粉垄对甘蔗根系结构发育及呼吸代谢相关酶活性的影响

doi:10.3864/j.issn.0578-1752.2021.03.006

摘要/Abstract

摘要：

【目的】探讨甘蔗粉垄技术增产增糖的根系细胞生理学机制,为粉垄技术推广提供理论依据。【方法】以桂糖42号为供试材料进行粉垄耕作处理（耕作深度40 cm）,以常规耕作为对照（耕作深度 25 cm,CK）,分别测定土壤速效养分,甘蔗农艺性状及产量和糖分、根系形态、根毛区组织细胞结构、根系活力、苹果酸脱氢酶、细胞色素氧化酶等呼吸代谢相关酶活性。【结果】（1）与常规耕作相比,新植蔗土壤的碱解氮和速效磷分别增加了8.7%和17.9%;宿根蔗土壤增加了10.4%和25.6%,且不同耕作方式间同一指标差异显著;（2）粉垄新植蔗出苗率和分蘖率比常规耕作分别提高了25.0%和17.4%,宿根蔗分别提高了30.6%和11.7%。砍收时,粉垄新植蔗株高、茎径、单茎重、有效茎、产量分别提高了13.2%、17.6%、29.0%、5.3%、12.9%,粉垄宿根蔗分别增加了7.6%、22.2%、70.3%、18.7%和12.9%,且不同耕作方式间同一指标差异显著;（3）粉垄甘蔗根长、根直径、根体积、根尖数、根表面、根鲜重、根干重比常规耕作分别增加20.9%—42.3%、12.3%—71.0%、33.3%—71.0%、6.4%—61.6%,21.8%—64.1%、26.8%—64.4%和32.6%—95.3%,且不同耕作方式间同一指标差异显著;（4）与常规耕作相比,粉垄甘蔗根毛区和根毛细胞更长,根毛排列更疏松有序,根尖细胞壁增厚,细胞质、粗糙型内质网和高尔基体更丰富,线粒体数目更多且嵴清晰,细胞核结构更紧致;粉垄新植蔗根毛长度、根毛密度、单位面积根毛总长度和细胞中线粒体数目分别增加了53.3%、73.0%、111.1%和37.5%;粉垄宿根蔗以上指标也分别增加了38.9%、95.9%、82.6%和53.8%,且不同耕作方式间同一指标差异显著;（5）与常规耕作相比,粉垄甘蔗根系活力在整个生育期均显著增强,在苗期、伸长期和成熟期分别增加了1.29倍、1.39倍和1.25;（6）与常规耕作相比,粉垄苹果酸脱氢酶（MDH）、细胞色素氧化酶（CytcA510）和多酚氧化酶（PPO）活性在苗期和伸长期均显著增加,在苗期,新植蔗粉垄甘蔗苹果酸脱氢酶、细胞色素氧化酶和多酚氧化酶活性分别提高了22.9%、28.1%和38.9%,宿根蔗以上各指标分别提高23.0%、20.3%、27.7%,差异显著;在伸长期,新植粉垄甘蔗分别显著提高21.2%、41.8%和33.7%,宿根蔗各指标分别提高27.4%、26.8%和53.3%;成熟期,除了细胞色素氧化酶差异不显著外,粉垄新植蔗和宿根蔗的苹果酸脱氢酶、多酚氧化酶活性均显著提高。【结论】粉垄可提高速效氮和速效磷含量,改善甘蔗根系的营养,提高根系活力和呼吸代谢相关酶活性,有利于根系组织细胞结构和根系形态的发育,从而进一步促进根系对水肥的吸收。

关键词: 粉垄, 甘蔗, 根系, 细胞结构, 生理

Abstract:

