Endopolyploidy as a potential driver of animal ecology and evolution

Neiman, Maurine; Beaton, Margaret J.; Hessen, Dag O.; Jeyasingh, Punidan D.; Weider, Lawrence J.

doi:10.1111/brv.12226

Cited by 53 publications

(56 citation statements)

References 159 publications

(283 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…A definitive answer to the question of the extent to which larger genome sizes and higher ploidal levels translate into N and P costs will require characterization of organismlevel consequences. For example, the increased N and P demands could be offset by the lower number of cells that are sometimes, but not always, associated with larger genomes (Neiman et al, 2017). Demands may also be offset by more efficient allocation of cellular P to RNA.…”

Section: Future Research Prioritiesmentioning

confidence: 99%

Impacts of Nitrogen and Phosphorus: From Genomes to Natural Ecosystems and Agriculture

et al. 2017

Self Cite

View full text Add to dashboard Cite

Nitrogen (N) and/or phosphorus (P) availability can limit growth of primary producers across most of the world's aquatic and terrestrial ecosystems. These constraints are commonly overcome in agriculture by applying fertilizers to improve yields. However, excessive anthropogenic N and P inputs impact natural environments and have far-reaching ecological and evolutionary consequences, from individual species up to entire ecosystems. The extent to which global N and P cycles have been perturbed over the past century can be seen as a global fertilization experiment with significant redistribution of nutrients across different ecosystems. Here we explore the effects of N and P availability on stoichiometry and genomic traits of organisms, which, in turn, can influence: (i) plant and animal abundances; (ii) trophic interactions and population dynamics; and (iii) ecosystem dynamics and productivity of agricultural crops. We articulate research priorities for a deeper understanding of how bioavailable N and P move through the environment and exert their ultimate impacts on biodiversity and ecosystem services.

show abstract

Section: Future Research Prioritiesmentioning

confidence: 99%

Impacts of Nitrogen and Phosphorus: From Genomes to Natural Ecosystems and Agriculture

et al. 2017

Self Cite

View full text Add to dashboard Cite

show abstract

“…Gill tissue has previously been used in genome size studies in crustaceans, and is a diploid tissue whose nuclei show intermediate levels of compaction relative to muscle cells or haemolymph (Deiana et al 1999;Jeffery and Gregory 2014). This method allowed us to avoid measuring any nuclei from endopolyploid tissues, which are common in crustaceans (Neiman et al 2015). The resulting cell suspension was then flattened with a coverslip that was held onto the slide by three clothespins.…”

Section: Genome Size Estimationmentioning

confidence: 99%

Patterns of genome size variation in snapping shrimp

Jeffery

Hultgren

Chak

et al. 2016

Genome

View full text Add to dashboard Cite

Although crustaceans vary extensively in genome size, little is known about how genome size may affect the ecology and evolution of species in this diverse group, in part due to the lack of large genome size datasets. Here we investigate interspecific, intraspecific, and intracolony variation in genome size in 39 species of Synalpheus shrimps, representing one of the largest genome size datasets for a single genus within crustaceans. We find that genome size ranges approximately 4-fold across Synalpheus with little phylogenetic signal, and is not related to body size. In a subset of these species, genome size is related to chromosome size, but not to chromosome number, suggesting that despite large genomes, these species are not polyploid. Interestingly, there appears to be 35% intraspecific genome size variation in Synalpheus idios among geographic regions, and up to 30% variation in Synalpheus duffyi genome size within the same colony.Key words: Synalpheus, genome size, C-value, polyploidy, gene duplication, chromosome. Résumé :Bien que les crustacés présentent une variation considérable en matière de taille de leurs génomes, peu de choses sont connues sur les liens entre la taille du génome et l'écologie ainsi que l'évolution des espèces au sein de ce large groupe. Cela découle en partie de l'absence de grands jeux de données. Dans ce travail, les auteurs ont étudié la variation pour la taille du génome aux niveaux interspécifique, intraspécifique et intracolonie chez 39 espèces de crevettes du genre Synalpheus, constituant ainsi l'un des plus grands jeux de données sur la taille des génomes au sein d'un seul genre parmi les crustacés. Les auteurs trouvent que la taille du génome va du simple au quadruple chez les Synalpheus, sans pour autant générer un signal phylogénétique ou qu'il y ait de lien avec la taille de l'organisme. Au sein de ce sous-ensemble d'espèces, la taille du génome est corrélée avec la taille des chromosomes mais pas leur nombre, ce qui suggère que les grands génomes ne sont pas le résultat de la polyploïdie de ces espèces. Ce qui est intéressant, c'est qu'il semble y avoir une variation intraspécifique pour la taille du génome de 35 % chez l'espèce Synalpheus idios, en fonction de l'origine géographique des spécimens, et jusqu'à 30 % au sein de spécimens du Synalpheus duffyi provenant de la même colonie. [Traduit par la Rédaction]

show abstract

“…Gene duplication could be beneficial by increasing the expression of fitness‐promoting gene products, as has been suggested for endopolyploidy, that is increased ploidy levels of specific tissues (Neiman, Beaton, Hessen, Jeyasingh, & Weider, 2015), but may also be nonadaptive. Potential benefits of increased accumulation of non‐protein‐coding elements are even less evident, despite the fact that genomes of most eukaryotic organisms are dominated by such elements.…”

Section: Introductionmentioning

confidence: 99%

Genome size in arthropods; different roles of phylogeny, habitat and life history in insects and crustaceans

Alfsnes

Leinaas

Hessen

2017

Ecology and Evolution

View full text Add to dashboard Cite

Despite the major role of genome size for physiology, ecology, and evolution, there is still mixed evidence with regard to proximate and ultimate drivers. The main causes of large genome size are proliferation of noncoding elements and/or duplication events. The relative role and interplay between these proximate causes and the evolutionary patterns shaped by phylogeny, life history traits or environment are largely unknown for the arthropods. Genome size shows a tremendous variability in this group, and it has a major impact on a range of fitness‐related parameters such as growth, metabolism, life history traits, and for many species also body size. In this study, we compared genome size in two major arthropod groups, insects and crustaceans, and related this to phylogenetic patterns and parameters affecting ambient temperature (latitude, depth, or altitude), insect developmental mode, as well as crustacean body size and habitat, for species where data were available. For the insects, the genome size is clearly phylogeny‐dependent, reflecting primarily their life history and mode of development, while for crustaceans there was a weaker association between genome size and phylogeny, suggesting life cycle strategies and habitat as more important determinants. Maximum observed latitude and depth, and their combined effect, showed positive, and possibly phylogenetic independent, correlations with genome size for crustaceans. This study illustrate the striking difference in genome sizes both between and within these two major groups of arthropods, and that while living in the cold with low developmental rates may promote large genomes in marine crustaceans, there is a multitude of proximate and ultimate drivers of genome size.

show abstract

Endopolyploidy as a potential driver of animal ecology and evolution

Cited by 53 publications

References 159 publications

Impacts of Nitrogen and Phosphorus: From Genomes to Natural Ecosystems and Agriculture

Impacts of Nitrogen and Phosphorus: From Genomes to Natural Ecosystems and Agriculture

Patterns of genome size variation in snapping shrimp

Genome size in arthropods; different roles of phylogeny, habitat and life history in insects and crustaceans

Contact Info

Product

Resources

About