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1. The cichlid oral and pharyngeal jaws are evolutionarily and genetically coupled

Author

Andrew J. Conith and R. Craig Albertson

Subjects
Science
Abstract

Modular, rather than integrated systems are classically thought to allow functional diversity to evolve rapidly. A study of cichlid fish shows integration between divergent jaw systems at the phylogenetic, population, and genetic scales, suggesting integration can and does facilitate rapid, coordinated trait evolution.

Published
2021
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2. Rapid morphological change in multiple cichlid ecotypes following the damming of a major clearwater river in Brazil

Author

Michelle C. Gilbert, Alberto Akama, Cristina Cox Fernandes, and R. Craig Albertson

Subjects
adaptation, anthropogenic change, contemporary evolution, geometric morphometrics, phenotypic plasticity, Evolution, QH359-425
Abstract

Abstract While anthropogenic disturbances can have damaging effects on biodiversity, they also offer an opportunity to understand how species adapt to new environments and may even provide insights into the earliest stages of evolutionary diversification. With these topics in mind, we explored the morphological changes that have occurred across several cichlid species following the damming of the Tocantins River, Brazil. The Tocantins was once a large (2,450 km), contiguous river system; however, upon closure of the Tucuruí Hydroelectric Dam in 1984, a large (~2,850 km2), permanent reservoir was established. We used geometric morphometrics to evaluate changes in native cichlids, comparing historical museum specimens collected from the Tocantins to contemporary specimens collected from the Tucuruí reservoir. Six species across five genera were included to represent distinct ecomorphs, from large piscivores to relatively small opportunistic omnivores. Notably, statistically significant changes in shape and morphological disparity were observed in all species. Moreover, the documented changes tended to be associated with functionally relevant aspects of anatomy, including head, fin, and body shape. Our data offer insights into the ways cichlids have responded, morphologically, to a novel lake environment and provide a robust foundation for exploring the mechanisms through which these changes have occurred.

Published
2020
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3. Ecomorphological divergence and habitat lability in the context of robust patterns of modularity in the cichlid feeding apparatus

Author

Andrew J. Conith, Michael R. Kidd, Thomas D. Kocher, and R. Craig Albertson

Subjects
Cichlid, Morphometrics, Modularity, Integration, Morphological evolution, Evolution, QH359-425
Abstract

Abstract Background Adaptive radiations are characterized by extreme and/or iterative phenotypic divergence; however, such variation does not accumulate evenly across an organism. Instead, it is often partitioned into sub-units, or modules, which can differentially respond to selection. While it is recognized that changing the pattern of modularity or the strength of covariation (integration) can influence the range or rate of morphological evolution, the relationship between shape variation and covariation remains unclear. For example, it is possible that rapid phenotypic change requires concomitant changes to the underlying covariance structure. Alternatively, repeated shifts between phenotypic states may be facilitated by a conserved covariance structure. Distinguishing between these scenarios will contribute to a better understanding of the factors that shape biodiversity. Here, we explore these questions using a diverse Lake Malawi cichlid species complex, Tropheops, that appears to partition habitat by depth. Results We construct a phylogeny of Tropheops populations and use 3D geometric morphometrics to assess the shape of four bones involved in feeding (mandible, pharyngeal jaw, maxilla, pre-maxilla) in populations that inhabit deep versus shallow habitats. We next test numerous modularity hypotheses to understand whether fish at different depths are characterized by conserved or divergent patterns of modularity. We further examine rates of morphological evolution and disparity between habitats and among modules. Finally, we raise a single Tropheops species in environments mimicking deep or shallow habitats to discover whether plasticity can replicate the pattern of morphology, disparity, or modularity observed in natural populations. Conclusions Our data support the hypothesis that conserved patterns of modularity permit the evolution of divergent morphologies and may facilitate the repeated transitions between habitats. In addition, we find the lab-reared populations replicate many trends in the natural populations, which suggests that plasticity may be an important force in initiating depth transitions, priming the feeding apparatus for evolutionary change.

Published
2020
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4. Ontogeny and social context regulate the circadian activity patterns of Lake Malawi cichlids

Author

Evan Lloyd, Aakriti Rastogi, Niah Holtz, Ben Aaronson, R. Craig Albertson, and Alex C. Keene

Abstract

Activity patterns tend to be highly stereotyped and critical for executing many different behaviors including foraging, social interactions and predator avoidance. Differences in the circadian timing of locomotor activity and rest periods can facilitate habitat partitioning and the exploitation of novel niches. As a consequence, closely related species often display highly divergent activity patterns, raising the possibility that a shift from diurnal to nocturnal behavior, or vice versa, can occur rapidly. In Africa’s Lake Malawi alone, there are over 500 species of cichlids, which inhabit diverse environments and exhibit extensive phenotypic variation. We have previously identified a substantial range in activity patterns across adult Lake Malawi cichlid species, from strongly diurnal to strongly nocturnal. In many species, including fishes, ecological pressures differ dramatically across life-history stages, raising the possibility that activity patterns may change over ontogeny. To determine if rest-activity patterns change across life stages we compared the locomotor patterns of six Lake Malawi cichlid species. While total rest and activity did not change between early juvenile and adult stages, rest-activity patterns did, with juveniles displaying distinct activity rhythms that are more robust than adults. One distinct difference between juveniles and adults is the emergence of complex social behavior. To determine whether social context is required for activity rhythms, we next measured locomotor behavior in group housed adult fish. We found that when normal social interactions were allowed, locomotor activity patterns were restored, supporting the notion that social interactions promote circadian regulation of activity in adult fish. These findings reveal a previously unidentified link between developmental stage and social interactions in the circadian timing of cichlid activity.

Published
2023
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6. Breaking constraints: The development and evolution of extreme fin morphology in the Bramidae

Author

Michelle C. Gilbert, Catherine S. Lerose, Andrew J. Conith, and R. Craig Albertson

Subjects
Animal Fins, Fishes, Animals, Selection, Genetic, Biological Evolution, Phylogeny, Ecology, Evolution, Behavior and Systematics, Developmental Biology
Abstract

The developmental process establishes the foundation upon which natural selection may act. In that same sense, it is inundated with numerous constraints that work to limit the directions in which a phenotype may respond to selective pressures. Extreme phenotypes have been used in the past to identify tradeoffs and constraints and may aid in recognizing how alterations to the Baupläne can influence the trajectories of lineages. The Bramidae, a family of Scombriformes consisting of 20 extant species, are unique in that five species greatly deviate from the stout, ovaloid bodies that typify the bramids. The Ptericlinae, or fanfishes, are instead characterized by relatively elongated body plans and extreme modifications to their medial fins. Here, we explore the development of Bramidae morphologies and examine them through a phylogenetic lens to investigate the concepts of developmental and evolutionary constraints. Contrary to our predictions that the fanfishes had been constrained by inherited properties of an ancestral state, we find that the fanfishes exhibit both increased rates of trait evolution and differ substantially from the other bramids in their developmental trajectories. Conversely, the remaining bramid genera differ little, both among one another and in comparison, to the sister family Caristiidae. In all, our data suggest that the fanfishes have broken constraints, thereby allowing them to mitigate trade-offs on distinctive aspects of morphology.

Published
2022
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8. The transcriptional state and chromatin landscape of cichlid jaw shape variation across species and environments

Author

Emily Tetrault, John Swenson, Ben Aaronson, Chelsea Marcho, and R. Craig Albertson

Subjects
Genetics, Ecology, Evolution, Behavior and Systematics
Abstract

Adaptive phenotypes are shaped by a combination of genetic and environmental forces, and while the literature is rich with studies focusing on either genetics or environment contributions, those that consider both are rare. Here we utilize the cichlid oral jaw apparatus to fill this knowledge-gap. First, we employed RNA-seq in bony and ligamentous tissues important for jaw opening to identify differentially expressed genes between species and across foraging environments. Our foraging treatments were designed to force animals to employ either suction or biting/scraping, which broadly mimic pelagic or benthic modes of feeding. We found a large number of differentially expressed genes between species, and while we identified relatively few differences between environments, species differences were far more pronounced when reared in the pelagic versus benthic environment. Further, these data carried the signature of genetic assimilation, and implicated cell cycle regulation in shaping the jaw across species and environments. Next, we repeated the foraging experiment and performed ATAC-seq procedures on nuclei harvested from the same tissues. Cross-referencing results from both analyses revealed subsets of genes that were both differentially expressed and differentially accessible in either the pelagic (n=15) or the benthic environment (n=11), as well as loci where differences were robust to foraging environment (n=13). All in all, these data provide novel insights into the epigenetic, genetic, and cellular bases of species- and environment-specific bone shapes, as well as the evolution of phenotypic plasticity in this iconic model system.

Published
2022
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9. Substrate type induces plastic responses in the craniofacial morphology of a winnowing cichlid

Author

Michelle C. Gilbert, Sofia N. Piggott, and R. Craig Albertson

Subjects
Aquatic Science
Abstract

Understanding how local populations respond to specific changes in the environment can help us better predict how populations respond to such change. With this topic in mind, we followed up on a previous study by exploring the capabilities of a Geophagini cichlid, known for its unique feeding strategy, to mount a plastic response. We exposed Satanoperca daemon, a winnowing cichlid, to three different substrate types, two of which encouraged winnowing behaviors and a third that prevented winnowing entirely. Using geometric morphometrics, we quantified aspects of craniofacial anatomy to test for morphological differences between the treatments and to test for the integration of different traits across the head. We found significant differences across our experimental populations in both shape and disparity. We report evidence in support of wide-spread integration across craniofacial traits. A notable exception to this pattern was the epibranchial lobe, a structure unique to the Geophagini, which exhibited more modular variation. Since anthropogenic alterations such as the damming of rivers can impact substrate type, these data offer insights into how Geophagini cichlids may respond to environmental change. In addition, this work further illuminates the functional morphology of winnowing foraging behaviors.

