美丽箬竹鞭段侧芽萌发生长的碳素制约作用

doi:10.11707/j.1001-7488.20220907

摘要/Abstract

摘要：

目的: 揭示美丽箬竹鞭侧芽萌发生长特征及其所受碳素供应的影响，为促进竹子侧芽萌发、提高竹林产量提供参考。方法: 选取美丽箬竹鞭径基本一致的带1株立竹(M)、未带立竹(N)的1年生竹鞭，进行3种鞭长(3 cm，L1；6 cm，L2；9 cm，L3)6种处理鞭段侧芽萌发试验，调查各处理的侧芽萌发生长位置以及新竹的数量、地径和高度，测定并分析各处理的新竹叶片的光合色素、非结构性碳水化合物含量及变化规律。结果: 1) 对ML1处理，侧芽萌发生长比例的鞭段部位差异不明显，而其余各处理的鞭段远端、近端侧芽萌发生长比例显著高于中段，存在侧芽萌发生长位置的明显偏向性，且偏向性特征随鞭段长度增大而加强。2)与未带立竹的处理相比，同一鞭段长度的带立竹处理的新竹地径、高度均显著升高，但新竹数量总体无明显差异；随鞭段长度增大，新竹数量对未带立竹处理呈升高趋势，对带立竹处理则差异不大，但新竹的地径和高度无论是否带立竹均无明显差异。3)对带立竹处理，新竹叶片光合色素、NSC含量均显著高于未带立竹处理，但各鞭段长度的NSC组分含量及比例变化规律不同；同时，ML1较ML2、ML3处理的新竹叶片可溶性糖含量无明显变化，但淀粉、NSC含量显著较高，而光合色素含量变化则相反，说明短鞭段带立竹处理的碳水化合物过量积累，光合作用受到反馈抑制。鞭段带立竹与否对新竹地径、高度、光合色素和NSC变化的影响明显大于鞭段长度的影响。结论: 碳素供应对鞭段侧芽萌发生长有明显制约作用，是侧芽萌发生长位置偏向性的重要致成因素。碳素供给不断增加，可逐渐消除这种偏向性萌发生长特征，而且鞭段碳素优先保障新竹数量，再满足新竹质量。增加鞭段碳素“库容”，是提高侧芽萌发率的重要途径。

关键词: 美丽箬竹, 鞭段, 侧芽偏向萌发, 非结构性碳水化合物, 碳限制

Abstract:

Objective: This study aims to reveal the characteristics of germination and growth of lateral buds on rhizome, explore the effect of rhizome carbon on the growth of lateral buds, and provide a reference for promoting germination of lateral buds and increasing the yield of bamboo forests. Method: One-year-old rhizomes of Indocalamus decorus with basically same rhizome diameter were used as the material. The rhizome segments with a mother culm (M) or without mother culm (N) were selected, and three different lengths of rhizome segments (L1, 3 cm; L2, 6 cm; L3, 9 cm) were retained by cuting off the rest part. The position of lateral bud germination and the growth of each treatment were investigated, the number, ground diameter and height of the young culms were measured, and the photosynthetic pigments and non-structural carbohydrate content were measured and analyzed. Result: 1) there was no significant difference in the germination ratio and growth of lateral buds over different parts of the rhizome in ML1 treatment, while lateral buds were sprouted out much more at both segment ends than those in its middle part in other treatments. It was showed that more lateral buds sprouted apically or basally, and the bias characteristics became more dramatic with the increase of the rhizome segment length. 2) Compared with the treatment without a mother culm, the ground diameter and height of young culms with a mother culm treatment were significantly increased with the same rhizome segment length, but there was no obvious difference in the number of young culms in general between the two treatments. As the increase of the rhizome segment length, the number of young culms increased in the treatment without mother culms, while the number of young culms in the treatment with a mother culm showed little difference. There was no significant difference in the ground diameter and height of young culms whether the rhizome segment had a mother culm or not. 3) The content of photosynthetic pigments and NSC in the leaves of young culm in the treatment with a mother culm were significantly higher than those in the treatment without mother culm. However, the content and proportion of NSC components in different rhizome lengths were different. At the same time, the soluble sugar content in young bamboo leaves with ML1 treatments showed no significant change compared with that in young bamboo leaves with ML2 and ML3 treatments, but the content of starch and NSC was significantly higher. The change of photosynthetic pigment content was opposite. The results indicated that the shorter rhizome segment with a mother culm had excessive carbohydrate accumulation and photosynthesis was inhibited by feedback. Effects of rhizome with mother culm or not on the diameter, height, photosynthetic pigment and NSC of young bamboo were significantly higher than those of the length of the rhizome segment. Conclusion: Carbon has an obvious restrictive effect on the germination of lateral buds on rhizome, which is an important factor causing the positional bias of the lateral bud germination. The continuous increase of carbon supply could gradually eliminate this biased germination characteristics, and the rhizome segment carbon gives priority to ensuring the quantity of young bamboo, and then the quality. Increasing the carbon storage capacity of rhizome segment is an important way to improve the lateral bud germination rate.

