Your search keyword '"Baker CV"' showing total 6 results

1. Insights into electrosensory organ development, physiology and evolution from a lateral line-enriched transcriptome.

Author

Modrell MS, Lyne M, Carr AR, Zakon HH, Buckley D, Campbell AS, Davis MC, Micklem G, and Baker CV

Subjects

Animals, Gene Expression Profiling, Sequence Analysis, RNA, Animal Structures embryology, Gene Expression Regulation, Developmental, Vertebrates embryology

Abstract

The anamniote lateral line system, comprising mechanosensory neuromasts and electrosensory ampullary organs, is a useful model for investigating the developmental and evolutionary diversification of different organs and cell types. Zebrafish neuromast development is increasingly well understood, but neither zebrafish nor Xenopus is electroreceptive and our molecular understanding of ampullary organ development is rudimentary. We have used RNA-seq to generate a lateral line-enriched gene-set from late-larval paddlefish ( Polyodon spathula ). Validation of a subset reveals expression in developing ampullary organs of transcription factor genes critical for hair cell development, and genes essential for glutamate release at hair cell ribbon synapses, suggesting close developmental, physiological and evolutionary links between non-teleost electroreceptors and hair cells. We identify an ampullary organ-specific proneural transcription factor, and candidates for the voltage-sensing L-type Ca v channel and rectifying K v channel predicted from skate (cartilaginous fish) ampullary organ electrophysiology. Overall, our results illuminate ampullary organ development, physiology and evolution.

Published

2017

2. The evolution of the vertebrate cerebellum: absence of a proliferative external granule layer in a non-teleost ray-finned fish.

Author

Butts T, Modrell MS, Baker CV, and Wingate RJ

Subjects

Animals, Basic Helix-Loop-Helix Transcription Factors metabolism, Cerebellum embryology, Fish Proteins metabolism, Nerve Tissue Proteins metabolism, Phylogeny, Skates, Fish embryology, Biological Evolution, Cerebellum physiology, Skates, Fish genetics, Vertebrates genetics

Abstract

The cerebellum represents one of the most morphologically variable structures in the vertebrate brain. To shed light on its evolutionary history, we have examined the molecular anatomy and proliferation of the developing cerebellum of the North American paddlefish, Polyodon spathula. Absence of an external proliferative cerebellar layer and the restriction of Atonal1 expression to the rhombic lip and valvular primordium demonstrate that transit amplification in a cerebellar external germinal layer, a prominent feature of amniote cerebellum development, is absent in paddlefish. Furthermore, expression of Sonic hedgehog, which drives secondary proliferation in the mouse cerebellum, is absent from the paddlefish cerebellum. These data are consistent with what has been observed in zebrafish and suggest that the transit amplification seen in the amniote cerebellum was either lost very early in the ray-finned fish lineage or evolved in the lobe-finned fish lineage. We also suggest that the Atoh1-positive proliferative valvular primordium may represent a synapomorphy (shared derived character) of ray-finned fishes. The topology of valvular primordium development in paddlefish differs significantly from that of zebrafish and correlates with the adult cerebellar form. The distribution of proliferative granule cell precursors in different vertebrate taxa is thus the likely determining factor in cerebellar morphological diversity., (© 2014 Wiley Periodicals, Inc.)

Published

2014

3. The evolution and development of vertebrate lateral line electroreceptors.

Author

Baker CV, Modrell MS, and Gillis JA

Subjects

Animals, Electric Fish physiology, Phylogeny, Sensation, Electric Organ physiology, Sensory Receptor Cells physiology, Vertebrates physiology

Abstract

Electroreception is an ancient vertebrate sense with a fascinating evolutionary history involving multiple losses as well as independent evolution at least twice within teleosts. We review the phylogenetic distribution of electroreception and the morphology and innervation of electroreceptors in different vertebrate groups. We summarise recent work from our laboratory that has confirmed the homology of ampullary electroreceptors in non-teleost jawed vertebrates by showing, in conjunction with previously published work, that these are derived embryonically from lateral line placodes. Finally, we review hypotheses to explain the distribution of electroreception within teleosts, including the hypothesis that teleost ampullary and tuberous electroreceptors evolved via the modification of mechanosensory hair cells in lateral line neuromasts. We conclude that further experimental work on teleost electroreceptor development is needed to test such hypotheses.

