半扭卷马先蒿个体内的种子生产模式及其对资源的响应

摘要/Abstract

摘要： 花序内部雌性繁殖成功的差异在很多植物当中都存在,解释花序内部雌性繁殖成功的假说主要有3种:传粉不均匀假说、结构效应假说和资源限制假说。但外部因素对植物花序内雌性生殖成功模式的影响的研究非常少。本实验对半扭卷马先蒿设置了3个密度梯度、2个剪叶水平,收取不同部位的果实,以研究密度和剪叶对半扭卷马先蒿个体内种子产量的影响。实验参数包括:单个果实种子数、种子重、种子均重和胚珠数。同时,还做了人工补充授粉和自然授粉单个果实种子数/胚珠数和单株果实数/花数的比较实验,结果证明,半扭卷马先蒿的繁殖不受花粉资源的限制;密度对单个果实的种子数、种子均重有显著影响。剪叶对单个果实的种子数、败育数、胚珠数、种子重有显著影响。剪叶和位置的交互作用在单个果实的种子数、败育数、胚珠数方面有显著作用,密度和位置的交互作用对上述参数均无显著影响。在剪叶和密度处理下,位置对果实的上述参数均有显著影响,剪叶植株的单个果实种子数、败育数、胚珠数、种子重均小于未剪叶的植株。由此可以看出,在半扭卷马先蒿的雌性繁殖成功当中,结构效应和资源限制假说可能同时起着作用。且资源条件不但影响着半扭卷马先蒿雌性生殖成功,而且影响着花序内的变异程度,表明了该种植物对种子生产的可塑性调节。

Abstract: There is a common phenomenon that a discrepancy in female productive success exists in the inflorescence of many plants, especially alpine plants. The non-uniform pollination hypothesis, the architecture effect hypothesis, and the resource competition hypothesis are three hypotheses to explain such patterns of within-inflorescence variation in female reproductive success. However, experiments to evaluate the influence of outside environmental factors on female reproductive success are rare. In this experiment, the effects of population density and defoliation on the female productive success of P. semitorta were investigated. The parameters tested include seed number, seed mass, ovule number per fruit, and individual seed weight. We also choose twenty natural groups of P. semitorta to find whether this plant’s reproduction allocation is restricted by pollen resources. There was no significant discrepancy in the rate of fruit set and the rate of seed set between natural pollinated and artificial supplement pollinated plants. However, population density had a significant effect on seed number per fruit and individual seed weight, while defoliation affected seed numbers, seed mass, and ovule number per fruit. In density and defoliation treatments, fruit position had a marked relationship to all the above parameters, indicating that architecture effects play a role in this plant’s female reproductive success. All the parameters of defoliated individual plants were less than those of the non-defoliated ones. The interaction effect of defoliation and fruit position had a significant influence on seed numbers and ovules per fruit, indicating that defoliation had a negative effect on female reproductive success. We suggest that the architecture effect and resource competition both affect female reproductive success of P. semitorta and that they are the results of plant plasticity.

中图分类号:

S324

王晓娟,张龙冲,赵志刚. 半扭卷马先蒿个体内的种子生产模式及其对资源的响应[J]. 草业学报, 2010, 19(4): 236-242.

WANG Xiao-juan, ZHANG Long-chong, ZHAO Zhi-gang. The pattern of seed reproduction and its response to resources in Pedicularis semitorta individuals[J]. Acta Prataculturae Sinica, 2010, 19(4): 236-242.