Key words: Indocalamus decorus, rhizome segment, lateral bud directional sprouting, NSC, carbonlimitation

中图分类号:

S795

谷瑞,徐森,陈双林,郭子武,杨丽婷. 美丽箬竹鞭段侧芽萌发生长的碳素制约作用[J]. 林业科学, 2022, 58(9): 70-78.

Rui Gu,Sen Xu,Shuanglin Chen,Ziwu Guo,Liting Yang. Carbon-Limitation to the Germination and of Growth Lateral Buds on Indocalamus decorus Rhizome[J]. Scientia Silvae Sinicae, 2022, 58(9): 70-78.

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参考文献 0

	杜佩剑. 2008. 不同基质配方及叶面肥浓度对四种观赏树种容器苗生长的影响. 南京: 南京农业大学.
	Du P J. 2008. Effect of different matrix formula and foliar fertilizer concentrations on the growth of four species of ornamental trees container seedlings. Nanjing: Nanjing Agricultural University. [in Chinese]
	董文渊, 黄宝龙, 谢泽轩, 等. 筇竹无性系地下茎生长规律的研究. 竹子研究汇刊, 2002, 21 (4): 55- 59.
	Dong W Y , Huang B L , Xie Z X , et al. Study on the pattern of rhizome growth of Qiongzhuea tumidinoda Clone. Journal of Bamboo Research, 2002, 21 (4): 55- 59.
	董文渊, 谢泽轩, 龙友和. 水竹无性繁殖育苗技术的研究. 竹子研究汇刊, 1999, 18 (3): 50- 54.
	Dong W Y , Xie Z X , Long Y H . A Study on off set-raising of Phyllostachys heteroclada by clonal propagation. Journal of Bamboo Research, 1999, 18 (3): 50- 54.
	高贵宾, 钟浩, 潘雁红, 等. 生态因子对美丽箬竹盆栽苗生物量分配的影响. 南京林业大学学报(自然科学版), 2017, 41 (5): 35- 41.
	Gao G B , Zhong H , Pan Y H , et al. Effects of ecological factors on biomass allocation of Indocalamus decorus pot seedlings. Journal of Nanjing Forestry University (Natural Sciences Edition), 2017, 41 (5): 35- 41.
	谷瑞, 徐森, 陈双林, 等. 美丽箬竹容器育苗鞭段侧芽萌发生长的位置偏向性. 生态学杂志, 2020, 39 (9): 2896- 2903.
	Gu R , Xu S , Chen S L , et al. Lateral rhizome bud directional sprouting of Indocalamus decorus seedling raised in container. Chinese Journal of Ecology, 2020, 39 (9): 2896- 2903.
	谷瑞, 徐森, 陈双林, 等. 美丽箬竹鞭段侧芽偏向性萌发生长的激素和养分作用. 林业科学, 2021, 5, 7.
	Gu R , Xu S , Chen S L , et al. Effects of hormones and nutrients on the directional growth of lateral rhizome bud of Indocalamus decorus. Scientia Silvae Sinicae, 2021, 57 (4): 73- 80.
	黄甫昭, 范怡, 王福升, 等. 篌竹的鞭系及根系结构. 林业科技开发, 2012, 26 (6): 55- 59.
	Huang F Z , Fan Y , Wang F S , et al. Studies on rhizome and root system structure of Phyllostachys nidularia Munro. Forestry Science and Technology Development, 2012, 26 (6): 55- 59.
	李翀, 周国模, 施拥军. 老竹水平和经营措施对新竹发育质量的影响. 生态学报, 2016, 36 (8): 2243- 2254.
	Li C , Zhou G M , Shi Y J . Effectsof old bamboo forests and relevant management measures on growth of new bamboo forests. Acta Ecologica Sinica, 2016, 36 (8): 2243- 2254.
	梁玖华, 黄河, 潘斌, 等. 叶面施肥对实生毛竹苗鞭笋生长与萌发的影响. 经济林研究, 2004, 22 (4): 47- 49.
	Liang J H , Huang H , Pan B , et al. Influence of leaf fertilization on Phyllostachys shoot grown from seed. Nonwood Forest Research, 2004, 22 (4): 47- 49.
	刘国华, 王福升, 丁雨龙. 4种地被竹根系分布特征及其力学性质. 林业科技开发, 2011, 25 (6): 20- 23.
	Liu G H , Wang F S , Ding Y L . A research on root system distribution characteristic and mechanical properties of 4 dwarf bamboos. Forestry Science And Technology Development, 2011, 25 (6): 20- 23.
	刘静, 汤定钦, 傅鹰. 模式植物侧芽和竹子笋芽分化发育的研究进展. 农业生物技术学报, 2017, 25 (5): 788- 804.