Published
2022
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10. Covariation of brain and skull shapes as a model to understand the roles for crosstalk in development and evolution

Author

Andrew J. Conith, Sylvie A. Hope, and R. Craig Albertson

Subjects
Ecology, Evolution, Behavior and Systematics, Article, Developmental Biology
Abstract

Covariation among discrete phenotypes can arise due to selection for shared functions, and/or shared genetic and developmental underpinnings. The consequences for such phenotypic integration are far-reaching, and can act to either facilitate or limit morphological variation. The vertebrate brain is known to act as an ‘organizer’ of craniofacial development, secreting morphogens that can affect the shape of the growing neurocranium, consistent with roles for pleiotropy in brain-neurocranium covariation. Here we test this hypothesis in cichlid fishes by first examining the degree of shape integration between the brain and neurocranium using 3D geometric morphometrics in an F(5) hybrid population, and then genetically mapping trait covariation using quantitative trait loci (QTL) analysis. We observe shape associations between the brain and neurocranium, a pattern that holds even when we assess associations between the brain and constituent parts of the neurocranium: the rostrum and braincase. We also recover robust genetic signals for both hard- and soft-tissue traits, and identify a genomic region where QTL for the brain and braincase overlap, implicating a role for pleiotropy in patterning trait covariation. Fine mapping of the overlapping genomic region identifies a candidate gene, notch1a, which is known to be involved in patterning skeletal and neural tissues during development. Taken together, these data offer a genetic hypothesis for brain-neurocranium covariation, as well as a potential mechanism by which behavioral shifts may simultaneously drive rapid change in neuroanatomy and craniofacial morphology.

Published
2022

11. The cichlid oral and pharyngeal jaws are evolutionarily and genetically coupled

Author

R. Craig Albertson and Andrew J. Conith

Subjects
Male, Candidate gene, Science, Quantitative Trait Loci, Foraging, Prey capture, General Physics and Astronomy, Locus (genetics), Context (language use), Biology, Quantitative trait, Article, General Biochemistry, Genetics and Molecular Biology, stomatognathic system, Cichlid, Animals, Pharyngeal jaw, Ecosystem, Mouth, Multidisciplinary, Cichlids, Feeding Behavior, Sequence Analysis, DNA, X-Ray Microtomography, General Chemistry, biology.organism_classification, Biological Evolution, stomatognathic diseases, Jaw, Evolutionary biology, Pharynx, Female, Evolutionary developmental biology, Lod Score, Molecular ecology, human activities, Adaptive evolution
Abstract

Evolutionary constraints may significantly bias phenotypic change, while “breaking” from such constraints can lead to expanded ecological opportunity. Ray-finned fishes have broken functional constraints by developing two jaws (oral-pharyngeal), decoupling prey capture (oral jaw) from processing (pharyngeal jaw). It is hypothesized that the oral and pharyngeal jaws represent independent evolutionary modules and this facilitated diversification in feeding architectures. Here we test this hypothesis in African cichlids. Contrary to our expectation, we find integration between jaws at multiple evolutionary levels. Next, we document integration at the genetic level, and identify a candidate gene, smad7, within a pleiotropic locus for oral and pharyngeal jaw shape that exhibits correlated expression between the two tissues. Collectively, our data show that African cichlid evolutionary success has occurred within the context of a coupled jaw system, an attribute that may be driving adaptive evolution in this iconic group by facilitating rapid shifts between foraging habitats, providing an advantage in a stochastic environment such as the East African Rift-Valley., Modular, rather than integrated systems are classically thought to allow functional diversity to evolve rapidly. A study of cichlid fish shows integration between divergent jaw systems at the phylogenetic, population, and genetic scales, suggesting integration can and does facilitate rapid, coordinated trait evolution.

Published
2021

13. Ciliary Rootlet Coiled-Coil 2 (crocc2) Is Associated with Evolutionary Divergence and Plasticity of Cichlid Jaw Shape

Author

Emily R. Tetrault, Mary Packard, R. Craig Albertson, Dina Navon, and Michelle C Gilbert

Subjects
0106 biological sciences, Male, Genetic Speciation, Plasticity, AcademicSubjects/SCI01180, craniofacial, 010603 evolutionary biology, 01 natural sciences, phenotypic plasticity, 03 medical and health sciences, Cichlid, Adaptive radiation, Genetics, Ciliary rootlet, Animals, eco-devo, Molecular Biology, Zebrafish, Ecology, Evolution, Behavior and Systematics, Discoveries, 030304 developmental biology, 0303 health sciences, Phenotypic plasticity, biology, Cilium, AcademicSubjects/SCI01130, cilia, Cichlids, biology.organism_classification, Adaptation, Physiological, Cytoskeletal Proteins, Jaw, Evolutionary biology, Developmental plasticity, mechanosensing, Female, human activities
Abstract

Cichlid fishes exhibit rapid, extensive, and replicative adaptive radiation in feeding morphology. Plasticity of the cichlid jaw has also been well documented, and this combination of iterative evolution and developmental plasticity has led to the proposition that the cichlid feeding apparatus represents a morphological “flexible stem.” Under this scenario, the fixation of environmentally sensitive genetic variation drives evolutionary divergence along a phenotypic axis established by the initial plastic response. Thus, if plasticity is predictable then so too should be the evolutionary response. We set out to explore these ideas at the molecular level by identifying genes that underlie both the evolution and plasticity of the cichlid jaw. As a first step, we fine-mapped an environment-specific quantitative trait loci for lower jaw shape in cichlids, and identified a nonsynonymous mutation in the ciliary rootlet coiled-coil 2 (crocc2), which encodes a major structural component of the primary cilium. Given that primary cilia play key roles in skeletal mechanosensing, we reasoned that this gene may confer its effects by regulating the sensitivity of bone to respond to mechanical input. Using both cichlids and zebrafish, we confirmed this prediction through a series of experiments targeting multiple levels of biological organization. Taken together, our results implicate crocc2 as a novel mediator of bone formation, plasticity, and evolution.

Published
2021

14. The genetic basis of coordinated plasticity across functional units in a Lake Malawi cichlid mapping population

Author

Paul Hatini, R. Craig Albertson, Dina Navon, and Lily Zogbaum

Subjects
Male, 0106 biological sciences, 0301 basic medicine, Modularity (biology), Quantitative Trait Loci, Population, Plasticity, Quantitative trait locus, Biology, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, Cichlid, Genetics, Animals, education, Ecology, Evolution, Behavior and Systematics, Patterns of evolution, Phenotypic plasticity, education.field_of_study, Cichlids, Feeding Behavior, biology.organism_classification, Adaptation, Physiological, Biological Evolution, Diet, Evolvability, Lakes, 030104 developmental biology, Evolutionary biology, Female, General Agricultural and Biological Sciences
Abstract

Adaptive radiations are often stereotypical, as populations repeatedly specialize along conserved environmental axes. Phenotypic plasticity may be similarly stereotypical, as individuals respond to environmental cues. These parallel patterns of variation, which are often consistent across traits, have led researchers to propose that plasticity can facilitate predictable patterns of evolution along environmental gradients. This "flexible stem" model of evolution raises questions about the genetic nature of plasticity, including how complex is the genetic basis for plasticity? Is plasticity across traits mediated by many distinct loci, or few "global" regulators? To address these questions, we reared a hybrid cichlid mapping population on alternate diet regimes mimicking an important environmental axis. We show that plasticity across an array of ecologically relevant traits is generally morphologically integrated, such that traits respond in a coordinated manner, especially those with overlapping function. Our genetic data are more ambiguous. While our mapping experiment provides little evidence for global genetic regulators of plasticity, these data do contain a genetic signal for the integration of plasticity across traits. Overall, our data suggest a compromise between genetic modularity, whereby plasticity may evolve independently across traits, and low level but widespread genetic integration, establishing the potential for plasticity to experience coordinated evolution.

Published
2021
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15. Weak genetic signal for phenotypic integration implicates developmental processes as major regulators of trait covariation

Author

Sylvie A Hope, R. Craig Albertson, Andrew J. Conith, and Brian Chhouk

Subjects
0106 biological sciences, 0301 basic medicine, Genotype, Ontogeny, Quantitative Trait Loci, Population, Quantitative trait locus, Biology, 010603 evolutionary biology, 01 natural sciences, Article, 03 medical and health sciences, Genetics, Animals, education, Ecology, Evolution, Behavior and Systematics, Morphometrics, education.field_of_study, Phenotypic integration, Cichlids, Phenotype, Qtl analysis, 030104 developmental biology, Evolutionary biology, Trait
Abstract

Phenotypic integration is an important metric that describes the degree of covariation among traits in a population, and is hypothesized to arise due to selection for shared functional processes. Our ability to identify the genetic and/or developmental underpinnings of integration is marred by temporally overlapping cell-, tissue-, and structure-level processes that serve to continually ‘overwrite’ the structure of covariation among traits through ontogeny. Here we examine whether traits that are integrated at the phenotypic level, also exhibit a shared genetic basis (e.g., pleiotropy). We micro-CT scanned two hard tissue traits, and two soft tissue traits (mandible, pectoral girdle, atrium, and ventricle respectively) from an F(5) hybrid population of Lake Malawi cichlids, and used geometric morphometrics to extract 3D shape information from each trait. Given the large degree of asymmetric variation that may reflect developmental instability, we separated symmetric- from asymmetric-components of shape variation. We then performed quantitative trait loci (QTL) analysis to determine the degree of genetic overlap between shapes. While we found ubiquitous associations among traits at the phenotypic level, except for a handful of notable exceptions, our QTL analysis revealed few overlapping genetic regions. Taken together, this indicates developmental interactions can play a large role in determining the degree of phenotypic integration among traits, and likely obfuscate the genotype to phenotype map, limiting our ability to gain a comprehensive picture of the genetic contributors responsible for phenotypic divergence.

