Greer Dennis H, Cirillo Chiara, Norling Cara L
School of Food and Wine Science and National Wine and Grape Industry Centre, Charles Sturt University, Locked Bag 588, Wagga Wagga, NSW 2678, Australia. Corresponding author; email:
Dipartimento di Arboricoltura, Botanica e Patologia Vegetale, Università degli Studi di Napoli Federico I, Via Università, 100 I-80056 Portici (Na), Italy.
Funct Plant Biol. 2003 Oct;30(9):927-937. doi: 10.1071/FP03111.
Fruiting kiwifruit [Actinidia deliciosa (A. Chev.) C.F. Liang et A.R. Ferguson] vines were grown in two controlled temperatures of 28 / 22 and 17 / 12°C (day / night) for 160 and 215 d, to measure shoot and fruit growth and carbon demand, and to examine competition between fruit and the shoot. Leaf area, internode lengths, fruit diameters, photosynthesis and respiration were measured at regular intervals. The net daily carbon balance per shoot was determined from the net carbon acquisition of shoots, and carbon sequestration as shoot biomass. Vines grown at high temperature had 200% more leaf area, similar stem lengths and 100% more biomass than vines grown at low temperature. Leaf area expansion and stem extension were transiently reduced when fruit growth was maximal. Photosynthetic and respiration rates were affected by temperature, leading to net carbon acquisition of 450 g shoot for 28 / 22°C-grown vines and 253 g shoot for 17 / 12°C-grown vines, 54% being used for leaf, stem and fruit growth. Reallocation of carbon occurred from leaves to fruit, and the consequent reduction in leaf area strongly reduced the overall carbon balance compared with vegetative vines at similar temperatures. The data support the conclusion that at low temperatures especially, there is insufficient carbon to meet the full demands of both fruit and shoot growth.
将结果实的猕猴桃[美味猕猴桃(A. Chev.)C.F. Liang和A.R. Ferguson]藤蔓种植在28 / 22和17 / 12°C(白天/夜晚)这两种可控温度下,时长分别为160天和215天,以测量新梢和果实的生长以及碳需求,并研究果实与新梢之间的竞争关系。定期测量叶面积、节间长度、果实直径、光合作用和呼吸作用。根据新梢的净碳获取量以及作为新梢生物量的碳固存来确定每个新梢的每日净碳平衡。与在低温下生长的藤蔓相比,在高温下生长的藤蔓叶面积多200%,茎长度相似,生物量多100%。当果实生长达到最大时,叶面积扩展和茎伸长会暂时减少。光合速率和呼吸速率受温度影响,使得在28 / 22°C下生长的藤蔓每个新梢的净碳获取量为450克,在17 / 12°C下生长的藤蔓为253克,其中54%用于叶、茎和果实生长。碳从叶片重新分配到果实,与在相似温度下的营养藤蔓相比,由此导致的叶面积减少极大地降低了整体碳平衡。这些数据支持了这样的结论,尤其是在低温下,没有足够的碳来满足果实和新梢生长的全部需求。