【Objective】By exploring the root cellular physiological mechanism on sugarcane yield and sugar content under the new farming method of Fenlong, this paper provided a theoretical basis for the promotion of Fenlong cultivation technology.【Method】Guitang 42 was used as the tested sugarcane variety, the conventional rotary tillage (CK, the depth of ploughing was 25 cm) and Fenlong cultivation (the depth of ploughing was 40 cm) were carried out to investigate the soil available nutrient, agronomic characters, yield and sugar content, root vitality, cellular ultrastructure and the enzyme of respiratory metabolic of sugarcane root.【Result】(1) The alkaline N and available P of new plant of Fenlong cultivation were 8.7% and 17.9% significantly higher than those under CK, respectively, and the alkaline N and available P of ratoon cane were 10.4% and 25.6% significantly higher than those under CK, respectively. (2) The emergence rate and tillering rate of Fenlong were increased by 25.0% and 17.4%, respectively, and regenerated sugarcane increased by 30.6% and 11.7%, respectively. Compared with conventional cultivation, the plant height, stem diameter, single stem weight, effective stem and yield of new planting sugarcane under Fenlonng cultivation increased by 13.2%, 17.6%, 29.0%, 5.3% and 12.9%, respectively, and regenerated sugarcane with Fenlonng cultivation increased by 7.6%, 22.2%, 70.3%, 18.7% and 12.9%, respectively. (3) The length, diameter, volume, root tip number, surface area, fresh weight and dry weight of root under Fenlong cultivation were 20.9%-42.3%, 12.3%-71.0%, 33.3%-71.0%, 6.4%-61.6%, 21.8%-64.1%, 26.8%-64.4% and 32.6%-95.3% significantly greater under CK, respectively. (4) Under Fenlong cultivation conditions, root hair area and cells were longer, the root hair arrangement was looser and more orderly, the root tip cell wall was thickened, the cytoplasm, rough endoplasmic reticulum and Golgi body were more abundant, the number of mitochondria was more and the crest was clear, and the nuclear structure was more compact than those under CK. The root hair length, root hair density, total root hair length per unit area and the number of mitochondria in cells were 53.3%, 73.0%, 111.1% and 37.5% higher than those under CK, respectively. The Fenlong tillage ratoon sugarcane above indicators also increased by 38.9%, 95.9%, 82.6% and 53.8%, respectively, and the same index was significantly different among different cultivation methods. (5) The root activity of sugarcane with Fenlong cultivation in seedling stage, elongation stage and maturity stage with Fenlong cultivation were 1.29 times, 1.39 times and 1.25 times significantly higher than CK, respectively. (6) The activity of malate dehydrogenase, cytochrome oxidase and polyphenol oxidase of sugarcane with Fenlong cultivation increased significantly at seedling stage and elongation stage. In the seedling stage, the activities of MDH? PPO and CytcA510 in newly planted sugarcane were 22.9%, 28.1% and 38.9% significantly higher than those under CK, and the indexes of ratoon cane were 23.0%, 20.3% and 27.7% significantly higher than those under CK, respectively. At the elongation stage, the activities of malate dehydrogenase, cytochrome oxidase and polyphenol oxidase of sugarcane with Fenlong cultivation were 21.2%, 41.8% and 33.7% significantly higher than those under CK, respectively; THE indexes of regenerated sugarcane were 27.4%, 26.8% and 53.3% higher than those of under CK, respectively; THE activities of MDH and PPO were significantly higher than those under CK.【Conclusion】 Fenlong cultivation of sugarcane could improve the soil available nutrient, improve the morphology and tissue cell structure of sugarcane roots, improve the activity of enzymes related to respiratory metabolism, thereby promoting the absorption of water and fertilizer by roots, facilitating growth and development on the ground, and increasing sugarcane yield and sugar content.

Key words: Fenlong, sugarcane, root, cell structure, physiology

李浩,韦本辉,黄金玲,李志刚,王令强,梁晓莹,李素丽. 粉垄对甘蔗根系结构发育及呼吸代谢相关酶活性的影响[J]. 中国农业科学, 2021, 54(3): 522-532.

LI Hao,WEI BenHui,HUANG JinLing,LI ZhiGang,WANG LingQiang,LIANG XiaoYing,LI SuLi. Effects of Fenlong Cultivation on Root Cell Structure and Enzyme of Respiratory Metabolic of Sugarcane[J]. Scientia Agricultura Sinica, 2021, 54(3): 522-532.

