喜马拉雅鸭茅野生二倍体与同源四倍体农艺性状的对比研究

doi:10.11686/cyxb2015221

摘要/Abstract

摘要： 本研究对供试的喜马拉雅野生二倍体鸭茅及其同源四倍体鸭茅进行单株和条播种植,旨在获得不同倍性水平鸭茅农艺性状特性。结果表明,喜马拉雅野生二倍体具有营养生长期比同源四倍体长,后期生长迅速,生育期比同源四倍体长的特点;同源四倍体各构件中的叶量(P<0.01)和单株产量(P<0.05)明显地高于同期喜马拉雅野生二倍体鸭茅。随着倍性的增加,增加了分蘖数、生殖枝数和千粒重,但是生殖枝所占的比重、穗量、种子数、发芽势和发芽率均降低,导致同源四倍体的育性不及喜马拉雅野生二倍体鸭茅。在干物质产量方面,同源四倍体每次刈割的产量和年干物质产量比喜马拉雅野生二倍体鸭茅分别提高20.3%~72.8%和18.3%~41.5%,枯草比例下降23.9%。从供草的均衡分析,同源四倍体供草均衡性优于喜马拉雅野生二倍体。在饲草营养价值方面,不论野生二倍体还是同源四倍体,随着成熟度的增加,粗蛋白、粗脂肪、灰分、钙含量、磷含量和半纤维素含量明显下降,中性洗涤纤维、酸性洗涤纤维和酸性木质素增加,而且随着倍性水平增加,同期生长不同倍性鸭茅的各营养成分增减不一,尤以完熟期的鸭茅随倍性水平的增加,钙含量明显地增加。

Abstract: An experiment has been conducted using single and drill planting methods on the wild diploid Dactylis glomerata subsp. Himalayensis and its autotetraploid in order to compare the agronomic traits of different ploidy cocksfoot. The results showed that the vegetative growth stage of wild diploid cocksfoot was longer than the autotetraploid type and that it grew rapidly at later stages. The yields of leaf and single plants in each component of autotetraploid were significantly higher than wild diploid cocksfoot at the same stage (P<0.05). With the increase of ploidy, the number of tillers, reproductive branches and 1000 seed weights increased, while the percentage of reproductive branch, spike yield, number of seeds, germination potential and germination rate decreased. Autotetraploid fertility is thus not as strong as that of the wild diploid. In terms of dry matter, autotetraploid yields from each cutting and total annual output were 20.3%-72.8% and 18.3%-41.5% respectively, which were higher than those of the wild diploid, but yields of withered grass dropped 23.9%, which was lower than that of wild diploid. Based on equilibrium analysis, autotetraploid forage balance was better than the wild diploid. In terms of nutritive value, crude protein, crude fat, ash, contents of calcium, phosphorus and hemicelluloses for both the wild diploid and its autotetraploid decreased significantly with increased maturity, while neutral detergent fiber, acid detergent fiber and acid lignin increased. With increasing ploidy levels, the percentages of nutritional components fluctuated unevenly during the growth period, with only calcium contents increasing significantly after maturity.

黄梅芬, 薛世明, 高月娥, 李乔仙, 张美艳, 余梅, 钟声. 喜马拉雅鸭茅野生二倍体与同源四倍体农艺性状的对比研究[J]. 草业学报, 2016, 25(1): 207-216.

HUANG Mei-Fen, XUE Shi-Ming, GAO Yue-E, LI Qiao-Xian, ZHANG Mei-Yan, YU Mei, ZHONG Sheng. Comparison of agronomical traits between the wild diploid and its autotetraploid in the Dactylis glomerata subsp. Himalayensis[J]. Acta Prataculturae Sinica, 2016, 25(1): 207-216.