	Liu J , Tang D Q , Fu Y . Research progress of differentiation and development of model plant lateral buds and bamboo shoot bud. Journal of Agricultural Biotechnology, 2017, 25 (5): 788- 804.
	刘勇. 我国苗木培育理论与技术进展. 世界林业研究, 2000, 13 (5): 43- 49.
	Liu Y . Advances in theory and techniques of seedling culture in China. World Forestry Research, 2000, 13 (5): 43- 49.
	楼一平, 吴良如, 刘耀荣. 微肥、激素对竹鞭笋芽萌发的影响. 林业科学研究, 1997, 10 (5): 541- 545.
	Lou Y P , Wu L R , Liu Y R . Effect of hormones, rare earth and micronutrient on promoting bamboo rhizome buds to produce shoots. Forest Research, 1997, 10 (5): 541- 545.
	陆媛媛, 郑林水, 刘仙, 等. 毛竹笋竹两用林地下鞭系结构调控技术. 中南林业科技大学学报, 2011, 31 (8): 61- 65.
	Lu Y Y , Zheng L S , Liu X . Structure regulation and control on underground bamboo rhizome system of bamboo forest for shoot and wood. Journal of Central South University of Forestry and Technology, 2011, 31 (8): 61- 65.
	庞元湘, 祁琳, 陈颖, 等. 4种观赏地被竹的生长及扩展能力比较. 世界竹藤通讯, 2018, 16 (5): 29- 31.
	Pang Y X , Qi L , Chen Y , et al. Investigation on the growth and expansion ability of four dwarf ornamental bamboo species. World Bamboo and Rattan, 2018, 16 (5): 29- 31.
	施建敏, 叶学华, 陈伏生, 等. 竹类植物对异质生境的适应-表型可塑性. 生态学报, 2014, 34 (20): 5687- 5695.
	Shi J M , Ye X H , Chen F S , et al. Adaptation of bamboo to heterogen eous habitat: phenotypic plasticity. Acta Ecologica Sinica, 2014, 34 (20): 5687- 5695.
	施征, 白登忠, 雷静品, 等. 祁连圆柏光合色素与非结构性碳水化合物含量对海拔变化的响应. 西北植物学报, 2012, 32, 2286- 2292.
	Shi Z , Bai D Z , Lei J P , et al. Variations of chloroplast pigments and non-structural carbohydrates of Sabina przewalskii along altitude in Qilian Mountains timberline. Acta Botanica Boreali-Occidentalia Sinica, 2012, 32, 2286- 2292.
	王波, 丁雨龙, 汪奎宏. 铺地竹竹鞭生长规律的调查研究. 林业科技开发, 2007, 21 (6): 16- 18.
	Wang B , Ding Y L , Wang K H . Study on the rhizome system growth regularity of Arundinaria. Forestry Science and Technology Development, 2007, 21 (6): 16- 18.
	王文娜, 高国强, 李俊楠., 等. 去叶对水曲柳苗木根系非结构性碳水化合物分配的影响. 应用生态学报, 2018, 29 (7): 2315- 2322.
	Wang W N , Gao G Q , Li J N , et al. Effects of defoliation on the allocation of non-structural carbohydrates in roots of Fraxinus mandshurica seedlings. Chinese Journal of Applied Ecology, 2018, 29 (7): 2315- 2322.
	王学奎. 植物生理生化实验原理和技术. 北京: 高等教育出版社, 2006: 134- 136.
	Wang X K . Experimental principles and techniques of plant physiology and biochemistry. Beijing: Higher Education Press, 2006: 134- 136.
	王兆国, 王传宽. 碳供给与碳利用对树木生长的限制机制. 植物生态学报, 2019, 43 (12): 1036- 1047.
	Wang Z G , Wang C K . Mechanisms of carbon source-sink limitations to tree growth. Chinese Journal of Plant Ecology, 2019, 43 (12): 1036- 1047.
	严蓓, 孙锦, 束胜, 等. 源钙对NaCl胁迫下黄瓜幼苗叶片光合特性及碳水化合物代谢的影响. 南京农业大学学报, 2014, 37 (1): 31- 36.
	Yan B , Sun J , Shu S. , et al. Effects of exogenous calcium on photosynthetic characteristics and carbohydrate metabolism in leaves of cucumber(Cucumis sativus L.) seedlings under NaCl stress. Journal of Nanjing Agricultural University, 2014, 37 (1): 31- 36.
	余水生, 毛海波, 朱文强. 施肥对毛竹鞭笋产量和地下竹鞭生长的影响. 江苏林业科技, 2016, 43 (6): 34- 37.