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链接本文: https://www.chinaagrisci.com/CN/10.3864/j.issn.0578-1752.2021.03.006

https://www.chinaagrisci.com/CN/Y2021/V54/I3/522

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参考文献 31

[1]	韦本辉. 旱地作物粉垄栽培技术研究简报. 中国农业科学, 2010,43(20):4330.
	WEI B H. Research on smash-ridging cultivation techniques of dryland crops. Scientia Agricultura Sinica, 2010,43(20):4330. (in Chinese)
[2]	韦本辉. 粉垄活化资源构建绿色农业“3+1”产业体系的探讨. 农业科学与技术(英文版), 2017,18(2):380-384.
	WEI B H. Discussion on the construction of green agriculture “3+1” industry system using Fenlong activated resources. Agricultural Science & Technology, 2017,18(2):380-384. (in Chinese)
[3]	韦本辉. 粉垄增产提质保水及倍用“天地资源”绿色发展的可能性. 农业科学与技术(英文版), 2017,18(9):1631-1637.
	WEI B H. Discussion on green development of fenlong for yield increase, quality enhancing, water retaining and multiple use of natural resources. Agricultural Science & Technology, 2017,18(9):1631-1637. (in Chinese)
[4]	韦本辉. 中国发明第四套农耕方法“粉垄”. 农业科学与技术(英文版), 2017,18(11):2045-2048, 2052.
	WEI B H. Fenlong cultivation-the fourth set of farming methods invented in China. Agricultural Science & Technology, 2017,18(11):2045-2048, 2052. (in Chinese)
[5]	韦本辉, 刘斌, 甘秀芹, 申章佑, 胡泊, 李艳英, 吴延勇, 陆柳英. 粉垄栽培对水稻产量和品质的影响. 中国农业科学, 2012,45(19):3946-3954.
	WEI B H, LIU B, GAN X Q, SHEN Z Y, HU B, LI Y Y, WU Y Y, LU L Y. Effect of Fenlong cultivation on yield and quality of rice. Scientia Agricultura Sinica, 2012,45(19):3946-3954. (in Chinese)
[6]	韦本辉. 重构耕层可持续增产的“水稻粉垄生态高效栽培法”. 农业科学与技术(英文版), 2014,15(9):1526-1529.
	WEI B H. Reconstruction of highly-efficient smash-ridging ecological cultivation method for sustainable yield-increasing of soil plough layers. Agricultural Science & Technology, 2014,15(9):1526-1529. (in Chinese)
[7]	韦本辉, 申章佑, 周佳, 周灵芝, 李艳英, 劳承英, 甘秀芹, 胡泊, 韦元波. 论粉垄“大科学”在人与自然共生中的作用与潜能. 农业科学与技术(英文版), 2017,18(12):2303-2308, 2311.
	WEI B H, SHEN Z Y, ZHOU J, ZHOU L Z, LI Y Y, LAO C Y, GAN X Q, HU P, WEI Y B. Discussion on action and potential of Fenlong megascience in the symbiosis between human and nature. Agricultural Science & Technology, 2017,18(12):2303-2308, 2311. (in Chinese)
[8]	聂胜委, 张玉亭, 张巧萍, 郭庆, 汤丰收, 王洪庆, 何宁. 粉垄耕作对小麦玉米产量及耕层土壤养分的影响. 土壤通报, 2017,48(4):930-936.
	NIE S W, ZHANG Y T, ZHANG Q P, GUO Q, TANG F S, WANG H Q, HE N. Effect of smashing ridge tillage on grain yields of winter wheat and summer maize and contents of soil nutrients. Chinese Journal of Soil Science, 2017,48(4):930-936. (in Chinese)
[9]	李轶冰, 逄焕成, 李华, 李玉义, 杨雪, 董国豪, 郭良海, 王湘峻. 粉垄耕作对黄淮海北部春玉米籽粒灌浆及产量的影响. 中国农业科学, 2013,46(14):3055-3064.
	LI Y B, PANG H C, LI H, LI Y Y, YANG X, DONG G H, GUO L H, WANG X J. Effects of deep vertically rotary tillage on grain filling and yield of spring maize in north Huang-Huai-Hai region. Scientia Agricultura Sinica, 2013,46(14):3055-3064. (in Chinese)
[10]	王世佳, 蒋代华, 朱文国, 张蓉蓉, 李军伟, 韦本辉. 粉垄耕作对农田赤红壤团聚体结构的影响. 土壤学报, 2020,57(2):326-335.
	WANG S J, JIANG D H, ZHU W G, ZHANG R R, LI J W, WEI B H. Effect of deep vertical rotary tillage on aggregate structure in farmland of lateritic red soil. Acta Pedologica Sinica, 2020,57(2):326-335. (in Chinese)
[11]	韦增林, 张亮曼, 卢国培, 曹小琼, 韦思庚, 黎忠海, 王小明. 粉垄栽培对甘蔗产量及糖分影响初报. 甘蔗糖业, 2018(6):37-40.
	WEI Z L, ZHANG L M, LU G P, CAO X Q, WEI S G, LI Z H, WANG X M. The effect of powder ridge cultivation on sugarcane yield and sugar. Sugarcane and Canesugar, 2018(6):37-40. (in Chinese)
[12]	韦本辉, 甘秀芹, 陈保善, 申章佑, 俞建, 宁秀呈, 陆柳英, 韦广泼, 胡泊, 莫润秀, 李艳英, 吴延勇. 粉垄整地与传统整地方式种植玉米和花生效果比较. 安徽农业科学, 2011,39(6):3216-3219.
	WEI B H, GAN X Q, CHEN B S, SHEN Z Y, YU J, NING X C, LU L Y, WEI G P, HU P, MO R X, LI Y Y, WU Y Y. Comparison of the cultivation of maize and peanuts by smash-riding and traditional land preparation methods. Journal of Anhui Agricultural Sciences, 2011,39(6):3216-3219. (in Chinese)
[13]	王奇, 陈培赛, 周佳, 周灵芝, 劳承英, 尹昌喜, 韦本辉. 粉垄耕作对甘蔗农艺性状及产量的影响. 江苏农业科学, 2019,47(4):65-68.
	WANG Q, CHEN P S, ZHOU J, ZHOU L Z, LAO C Y, YIN C X, WEI B H. Effects of smash-ridging cultivation on agronomic characters and yield of sugarcane. Jiangsu Agricultural Sciences, 2019,47(4):65-68. (in Chinese)
