Thorson's rule, life‐history evolution, and diversification of benthic octopuses (Cephalopoda: Octopodoidea)

Ibáñez, Christian M.; Rezende, Enrico L.; Sepúlveda, Roger D.; Avaria‐Llautureo, Jorge; Hernández, Cristián E.; Sellanes, Javier; Poulin, Élie; Pardo‐Gandarillas, M. Cecilia

doi:10.1111/evo.13559

Cited by 31 publications

(27 citation statements)

References 58 publications

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“…Such a significant phylogenetic signal can be caused by developmental or genetic constraints, a low rate of evolutionary change, strong stabilizing selection, epistatic interactions with other traits, or adaptive radiation into similar niches (Harvey & Purvis, ; Losos, ; Revell, Harmon, & Collar, ; Wiens & Graham, ). Egg size, larval size, and larval developmental mode show signs of adaptive evolution because these traits, correlated with temperature, water depth, or chlorophyll a concentration (see e.g., Ibáñez et al, for similar conclusions). The combination of both strong phylogenetic and adaptive signals could be the result of phylogenetic niche conservatism, possibly caused by adaptive radiations of closely related species into similar niches (Ackerly, ; Harvey & Purvis, ).…”

Section: Discussionmentioning

confidence: 87%

“…Thorson's rule has been tested extensively using community or comparative datasets, and explains the geographic distribution of larval developmental mode in gastropods, bivalves, chitons, octopuses, anomurans, brachyurans, peracarids, holothuroids, and ophiuroids (e.g., Collin, ; Fernández, Astorga, Navarrete, Valdovinos, & Marquet, ; Pappalardo & Fernández, ; Ibáñez et al, ; see table 1 in Ibáñez et al, for a detailed compilation of studies analyzing Thorson's rule). Interestingly, several other studies, sometimes on the same taxa, did not find support for Thorson's rule (e.g., Pearse, for holothuroids and ophiuroids, Voight, for octopuses and Stanwell‐Smith, Peck, Clarke, Murray, & Todd, for Antarctic invertebrates).…”

Section: Introductionmentioning

confidence: 99%

“…Interestingly, several other studies, sometimes on the same taxa, did not find support for Thorson's rule (e.g., Pearse, for holothuroids and ophiuroids, Voight, for octopuses and Stanwell‐Smith, Peck, Clarke, Murray, & Todd, for Antarctic invertebrates). Ibáñez et al () suggest that these contrasting findings are the result of different analytical approaches, and a general lack of phylogenetic statistics (but see Pappalardo et al, ).…”

Section: Introductionmentioning

confidence: 99%

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Testing adaptive hypotheses on the evolution of larval life history in acorn and stalked barnacles

Ewers‐Saucedo

Pappalardo

2019

Ecology and Evolution

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Despite strong selective pressure to optimize larval life history in marine environments, there is a wide diversity with regard to developmental mode, size, and time larvae spend in the plankton. In the present study, we assessed if adaptive hypotheses explain the distribution of the larval life history of thoracican barnacles within a strict phylogenetic framework. We collected environmental and larval trait data for 170 species from the literature, and utilized a complete thoracican synthesis tree to account for phylogenetic nonindependence. In accordance with Thorson's rule, the fraction of species with planktonic‐feeding larvae declined with water depth and increased with water temperature, while the fraction of brooding species exhibited the reverse pattern. Species with planktonic‐nonfeeding larvae were overall rare, following no apparent trend. In agreement with the “size advantage” hypothesis proposed by Strathmann in 1977, egg and larval size were closely correlated. Settlement‐competent cypris larvae were larger in cold water, indicative of advantages for large juveniles when growth is slowed. Planktonic larval duration, on the other hand, was uncorrelated to environmental variables. We conclude that different selective pressures appear to shape the evolution of larval life history in barnacles.

