Cold stratification in winter is more than enough for seed dormancy-break of summer annuals in eastern North America: implications for climate change

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Carol C. Baskin, Jerry M. Baskin
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Abstract

Germination of seeds of some summer annuals in Kentucky (eastern USA) in late-winter lead to the hypothesis that under present climate conditions the whole length of the winter cold stratification (CS) period is not required for dormancy-break of seeds of summer annuals with physiological dormancy (PD). We evaluated our data from germination phenology studies of 45 species (69 datasets) and buried-seed studies of 33 species (44 datasets). We determined time and temperature of germination after CS and percentage of the total number of hours of CS during winter (% of winter CS) seeds received prior to start of germination. In the phenology studies, mean temperature during the week of first germination for C3 and C4 species was 11.1 and 14.4°C, respectively, and % of winter CS was 80.8 and 87.4, respectively. In the buried-seed studies, % of CS for C3 and C4 species was 40.8 and 48.1, respectively, when they germinated to 25% at 20/10°C. For 32 of 33 species in the buried-seed studies, the minimum temperature at which seeds germinated decreased with increased CS; thus, seeds had Type 2 non-deep PD. The time of germination is controlled by a number of hours of CS, a decrease in minimum temperature at which seeds can germinate and a temperature increase in early spring. Seeds can germinate at relatively high temperatures as early as December and January, but they continue to be CS until spring. Temperature increases in eastern North America due to global warming are not likely to inhibit the germination of summer annuals with PD in spring.

冬季的冷分层足以使北美东部夏季一年生植物的种子休眠:对气候变化的影响
美国东部肯塔基州一些夏季一年生植物的种子在冬末萌发,提出了在当前气候条件下,具有生理休眠(PD)的夏季一年生植物的种子不需要整个冬季冷分层(CS)期的休眠。我们对45个物种(69个数据集)的萌发物候研究和33个物种(44个数据集)的埋种研究数据进行了评估。我们测定了萌发后的萌发时间和温度,以及在萌发开始前收到的种子在冬季的总萌发时数(占冬季萌发时数的百分比)。在物候学研究中,C3和C4种首次萌发周的平均温度分别为11.1°C和14.4°C,冬季CS的%分别为80.8%和87.4。在埋种研究中,当C3和C4在20/10℃萌发至25%时,CS的百分比分别为40.8%和48.1%。33种植物中有32种种子萌发的最低温度随CS的增加而降低;因此,种子具有2型非深部PD。发芽时间受日照时数、种子萌发最低温度的降低和早春温度的升高所控制。种子可以在相对较高的温度下发芽,早在12月和1月,但它们一直持续到春天。由于全球变暖,北美东部的气温升高不太可能抑制春季PD的夏季一年生植物的发芽。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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