Published
2020
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16. Hedgehog signaling is necessary and sufficient to mediate craniofacial plasticity in teleosts

Author

Ira Male, Dina Navon, Benjamin Aaronson, Rolf O. Karlstrom, R. Craig Albertson, and Emily R. Tetrault

Subjects
ecodevo, Fish Proteins, Evolution, Foraging, Plasticity, craniofacial, phenotypic plasticity, flexible stem, Cichlid, Animals, Hedgehog Proteins, Craniofacial, Hedgehog, Phenotypic plasticity, Multidisciplinary, biology, Skull, Cichlids, Biological Sciences, biology.organism_classification, Phenotype, hedgehog signaling, Adaptation, Physiological, Hedgehog signaling pathway, Evolutionary biology, Signal Transduction
Abstract

Significance Phenotypic plasticity has emerged as an important concept in evolutionary biology. It is thought to contribute to an organism’s ability to adapt to environmental change within a single generation, which may facilitate survival and increase fitness. Furthermore, plasticity has the potential to bias the direction and/or speed of evolution by changing patterns of phenotypic variation and exposing new genetic variation to selection (i.e., flexible stem evolution). Our understanding of this important phenomenon is incomplete owing to limited knowledge of the molecular underpinnings of reaction norm evolution. Using the teleost feeding apparatus as a model, we explore this open question and show that the Hh signaling pathway underlies the ability of this structure to respond plastically to alternate feeding regimes., Phenotypic plasticity, the ability of a single genotype to produce multiple phenotypes under different environmental conditions, is critical for the origins and maintenance of biodiversity; however, the genetic mechanisms underlying plasticity as well as how variation in those mechanisms can drive evolutionary change remain poorly understood. Here, we examine the cichlid feeding apparatus, an icon of both prodigious evolutionary divergence and adaptive phenotypic plasticity. We first provide a tissue-level mechanism for plasticity in craniofacial shape by measuring rates of bone deposition within functionally salient elements of the feeding apparatus in fishes forced to employ alternate foraging modes. We show that levels and patterns of phenotypic plasticity are distinct among closely related cichlid species, underscoring the evolutionary potential of this trait. Next, we demonstrate that hedgehog (Hh) signaling, which has been implicated in the evolutionary divergence of cichlid feeding architecture, is associated with environmentally induced rates of bone deposition. Finally, to demonstrate that Hh levels are the cause of the plastic response and not simply the consequence of producing more bone, we use transgenic zebrafish in which Hh levels could be experimentally manipulated under different foraging conditions. Notably, we find that the ability to modulate bone deposition rates in different environments is dampened when Hh levels are reduced, whereas the sensitivity of bone deposition to different mechanical demands increases with elevated Hh levels. These data advance a mechanistic understanding of phenotypic plasticity in the teleost feeding apparatus and in doing so contribute key insights into the origins of adaptive morphological radiations.

Published
2020

17. Polygenic sex determination produces modular sex polymorphism in an African cichlid fish

Author

Emily C. Moore, Patrick J. Ciccotto, Erin N. Peterson, Melissa S. Lamm, R. Craig Albertson, and Reade B. Roberts

Subjects
Male, Sex Characteristics, Phenotype, Polymorphism, Genetic, Sex Chromosomes, Multidisciplinary, Animals, Female, Cichlids, Genetic Fitness, Sex Determination Processes
Abstract

For many vertebrates, a single genetic locus initiates a cascade of developmental sex differences in the gonad and throughout the organism, resulting in adults with two phenotypically distinct sexes. Species with polygenic sex determination (PSD) have multiple interacting sex determination alleles segregating within a single species, allowing for more than two genotypic sexes and scenarios where sex genotype at a given locus can be decoupled from gonadal sex. Here we investigate the effects of PSD on secondary sexual characteristics in the cichlid fish Metriaclima mbenjii, where one female (W) and one male (Y) sex determination allele interact to produce siblings with four possible sex classes: ZZXX females, ZWXX females, ZWXY females, and ZZXY males. We find that PSD in M. mbenjii produces an interplay of sex linkage and sex limitation resulting in modular variation in morphological and behavioral traits. Further, the evolution or introgression of a newly acquired sex determiner creates additional axes of phenotypic variation for varied traits, including genital morphology, craniofacial morphology, gastrointestinal morphology, and home tank behaviors. In contrast to single-locus sex determination, which broadly results in sexual dimorphism, polygenic sex determination can induce higher-order sexual polymorphism. The modularity of secondary sexual characteristics produced by PSD provides context for understanding the evolutionary causes and consequences of maintenance, gain, or loss of sex determination alleles in populations.

Published
2022
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18. A brain-wide analysis maps structural evolution to distinct anatomical modules

Author

Robert A. Kozol, Andrew J. Conith, Anders Yuiska, Alexia Cree-Newman, Bernadeth Tolentino, Kasey Banesh, Alexandra Paz, Evan Lloyd, Johanna E. Kowalko, Alex C. Keene, R. Craig Albertson, and Erik R. Duboue

Abstract

Brain anatomy is highly variable and it is widely accepted that anatomical variation impacts brain function and ultimately behavior. The structural complexity of the brain, including differences in volume and shape, presents an enormous barrier to define how variability underlies differences in function. In this study, we sought to investigate the evolution of brain anatomy in relation to brain region volume and shape across the brain of a single species with variable genetic and anatomical morphs. We generated a high-resolution brain atlas for the blind Mexican cavefish and coupled the atlas with automated computational tools to directly assess brain region shape and volume variability across all populations. We measured the volume and shape of every neuroanatomical region of the brain and assess correlations between anatomical regions in surface, cavefish and surface to cave F2 hybrids, whose phenotypes span the range of surface to cave. We find that dorsal regions of the brain are contracted in cavefish, while ventral regions have expanded. Interestingly, in hybrid fish the volume and shape of dorsal regions are inversely proportional to ventral regions. This trend is true for both volume and shape, suggesting that these two parameters share developmental mechanisms necessary for remodeling the entire brain. Given the high conservation of brain anatomy and function among vertebrate species, we expect these data to studies reveal generalized principles of brain evolution and show that Astyanax provides a system for functionally determining basic principles of brain evolution by utilizing the independent genetic diversity of different morphs, to test how genes influence early patterning events to drive brain-wide anatomical evolution.

Published
2022
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19. Polygenic sex determination produces modular sex polymorphism in an African cichlid fish

Author

R. Craig Albertson, Melissa S. Lamm, Erin N. Peterson, Reade B. Roberts, Emily C. Moore, and Patrick J. Ciccotto

Subjects
Sexual dimorphism, Gonad, medicine.anatomical_structure, biology, Cichlid, Evolutionary biology, Secondary sex characteristic, medicine, Sex organ, Context (language use), Locus (genetics), Allele, biology.organism_classification
Abstract

For many vertebrates, a single genetic locus initiates a cascade of developmental sex differences in the gonad and throughout the organism, resulting in adults with two, phenotypically distinct sexes. Species with polygenic sex determination (PSD) have multiple interacting sex determination alleles segregating within a single species, allowing for more than two genotypic sexes, and scenarios where sex genotype at a given locus can be decoupled from gonadal sex. Here we investigate the effects of PSD on secondary sexual characteristics in the cichlid fish Metriaclima mbenjii, where one female (W) and one male (Y) sex determination allele interact to produce siblings with four possible sex classes: ZZXX females, ZWXX females, ZWXY females, and ZZXY males. We find that PSD in M. mbenjii produces an interplay of sex-linkage and sex-limitation resulting in modular variation in morphological and behavioral traits. Further, the evolution or introgression of a novel sex determiner creates additional axes of phenotypic variation for varied traits, including genital morphology, craniofacial morphology, gastrointestinal morphology, and home tank behaviors. In contrast to single-locus sex determination, which broadly results in sexual dimorphism, polygenic sex determination can induce higher-order sexual polymorphism. The modularity of secondary sexual characteristics produced by PSD provides novel context for understanding the evolutionary causes and consequences of maintenance, gain, or loss of sex determination alleles in populations.Significance StatementSex differences in traits can occur when those traits are modified by genetic factors inherited on sex chromosomes. We investigated how sex differences emerge in a species with more than one set of sex chromosomes, measuring a variety of morphological, physiological, and behavioral traits. Rather than exhibiting sexual dimorphism associated with primary sex, the species has higher-order sexual polymorphism in secondary sexual characteristics, or more than two phenotypic sexes. Variation in secondary sexual characteristics is modular, involving the interplay of sex-linked and sex-limited traits. Our findings provide novel implications for how sex determination systems and whole-organism fitness traits co-evolve, including that significant creation or loss of variation in diverse traits can occur during transitions among sex chromosome systems.

