Small-Seeded Species Produce More Seeds Per Square Metre of Canopy Per Year, but Not Per Individual Per Lifetime
1 The trade-off between seed mass and the number of seeds a plant can make for a given amount of energy underpins our understanding of seed ecology. However, there is little information on the magnitude of the fecundity advantage of small-seeded species over an entire plant lifetime. 2 We compiled d...
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| Published in | The Journal of ecology Vol. 92; no. 3; pp. 384 - 396 |
|---|---|
| Main Authors | , , , |
| Format | Journal Article |
| Language | English |
| Published |
Oxford, UK
British Ecological Society
01.06.2004
Blackwell Science Ltd Blackwell Science Blackwell Publishing Ltd |
| Subjects | |
| Online Access | Get full text |
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| Abstract | 1 The trade-off between seed mass and the number of seeds a plant can make for a given amount of energy underpins our understanding of seed ecology. However, there is little information on the magnitude of the fecundity advantage of small-seeded species over an entire plant lifetime. 2 We compiled data from the literature to quantify the relationships between: (i) seed mass and plant size (because the photosynthetic area of a plant determines how much energy is available for allocation to seed production); (ii) seed mass and plant reproductive lifetime (the number of years a plant has to produce seeds); and (iii) seed mass and the number of seeds produced per individual per year, and per lifetime. 3 Seed mass was positively related to all measures of plant size (canopy area, plant height, stem diameter, plant mass and canopy volume). There were also positive correlations between seed mass and time to first reproduction, plant life span, and reproductive life span. Thus, although small-seeded species produce more seeds per unit canopy area per year than large-seeded species, large-seeded species tend to have larger canopies and more reproductive years. 4 These patterns accord well with independently gathered data on annual and lifetime seed production. The negative relationship between seed mass and the number of seeds produced per year was much shallower on a per individual basis than on a per unit canopy basis. Seed mass was not significantly related to the total number of seeds produced by an individual plant throughout its lifetime. 5 Our previous understanding of seed mass as a spectrum from production of many small seeds, each with low establishment probability, to a few large seeds each with higher establishment probability, was missing some important elements. To understand the forces shaping the evolution of seed mass, we will need to consider plant size and longevity, as well as seedling survival rates and the number of seeds that can be produced for a given amount of energy. |
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| AbstractList | The trade-off between seed mass and the number of seeds a plant can make for a given amount of energy underpins the understanding of seed ecology. However, there is little information on the magnitude of the fecundity advantage of small-seeded species over an entire plant lifetime. Moles et al compiled data from the literature to quantify the relationships between: 1) seed mass and plant size; 2) seed mass and plant reproductive lifetime; and 3) seed mass and the number of seeds produced per individual per year, and per lifetime. Summary The trade‐off between seed mass and the number of seeds a plant can make for a given amount of energy underpins our understanding of seed ecology. However, there is little information on the magnitude of the fecundity advantage of small‐seeded species over an entire plant lifetime. We compiled data from the literature to quantify the relationships between: (i) seed mass and plant size (because the photosynthetic area of a plant determines how much energy is available for allocation to seed production); (ii) seed mass and plant reproductive lifetime (the number of years a plant has to produce seeds); and (iii) seed mass and the number of seeds produced per individual per year, and per lifetime. Seed mass was positively related to all measures of plant size (canopy area, plant height, stem diameter, plant mass and canopy volume). There were also positive correlations between seed mass and time to first reproduction, plant life span, and reproductive life span. Thus, although small‐seeded species produce more seeds per unit canopy area per year than large‐seeded species, large‐seeded species tend to have larger canopies and more reproductive years. These patterns accord well with independently gathered data on annual and lifetime seed production. The negative relationship between seed mass and the number of seeds produced per year was much shallower on a per individual basis than on a per unit canopy basis. Seed mass was not significantly related to the total number of seeds produced by an individual plant throughout its lifetime. Our previous understanding of seed mass as a spectrum from production of many small seeds, each with low establishment probability, to a few large seeds each with higher establishment probability, was missing some important elements. To understand the forces