Your search keyword '"Rebecca S. Snell"' showing total 2 results

1. Intrinsic and extrinsic drivers of intraspecific variation in seed dispersal are diverse and pervasive

Author

Evan C. Fricke, John R. Poulsen, Onja H. Razafindratsima, Clare E. Aslan, Rebecca S. Snell, Rafał Zwolak, Manette E Sandor, Brittany R. Cavazos, Noelle G. Beckman, Eugene W. Schupp, Landon R. Jones, Edu O. Effiom, Katriona Shea, Flavia A. Montaño-Centellas, and McConkey, Kim

Subjects

0106 biological sciences, Range (biology), Seed dispersal, Crop size, seed dispersal traits, Plant Biology, Context (language use), Plant Science, Biology, 010603 evolutionary biology, 01 natural sciences, Intraspecific competition, intraindividual variation, Special Issue: The Role of Seed Dispersal in Plant Populations: Perspectives and Advances in a Changing World, interindividual variation, 2. Zero hunger, seed dispersal effectiveness, Ecology, 15. Life on land, fruit size, Editor's Choice, Variation (linguistics), Habitat, Trait, Biological dispersal, 010606 plant biology & botany

Abstract

There is growing realization that intraspecific variation in seed dispersal can have important ecological and evolutionary consequences. However, we do not have a good understanding of the drivers or causes of intraspecific variation in dispersal, how strong an effect these drivers have, and how widespread they are across dispersal modes. As a first step to developing a better understanding, we present a broad, but not exhaustive, review of what is known about the drivers of intraspecific variation in seed dispersal, and what remains uncertain. We start by decomposing ‘drivers of intraspecific variation in seed dispersal’ into intrinsic drivers (i.e. variation in traits of individual plants) and extrinsic drivers (i.e. variation in ecological context). For intrinsic traits, we further decompose intraspecific variation into variation among individuals and variation of trait values within individuals. We then review our understanding of the major intrinsic and extrinsic drivers of intraspecific variation in seed dispersal, with an emphasis on variation among individuals. Crop size is the best-supported and best-understood intrinsic driver of variation across dispersal modes; overall, more seeds are dispersed as more seeds are produced, even in cases where per seed dispersal rates decline. Fruit/seed size is the second most widely studied intrinsic driver, and is also relevant to a broad range of seed dispersal modes. Remaining intrinsic drivers are poorly understood, and range from effects that are probably widespread, such as plant height, to drivers that are most likely sporadic, such as fruit or seed colour polymorphism. Primary extrinsic drivers of variation in seed dispersal include local environmental conditions and habitat structure. Finally, we present a selection of outstanding questions as a starting point to advance our understanding of individual variation in seed dispersal., Intraspecific variation in the quantity and quality of seed dispersal has important ecological and evolutionary consequences, yet it is generally ignored in favour of simply using population mean values. In a broad but not exhaustive review we show that drivers of intraspecific variation in seed dispersal are diverse and pervasive. These include both intrinsic (i.e. variation in traits of individual plants) and extrinsic (i.e. variation in ecological context) drivers. Further, these drivers appear to interact frequently in complex ways. Current theory does not include or account for these complex and interacting drivers.

Published

2019

2. Employing plant functional groups to advance seed dispersal ecology and conservation

Author

Evan C. Fricke, Liba Pejchar, Alan Hastings, Katie Gurski, Robin R. Decker, Christopher Strickland, Jeremy S. Johnson, Maria N. Miriti, Jenny Zambrano, Sebastian J. Schreiber, Judie Bronstein, Janneke HilleRisLambers, Ying Zhou, Haldre S. Rogers, Damaris Zurell, Geno Schupp, Bette A. Loiselle, James M. Bullock, Florian Hartig, Emilio M. Bruna, Noelle G. Beckman, Edu O. Effiom, John R. Poulsen, Clare E. Aslan, Gesine Pufal, Jedediah F. Brodie, Oleg Kogan, Katriona Shea, Mike Neubert, Manette E Sandor, Robert Stephen Cantrell, Onja H. Razafindratsima, and Rebecca S. Snell

Subjects

0106 biological sciences, Seed dispersal, mutualism, Population, Plant Biology, Plant Science, Biology, 010603 evolutionary biology, 01 natural sciences, dispersal vectors, Ecology and Environment, Single species, Ecosystem, education, Point of View, generalization, 2. Zero hunger, Mutualism (biology), seed dispersal effectiveness, education.field_of_study, Data collection, Ecology, food and beverages, 15. Life on land, directed dispersal, Editor's Choice, Germination, Biological dispersal, dependency, 010606 plant biology & botany

Abstract

Seed dispersal enables plants to reach hospitable germination sites and escape natural enemies. Understanding when and how much seed dispersal matters to plant fitness is critical for understanding plant population and community dynamics. At the same time, the complexity of factors that determine if a seed will be successfully dispersed and subsequently develop into a reproductive plant is daunting. Quantifying all factors that may influence seed dispersal effectiveness for any potential seed-vector relationship would require an unrealistically large amount of time, materials and financial resources. On the other hand, being able to make dispersal predictions is critical for predicting whether single species and entire ecosystems will be resilient to global change. Building on current frameworks, we here posit that seed dispersal ecology should adopt plant functional groups as analytical units to reduce this complexity to manageable levels. Functional groups can be used to distinguish, for their constituent species, whether it matters (i) if seeds are dispersed, (ii) into what context they are dispersed and (iii) what vectors disperse them. To avoid overgeneralization, we propose that the utility of these functional groups may be assessed by generating predictions based on the groups and then testing those predictions against species-specific data. We suggest that data collection and analysis can then be guided by robust functional group definitions. Generalizing across similar species in this way could help us to better understand the population and community dynamics of plants and tackle the complexity of seed dispersal as well as its disruption., Seed dispersal is critical to plant fitness and plant community dynamics. However, measuring and tracking all factors that influence seed dispersal effectiveness for any potential seed-disperser relationship would require an unrealistically large amount of time, materials and financial resources. Building on current frameworks, we suggest that seed dispersal ecology quantify seed dispersal at the scale of plant functional groups, in order to reduce complexity to manageable levels. Based on functional group classifications, plant species can be distinguished by their level of dependence on seed dispersal and its mechanisms.

Published

2019