Seed size variation: magnitude, distribution, and ecological correlates

Michaels, Helen J.; Benner, B. L.; Hartgerink, A. P.; Lee, T. D.; Rice, Stanley A.; Willson, Mary F.; Bertin, Robert I.

doi:10.1007/bf02067274

Cited by 209 publications

(169 citation statements)

References 35 publications

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“…Observed seed germination variance is often explained as a diversification bet-hedging strategy whereby individuals minimize the likelihood of complete reproductive failure by paying a cost in the form of a reduction in expected fitness. Explaining seed trait variance has been, and continues to be, a major concern to those interested in life-history evolution because of the close association between seed traits and fitness (e.g., Cohen 1966;Janzen 1969;Smith and Fretwell 1974;Harper 1977;Marks and Prince 1981;Venable 1985;Kalisz 1986;Michaels et al 1988;Venable and Brown 1988;Westoby et al 1992;Philippi 1993;Rees 1997;Simons and Johnston 2000a;Galloway 2002;Donohue et al 2005;Evans and Dennehy 2005).…”

Section: Discussionmentioning

confidence: 99%

“…Much seed trait variation also resides within species (Schaal 1980;Stanton 1984;Thompson 1984;Kalisz 1986;Michaels et al 1988;Zammit and Zedler 1990;Biere 1991a;Wolfe 1995;Galloway 2002;Imbert 2002), even in crop plants that have been subjected to artificial selection to control this variance (references in Silvertown 1984). This was neither expected on theoretical grounds (e.g., Smith and Fretwell 1974) nor recognized until the 1980s (Michaels et al 1988;Westoby et al 1992).…”

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confidence: 99%

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Environmental and Genetic Sources of Diversification in the Timing of Seed Germination: Implications for the Evolution of Bet Hedging

2006

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Abstract. Environmental variation that is not predictably related to cues is expected to drive the evolution of bethedging strategies. The high variance observed in the timing of seed germination has led to it being the most cited diversification strategy in the theoretical bet-hedging literature. Despite this theoretical focus, virtually nothing is known about the mechanisms responsible for the generation of individual-level diversification. Here we report analyses of sources of variation in timing of germination within seasons, germination fraction over two generations and three sequential seasons, and the genetic correlation structure of these traits using almost 10,000 seeds from more than 100 genotypes of the monocarpic perennial Lobelia inflata. Microenvironmental analysis of time to germination suggests that extreme sensitivity to environmental gradients, or microplasticity, even within a homogeneous growth chamber, may act as an effective individual-level diversification mechanism and explains more than 30% of variance in time to germination. The heritability of within-season timing of germination was low (h 2 ϭ 0.07) but significant under homogeneous conditions. Consistent with individual-level diversification, this low h 2 was attributable not to low additive genetic variance, but to an unusually high coefficient of residual variation in time to germination. Despite high power to detect additive genetic variance in within-season diversification, it was low and indistinguishable from zero. Restricted maximum likelihood detected significant genetic variation for germination fraction (h 2 ϭ 0.18) under homogeneous conditions. Unexpectedly, this heritability was positive when measured within a generation by sibling analysis and negative when measured across generations by offspring-on-parent regression. The consistency of dormancy fraction over multiple delays, a major premise of Cohen's classic model, was supported by a strong genetic correlation (r ϭ 0.468) observed for a cohort's germination fraction over two seasons. We discuss implications of the results for the evolution of bet hedging and highlight the need for further empirical study of the causal components of diversification.Key words. Diversification bet hedging, dormancy, environmental unpredictability, heritability, microplasticity, phenotypic plasticity, seed germination. Cole's (1954) renowned result-showing that the fitness of an annual and a perennial plant are equal given that the annual produces just one seed more than the perennialprompted the development of life-history theory by underscoring the evolutionary importance of age(stage)-dependent survival. Mortality at the seed and seedling stage is expected to be much higher than at later stages, especially for annual plants that produce a large number of small seeds (Harper 1977). From the perspective of life-history evolution, the importance of the timing of germination is clear: upon germination, a plant steps from the least to the most vulnerable stage of its life cycle. Thus, the ti...