	Yu S S , Mao H B , Zhu W Q . Effects of fertilization on bamboo shoots production and bamboo shoots growth. Journal of Jiangsu Forestry Science and Technology, 2016, 43 (6): 34- 37.
	袁进成, 刘颖慧. 高等植物侧芽、侧枝的发生及调控. 河北北方学院学报(自然科学版), 2007, 23 (5): 18- 23.
	Yuan J C , Liu Y H . Advancing in the control of lateral buds and branching initiation in high plants. Journal of Hebei North University (Natural Science Edition), 2007, 23 (5): 18- 23.
	张卓文, 汤景明, 熊艳平, 等. 雷竹引种后地下鞭生长规律研究. 华中农业大学学报, 2001, 20 (1): 77- 80.
	Zhang Z W , Tang J M , Xiong Y P , et al. Studies on the bamboo rhizome growth after Introduction of Phyllostachys praecon f. preveynalis. Journal of Huazhong Agricultural University, 2001, 20 (1): 77- 80.
	郑炳松, 金爱武, 董林根. 雷竹地下鞭笋芽分化过程中营养动态初步研究. 浙江林学院学报, 1998, 15 (3): 232- 235.
	Zheng B S , Jin A W , Dong L G . Preliminary study of nutrient dynamics of Lei bamboo rhizome during mixed bud differentiation. Journal of Zhejiang Forestry College, 1998, 15 (3): 232- 235.
	周永斌, 吴栋栋, 于大炮, 等. 长白山不同海拔岳桦非结构碳水化合物含量的变化. 植物生态学报, 2009, 33 (1): 118- 124.
	Zhou Y B , Wu D D , Yu D P , et al. Variations of non-structural carbohydrate content in Betula ermanii at different elevations of Changbai Mountain, China. Chinese Journal of Plant Ecology, 2009, 33 (1): 118- 124.
	邹帆, 张万荣, 冯儒飞. 地被观赏竹在植物型护岸中的应用前景. 山西建筑, 2017, 43 (4): 215- 216.
	Zou F , Zhang W R , Feng R F . The application foreground of dwarf bamboos in the ecological revetment. Shanxi Architecture, 2017, 43 (4): 215- 216.
	Barbaroux C , Breda N , Dufrene E . Distribution of above-ground and below-ground carbohydrate reserves in adult trees of two contrasting broad-leaved species (Quercus petraea and Fagus sylvatica). New Phytologist, 2003, 157 (3): 605- 615.
	Chapin F S , Schulze E D , Mooney H A . The ecology and economics of storage in plants. Annual Review of Ecology and Systematics, 1990, 21, 423- 447.
	Koch K E . Carbohydrate-modulated gene expression in plants. Annual Review of Plant Physiology and Plant Molecular Biology, 1996, 47, 509- 540.
	Shi P L , Körner C , Hoch G . End of season carbon supply status of woody species near the treeline in western China. Basic and Applied Ecology, 2006, 7, 370- 377.
	White A C , Rogers A , Rees M , et al. How can we make plants grow faster? A source-sink perspective on growth rate. Journal of Experimental Botany, 2015, 67, 31- 45.
	Wilson E R , Vitols K C , Park A . Root characteristics and growth potential of container and bare-root seedlings of red oak (Quercus rubra L.) in Ontario, Canada. New Forests, 2007, 34 (2): 163- 176.
	Wurth M K R , Pelaez-Riedl S , Wright S J , et al. Non-structural carbohydrate pools in a tropical forest. Oecologia, 2005, 143 (1): 11- 24.
	Xu Z F , Yin H J , Xiong P , et al. Short- term responses of Picea asperata seedlings of different ages grown in two contrasting forest ecosystems to experimental warming. Environmental and Experimental Botany, 2012, 77, 1- 11.
	Yu D P , Wang Q W , Liu J Q , et al. Formation mechanisms of the alpine Erman' s birch (Betula ermanii) treeline on Changbai Mountain in Northeast China. Trees, 2014, 28 (3): 935- 947.

