中国特有濒危植物扇蕨的生物生态学特性及其濒危机制初探

doi:10.3724/SP.J.1003.2009.08160

摘要/Abstract

摘要：

扇蕨(Neocheiropteris palmatopedata)目前仅零星分布于我国的四川、贵州和云南, 其种群数量日趋减少, 濒临灭绝, 已被列为国家二级保护植物。我们在对扇蕨的种群生态及群落特征、萌发和生长特性、土壤性质研究的基础上分析了导致其濒危的因素。结果表明: 扇蕨生长在原生性强的常绿阔叶林和针阔混交林下, 在群落中处于受支配的地位。扇蕨的孢子无休眠期, 萌发率较高, 因此孢子萌发不是导致其濒危的原因。但扇蕨在自然条件下完成其生命周期所需时间长,易受自然灾害如旱灾等的影响, 导致孢子成苗率极低。虽然扇蕨萌生能力强,但利用根状茎繁殖不能扩展其分布范围。扇蕨生境土壤化学成分分析结果表明,有机质、有效钙、有效镁、有效硼是影响扇蕨生长发育的关键土壤因子。总之, 扇蕨自身特殊的生物生态学特性使其生存竞争力低是其濒危最主要和最直接的原因,而人类活动导致的生境丧失及相伴的生境片断化加速了这一物种的濒危。

关键词: Neocheiropteris palmatopedata, 生长特性, 孢子萌发, 竞争

Abstract

Neocheiropteris palmatopedata, a rare and endangered species endemic to China, has a scattered distribution only in Sichuan, Guizhou and Yunnan provinces. Declining rapidly in population size and on the verge of extinction, it was listed as a plant of second-class protection in The List of Chinese Urgently Protected Wild Plants. To explore endangerment mechanisms of N. palmatopedata, we investigated its population and community structure, germination and growth characteristics as well as soil properties of its habitat. Our results indicated that N. palmatopedata grew in primary evergreen broad-leaved, and mixed coniferous-broad-leaved forests. It was dominated by other species in the community. Spores germinated without a dormancy period and the germination rate was high, indicating that spore characteristics are not a factor causing its endangerment. However, N. palmatopedata required a long period of time to complete its life cycle under natural conditions. During this period, it was vulnerable to stochastic events such as drought, causing a low seedling survival rate. Although the species shows strong rhizome initiation, population growth is not affected by rhizome propagation. Soil property analysis showed that organic matter, potent Ca and availability of Mg were key factors for growth and development of N. palmatopedata. In conclusion, narrow bioecological characteristics led to lowered survivorship and contribute to the endangerment of N. palmatopedata. Human-induced habitat loss and accompanying habitat fragmentation likely accelerated the endangerment process. Our results could provide a theoretical basis for the effective protection of this species.

Key words: Neocheiropteris palmatopedata, growth characteristics, spore germination, competition

邓亚妮, 成晓, 焦瑜, 陈贵菊 (2009) 中国特有濒危植物扇蕨的生物生态学特性及其濒危机制初探. 生物多样性, 17, 62-68. DOI: 10.3724/SP.J.1003.2009.08160.

Yani Deng, Xiao Cheng, Yu Jiao, Guiju Chen (2009) Bioecological characteristics and endangerment mechanisms of Neocheiropteris palmatopedata, an endangered plant endemic to China. Biodiversity Science, 17, 62-68. DOI: 10.3724/SP.J.1003.2009.08160.

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链接本文: https://www.biodiversity-science.net/CN/10.3724/SP.J.1003.2009.08160

