Hostname: page-component-586b7cd67f-g8jcs Total loading time: 0 Render date: 2024-11-26T12:24:33.913Z Has data issue: false hasContentIssue false

Effect of selective abortion on seed germination and post-germination performance of offspring

Published online by Cambridge University Press:  09 October 2019

Jerry M. Baskin
Affiliation:
Department of Biology, University of Kentucky, Lexington, KY 40506-0225, USA
Carol C. Baskin*
Affiliation:
Department of Biology, University of Kentucky, Lexington, KY 40506-0225, USA Department of Plant and Soil Sciences, University of Kentucky, Lexington, KY 40546-0312, USA
*
Author for correspondence: Carol C. Baskin, E-mail: [email protected]

Abstract

Hermaphroditic angiosperms, especially outcrossers, generally produce many more flowers and ovules than they can mature into fruits and seeds. One of the several hypotheses to account for the production of ‘excess’ flowers is selective abortion, which has been shown to increase offspring quality in plants. Our primary aim was to review the literature on the effects of selective abortion on seed germination and post-germination offspring vigour. Of 14 case studies (11 species in 10 genera and four families of flowering plants), germination percentage or rate (speed) increased in six and did not increase in eight, whereas post-germination offspring performance increased in 11 and did not increase in three. In six of the eight cases in which germination was not increased, seedling/juvenile vigour was increased. Seed mass was less likely to influence seed germination than seedling/juvenile vigour. Although selective abortion has been shown to increase progeny vigour of the early life history stages of plants, neither its demographic nor evolutionary importance has been demonstrated.