shaping the evolution of seed mass, we will need to consider plant size and longevity, as well as seedling survival rates and the number of seeds that can be produced for a given amount of energy. Seed ecology expresses the trade-off between seed mass and the number of seeds generated. Data from the literature were examined to identify relationships between seed mass and plant size, and seed mass and the number of seeds produced by individual and over a plant lifetime. Seeds mass was positively correlated with all plant size indicators, as well as time to first reproduction, life span, and reproductive life span. Small-seeded species produce more seeds per unit canopy area, but have smaller canopies and fewer reproductive years. Summary 1 The trade‐off between seed mass and the number of seeds a plant can make for a given amount of energy underpins our understanding of seed ecology. However, there is little information on the magnitude of the fecundity advantage of small‐seeded species over an entire plant lifetime. 2 We compiled data from the literature to quantify the relationships between: (i) seed mass and plant size (because the photosynthetic area of a plant determines how much energy is available for allocation to seed production); (ii) seed mass and plant reproductive lifetime (the number of years a plant has to produce seeds); and (iii) seed mass and the number of seeds produced per individual per year, and per lifetime. 3 Seed mass was positively related to all measures of plant size (canopy area, plant height, stem diameter, plant mass and canopy volume). There were also positive correlations between seed mass and time to first reproduction, plant life span, and reproductive life span. Thus, although small‐seeded species produce more seeds per unit canopy area per year than large‐seeded species, large‐seeded species tend to have larger canopies and more reproductive years. 4 These patterns accord well with independently gathered data on annual and lifetime seed production. The negative relationship between seed mass and the number of seeds produced per year was much shallower on a per individual basis than on a per unit canopy basis. Seed mass was not significantly related to the total number of seeds produced by an individual plant throughout its lifetime. 5 Our previous understanding of seed mass as a spectrum from production of many small seeds, each with low establishment probability, to a few large seeds each with higher establishment probability, was missing some important elements. To understand the forces shaping the evolution of seed mass, we will need to consider plant size and longevity, as well as seedling survival rates and the number of seeds that can be produced for a given amount of energy. The trade-off between seed mass and the number of seeds a plant can make for a given amount of energy underpins our understanding of seed ecology. However, there is little information on the magnitude of the fecundity advantage of small-seeded species over an entire plant lifetime. We compiled data from the literature to quantify the relationships between: (i) seed mass and plant size (because the photosynthetic area of a plant determines how much energy is available for allocation to seed production); (ii) seed mass and plant reproductive lifetime (the number of years a plant has to produce seeds); and (iii) seed mass and the number of seeds produced per individual per year, and per lifetime. Seed mass was positively related to all measures of plant size (canopy area, plant height, stem diameter, plant mass and canopy volume). There were also positive correlations between seed mass and time to first reproduction, plant life span, and reproductive life span. Thus, although small-seeded species produce more seeds per unit canopy area per year than large-seeded species, large-seeded species tend to have larger canopies and more reproductive years. These patterns accord well with independently gathered data on annual and lifetime seed production. The negative relationship between seed mass and the number of seeds produced per year was much shallower on a per individual basis than on a per unit canopy basis. Seed mass was not significantly related to the total number of seeds produced by an individual plant throughout its lifetime. Our previous understanding of seed mass as a spectrum from production of many small seeds, each with low establishment probability, to a few large seeds each with higher establishment probability, was missing some important elements. To understand the forces shaping the evolution of seed mass, we will need to consider plant size and longevity, as well as seedling survival rates and the number of seeds that can be produced for a given amount of energy. 1 The trade-off between seed mass and the number of seeds a plant can make for a given amount of energy underpins our understanding of seed ecology. However, there is little information on the magnitude of the fecundity advantage of small-seeded species over an entire plant lifetime. 2 We compiled data from the literature to quantify the relationships between: (i) seed mass and plant size (because the photosynthetic area of a plant determines how much energy is available for allocation to seed production); (ii) seed mass and plant reproductive lifetime (the number of years a plant has to produce seeds); and (iii) seed mass and the number of seeds produced per individual per year, and per lifetime. 