我们的网站为什么显示成这样?

可能因为您的浏览器不支持样式,您可以更新您的浏览器到最新版本,以获取对此功能的支持,访问下面的网站,获取关于浏览器的信息:

|Table of Contents|

高温胁迫下不同叶色银杏嫁接苗光响应曲线的拟合(PDF)

《南京林业大学学报(自然科学版)》[ISSN:1000-2006/CN:32-1161/S]

Issue:
2015年02期
Page:
14-20
Column:
专题报道
publishdate:
2015-04-01

Article Info:/Info

Title:
Fitting the light response curves of two ginkgo variants under heating stress
Article ID:
1000-2006(2015)02-0014-07
Author(s):
WANG Huanli12CAO Fuliang12*LIU Xinliang12
1. Co-Innovation Center For the Sustainable Forestry in Southern China, Nanjing 210037, China;
2. College of Forestry, Nanjing Forestry University, Nanjing 210037, China
Keywords:
Ginkgo biloba variant light saturation point light compensation point light response curve
Classification number :
S718.43
DOI:
10.3969/j.issn.1000-2006.2015.02.003
Document Code:
A
Abstract:
In this paper, we measured the light response curves of two ginkgo variants under different temperature, which were two-year old grafted ginkgo plants including the yellow and green genotypes collected from the two branches of the same tree, and then fitted those curves by four common models(the rectangular hyperbola model, the nonrectangular hyperbola model, the exponential model and the modified rectangular hyperbola model). It revealed that rectangular hyperbolic model was the best model to fit ginkgo’s light response curve. Meanwhile, we compared photosynthetic parameters of those two grafted ginkgos under different temperature. It was revealed that the values of light saturation point and maximum net photosynthetic rate(Pn,max)in yellow-leaf grafted ginkgo were significantly lower than yellow-leaf grafted ginkgo under same temperature, while apparent quantum yield(Φ), dark respiration rate(RD)and light compensation point dropped significantly when temperature was above threshold value and threshold values of yellow ginkgo(≥28 ℃ in April and ≥38 ℃ in July)were lower than green ginkgo(≥30 ℃ in April and ≥40 ℃ in July). Based on the results, we provided a reference for the future study on ginkgo’s light response curve under difference stresses. Meanwhile, the upper temperature of these two kinds of ginkgo was a theoretical basis for establishing cultivation and management measure of yellow-leaf grafted ginkgo.

