. E. Wisniewski, and G. A. Davis. 1993. Assessment of freeze injury in ‘Boskoop Giant’ black currant buds. HortScience 28(6):652-654.
Terblanche, J. H. 1986. Technical implications of the post-harvest physiology in deciduous fruit. Decid. Fruit Grow. 36:23-27.
Torrey, J. G. 1976. Root hormones and plant growth. Ann. Rev. Plant Physiol. 27:435-459.
van Zyl, J. L. 1984. Response of colombar grapevines to irrigation as regards quality aspects and growth. S. Afr. J. Enol. Vitic. 5:19-28.
Wang, S. Y., M. Faust, and G. L. Steffens. 1985. Metabolic changes in cherry flower buds associated with breaking of dormancy in early and late blooming cultivars. Physiol. Plant. 65:85-94.
Wample, R. L., B. Schnabel, and M. Ahmedullah. 1987. Leaf area and conductance, internode length. and root structure of five cultivars of Vitis vinifera treated with paclobutrazol. Amer. J. Enol. Vitic. 38(4):255-259.
Weaver, R. J. 1976. Grape growing. John Wiley &Sons, New Work.
Westwood, M. N. 1993. Temperature-zone pomology, physiology and culture. Timber Press, Portland.
Williams, L. E. and M. A. Matthews. 1990. Grapevine. In: Irrigation of agricultural crops. B. A. Stewart and D. R. Nirlson. (eds.) p.1019-1055. Amer. Soc. Agron. Inc. Publishers USA.
Williams, L. E. and R. J. Smith 1991 The effect of rootstock on the partitioning of dry weight, nitrogen and potassium, and root distribution of Cabernet Sauvignon grapevines. Amer. J. Enol. Vitic 42(2):118-123.
Williamson, J. G. and D. C. Coston. 1989. The relationship among root growth, shoot growth, and fruit growth of peach. J. Amer. Soc. Hort. Sci. 114(2):180-183.
Winkler, A. J., J. A. Cook, W. M. Kliewer, and L. A. Lider. 1974. General viticulture. University of California Press, Berkeley.
Wood, B. W. 1983. Change in indoleacetic acid, abscisic acid, gibberellins and cytokinins during budbreak in pecan. J. Amer. Soc. Hort. Sci. 108(2):333-338.
Yang, Y. S., Y. Hori, and R. Ogata. 1980. Studies on retranslocation of accumulated assimilates in ‘Delaware’ grapevines. II. Retranslocation of assimilated during the previous growing season. Tohoku J. Agri. Res. 31(2):109-119.
Yang, Y. S. and Y. Hori 1980. Studies on retranslocation of accumulated assimilates in ‘Delaware’ grapevines. III. Early growth of new shoot as dependent on accumulated and current year assimilates. Tohoku J. Agri. Res. 31(2):120-129.
Yoshioka, H. K., K. Nagai, K. Aoba, and M. Fukumoto. 1988. Seasonal changes of carbohydrates metabolism in apple trees. Sci. Hort. 36:219-227.
Young, E. 1989. Cytokinin and soluble carbohydrate concentration in xylem sap of apple during dormancy and budbreak. J. Amer. Soc. Hort. Sci. 114(2):297-300.
Young , E., T. K. Dautlick, and R. D. Belding. 1995. Respiratory changes during dormancy breaking of apple trees. Acta Hort. 395:21-33.
Young, E. and D. J. Werner 1985 Effects of shoot, root, and shank chilling during rest in apple and peach on growth resumption and carbohydrates. J. Amer. Soc. Hort. Sci. 110(6):769-774.
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