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Section: Discussionmentioning

confidence: 99%

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confidence: 99%

Environmental and Genetic Sources of Diversification in the Timing of Seed Germination: Implications for the Evolution of Bet Hedging

2006

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“…Environmental maternal effects can influence a variety of plant traits, including emergence time, rates of leaf development and juvenile size (Michaels et al, 1988;Helenurm and Schaal, 1996;Stanton and Galen, 1997). In the wild radish Raphanus raphanistrum, herbivory on maternal plants increased allocation to chemical defense in seedlings (Agrawal et al, 1999), but these effects became less pronounced in older plants, where defenses were more strongly determined by offspring environment (Agrawal, 2001(Agrawal, , 2002.…”

Section: Discussionmentioning

confidence: 99%

Variation in Lupinus arboreus alkaloid profiles and relationships with multiple herbivores

Adler

Kittelson

2004

Biochemical Systematics and Ecology

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Variation in plant defensive profiles can be affected by environmental factors, genetic factors, and their interactions, and different feeding guilds may have different responses to variation in defenses. Here we present results of a factorial breeding design in Lupinus arboreus from three sites of origin to determine how parental effects, population differences, and environmental effects influence alkaloid profiles and resistance to multiple herbivores. Alkaloids were identified and quantified in seeds and adult plants grown at each of the three sites. We also censused five different herbivores on plants over 2 years and determined the relationship between each herbivore density and total alkaloids, alkaloid profiles, plant size and site. We found strong effects of origin, maternal parent, and maternal Â paternal interactions on seed alkaloid profiles, and effects of origin, destination site, their interactions, and maternal Â paternal interactions on leaf alkaloid profiles. However, there was no correlation between alkaloid concentration or specific compounds in seeds and full-sib adult plants. Density of the leaf galler Dasineura lupinorum and the fungus Colletotrichium spp. was affected by total alkaloid concentration and alkaloid profiles, while density of apical flies and bud gallers was not affected by any alkaloid measure. Red and green forms of the leaf galler had different responses to alkaloids, and green leaf gallers and fungi had opposite responses to measures of alkaloid profiles. These results highlight the complexity of interactions between herbivores and plant defenses, and indicate that measuring selection for defense traits may not be straightforward in natural environments that include multiple herbivore guilds. #

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“…The combination of low-level baseline unreduced gamete production along with a single high-level producer highlights the variable nature of unreduced gamete production that may be a product of environment, development and genetics (Ramsey and Schemske, 1998). Intensive sampling at other scales, including within individuals, could reveal additional patterns, including the possibility that variation in unreduced gamete production may be greatest at the scale of the flower within an individual, as is the case for seed size (Michaels et al, 1988).…”

Section: Rates Of Unreduced Gamete Productionmentioning

confidence: 99%

Genetic and environmental determinants of unreduced gamete production in Brassica napus, Sinapis arvensis and their hybrids

2016

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Unreduced gametes, sperm or egg cells with the somatic chromosome number, are an important mechanism of polyploid formation and gene flow between heteroploid plants. The meiotic processes leading to unreduced gamete formation are well documented, but the relative influence of environmental and genetic factors on the frequency of unreduced gametes remain largely untested. Furthermore, direct estimates of unreduced gametes based on DNA content are technically challenging and, hence, uncommon. Here, we use flow cytometry to measure the contribution of genetic (hybridization) and environmental (nutrient limitation, wounding) changes to unreduced male gamete production in Brassica napus, Sinapis arvensis and two hybrid lines. Treatments were applied to greenhouse grown plants in a random factorial design, with pollen sampled at two time intervals. Overall, the frequency of unreduced gametes averaged 0.59% (range 0.06-2.17%), plus a single outlier with 27%. Backcrossed hybrids had 39 to 75% higher unreduced gamete production than parental genotypes, averaged across all treatments, although the statistical significance of these differences depended on sampling period and wounding treatment. Unreduced gamete frequencies were higher for the second sampling period than the first. There were no direct effects of wounding or nutrient regime. Our results indicate that both genetic and environmental factors can induce increased unreduced gametes, highlighting the potential importance of environmental heterogeneity and genetic composition of populations in driving polyploid evolution.

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Seed size variation: magnitude, distribution, and ecological correlates

Cited by 209 publications

References 35 publications

Environmental and Genetic Sources of Diversification in the Timing of Seed Germination: Implications for the Evolution of Bet Hedging

Environmental and Genetic Sources of Diversification in the Timing of Seed Germination: Implications for the Evolution of Bet Hedging

Variation in Lupinus arboreus alkaloid profiles and relationships with multiple herbivores

Genetic and environmental determinants of unreduced gamete production in Brassica napus, Sinapis arvensis and their hybrids

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