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Section: Discussionmentioning

confidence: 87%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Testing adaptive hypotheses on the evolution of larval life history in acorn and stalked barnacles

Ewers‐Saucedo

Pappalardo

2019

Ecology and Evolution

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“…The Antarctic is assumed to be another center of origin of some deep-water fauna, including some groups of octopuses (Collins and Rodhouse, 2006;Strugnell et al, 2008;Xavier et al, 2018). The high endemism of benthic octopuses in this continent was supported by the evolution toward a holobenthic development that has influenced in situ speciation (Ibáñez et al, 2018).The historical causes entail isolation of the Antarctic fauna by (i) separation of the Antarctic continent from South America and Australia; and (ii) subsequent formation of the Antarctic Circumpolar Current, as the Drake Passage and Tasman gateway opened up around 30 Mya ago (Livermore et al, 2005;Scher et al, 2015). Strugnell et al (2008) estimated that the lineage of Antarctic (and deep-sea) octopuses diverged around 33 Mya (and radiated at 15 Mya).…”

Section: Polar Endemisms and Shared Richnessmentioning

confidence: 99%

Global Patterns of Species Richness in Coastal Cephalopods

et al. 2019

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“…Considering that nearly 200 species are currently incorporated within this categorization, most of the octopod phylogenies published to date have included only few species (<30) (Carlini et al, 2001;Guzik et al, 2005;Strugnell et al, 2005;Strugnell et al, 2014), with just a few studies considering more than fifty species (see Lindgren et al, 2012;Ibáñez et al, 2014Ibáñez et al, , 2018. Incorporating much more species into octopod phylogenies seems problematic, as most species are recognized only from type material that has been fixed in formaldehyde and consequently lacks color and characters seen only in living specimens, and for which DNA sequences are not available.…”

Section: Introductionmentioning

confidence: 99%

Systematics and Phylogenetic Relationships of New Zealand Benthic Octopuses (Cephalopoda: Octopodoidea)

et al. 2020

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The systematics of the New Zealand octopods have only been reviewed twice in the last 100 years. In these revisions many species have been provisionally classified in the genus Octopus. Recent genetic studies have synonymized some New Zealand species with octopuses from other regions. The present study investigates the systematics and phylogeny of octopuses from New Zealand using eighty eight specimens, three mitochondrial genes (16S rRNA, cytochrome c oxidase subunit I, and cytochrome c oxidase subunit III) and one nuclear gene (Rhodopsin). Forty-four new octopod DNA sequences (belonging to 13 species) were included, adding to the 83 existing sequences from GenBank. All sequences were used to generate phylogenetic trees based on Maximum Likelihood (ML) and Bayesian inference (BI), with a data set composed by 97 species, including octopod sister groups and Vampyroteuthis infernalis as an outgroup. Gene tree and species delimitation analyses revealed a distinct genetic difference between two sympatric Graneledone subspecies, which we propose as valid species. Muusoctopus tangaroa is a sister species of M. thielei from Kerguelen; while Enteroctopus zealandicus forms a clade with E. megalocyathus from South America and E. dofleini from the North Pacific. Similarly, Octopus campbelli, O. huttoni, and O. mernoo form a monophyletic group with Robsonella fontaniana from South America, Scaeurgus unicirrhus from the Atlantic and O. pallidus from Australia. Pinnoctopus cordiformis is close to Grimpella thaumastocheir and several species of Octopus sensu lato as in previous phylogenetic studies. This study suggests that octopuses from New Zealand have different phylogenetic and biogeographic origins and represent independent radiations into this region.

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Thorson's rule, life‐history evolution, and diversification of benthic octopuses (Cephalopoda: Octopodoidea)

Cited by 31 publications

References 58 publications

Testing adaptive hypotheses on the evolution of larval life history in acorn and stalked barnacles

Testing adaptive hypotheses on the evolution of larval life history in acorn and stalked barnacles

Global Patterns of Species Richness in Coastal Cephalopods

Systematics and Phylogenetic Relationships of New Zealand Benthic Octopuses (Cephalopoda: Octopodoidea)

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