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9 - Evolution, Development and Regeneration of Fish Dentitions

Published online by Cambridge University Press:  31 December 2018

By
Gareth J. Fraser  and
Alex P. Thiery
Edited by
Zerina Johanson ,
Charlie Underwood  and
Martha Richter
Zerina Johanson
Affiliation:
Natural History Museum, London
Charlie Underwood
Affiliation:
Birkbeck, University of London
Martha Richter
Affiliation:
Natural History Museum, London
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Summary

The diversity of fishes provides a wealth of morphological variety to investigate at the developmental and genetic level. The diverse range of phenotypes offered by fish dentitions provides an excellent comparative context for studies of evolutionary developmental biology. This chapter discusses the evolution, development and regenerative capacity of chondrichthyan and osteichthyan dentitions. We provide an overview of the recent insights into how general fish dentitions are initiated and how they continue to redevelop over multiple tooth generations.

Type
Chapter
Information
Evolution and Development of Fishes , pp. 160 - 171
Publisher: Cambridge University Press
Print publication year: 2019

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References

Abduweli, D, Baba, O, Tabata, MJ, Higuchi, K, Mitani, H, Takano, Y. 2014. Tooth replacement and putative odontogenic stem cell niches in pharyngeal dentition of medaka (Oryzias latipes). Microscopy 63:141153.Google Scholar
Atkinson, CJ, Martin, KJ, Fraser, GJ, Collin, SP. 2016. Morphology and distribution of taste papillae and oral denticles in the developing oropharyngeal cavity of the bamboo shark, Chiloscyllium punctatum. Biol Open 5:17591769.Google Scholar
Berkovitz, BK, Moore, MH. 1975. Tooth replacement in the upper jaw of the rainbow trout (Salmo gairdneri). J Exp Zool 193:221234.Google Scholar
Berkovitz, BK, Shellis, RP. 2016. The Teeth of Non-Mammalian Vertebrates. London: Academic Press.Google Scholar
Bloomquist, RF, Parnell, NF, Phillips, KA, Fowler, TE, Yu, T-Y, Sharpe, PT, Streelman, JT. 2015. Coevolutionary patterning of teeth and taste buds. Proc Natl Acad Sci U S A 112:E5954–5962.Google Scholar
Botella, H. 2006. The oldest fossil evidence of dental lamina in sharks. J Vert Paleo 26:10021003.Google Scholar
Botella, H, Valenzuela-Rios, JI, Martinez-Perez, P. 2009. Tooth replacement rates in early chondrichthyans: A qualitative approach. Lethaia 42:365376.CrossRefGoogle Scholar
Cobourne, MT, Sharpe, PT. 2003. Tooth and jaw: Molecular mechanisms of patterning in the first branchial arch. Arch Oral Biol 48:114.CrossRefGoogle ScholarPubMed
Debiais-Thibaud, M, Chiori, R, Enault, S, Oulion, S, Germon, I, Martinand-Mari, C, Casane, D, Borday-Birraux, V. 2015. Tooth and scale morphogenesis in shark: An alternative process to the mammalian enamel knot system. BMC Evol Biol 15:292.Google Scholar
Debiais-Thibaud, M, Oulion, S, Bourrat, F, Laurenti, P, Casane, D, Borday-Birraux, V. 2011. The homology of odontodes in gnathostomes: Insights from Dlx gene expression in the dogfish, Scyliorhinus canicula. BMC Evol Biol 11:307.CrossRefGoogle ScholarPubMed
Donoghue, PCJ, Rücklin, M. 2016. The ins and outs of the evolutionary origin of teeth. Evol Dev 18:1930.Google Scholar
