祖先性状重建法揭示铁线蕨属植物孢子表面纹饰的形态多样性及其演化

doi:10.17520/biods.2019111

生物多样性 ›› 2019, Vol. 27 ›› Issue (11): 1228-1235. DOI: 10.17520/biods.2019111 cstr: 32101.14.biods.2019111

所属专题：物种形成与系统进化

祖先性状重建法揭示铁线蕨属植物孢子表面纹饰的形态多样性及其演化

赵国华^1,²,王莹²,商辉²,周喜乐³,王爱华⁴,李玉峰⁵,王晖¹,刘保东⁶,严岳鸿^2,^*()

1 深圳市中国科学院仙湖植物园, 广东深圳 518004
2 上海辰山植物园, 中国科学院上海辰山植物科学研究中心, 上海 201602
3 湘西土家族苗族自治州森林资源监测中心, 湖南吉首 416000
4 南宁师范大学北部湾环境演变与资源利用教育部重点实验室, 南宁 530001
5 湖南科技大学生命科学学院, 湖南湘潭 411201
6 哈尔滨师范大学植物生物学黑龙江省高校重点实验室, 哈尔滨 150025

收稿日期:2019-03-29 接受日期:2019-10-08 出版日期:2019-11-20 发布日期:2020-01-17
通讯作者: 严岳鸿
基金资助:
国家标本资源共享平台项目、科技部科技基础性工作专项(2013FY112100);生物多样性调查与评估项目(2019HJ2096001006);上海市绿化与市容管理局科学技术项目(G162416);湖南省教育厅科学研究项目(10C0720)

Ancestral state reconstruction reveals the diversity and evolution of spore ornamentation in Adiantum (Pteridaceae)

Guohua Zhao^1,²,Ying Wang²,Hui Shang²,Xile Zhou³,Aihua Wang⁴,Yufeng Li⁵,Hui Wang¹,Baodong Liu⁶,Yuehong Yan^2,^*()

1 Fairylake Botanical Garden, Shenzhen & Chinese Academy of Sciences, Shenzhen, Guangdong 518004;
2 Shanghai Chenshan Botanical Garden, Shanghai Chenshan Plant Science Research Center, Chinese Academy of Sciences, Shanghai 201602
3 Xiangxi Tujia and Miao Autonomous Prefecture Forest Resources Monitoring Center, Jishou, Hunan 416000
4 Key Laboratory of Beibu Gulf Environment Change and Resources Use of Ministry of Education, Nanning Normal University, Nanning 530001
5 School of Life Science, Hunan University of Science and Technology, Xiangtan, Hunan 411201
6 Harbin Normal University, Key Laboratory of Plant Biology, College of Heilongjiang Province, Harbin 150025

Received:2019-03-29 Accepted:2019-10-08 Online:2019-11-20 Published:2020-01-17
Contact: Yan Yuehong

1. 附录1 GenBank下载的参比材料(rbcL, atpB, atpA, trnL-F和rps4-trnS).pdf(279KB)

摘要/Abstract

摘要：

蕨类植物孢子表面的纹饰形态复杂多样, 在分类学和古生物学研究中具有重要意义, 目前探索祖先性状演化常用形态学与系统发育学结合的方法。本文选取一回羽叶铁线蕨类植物为材料, 用扫描电子显微镜观察其孢子形态, 用5个叶绿体基因序列构建系统树, 用最大似然法和最大简约法来分析孢子性状的演化。结果表明: 一回羽叶铁线蕨类的孢子纹饰有5种类型, 即光滑、粗糙、颗粒、疣状及瘤状; 这一类群的祖先孢子纹饰有很大的可能是瘤状纹饰; 疣状纹饰可能是由瘤状纹饰演化而来; 孢子纹饰由简单向复杂演化, 越进化的物种其孢子纹饰越复杂。

关键词: 蕨类, 孢子纹饰, 系统发育, 性状演化

Abstract

Spore morphology is diverse and complex in ferns, thus serving as an important indicator of taxonomy. In conjunction, morphological traits and phylogeny are used to study taxonomy and recent character evolution. This study analyzes the evolution of spore ornamentation in once-pinnate maidenhair ferns (Adiantum) using scanning electron microscopy and ancestral state reconstruction. Our results show that there are five ornamental types in once-pinnate maidenhair ferns: psilate, scabrate, granulate, verrucate and tuberculate. The ancestral state of spore ornamentation in Adiantum is probably tuberculate, with verrucate ornamentation possibly deriving from tuberculate. We suggest that spore ornamentation evolved from simple to complex in Adiantum. In other words, the more evolutionary species, will with a more complex spore ornamentation.