Published
2021
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21. Extreme Morphology, Functional Trade-offs, and Evolutionary Dynamics in a Clade of Open-Ocean Fishes (Perciformes: Bramidae)

Author

Catherine S Lerose, Steve Huskey, R. Craig Albertson, Michelle C Gilbert, Andrew J. Conith, and Joshua K. Moyer

Subjects
0106 biological sciences, 0301 basic medicine, Fin, Phylogenetic tree, Range (biology), Lineage (evolution), Plant Science, Biology, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Perciformes, Dorsal fin, 03 medical and health sciences, 030104 developmental biology, Phylogenetics, Evolutionary biology, AcademicSubjects/SCI00960, Animal Science and Zoology, Evolutionary dynamics, Ecology, Evolution, Behavior and Systematics, Research Article
Abstract

SynopsisWhen novel or extreme morphologies arise, they are oft met with the burden of functional trade-offs in other aspects of anatomy, which may limit phenotypic diversification and make particular adaptive peaks inaccessible. Bramids (Perciformes: Bramidae) comprise a small family of 20 extant species of fishes, which are distributed throughout pelagic waters worldwide. Within the Bramidae, the fanfishes (Pteraclis and Pterycombus) differ morphologically from the generally stout, laterally compressed species that typify the family. Instead, Pteraclis and Pterycombus exhibit extreme anterior positioning of the dorsal fin onto the craniofacial skeleton. Consequently, they possess fin and skull anatomies that are radically different from other bramid species. Here, we investigate the anatomy, development, and evolution of the Bramidae to test the hypothesis that morphological innovations come at functional (proximate) and evolutionary (ultimate) costs. Addressing proximate effects, we find that the development of an exaggerated dorsal fin is associated with neurocrania modified to accommodate an anterior expansion of the dorsal fin. This occurs via reduced development of the supraoccipital crest (SOC), providing a broad surface area on the skull for insertion of the dorsal fin musculature. While these anatomical shifts are presumably associated with enhanced maneuverability in fanfishes, they are also predicted to result in compromised suction feeding, possibly limiting the mechanisms of feeding in this group. Phylogenetic analyses suggest craniofacial and fin morphologies of fanfishes evolved rapidly and are evolutionarily correlated across bramids. Furthermore, fanfishes exhibit a similar rate of lineage diversification as the rest of the Bramidae, lending little support for the prediction that exaggerated medial fins are associated with phylogenetic constraint. Our phylogeny places fanfishes at the base of the Bramidae and suggests that nonfanfish bramids have reduced medial fins and re-evolved SOCs. These observations suggest that the evolution of novel fin morphologies in basal species has led to the phylogenetic coupling of head and fin shape, possibly predisposing the entire family to a limited range of feeding. Thus, the evolution of extreme morphologies may have carryover effects, even after the morphology is lost, limiting ecological diversification of lineages.

Published
2021

22. Patterns of Trophic Evolution: Integration and Modularity of the Cichlid Skull

Author

R. Craig Albertson and Yinan Hu

Subjects
Evolvability, Phenotypic plasticity, biology, Cichlid, Evolutionary biology, Modularity (biology), Specialization (functional), Ecosystem diversity, Diversification (marketing strategy), biology.organism_classification, human activities, Trophic level
Abstract

A key axis of diversification among cichlid species is trophic specialization, and much effort has been dedicated to revealing the factors that have contributed to the vast array of feeding morphologies that have evolved in this group. While the physical environment, especially within the large East African lakes, has undoubtedly facilitated their evolutionary success, there must also be intrinsic attributes of cichlids that have increased their evolutionary potential. The modular design of organisms has been credited for promoting diversity across metazoans. This is because the mixing and matching of preexisting anatomical “units” is a more efficient way to expand ecological diversity than the independent evolution of each component part. We suggest that modularity may also play an important role in cichlid craniofacial diversification. We review work focused on describing modularity in cichlids at multiple levels of biological organization—e.g., genetic, anatomical, and functional—and how each can explain the pattern and pace of morphological evolution in this group. We show further how changes in the action of a single molecular pathway—the Hedgehog signal transduction pathway—can promote integration at multiple levels. We consider this pathway to be a molecular “hotspot” for early and ongoing diversification in this group. Understanding the factors that promote and constrain biological diversity is an important topic in evolutionary biology. As cichlid researchers, we are in a unique position to contribute key insights into this question.

Published
2021
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23. Diversity in rest-activity patterns among Lake Malawi cichlid fishes suggests a novel axis of habitat partitioning

Author

R. Craig Albertson, Brian Chhouk, Andrew J. Conith, Evan Lloyd, and Alex C. Keene

Subjects
0106 biological sciences, Malawi, Physiology, Foraging, Zoology, Aquatic Science, Biology, Nocturnal, 010603 evolutionary biology, 01 natural sciences, Nocturnality, 03 medical and health sciences, Cichlid, Tropheops, Animals, Circadian rhythm, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Ecosystem, Phylogeny, 030304 developmental biology, Ecological niche, 0303 health sciences, Cichlids, biology.organism_classification, Biological Evolution, Comparative behavior, Lakes, Habitat, Insect Science, Animal Science and Zoology, human activities, Research Article
Abstract

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 measured locomotor activity across the circadian cycle in 11 Lake Malawi cichlid species. We documented surprising variability in the circadian time of locomotor activity and the duration of rest. In particular, we identified 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 that it results from acute response to light rather than an endogenous circadian rhythm. Finally, we showed that nocturnality is associated with increased eye size after correcting for evolutionary history, 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 variation in nocturnal activity., Summary: Cichlids show a remarkable diversity in morphology and behavior. Cichlid species exhibit differences in strength and polarity of activity rhythms, revealing a new axis of habitat partitioning.

Published
2020

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

Author

R. Craig Albertson, Brian Chhouk, Alex C. Keene, and Evan Lloyd

Subjects
Ecological niche, Nocturnality, biology, Habitat, Cichlid, Foraging, Tropheops, Zoology, Circadian rhythm, Nocturnal, biology.organism_classification, human activities
Abstract

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.

Published
2020
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25. Ecomorphological divergence and habitat lability in the context of robust patterns of modularity in the cichlid feeding apparatus

Author

R. Craig Albertson, Andrew J. Conith, Michael R. Kidd, and Thomas D. Kocher

Subjects
0106 biological sciences, 0301 basic medicine, Species complex, Malawi, Evolution, Biodiversity, Integration, Modularity, Mandible, 010603 evolutionary biology, 01 natural sciences, Models, Biological, 03 medical and health sciences, Cichlid, Phylogenetics, QH359-425, Animals, Morphological evolution, 14. Life underwater, Pharyngeal jaw, Ecology, Evolution, Behavior and Systematics, Ecosystem, Phylogeny, Morphometrics, biology, Water, Replicate, Cichlids, Feeding Behavior, biology.organism_classification, Lakes, 030104 developmental biology, Habitat, Jaw, Evolutionary biology, Pharynx, Research Article
Abstract

BackgroundAdaptive radiations are characterized by extreme and/or iterative phenotypic divergence; however, such variation does not accumulate evenly across an organism. Instead, it is often partitioned into sub-units, or modules, which can differentially respond to selection. While it is recognized that changing the pattern of modularity or the strength of covariation (integration) can influence the range or rate of morphological evolution, the relationship between shape variation and covariation remains unclear. For example, it is possible that rapid phenotypic change requires concomitant changes to the underlying covariance structure. Alternatively, repeated shifts between phenotypic states may be facilitated by a conserved covariance structure. Distinguishing between these scenarios will contribute to a better understanding of the factors that shape biodiversity. Here, we explore these questions using a diverse Lake Malawi cichlid species complex,Tropheops,that appears to partition habitat by depth.ResultsWe construct a phylogeny ofTropheopspopulations and use 3D geometric morphometrics to assess the shape of four bones involved in feeding (mandible, pharyngeal jaw, maxilla, pre-maxilla) in populations that inhabit deep versus shallow habitats. We next test numerous modularity hypotheses to understand whether fish at different depths are characterized by conserved or divergent patterns of modularity. We further examine rates of morphological evolution and disparity between habitats and among modules. Finally, we raise a singleTropheopsspecies in environments mimicking deep or shallow habitats to discover whether plasticity can replicate the pattern of morphology, disparity, or modularity observed in natural populations.ConclusionsOur data support the hypothesis that conserved patterns of modularity permit the evolution of divergent morphologies and may facilitate the repeated transitions between habitats. In addition, we find the lab-reared populations replicate many trends in the natural populations, which suggests that plasticity may be an important force in initiating depth transitions, priming the feeding apparatus for evolutionary change.

Published
2020

26. Plasticity and genetic basis of cichlid gill arch anatomy reveal novel roles for Hedgehog signaling

Author

Lily Zogbaum, R. Craig Albertson, and Patrick G Friend

Subjects
0106 biological sciences, 0301 basic medicine, Gills, Foraging, Locus (genetics), Biology, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, Cichlid, Genetics, Animals, Hedgehog Proteins, Hedgehog, Zebrafish, Ecology, Evolution, Behavior and Systematics, Phenotypic plasticity, fungi, Cichlids, Ecological genetics, biology.organism_classification, Genetic architecture, 030104 developmental biology, Evolutionary biology, Signal Transduction
Abstract

Teleost gill arches are exquisitely evolved to maximize foraging efficiency, and include structures for the capture, filtering, and processing of prey. While both plasticity and a genetic basis for gill arch traits have been noted, the relative contributions of genetics and the environment in shaping these structures remains poorly understood. East African cichlids are particularly useful in this line of study due to their highly diverse and plastic feeding apparatus. Here we explore the gene-by-environmental effects on cichlid GRs by rearing pure bred species and their F3 hybrids in different foraging environments. We find that anatomical differences between species are dependent on the environment. The genetic architecture of these traits is also largely distinct between foraging environments. We did, however, note a few genomic "hotspots" where multiple traits map to a common region. One of these, for GR number across multiple arches, maps to the ptch1 locus, a key component of the Hedgehog (Hh) pathway that has previously been implicated in cichlid oral jaw shape and plasticity. Since Hh signalling has not previously been implicated in GR development, we explored functional roles for this pathway. Using a small molecule inhibitor in cichlids, as well as zebrafish transgenic systems, we demonstrate that Hh levels negatively regulate GR number, and are both necessary and sufficient to maintain plasticity in this trait. In all these data underscore the critical importance of the environment in determining the relationship between genotype and phenotype, and provide a molecular inroad to better understand the origins of variation in this important foraging-related trait.