参考文献

[1] Guitian J, Navarro L. Allocation of reproductive resources within the inforescences of Petrocoptis grandifora (Caryo-phyllaceae)[J]. Canada Journal Botany, 1996, 74: 1482-1486.
[2] Guitian J, Medrano M, Oti J. Variation in floral sex allocation in Polygonatum odoratum (Liliaceae)[J]. Annual Botany, 2004, 94: 433-440.
[3] Ishii H S, Sakai S. Temporal variation in floral display size and individual floral sex allocation in racemes of Narthecium asiaticum (Liliaceae)[J]. American Journal of Botany, 2002, 89: 441-446.
[4] Mazer S J, Dawson K A. Size-dependent sex allocation within flowers of the annual herb Clarkia unguiculata (Onagraceae): Ontogenetic and among-plant variation[J]. American Journal of Botany, 2001, 88: 819-831.
[5] Vallius E. Position-dependent reproductive success of flowers in Dactylorhiza maculata (Orchidaceae)[J]. Functional Ecology, 2000, 14: 573-579.
[6] Ashman T L, Hitchens M S. Dissecting the causes of variation in intra-inflorescence allocationin sexually polymorphic species, Fragaria virginiana (Rosaceae)[J]. American Journal of Botany, 2000, 87: 197-204.
[7] Medrano M, Guitlan P, Guitan J. Patterns of fruit and seed set within Pancratium maritimum (Amaryllidaceae): Uniform pollination, resource limitation, or architecture effect[J]. American Journal of Botany, 2000, 87: 493-501.
[8] Kudo G, Maeda T, Narita K. Variation in floral sex allocation and reproductive success within inflorescences of Corydalis ambigua (Fumariaceae): Pollination efficiency or resource limitation[J]. Journal of Ecology, 2001, 89: 48-56.
[9] Buide M L. Intra-inflorescence variation in floral traits and reproductive success of the hermaphrodite Silene acutifolia[J]. Annual Botany, 2004, 94: 441-448.
[10] Kliber A, Eckert C G. Sequential decline in allocation among flowers within inflorescences: Proximate mechanisms and adaptive significance[J]. Ecology, 2004, 85: 1675-1687.
[11] Berry P E, Calvo R N. Pollinator limitation and position dependent fruit set in the high and eanorchid Myrosmodescoch-leare (Orchidaceae)[J]. Plant Systematics and Evolution, 1991, 174: 93-101.
[12] Vaughton G. Nonrandom patterns of fruit set in Banksia spinulosa (Proteaceae): Inter ovary competition within and among in florescences[J]. International Journal of Plant Sciences, 1993, 154: 306-381.
[13] 樊宝丽, 赵志刚, 孟金柳, 等. 露蕊乌头(Aconitum gymnandrum Maxim)花序内位置依赖的性分配[J]. 生态学报, 2008, 6:2909-2915.
[14] Zimmerman J K, Aide T M. Patterns of fruit production in a Neotropical orchid: Pollinator vs. resource limitation[J]. American Journal of Botany, 1989, 76: 67-73.
[15] Mosjidis J A, Yermanos D M. Plant position effect on seed weight, oil content and oil composition in sesame[J]. Euphytica, 1985, 34:193-199.
[16] Nekonam M S, Razmjoo K S. Effect of plant density on yield, yield components and effective medicine ingredients of blond psyllium (Plantago ovata Forsk.)accessions[J]. International Journal of Agriculture and Biology, 2007, 4: 606-609.
[17] Oscar J, Rocha, Stephenson A G. Effect of ovule position in fabaceous flower on seed set and out-crossing rates[J]. Botanical Gazette, 1990, 137: 250-254.
[18] Ashman T L, Jennifer P, Chriaty D. Size denpendent sex allocation in a genodioecious strawberry: The effect of sex morph or inflorescence architecture[J]. International Journal of Plant Science, 2001, 162: 327-334.
[19] Zhao Z G, Meng J L, Fan B L, et al. Reproductive patterns within racemes in protandrous Aconitum gymnandrum (Ranunculaceae): Potential mechanism and among-family variation[J]. Plant Systematics and Evolution, 2008, 243: 247-256.
