沙埋和种子大小对固沙禾草沙鞭的种子萌发与幼苗出土的影响

doi:10.17521/cjpe.2005.0097

摘要/Abstract

摘要：

该文研究了野外条件下不同深度的沙埋对沙鞭(Psammochloa villosa)种子萌发和幼苗出土的影响,以及温室条件下种子大小对不同深度沙埋后的种子萌发和幼苗出土的影响。结果表明,沙埋深度显著影响沙鞭的种子萌发率、幼苗出土率和种子休眠率。沙子表面的种子不能萌发。2 cm的浅层沙埋时的种子萌发率和幼苗出土率最高,1 cm 沙埋的种子萌发率和幼苗出土率次之。沙埋深度超过2 cm之后,沙鞭的种子萌发率和幼苗出土率与沙埋深度呈负相关。2 cm的种子休眠率最低。从2 ~12 cm,种子休眠率随着沙埋深度的增加而增加。在幼苗能够出土的深度(1~6 cm),幼苗首次出土所需的时间随着沙埋深度的增加而延长。种子大小对沙鞭的种子萌发率没有显著影响。但是在深层沙埋(6 cm)时,与小种子相比,大种子产生的幼苗的出土率较高。从2~6 cm,大种子形成的幼苗的茎长度都较长。

关键词: 沙鞭, 沙埋深度, 种子大小, 种子萌发, 幼苗出土, 种子生态学

Abstract:

Sand burial is a common phenomenon in sand dune ecosystems all over the world. Although many studies concerning the effects of sand burial on seed germination and seedling emergence have been conducted in many parts of the world, such studies are rare in China. In the summer of 2003, we studied the effects of sand burial depth (0, 1, 2, 4, 6, 8, 10 and 12 cm) and seed size on seed germination and seedling emergence of Psammochloa villosa, an important psammophyte that establishes on mobile sand dunes in deserts and sandy lands of North China. Seeds were collected in their natural habitat in Mu-Us Sandland, Ordos Plateau, in 2002 and stored at -18 ℃. The average seed mass of P. villosa was (5.51±0.05) mg. Seeds were sorted into 3 groups based on their mass: small (4 - 4.9 mg, mean = (4.489 ± 0.012) mg), medium (5 - 5.9 mg, mean = (5.457 ± 0.012) mg), and large (6 - 6.9 mg, mean = (6.415 ± 0.011) mg). We conducted two experiments, one in the field and the other in a non-heated greenhouse. In the second experiment, burial depth was 1, 2, 4, 6 and 8 cm. Before burial experiments, all seeds were treated with cold stratification in 5 ℃ for 4 weeks in order to break dormancy.
We found that sand burial depth had significant effects on seed germination and seedling emergence ofP. villosa. Experiments revealed that the highest percentage of seeds that germinated and seedlings that emerged occurred at 2 cm burial depth. Few seeds lying on the surface of the sand germinated, and, those that did germinate, could not anchor their roots into the soil and seedlings did not establish successfully. The next greatest germination and emergence percentage occurred at the 1 cm burial depth. The timing of emergence was delayed with deeper burial depth. As burial depth increased from 2 to 12 cm, the percentage of seeds that germinated and emerged declined, a higher number of seeds remained dormant, and the number of days before first emergence increased. As sand burial depth increased, some seeds were able to germinate but the seedlings were not able to emerge possibly because the seeds did not have enough energy. Seedlings that could not emerge, etiolated, died and decomposed in the sand. At all depths, the seeds that could not germinate remained dormant. Possible reasons for sustained dormancy include poor aeration, high sand moisture, low soil temperature, poor O₂ content, higher CO₂ levels in soil and low light intensity. The dormant seeds, which form soil seed banks, are very important for the long-term survival of this species. The dormant seeds can germinate when sand erosion decreases the burial depth and the seeds are exposed to optimal environmental conditions, such as sand depth. However, our experiment revealed that seeds buried at deeper depths had higher mortality rates (15 - 35%). The high mortality might be due to fungal infection, water-soluble germination inhibitors in the seed coat, and an unfavorable microenvironment and low O₂ concentrations.
Seed size did not affect the percentage of seeds that germinated or remained dormant, but had a remarkable effect on the percentage of seedlings that emerged at different sand burial depths. At greater depths (>6 cm), large seeds had higher rates of seedling emergence than medium and small seeds. From 1 to 6 cm depth, the seedling shoots that originated from large seeds were longer than those from small seeds; also, at 2 to 6 cm depth, seedling shoots that originated from medium sized seeds were longer than those from small seeds. Therefore, we suggest larger seeds have ecological advantages in sand dune ecosystems. Larger seeds have a larger endosperm, contain more energy, and thus can emerge from deeper burial depths. This will benefit seedling growth in early stages and help them to successfully establish under extreme desert conditions. Sand burial might be a selective pressure on seed size; therefore, seed polymorphism as an evolutionary strategy can benefit the renewal ofP. villosa populations. In sand dune habitats, P. villosa produced different sizes of seeds that could emerge from different depths of sand burial. The diversity of seed size could enhance opportunities for seedling establishment in this heterogeneous environment allowing plants to respond to different sand burial depths, enhance their ability to adapt to the changing environment, and increase survival.