Key words: fern, spore ornamentation, phylogenetic, character evolution

赵国华, 王莹, 商辉, 周喜乐, 王爱华, 李玉峰, 王晖, 刘保东, 严岳鸿 (2019) 祖先性状重建法揭示铁线蕨属植物孢子表面纹饰的形态多样性及其演化. 生物多样性, 27, 1228-1235. DOI: 10.17520/biods.2019111.

Guohua Zhao, Ying Wang, Hui Shang, Xile Zhou, Aihua Wang, Yufeng Li, Hui Wang, Baodong Liu, Yuehong Yan (2019) Ancestral state reconstruction reveals the diversity and evolution of spore ornamentation in Adiantum (Pteridaceae). Biodiversity Science, 27, 1228-1235. DOI: 10.17520/biods.2019111.

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链接本文: https://www.biodiversity-science.net/CN/10.17520/biods.2019111

https://www.biodiversity-science.net/CN/Y2019/V27/I11/1228

图/表 5

参考文献 34

1	Barrington DS, Paris CA, Ranker TA ( 1986) Systematic inferences from spore and stomate size in the ferns. American Fern Journal, 76, 149-159.
2	Blackmore S, Barnes SH ( 1987) Embryophyte spore walls: Origin, development, and homologies. Cladistics, 3, 185-195.
3	Campo MV, Lugardon B ( 1973) Structure grenue infratectale de l’ectexine des pollens de quelques Gymnospermes et Angiospermes. Pollen et Spores, 15, 171-189. (in French)
4	Caroline PD, Patrica LF ( 2001) Modern pollen precipitation from an elevational transect in central Jordan and its relationship to vegetation. Journal of Biogeography, 28, 1195-1210.
5	Co-David D, Langeveld D, Noordeloos ME ( 2009) Molecular phylogeny and spore evolution of Entolomataceae. Persoonia, 23, 147.
6	Devi S ( 1979) Spore types, morphological evolution and phylogeny in the Pteridaceae. Grana, 18, 41-46.
7	Hummel J, Gee CT, Südekum KH, Sander PM, Clauss M ( 2008) In vitro digestibility of fern and gymnosperm foliage: Implications for sauropod feeding ecology and diet selection. Proceedings of the Royal Society B: Biological Sciences, 275, 1015-1021.
8	Lellinger DB ( translated by Xiang JY, Wu SG ) ( 2007) A Modern English-Chinese Glossary for Taxonomic Pteridology. Yunnan Science and Technology Press, Kunming. (in Chinese)
	[ 向建英, 武素功译 ( 2007) 现代英中对照蕨类植物分类学词汇. 云南科技出版社, 昆明.]
9	Liu HM, Zhang XC, Chen ZD, Qiu YL ( 2007) Inclusion of the Eastern Asia endemic genus Sorolepidium in Polystichum (Dryopteridaceae) evidence from the chloroplast rbcL gene and morphological characteristics. Chinese Science Bulletin, 52, 631-638.
10	Lu JM, Wen J, Lutz S, Wang YP, Li DZ ( 2012) Phylogenetic relationships of Chinese Adiantum based on five plastid markers. Journal of Plant Research, 125, 237-249.
11	Luo YL, Sun XJ ( 2001) Vegetation evolution in the northen South China Sea region since 40 ka BP—An attempt to reconstruct palaeovegetation based on biomization. Acta Botanica Sinica, 43, 1202-1206.
12	Mehltreter K, Mehltreter K, Walker L, Sharpe J ( 2010) Fern Ecology. Cambridge University Press, Cambridge.
13	Midgley J, Midgley G, Bond W ( 2002) Why were dinosaurs so large? A food quality hypothesis. Evolutionary Ecology Research, 4, 1093-1095.
14	Ottosson JG, Anderson JM ( 1983) Number, seasonality and feeding habits of insects attacking ferns in Britain: An ecological consideration. Journal of Animal Ecology, 52, 385-406.
15	Patricia L ( 1992) Spatial patterns of atmospheric pollen dispersal in the Colorado Rocky Mountains, USA. Review of Palaeobotany and Palynology, 74, 293-313.
16	The Chromosome Counts Database ( CCDB) ( 2014) A community resource of plant chromosome numbers. 2014) A community resource of plant chromosome numbers. .

