基于Thermal Time模型预测高加索三叶草花序生长和花期发展

doi:10.11733/j.issn.1007-0435.2025.03.019

草地学报 ›› 2025, Vol. 33 ›› Issue (3): 850-858.DOI: 10.11733/j.issn.1007-0435.2025.03.019

• 研究论文 • 上一篇

基于Thermal Time模型预测高加索三叶草花序生长和花期发展

张慧敏¹, 王明玖¹, 提忠慧¹, 刘嘉伟², 曹克璠¹, 马一鸣¹

1. 内蒙古农业大学草业学院, 内蒙古呼和浩特 010020;
2. 内蒙古自治区农牧业科学院, 内蒙古呼和浩特 010031

收稿日期:2024-05-15 修回日期:2024-08-03 发布日期:2025-04-07
通讯作者: 王明玖,E-mail:wangmj_0540@163.com
作者简介:张慧敏（1995-）,女,汉族,内蒙古巴彦淖尔人,博士研究生,主要从事牧草遗传育种研究,E-mail：zhanghm0927@163.com
基金资助:
国家自然科学基金项目（32160334）;国家留学基金委资助

Prediction of Inflorescence Growth and Flowering Development in Caucasian Clover Based on Thermal Time Model

ZHANG Hui-min¹, WANG Ming-jiu¹, TI Zhong-hui¹, LIU Jia-wei², CAO Ke-fan¹, MA Yi-ming¹

1. College of Grassland Science, Inner Mongolia Agricultural University, Hohhot, Inner Mongolia 010020, China;
2. Inner Mongolia Academy of Agricultural and Animal Husbandry Sciences, Hohhot, Inner Mongolia 010031, China

Received:2024-05-15 Revised:2024-08-03 Published:2025-04-07

摘要/Abstract

摘要： Thermal time模型认为植物需要高于基准温度（Base temperature, T_b）累积固定量的热效应（Thermal time, T_t）来完成特定的发育阶段,低于T_b或未达到固定量的T_t,不发生发育阶段的转化。本文在中国青藏高原、内蒙古高原、东北平原和新西兰坎特伯雷平原设置5个试验区,以高加索三叶草（Trifolium ambiguum Bieb.）为研究对象,观测单个花序发育速率和种群开花进展速率。基于试验区温度,运用Thermal time模型预测花序生长和花期进展,旨在量化花序开放和花期推进所需的热量条件,以此指导高加索三叶草饲草利用和种子生产。结果表明,高加索三叶草从现蕾发育到最大花序尺寸约需在2℃以上累积25℃·d；从始花期到盛花期需在7.5℃以上累积635℃·d；从盛花期到结实期存在地形差异,高原地区需在8.7℃以上累积1813℃·d,平原地区需在3℃以上累积1290℃·d。在高原地区高加索三叶草更适合饲草利用,在平原地区有种子生产利用的潜质。

关键词: 高加索三叶草, 温度, 基温, 花期, 热效应

Abstract: The Thermal time model assumes that plants require a cumulative fixed amount of thermal time （T_t） above a base temperature （T_b） to complete a specific developmental stage and that no developmental stage transformation occurs below T_b or not reaching a cumulative fixed amount of T_t. A total of five experimental sites were established on the Tibetan Plateau, the Inner Mongolian Plateau, and the Northeastern Plain, China, and the Canterbury Plain, New Zealand to observe the development rate of individual inflorescence and the rate of flowering progress in populations of Caucasian Clover （Trifolium ambiguum Bieb.）. Thermal time model was applied to predict inflorescence growth and flower development based on the temperatures in the trial areas, with the aim of quantifying the thermal conditions required for inflorescence opening and flower development as a guide for Caucasian clover forage use and seed production. The results showed that from flower bud to maximum inflorescence size required accumulating 25℃·d above 2℃, and 635℃·d above 7.5 ℃ was required from initial flowering to full flowering. There were topographic differences from full flowering stage to seed setting stage, with 1813℃·d above 8.7℃ in the plateau region, and 1290℃·d above 3℃ in the plain regions, which makes Caucasian clover more suitable for forage use in the plateau regions and seed production in the plain regions.

Key words: Caucasian clover, temperature, Base temperature, Flowering stage, Thermal time

中图分类号:

S314

张慧敏, 王明玖, 提忠慧, 刘嘉伟, 曹克璠, 马一鸣. 基于Thermal Time模型预测高加索三叶草花序生长和花期发展[J]. 草地学报, 2025, 33(3): 850-858.

ZHANG Hui-min, WANG Ming-jiu, TI Zhong-hui, LIU Jia-wei, CAO Ke-fan, MA Yi-ming. Prediction of Inflorescence Growth and Flowering Development in Caucasian Clover Based on Thermal Time Model[J]. Acta Agrestia Sinica, 2025, 33(3): 850-858.

