The influence of feeding on the evolution of sensory signals: a comparative test of an evolutionary trade‐off between masticatory and sensory functions of skulls in southern African Horseshoe bats (Rhinolophidae)

Jacobs, David S.; Bastian, Anna; Bam, Lunga

doi:10.1111/jeb.12548

Cited by 22 publications

(35 citation statements)

References 73 publications

(134 reference statements)

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“…Interestingly, all extant species of carnivorous and animalivorous bats emit echolocation calls nasally, whereas most insectivorous and both piscivorous bat species are oral echolocators. Recent work on a family of nasal echolocating bats (Rhinolophidae) demonstrated trade-offs between masticatory and sensory functions; higher bite forces, a product of a shorter rostrum, are associated with higher echolocation frequencies [76]. Simultaneously, resting frequency and pulse repetition scale negatively with bat size, and pulse duration scales positively with body mass in certain species [77,78].…”

Section: Discussionmentioning

confidence: 99%

Go big or go fish: morphological specializations in carnivorous bats

2016

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Specialized carnivory is relatively uncommon across mammals, and bats constitute one of the few groups in which this diet has evolved multiple times. While size and morphological adaptations for carnivory have been identified in other taxa, it is unclear what phenotypic traits characterize the relatively recent evolution of carnivory in bats. To address this gap, we apply geometric morphometric and phylogenetic comparative analyses to elucidate which characters are associated with ecological divergence of carnivorous bats from insectivorous ancestors, and if there is morphological convergence among independent origins of carnivory within bats, and with other carnivorous mammals. We find that carnivorous bats are larger and converged to occupy a subset of the insectivorous morphospace, characterized by skull shapes that enhance bite force at relatively wide gapes. Piscivorous bats are morphologically distinct, with cranial shapes that enable high bite force at narrow gapes, which is necessary for processing fish prey. All animal-eating species exhibit positive allometry in rostrum elongation with respect to skull size, which could allow larger bats to take relatively larger prey. The skull shapes of carnivorous bats share similarities with generalized carnivorans, but tend to be more suited for increased bite force production at the expense of gape, when compared with specialized carnivorans.

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Section: Discussionmentioning

confidence: 99%

Go big or go fish: morphological specializations in carnivorous bats

2016

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“…These adaptive complexes can also include skull shape and size because it houses features for the production and reception of sensory signals while also functioning in handling and mastication of food. This has been evident in both mammals and birds (Freeman & Lemen, 2010;Jacobs, Bastian, & Bam, 2014). Nevertheless, several studies have also implicated drift in the evolution of acoustic signals that are used in reproduction rather than orientation, for example, in Neotropical singing mice (Campbell et al, 2010), anurans (Ohmer, Robertson, & Zamudio, 2009), and in birds (Irwin, Thimgan, & Irwin, 2008).…”

Section: Introductionmentioning

confidence: 99%

The relative contribution of drift and selection to phenotypic divergence: A test case using the horseshoe bats Rhinolophus simulator and Rhinolophus swinnyi

Mutumi

Jacobs

Winker

2017

Ecology and Evolution

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Natural selection and drift can act on populations individually, simultaneously or in tandem and our understanding of phenotypic divergence depends on our ability to recognize the contribution of each. According to the quantitative theory of evolution, if an organism has diversified through neutral evolutionary processes (mutation and drift), variation of phenotypic characteristics between different geographic localities (B) should be directly proportional to the variation within localities (W), that is, B ∝ W.Significant deviations from this null model imply that non-neutral forces such as natural selection are acting on a phenotype. We investigated the relative contributions of drift and selection to intraspecific diversity using southern African horseshoe bats as a test case. We characterized phenotypic diversity across the distributional range of Rhinolophus simulator (n = 101) and Rhinolophus swinnyi (n = 125) using several traits associated with flight and echolocation. Our results suggest that geographic variation in both species was predominantly caused by disruptive natural selection (B was not directly proportional to W). Evidence for correlated selection (co-selection) among traits further confirmed that our results were not compatible with drift. Selection rather than drift is likely the predominant evolutionary process shaping intraspecific variation in traits that strongly impact fitness.

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“…RF of R. clivosus s.l. is almost 40 kHz above that expected based on body mass), which may be because selection increase bite force and then promote a decrease in snout length, and thus could in turn lead to higher frequencies (Jacobs et al ., ). Santana & Lofgren () showed that horseshoe bats in Africa and Mediterranean regions have a proportionally taller skull and a narrower rostrum with a smaller nasal capsule, which may explain partly that several species emit frequencies that are higher than what would be expected based on body size.…”

Section: Discussionmentioning

confidence: 97%

“…The nasal capsules enhance the second harmonic of the echolocation calls by forming part of a frequency-specific impedance matching system during vocalization (Hartley & Suthers, 1988;Pedersen, 1998). Differences in size and shape of the nasal capsules have been found across horseshoe bat species, and have been seen as a cause behind divergences in echolocation frequency among populations within a species (Armstrong & Coles, 2007;Odendaal & Jacobs, 2011) as well as across species (Jacobs et al, 2014). Here, we found that RF was significantly and negatively related to both NSH and PC1 extracted from the measurements of the nasal capsules among horseshoe bats.…”

Section: Discussionmentioning

confidence: 99%

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The allometry of echolocation call frequencies in horseshoe bats: nasal capsule and pinna size are the better predictors than forearm length

Jiang

Müller

et al. 2015

Journal of Zoology

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The evolution of acoustic signals and the morphological traits mediating its production and reception are often coupled. The echolocation call frequencies of horseshoe bats normally decline as body size increases, but remarkable exceptions to the rule have been observed, such as Rhinolophus macrotis, R. marshalli and R. rex, having lower echolocation call frequencies than expected for their body size. Forearm length is commonly used to scale allometric relationships across horseshoe bats. However, little is known about the allometric relationships between echolocation call frequencies and morphological traits mediating directly echolocation calls' production or reception, such as the nasal capsule, the cochlea or the pinna. Here we have tested the allometry hypothesis regarding the evolution of echolocation in 12 horseshoe bats distributed in China by integrating echolocation call frequencies, phylogeny, forearm length, cochlea size, pinna size and nasal capsule size. Our results showed no significant correlation between echolocation call frequency and forearm length across these species without considering the phylogeny of the group. However, ear length, ear width and nasal capsule size were significantly and negatively correlated with echolocation call frequencies among the studied species. The fit between the linear regression model and the data was much better for the relationships between echolocation call frequencies and pinna or nasal capsule size than for the relationship between echolocation call frequencies and forearm length. These findings illustrated that both pinna and nasal capsule size were better predictors of echolocation call frequencies than forearm length. Given that the echolocation call frequencies of horseshoe bats can play key roles in sexual selection and speciation, the divergence we observed among species may influence the evolution of echolocation calls across horseshoe bats in China.

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The influence of feeding on the evolution of sensory signals: a comparative test of an evolutionary trade‐off between masticatory and sensory functions of skulls in southern African Horseshoe bats (Rhinolophidae)

Cited by 22 publications

References 73 publications

Go big or go fish: morphological specializations in carnivorous bats

Go big or go fish: morphological specializations in carnivorous bats

The relative contribution of drift and selection to phenotypic divergence: A test case using the horseshoe bats Rhinolophus simulator and Rhinolophus swinnyi

The allometry of echolocation call frequencies in horseshoe bats: nasal capsule and pinna size are the better predictors than forearm length

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