[20] Wolfe L M. Why does the size of reproductive structures decline through time in Hydrophyllum appendiculatum (Hydro-phyllaceae): Developmental constraints vs resource limitation[J]. American Journal of Botany, 1992, 79: 1286-1290.
[21] Diggle P K. Arechitecture effect and interpretation of fruit and seed development[J]. Annual Review of Ecology and Systematics, 1995, 26: 531-552.
[22] Diggle P K. Ontogenic and contingency of floral morphlogy, the effects of arechitecture and resource limitation[J]. International of Plant Science, 1997, 158: 99-107.
[23] Thomson J D. Development of ovules and pollen among flowers within inflorescences[J]. Evolution in Plants, 1989, 3: 65-68.
[24] Kwak M M. Pollination and pollen flow disturbed by honeybees in bumblebee-pollinated Rhinathus populations[A]. In: Andel J, Brakker J P, Sanydon R W. Disturbance in Grasslands[M]. Kordrcht: Junk, 1987: 273-283.
[25] Drisig H. Ideal free distribution of nectar foaring bumblebees[J]. Oikos, 1995, 72: 161-172.
[26] Kunin W E. Population size and density effects in pollination: Pollination foaring and plant reproductive success in experimental arrays of Brassica kaber[J]. Ecology, 1997, 85: 225-234.
[27] Bosch M, Waser N M. Effect of local density on pollination and reproduction in Delphmium nuttallianum and Aconitum columbianum (Ranunculaceae)[J]. American Journal of Botany, 1999, 86: 871-879.
[28] Zhao Z G, He Y L, Wang M T, et al. Variations of flower size and reproductive traits in self-incompatible Trollius ranunculoides (Ranunculaceae) among local habitats at Alpine Meadow[J]. Plant Ecology, 2007, 193: 241-251.
[29] Sangoil L. Understanding plant density effects on maize growth and development: An important issue to maximize grain yield[J]. Cioncia Rural, 2000, 31: 159-168.
[30] Bos H J, Vos J, Struik P C. Morphological analogy of plant density on early leaf area growth in maize[J]. Netherland General of Agriculture Science, 2000, 48: 199-212.
[31] Iwaizumi M G, Sakai S. Variation in flower biomass among nearby populations of impatiens textori (aminaceae): Effects of population plant densities[J]. Canada Journal Botany, 2004, 82: 563-572.
[32] Bosch M, Nicolas M, Waser. Experimental manipulation of plant and its effect on pollination and reproduction of two confamilial montane herd[J]. Oecologia, 2001, 126: 76-83.
[33] Kirchner F, Luigten S H, Lmbert E, et al. Effects of local density on insect visitation and fertilization success in the narrow-endemic Centaurea corymbosa (Asteraceae)[J]. Oikos, 2005, 111: 130-142.
[34] Najafi F, Moghadam P R. Effect of irrigation regimes and plant density on yield and agronomic characteristics of blond psyllium (Plantago ovata)[J]. Japan Agriculture Science Technology, 2002, 16: 59-65.
[35] Pawar S U, Kharwade M L, Wawari H. Effect of plant density on vegetative growth and yield performance of different varieties of French bean under irrigated condition[J]. Karnataka Japan Agriculture Science, 2007, 20: 684-685.
[36] Ali M, Singh K K. Performance of chickpea (Cicer arietinum) genotypes at varying population densities under late sown conditions[J]. Indian Journal of Agricultural Sciences, 1999, 69: 393-395.
[37] Brunet J. Male reproductive success and variation in fruit and seed set in Aquilegia caerulea (Ranunculaceae)[J]. Ecology, 1996, 77: 2458-2471.
[38] Cushman K E, Horgan T E, Nagel D H, et al. Plant density affects pumpkin size and weight but not yield[C]. Annual Report of the North Mississipp, Research & Extension Center, Miss. Agriculture & For Expect Statistics Information, Bull, 2002, 386: 282-283.
[39] Muir J P, Reed R L, Malinowski D P. Trailling and smooth-seeded wild beans: Native annual warm season legumes for Texas[J]. Forage Research in Texas, 2003: 5254-5267.