Ellis, NA, Donde, NN, Miller, CT. 2016. Early development and replacement of the stickleback dentition. J Morph 277:10721083.Google Scholar
Ellis, NA, Glazer, AM, Donde, NN, Cleves, PA, Agoglia, RM, Miller, CT. 2015. Distinct developmental genetic mechanisms underlie convergently evolved tooth gain in sticklebacks. Development 142:24422451.Google Scholar
Fraser, GJ, Berkovitz, BK, Graham, A, Smith, MM. 2006. Gene deployment for tooth replacement in the rainbow trout (Oncorhynchus mykiss): A developmental model for evolution of the osteichthyan dentition. Evol Dev 8:446457.Google Scholar
Fraser, GJ, Bloomquist, RF, Streelman, JT. 2008. A periodic pattern generator for dental diversity. BMC Biology 6:32.Google Scholar
Fraser, GJ, Bloomquist, RF, Streelman, JT. 2013. Common developmental pathways link tooth shape to regeneration. Dev Biol 377:399414.Google Scholar
Fraser, GJ, Britz, R, Hall, A, Johanson, Z, Smith, MM. 2012. Replacing the first-generation dentition in pufferfish with a unique beak. Proc Natl Acad Sci U S A 109:81798184.Google Scholar
Fraser, GJ, Cerny, R, Soukup, V, Bronner-Fraser, M, Streelman, JT. 2010. The odontode explosion: The origin of tooth-like structures in vertebrates. BioEssays 32:808817.CrossRefGoogle ScholarPubMed
Fraser, GJ, Graham, A, Smith, MM. 2004. Conserved deployment of genes during odontogenesis across osteichthyans. Proc R Soc Lond B Biol Sci 271:23112317.CrossRefGoogle ScholarPubMed
Fraser, GJ, Graham, A, Smith, MM. 2006. Developmental and evolutionary origins of the vertebrate dentition: Molecularcontrols for spatio-temporal organisation of tooth sites in osteichthyans. J Exp Zool B: Mol Dev Evol 306:183203.Google Scholar
Fraser, GJ, Hulsey, CD, Bloomquist, RF, Uyesugi, K, Manley, NR, Streelman, JT. 2009. An ancient gene network is co-opted for teeth on old and new jaws. PLoS Biol 7:e31.Google Scholar
Huysseune, A, Witten, PE. 2006. Developmental mechanisms underlying tooth patterning in continuously replacing osteichthyan dentitions. J Exp Zool Mol Dev Evol 306:204215.Google Scholar
Huysseune, A, Witten, PE. 2008. An evolutionary view on tooth development and replacement in wild Atlantic salmon (Salmo salar L.). Evol Dev 10: 614.Google Scholar
Jernvall, J, Thesleff, I. 2000. Reiterative signaling and patterning during mammalian tooth morphogenesis. Mech Dev 92:1929.Google Scholar
Jernvall, J, Thesleff, I. 2012. Tooth shape formation and tooth renewal: Evolving with the same signals. Development 139:34873497.Google Scholar
Juuri, E, Isaksson, S, Jussila, M, Heikinheimo, K, Thesleff, I. 2013a. Expression of the stem cell marker, SOX2, in ameloblastoma and dental epithelium. Eur J Oral Sci 121:509516.Google Scholar
Juuri, E, Jussila, M, Seidel, K, Holmes, S, Wu, P, Richman, J, Heikinheimo, K, Chuong, CM, Arnold, K, Hochedlinger, K, Klein, O, Michon, F, Thesleff, I. 2013b. Sox2 marks epithelial competence to generate teeth in mammals and reptiles. Development 140:14241432.Google Scholar
Juuri, E, Saito, K, Ahtiainen, L, Seidel, K, Tummers, M, Hochedlinger, K, Klein, OD, Thesleff, I, Michon, F. 2012. Sox2+ stem cells contribute to all epithelial lineages of the tooth via Sfrp5+ progenitors. Dev Cell 23: 17328.Google Scholar