https://www.biodiversity-science.net/CN/Y2009/V17/I1/62

图/表 3

参考文献 14

[1]	Gibby M (1985) Cytological observations on Indian subcontinent and Chinese Dryopteris and Polystichum (Pteridophyta: Dryopteridaceae). Bulletin of the British Museum of Natural History (Botany), 14, 1-42.
[2]	Han JY (韩见宇), Dong Y (董燕) (1997) Reproduction and cultivation of Neocheiropteris palmatopedata. Journal of Chinese Medicinal Materials (中药材), 20, 219-220. (in Chinese with English abstract)
[3]	Heywood VH (1991) Plant conservation and botanic gardens. In: Proceedings of the First Conference of the International Association of Botanical Gardens, Asia Division (eds Kato M, Kawakami S, Shimizu H), pp. 7-13, Japan Association of Botanical Gardens, Tokyo.
[4]	China Plant Specialist Group(2004) Neocheiropteris palmatopedata. In: IUCN 2007. 2007 IUCN Red List of Threatened Species. http://www.iucnredlist.org/search/details.php/46620/ all(2008).
[5]	Lao JC (劳家柽) (1988) Handbook for Soil Agrochemical Analysis (土壤农化分析手册). China Agriculture Press, Beijing. (in Chinese)
[6]	Lin YX (林尤兴), Zhang XC (张宪春), Shi L (石雷), Lu SG (陆树刚) (2000) Flora Reipublicae Popularis Sinicae (中国植物志). Tomus 6. Science Press, Beijing. (in Chinese)
[7]	Li QK (李酋开) (1983) Conventional Analytical Methods for Soil Agricultural Chemistry (土壤农业化学常规分析方法). Science Press, Beijing. (in Chinese)
[8]	Riggs LA (1990) Conserving genetic resources on-site in forest ecosystems. Forest Ecology and Management, 35, 45-68.
[9]	Wang YP (王用平), Zeng LL (曾莉莉), Han JY (韩见宇), Wei DS (魏德生), Wang XY (王筱英), Wang PS (王培善) (1995) An introduction to the rare and endangered pteridophytes in Guizhou Botanical Garden. Guizhou Science (贵州科学), 13(3), 53-55. (in Chinese with English abstract)
[10]	Yang FC (杨逢春), Hu XW (胡新文), You LL (尤丽莉) (2007) Geographical distribution and floristic composition of pteridophytes in Hainan Island. Acta Botanica Yunnanica (云南植物研究), 29, 155-160. (in Chinese with English abstract)
[11]	Yu YF (于永福) (1999) The milestone of the work of protecting wild plant of China: The list of Chinese urgently protected wild plants (the 1st group). Plants (植物杂志), (5), 3-11. (in Chinese)
[12]	Zeng HY (曾汉元), Ding BY (丁炳扬) (2004) Observations on the spore germination and prothallium development of ferns. Journal of Wuhan Botanical Research (武汉植物学研究), 22, 368-371. (in Chinese with English abstract)
[13]	Zhang GF (张光飞), Su WH (苏文华), Shi RL (施荣林), Yan HZ (闫海忠) (2004) Relation between the environmental factors and the photosynthesis of a rare pteridophyte: Neocheiropteris palmatopedata. Journal of Wuhan Botanical Research (武汉植物学研究), 22, 125-128. (in Chinese with English abstract)
[14]	Zhang XC (张宪春) (2001) Endemic and rare ferns in China. Plants (植物杂志), (4), 1-1. (in Chinese)

种群 Population	地点 Locality	海拔 Elevation (m)	坡向 Aspect	生境 Habitat	植被类型 Vegetation type	分布面积Population area (m²)	种群大小 Population size
KM1	云南昆明 Kunming, Yunnan	2,150	阳坡 Sunny	山坡林下 Under hillside woods	常绿阔叶林 Evergreen broad-leaved forest	120-150	180-200
LQ1	云南禄劝 Luquan, Yunnan	1,500	阴坡 Shady	沟边林下 Under woods and beside water ditches	常绿阔叶林 Evergreen broad-leaved forest	30-40	30-50
WD1	云南武定 Wuding, Yunnan	2,200	阴坡 Shady	山坡林下 Under hillside woods	常绿阔叶林 Evergreen broad-leaved forest	30-35	150-180
YR1	云南永仁 Yongren, Yunnan	2,000	阴坡 Shady	山坡林下 Under hillside woods	常绿阔叶林 Evergreen broad-leaved forest	200-250	200-250
YM1	云南易门 Yimen, Yunnan	1,680	半阳坡Half-sunny	山坡林下 Under hillside woods	常绿阔叶林 Evergreen broad-leaved forest	1	3
ML1	云南弥勒 Mile, Yunan	1,950	阴坡 Shady	山坡林下 Under hillside woods	常绿阔叶林 Evergreen broad-leaved forest	40-45	80-100
PZH1	四川攀枝花 Panzhihua, Sichuan	2,200	阴坡 Shady	山坡林下 Under hillside woods	针阔混交林 Mixed coniferous and broad-leaved forest	20-25	30-35
PZH2	四川攀枝花 Panzhihua, Sichuan	2,200	阴坡 Shady	山坡林下 Under hillside woods	针阔混交林 Mixed coniferous and broad-leaved forest	20-25	25-30

种群 Population	地点 Locality	海拔 Elevation (m)	坡向 Aspect	生境 Habitat	植被类型 Vegetation type	分布面积Population area (m²)	种群大小 Population size
KM1	云南昆明 Kunming, Yunnan	2,150	阳坡 Sunny	山坡林下 Under hillside woods	常绿阔叶林 Evergreen broad-leaved forest	120-150	180-200
LQ1	云南禄劝 Luquan, Yunnan	1,500	阴坡 Shady	沟边林下 Under woods and beside water ditches	常绿阔叶林 Evergreen broad-leaved forest	30-40	30-50
WD1	云南武定 Wuding, Yunnan	2,200	阴坡 Shady	山坡林下 Under hillside woods	常绿阔叶林 Evergreen broad-leaved forest	30-35	150-180
YR1	云南永仁 Yongren, Yunnan	2,000	阴坡 Shady	山坡林下 Under hillside woods	常绿阔叶林 Evergreen broad-leaved forest	200-250	200-250
YM1	云南易门 Yimen, Yunnan	1,680	半阳坡Half-sunny	山坡林下 Under hillside woods	常绿阔叶林 Evergreen broad-leaved forest	1	3
ML1	云南弥勒 Mile, Yunan	1,950	阴坡 Shady	山坡林下 Under hillside woods	常绿阔叶林 Evergreen broad-leaved forest	40-45	80-100
PZH1	四川攀枝花 Panzhihua, Sichuan	2,200	阴坡 Shady	山坡林下 Under hillside woods	针阔混交林 Mixed coniferous and broad-leaved forest	20-25	30-35
PZH2	四川攀枝花 Panzhihua, Sichuan	2,200	阴坡 Shady	山坡林下 Under hillside woods	针阔混交林 Mixed coniferous and broad-leaved forest	20-25	25-30