参考文献

[1] Wang W X, Meng X H, Zhang Z H, et al . Technical Manual of Grassland Production[M]. Lanzhou: Gansu Science and Technology Press, 1992: 225-226.
[2] Hirata M, Yuyaman, Cai H W. Isolation and characterization of simple sequence repeat markers for the tetraploid forage grass Dactylis glomerata . Plant Breeding, 2011, 130: 503-506.
[3] Holmes W. Production and Utilization of Grassland[M]. Tang W Q, interpretation. Urumchi: Xinjiang People’s Press, 1986: 107.
[4] Jia S X. Forage Floras of China (Volume 1)[M]. Beijing: Agriculture Press, 1987: 69-73.
[5] Zhang X Q, Du Y, Zheng D C, et al . Karyotype analysis of Dactylis glomerata L. grassland of China, 1994, (3): 55-57.
[6] Lindner R, Garci A. Genetic differences between natural populations of diploid and tetraploid Dactylis glomerata spp. izcoi. Grass and Forage Science, 1997, 52(3): 291-297.
[7] Lumaret R, Barrientos E. Phylogenetic relationships and gene flow between sympatric diploid and tetraploid plants of Dactylis glomerata (Gramineae). Plant Systematics and Evolution, 1990, 169: 1-2, 81-96.
[8] Ortiz S, Rodriguez, Oubina J. Dactylis glomerata subsp. Izcoi, a new subspecies from Galicia NW Iberian peninsula. Annales Botanici Fennici, 1993, 30: 4, 305-311.
[9] Falistocco E, Caceres M E, Falcinelli M. Meiotic mechanisms of 2n pollen formation in Dactylis glomerata subsp. Lusitanica. Journal of Genetics and Breeding, 1994, 48: 1, 41-45.
[10] Maceira N O, Jacquard P, Lumaret R. Competition between diploid and derivative autotetraploid Dactylis glomerata L. from Galicia. Implication for the establishment of novel polyploidy populations. New Phytologist, 1993, 124: 321-328.
[11] Borrill M, Lindner R. Diploid-tetraploid sympatry in Dactylis (Gramineae). New Phytologist, 1971, 70: 1111-1124.
[12] Lumaret R, Bowman C M, Dyer T A. Autotetraploidy in Dactylis glomerata L.: Further evidence from studies of chloroplast DNA variation. Theoretical and Applied Genetics, 1989, 78: 393-399.
[13] Wu Q J. Wild Herbage Atlas of Guizhou Province[M]. Guiyang: Guizhou People’s Publishing House, 1986.
[14] Fujimoto F, Sato S, Gujgnard G, et al . Studies on genetic resources of the genus Dactylis II. Characteristics of populations of Dactylis glomerata L., collected in Morocco and Portugal. Bulletin of National Grassland Research Institute, 1991, 45: 25-42.
[15] Zhong S, Du Y, Zheng D C, et al . A study on agronomic characters of ploids Dactylis glomerata L. Acta Agrestia Sinica, 1997, 5(1): 54-61.
[16] Zhou Z W, Kui J X, Zhong S, et al . Karyotype analysis of wild Dactylis glomerata L. in Yunnan. Pratacultural Science, 2000, 17(6): 48-51.
[17] Wetschnig W. Karyotype morphology of some diploid subspecies of Dactylis glomerata L.(Poaceae). Annales Rei Botanicae, 1991, 31: 35-55.
[18] Lumaret R. Doubled duplication of the structural gene for cytosolic phosphoglucose isomerase in the Dactylis glomerata L. polyploid complex. Molecular Biology and Evolution, 1986, 3(6): 499-521.
[19] Sato T, Maceira N, Lumaret R, et al . Flowering characteristics and fertility of interploidy progeny from normal and 2n gametes in Dactylis glomerata L. New Phytologlist, 1993, 124: 309-319.
[20] Fujimoto F. Genetic resources of orchardgrass ( Dactylis glomerata L.) and related subspecies from warmer regions. Japan Agricultural Research Quarterly, 1993, 27: 106-111.
[21] Guignard G, Fujimoto F, Yamaguchi H. Studies on genetic resources of genus Dactylis I Characteristics of several subspecies and CHIAS chromosome image analysis of subsp. Himalayesis Domin. Bulletin of National Grassland Research Institute, 1991, 45: 11-23.
[22] Lumaret R. Cytology, genetics, and evolution in the genus Dactylis . Critical Reviews in Plants Science, 1988, 7(1): 55-91.