Kirino, M, Parne, J, Hansen, A, Kiyohara, S, Finger, TE. 2013. Evolutionary origins of taste buds: Phylogenetic analysis of purinergic neurotransmission in epithelial chemosensors. Open Biol 3:130015.Google Scholar
Luer, CA, Blum, PC, Gilbert, PW. 1990. Rate of tooth replacement in the nurse shark, Ginglymostoma cirratum. Copeia 1:82191.Google Scholar
Lumsden, AG. 1988. Spatial organization of the epithelium and the role of neural crest cells in the initiation of the mammalian tooth germ. Development 103:155169.Google Scholar
Maisey, JG, Turner, S, Naylor, GJ, Miller, RF. 2014. Dental patterning in the earliest sharks: Implications for tooth evolution. J Morph 275:586596.Google Scholar
Martin, KJ, Rasch, LJ, Cooper, RL, Metscher, BD, Johanson, Z, Fraser, GJ. 2016. Sox2+ progenitors in sharks link taste development with the evolution of regenerative teeth from denticles. Proc Natl Acad Sci USA 113:1476914774.Google Scholar
Moriyama, K, Watanabe, S, Iida, M, Sahara, N. 2010. Plate-like permanent dental laminae of upper jaw dentition in adult gobiid fish, Sicyopterus japonicus. Cell Tissue Res 340:189200.Google Scholar
Moss, S. 1967. Tooth Replacement in the lemon shark, Negaprion brevirostris. In: Gilbert, P, Mathewson, R, Rall, D, editors. Sharks, Skates and Rays. Baltimore: The Johns Hopkins University Press. pp. 319329.Google Scholar
Motta, PJ, Huber, DR. 2012. Prey capture behavior and feeding mechanics of elasmobranchs. In: Heithaus, MR, Carrier, JC, Musick, JA, editors. Biology of Sharks and their Relatives, 3rd edition. Boca Raton: CRC Press. pp. 153209.Google Scholar
Moyer, JK, Riccio, ML, Bemis, WE. 2015. Development and microstructure of tooth histotypes in the blue shark, Prionace glauca (Carcharhiniformes: Carcharhinidae) and the great white shark, Carcharodon carcharias (Lamniformes: Lamnidae). J Morph 276:797817.Google Scholar
Nielsen, J, Hedeholm, RB, Heinemeier, J, Bushnell, PG, Christiansen, JS, Olsen, J, Ramsey, CB, Brill, RW, Simon, M, Steffensen, KF, Steffensen, JF. 2016. Eye lens radiocarbon reveals centuries of longevity in the Greenland shark (Somniosus microcephalus). Science 353:702704.Google Scholar
Rasch, LJ, Martin, KJ, Cooper, RL, Metscher, BD, Underwood, CJ, Fraser, GJ. 2016. An ancient dental gene set governs development and continuous regeneration of teeth in sharks. Dev Biol 415:347370.Google Scholar
Reif, W-E, McGill, D, Motta, P. 1978. Tooth replacement rates of the sharks Triakis semifasciata and Ginglymostoma cirratum. Zool Jahrb Abt Anat Ontog 99:151156.Google Scholar
Rücklin, M, Donoghue, PCJ, Johanson, Z, Trinajstic, K, Marone, F, Stampanoni, M. 2012. Development of teeth and jaws in the earliest jawed vertebrates. Nature 491:748751.Google Scholar
Rücklin, M, Giles, S, Janvier, P, Donoghue, PCJ. 2011. Teeth before jaws? Comparative analysis of the structure and development of the external and internal scales in the extinct jawless vertebrate Loganellia scotica. Evol Dev 13:523532.Google Scholar
Sahara, N, Moriyama, K, Iida, M, Watanabe, S. 2017. Fate of worn-out functional teeth in the upper jaw dentition of Sicyopterus japonicus (Gobioidei: Sicydiinae) during tooth replacement. Anat Rec. doi:10.1002/ar.23685.Google Scholar
Schnetz, L, Pfaff, C, Kriwet, J. 2016. Tooth development and histology patterns in lamniform sharks (Elasmobranchii, Lamniformes) revisited. J Morph 277:15841598.Google Scholar