3 Seed mass was positively related to all measures of plant size (canopy area, plant height, stem diameter, plant mass and canopy volume). There were also positive correlations between seed mass and time to first reproduction, plant life span, and reproductive life span. Thus, although small-seeded species produce more seeds per unit canopy area per year than large-seeded species, large-seeded species tend to have larger canopies and more reproductive years. 4 These patterns accord well with independently gathered data on annual and lifetime seed production. The negative relationship between seed mass and the number of seeds produced per year was much shallower on a per individual basis than on a per unit canopy basis. Seed mass was not significantly related to the total number of seeds produced by an individual plant throughout its lifetime. 5 Our previous understanding of seed mass as a spectrum from production of many small seeds, each with low establishment probability, to a few large seeds each with higher establishment probability, was missing some important elements. To understand the forces shaping the evolution of seed mass, we will need to consider plant size and longevity, as well as seedling survival rates and the number of seeds that can be produced for a given amount of energy. |
| Author | Moles, Angela T. Leishman, Michelle R. Falster, Daniel S. Westoby, Mark |
| Author_xml | – sequence: 1 givenname: Angela T. surname: Moles fullname: Moles, Angela T. – sequence: 2 givenname: Daniel S. surname: Falster fullname: Falster, Daniel S. – sequence: 3 givenname: Michelle R. surname: Leishman fullname: Leishman, Michelle R. – sequence: 4 givenname: Mark surname: Westoby fullname: Westoby, Mark |
| BackLink | http://pascal-francis.inist.fr/vibad/index.php?action=getRecordDetail&idt=15774937$$DView record in Pascal Francis |
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| ContentType | Journal Article |
| Copyright | Copyright 2004 British Ecological Society 2004 INIST-CNRS Copyright Blackwell Science Ltd. Jun 2004 |
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| References | 2001; 92 2001; 93 1984; 123 1949; 8 2000; 88 1975 1974; 108 2002; 159 1999; 87 2003; 18 1970; 1 1974; 186 1999; 80 1981; 89 1994; 143 2003; 91 2000 2002; 44 1999; 55 2003; 5 1993; 80 1972; 53 1988; 131 2002; 90 1981; 118 1990; 135 1989 1994; 75 1992; 140 1991; 79 1989; 133 2002; 33 1997 1982; 120 1939; 31 1995 1993 2003 1999; 145 1998; 138 2003; 30 1992; 73 1995; 83 2004; 92 1997; 79 2001; 8 1997; 78 1985; 112 1988; 66 1992; 139 1995; 146 1996; 351 e_1_2_6_51_1 e_1_2_6_53_1 e_1_2_6_32_1 e_1_2_6_30_1 Corner E.J.H. (e_1_2_6_9_1) 1949; 8 e_1_2_6_19_1 e_1_2_6_13_1 e_1_2_6_34_1 e_1_2_6_17_1 e_1_2_6_55_1 e_1_2_6_15_1 e_1_2_6_38_1 Udvardy M.D.F. (e_1_2_6_49_1) 1975 e_1_2_6_43_1 e_1_2_6_20_1 Niklas K.J. (e_1_2_6_36_1) 2003; 5 e_1_2_6_41_1 Sokal R.R. (e_1_2_6_44_1) 1995 e_1_2_6_5_1 e_1_2_6_24_1 e_1_2_6_3_1 e_1_2_6_22_1 e_1_2_6_28_1 e_1_2_6_45_1 e_1_2_6_26_1 e_1_2_6_47_1 e_1_2_6_52_1 e_1_2_6_54_1 e_1_2_6_10_1 e_1_2_6_31_1 e_1_2_6_50_1 e_1_2_6_14_1 e_1_2_6_35_1 e_1_2_6_12_1 e_1_2_6_33_1 e_1_2_6_18_1 e_1_2_6_39_1 e_1_2_6_16_1 e_1_2_6_37_1 e_1_2_6_42_1 e_1_2_6_21_1 e_1_2_6_40_1 Eriksson O. (e_1_2_6_11_1) 1997 e_1_2_6_8_1 e_1_2_6_4_1 e_1_2_6_6_1 Charnov E.L. (e_1_2_6_7_1) 1993 e_1_2_6_25_1 e_1_2_6_48_1 e_1_2_6_23_1 e_1_2_6_2_1 e_1_2_6_29_1 e_1_2_6_27_1 e_1_2_6_46_1 |
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| Snippet | 1 The trade-off between seed mass and the number of seeds a plant can make for a given amount of energy underpins our understanding of seed ecology. However,... Summary 1 The trade‐off between seed mass and the number of seeds a plant can make for a given amount of energy underpins our understanding of seed ecology.... Summary The trade‐off between seed mass and the number of seeds a plant can make for a given amount of energy underpins our understanding of seed ecology.... The trade-off between seed mass and the number of seeds a plant can make for a given amount of energy underpins the understanding of seed ecology. However,... Seed ecology expresses the trade-off between seed mass and the number of seeds generated. Data from the literature were examined to identify relationships... The trade-off between seed mass and the number of seeds a plant can make for a given amount of energy underpins our understanding of seed ecology. However,... |
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| SubjectTerms | age at reproduction Animal and plant ecology Animal, plant and microbial ecology Annuals Autoecology Biological and medical sciences Botany Fundamental and applied biological sciences. Psychology General aspects Habitats Human ecology Life span lifetime seed output Plant ecology Plant growth plant life span Plant reproduction plant size Plants Plants and fungi Seed Mass Relationships Seed output Seed production seed size Seedlings Seeds Survival analysis Vegetation canopies |
| Title | Small-Seeded Species Produce More Seeds Per Square Metre of Canopy Per Year, but Not Per Individual Per Lifetime |
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