Published
2020

27. Role of Chd7 in zebrafish: a model for CHARGE syndrome.

Author

Shunmoogum A Patten, Nicole L Jacobs-McDaniels, Charlotte Zaouter, Pierre Drapeau, R Craig Albertson, and Florina Moldovan

Subjects
Medicine, Science
Abstract

CHARGE syndrome is caused by mutations in the CHD7 gene. Several organ systems including the retina, cranial nerves, inner ear and heart are affected in CHARGE syndrome. However, the mechanistic link between mutations in CHD7 and many of the organ systems dysfunction remains elusive. Here, we show that Chd7 is required for the organization of the neural retina in zebrafish. We observe an abnormal expression or a complete absence of molecular markers for the retinal ganglion cells and photoreceptors, indicating that Chd7 regulates the differentiation of retinal cells and plays an essential role in retinal cell development. In addition, zebrafish with reduced Chd7 display an abnormal organization and clustering of cranial motor neurons. We also note a pronounced reduction in the facial branchiomotor neurons and the vagal motor neurons display aberrant positioning. Further, these fish exhibit a severe loss of the facial nerves. Knock-down of Chd7 results in a curvature of the long body axis and these fish develop irregular shaped vertebrae and have a reduction in bone mineralization. Chd7 knockdown also results in a loss of proper segment polarity illustrated by flawed efnb2a and ttna expression, which is associated with later vascular segmentation defects. These critical roles for Chd7 in retinal and vertebral development were previously unrecognized and our results provide new insights into the role of Chd7 during development and in CHARGE syndrome pathogenesis.

Published
2012
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28. Morphological disparity in ecologically diverse versus constrained lineages of Lake Malaŵi rock-dwelling cichlids

Author

Michael J. Pauers and R. Craig Albertson

Subjects
0106 biological sciences, Morphometrics, Ecological niche, biology, 010604 marine biology & hydrobiology, Foraging, Context (language use), Labeotropheus, Aquatic Science, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Evolvability, Evolutionary biology, Tropheops, Species richness
Abstract

Lake Malaŵi cichlids have evolved rapidly, extensively, and in some cases iteratively to fill an array of ecological niches; however, neither species richness nor trophic diversity is distributed equally across lineages. In the context of evolutionary theory, such differences offer predictions about the magnitudes and patterns of morphological variation within lineages. In this paper, we use geometric morphometrics in three prevalent rock-dwelling genera to address questions related to morphological diversity, disparity, integration, and modularity. In particular, we focus on comparisons between the highly specialized and species-poor genus, Labeotropheus (Ahl in Sitzungsberichte der Berlinische Gesellschaft Naturforschender Freunde zu Berlin 1926:51–62, 1927), and the more ecologically diverse and species-rich genus, Tropheops (Trewavas in Revue Francaise d’Aquariologie Herpetologie 10:97–106, 1984), as well as between species with lake-wide versus more limited distributions. We find that Labeotropheus exhibits comparable levels of morphological disparity to Tropheops, which suggests that a specialized foraging mode has not constrained cranial variability in this genus. We also find that species with a lake-wide distribution exhibit levels of disparity three times greater than that in a species with a limited distribution. Finally, we show that magnitudes of integration and patterns of modularity are lineage specific, and do not directly correspond to ecology. In sum, these data provide insights into the complex relationship between ecology, morphological variability, and evolvability.

Published
2018
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29. Genetic and developmental origins of a unique foraging adaptation in a Lake Malawi cichlid genus

Author

Jacqueline F. Webb, R. Craig Albertson, Andrew J. Conith, Yinan Hu, Moira R. Conith, and Maura A. Maginnis

Subjects
Fish Proteins, 0301 basic medicine, Malawi, Multidisciplinary, Lineage (genetic), biology, Morphogenesis, ADAM12 Protein, Cichlids, Quantitative trait locus, biology.organism_classification, Adaptation, Physiological, Lakes, 03 medical and health sciences, 030104 developmental biology, Transforming Growth Factor beta, Cichlid, Evolutionary biology, Basic Helix-Loop-Helix Transcription Factors, Evolutionary developmental biology, Animals, Adaptation, Snout, human activities, Zebrafish
Abstract

Phenotypic novelties are an important but poorly understood category of morphological diversity. They can provide insights into the origins of phenotypic variation, but we know relatively little about their genetic origins. Cichlid fishes display remarkable diversity in craniofacial anatomy, including several novelties. One aspect of this variation is a conspicuous, exaggerated snout that has evolved in a single Malawi cichlid lineage and is associated with foraging specialization and increased ecological success. We examined the developmental and genetic origins for this phenotype and found that the snout is composed of two hypertrophied tissues: the intermaxillary ligament (IML), which connects the right and left sides of the upper jaw, and the overlying loose connective tissue. The IML is present in all cichlids, but in its exaggerated form it interdigitates with the more superficial connective tissue and anchors to the epithelium, forming a unique ligament–epithelial complex. We examined the Transforming growth factor β (Tgfβ) → Scleraxis (Scx) candidate pathway and confirmed a role for these factors in snout development. We demonstrate further that experimental up-regulation of Tgfβ is sufficient to produce an expansion of scx expression and concomitant changes in snout morphology. Genetic and genomic mapping show that core members of canonical Tgfβ signaling segregate with quantitative trait loci (QTL) for snout variation. These data also implicate a candidate for ligament development, adam12 , which we confirm using the zebrafish model. Collectively, these data provide insights into ligament morphogenesis, as well as how an ecologically relevant novelty can arise at the molecular level.

Published
2018
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30. Genetic analyses in Lake Malawi cichlids identify new roles for Fgf signaling in scale shape variation

Author

R. Craig Albertson, Kara E. Powder, Kenta C. Kawasaki, and Emily R. Tetrault

Subjects
0106 biological sciences, 0301 basic medicine, Appendage, Body position, Scale development, Medicine (miscellaneous), Biology, Quantitative trait locus, Fibroblast growth factor, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Genome, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, 030104 developmental biology, Quantitative RTPCR, lcsh:Biology (General), Evolutionary biology, Cichlid, General Agricultural and Biological Sciences, human activities, lcsh:QH301-705.5
Abstract

Elasmoid scales are the most common epithelial appendage among vertebrates, however an understanding of the genetic mechanisms that underlie variation in scale shape is lacking. Using an F2 mapping cross between morphologically distinct cichlid species, we identified >40 QTL for scale shape at different body positions. We show that while certain regions of the genome regulate variation in multiple scales, most are specific to scales at distinct positions. This suggests a degree of regional modularity in scale development. We also identified a single QTL for variation in scale shape disparity across the body. Finally, we screened a QTL hotspot for candidate loci, and identified the Fgf receptor fgfr1b as a prime target. Quantitative rtPCR and small molecule manipulation support a role for Fgf signaling in shaping cichlid scales. While Fgfs have previously been implicated in scale loss, these data reveal new roles for the pathway in scale shape variation.

Published
2018
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31. Limits of principal components analysis for producing a common trait space: implications for inferring selection, contingency, and chance in evolution.

Author

Kevin J Parsons, W James Cooper, and R Craig Albertson

Subjects
Medicine, Science
Abstract

Comparing patterns of divergence among separate lineages or groups has posed an especially difficult challenge for biologists. Recently a new, conceptually simple methodology called the "ordered-axis plot" approach was introduced for the purpose of comparing patterns of diversity in a common morphospace. This technique involves a combination of principal components analysis (PCA) and linear regression. Given the common use of these statistics the potential for the widespread use of the ordered axis approach is high. However, there are a number of drawbacks to this approach, most notably that lineages with the greatest amount of variance will largely bias interpretations from analyses involving a common morphospace. Therefore, without meeting a set of a priori requirements regarding data structure the ordered-axis plot approach will likely produce misleading results.Morphological data sets from cichlid fishes endemic to Lakes Tanganyika, Malawi, and Victoria were used to statistically demonstrate how separate groups can have differing contributions to a common morphospace produced by a PCA. Through a matrix superimposition of eigenvectors (scale-free trajectories of variation identified by PCA) we show that some groups contribute more to the trajectories of variation identified in a common morphospace. Furthermore, through a set of randomization tests we show that a common morphospace model partitions variation differently than group-specific models. Finally, we demonstrate how these limitations may influence an ordered-axis plot approach by performing a comparison on data sets with known alterations in covariance structure. Using these results we provide a set of criteria that must be met before a common morphospace can be reliably used.Our results suggest that a common morphospace produced by PCA would not be useful for producing biologically meaningful results unless a restrictive set of criteria are met. We therefore suggest biologists be aware of the limitations of the ordered-axis plot approach before employing it on their own data, and possibly consider other, less restrictive methods for addressing the same question.

Published
2009
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32. Effect of craniofacial genotype on the relationship between morphology and feeding performance in cichlid fishes

Author

David G. Matthews and R. Craig Albertson

Subjects
0106 biological sciences, 0301 basic medicine, Genotype, Population, Morphology (biology), 010603 evolutionary biology, 01 natural sciences, Bone and Bones, 03 medical and health sciences, Cichlid, Adaptive radiation, Genetics, Animals, Allele, Craniofacial, education, Ecology, Evolution, Behavior and Systematics, education.field_of_study, biology, Human evolutionary genetics, Cichlids, Feeding Behavior, biology.organism_classification, 030104 developmental biology, Jaw, General Agricultural and Biological Sciences
Abstract

The relationship between morphology and performance is complex, but important for understanding the adaptive nature of morphological variation. Recent studies have sought to better understand this system by illuminating the interconnectedness of different functional systems; however, the role of genetics is often overlooked. In this study, we attempt to gain insights into this relationship by examining the effect of genotypic variation at putative craniofacial loci on the relationship between morphology and feeding performance in cichlids. We studied two morphologically disparate species, as well as a morphologically intermediate hybrid population. We assessed feeding performance, jaw protrusion, and general facial morphology for each fish. We also genotyped hybrid animals at six previously identified craniofacial loci. Cichlid species were found to differ in facial geometry, kinematic morphology, and performance. Significant correlations were also noted between these variables; however, the explanatory power of facial geometry in predicting performance was relatively poor. Notably, when hybrids were grouped by genotype, the relationship between shape and performance improved. This relationship was especially robust in animals with the specialist allele at sox9b, a well-characterized regulator of craniofacial development. These data suggest a novel role for genotype in influencing complex relationships between form and function.

