Environmental Complexity and Social Organization Sculpt the Brain in Lake Tanganyikan Cichlid Fish

Pollen, Alexander A.; Dobberfuhl, Adam; Scace, Justin; Igulu, Mathias M.; Renn, Susan C. P.; Shumway, Caroly A.; Hofmann, Hans A.

doi:10.1159/000101067

Cited by 250 publications

(401 citation statements)

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“…Habitat has also been shown to influence brain size in bats (Safi & Dechmann 2005) and, in Tanganyikan cichlids, habitat complexity was found to be associated with larger brains and larger cerebella, while the telencephalon showed a similar trend (Pollen et al 2007). Habitat complexity was further shown to be correlated with the number of species and number of individuals (Pollen et al 2007); however, we found that habitat and diet are correlated, but Pollen et al (2007) did not include diet in their analyses, thus its influence on brain size cannot be ruled out.…”

Section: Discussionmentioning

confidence: 99%

“…bottom-dwelling invertebrates and crustaceans) as 3; plankton and zooplankton as 4; invertebrates and crustaceans found in the water column as 5; and fishes as 6. Habitat reflected variation in complexity, previously shown to be correlated with brain structure (Pollen et al 2007): benthic and benthopelagic habitats were coded as 1; semi-pelagic as 2; sandy or shallow vegetated habitats as 3; rocky or rubble as 4; and rock habitat as 5. Pollen et al (2007) showed that sandy, rocky or rubble (intermediate) and rock habitat differ significantly in several quantitative measures of complexity, thus the categorization adequately reflects complexity.…”

Section: Methodsmentioning

confidence: 99%

“…Two previous studies have analysed the correlates of brain size and structure in African cichlid fishes and their results suggest an influence of diet and habitat (Huber et al 1997;Pollen et al 2007). Interestingly, results from one study suggest a potential effect of mating pattern on telencephalon size ( Pollen et al 2007).…”

Section: Introductionmentioning

confidence: 99%

“…However, neural structures within the brain evolve in concert in response to specific cognitive challenges as shown by the presence of 'cerebrotypes' that highlight convergent response of brain architecture to specific selection pressures (Clark et al 2001;de Winter & Oxnard 2001;Iwaniuk & Hurd 2005), such changes are expected to be reflected in total brain size. As an example of this, in Tanganyikan cichlids, whole brain size explained 50-76 per cent of the variation in all brain structures, except for the dorsal medulla where the variance explained was 18-32 per cent (Pollen et al 2007). Thus, the resulting correlates of brain size should point to factors that have a notable influence on one or several neural structures.…”

Section: Introductionmentioning

confidence: 99%

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Social fishes and single mothers: brain evolution in African cichlids

2008

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As with any organ, differences in brain size-after adequate control of allometry-are assumed to be a response to selection. With over 200 species and an astonishing diversity in niche preferences and social organization, Tanganyikan cichlids present an excellent opportunity to study brain evolution. We used phylogenetic comparative analyses of sexed adults from 39 Tanganyikan cichlid species in a multiple regression framework to investigate the influence of ecology, sexual selection and parental care patterns on whole brain size, as well as to analyse sex-specific effects. First, using species-specific measures, we analysed the influence of diet, habitat, form of care (mouthbrooding or substrate guarding), care type (biparental or female only) and intensity of sexual selection on brain size, while controlling for body size. Then, we repeated the analyses for male and female brain size separately. Type of diet and care type were significantly correlated with whole brain size. Sex-specific analyses showed that female brain size correlated significantly with care type while male brain size was uncorrelated with care type. Our results suggest that more complex social interactions associated with diet select for larger brains and further that the burden of uniparental care exerts high cognitive demands on females.

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Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Social fishes and single mothers: brain evolution in African cichlids

2008

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“…Various species of reef fish have larvae that navigate through multiple coastal ecosystems before settling (Nagelkerken 2009). For example, reef species that are associated with mangroves and seagrass beds during only their early life stage need to navigate as larvae from the open ocean, across coastal shelves that harbor coral reefs, towards bays or lagoons that harbor juvenile habitats (Pollen et al 2007, Pollux et al 2007. Potentially, larvae of such species consecutively use auditory, olfactory, and visual cues to navigate from the open ocean towards their settlement habitats (Huijbers et al 2012).…”

Section: Introductionmentioning

confidence: 99%

Orientation from open water to settlement habitats by coral reef fish: behavioral flexibility in the use of multiple reliable cues

Igulu¹,

Nagelkerken

Beek³

et al. 2013

Mar. Ecol. Prog. Ser.

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Most coastal marine organisms have a dispersive oceanic larval stage, during which they must be able to distinguish and respond to relevant environmental cues when settling into their first benthic habitat. Chemical stimuli emanating from settlement habitats and being dispersed by water plumes could enable long-distance navigation by larval reef fish, but we know little about the cues responsible and their interactive effects. In the present study, we tested this by conducting several ex situ choice experiments in which the response of the coral reef fish Lutjanus fulviflamma towards different chemical cues from coastal habitats was tested close to their settlement stage. Fish preferred seagrass habitat water over that from coral reef and mangrove habitats. Furthermore, fish were attracted to chemical cues from their own species (conspecifics) and other fish species, as well as vegetation of 4 different seagrass species, when offered in isolation (i.e. soaked in neutral water), but a strong response remained only towards cues from conspecifics and seagrass leaves when these cues were mixed with seagrass habitat water that naturally contains other cues. Hierarchical effects were observed as fish preferred chemical cues from seagrass leaves over those from conspecifics when both were offered at the same time. The importance of visual habitat cues only overruled that of chemical cues when it concerned preferred cues (i.e. seagrass as opposed to mangrove cues). Our findings indicate that pelagic fish and settlers possess the ability to use multiple reliable chemical cues to locate suitable early life stage habitats, although the importance of these cues is context-dependent. Nevertheless, this flexibility in choice behavior is probably an adaptive strategy to enhance fitness by increasing successful orientation towards preferred settlement habitats.

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