Your search keyword '"Tyler E. Boggs"' showing total 14 results

1. Genetic mapping of craniofacial traits in the Mexican tetra reveals loci associated with bite differences between cave and surface fish

Author

Amanda K. Powers, Carole Hyacinthe, Misty R. Riddle, Young Kwang Kim, Alleigh Amaismeier, Kathryn Thiel, Brian Martineau, Emma Ferrante, Rachel L. Moran, Suzanne E. McGaugh, Tyler E. Boggs, Joshua B. Gross, and Clifford J. Tabin

Subjects

Jaws, Teeth, Feeding behavior, Quantitative trait loci, Cavefish, Ecology, QH540-549.5, Evolution, QH359-425

Abstract

Abstract Background The Mexican tetra, Astyanax mexicanus, includes interfertile surface-dwelling and cave-dwelling morphs, enabling powerful studies aimed at uncovering genes involved in the evolution of cave-associated traits. Compared to surface fish, cavefish harbor several extreme traits within their skull, such as a protruding lower jaw, a wider gape, and an increase in tooth number. These features are highly variable between individual cavefish and even across different cavefish populations. Results To investigate these traits, we created a novel feeding behavior assay wherein bite impressions could be obtained. We determined that fish with an underbite leave larger bite impressions with an increase in the number of tooth marks. Capitalizing on the ability to produce hybrids from surface and cavefish crosses, we investigated genes underlying these segregating orofacial traits by performing Quantitative Trait Loci (QTL) analysis with F2 hybrids. We discovered significant QTL for bite (underbite vs. overbite) that mapped to a single region of the Astyanax genome. Within this genomic region, multiple genes exhibit coding region mutations, some with known roles in bone development. Further, we determined that there is evidence that this genomic region is under natural selection. Conclusions This work highlights cavefish as a valuable genetic model for orofacial patterning and will provide insight into the genetic regulators of jaw and tooth development.

Published

2023

2. Alterations to cavefish red blood cells provide evidence of adaptation to reduced subterranean oxygen

Author

Tyler E. Boggs, Jessica S. Friedman, and Joshua B. Gross

Subjects

Medicine, Science

Abstract

Abstract Animals inhabiting extreme environments allow the powerful opportunity to examine adaptive evolution in response to diverse pressures. One such pressure is reduced oxygen, commonly present at high-altitude and subterranean environments. Cave-dwelling animals must also deal with darkness and starvation, both of which have been rigorously studied as key forces driving the evolution of cave-associated traits. Interestingly, hypoxia as an environmental pressure has received less attention. Here we examined putatively adaptive phenotypes evolving in a freshwater teleost fish, Astyanax mexicanus, which includes both surface- and cave-dwelling forms. This model system also provides the opportunity to identify convergent responses to hypoxia, owing to the presence of numerous natural and independently-colonised cave populations, alongside closely-related surface conspecifics. The focus of this study is hemoglobin, an essential molecule for oxygen transport and delivery. We found that multiple cave populations harbor a higher concentration of hemoglobin in their blood, which is coincident with an increase in cave morph erythrocyte size compared to surface fish. Interestingly, both cave and surface morphs have comparable numbers of erythrocytes per unit of blood, suggesting elevated hemoglobin is not due to overproduction of red blood cells. Alternatively, owing to an increased cell area of erythrocytes in cavefish, we reason that they contain more hemoglobin per erythrocyte. These findings support the notion that cavefish have adapted to hypoxia in caves through modulation of both hemoglobin production and erythrocyte size. This work reveals an additional adaptive feature of Astyanax cavefish, and demonstrates that coordinated changes between cellular architecture and molecular changes are necessary for organisms evolving under intense environmental pressure.