Published
2017
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34. Rapid morphological change in multiple cichlid ecotypes following the damming of a major clearwater river in Brazil

Author

Michelle C Gilbert, R. Craig Albertson, Cristina Cox Fernandes, and Alberto Akama

Subjects
0106 biological sciences, 0301 basic medicine, Evolution, Biodiversity, adaptation, 010603 evolutionary biology, 01 natural sciences, phenotypic plasticity, 03 medical and health sciences, Cichlid, QH359-425, Genetics, geometric morphometrics, Ecology, Evolution, Behavior and Systematics, Morphometrics, Phenotypic plasticity, biology, Ecotype, Ecology, Lake (environment), Original Articles, biology.organism_classification, 030104 developmental biology, Original Article, Omnivore, Adaptation, anthropogenic change, General Agricultural and Biological Sciences, contemporary evolution
Abstract

While anthropogenic disturbances can have damaging effects on biodiversity, they also offer an opportunity to understand how species adapt to new environments and may even provide insights into the earliest stages of evolutionary diversification. With these topics in mind, we explored the morphological changes that have occurred across several cichlid species following the damming of the Tocantins River, Brazil. The Tocantins was once a large (2,450 km), contiguous river system; however, upon closure of the Tucuruí Hydroelectric Dam in 1984, a large (~2,850 km2), permanent reservoir was established. We used geometric morphometrics to evaluate changes in native cichlids, comparing historical museum specimens collected from the Tocantins to contemporary specimens collected from the Tucuruí reservoir. Six species across five genera were included to represent distinct ecomorphs, from large piscivores to relatively small opportunistic omnivores. Notably, statistically significant changes in shape and morphological disparity were observed in all species. Moreover, the documented changes tended to be associated with functionally relevant aspects of anatomy, including head, fin, and body shape. Our data offer insights into the ways cichlids have responded, morphologically, to a novel lake environment and provide a robust foundation for exploring the mechanisms through which these changes have occurred.

Published
2019

35. Genetic and developmental basis for fin shape variation in African cichlid fishes

Author

Nathan Olearczyk, R. Craig Albertson, and Dina Navon

Subjects
0301 basic medicine, Candidate gene, Genotype, Quantitative Trait Loci, Population, Adaptation, Biological, Quantitative trait locus, 03 medical and health sciences, Cichlid, Pleiotropy, Adaptive radiation, Genetics, Animals, 14. Life underwater, education, Wnt Signaling Pathway, Ecology, Evolution, Behavior and Systematics, education.field_of_study, biology, Fish fin, Chromosome Mapping, Cichlids, biology.organism_classification, Genetics, Population, Phenotype, 030104 developmental biology, Evolutionary biology, Animal Fins, Evolutionary developmental biology
Abstract

Adaptive radiations are often characterized by the rapid evolution of traits associated with divergent feeding modes. For example, the evolutionary history of African cichlids is marked by repeated and coordinated shifts in skull, trophic, fin and body shape. Here, we seek to explore the molecular basis for fin shape variation in Lake Malawi cichlids. We first described variation within an F2 mapping population derived by crossing two cichlid species with divergent morphologies including fin shape. We then used this population to genetically map loci that influence variation in this trait. We found that the genotype-phenotype map for fin shape is largely distinct from other morphological characters including body and craniofacial shape. These data suggest that key aspects of fin, body and jaw shape are genetically modular and that the coordinated evolution of these traits in cichlids is more likely due to common selective pressures than to pleiotropy or linkage. We next combined genetic mapping data with population-level genome scans to identify wnt7aa and col1a1 as candidate genes underlying variation in the number of pectoral fin ray elements. Gene expression patterns across species with different fin morphologies and small molecule manipulation of the Wnt pathway during fin development further support the hypothesis that variation at these loci underlies divergence in fin shape between cichlid species. In all, our data provide additional insights into the genetic and molecular mechanisms associated with morphological divergence in this important adaptive radiation.

Published
2016
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36. Cichlid fishes as a model to understand normal and clinical craniofacial variation

Author

R. Craig Albertson and Kara E. Powder

Subjects
0301 basic medicine, Embryo, Nonmammalian, Craniofacial abnormality, Quantitative Trait Loci, Embryonic Development, Quantitative trait locus, Article, Craniofacial Abnormalities, Fish Diseases, 03 medical and health sciences, Species Specificity, Cichlid, Pleiotropy, Genetic Pleiotropy, medicine, Animals, Humans, Craniofacial, Maxillofacial Development, Molecular Biology, Genetics, biology, Gene Expression Regulation, Developmental, Cichlids, Feeding Behavior, Cell Biology, biology.organism_classification, medicine.disease, Biological Evolution, Disease Models, Animal, Phenotype, 030104 developmental biology, Neural Crest, Evolutionary biology, Trans-Activators, Gene-Environment Interaction, Neural crest cell migration, Head, Signal Transduction, Developmental Biology, Genetic screen
Abstract

We have made great strides towards understanding the etiology of craniofacial disorders, especially for 'simple' Mendelian traits. However, the facial skeleton is a complex trait, and the full spectrum of genetic, developmental, and environmental factors that contribute to its final geometry remain unresolved. Forward genetic screens are constrained with respect to complex traits due to the types of genes and alleles commonly identified, developmental pleiotropy, and limited information about the impact of environmental interactions. Here, we discuss how studies in an evolutionary model - African cichlid fishes - can complement traditional approaches to understand the genetic and developmental origins of complex shape. Cichlids exhibit an unparalleled range of natural craniofacial morphologies that model normal human variation, and in certain instances mimic human facial dysmorphologies. Moreover, the evolutionary history and genomic architecture of cichlids make them an ideal system to identify the genetic basis of these phenotypes via quantitative trait loci (QTL) mapping and population genomics. Given the molecular conservation of developmental genes and pathways, insights from cichlids are applicable to human facial variation and disease. We review recent work in this system, which has identified lbh as a novel regulator of neural crest cell migration, determined the Wnt and Hedgehog pathways mediate species-specific bone morphologies, and examined how plastic responses to diet modulate adult facial shapes. These studies have not only revealed new roles for existing pathways in craniofacial development, but have identified new genes and mechanisms involved in shaping the craniofacial skeleton. In all, we suggest that combining work in traditional laboratory and evolutionary models offers significant potential to provide a more complete and comprehensive picture of the myriad factors that are involved in the development of complex traits.

Published
2016
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37. Osterix/Sp7 limits cranial bone initiation sites and is required for formation of sutures

Author

Shannon Fisher, Jacqueline C. Simonet, R. Craig Albertson, Erika Kague, Paula R. Roy, Gui Hu, Alexandra Stanley, and Garrett Asselin

Subjects
0301 basic medicine, Article, 03 medical and health sciences, 0302 clinical medicine, Osteogenesis, Precursor cell, Bone cell, medicine, Animals, Humans, Molecular Biology, Zebrafish, Body Patterning, Fibrous joint, Zebrafish mutant, Osteoblasts, Craniofacial skeleton, Sutures, biology, Skull, Osteoblast, Cranial Sutures, Cell Biology, Anatomy, Osterix/Sp7, Zebrafish Proteins, biology.organism_classification, Skeleton (computer programming), Cartilage, 030104 developmental biology, medicine.anatomical_structure, Sp7 Transcription Factor, Bone Morphogenetic Proteins, Mutation, Bone maturation, Transcriptome, 030217 neurology & neurosurgery, Signal Transduction, Transcription Factors, Developmental Biology
Abstract

During growth, individual skull bones overlap at sutures, where osteoblast differentiation and bone deposition occur. Mutations causing skull malformations have revealed some required genes, but many aspects of suture regulation remain poorly understood. We describe a zebrafish mutation in osterix/sp7, which causes a generalized delay in osteoblast maturation. While most of the skeleton is patterned normally, mutants have specific defects in the anterior skull and upper jaw, and the top of the skull comprises a random mosaic of bones derived from individual initiation sites. Osteoblasts at the edges of the bones are highly proliferative and fail to differentiate, consistent with global changes in gene expression. We propose that signals from the bone itself are required for orderly recruitment of precursor cells and growth along the edges. The delay in bone maturation caused by loss of Sp7 leads to unregulated bone formation, revealing a new mechanism for patterning the skull and sutures.

Published
2016
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38. Evolution of a soft-tissue foraging adaptation in African cichlids: Roles for novelty, convergence, and constraint

Author

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

Subjects
0106 biological sciences, 0301 basic medicine, Foraging, Biology, Nose, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, Cichlid, Genetics, Animals, Ecology, Evolution, Behavior and Systematics, Selection (genetic algorithm), Phylogeny, integumentary system, Novelty, Cichlids, Feeding Behavior, biology.organism_classification, Biological Evolution, body regions, Constraint (information theory), 030104 developmental biology, Evolutionary biology, Trait, Adaptation, General Agricultural and Biological Sciences, Snout
Abstract

Understanding the origins of biodiversity demands consideration of both extrinsic (e.g., ecological opportunity) and intrinsic (e.g., developmental constraint) factors. Here, we use a combination of phylogenetic and genetic tools to address the origin of novelty in African cichlids. In particular, we focus on an extreme hypertrophied snout that is structurally integrated with the upper jaw. We show that this bizarre trait has evolved independently in at least two distinct and ecologically successful cichlid clades. We find that snout dimensions are decoupled both phenotypically and genetically, which has enabled it to evolve independently in multiple directions. Further, patterns of variation among species and within a genetic mapping pedigree suggest that relative to snout length, depth is under greater genetic and/or developmental constraint. Models of evolution suggest that snout shape is under selection for feeding behavior, with snout depth being important for algae scraping and snout length for sand sifting. Indeed, the deep snout of some algivores is achieved via an expansion of the intermaxillary ligament, which is important for jaw stability and may increase feeding performance. Overall, our data imply that the evolution of exaggerated snout depth required overcoming a genetic/developmental constraint, which led to expanded ecological opportunity via foraging adaptation.

