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PLOS ONE 2012

The Anther Steps onto the Stigma for Self-Fertilization in a Slipper Orchid

DOI: 10.1371/journal.pone.0037478

Li-Jun Chen, Ke-Wei Liu, Xin-Ju Xiao, Wen-Chieh Tsai, Yu-Yun Hsiao, Jie Huang, Zhong-Jian Liu

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Abstract:

Background Due to the spatial separation between male and female pollen grains from the anther of most flowering plants, including orchids, pollens are transported by wind or animals and deposited onto the receptive surface of the stigma of a different plant. However, self-pollination is common in pollinating animal-scarce habitats. In such habitats, self-pollinations require the assistance of a pollinating agent (e.g., wind, gravity, or floral assembly) to transport the pollen grains from the anther onto its own stigma. Methodology/Principal Findings Based on observations on floral morphology and flowering phenology, tests of the breeding system, and a comparison of pollination mechanisms, a new self-pollination process was discovered in the hermaphroditic (i.e., possessing spatially separated male and female organs) flower of a slipper orchid, Paphiopedilum parishii. The anther changes from a solid to a liquid state and directly steps onto the stigma surface without the aid of any pollinating agent or floral assembly. Conclusions The mode of self-pollination discussed here is a new addition to the broad range of genetic and morphological mechanisms that have evolved in flowering plants to ensure their reproductive success. The present self-contained pollination mechanism is a possible adaptation to the insect-scarce habitat of the orchid.