Published

2022

3. A chromosome-level genome of Astyanax mexicanus surface fish for comparing population-specific genetic differences contributing to trait evolution

Author

Wesley C. Warren, Tyler E. Boggs, Richard Borowsky, Brian M. Carlson, Estephany Ferrufino, Joshua B. Gross, LaDeana Hillier, Zhilian Hu, Alex C. Keene, Alexander Kenzior, Johanna E. Kowalko, Chad Tomlinson, Milinn Kremitzki, Madeleine E. Lemieux, Tina Graves-Lindsay, Suzanne E. McGaugh, Jeffrey T. Miller, Mathilda T. M. Mommersteeg, Rachel L. Moran, Robert Peuß, Edward S. Rice, Misty R. Riddle, Itzel Sifuentes-Romero, Bethany A. Stanhope, Clifford J. Tabin, Sunishka Thakur, Yoshiyuki Yamamoto, and Nicolas Rohner

Subjects

Science

Abstract

Mexican Tetra cavefish have long been of interest in understanding adaptation to severe environmental change. Here the authors present a chromosome-level genome for the proxy-ancestral surface fish, and use CRISPR gene-editing to show the role of the rx3 gene in eye size.

Published

2021

4. Facial bone fragmentation in blind cavefish arises through two unusual ossification processes

Author

Amanda K. Powers, Shane A. Kaplan, Tyler E. Boggs, and Joshua B. Gross

Subjects

Medicine, Science

Abstract

Abstract The precise mechanisms underlying cranial bone development, evolution and patterning remain incompletely characterised. This poses a challenge to understanding the etiologies of craniofacial malformations evolving in nature. Capitalising on natural variation, “evolutionary model systems” provide unique opportunities to identify underlying causes of aberrant phenotypes as a complement to studies in traditional systems. Mexican blind cavefish are a prime evolutionary model for cranial disorders since they frequently exhibit extreme alterations to the skull and lateral asymmetries. These aberrations occur in stark contrast to the normal cranial architectures of closely related surface-dwelling fish, providing a powerful comparative paradigm for understanding cranial bone formation. Using a longitudinal and in vivo analytical approach, we discovered two unusual ossification processes in cavefish that underlie the development of ‘fragmented’ and asymmetric cranial bones. The first mechanism involves the sporadic appearance of independent bony elements that fail to fuse together later in development. The second mechanism involves the “carving” of channels in the mature bone, a novel form of post-ossification remodeling. In the extreme cave environment, these novel mechanisms may have evolved to augment sensory input, and may indirectly result in a trade-off between sensory expansion and cranial bone development.

Published

2018

5. An Asymmetric Genetic Signal Associated with Mechanosensory Expansion in Cave-Adapted Fish

Author

Amanda K. Powers, Tyler E. Boggs, and Joshua B. Gross

Subjects

craniofacial, intramembranous, neuromast, lateral line, QTL analysis, Mathematics, QA1-939

Abstract

A key challenge in contemporary biology is connecting genotypic variation to phenotypic diversity. Quantitative genetics provides a powerful technique for identifying regions of the genome that covary with phenotypic variation. Here, we present a quantitative trait loci (QTL) analysis of a natural freshwater fish system, Astyanax mexicanus, that harbors two morphs corresponding to a cave and surface fish. Following their divergence ~500 Kya, cavefish have adapted to the extreme pressures of the subterranean biome. As a consequence, cavefish have lost numerous features, but evolved gains for a variety of constructive features including behavior. Prior work found that sensory tissues (neuromasts) present in the “eye orbit” region of the skull associate with sensitivity to vibrations in water. This augmented sensation is believed to facilitate foraging behavior in the complete darkness of a cave, and may impact on evolved lateral swimming preference. To this point, however, it has remained unclear how morphological variation integrates with behavioral variation through heritable factors. Using a QTL approach, we discovered the genetic architecture of neuromasts present in the eye orbit region, demonstrating that this feature is under genetic control. Interestingly, linked loci were asymmetric–signals were detected using only data collected from the right, but not left, side of the face. This finding may explain enhanced sensitivity and/or feedback of water movements mediating a lateral swimming preference. The locus we discovered based on neuromast position maps near established QTL for eye size and a facial bone morphology, raising the intriguing possibility that eye loss, sensory expansion, and the cranial skeleton may be integrated for evolving adaptive behaviors. Thus, this work will further our understanding of the functional consequence of key loci that influence the evolutionary origin of changes impacting morphology, behavior, and adaptation.