17	Shang H, Yan YH ( 2014) Soral crypsis of insect larvea on bracken ferns. Chinese Journal of Nature, 36, 426-430. (in Chinese with English abstract)
	[ 商辉, 严岳鸿 ( 2014) 昆虫幼虫对凤尾蕨属植物孢子囊群的拟态. 自然杂志, 36, 426-430.]
18	Shang H, Wang Y, Zhu XF, Zhao GH, Wang FG, Lu JM ( 2016) Likely allopatric origins of Adiantum × meishanianum (Pteridaceae) through multiple hybridizations. Journal of Systematics and Evolution, 54, 528-534.
19	Smart J, Hughes NF ( 1973) The Insect and the Plant: Progressive Palaeoecological Integration. John Wiley & Sons, New York.
20	Tanaka N, Uehara K, Murata J ( 2004) Correlation between pollen morphology and pollination mechanisms in the Hydrocharitaceae. Journal of Plant Research, 117, 265-276.
21	Tao ZB, Wortley AH, Lu L, Li DZ, Wang H, Blackmore S ( 2018) Evolution of angiosperm pollen. 6. The Celastrales, Oxalidales, and Malpighiales (Com) clade and Zygophyllales. Annals of the Missouri Botanical Garden, 103, 393-442.
22	Tryon AF ( 1985) Spores of myrmecophytic ferns. Proceedings of the Royal Society of Edinburgh, Section B: Biological Sciences, 86, 105-110.
23	Tryon AF, Lugardon B ( 1991) Spores of the Pteridophyta: Surface, Wall Structure, and Diversity Based on Electron Microscope Studies. Springer Verlag, New York.
24	Walker JW ( 1974) Evolution of exine structure in the pollen of primitive angiosperms. American Journal of Botany, 61, 891-902.
25	Walker TG ( 1985) Spore filaments in the ant-fern Lecanopteris mirabilis—An alternative viewpoint. Proceedings of the Royal Society of Edinburgh Section B: Biological Sciences, 86, 111-114.
26	Wang AH, Sun Y, Wang FG, Schneider H, Zhai JW, Liu DM, Zhou JS, Xing FW, Chen HF ( 2015 a) Identification of the relationship between Chinese Adiantum reniforme var. sinense and Canary Adiantum reniforme. BMC Plant Biology, 15, 36.
27	Wang FG, Liu HM, He CM, Yang DM, Xing FW ( 2015 b) Taxonomic and evolutionary implication of spore ornamentation in Davalliaceae. Journal of Systematics and Evolution, 53, 72-81.
28	Wang QX, Dai XL ( 2001) Spores of Polypodiales (Filicales) from China. Science Press, Beijing. (in Chinese)
	[ 王全喜, 戴锡玲 ( 2001) 中国水龙骨目(真蕨目)植物孢子形态的研究. 科学出版社, 北京.]
29	Wang WM ( 2009) Progress and prospect of studies on palynology in China. Acta Palaeontologica Sinica, 48, 338-346. (in Chinese with English abstract)
	[ 王伟铭 ( 2009) 中国孢粉学的研究进展与展望. 古生物学报, 48, 338-346.]
30	Wang Y, Shang H, Gu YF, Wei HJ, Zhao GH, Dai XL, Yan YH ( 2015) A new cryptic hybrid species of Adiantum L. (Pteridaceae) indentified by nuclear and chloroplast DNA sequences. Chinese Science Bulletin, 60, 922-932. (in Chinese with English abstract)
	[ 王莹, 商辉, 顾钰峰, 韦宏金, 赵国华, 戴锡玲, 严岳鸿 ( 2015) 用核DNA和叶绿体DNA序列鉴别铁线蕨属Adiantum L. (凤尾蕨科)新的隐性杂交种. 科学通报, 10, 922-932.]
31	Wang Y, Shang H, Zhou XL, Zhao GH, Dai XL, Yan YH ( 2015 c) Adiantum × ailaoshanense (Pteridaceae), a new natural hybrid from Yunnan, China. Phytotaxa, 236, 266-272.
32	Wei R, Schneider H, Zhang XC ( 2013) Toward a new circumscription of the twinsorus-fern genus Diplazium (Athyriaceae): A molecular phylogeny with morphological implications and infrageneric taxonomy. Taxon, 62, 441-457.
33	Yang ZJ, Xu JM ( 2002) Advances in studies on relationship among pollen, vegetation and climate. Acta Phytoecologica Sinica, 26(Suppl.), 73-81. (in Chinese with English abstract)
	[ 杨振京, 徐建明 ( 2002) 孢粉-植被-气候关系研究进展. 植物生态学报, 26(增刊), 73-81.]
34	Zhang WY, Kuo LY, Li FW, Wang CN, Chiou WL ( 2014) The hybrid origin of Adiantum meishanianum (Pteridaceae): A rare and endemic species in Taiwan. Systematic Botany, 39, 1034-1041.