	山坡林下土 Under hillside woods	沟边林下土 Under woods and beside water ditches	栽培腐叶土 Leaf mould for cultivation	红壤 Red soil
pH (水土比2.5: 1)	5.22±0.02^c	6.02±0.02^b	4.23±0.03^d	6.55±0.03^a
有机质 Organic matter (%)	13.77±0.12^b	8.39±0.05^c	36.08±0.06^a	2.47±0.05^d
全氮 Total N (%)	0.48±0.01^b	0.34±0.03^c	0.93±0.01^a	0.13±0.01^d
全磷 Total P (%)	0.11±0^c	0.06±0^d	0.14±0^b	0.17±0^a
全钾 Total K ((mg/kg))	0.53±0^b	1.50±0.01^a	0.23±0^d	0.26±0^c
速效氮 Available N (mg/kg)	132.51±11.70^c	162.70±0.97^b	231.87±3.01^a	126.51±1.30^c
速效磷 Available P (mg/kg)	21.54±1.04^c	35.12±0.66^b	56.77±2.36^a	18.81±0.18^c
速效钾 Available K (mg/kg)	253.17±7.45^b	402.64±6.47^a	404.73±2.97^a	171.62±2.73^c
有效钙 Potent Ca (mg/kg)	3567.23±10.41^b	5871.63±7.35^a	468.96±4.18^d	859.25±1.85^c
有效镁 Available Mg (mg/kg)	415.08±11.15^b	684.50±6.52^a	175.89±0.54^d	199.37±1.11^c
有效锌 Available Zn (mg/kg)	13.17±0.20^b	16.05±0.20^a	16.09±0.20^a	2.24±0.07^c
有效铁 Available Fe (mg/kg)	12.33±0.27^c	16.49±0.22^b	18.71±0.22^a	10.65±0.09^d
有效硼 Available B (mg/kg)	1.93±0.01^b	2.65±0.20^a	1.10±0^c	0.21±0.01^d
有效硫 Available S (mg/kg)	30.61±0.61^b	17.61±0.30^c	13.85±0.12^d	35.48±0.44^a

	山坡林下土 Under hillside woods	沟边林下土 Under woods and beside water ditches	栽培腐叶土 Leaf mould for cultivation	红壤 Red soil
pH (水土比2.5: 1)	5.22±0.02^c	6.02±0.02^b	4.23±0.03^d	6.55±0.03^a
有机质 Organic matter (%)	13.77±0.12^b	8.39±0.05^c	36.08±0.06^a	2.47±0.05^d
全氮 Total N (%)	0.48±0.01^b	0.34±0.03^c	0.93±0.01^a	0.13±0.01^d
全磷 Total P (%)	0.11±0^c	0.06±0^d	0.14±0^b	0.17±0^a
全钾 Total K ((mg/kg))	0.53±0^b	1.50±0.01^a	0.23±0^d	0.26±0^c
速效氮 Available N (mg/kg)	132.51±11.70^c	162.70±0.97^b	231.87±3.01^a	126.51±1.30^c
速效磷 Available P (mg/kg)	21.54±1.04^c	35.12±0.66^b	56.77±2.36^a	18.81±0.18^c
速效钾 Available K (mg/kg)	253.17±7.45^b	402.64±6.47^a	404.73±2.97^a	171.62±2.73^c
有效钙 Potent Ca (mg/kg)	3567.23±10.41^b	5871.63±7.35^a	468.96±4.18^d	859.25±1.85^c
有效镁 Available Mg (mg/kg)	415.08±11.15^b	684.50±6.52^a	175.89±0.54^d	199.37±1.11^c
有效锌 Available Zn (mg/kg)	13.17±0.20^b	16.05±0.20^a	16.09±0.20^a	2.24±0.07^c
有效铁 Available Fe (mg/kg)	12.33±0.27^c	16.49±0.22^b	18.71±0.22^a	10.65±0.09^d
有效硼 Available B (mg/kg)	1.93±0.01^b	2.65±0.20^a	1.10±0^c	0.21±0.01^d
有效硫 Available S (mg/kg)	30.61±0.61^b	17.61±0.30^c	13.85±0.12^d	35.48±0.44^a

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