Published

2020

6. Developmental and genetic basis of troglomorphic traits in the teleost fish Astyanax mexicanus

Author

Joshua B. Gross, Tyler E. Boggs, Sylvie Rétaux, and Jorge Torres-Paz

Published

2023

7. List of contributors

Author

Luc Aquilina, Maria Avramov, Maria Elina Bichuette, Lilijana Bizjak-Mali, Tyler E. Boggs, Špela Borko, Andrew J. Boulton, Anton Brancelj, John M. Buffington, David B. Carlini, Didier Casane, Murray Close, Steven Cooper, David C. Culver, Thibault Datry, Teo Delić, Tiziana Di Lorenzo, David Eme, Arnaud Faille, Rodrigo Lopes Ferreira, Lucas Fillinger, Cene Fišer, Žiga Fišer, Daniel W. Fong, Clémentine François, Diana Maria Paola Galassi, Christian Griebler, Joshua B. Gross, Hans Juergen Hahn, Kim M. Handley, Jennifer Hellal, Frédéric Hervant, Grant C. Hose, William F. Humphreys, William Humphreys, Sanda Iepure, William R. Jeffery, Catherine Joulian, Clemens Karwautz, Kathryn Korbel, Rok Kostanjšek, Daniel Kretschmer, Tristan Lefébure, Simon Linke, Erik Garcia Machado, Florian Malard, Stefano Mammola, Pierre Marmonier, Florian Mermillod-Blondin, Oana Teodora Moldovan, Matthew L. Niemiller, Tanja Pipan, Maxime Policarpo, Simona Prevorčnik, Meredith Protas, Ana Sofia P.S. Reboleira, Ana Sofia Reboleira, Robert Reinecke, Sylvie Rétaux, Anne Robertson, Mattia Saccò, Nathanaelle Saclier, Tobias Siemensmeyer, Kevin S. Simon, Laurent Simon, Cornelia Spengler, Heide Stein, Fabio Stoch, Christine Stumpp, Daniele Tonina, Jorge Torres-Paz, Peter Trontelj, Michael Venarsky, Ross Vander Vorste, Alexander Wachholz, Louise Weaver, Alexander Weigand, Masato Yoshizawa, Maja Zagmajster, and Valerija Zakšek

Published

2023

8. Alterations to cavefish red blood cells provide evidence of adaptation to reduced subterranean oxygen

Author

Tyler E, Boggs, Jessica S, Friedman, and Joshua B, Gross

Subjects

Oxygen, Caves, Erythrocytes, Characidae, Animals, Hypoxia, Adaptation, Physiological, Biological Evolution

Abstract

Animals inhabiting extreme environments allow the powerful opportunity to examine adaptive evolution in response to diverse pressures. One such pressure is reduced oxygen, commonly present at high-altitude and subterranean environments. Cave-dwelling animals must also deal with darkness and starvation, both of which have been rigorously studied as key forces driving the evolution of cave-associated traits. Interestingly, hypoxia as an environmental pressure has received less attention. Here we examined putatively adaptive phenotypes evolving in a freshwater teleost fish, Astyanax mexicanus, which includes both surface- and cave-dwelling forms. This model system also provides the opportunity to identify convergent responses to hypoxia, owing to the presence of numerous natural and independently-colonised cave populations, alongside closely-related surface conspecifics. The focus of this study is hemoglobin, an essential molecule for oxygen transport and delivery. We found that multiple cave populations harbor a higher concentration of hemoglobin in their blood, which is coincident with an increase in cave morph erythrocyte size compared to surface fish. Interestingly, both cave and surface morphs have comparable numbers of erythrocytes per unit of blood, suggesting elevated hemoglobin is not due to overproduction of red blood cells. Alternatively, owing to an increased cell area of erythrocytes in cavefish, we reason that they contain more hemoglobin per erythrocyte. These findings support the notion that cavefish have adapted to hypoxia in caves through modulation of both hemoglobin production and erythrocyte size. This work reveals an additional adaptive feature of Astyanax cavefish, and demonstrates that coordinated changes between cellular architecture and molecular changes are necessary for organisms evolving under intense environmental pressure.