[14]	韦本辉, 甘秀芹, 申章佑, 宁秀呈, 陆柳英, 韦广泼, 李艳英, 胡泊, 刘斌, 吴延勇. 粉垄栽培甘蔗试验增产效果. 中国农业科学, 2011,44(21):4544-4550.
	WEI B H, GAN X Q, SHEN Z Y, NING X C, LU L Y, WEI G P, LI Y Y, HU P, LIU B, WU Y Y. Yield increase of smash-ridging cultivation of sugarcane. Scientia Agricultura Sinica, 2011,44(21):4544-4550. (in Chinese)
[15]	BAQUERO J E, Ralisch R, Medina C D C, FILHO J T, GUIMARÃES M D F. Soil physical properties and sugarcane root growth in a red oxiso. Revista Brasileira de Ciência do Solo, 2012,36(1):63-70.
[16]	ARRUDA E M, ALMEIDA R F D, DOMINGUES L A D S, JUNIOR A C D S, MORAES E R D, BARROS L R, SOUSA J L D O, LANA R M Q . Soil porosity and density in sugarcane cultivation under different tillage systems. African Journal of Agricultural Research, 2016,11(30):2689-2696.
[17]	OTTO R, SILVA A P, FRANCO H C J, OLIVEIRA E C A, TRIVELIN P C O. High soil penetration resistance reduces sugarcane root system development. Soil & Tillage Research, 2011,117:201-210.
[18]	鲍士旦. 土壤农化分析. 第三版. 北京: 中国农业出版社, 2000.
	BAO S D. . Soil Agrochemical Analysis. 3rd edition. Beijing: China Agriculture Press, 2000. (in Chinese)
[19]	高俊凤. 植物生理学实验指导. 北京: 高等教育出版社, 2006.
	GAO J F. Plant Physiology Experiment Guide. Beijing: Higher Education Press, 2006.(in Chinese)
[20]	叶尚红. 植物生理生化实验教程. 第2版. 昆明: 云南科技出版社, 2007: 212.
	YE S H. Plant Physiology and Biochemistry Experiment Course. 2th edition. Kunming: Yunnan Science and Technology Press, 2007: 212(in Chinese)
[21]	褚光, 刘洁, 张耗, 杨建昌. 超级稻根系形态生理特征及其与产量形成的关系. 作物学报, 2014,40(5):850-858.
	CHU G, LIU J, ZHANG H, YANG J C. Morphology and physiology of roots and their relationships with yield formation in super rice. Acta Agronomica Sinica, 2014,40(5):850-858. (in Chinese)
[22]	杨建昌. 水稻根系形态生理与产量、品质形成及养分吸收利用的关系. 中国农业科学, 2011,44(1):36-46.
	YANG J C. Relationships of rice root morphology and physiology with the formation of grain yield and quality and the nutrient absorption and utilization. Scientia Agricultura Sinica, 2011,44(1):36-46. (in Chinese)
[23]	YAO Y Z. Effects of ridge tillage on photosynthesis and root characters of rice. Chilean Journal of Agricultural Research, 2015,75(1):35-41.
[24]	HAWES M C, GUNAWARDENA U, MIYASAKA S, ZHAO X W. The role of root border cells in plant defense. Trends in Plant Science, 2000,5(3):128-133. doi: 10.1016/s1360-1385(00)01556-9 pmid: 10707079
[25]	ZHAI L C, XU P, ZHANG Z B, WEI B H, JIA X L, ZHANG L H. Improvements in grain yield and nitrogen use efficiency of summer maize by optimizing tillage practice and nitrogen application rate. Agronomy Journal, 2019,111(2):666-676.
[26]	HERMAN E M, LARKINS B A. Protein storage bodies and vacuoles. The Plant Cell, 1999,11(4):601-613. doi: 10.1105/tpc.11.4.601 pmid: 10213781
[27]	李志霞, 秦嗣军, 吕德国, 聂继云. 植物根系呼吸代谢及影响根系呼吸的环境因子研究进展. 植物生理学报, 2011,47(10):957-966.
	LI Z X, QIN S J, LÜ D G, NIE J Y. Research progress in root respiratory metabolism of plant and the environmental influencing factors. Plant Physiology Journal, 2011,47(10):957-966. (in Chinese)
[28]	SHUKLA S K, YADAV R L, GUPTA R, SINGH A K, AWASTHI S K, GAUR A. Deep tillage, soil moisture regime, and optimizing N nutrition for sustaining soil health and sugarcane yield in subtropical india. Communications in Soil Science and Plant Analysis, 2018,49(4):444-462.
[29]	WASAYA A, TAHIR M, MANAF A, AHMED M, KALEEM S, AHMAD I. Improving maize productivity through tillage and nitrogen management. African Journal of Biotechnology, 2011,10(82):19025-19034.
[30]	郑俊鶱, 孙艳, 韩寿坤, 张浩. 土壤紧实胁迫对黄瓜根系呼吸代谢的影响. 应用生态学报, 2013,24(3):741-746.
	ZHENG J X, SUN Y, HAN S K, ZHANG H. Effects of soil compaction stress on respiratory metabolism of cucumber root. Chinese Journal of Applied Ecology, 2013,24(3):741-746. (in Chinese)
[31]	SURENDRAN U, RAMESH V, JAYAKUMAR M, MARIMUTHU S, SRIDEVI G. Improved sugarcane productivity with tillage and trash management practices in semi arid tropical agro ecosystem in India. Soil & Tillage Research. 2016,158:10-21.

