Evolution of a soft‐tissue foraging adaptation in African cichlids: Roles for novelty, convergence, and constraint

Conith, Moira R.; Conith, Andrew J.; Albertson, R. Craig

doi:10.1111/evo.13824

Cited by 17 publications

(18 citation statements)

References 75 publications

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“…Deeper ventricle shapes are typically associated with more active and athletic fish that require greater blood pressure and stroke work (Claireaux et al, 2005). LF therefore appear to develop a more athletic heart, running counter to our initial expectation that LF is a more efficient forager and should therefore expend less overall energy while feeding, compared to TRC (Conith et al, 2019a). Both species are territorial, with males vigorously defending breeding territories (Ribbink et al, 1983), and a recent study examining activity levels across cichlid species found that LF and TRC exhibit high and indistinguishable levels of activity relative to other species (Lloyd et al, 2020).…”

Section: Morphological Variation Among Hybrids Mimics Variation Obsmentioning

confidence: 73%

“…Recent studies have also demonstrated that patterns of trait covariation can span tissues with vastly different developmental origins (e.g. Martínez-Vargas et al, 2017;Conith et al, 2019a;Yamamoto et al, 2020). Taken together, it appears that patterns of integration can encompass multiple tissue types, even extending beyond structures in close physical proximity, to act as a global mechanism permitting the skull to operate as a single unit.…”

Section: Phenotypic Integration Is Present Within and Between Dispamentioning

confidence: 99%

“…As a result, TRC have a more shallow craniofacial profile, narrower and longer oral jaws, and a more gracile skull shape. While the diet of TRC is similar to LF, TRC plucks filamentous algae using a twisting and jerking method that is presumably more energetically expensive, and means they are often subjected to the turbulent waters surrounding the rocks (Conith et al, 2019a;Konings, 2007).…”

Section: Hybrid Populationmentioning

confidence: 99%

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Weak genetic signal for phenotypic integration implicates developmental processes as major regulators of trait covariation

et al. 2020

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Phenotypic integration (i.e. the degree of covariation among traits) is an important and ubiquitous feature of multicellular organisms that shapes functionality within and among structures. Integration can permit or limit the accumulation of morphological variation by partitioning traits into distinct subunits (i.e. modules) and then varying the degree of association among these subunits (Goswami et al., 2014; Klingenberg, 2008). Recent research has demonstrated that differences among populations in the pattern and magnitude of phenotypic integration can have major consequences for taxonomic diversification, rates of morphological evolution, and the ability of a population to respond to selection (

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Section: Morphological Variation Among Hybrids Mimics Variation Obsmentioning

confidence: 73%

Section: Phenotypic Integration Is Present Within and Between Dispamentioning

confidence: 99%

Section: Hybrid Populationmentioning

confidence: 99%

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Weak genetic signal for phenotypic integration implicates developmental processes as major regulators of trait covariation

et al. 2020

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“…This species exhibits significant habitat and dietary overlap with L. fuelleborni, another algae foraging species from the rocky shallows. L. fuelleborni is arguably one of the most ecologically successful species in the lake, with numerous anatomical adaptations that enable it to dominate this niche [31,[44][45][46]. How then might another species coexist with such a well-adapted forager?…”

Section: Discussionmentioning

confidence: 99%

Diversity in rest-activity patterns among Lake Malawi cichlid fishes suggests novel axis of habitat partitioning

Lloyd

Chhouk

Keene

et al. 2020

Preprint

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Animals display remarkable diversity in rest and activity patterns that are regulated by endogenous foraging strategies, social behaviors, and predator avoidance. Alteration in the circadian timing of activity or the duration of rest-wake cycles provide a central mechanism for animals to exploit novel niches. The diversity of the 3000 cichlid species throughout the world provides a unique opportunity to examine variation in locomotor activity and rest. Lake Malawi alone is home to over 500 species of cichlids that display divergent behaviors and inhabit well-defined niches throughout the lake. These species are presumed to be diurnal, though this has never been tested systematically. Here, we measure locomotor activity across the circadian cycle in 12 cichlid species from divergent lineages and distinct habitats. We document surprising variability in the circadian time of locomotor activity and the duration of rest. In particular, we identify a single species, Tropheops sp. red cheek that is nocturnal. Nocturnal behavior was maintained when fish were provided shelter, but not under constant darkness, suggesting it results from acute response to light rather than an endogenous circadian rhythm. Finally, we show that nocturnality is associated with increased eye size, suggesting a link between visual processing and nighttime activity. Together, these findings identify diversity of locomotor behavior in Lake Malawi cichlids and provide a system for investigating the molecular and neural basis underlying the evolution of nocturnal activity.