Type
Research Opinion
Copyright
Copyright © Cambridge University Press 2019 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Andersson, S (1993) The potential for selective seed maturation in Achillea ptarmica (Asteraceae). Oikos 66, 3642.Google Scholar
Ayre, DJ and Whelan, RJ (1989) Factors controlling fruit set in hermaphroditic plants: studies with the Australian Proteaceae. Trends in Ecology and Evolution 4, 267272.Google Scholar
Baskin, JM and Baskin, CC (2015) Pollen (microgametophyte) competition: an assessment of its significance in the evolution of flowering plants, with particular reference to seed germination. Seed Science Research 25, 111.Google Scholar
Bawa, KS and Buckley, DP (1989) Seed:ovule ratios, selective seed abortion, and mating systems in Leguminosae. In Stirton, CH and Zarcchi, (eds), Advances in Legume Biology. Monographs in Systematic Botany from the Missouri Botanical Garden 29, 243262.Google Scholar
Bawa, KS and Webb, CJ (1984) Flower, fruit and seed abortion in tropical forest trees: implications for the evolution of paternal and maternal reproductive patterns. American Journal of Botany 71, 736751.Google Scholar
Bookman, SS (1984) Evidence for selective fruit production in Asclepias. Evolution 38, 7286.Google Scholar
Burd, M (1998) ‘Excess’ flower production and selective fruit abortion: a model of potential benefits. Ecology 79, 21232132.Google Scholar
Burd, M (2004) Offspring quality in relation to excess flowers in Pultenaea gunnii (Fabaceae). Evolution 58, 23712376.Google Scholar
Burd, M and Callahan, HS (2000) What does the male function hypothesis claim? Journal of Evolutionary Biology 13, 735742.Google Scholar
Casper, BB (1988) Evidence for selective embryo abortion in Cryptantha flava. The American Naturalist 132, 318326.Google Scholar
Ehrlén, J (1991) Why do plants produce surplus flowers? A reserve-ovary model. The American Naturalist 138, 918933.Google Scholar
Ganeshaiah, KN and Shaanker, RU (1988) Seed abortion in wind-dispersed pods of Dalbergia sissoo: maternal regulation or sibling rivalry? Oecologia 77, 135139.Google Scholar
Gremer, JR, Crone, EE and Lesica, P (2012) Are dormant plants hedging their bets? Demographic consequences of prolonged dormancy in variable environments. The American Naturalist 179, 315327.Google Scholar
Gutiérrez, D, Menéndez, R and Obeso, JR (1996) Effect of ovule position on seed maturation and seed weight of Ulex europaeus and Ulex gallii (Fabaceae). Canadian Journal of Botany 74, 848853.Google Scholar
Holtsford, TP (1985) Nonfruiting hermaphroditic flowers of Calochortus leichtlinii (Liliaceae): potential reproductive functions. American Journal of Botany 72, 16871694.Google Scholar
Janzen, DH (1977) A note on optimal mate selection by plants. The American Naturalist 111, 365371.Google Scholar
Kozlowski, J and Stearns, SC (1989) Hypotheses for the production of excess zygotes: models of bet-hedging and selective abortion. Evolution 43, 13691377.Google Scholar
Lee, TD (1984) Patterns of fruit maturation: a gametophyte competition hypothesis. The American Naturalist 123, 427432.Google Scholar
Mena-Ali, JI and Rocha, OJ (2005a) Effect of ovule position within the pod on the probability of seed production in Bauhinia ungulata (Fabaceae). Annals of Botany 95, 449455.Google Scholar
Mena-Ali, JI and Rocha, OJ (2005b) Selective seed abortion affects the performance of the offspring in Bauhinia ungulata. Annals of Botany 95, 10171023.Google Scholar
Philippi, T (1993) Bet-hedging of desert annuals: variation among populations and maternal effects in Lepidium lasiocarpum. The American Naturalist 142, 488507.Google Scholar
Rocha, OJ and Stephenson, AG (1990) Effect of ovule position on seed production, seed weight, and progeny performance in Phaseolus coccineus L. (Leguminosae). American Journal of Botany 77, 13201329.Google Scholar
Rocha, OJ and Stephenson, AG (1991) Effects of nonrandom seed abortion on progeny performance in Phaseolus coccineus L. Evolution 45, 11981208.Google Scholar
Seger, J and Brockmann, HJ (1987) What is bet-hedging? Oxford Surveys in Evolutionary Biology 4, 182211.Google Scholar
Shaanker, RU, Ganeshaiah, KN and Bawa, KS (1988) Parent-offspring conflict, sibling rivalry, and brood size patterns in plants. Annual Review of Ecology and Systematics 19, 177205.Google Scholar
Shelton, AO (2008) Skewed sex ratios, pollen limitation and reproductive failure in the dioecious seagrass Phyllospadix. Ecology 89, 30203029.Google Scholar
Simons, AM (2011) Modes of response to environmental change and the elusive empirical evidence for bet hedging. Proceedings of the Royal Society B 278, 16011609.Google Scholar
Stephenson, AG (1979) An evolutionary examination of the floral display of Catalpa speciosa (Bignoniaceae). Evolution 33, 12001209.Google Scholar
Stephenson, AG (1980) Fruit set, herbivory, fruit reduction, and the fruiting strategy of Catalpa speciosa (Bignoniaceae). Ecology 61, 5764.Google Scholar
Stephenson, AG (1981) Flower and fruit abortion: proximate causes and ultimate functions. Annual Review of Ecology and Systematics 12, 253279.Google Scholar
Stephenson, AG, Johnson, RS and Winsor, TA (1988) Effects of competition on the growth of Lotus corniculatus L. seedlings produced by random and natural patterns of fruit abortion. The American Midland Naturalist 120, 102107.Google Scholar
Stephenson, AG and Winsor, JA (1986) Lotus corniculatus regulates offspring quality through selective fruit abortion. Evolution 40, 453458.Google Scholar
Susko, DJ (2006) Effect of ovule position on patterns of seed maturation and abortion of Robinia pseudoacacia (Fabaceae). Canadian Journal of Botany 84, 12591265.Google Scholar
Sutherland, S (1986) Patterns of fruit-set: what controls fruit-flower ratios in plants? Evolution 40, 117128.Google Scholar
Sutherland, S (1987) Why hermaphroditic plants produce many more flowers than fruits: experimental tests with Agave mckelveyana. Evolution 41, 750759.Google Scholar
Sutherland, S and Delph, LF (1984) On the importance of male fitness in plants: patterns of fruit-set. Ecology 65, 10931104.Google Scholar
Torres, C, Eynard, MC, Aizen, MA and Galetto, L (2002) Selective fruit maturation and seedling performance in Acacia caven (Fabaceae). International Journal of Plant Sciences 163, 809813.Google Scholar
Udovic, D and Aker, C (1981) Fruit abortion and the regulation of fruit number in Yucca whipplei. Oecologia 49, 245248.Google Scholar
Webb, CJ and Bawa, KS (1985) Patterns of fruit and seed production in Bauhinia ungulata (Leguminosae). Plant Systematics and Evolution 151, 5565.Google Scholar
Wiens, D (1984) Ovule survivorship, brood size, life history, breeding systems, and reproductive success in plants. Oecologia 64, 4753.Google Scholar
Wiens, D, Calvin, CL, Wilson, CA, Davern, CI, Frank, C and Seavey, SR (1987) Reproductive success, spontaneous embryo abortion, and genetic load in flowering plants. Oecologia 71, 501509.Google Scholar
Willson, MF and Price, PW (1977) The evolution of inflorescence size in Asclepias (Asclepiadaceae). Evolution 31, 495511.Google Scholar
Willson, MF and Rathcke, BJ (1974) Adaptive design of the floral display in Asclepias syriaca L. The American Midland Naturalist 92, 4757.Google Scholar
Winsor, JA, Davis, LE and Stephenson, AG (1987) The relationship between pollen load and fruit maturation and the effect of pollen load on offspring vigor in Cucurbita pepo. The American Naturalist 129, 643656.Google Scholar