[23] Editorial Committee of Flora of China, Chinese Academy of Sciences. The Flora of Chinese (The First Edition)[M]. Beijing: Chinese Science Press, 2002: 90.
[24] Zhong S, Du Y, Zheng D C, et al . A study on agronomic characters of tetraploids Dactylis glomerata . Pratacultural Science, 1998, 8(2): 20-23.
[25] Zhang X Q, Du Y, Zheng D C. Study on biological property in diploid and tetraploid of Dactylis glomerata . Journal of Sichuan Agricultural University, 1996, 14(2): 202-206.
[26] Zeng B, Lan Y, Wu L. The rust resistance research of Chinese natural orchardgrass germplasm. Journal of Plant Genetic Resources, 2010, 11(3): 278-283.
[27] Peng Y, Zhang X Q, Zeng B. A study on variations of morphologic features of Dactylis glomerata L. Acta Prataculturae Sinica, 2007, 16(2): 69-75.
[28] Jiang L F, Zhang X Q, Huang L K, et al . Analysis of genetic diversity in a cocksfoot( Dactylis glomerata ) variety using SCoT markers. Acta Prataculturae Sinica, 2014, 23(1): 229-238.
[29] Zhong S. Study on crossing of different ploidy of Dactylis glomerata . Southwest China Journal of Agricultural Science, 2006, 19(6): 1034-1038.
[30] Han J G. Practical Forage Seed Science[M]. Beijing: China Agricultural University Press, 1997: 133-142.
[31] Lumaret R. Polyploidy and habits differentiation in Dactylis glomerata L. from Galicia(Spain). Oecologia, 1987, 173(3): 436-446.
[32] Huang Q C, Sun J S. Prospects for the plant polyploidy in crop breeding. Science and Technology Review, 1997, (7): 50, 53-55.
[33] Yang Y H. General Genetics[M]. Beijing: Higher Education Press, 2000: 150-156.
[34] Huang Q C. Progress of apomixes in poaceae. Journal of Wuhan Botanical Research, 1999, 17(Suppl.): 39-44.
[35] Bretagnolle F, Lumaret R. Bilateral polyploidization in Dactylis glomerata L. subsp. lusitanica: occurrence, morphological and genetic characteristics of first polyploids. Euphytica, 1995, 84: 197-207.
[36] Zhang X Q. High Quality Forage-Exploration, Innovation and Utilization of Orchardgrass Germplasm[M]. Beijing: Science Press House, 2015.
[37] Wang S M, Hu S L, Zhang B, et al . The study on hay yield and nutrition of alfalfa cultivars. Acta Agriculturae Boreali-occidentalis Sinica, 2004, 13(1): 14-17.
[38] Mizuno K. Studies on palatability in varieties of orchardgrass( Dactylis glomerata L.). Research Report of Pasture Trial Station, 1999, 58: 61-121.
[1] 汪王玺, 孟宪汉, 张自和, 等. 草业生产技术手册[M]. 兰州: 甘肃科学技术出版社, 1992: 225-226.
[3] Holmes W. 草地生产及其利用[M]. 唐文青, 译. 乌鲁木齐: 新疆人民出版社, 1986: 107.
[4] 贾慎修.中国饲用植物志(第一卷)[M]. 北京: 农业出版社, 1987: 69-73.
[5] 张新全, 杜逸, 郑德成, 等. 鸭茅染色体核型分析. 中国草地, 1994, (3): 55-57.
[13] 吴启进. 贵州省主要野生牧草图谱[M]. 贵阳: 贵州人民出版社, 1986.
[15] 钟声, 杜逸, 郑德成, 等. 二倍体鸭茅农艺性状的初步研究. 草地学报, 1997, 5(1): 54-61.
[16] 周自玮, 奎嘉祥, 钟声, 等. 云南野生鸭茅核型分析. 草业科学, 2000, 17(6): 48-51.
[23] 中国科学院中国植物志编辑委员会.中国植物志(第一版)[M]. 北京: 中国科学出版社, 2002: 90.
[24] 钟声, 杜逸, 郑德成, 等. 野生四倍体鸭茅农艺性状的初步研究. 草业科学, 1998, 8(2): 20-23.
[25] 张新全, 杜逸, 郑德成. 鸭茅二倍体和四倍体生物学特性的研究. 四川农业大学学报, 1996, 14(2): 202-206.
[26] 曾兵, 兰英, 伍莲. 中国野生鸭茅种质资源锈病抗性研究. 植物遗传资源学报, 2010, 11(3): 278-283.
[27] 彭燕, 张新全, 曾兵. 野生鸭茅植物学形态特征变异研究. 草业学报, 2007, 16(2): 69-75.
[28] 蒋林峰, 张新全, 黄林凯, 等. 鸭茅品种的SCoT遗传变异分析. 草业学报, 2014, 23(1): 229-238.
[29] 钟声. 鸭茅不同倍性杂交后代发育特性的初步研究.西南农业学报, 2006, 19(6): 1034-1038.
[30] 韩建国. 实用牧草种子学[M]. 北京: 中国农业大学出版社. 1997: 133-142.
[32] 黄群策, 孙敬三. 植物多倍体在作物育种中的展望. 科技导报, 1997, (7): 50, 53-55.
[33] 杨业华. 普通遗传学[M]. 北京: 高等教育出版社, 2000: 150-156.
[34] 黄群策. 禾本科植物无融合生殖的研究进展. 武汉植物学研究, 1999, 17(增刊): 39-44.
[36] 张新全. 优质牧草-鸭茅种质资源发掘及创新利用研究[M]. 北京: 科学出版社, 2015.
[37] 万素梅, 胡守林, 张波,等. 不同紫花苜蓿品种产草量及营养成分研究. 西北农业学报,2004 ,13(1): 14-17.
[38] 水野和彦. オーチャードグラス( Dactylis glomerata L.)における品種の嗜好性に関する育種学的研究.草地試験場研究報告, 1999, 58: 61-121.