物种 Species	标本号及采集地 Vouchers and locality	赤道轴 × 极轴 Equatorial diam × polar diam (µm)	孢子纹饰 Spore ornamentation	图1中位置 Position in Fig. 1
A. latifolium	Zxl9882. 泰国曼谷植物标本馆 Bangkok Herbarium, Bangkok, Thailand	33.5 × 27.0	粗糙 Scabrate	1A
扇叶铁线蕨 A. flabellulatum	Zxl10018. 中国广东南岭国家森林公园 Nanling National Forest Park, Guangdong, China	45.5 × 31.2	颗粒 Granulate	1B
团羽铁线蕨 A. capillus-junonis	Zxl9959. 中国广东南岭国家森林公园 Nanling National Forest Park, Guangdong, China	46.5 × 43.0	光滑 Psilate	1C
半月形铁线蕨 A. philippense	Yan12405, Yan12086. 中国云南元江; Zxl9839. 泰国彭世洛府屯萨朗峦国家公园 Yan12405, Yan12086. Yuanjiang, Yunnan, China; Zxl9839. Thung Salaeng Luang National Park, Phitsanulok, Thailand	33.4 × 25.7	粗糙 Scabrate	1D
孟连铁线蕨 A. menglianense	Yan12415, Yan12409. 中国云南元江 Yuanjiang, Yunnan, China	31.5 × 26.6	颗粒 Granulate	1E
翅柄铁线蕨 A. soboliferum	Yan11393. 中国海南昌江 Changjiang, Hainan, China	34.0 × 30.5	颗粒 Granulate	1F
A. zollingeri	Zxl9812, Zxl9911, ZXL9851. 泰国碧武里府康卡沾国家公园 Kaeng Krachan National Park, Phetchaburi, Thailand	34.0 × 27.3	瘤状 Tuberculate	1G
鞭叶铁线蕨 A. caudatum	Yan12408. 中国云南元江 Yuanjiang, Yunnan, China	40.6 × 33.5	瘤状 Tuberculate	1H
白垩铁线蕨 A. gravesii	WYG393. 中国贵州贞丰 Zhenfeng, Guizhou, China	51.5 × 36.1	瘤状 Tuberculate	1I
小铁线蕨 A. mariesii	Zxl9685. 中国湖南桑植 Sangzhi, Hunan, China	36.8 × 30.1	疣状 Verrucate	1J
仙霞铁线蕨 A. juxtapositum	Yan1205071. 中国广东仁化 Renhua, Guangdong, China	60.4 × 45.7	疣状 Verrucate	1K
普通铁线蕨 A. edgewothii	Yan12412. 中国云南元江 Yuanjiang, Yunnan, China	30.0 × 25.6	瘤状 Tuberculate	1L
假鞭叶铁线蕨 A. malesianum	Yan12416, Yan12404. 中国云南元江 Yuanjiang, Yunnan, China	38.8 × 32.8	瘤状 Tuberculate	1M
梅山铁线蕨 A. × meishanianum	Yan12411. 中国云南元江 Yuanjiang, Yunnan, China	-	瘤状 Tuberculate	1N
苍山铁线蕨 A. sinicum	Yan112601, Yan12414. 中国云南元江 Yuanjiang, Yunnan, China	31.7 × 29.1	瘤状 Tuberculate	1O
哀牢山铁线蕨 A. × ailaoshanense	Yan12413, Yan12410. 中国云南元江 Yuanjiang, Yunnan, China	-	瘤状 Tuberculate	1P