Published

2021

9. Developmental integration between the lateral line sensory system and the craniofacial complex in a natural population

Author

Tyler E. Boggs, Joshua B. Gross, Shane A. Kaplan, and Amanda K. Powers

Subjects

Natural population growth, Genetics, Sensory system, Craniofacial, Biology, Line (text file), Molecular Biology, Biochemistry, Neuroscience, Biotechnology

Published

2021

10. An Asymmetric Genetic Signal Associated with Mechanosensory Expansion in Cave-Adapted Fish

Author

Joshua B. Gross, Amanda K. Powers, and Tyler E. Boggs

Subjects

Facial bone, QTL analysis, Physics and Astronomy (miscellaneous), General Mathematics, Foraging, Cavefish, intramembranous, Locus (genetics), Biology, Quantitative trait locus, craniofacial, Article, 03 medical and health sciences, 0302 clinical medicine, Computer Science (miscellaneous), medicine, 030304 developmental biology, 0303 health sciences, lcsh:Mathematics, neuromast, Quantitative genetics, lcsh:QA1-939, Genetic architecture, lateral line, Skull, medicine.anatomical_structure, Chemistry (miscellaneous), Evolutionary biology, 030217 neurology & neurosurgery

Abstract

A key challenge in contemporary biology is connecting genotypic variation to phenotypic diversity. Quantitative genetics provides a powerful technique for identifying regions of the genome that covary with phenotypic variation. Here, we present a quantitative trait loci (QTL) analysis of a natural freshwater fish system, Astyanax mexicanus, that harbors two morphs corresponding to a cave and surface fish. Following their divergence ~500 Kya, cavefish have adapted to the extreme pressures of the subterranean biome. As a consequence, cavefish have lost numerous features, but evolved gains for a variety of constructive features including behavior. Prior work found that sensory tissues (neuromasts) present in the “eye orbit” region of the skull associate with sensitivity to vibrations in water. This augmented sensation is believed to facilitate foraging behavior in the complete darkness of a cave, and may impact on evolved lateral swimming preference. To this point, however, it has remained unclear how morphological variation integrates with behavioral variation through heritable factors. Using a QTL approach, we discovered the genetic architecture of neuromasts present in the eye orbit region, demonstrating that this feature is under genetic control. Interestingly, linked loci were asymmetric–signals were detected using only data collected from the right, but not left, side of the face. This finding may explain enhanced sensitivity and/or feedback of water movements mediating a lateral swimming preference. The locus we discovered based on neuromast position maps near established QTL for eye size and a facial bone morphology, raising the intriguing possibility that eye loss, sensory expansion, and the cranial skeleton may be integrated for evolving adaptive behaviors. Thus, this work will further our understanding of the functional consequence of key loci that influence the evolutionary origin of changes impacting morphology, behavior, and adaptation.