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“…Labeotropheus cichlids is used as a fulcrum, allowing fish to more easily crop algae from rocks 111 versus the bite-and-twist method observed in other cichlid species (Konings 2007;Conith et al 112 2018), and specifically that increased snout depth may help create this mechanical advantage 113 (Conith et al 2019). A similar method may be used during oral shelling to amplify force while 114 removing snails from their shells.…”

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confidence: 99%

Function of a novel nasal protrusion for oral-shelling within an adaptive radiation of pupfishes

John

Dixon

Martin

2020

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293 words, Main text plus references: 4988 words, 3 Figures, Supplemental Figures 29 S1&S2, and 1 Supplemental video S1 30 31 2 Significance Statement 32Specialization on hard-shell prey items (i.e. durophagy) is a common dietary niche among fishes. 33Oral shelling is a rare technique used by some durophagous fish to consume prey items like 34 snails; however, adaptations for oral shelling are still unknown. Here, we document the first 35 evidence of oral shelling in a cyprinodontiform fish, the durophagous pupfish (Cyprinodon 36 brontotheroides), and experimentally test whether its novel nasal protrusion is an adaptation for 37 oral shelling using hybrid feeding trials. Abstract 55Dietary specialization on hard prey items, such as mollusks and crustaceans, is commonly 56 observed in a diverse array of fish species. Many fish consume these types of prey by crushing 57 the shell to consume the soft tissue within, but a few fishes extricate the soft tissue without 58 breaking the shell using a method known as oral shelling. Oral shelling involves pulling a 59 mollusk from its shell and may be a way to subvert an otherwise insurmountable shell defense. 60However, the biomechanical requirements and potential adaptations for oral shelling are 61 unknown. Here, we test the hypothesis that a novel nasal protrusion is an adaptation for oral 62 shelling in a durophagous pupfish (Cyprinodon brontotheroides). We first demonstrate oral 63 shelling in this species and then predicted that a larger nasal protrusion would allow pupfish to 64 consume larger snails. Durophagous pupfish are found within an endemic radiation of pupfish on 65 San Salvador Island, Bahamas. We took advantage of closely related sympatric species and 66 outgroups to test: 1) whether durophagous pupfish shell and consume more snails than other 67 species, 2) if F1 and F2 durophagous hybrids consume similar amounts of snails as purebred 68 durophagous pupfish, and 3) to determine if nasal protrusion size in parental and hybrid 69 populations increases the maximum diameter snail consumed. We found that durophagous 70 pupfish and their hybrids consumed the most snails, but did not find a strong association between 71 nasal protrusion size and maximum snail size consumed within the parental or F2 hybrid 72 population, suggesting that the size of their novel nasal protrusion does not provide a major 73 benefit in oral shelling. Instead, we suggest that nasal protrusion may increase feeding efficiency, 74 act as a sensory organ, or is a sexually selected trait, and that a strong feeding preference may be 75 most important for oral shelling. 76 77 4 Introduction 78

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Evolution of a soft‐tissue foraging adaptation in African cichlids: Roles for novelty, convergence, and constraint

Cited by 17 publications

References 75 publications

Weak genetic signal for phenotypic integration implicates developmental processes as major regulators of trait covariation

Weak genetic signal for phenotypic integration implicates developmental processes as major regulators of trait covariation

Diversity in rest-activity patterns among Lake Malawi cichlid fishes suggests novel axis of habitat partitioning

Function of a novel nasal protrusion for oral-shelling within an adaptive radiation of pupfishes

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