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参考文献

[1] BERENJI S,MOOT D J,MOIR J L,et al. Dry matter yield, root traits, and nodule occupancy of lucerne and Caucasian clover when grown in acidic soil with high aluminium concentrations[J]. Plant and Soil,2017,416(1):227-241
[2] ALEXANDER J R,VENTEREA R T,BAKER J M,et al. Kura clover living mulch:spring management effects on nitrogen[J]. Agronomy,2019,9(2):69
[3] 鲍根生,张鹏,马祥,等.高寒区氮添加对禾豆间作系统牧草和种子产量的影响[J].草地学报,2023,31(7):2210-2219
[4] 何瑞,闫芳,祝睿彦,等.唐古特瑞香开花物候及繁育系统研究[J].草地学报,2024,32(1):188-197
[5] ZHENG Y J,YANG Z,XU C, et al. The interactive effects of daytime high temperature and humidity on growth and endogenous hormone concentration of tomato seedlings[J]. HortScience,2020,55(10):1575-1583
[6] FRAGOSO-JIMENEZ J C, SILVA-MORALES J, BARBA-GONZALEZ R, et al. Temperature effects on meristem differentiation and flowering date in tuberose (Agave amica L.)[J]. Scientia Horticulturae,2021,275:109663
[7] ZHANG S,DAI J,GE Q. Responses of autumn phenology to climate change and the correlations of plant hormone regulation[J]. Scientific Reports,2020,10(1):9039
[8] PARRA-CORONADO A, FISCHER G, FISCHER G, et al. Growth model of the pineapple guava fruit as a function of thermal time and altitude[J]. Ingeniería e Investigación,2016,36(3):6-14
[9] IANNUCCI A, TERRIBILE M R, MARTINIELLO P. Effects of temperature and photoperiod on flowering time of forage legumes in a Mediterranean environment[J]. Field Crops Research,2008,106(2):156-162
[10] 孙佳,王磊,万胜,等.南疆不同产地红枣品质差异及其与气候因子的关系[J].经济林研究,2023,41(3):278-285
[11] 徐博,王英哲,徐安凯,等.基于生长度日的紫花苜蓿生育期预测模型[J].草业科学,2016,33(1):93-100
[12] 陈艳玲,顾晓鹤,董燕生,等.利用有效积温提高冬小麦估产精度的研究[J].麦类作物学报,2014,34(8):1130-1135
[13] LONATI M,MOOT D J,ACETO P,et al. Thermal time requirements for germination, emergence and seedling development of adventive legume and grass species[J]. New Zealand Journal of Agricultural Research,2009,52(1):17-29
[14] POWERS J S. Consequences of elevated temperature on prairie plants:legumes, nitrogen, and phenology[D]. Twin Cities, University of Minnesota,2012:40-47
[15] VÂRBAN R,ONA A,STOIE A, et al. Phenological assessment for agronomic suitability of some agastache species based on standardized BBCH Scale[J]. Agronomy,2021,11(11):2280
[16] ANGUS J F, CUNNINGHAM R B, MONCUR M W, et al. Phasic development in field crops I. Thermal response in the seedling phase[J]. Field Crops Research,1980(3):365-378
[17] BLACK A D, MOOT D J, LUCAS R J. Seedling development and growth of white clover, caucasian clover and perennial ryegrass grown in field and controlled environments[C]//Proceedings of the New Zealand Grassland Association. New Zealand:Academic Press,2002:197-204
[18] HADLEY P, ROBERTS E H, SUMMERFIELD R J, et al. Effects of temperature and photoperiod on flowering in Soya bean[Glycine max(L.) Merrill]:a quantitative model[J]. Annals of Botany,1984,53(5):669-681
[19] BLACK A D, MOOT D J, LUCAS R J. Development and growth characteristics of Caucasian and white clover seedlings, compared with perennial ryegrass[J]. Grass and Forage Science,2006,61(4):442-453
[20] 陈祥,魏臻武,任海龙,等.光周期与种质特性对南苜蓿初花期的影响[J].中国草地学报,2016(2):34-40
[21] 郝敦元,高霞,刘钟龄,等.内蒙古草原生态系统健康评价的植物群落组织力测定[J].生态学报,2004,24(8):1671-1677
[22] GUY B R. "Endura" Caucasian clover:progress towards commercial seed production[C]//Proceedings of the New Zealand Grassland Association. New Zealand:Academic Press, 1996:195-197
[23] 姜华,毕玉芬,何承刚,等.苜蓿授粉机理及其与传粉昆虫的关系[J].草业科学,2003,20(1):1-6
[24] 万海霞,邓洪平,何平,等.濒危植物丰都车前的繁育系统与传粉生物学研究[J].生态学报,2018,38(11):4018-4026
[25] 樊文娜,严学兵,史莹华,等.光周期与温度对紫花苜蓿phyA和phyB mRNA表达的影响[J].草地学报,2011,19(6):975-982
[26] 王力.青藏高原东北部农作物与牧草物候特征及其对气候变化的响应[D].兰州:兰州大学,2018:45-58
[27] WALLACE D H, ENRIQUEZ G A. Daylength and temperature effects on days to flowering of early and late maturing beans (Phaseolus vulgaris L.)[J]. Journal of the American Society for Horticultural Science,1980,105(4):583-591
[28] CHRISTIANSEN J L, JØRNSGÅRD B. Influence of day length and temperature on number of main stem leaves and time to flowering in lupin[J]. Annals of Applied Biology,2002,140(1):29-35

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基于Thermal Time模型预测高加索三叶草花序生长和花期发展

Prediction of Inflorescence Growth and Flowering Development in Caucasian Clover Based on Thermal Time Model

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