Published

2021

11. Reduced Oxygen as an Environmental Pressure in the Evolution of the Blind Mexican Cavefish

Author

Tyler E. Boggs and Joshua B. Gross

Subjects

0106 biological sciences, Niche, Cavefish, Biology, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, Cave, Extant taxon, Sierra de El Abra, lcsh:QH301-705.5, Organism, 030304 developmental biology, Nature and Landscape Conservation, 0303 health sciences, geography, geography.geographical_feature_category, Extinction, Ecology, Astyanax mexicanus, Ecological Modeling, cave evolution, Environmental pressure, social sciences, Karst, Agricultural and Biological Sciences (miscellaneous), humanities, cavefish, lcsh:Biology (General), dissolved oxygen

Abstract

Extreme environmental features can drive the evolution of extreme phenotypes. Over the course of evolution, certain environmental changes may be so drastic that they lead to extinction. Conversely, if an organism adapts to harsh environmental changes, the adaptations may permit expansion of a novel niche. The interaction between environmental stressors and adaptive changes is well-illustrated by the blind Mexican cavefish, Astyanaxmexicanus, which has recurrently adapted to the stark subterranean environment. The transition from terrestrial rivers and streams (occupied by extant surface morphs of the same species) to the cave has been accompanied by the resorption of eyes, diminished pigmentation and reduced metabolism in cave-dwelling morphs. The principal features of caves most often associated with evolution of these common cave features are the absence of light and limited nutrition. However, a putatively essential cave feature that has received less attention is the frequently low concentration of oxygen within natural karst environments. Here, we review the potential role of limited oxygen as a critical environmental feature of caves in the Sierra de El Abra. Additionally, we review evidence that Astyanax cavefish may have evolved adaptive features enabling them to thrive in lower oxygen compared to their surface-dwelling counterparts.

Published

2021

12. A chromosome level genome ofAstyanax mexicanussurface fish for comparing population-specific genetic differences contributing to trait evolution

Author

Rachel L. Moran, Estephany Ferrufino, Alexander Kenzior, Madeleine E. Lemieux, Johanna E. Kowalko, R. Peuss, Y. Yoshiyuki, Nicolas Rohner, Misty R. Riddle, Sunishka Thakur, Itzel Sifuentes-Romero, Clifford J. Tabin, Welsey C Warren, Suzanne E. McGaugh, Tina A. Graves-Lindsay, Zhiyuan Hu, Joshua B. Gross, Jeffrey T. Miller, Richard Borowsky, L. Hiller, Edward S. Rice, Milinn Kremitzki, Brian M. Carlson, Mathilda T.M. Mommersteeg, Alex C. Keene, Tyler E. Boggs, Chad Tomlinson, and Bethany A. Stanhope

Subjects

Candidate gene, Evolutionary biology, Trait, Cavefish, Chromosome, Biology, Adaptation, Quantitative trait locus, Genome, Gene

Abstract

Identifying the genetic factors that underlie complex traits is central to understanding the mechanistic underpinnings of evolution. In nature, adaptation to severe environmental change, such as encountered following colonization of caves, has dramatically altered genomes of species over varied time spans. Genomic sequencing approaches have identified mutations associated with troglomorphic trait evolution, but the functional impacts of these mutations remain poorly understood. The Mexican Tetra,Astyanax mexicanus, is abundant in the surface waters of northeastern Mexico, and also inhabits at least 30 different caves in the region. Cave-dwellingA. mexicanusmorphs are well adapted to subterranean life and many populations appear to have evolved troglomorphic traits independently, while the surface-dwelling populations can be used as a proxy for the ancestral form. Here we present a high-resolution, chromosome-level surface fish genome, enabling the first genome-wide comparison between surface fish and cavefish populations. Using this resource, we performed quantitative trait locus (QTL) mapping analyses for pigmentation and eye size and found new candidate genes for eye loss such asdusp26. We used CRISPR gene editing inA. mexicanusto confirm the essential role of a gene within an eye size QTL,rx3, in eye formation. We also generated the first genome-wide evaluation of deletion variability that includes an analysis of the impact on protein-coding genes across cavefish populations to gain insight into this potential source of cave adaptation. The new surface fish genome reference now provides a more complete resource for comparative, functional, developmental and genetic studies of drastic trait differences within a species.