References

[1] 郁万文, 曹福亮. 黄叶银杏叶色发育及光合特性研究[J]. 安徽农业科学, 2011, 39(25): 15410-15412,15494.Yu W W, Cao F L.Preliminary study on leaf color development and photosynthetic characteristics of golden-leaf ginkgo [J]. Journal of Anhui Agriculture Science, 2011, 39(25): 15410-15412, 15494.
[2] 蒋高明, 何维明. 一种在野外自然光照条件下快速测定光合作用-光响应曲线的新方法[J]. 植物学通报, 1999,16(6): 712-718.Jiang G M, He W M. A quick new method for determining light response curves fo photosynthesis under field light conditions [J]. Chinese Bulletin of Botany, 1999, 16(6): 712-718.
[3] 张弥, 吴家兵, 关德新, 等. 长白山阔叶红松林主要树种光合作用的光响应曲线[J]. 应用生态学报, 2006,17(9):1575-1578.Zhang M, Wu J B, Guan D X, et al. Light response curve of dominant tree species photosynthesis in broadleaved Korean pine forest of Chang-bai Mountain [J]. Chinese Journal of Applied Ecology, 2006, 17(9): 1575-1578.
[4] Ye Z P. A new model for relationship between irradiance and the rate of photosynthesis in Oryza sativa [J]. Photosynthetica, 2007, 45(4): 637-640.
[5] Thornley J H M. Dynamic model of leaf photosynthesis with acclimation to light and nitrogen [J]. Annals of Botany, 1998, 81(3): 421-430.
[6] Rabinowitch E I. Photosynthesis and related processes [J]. Soil Science, 1951,72(6): 482.
[7] Kyei-Boahen S, Lada R, Astatkie T, et al. Photosynthetic response of carrots to varying irradiances [J]. Photosynthetica, 2003, 41(2): 301-305.
[8] Marshall B, Biscoe P V. A model for C3 leaves describing the dependence of net photosynthesis on irradiance [J]. Journal of Experimental Botany, 1980, 31(1): 29-39.
[9] Bassman J H, Zwier J C. Gas exchange characteristics of Populus trichocarpa, Populus deltoides and Populus trichocarpa×P. deltoides clones [J]. Tree Physiology, 1991, 8(2): 145-159.
[10] 叶子飘. 光合作用对光合和CO2响应模型的研究进展[J]. 植物生态学报, 2010, 34(6): 727-740.Ye Z P. A review on modeling of responses of photosynthesis to light and CO2 [J]. Chinese Journal of Plant Ecology, 2010, 34(6): 727-740.
[11] Lang Y, Wang M, Zhang G C, et al. Experimental and simulated light responses of photosynthesis in leaves of three tree species under different soil water conditions[J]. Photosynthetica, 2013, 51(3): 370-378.
[12] 陈卫英, 陈真勇, 罗辅燕, 等. 光响应曲线的指数改进模型与常用模型比较[J]. 植物生态学报, 2012, 36(12): 1277-1285.Chen W Y, Chen Z Y, Luo F Y, et al. Comparison between modified exponential model and common models of light-response curve [J]. Chinese Journal of Plant Ecology, 2012, 36(12): 1277-1285.
[13] Taiz L, Zeiger E. Plant physiology [M]. Sunderland: Sinauer Associates, Inc., 2010.
[14] Kakani V G, Boote K J, Reddy K R, et al. Response of bahiagrass carbon assimilation and photosystem activity to below optimum temperatures [J]. Functional Plant Biology, 2008, 35(12): 1243-1254.
[15] Oberhuber W, Edwards C E. Temperature dependence of the linkage of quantum yield of photosystem II to CO2 fixation in C3 and C4 plants [J]. Plant Physiology, 1993,101(2): 507-512.
[16] Salvucci M E, Crafts-Brandner S J. Relationship between the heat tolerance of photosynthesis and the thermal stability of Rubisco activase in plants from contrasting thermal environments [J]. Plant Physiology, 2004, 134(4): 1460-1470.
[17] Greer D H, Weedon M M. Modelling photosynthetic responses to temperature of grapevine(Vitis vinifera cv. Semillon)leaves on vines grown in a hot climate [J]. Plant, Cell & Environment, 2012, 35(6): 1050-1064.
[18] Pimentel C, Ribeiro R V, Machado E C, et al. In vivo temperature limitations of photosynthesis in Phaseolus vulgaris L.[J]. Environmental and Experimental Botany, 2013, 91: 84-89.
[19] Yang X Y, Wang X F, Wei M. Response of photosynthesis in the leaves of cucumber seedlings to light intensity and CO2 concentration under nitrate stress [J]. Turkish Journal of Botany, 2010, 34: 303-310.
[20] Bascu?án-Godoy L, Sanhueza C, Cuba M, et al. Cold-acclimation limits low temperature induced photoinhibition by promoting a higher photochemical quantum yield and a more effective PSII restoration in darkness in the Antarctic rather than the Andean ecotype of Colobanthus quitensis Kunt Bartl(Cariophyllaceae)[J]. BMC Plant Biology, 2012, 12(1): 114.
[21] Nunes C, Araújo S S, Silva J M, et al. Photosynthesis light curves: a method for screening water deficit resistance in the model legume Medicago truncatula [J]. Annals of Applied Biology, 2009, 155(3): 321-332.
[22] Greer D H, Halligan E A. Photosynthetic and fluorescence light responses for kiwifruit(Actinidia deliciosa)leaves at different stages of development on vines grown at two different photon flux densities [J]. Functional Plant Biology, 2001,28(5):373-382.
[23] Sun O, Sweet G. Genotypic variation in light and temperature response of photosynthesis in Nothofagus solandri var. cliffortioides and N. menziesii [J]. Functional Plant Biology, 1996, 23(4): 421-428.
[24] Man R, Lieffers V J. Seasonal photosynthetic responses to light and temperature in white spruce(Picea glauca)seedlings planted under an aspen(Populus tremuloides)canopy and in the open [J]. Tree Physiology, 1997, 17(7): 437-444.
[25] Schultz H R. Extension of a Farquhar model for limitations of leaf photosynthesis induced by light environment, phenology and leaf age in grapevines(Vitis vinifera L. cvv. White Riesling and Zinfandel)[J]. Functional Plant Biology, 2003, 30(6): 673-687.
[26] Osmond C B. Photorespiration and photoinhibition: some implications for the energetics of photosynthesis [J]. BBA-Bioenergetics, 1981, 639(2): 77-98.
[27] Sage R F, Kubien D S. The temperature response of C3 and C4 photosynthesis[J]. Plant, Cell & Environment, 2007, 30(9): 1086-1106.
[28] Yamori W, Hikosaka K, Way D. Temperature response of photosynthesis in C3, C4, and CAM plants: temperature acclimation and temperature adaptation [J]. Photosynthesis research, 2014,119(1-2): 101-117.
[29] Zhou H H, Chen Y N, Li W H, et al. Photosynthesis of Populus euphratica in relation to groundwater depths and high temperature in arid environment, northwest China [J]. Photosynthetica, 2010, 48(2): 257-268.
[30] 薛伟, 李向义, 林丽莎, 等. 短时间热胁迫对疏叶骆驼刺光系统II、Rubisco活性和活性氧化剂的影响[J]. 应用生态学报, 2011, 35(4): 441-451.Xue W, Li X Y, Lin L S, et al. Effects of short time heat stress on photosystemII, Rubisco activities and oxidative radicals in Alhagi sparsifolia[J]. Chinese Journal of Plant Ecology, 2011, 35(4): 441-451.

Last Update: 2015-03-31