处理	近端	中段	远端
Treatment	Proximal end	Middle end	Distal end
NL1	31.92±7.57 Ba	22.69±2.52 Ca	45.38±5.04 Aa
NL2	35.74±2.85 Ba	20.74±1.28 Ca	43.52±4.09 Aa
NL3	42.51±5.35 Aa	20.65±1.84 Ba	36.84±3.53 Aa
ML1	33.82±5.95 Aa	34.99±1.53 Aa	31.18±4.56 Ab
ML2	32.77±5.31Aa	22.55±3.96 Bb	36.21±3.43Aab
ML3	36.81±4.66 Aa	15.72±5.00 Bb	47.46±9.61 Aa

指标Indexes	处理Treatments	L1	L2	L3
叶绿素a含量	N	2.49±0.11 Ba	2.68±0.35 Ba	2.67±0.17 Ba
Contet of Chl a/(mg·g^-1)	M	2.74±0.07 Ab	3.05±0.21 Aa	3.16±0.24 Aa
叶绿素b含量	N	0.79±0.03 Ba	0.87±0.07 Ba	0.86±0.07 Ba
Contet of Chl b/(mg·g^-1)	M	0.91±0.06 Ab	1.06±0.05 Aa	1.00±0.09 Aa
叶绿素(a+b)含量	N	3.28±0.14 Ba	3.58±0.31 Ba	3.52±0.24 Ba
Contet of Chl/(mg·g^-1)	M	3.66±0.12 Ab	4.11±0.26 Aa	4.14±0.35 Aa
类胡萝卜素含量	N	0.46±0.02 Ba	0.49±0.04 Ba	0.49±0.03 Ba
Contet of Car	M	0.50±0.01 Ab	0.56±0.04 Aa	0.59±0.05 Aa
叶绿素a /b	N	3.15±0.04 Aa	3.13±0.04 Aa	3.12±0.10 Aa
Chl a/b	M	3.01±0.13 Ba	2.88±0.09 Bb	3.11±0.03 Aa
可溶性糖含量	N	1.51±0.05 Bb	1.71±0.02 Ba	1.67±0.05 Ba
Contet of soluble sugar/(mg·g^-1)	M	1.75±0.07 Aa	1.81±0.06 Aa	1.87±0.09 Aa
淀粉含量	N	7.49±0.33 Ba	7.55±0.33 Aa	7.67±0.11 Aa
Contet of starch/(mg·g^-1)	M	8.54±0.17 Aa	7.88±0.05 Ab	7.92±0.25 Ab
NSC含量	N	9.00±0.30 Ba	9.36±0.32 Ba	9.34±0.06 Ba
Contet of NSC/(mg·g^-1)	M	10.28±0.16 Aa	9.72±0.09 Ab	9.79±0.27Ab
可溶性糖/淀粉	N	0.20±0.01 Aa	0.22±0.01 Aa	0.22±0.01 Aa
Soluble starch ratio	M	0.20±0.02 Aa	0.23±0.01 Aa	0.23±0.04 Aa