Published

2020

13. Dark-rearing uncovers novel gene expression patterns in an obligate cave-dwelling fish

Author

Connor R. Sears, Tyler E. Boggs, and Joshua B. Gross

Subjects

0106 biological sciences, 0301 basic medicine, Candidate gene, genetic structures, Light, Quantitative Trait Loci, Zoology, Cavefish, RNA-Seq, Olfaction, Quantitative trait locus, Biology, Environment, Real-Time Polymerase Chain Reaction, 010603 evolutionary biology, 01 natural sciences, Article, 03 medical and health sciences, Genetics, Animals, Ecology, Evolution, Behavior and Systematics, Obligate, Characidae, Sequence Analysis, RNA, Gene Expression Profiling, Darkness, Caves, 030104 developmental biology, MRNA Sequencing, Molecular Medicine, Animal Science and Zoology, sense organs, Transcriptome, Developmental Biology

Abstract

Extreme environments often result in the evolution of dramatic adaptive features. The Mexican tetra, Astyanax mexicanus, includes 30 different populations of cave-dwelling forms that live in perpetual darkness. As a consequence, many populations have evolved eye loss, reduced pigmentation, and amplification of nonvisual sensory systems. Closely-related surface-dwelling morphs demonstrate typical vision, pigmentation, and sensation. Transcriptomic assessments in this system have revealed important developmental changes associated with the cave morph, however, they have not accounted for photic rearing conditions. Prior studies reared individuals under a 12:12 hr light/dark (LD) cycle. Here, we reared cavefish under constant darkness (DD) for 5+ years. From these experimental individuals, we performed mRNA sequencing and compared gene expression of surface fish reared under LD conditions to cavefish reared under DD conditions to identify photic-dependent gene expression differences. Gene Ontology enrichment analyses revealed a number of previously underappreciated cave-associated changes impacting blood physiology and olfaction. We further evaluated the position of differentially expressed genes relative to QTL positions from prior studies and found several candidate genes associated with these ecologically relevant lighting conditions. In sum, this work highlights photic conditions as a key environmental factor impacting gene expression patterns in blind cave-dwelling fish.

Published

2020

14. Facial bone fragmentation in blind cavefish arises through two unusual ossification processes

Author

Tyler E. Boggs, Shane A. Kaplan, Amanda K. Powers, and Joshua B. Gross

Subjects

0301 basic medicine, Mature Bone, Facial bone, Science, Cavefish, Biology, Facial Bones, Article, 03 medical and health sciences, 0302 clinical medicine, Osteogenesis, medicine, Animals, Longitudinal Studies, 14. Life underwater, Craniofacial, Multidisciplinary, Characidae, Ossification, Mechanism (biology), Skull, 030104 developmental biology, medicine.anatomical_structure, Fragmentation (music), Medicine, medicine.symptom, Neuroscience, 030217 neurology & neurosurgery

Abstract

The precise mechanisms underlying cranial bone development, evolution and patterning remain incompletely characterised. This poses a challenge to understanding the etiologies of craniofacial malformations evolving in nature. Capitalising on natural variation, “evolutionary model systems” provide unique opportunities to identify underlying causes of aberrant phenotypes as a complement to studies in traditional systems. Mexican blind cavefish are a prime evolutionary model for cranial disorders since they frequently exhibit extreme alterations to the skull and lateral asymmetries. These aberrations occur in stark contrast to the normal cranial architectures of closely related surface-dwelling fish, providing a powerful comparative paradigm for understanding cranial bone formation. Using a longitudinal and in vivo analytical approach, we discovered two unusual ossification processes in cavefish that underlie the development of ‘fragmented’ and asymmetric cranial bones. The first mechanism involves the sporadic appearance of independent bony elements that fail to fuse together later in development. The second mechanism involves the “carving” of channels in the mature bone, a novel form of post-ossification remodeling. In the extreme cave environment, these novel mechanisms may have evolved to augment sensory input, and may indirectly result in a trade-off between sensory expansion and cranial bone development.

Published

2018