种植方式 Planting method	处理 Treatment	碱解氮 Available N (mg·kg^-1)	速效磷 Available P (mg·kg^-1)	速效钾 Available K (mg·kg^-1)
新植蔗 New planting sugarcane	CK	291.67±5.83b	11.11±0.26b	714.03±14.28a
新植蔗 New planting sugarcane	粉垄 Fenlong	317.00±61.36a	13.10±1.10a	715.80±28.21a
宿根蔗 Stubble cane	CK	352.00±4.90b	10.84±0.24b	588.51±11.77a
宿根蔗 Stubble cane	粉垄 Fenlong	388.67±12.21a	13.61±0.90a	568.65±82.31a

种植方式 Planting method	处理 Treatment	出苗率 Seedling rate (%)	分蘖率 Tillering rate (%)	株高 Plant height (cm)	茎径 Stem diameter (cm)	单茎重 Single stem weight (kg/plant)	有效茎 Effective stems (plant/hm²)	产量 Yield (kg·hm^-2)	甘蔗糖分 Sugar content (%)
新植蔗 New planting sugarcane	CK	32.0±1.03b	51.20±1.25b	295.0±2.57b	2.56±0.03b	1.83±0.06a	61477±91b	109814±2252b	13.86±0.33b
新植蔗 New planting sugarcane	粉垄Fenlong	40.0±0.89a	60.10±2.01a	334.0±2.31a	3.01±0.08a	2.36±0.08b	64719±102a	130555±3539a	15.50±0.45a
宿根蔗 Stubble cane	CK	17.3±2.20b	56.40±9.50a	251.9±2.80b	2.39±0.90b	1.28±0.06b	41520±75b	82589±1360b	15.20±0.60a
宿根蔗 Stubble cane	粉垄Fenlong	22.6±2.30a	63.00±7.90a	271.2±5.60a	2.92±0.50a	2.18±0.04a	49274±98a	93257±1718a	15.80±0.10a