Smith, MM. 2003. Vertebrate dentitions at the origin of jaws: When and how pattern evolved. Evol Dev 5:394413.Google Scholar
Smith, MM, Coates, MI. 1998. Evolutionary origins of the vertebrate dentition: phylogenetic patterns and developmental evolution. Eur J Oral Sci 106 Suppl 1:482500.Google Scholar
Smith, MM, Fraser, GJ, Chaplin, N, Hobbs, C, Graham, A. 2009a. Reiterative pattern of sonic hedgehog expression in the catshark dentition reveals a phylogenetic template for jawed vertebrates. Proc Biol Sci B 276:12251233.Google Scholar
Smith, MM, Fraser, GJ, Mitsiadis, TA. 2009b. Dental lamina as source of odontogenic stem cells: Evolutionary origins and developmental control of tooth generation in gnathostomes. J Exp Zoolog B Mol Dev Evol 312B:260280.Google Scholar
Smith, MM, Johanson, Z, Butts, T, Ericsson, R, Modrell, M, Tulenko, FJ, Davis, MC, Fraser, GJ. 2015. Making teeth to order: Conserved genes reveal an ancient molecular pattern in paddlefish (Actinopterygii). Proc Biol Sci B 282:20142700.Google Scholar
Smith, MM, Johanson, Z, Underwood, C, Diekwisch, TGH. 2013. Pattern formation in development of chondrichthyan dentitions: A review of an evolutionary model. Hist Biol 25:27142.Google Scholar
Streelman, JT, Albertson, RC. 2006. Evolution of novelty in the cichlid dentition. J Exp Zool B: Mol Dev Evol 306:216226.Google Scholar
Streelman, JT, Bloomquist, RF, Fowler, TE. 2015. Developmental plasticity of patterned and regenerating oral organs. Curr Top Dev Biol 115:321333.Google Scholar
Streelman, JT, Webb, JF, Albertson, RC, Kocher, TD. 2003. The cusp of evolution and development: A model of cichlid tooth shape diversity. Evol Dev 5:600608.Google Scholar
Sun, Z, Yu, W, Sanz Navarro, M, Sweat, M, Eliason, S, Sharp, T, et al. 2016. Sox2 and Lef-1 interact with Pitx2 to regulate incisor development and stem cell renewal. Development 143:41154126.Google ScholarPubMed
Thesleff, I, Sharpe, P. 1997. Signalling networks regulating dental development. Mech Dev 67:111123.CrossRefGoogle ScholarPubMed
Thiery, AP, Shono, T, Kurokawa, D, Britz, R, Johanson, Z, Fraser, GJ. 2017. Spatially restricted dental regeneration drives pufferfish beak development. Proc Natl Acad Sci USA 114:E4425E4434.Google Scholar
Tucker, AS, Fraser, GJ. 2014. Evolution and developmental diversity of tooth regeneration. Sem Cell Dev Biol 25–26:7180.Google Scholar
Tucker, AS, Sharpe, P. 1999. Molecular genetics of tooth morphogenesis and patterning: The right shape in the right place. J Dent Res 78:826834.Google Scholar
Tucker, AS, Sharpe, P. 2004. The cutting-edge of mammalian development: How the embryo makes teeth. Nat Rev Genet 5:499508.Google Scholar
Tuisku, F, Hildebrand, C, 1994. Evidence for a neural influence on tooth germ generation in a polyphyodont species. Dev Biol 165:19.Google Scholar
Underwood, C, Johanson, Z, Smith, MM. 2016. Cutting blade dentitions in squaliform sharks form by modification of inherited alternate tooth ordering patterns. R Soc Open Sci 3:160385.Google Scholar
Underwood, CJ, Johanson, Z, Welten, M, Metscher, B, Rasch, LJ, Fraser, GJ, Smith, MM. 2015. Development and evolution of dentition pattern and tooth order in the skates and rays (Batoidea; Chondrichthyes). PLoS ONE 10:e0122553.Google Scholar

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