Published
2018

40. The genetic and developmental basis of an exaggerated craniofacial trait in East African cichlids

Author

R. Craig Albertson and Moira R. Concannon

Subjects
0106 biological sciences, Genetics, 0303 health sciences, education.field_of_study, Candidate gene, biology, Population, Labeotropheus, Quantitative trait locus, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Haplochromine, 03 medical and health sciences, Cichlid, Evolutionary biology, Tropheops, Trait, Molecular Medicine, Animal Science and Zoology, education, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Developmental Biology
Abstract

The evolution of an exaggerated trait can lead to a novel morphology that allows organisms to exploit new niches. The molecular bases of such phenotypes can reveal insights into the evolution of unique traits. Here, we investigate a rare morphological innovation in modern haplochromine cichlids, a flap of fibrous tissue that causes a pronounced projection of the snout, which is limited to a single genus (Labeotropheus) of Lake Malawi cichlids. We compare flap size in our focal species L. fuelleborni (LF) to homologous landmarks in other closely related cichlid species that show a range of ecological overlap with LF, and demonstrate that variation in flap size is discontinuous among Malawi cichlid species. We demonstrate further that flap development in LF begins at early juvenile stages, and scales allometrically with body size. We then used an F2 hybrid mapping population, derived via crossing LF to a close ecological competitor that lacks this trait, Tropheops "red cheek" (TRC), to identify quantitative trait loci (QTL) that underlie flap development. In all, we identified four loci associated with variation in flap size, and for each the LF allele contributed to a larger flap. We next cross-referenced our QTL map with population genomic data, comparing natural populations of LF and TRC, to identify divergent polymorphisms within each QTL interval. Candidate genes for flap development are discussed. Together, these data indicate a relatively simple and tractable genetic basis for this morphological innovation, which is consistent with its apparently sudden and saltatory evolutionary history. J. Exp. Zool. (Mol. Dev. Evol.) 324B: 662-670, 2015. © 2015 Wiley Periodicals, Inc.

Published
2015
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41. Nested Levels of Adaptive Divergence: The Genetic Basis of Craniofacial Divergence and Ecological Sexual Dimorphism

Author

R. Craig Albertson, Kevin J. Parsons, Jason Wang, and Graeme J. Anderson

Subjects
0106 biological sciences, Male, Genotype, Population, Quantitative Trait Loci, Context (language use), Investigations, craniofacial, 010603 evolutionary biology, 01 natural sciences, Divergence, 03 medical and health sciences, Cichlid, Adaptive radiation, Genetic variation, sexual antagonism, Genetics, Animals, education, Molecular Biology, Genetics (clinical), Alleles, 030304 developmental biology, 0303 health sciences, education.field_of_study, Sex Characteristics, biology, morphometrics, Ecology, Chromosome Mapping, Genetic Variation, Cichlids, biology.organism_classification, Genetic divergence, Sexual dimorphism, Phenotype, Evolutionary biology, Face, Female, adaptive radiation, QTL mapping cichlid
Abstract

Exemplary systems for adaptive divergence are often characterized by their large degrees of phenotypic variation. This variation represents the outcome of generations of diversifying selection. However, adaptive radiations can also contain a hierarchy of differentiation nested within them where species display only subtle phenotypic differences that still have substantial effects on ecology, function, and ultimately fitness. Sexual dimorphisms are also common in species displaying adaptive divergence and can be the result of differential selection between sexes that produce ecological differences between sexes. Understanding the genetic basis of subtle variation (between certain species or sexes) is therefore important for understanding the process of adaptive divergence. Using cichlids from the dramatic adaptive radiation of Lake Malawi, we focus on understanding the genetic basis of two aspects of relatively subtle phenotypic variation. This included a morphometric comparison of the patterns of craniofacial divergence between two ecologically similar species in relation to the larger adaptive radiation of Malawi, and male–female morphological divergence between their F2 hybrids. We then genetically map craniofacial traits within the context of sex and locate several regions of the genome that contribute to variation in craniofacial shape that is relevant to sexual dimorphism within species and subtle divergence between closely related species, and possibly to craniofacial divergence in the Malawi radiation as a whole. To enhance our search for candidate genes we take advantage of population genomic data and a genetic map that is anchored to the cichlid genome to determine which genes within our QTL regions are associated with SNPs that are alternatively fixed between species. This study provides a holistic understanding of the genetic underpinnings of adaptive divergence in craniofacial shape.

Published
2015

42. Body Shape Evolution in Sunfishes: Divergent Paths to Accelerated Rates of Speciation in the Centrarchidae

Author

Kevin J. Parsons, R. Craig Albertson, Andrew J. Smith, Nathan Nelson-Maney, and W. James Cooper

Subjects
Morphometrics, Ecological niche, Lepomis, Natural selection, Phylogenetic tree, biology, Niche, Zoology, Micropterus, biology.organism_classification, Clade, Ecology, Evolution, Behavior and Systematics
Abstract

Vertebrate evolutionary radiations are the result of divergence along a variety of ecological and behavioural axes. In addition, the potential for clades to evolve along any one axis can be strongly influenced by the types and levels of phenotypic variation that are exposed to natural selection. Understanding the factors that promote and constrain morphological diversification is a central goal of evolutionary biology. Here we use the sunfishes (Centrarchidae), a perciform family containing three main clades (Lepomis, Micropterus, and a basal clade), to explore this question with respect to variation in body shape. We gathered morphological data from 26 of the 38 centrarchid species using geometric morphometrics and analyzed the resultant shape data over a time-calibrated phylogenetic tree. We find that centrarchids partitioned body shape early in their evolutionary history, a pattern that is largely associated with expansion into divergent foraging niches and elaboration of sexual ornamentation. The morphological disparity of each clade was tightly linked to integration: those clades with high disparity (Lepomis, basal clade) were the least integrated, while the opposite trend was observed in Micropterus. We also find evidence for an increase in speciation rate at the node leading to Lepomis and Micropterus, and a decline in speciation for the basal clade. Our data lead us to suggest different hypotheses for explaining accelerated speciation in Micropterus and Lepomis: invasion of a novel pursuit-predator niche that reduced resource competition (Micropterus), and the elaboration of opercular morphology (Lepomis), a trait that is linked to reproductive behaviour and facilitates mate recognition in communities with many sunfish species.

Published
2015
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43. Preface: Advances in cichlid research: behavior, ecology, and evolutionary biology

Author

R. Craig Albertson, Kristina M. Sefc, Tetsumi Takahashi, Martin J. Genner, and Stephan Koblmüller

Subjects
biology, Ecology, Range (biology), Ecology (disciplines), media_common.quotation_subject, Niche, Aquatic Science, Ecology and Evolutionary Biology, biology.organism_classification, Extant taxon, Cichlid, Pharyngeal jaw, Diversity (politics), media_common
Abstract

With about 1,300validlydescribedspecies,butatleast2,200 species known, cichlid fishes (Cichlidae) repre-sent the second most species-rich family of freshwaterfishaftertheCyprinidae(2,700describedspecies),andaccount for about 13% of extant freshwater fishdiversity. They are naturally distributed from Centraland South America, across Africa to Madagascar, andsouthern India. Throughout this distributional range,they have repeatedly demonstrated their capacity offorming adaptive radiations—explosive speciationwith niche partitioning—generating an outstandingvariation of body shapes, color patterns, behavior, andecomorphological specializations (e.g., Schliewenet al., 1994; Danley & Kocher, 2001; Joyce et al.,2005; Barluenga et al., 2006; Muschick et al., 2012;Lo´pez-Ferna´ndez et al., 2013). This extraordinarydiversity and an often stunning pace of speciationmakes cichlid fishes particularly well suited forstudying the factors and mechanisms underlyingpopulation differentiation, diversification, and spe-ciation. They are now well established among theprime model systems in evolutionary biology research(Kocher, 2004; Seehausen, 2006). With the develop-ment of an increasing number of genetic and genomicresources, including the recent sequencing of severalcichlid genomes (Brawand et al. 2014), cichlids willreceive even greater attention in future evolutionaryand ecological research.This special issue comprises sixteen studies with aparticular focus on behavior, ecology, and/or evolu-tionary biology of cichlid fishes. Together, theyadvance our knowledge of the mechanisms generatingand maintaining the tremendous diversity of thisfreshwater fish family.Over the last few decades, a multitude of studieshave employed various approaches to shed light on thefactors responsible for the stunning diversity withinthis family. An elaborate reproductive behavior and ahighly developed pharyngeal jaw have long beenrecognized as important key factors for the cichlids’evolutionary success (Liem, 1973; Keenleyside

Published
2015
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44. Supplemental Table from Conserved but flexible modularity in the zebrafish skull: implications for craniofacial evolvability

Author

Parsons, Kevin J., Son, Young H., Crespel, Amelie, Thambithurai, Davide, Killen, Shaun, Harris, Matthew P., and R. Craig Albertson

Abstract

Morphological variation is the outward manifestation of development and provides fodder for adaptive evolution. Because of this contingency, evolution is often thought to be biased by developmental processes and functional interactions among structures, which are statistically detectable through forms of covariance among traits. This can take the form of substructures of integrated traits, termed modules, which together comprise patterns of variational modularity. While modularity is essential to an understanding of evolutionary potential, biologists currently have little understanding of its genetic basis and its temporal dynamics over generations. To address these open questions, we compared patterns of craniofacial modularity among laboratory strains, defined mutant lines and a wild population of zebrafish (Danio rerio). Our findings suggest that relatively simple genetic changes can have profound effects on covariance, without greatly affecting craniofacial shape. Moreover, we show that instead of completely deconstructing the covariance structure among sets of traits, mutations cause shifts among seemingly latent patterns of modularity suggesting that the skull may be predisposed towards a limited number of phenotypes. This new insight may serve to greatly increase the evolvability of a population by providing a range of ‘preset’ patterns of modularity that can appear readily and allow for rapid evolution.