References

[1]	Barrett SCH (2002) The evolution of plant sexual diversity. Nature Reviews Genetics 3: 274–284.
[2]	Li QJ, Xu ZF, Kress WJ, Xia YM, Zhang L, et al. (2001) Flexible style that encourages outcrossing. Nature 410: 432.
[3]	Richards AJ (1997) Plant Breeding System, 2nd ed Chapman & Hall (London).
[4]	Barrett SCH (2002) Sexual interference of the floral kind. Heredity 88: 154–159.
[5]	Darwin C (1916) The Effects of Cross and Self-fertilization in the Vegetable Kingdom 2nd ed (Murray, London).
[6]	Lloyd DG (1992) Self- and cross-fertilization in plants. II. The selection of self-fertilization. Int J Plant Sci 153: 370–380.
[7]	Schoen DJ, Morgan MT, Bataillon T (1996) How does self-pollination evolve' inference from floral ecology and molecular genetic variation. Phil Trans R Soc Lond B 351: 1281–1290.
[8]	Schoen DJ, Brown AHD (1991) Whole- and part-flower self-pollination in Glycine clandestine and G. argyrea and the evolution of autogamy. Evolution 45: 1665–1674.
[9]	Liu KW, Liu ZJ, Huang LQ, Li LQ, Chen LJ, et al. (2006) Self-fertilization strategy in an orchid. Nature 441: 945–946.
[10]	Wang Y, Zhang D, Renner SS, Chen Z (2004) A new self-pollination mechanism. Nature 431: 39–40.
[11]	Liu ZJ, Chen LJ, Liu KW, Li LQ, Ma XY, et al. (2008) Chenorchis: a new orchid genus and its eco-strategy of ant pollination. Acta Ecol Sin 6: 2433–2444.
[12]	Kalisz S, Vogler DW (2003) Benefits of autonomous selfing under unpredictable pollinator environments. Ecology 84: 2928–2942.
[13]	Catling PM (1990) Auto-pollination in the Orchidaceae. In: Arditti J (Ed), Orchid Biology: Reviews and Perspectives. V Timber Press (Portland). pp 121–158:
[14]	Anderson WR (1980) Crytptic self-fertilization in Malpighiaceae. Science 207: 892–893.
[15]	Xiao XJ, Liu KW, Zheng YY, Zhang YT, Tsai WC, et al. (2012) Predicted Disappearance of Cephalantheropsis obcordata in Luofu Mountain due to changes in rainfall patterns. PloS ONE 7(1): e29718. doi:10.1371/journal.pone.0029718.
[16]	Liu ZJ, Chen SC, Chen LJ, Lei SP (2009) The Genus Paphiopedilum in China. Science Press (Beijing).
[17]	Cribb PJ (1998) The Genus Paphiopedilum (ed. 2). Natural History Publications (Borneo) Sdn. Bhd. & R. B. G. Kew, Kota Kinabalu (Sabah. Malaysia).
[18]	Liu ZJ, Chen LJ, Zhou Q (2009) The Mix-breeding Strategy of Paphiopedilum armeniacum (Orchidaceae). Nova Science Publishers, Inc. (New York).
[19]	Darwin C (1882) The Various Contrivances by Which Orchids are Fertilized by Insects, 2nd ed (Murray, London).
[20]	Van der Cingel NA (1995) An atlas of orchid pollination. A. A. Balkema, Rotterdam.
[21]	Van der Cingel NA (2001) An atlas of orchid pollination: America, Africa, Asia and Australia. A.A. Balkema, Rotterdam.
[22]	Peter CI (2009) Pollinators, floral deception and evolutionary processes in Eulophia (Orchidaceae) and its allies. PhD Thesis, University of KwaZulu-Natal.
[23]	Gale S (2007) Autogamous seed set in a critically endangered orchid in Japan; pollination studies for the conservation of Nervilia nipponica. Pl Syst Evol 1–4: 59–73.
[24]	Liu ZJ, Chen LJ, Chen SC, Cai J, Tsai WC, et al. (2011) Paraholcoglossum and Tsiorchis, two new orchid genera established by molecular and morphological analyses of the Holcoglossum alliance. (10).PLoS ONE 6. e24864 p. doi:10.1371/journal.pone.0024864.
[25]	Micheneau C, Fournel J, Gauvin-Bialecki A, Pailler T (2008) Auto-pollination in a long-spurred endemic orchid (Jumellea stenophylla) on Reunion Island (Mascarene Archipelago, Indian Ocean). Pl Syst Evol 272: 11–22.
[26]	Peter CI, Johnson SD (2009) Autonomous self-pollination and pseudo-fruit set in South African species of Eulophia (Orchidaceae). Sou Afr J Bot 75: 791–797.
[27]	Dole JA (1992) Reproductive assurance mechanisms in three taxa of the Mimulus guttatus complex (Scrophulariaceae). Amer J Bot 79: 650–659.
[28]	Lord EM (1981) Cleistogamy: A tool for the study of floral morphogenesis, function and evolution. Bot. Rev. 47: 421–449.
[29]	Shi J, Cheng J, Luo D, Shangguan FZ, Luo YB (2007) Pollination syndromes predict brood-site deceptive pollination by female hoverflies in Paphiopedilum dianthum (Orchidaceae). Acta Phytotax Sin 45: 551–560.
[30]	Goodwillie C, Kalisz S, Eckert CG (2005) The evolutionary enigma of mixed mating systems in plants: occurrence, theoretical explanations, and empirical evidence. Annu Rev Ecol Evol Syst 36: 47–79.
[31]	Holsinger KE (2000) Reproductive systems and evolution in vascular plants. Proc Natl Acad Sci USA 97: 7037–7042.
[32]	Fisher RA (1941) Average excess and average effect of a gene substitution. Annals of Eugenics 11: 53–63.
[33]	Stebbins GL (1970) Adaptive radiation in angiosperms. I. Pollination mechanisms. Annu Rev Ecol Syst l: 307–326.
[34]	Wyatt R (1984) Evolution of self-pollination in granite outcrop species of Arenaria (Caryophyllaceae). III. Reproductive effort and pollen-ovule ratios. Syst Bot 9: 432–440.
[35]	Baker HG (1955) Self-compatibility and establishment after “long distance” dispersal. Evolution 9: 347–349.
[36]	Stebbins GL (1957) Self-fertilization and population variability in higher plants. Amer Nat 91: 337–354.
[37]	Tolland O, Sottocornola M (2001) Pollen limitation of reproductive success in two, sympatric alpine willows (Salicaceae) with contrasting pollination strategies. Amer J Bot 88: 1011–1015.
[38]	Kalisz S, Vogler DW, Fails B, Finer M, Shepard E, et al. (1999) The mechanism of delayed selfing in Collinsia verna (Scrophularicaceae). Amer J Bot 86: 1239–1247.
[39]	Kalisz S, Vogler DW, Hanley KM (2004) Context-dependent autonomous self fertilization yields reproductive assurance and mixed mating. Nature 430: 884–887.

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