[40] Pellegrino G, Musacchio A. Effect of defoliation on reproductive success in two orchids, Serapias vomeracea and Dactylorhiza[J]. Annales Botanici Fennici, 2006, 48: 123-128.
[41] Erba S, Bayday H. Defoliation effects on sunflower (Helianthus annuus L.) seed yield and oil quality[J]. Turk Journal Biology, 2007, 31: 115-118.
[42] Adjei M B, Mislevy P, Chason W. Timing, defoliation management and nitrogen effects on seed yield of argentine bahiagra[J]. Agronomy Journal, 2000, 92: 36-41.
[43] Macior L W, Ya T, Zhang J C. Reproductive biology of Pedicularis (Scrophulariaceae) in the Sichuan Himalaya[J]. Plant Species Biology, 2001, 16: 83-89.
[44] Wang H, Mill R R, Blackmore S. Pollen morphology and infra-generic evolutionary relationships in some Chinese species of Pedicularris (Scrophulariaceae)[J]. Plant Systematics and Evolution, 2003, 237:1-17.
[45] Yang C F, Guo Y H. Pollen size-number trade-off and pollen-pistil relationships in Pedicularis (Orobanchaceae)[J]. Plant Systematics and Evolution, 2004, 247: 177-185.
[46] Yang C F, Guo Y H, Gituru R W, et al. Variation in stigma morphology-How does it contribute to pollination adaption in Pedicularis (Orobanchaceae)[J]. Plant Systematics and Evolution, 2002, 236: 89-98.
[47] Tang Y, Xie J S. A pollination ecology study of Pedicularis linnaeus (Orobanchaceae)in a subalpine to alpine area of northwest Sichuan, China[J]. Arctic, Antactic, and Apline Research, 2006, 38: 446-453.
[48] Yang C F, Gituru R W, Guo Y H. Reproductive isolation of two sympatric louseworts, Pedicularis rhinanthoides and Pedicularis longiflora (Orobanchaceae): How does the same pollinator type avoid interspecific pollen transfer[J]. Biology Journal, 2007, 23: 37-48.
[49] Sun Y H, Guo Y H, Gituru R W, et al. Corolla wilting facilitates delayed autonomous self-pollination in Pedicularis dunniana (Orobanchaceae)[J]. Plant Systematics and Evolution, 2005, 251: 229-237.
[50] 傅立国, 陈潭清, 朗楷永, 等. 高等植物[A]. 马先蒿属[M]. 青岛:青岛出版社, 2004.
[51] Du G Z, Wang G. Succession and qualitative change of artificial grassland of Gannan sub-alpine meadow[J]. Acta Botanica Sinica, 1995, 37: 306-313.
[52] Kawai Y, Kudo G. Effectiveness of buzz pollination in Pedicularis chamissonis: Significance of multiple visits by bumblebees[J]. Ecology Research, 2008, 10: 1284-1293.
[53] Larson B M H, Barrett S C H. The pollination ecology of buzz-pollinated Rhexia virginica (Melastomataceae)[J]. American Journal Botany, 1999, 87: 371-385.
[54] Gross C L, Bartier F V, Mulligan D R. Floral structure, breeding system and fruit-set in the threatened sub-shrub Tetratheca juncea Smith(Tremandraceae)[J]. Annual Botany, 2003, 92: 771-777.
[55] Liu H, Koptur S. Breeding system and pollination of a narrowly endemic herb of the lower Florida keys: Impacts of the urban-wild land interface[J]. American Journal of Botany, 2003, 90: 1180-1184.
[56] Byrne M, Mazer S J. The effect of position on fruit characteristics, and relationships among components of yield in Phytolacca rivinoides (Phytolaccaceae)[J]. Biotropica, 1990, 22: 353-365.
[57] Alan O, Eser B. Pepper seed yield and quality in relation to fruit position of mother plant[J]. Pakistan Jornal of Biological Sciences, 2007, 10: 4251-4255.
[58] Hiei K, Ohara M. Variation in fruit-and seed set among and within in florescences of Melampyrum roseum var. japonicum (Scrophulariaceae)[J]. Plant Species Biology, 2002, 17: 13-23.
[59] Boroomandan P, Khoramivafa M, Haghi Y, et al. The effect of nitrogen starter fertilizer and plant density on yield, yield components and oil and protein compotent of soybean[J]. Pakistan Gournal of Biological Science, 2009, 12:378-382.
[60] 王鹤龄, 牛俊义, 郑华平, 等. 玛曲高寒沙化草地生态位特征及其施肥改良研究[J]. 草业学报, 2008, 17(6):18-24.