物种 Species	标本号及采集地 Vouchers and locality	赤道轴 × 极轴 Equatorial diam × polar diam (µm)	孢子纹饰 Spore ornamentation	图1中位置 Position in Fig. 1
A. latifolium	Zxl9882. 泰国曼谷植物标本馆 Bangkok Herbarium, Bangkok, Thailand	33.5 × 27.0	粗糙 Scabrate	1A
扇叶铁线蕨 A. flabellulatum	Zxl10018. 中国广东南岭国家森林公园 Nanling National Forest Park, Guangdong, China	45.5 × 31.2	颗粒 Granulate	1B
团羽铁线蕨 A. capillus-junonis	Zxl9959. 中国广东南岭国家森林公园 Nanling National Forest Park, Guangdong, China	46.5 × 43.0	光滑 Psilate	1C
半月形铁线蕨 A. philippense	Yan12405, Yan12086. 中国云南元江; Zxl9839. 泰国彭世洛府屯萨朗峦国家公园 Yan12405, Yan12086. Yuanjiang, Yunnan, China; Zxl9839. Thung Salaeng Luang National Park, Phitsanulok, Thailand	33.4 × 25.7	粗糙 Scabrate	1D
孟连铁线蕨 A. menglianense	Yan12415, Yan12409. 中国云南元江 Yuanjiang, Yunnan, China	31.5 × 26.6	颗粒 Granulate	1E
翅柄铁线蕨 A. soboliferum	Yan11393. 中国海南昌江 Changjiang, Hainan, China	34.0 × 30.5	颗粒 Granulate	1F
A. zollingeri	Zxl9812, Zxl9911, ZXL9851. 泰国碧武里府康卡沾国家公园 Kaeng Krachan National Park, Phetchaburi, Thailand	34.0 × 27.3	瘤状 Tuberculate	1G
鞭叶铁线蕨 A. caudatum	Yan12408. 中国云南元江 Yuanjiang, Yunnan, China	40.6 × 33.5	瘤状 Tuberculate	1H
白垩铁线蕨 A. gravesii	WYG393. 中国贵州贞丰 Zhenfeng, Guizhou, China	51.5 × 36.1	瘤状 Tuberculate	1I
小铁线蕨 A. mariesii	Zxl9685. 中国湖南桑植 Sangzhi, Hunan, China	36.8 × 30.1	疣状 Verrucate	1J
仙霞铁线蕨 A. juxtapositum	Yan1205071. 中国广东仁化 Renhua, Guangdong, China	60.4 × 45.7	疣状 Verrucate	1K
普通铁线蕨 A. edgewothii	Yan12412. 中国云南元江 Yuanjiang, Yunnan, China	30.0 × 25.6	瘤状 Tuberculate	1L
假鞭叶铁线蕨 A. malesianum	Yan12416, Yan12404. 中国云南元江 Yuanjiang, Yunnan, China	38.8 × 32.8	瘤状 Tuberculate	1M
梅山铁线蕨 A. × meishanianum	Yan12411. 中国云南元江 Yuanjiang, Yunnan, China	-	瘤状 Tuberculate	1N
苍山铁线蕨 A. sinicum	Yan112601, Yan12414. 中国云南元江 Yuanjiang, Yunnan, China	31.7 × 29.1	瘤状 Tuberculate	1O
哀牢山铁线蕨 A. × ailaoshanense	Yan12413, Yan12410. 中国云南元江 Yuanjiang, Yunnan, China	-	瘤状 Tuberculate	1P

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[14]	张淑梅, 李微, 李丁男. 辽宁省高等植物多样性编目[J]. 生物多样性, 2022, 30(6): 22038-.
[15]	王健铭, 曲梦君, 王寅, 冯益明, 吴波, 卢琦, 何念鹏, 李景文. 青藏高原北部戈壁植物群落物种、功能与系统发育β多样性分布格局及其影响因素[J]. 生物多样性, 2022, 30(6): 21503-.

祖先性状重建法揭示铁线蕨属植物孢子表面纹饰的形态多样性及其演化

Ancestral state reconstruction reveals the diversity and evolution of spore ornamentation in Adiantum (Pteridaceae)

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