Key words: Psammochloa villosa, Sand burial depth, Seed size, Seed germination, Seedling emergence, Seed ecology

朱雅娟, 董鸣, 黄振英. 沙埋和种子大小对固沙禾草沙鞭的种子萌发与幼苗出土的影响. 植物生态学报, 2005, 29(5): 730-739. DOI: 10.17521/cjpe.2005.0097

ZHU Ya-Juan, DONG Ming, HUANG Zhen-Ying. EFFECTS OF SAND BURIAL AND SEED SIZE ON SEED GERMINATION AND SEEDLING EMERGENCE OF PSAMMOCHLOA VILLOSA. Chinese Journal of Plant Ecology, 2005, 29(5): 730-739. DOI: 10.17521/cjpe.2005.0097

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链接本文: https://www.plant-ecology.com/CN/10.17521/cjpe.2005.0097

https://www.plant-ecology.com/CN/Y2005/V29/I5/730

图/表 8

图1 不同沙埋深度的沙鞭种子在30 d内的幼苗出土率(平均值±标准误) 8、10和12 cm的幼苗出土率为0

Fig.1 Seedling emergence (Mean ± SE) of Psammochloa villosa's seeds buried in different depths in 30 days Emergence percentage of 8, 10 and 12 cm is 0

图2 沙埋深度对沙鞭的种子萌发率(SG)、幼苗出土率(SE)、种子休眠率(SDo)和种子死亡率(SDe)(平均值±标准误)的影响根据Tukey's 检验,各组之内由不同小写字母标记的值之间的差异是显著的 (p<0.05)

Fig.2 Effects of sand burial on the percentage of seed germination (SG), seedling emergence (SE), seed dormant (SDo) and seed death (SDe) (Mean ± SE) of Psmmochloa villosa In each group, the values followed by different letters in lower case are significantly different (p<0.05), according to Tukey's test

图3 不同深度的沙埋对沙鞭幼苗首次出土所需时间(平均值±标准误)的影响图注同图2

Fig.3 Effects of sand burial on days of first emergence (Mean±SE) of Psammochloa villosa seedling The note see Fig.2

图4 沙埋深度和种子大小对沙鞭的幼苗出土率(平均值±标准误)的影响图注同图2

Fig.4 Effects of sand burial depth and seed size on percentages of seedling emergence (Mean±SE) of Psammochloa villosa The note see Fig.2

表1 沙埋深度和种子大小以及二者的相互作用对沙鞭的幼苗出土率、种子萌发率和种子休眠率的影响的双因素方差分析

Table 1 Two-way ANOVA analysis of effects of burial depth, seed size and their interaction on the percentage of seedling emergence, seed germination and seed dormancy of Psammochloa villosa

变差来源 Source of variation	自由度 df	平方和 SS	均方 MS	F值 F-value	p值 p-value
幼苗出土率 Seedling emergence (%)
沙埋深度Burial depth (cm)	5	10.945	2.189	178.339	<0.001
种子大小Seed size	2	0.132	0.066	5.369	0.007
深度×大小Depth×Size	10	0.159	0.016	1.298	0.255
误差Error	54	0.663	0.012
总和Total	71	11.988
种子萌发率 Seed germination (%)
沙埋深度Burial depth (cm)	5	4.626	0.925	870.736	<0.001
种子大小Seed size	2	0.009	0.005	4.421	0.017
深度×大小Depth×Size	10	0.012	0.001	1.147	0.347
误差Error	54	0.057	0.001
总和Total	71	4.705
种子休眠率 Seed dormancy (%)
沙埋深度Burial depth (cm)	5	7.217	1.443	616.618	<0.001
种子大小Seed size	2	0.016	0.008	3.456	0.039
深度×大小Depth×Size	10	0.013	0.001	0.573	0.828
误差Error	54	0.126	0.002
总和Total	71	7.372
幼苗的茎长度Seedling length (cm)
沙埋深度Burial depth (cm)	3	4 295.757	1 431.9	392.245	<0.001
种子大小Seed size	2	164.210	82.105	22.491	<0.001
深度×大小Depth×Size	6	131.288	21.881	5.994	<0.001
误差Error	423	1 544.184	3.651
总和Total	434	6 135.449

图5 沙埋深度和种子大小对沙鞭的种子萌发率(平均值±标准误)的影响图注同图2

Fig.5 Effects of sand burial depth and seed size on percentages of seed germination (Mean ± SE) of Psammochloa villosa The note see Fig.2

图6 沙埋深度和种子大小对沙鞭的种子休眠率(平均值±标准误)的影响图注同图2

Fig.6 Effects of sand burial depth and seed size on percentages of seed dormancy (Mean ± SE) of Psammochloa villosa The note see Fig.2

图7 沙埋深度和种子大小对沙鞭的幼苗的茎长度(平均值±标准误)的影响图注同图2

Fig.7 Effects of sand burial depth and seed size on seedling length (Mean ± SE) of Psammochloa villosa The note see Fig.2

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