变异来源 Source of variation	立竹处理MT			鞭段长度RL			立竹处理×鞭段长度MT×RL
变异来源 Source of variation	离差平方和SS	均方MS	F	离差平方和 SS	均方MS	F	离差平方和SS	均方 MS	F
新竹数量Number of young bamboo	3.556	3.556	0.753	66.333	33.167	7.024^*	65.444	32.722	6.929^*
地径Ground diameter	0.116	0.116	24.343^**	0.015	0.008	1.585	0.001	0	0.075
新竹高度Height of young bamboo	435.518	435.518	124.75^**	4.621	2.311	0.662	6.118	3.059	0.876
叶绿素a Chl a	1.19	1.19	25.98^**	0.586	0.293	6.403^**	0.066	0.033	0.719
叶绿素b Chl b	0.224	0.224	42.218^**	0.074	0.037	6.932^**	0.01	0.005	0.937
总叶绿素Chl (a+b)	2.447	2.447	30.478^**	1.054	0.527	6.562^**	0.099	0.05	0.617
类胡萝卜素Car	0.044	0.044	28.847^**	0.024	0.012	7.94^**	0.004	0.002	1.149
叶绿素a/b Chla/b	0.146	0.146	21.307^**	0.071	0.035	5.165^**	0.078	0.039	5.707^**
可溶性糖Soluble sugar	0.216	0.216	42.047^**	0.099	0.049	9.572^**	0.003	0.003	0.545
淀粉Starch	2.012	2.012	40.401^**	0.49	0.245	4.923^**	0.821	0.821	16.49^**
可溶性糖/淀粉Soluble sugar/Starch	0	0	2.416	0.003	0.001	10.079^**	0	0	2.915
NSC	3.442	3.442	71.814^**	0.3	0.15	3.131^**	0.88	0.88	18.366^**

[1]	倪妍妍,简尊吉,徐瑾,曾立雄,阮宏华,雷蕾,肖文发,李迈和. 马尾松非结构性碳库大小及分配的纬向变化[J]. 林业科学, 2022, 58(8): 41-52.
[2]	谷瑞,徐森,陈双林,郭子武,章超. 美丽箬竹鞭段侧芽偏向性萌发生长的激素和养分作用[J]. 林业科学, 2021, 57(4): 73-81.
[3]	徐军亮,竹磊,师志强,武靖,章异平. 栓皮栎粗根和茎干中非结构性碳水化合物含量的调配关系[J]. 林业科学, 2021, 57(1): 200-206.
[4]	洪琮浩,洪震,雷小华,汪俊峰,闫道良. 氮添加对长序榆C、N、P养分含量及非结构性碳水化合物含量的影响[J]. 林业科学, 2020, 56(6): 186-192.
[5]	王凯,宋琪,张日升,张大鹏,孙菊. 科尔沁沙地防护林主要树种的非结构性碳水化合物分布特征[J]. 林业科学, 2020, 56(12): 39-48.
[6]	陈奕帆,付晓莉,王辉民,戴晓琴,寇亮,陈伏生,卜文圣. 林下植被清除对不同径级中龄杉木生长速率的影响机制[J]. 林业科学, 2020, 56(11): 21-30.
[7]	钱杨, 孙洪刚, 董汝湘, 姜景民. 针叶树碳水化合物分配研究进展[J]. 林业科学, 2018, 54(1): 141-153.
[8]	代永欣, 王林, 万贤崇. 遮荫和环剥对刺槐、侧柏苗木碳素分配和水力学特性的影响[J]. 林业科学, 2017, 53(7): 37-44.
[9]	刘万德, 苏建荣, 李帅锋, 郎学东, 黄小波, 张志钧. 云南普洱季风常绿阔叶林主要树种非结构性碳水化合物变异分析[J]. 林业科学, 2017, 53(6): 1-9.
[10]	成方妍, 王传宽. 树种和组织对树干非结构性碳水化合物储量估测的影响[J]. 林业科学, 2016, 52(2): 1-9.
[11]	周永斌吴栋栋于大炮. 长白山岳桦体内碳素供应状况[J]. 林业科学, 2010, 46(3): 161-165.