种植方式 Planting method	生长期 Growth period	处理 Treatment	根长 Root length (cm)	根表面积 Root surface area (cm²)	根直径 Root diameter (mm)	根体积 Root volume (cm³/plant)	根尖数 Total root (No./plant)	根鲜重 Root fresh weight (g/plant)	根干重 Root dry matter (g/plant)
新植蔗 New planting sugarcane	苗期 Seeding stage	CK	13.64±1.21b	139.87±12.21b	0.70±0.021b	12.17±0.41b	3730.78±52.21b	10.94±0.22b	2.38±0.26b
	苗期 Seeding stage	粉垄Fenlong	18.20±1.41a	170.29±9.21a	0.93±0.041a	16.22±0.33a	6030.23±32.01a	16.69±0.71a	3.80±0.31a
	伸长期 Elongation stage	CK	22.73±2.21b	263.90±2.21b	1.33±0.02b	22.95±0.53b	7039.20±56.02b	20.65±0.12b	4.49±0.02b
	伸长期 Elongation stage	粉垄Fenlong	32.34±1.31a	321.30±12.11a	1.75±0.03a	30.60±1.21a	11377.80±39.02a	33.94±0.32a	6.28±0.03a
	成熟期 Mature stage	CK	30.73±2.21b	377.02±25.00b	1.90±0.02b	32.79±3.50b	10056.00±102.00b	29.50±1.50b	6.42±0.31b
	成熟期 Mature stage	粉垄Fenlong	40.34±1.23a	459.13±21.00a	2.50±0.03a	43.72±2.41a	16254.00±145.00a	44.21±1.10a	12.54±0.41a
宿根蔗 Stubble cane	苗期 Seeding stage	CK	20.64±1.21b	517.43±84.00a	0.65±0.10a	27.99±5.46b	1085.24±5.46b	13.94±0.32b	3.38±0.36b
	苗期 Seeding stage	粉垄Fenlong	28.20±1.41a	685.73±63.00a	0.73±0.05a	41.48±5.45a	1285.87±5.45a	18.69±0.81a	4.80±0.39a
	伸长期 Elongation stage	CK	36.73±2.21b	738.17±105.78b	0.93±0.11b	38.47±5.47b	1527.08±37.57b	25.65±0.32b	5.49±0.22b
	伸长期 Elongation stage	粉垄Fenlong	48.34±1.31a	1211.47±169.42a	1.59±0.18a	65.79±9.02a	2182.17±30.92a	38.94±0.52a	7.28±0.23a
	成熟期 Mature stage	CK	50.73±2.21b	1454.72±206.73b	1.63±0.21b	58.16±14.05b	2555.17±68.77b	32.50±0.50b	8.42±0.41b
	成熟期 Mature stage	粉垄Fenlong	61.34±1.23a	1788.26±129.18a	1.91±0.17a	80.35±7.09a	2719.78±66.23a	41.21±0.56a	12.54±0.61a

种植方式 Planting method	处理 Treatment	根毛平均长度 Average lenghth of root hair (mm)	根毛密度 Root hair density (ind/mm²)	单位面积根毛总长度 Total length of root per area (mm)	线粒体数目 Mitochondria number (No./cell)
新植蔗 New planting sugarcane	CK	0.15±0.01b	110.36±2.23b	18±0.15b	16±0.52b
新植蔗 New planting sugarcane	粉垄Fenlong	0.23±0.02a	190.94±0.94a	38±0.12a	22±0.32a
宿根蔗 Stubble cane	CK	0.18±0.02b	92.36±2.23a	23±0.15b	13±0.42b
宿根蔗 Stubble cane	粉垄Fenlong	0.25±0.01a	180.94±0.94a	42±0.12a	20±0.42a