Published
2018
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45. Re-description and Reassignment of the DamselfishAbudefduf luridus(Cuvier, 1830) Using Both Traditional and Geometric Morphometric Approaches

Author

R. Craig Albertson, Mark W. Westneat, W. James Cooper, and Richard E. Jacob

Subjects
geography, Abudefduf luridus, geography.geographical_feature_category, food.ingredient, biology, Phylogenetic tree, Zoology, Close relatives, Aquatic Science, biology.organism_classification, food, Taxon, Genus, Animal Science and Zoology, Similiparma, Damselfish, Reef, Ecology, Evolution, Behavior and Systematics
Abstract

Here we present a re-description of Abudefduf luridus and reassign it to the genus Similiparma. We supplement traditional diagnoses and descriptions of this species with quantitative anatomical data collected from a family-wide geometric morphometric analysis of head morphology (44 species representing all 30 damselfish genera) and data from cranial micro-CT scans of fishes in the genus Similiparma. The use of geometric morphometric analyses (and other methods of shape analysis) permits detailed comparisons between the morphology of specific taxa and the anatomical diversity that has arisen in an entire lineage. This provides a particularly useful supplement to traditional description methods and we recommend the use of such techniques by systematists. Similiparma and its close relatives constitute a branch of the damselfish phylogenetic tree that predominantly inhabits rocky reefs in the Atlantic and Eastern Pacific, as opposed to the more commonly studied damselfishes that constitute a large portion of ...

Published
2014
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46. Hedgehog signaling mediates adaptive variation in a dynamic functional system in the cichlid feeding apparatus

Author

Yinan Hu and R. Craig Albertson

Subjects
Fish Proteins, Male, Patched Receptors, Quantitative Trait Loci, Population genetics, Receptors, Cell Surface, Biology, Cichlid, Adaptive radiation, Animals, Hedgehog Proteins, Craniofacial, Hedgehog, In Situ Hybridization, Genetics, Bone Development, Polymorphism, Genetic, Multidisciplinary, Chromosome Mapping, Gene Expression Regulation, Developmental, Cichlids, Feeding Behavior, Biological Sciences, biology.organism_classification, Adaptation, Physiological, Hedgehog signaling pathway, Jaw, Larva, Evolutionary developmental biology, Female, Adaptation, Signal Transduction
Abstract

Adaptive variation in the craniofacial skeleton is a key component of resource specialization and habitat divergence in vertebrates, but the proximate genetic mechanisms that underlie complex patterns of craniofacial variation are largely unknown. Here we demonstrate that the Hedgehog (Hh) signaling pathway mediates widespread variation across a complex functional system that affects the kinematics of lower jaw depression--the opercular four-bar linkage apparatus--among Lake Malawi cichlids. By using a combined quantitative trait locus mapping and population genetics approach, we show that allelic variation in the Hh receptor, ptch1, affects the development of distinct bony elements in the head that represent two of three movable links in this functional system. The evolutionarily derived allele is found in species that feed from the water column, and is associated with shifts in anatomy that translate to a four-bar system capable of faster jaw rotation. Alternatively, the ancestral allele is found in species that feed on attached algae, and is associated with the development of a four-bar system that predicts slower jaw movement. Experimental manipulation of the Hh pathway during cichlid development recapitulates functionally salient natural variation in craniofacial geometry. In all, these results significantly extend our understanding of the mechanisms that fine-tune the craniofacial skeletal complex during adaptation to new foraging niches.

Published
2014
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47. Deficiency of zebrafishfgf20aresults in aberrant skull remodeling that mimics both human cranial disease and evolutionarily important fish skull morphologies

Author

Rachel M. Wirgau, W. James Cooper, R. Craig Albertson, and Elly M. Sweet

Subjects
biology, Lateral line, Morphogenesis, Vertebrate, Anatomy, biology.organism_classification, Skull, medicine.anatomical_structure, Evolutionary biology, biology.animal, Cranial vault, medicine, Craniofacial, Blastema, Zebrafish, Ecology, Evolution, Behavior and Systematics, Developmental Biology
Abstract

The processes that direct skull remodeling are of interest to both human-oriented studies of cranial dysplasia and evolutionary studies of skull divergence. There is increasing awareness that these two fields can be mutually informative when natural variation mimics pathology. Here we describe a zebrafish mutant line, devoid of blastema (dob), which does not have a functional fgf20a protein, and which also presents cranial defects similar to both adaptive and clinical variation. We used geometric morphometric methods to provide quantitative descriptions of the effects of the dob mutation on skull morphogenesis. In combination with "whole-mount in situ hybridization" labeling of normal fgf20a expression and assays for osteoblast and osteoclast activity, the results of these analyses indicate that cranial dysmorphologies in dob zebrafish are generated by aberrations in post-embryonic skull remodeling via decreased osteoblasotgenesis and increased osteoclastogenesis. Mutational effects include altered skull vault geometries and midfacial hypoplasia that are consistent with key diagnostic signs for multiple human craniofacial syndromes. These phenotypic shifts also mimic changes in the functional morphology of fish skulls that have arisen repeatedly in several highly successful radiations (e.g., damselfishes and East-African rift-lake cichlids). Our results offer the dob/fgf20a mutant as an experimentally tractable model with which to examine post-embryonic skull development as it relates to human disease and vertebrate evolution.

Published
2013
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48. Unifying and generalizing the two strands of evo-devo

Author

Kevin J. Parsons and R. Craig Albertson

Subjects
Divergence (linguistics), Ecology, Quantitative Trait Loci, Genomics, Biological evolution, Biology, Quantitative trait locus, Biological Evolution, Field (geography), Evolution, Molecular, Phenotype, Evolutionary biology, Morphogenesis, Evolutionary developmental biology, Ecology, Evolution, Behavior and Systematics, Developmental Biology, Simple (philosophy)
Abstract

The emergence of evo-devo has had profound effects on how we study evolution. However, evo-devo research has tended to involve two general approaches, one being mechanistic and typological with a focus on simple, bimodal phenotypes, and the other being quantitative and focusing on multidimensional phenotypes without an understanding of underlying genetic mechanisms. Here, we suggest that, given recent technological advances in genomics, molecular biology, and morphometrics, evo-devo is poised for a reconciliation through which the field will realize far greater explanatory potential with respect to the patterns and processes that underlie adaptive phenotypic divergence. With this in mind, we review the recent literature and put forward a generalized evo-devo approach that is suitable for studies of quantitative traits in a range of taxa.

Published
2013
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49. Evolvability of the Cichlid Jaw: New Tools Provide Insights into the Genetic Basis of Phenotypic Integration

Author

R. Craig Albertson, Kevin J. Parsons, and Yinan Hu

Subjects
Genetics, Evolvability, Evolutionary biology, Cichlid, Adaptive radiation, Epistasis, Quantitative trait locus, Biology, biology.organism_classification, Jackknife resampling, Ecology, Evolution, Behavior and Systematics, Human genetics, Divergence
Abstract

Phenotypic integration is a phenomenon that manifests itself as the covariation among traits, and is thought to substantially influence how evolution unfolds, both in terms of rate and direction, which ultimately determines evolvability. To date little is known about how integration may change across an adaptive radiation, nor do we have a way of determining its genetic basis. Here we sought to test the hypotheses that (1) higher magnitudes of integration are associated with a greater degree of eco-morphological divergence, and (2) integration has a tractable genetic basis. To this end, we first evaluated the magnitude of integration at the population level in the lower jaws of two Lake Malawi cichlid species that exhibit different degrees of trophic specialization. We find that the more eco-morphologically divergent species does indeed exhibit a significantly higher magnitude of integration, which is consistent with our first hypothesis. Next, we developed a new statistical approach based on jackknife pseudovalues to produce a quantitative trait representative of inter-individual variation in the magnitude of integration. This metric was successfully applied to map the genetic basis of integration in the lower jaws of F2 hybrids derived from the two parental species that exhibited differences in the magnitude of integration. We detected three QTLs and two epistatic interactions that contribute to variation in integration within the cichlid mandible. We also detected a single QTL for lower jaw shape. None of the single QTLs for integration identified here overlapped with the interval for lower jaw shape, although one of the epistatic loci for integration did overlap with shape QTL. These results underscore a complex relationship between integration and shape, but suggest largely distinct genetic bases for these two traits. In all, our results show that phenotypic integration has a tractable, yet complex, genetic basis and that we now have the tools available to shed new light on the mechanisms that both promote and limit craniofacial diversity.

Published
2013
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50. New Frontiers for Organismal Biology

Author

Dietmar Kültz, R. Craig Albertson, Ken Dewar, Michael J. Meaney, George N. Somero, Dan Stanzione, Gene E. Robinson, Barney A. Schlinger, Molly E. Cummings, Louis J. Gross, Joel G. Kingsolver, Hans A. Hofmann, Alexander W. Shingleton, Hannah V. Carey, Scott V. Edwards, David F. Clayton, Anne E. Todgham, and Marla B. Sokolowski

Subjects
Ecology, Multicellular animals, media_common.quotation_subject, Data interpretation, Genetic data, Context (language use), Biology, Genome, Evolutionary biology, Genetic variation, Life history, General Agricultural and Biological Sciences, Function (engineering), media_common
Abstract

Understanding how complex organisms function as integrated units that constantly interact with their environment is a long-standing challenge in biology. To address this challenge, organismal biology reveals general organizing principles of physiological systems and behavior—in particular, in complex multicellular animals. Organismal biology also focuses on the role of individual variability in the evolutionary maintenance of diversity. To broadly advance these frontiers, cross-compatibility of experimental designs, methodological approaches, and data interpretation pipelines represents a key prerequisite. It is now possible to rapidly and systematically analyze complete genomes to elucidate genetic variation associated with traits and conditions that define individuals, populations, and species. However, genetic variation alone does not explain the varied individual physiology and behavior of complex organisms. We propose that such emergent properties of complex organisms can best be explained through a renewed emphasis on the context and life-history dependence of individual phenotypes to complement genetic data.

Published
2013
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