Abstract
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.
Highlights
Genome size varies greatly both within and among various taxonomic levels of plants and animals, and a number hypotheses for the selective drivers of either small or large genome size have been proposed (Cavalier-Smith, 1978; Gregory, 2005; Lynch & Walsh, 2007)
From gBif we obtained for each species; observations of the maximum absolute latitude (MAL), maximum depth (MDE) and maximum elevation (MEL)
Regression models were evaluated for the crustaceans, with C- values as the independent variable and maximum organism size (MOS), maximum absolute latitude (MAL), maximum depth (MDE), and habitat (HAB) as dependent variables (Table 2)
Summary
Genome size varies greatly both within and among various taxonomic levels of plants and animals, and a number hypotheses for the selective drivers of either small or large genome size have been proposed (Cavalier-Smith, 1978; Gregory, 2005; Lynch & Walsh, 2007). Several processes may lead to genome enlargement or genome streamlining, which subsequently may affect a number of fitness-related traits (Petrov, 2001), such as gene activity and cell size as well as metabolic rate, growth and body size, and thereby being subject to selection (Hessen, Daufresne, & Leinaas, 2013) Over evolutionary time these processes have led to clade-specific differences in genome size at higher taxonomic levels as well as distinct variations among related species and even conspecific populations Patterns of genome size variation among organisms at different levels of taxonomic relatedness could elucidate causalities and implications, and help to distinguish between evolutionary drivers at various timescales (Gregory, 2005) To address these issues, we investigate here the genome size of the two major arthropod groups: the crustaceans (Subphylum: Crustacea) and the insects (Class: Insecta) based on publicly available data. After examining the phylogenetic distribution of the genome size, we subsequently screened for environmental effects using observational data as proxies for the organisms’ habitat
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