Homeobox genes in axolotl lateral line placodes and neuromasts

Metscher, Brian; Northcutt, R. Glenn; Gardiner, David M.; Bryant, Susan V.

doi:10.1007/s004270050116

Cited by 25 publications

(17 citation statements)

References 35 publications

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“…To our knowledge, the homeobox genes Msx2 and Dlx3 are the only previously described transcription factors expressed during neuromast and ampullary organ development in the axolotl: in the mature sense organs, both genes were reported to be expressed in the sensory receptor cells and support cells, though expression data were only shown for neuromasts (Metscher et al 1997). However, neither of these genes is expressed during neuromast or ampullary organ development in the paddlefish (M.S.M., unpublished data), suggesting they may not be conserved markers for lateral line sense organs in bony fishes.…”

Section: Discussionmentioning

confidence: 99%

Evolution of electrosensory ampullary organs: conservation of Eya4 expression during lateral line development in jawed vertebrates

Modrell¹,

Baker

2012

Evolution and Development

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SUMMARYThe lateral line system of fishes and amphibians comprises two ancient sensory systems: mechanoreception and electroreception. Electroreception is found in all major vertebrate groups (i.e., jawless fishes, cartilaginous fishes and bony fishes); however, it was lost in several groups including anuran amphibians (frogs) and amniotes (reptiles, birds and mammals), as well as in the lineage leading to the neopterygian clade of bony fishes (bowfins, gars and teleosts). Electroreception is mediated by modified 'hair cells', which are collected in ampullary organs that flank lines of mechanosensory hair cell-containing neuromasts. In the axolotl (a urodele amphibian), grafting and ablation studies have shown a lateral line placode origin for both mechanosensory neuromasts and electrosensory ampullary organs (and the neurons that innervate them). However, little is known at the molecular level about the development of the amphibian lateral line system in general and electrosensory ampullary organs in particular. Previously, we identified Eya4 as a marker for lateral line (and otic) placodes, neuromasts and ampullary organs in a shark (a cartilaginous fish) and a paddlefish (a basal ray-finned fish). Here, we show that Eya4 is similarly expressed during otic and lateral line placode development in the axolotl (a representative of the lobe-finned fish clade). Furthermore, Eya4 expression is specifically restricted to hair cells in both neuromasts and ampullary organs, as identified by co-expression with the calcium-buffering protein Parvalbumin3. As well as identifying new molecular markers for amphibian mechanosensory and electrosensory hair cells, these data demonstrate that Eya4 is a conserved marker for lateral line placodes and their derivatives in all jawed vertebrates.

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Section: Discussionmentioning

confidence: 99%

Evolution of electrosensory ampullary organs: conservation of Eya4 expression during lateral line development in jawed vertebrates

Modrell¹,

Baker

2012

Evolution and Development

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“…Only five molecular markers for vertebrate ampullary organs have previously been reported: in axolotl, Dlx3 and Msx2 (Metscher et al, 1997), and in sharks, Eya4 (O'Neill et al, 2007), Sox8, and ephrinB2 (Freitas et al, 2006). Hence, Sox3 is a novel molecular marker for vertebrate ampullary organs and also the first published molecular marker for actinopterygian ampullary organs.…”

Section: Sox3 Is Expressed Throughout the Development Of Both Mechanomentioning

confidence: 99%

Molecular analysis of neurogenic placode development in a basal ray‐finned fish

Modrell

Buckley

Baker

2011

Genesis

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Summary: Neurogenic placodes are transient, thickened patches of embryonic vertebrate head ectoderm that give rise to the paired peripheral sense organs and most neurons in cranial sensory ganglia. We present the first analysis of gene expression during neurogenic placode development in a basal actinopterygian (rayfinned fish), the North American paddlefish (Polyodon spathula). Pax3 expression in the profundal placode confirms its homology with the ophthalmic trigeminal placode of amniotes. We report the conservation of expression of Pax2 and Pax8 in the otic and/or epibranchial placodes, Phox2b in epibranchial placode-derived neurons, Sox3 during epibranchial and lateral line placode development, and NeuroD in developing cranial sensory ganglia. We identify Sox3 as a novel marker for developing fields of electrosensory ampullary organs and for ampullary organs themselves. Sox3 is also the first molecular marker for actinopterygian ampullary organs. This is consistent with, though does not prove, a lateral line placode origin for actinopterygian ampullary organs. genesis 49:278-294, 2011. V V C 2011 Wiley-Liss, Inc.

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“…Metscher et al [1997] found that in axolotls homeobox genes Msx1 & 2 and Dlx3 are expressed in mature neuromast support cells, and Dlx3 is also expressed in mature hair cells. Interestingly, Msx2 and Dlx3 are expressed in differentiated primitive neuromasts but not in neuromast primordia [Metscher et al, 1997].…”

Section: Inductionmentioning

confidence: 99%

“…Dorsolateral placodes not only arise from the lateral walls of the hindbrain neural folds [Northcutt, 1996], but they do so in an anterior-posterior series. Metscher et al [1997] demonstrated Hox gene expression in at least one lateral line placode, and Northcutt [1996] suggested that each dorsolateral placode should have a unique pattern of Hox gene expression that could be altered by exposure to retinoic acid, which is involved with setting boundaries of Hox gene expression. Gibbs and Northcutt [2004b] have shown that when late gastrula -early neurula axolotl embryos were exposed to retinoic acid, embryos not only lost organization of their lateral line neuromasts in a dose dependent fashion, but also completely lost ampullary organs at the highest dose.…”

Section: Inductionmentioning

confidence: 99%

Lateral Line Receptors: Where Do They Come from Developmentally and Where Is Our Research Going?

Gibbs

2004

Brain Behav Evol

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The lateral line system is composed of both mechanoreceptors, which exhibit little variation in structure between taxonomic groups, and electroreceptors, which exhibit considerably more variation. Cathodally sensitive ampullary electroreceptors are the primitive condition and are found in agnathans, chondrichthyans, and most osteichthyans. Aquatic amphibians also have ampullary electroreceptors for at least part of their life cycle. The more recently evolved anodally sensitive ampullary electroreceptors and tuberous electroreceptors are only found in four groups of teleost fishes. The basic ontogenetic unit of lateral line development is the dorsolateral placode. Primitively, there are six pairs of placodes, which pass through sequential stages of development into lateral line receptors. There is no question about the origin of primitive mechanoreceptors or electroreceptors, however, we do not have a good understanding of the origin of teleost mechanoreceptors and their ampullary or tuberous electroreceptors; do they come exclusively from dorsolateral placodes or from neural crest or even general ectoderm? A second intriguing lateral line question is how certain teleost fish groups evolved tuberous electroreceptors. Electroreception appears to have re-evolved at least twice in teleosts after being lost during the neopterygian radiation. It has been suggested that the development of tuberous electroreceptors might be due to changes in placodal patterning or a change in the general ectoderm that placodes arise from. Unfortunately, our understanding of lateral line origins in fishes is very sketchy, and, if we are to answer such an evolutionary question, we first need more complete information about lateral line development in a variety of fishes, which can then be combined with gene expression data to better interpret lateral line receptor development.

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Homeobox genes in axolotl lateral line placodes and neuromasts

Cited by 25 publications

References 35 publications

Evolution of electrosensory ampullary organs: conservation of Eya4 expression during lateral line development in jawed vertebrates

Evolution of electrosensory ampullary organs: conservation of Eya4 expression during lateral line development in jawed vertebrates

Molecular analysis of neurogenic placode development in a basal ray‐finned fish

Lateral Line Receptors: Where Do They Come from Developmentally and Where Is Our Research Going?

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