Published

2013

4. Developmental evidence for serial homology of the vertebrate jaw and gill arch skeleton.

Author

Gillis JA, Modrell MS, and Baker CV

Subjects

Animals, Bayes Theorem, Body Patterning genetics, Branchial Region embryology, Branchial Region metabolism, Elasmobranchii anatomy & histology, Elasmobranchii embryology, Elasmobranchii genetics, Embryo, Nonmammalian metabolism, Gene Expression Regulation, Developmental, Gills metabolism, Homeodomain Proteins genetics, Homeodomain Proteins metabolism, Mammals anatomy & histology, Mammals embryology, Mesoderm embryology, Mesoderm metabolism, Models, Biological, Phylogeny, Transcription Factors genetics, Transcription Factors metabolism, Vertebrates genetics, Branchial Region anatomy & histology, Gills anatomy & histology, Gills embryology, Jaw anatomy & histology, Jaw embryology, Vertebrates anatomy & histology, Vertebrates embryology

Abstract

Gegenbaur's classical hypothesis of jaw-gill arch serial homology is widely cited, but remains unsupported by either palaeontological evidence (for example, a series of fossils reflecting the stepwise transformation of a gill arch into a jaw) or developmental genetic data (for example, shared molecular mechanisms underlying segment identity in the mandibular, hyoid and gill arch endoskeletons). Here we show that nested expression of Dlx genes--the 'Dlx code' that specifies upper and lower jaw identity in mammals and teleosts--is a primitive feature of the mandibular, hyoid and gill arches of jawed vertebrates. Using fate-mapping techniques, we demonstrate that the principal dorsal and ventral endoskeletal segments of the jaw, hyoid and gill arches of the skate Leucoraja erinacea derive from molecularly equivalent mesenchymal domains of combinatorial Dlx gene expression. Our data suggest that vertebrate jaw, hyoid and gill arch cartilages are serially homologous, and were primitively patterned dorsoventrally by a common Dlx blueprint.

Published

2013

5. The amniote paratympanic organ develops from a previously undiscovered sensory placode.

Author

O'Neill P, Mak SS, Fritzsch B, Ladher RK, and Baker CV

Subjects

Animals, Biological Evolution, Chick Embryo, Chickens metabolism, Ear, Middle cytology, Ear, Middle metabolism, Ectoderm cytology, Ectoderm metabolism, Hair Cells, Auditory metabolism, Neurons, Afferent cytology, Neurons, Afferent metabolism, Phylogeny, Quail embryology, Quail metabolism, SOXB1 Transcription Factors genetics, SOXB1 Transcription Factors metabolism, Sense Organs embryology, Sense Organs metabolism, Sharks embryology, Sharks metabolism, Vertebrates classification, Vertebrates genetics, Vertebrates metabolism, Ear, Middle embryology, Ectoderm embryology, Hair Cells, Auditory cytology, Vertebrates embryology

Abstract

The paratympanic organ, a mechanosensory hair cell-containing pouch in the amniote middle ear, was first described 100 years ago, yet its origins remain unresolved. Homology with the anamniote spiracular organ is supported by association with homologous skeletal elements and similar central targets of afferent neurons, suggesting it might be a remnant of the water-dependent lateral line system, otherwise lost during the amniote transition to terrestrial life. However, this is incompatible with studies suggesting that it arises from the first epibranchial (geniculate) placode. Here we show that a previously undiscovered Sox2-positive placode, immediately dorsal to the geniculate placode, forms the paratympanic organ and its afferent neurons, which are molecularly and morphologically distinct from geniculate neurons. These data remove the only obstacle to accepting the homology of the paratympanic organ and spiracular organ. We hypothesize that the paratympanic organ/spiracular organ represents an ancient head ectoderm module, developmentally and evolutionarily independent of both lateral line and epibranchial placodes.

Published

2012

6. The evolution and elaboration of vertebrate neural crest cells.

Author

Baker CV

Subjects

Animals, Cartilage physiology, Neural Crest physiology, Biological Evolution, Cell Differentiation physiology, Gene Regulatory Networks genetics, Models, Biological, Neural Crest cytology, Phylogeny, Vertebrates embryology

Abstract

Vertebrate neural crest cells are embryonic neuroepithelial cells that undergo an epithelial-mesenchymal transition, migrate throughout the embryo and form a wide variety of derivatives, including peripheral neurons and glia, pigment cells, and craniofacial cartilage, bone and teeth. Neural crest cell evolution and elaboration is intimately bound up with vertebrate evolution: the most primitive living vertebrates, lampreys and hagfishes, have most but not all neural crest derivatives. A torrent of recent molecular information has changed our understanding of vertebrate phylogenetic relationships, expanded our understanding of the gene circuitry underlying neural crest development, and given interesting information on the deployment of homologues of these genes in invertebrate relatives such as ascidians and amphioxus. New molecular insights into the evolutionary origin of cartilage, as well as into the nature and evolution of the cells and genes involved in tooth and bone formation, enable tentative hypotheses to be framed for the evolution of skeletal neural crest derivatives.

Published

2008