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PLOS ONE 2012

Ancient Origin of the Modern Deep-Sea Fauna

DOI: 10.1371/journal.pone.0046913

Ben Thuy, Andy S. Gale, Andreas Kroh, Michal Kucera, Lea D. Numberger-Thuy, Mike Reich, Sabine St？hr

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Abstract:

The origin and possible antiquity of the spectacularly diverse modern deep-sea fauna has been debated since the beginning of deep-sea research in the mid-nineteenth century. Recent hypotheses, based on biogeographic patterns and molecular clock estimates, support a latest Mesozoic or early Cenozoic date for the origin of key groups of the present deep-sea fauna (echinoids, octopods). This relatively young age is consistent with hypotheses that argue for extensive extinction during Jurassic and Cretaceous Oceanic Anoxic Events (OAEs) and the mid-Cenozoic cooling of deep-water masses, implying repeated re-colonization by immigration of taxa from shallow-water habitats. Here we report on a well-preserved echinoderm assemblage from deep-sea (1000–1500 m paleodepth) sediments of the NE-Atlantic of Early Cretaceous age (114 Ma). The assemblage is strikingly similar to that of extant bathyal echinoderm communities in composition, including families and genera found exclusively in modern deep-sea habitats. A number of taxa found in the assemblage have no fossil record at shelf depths postdating the assemblage, which precludes the possibility of deep-sea recolonization from shallow habitats following episodic extinction at least for those groups. Our discovery provides the first key fossil evidence that a significant part of the modern deep-sea fauna is considerably older than previously assumed. As a consequence, most major paleoceanographic events had far less impact on the diversity of deep-sea faunas than has been implied. It also suggests that deep-sea biota are more resilient to extinction events than shallow-water forms, and that the unusual deep-sea environment, indeed, provides evolutionary stability which is very rarely punctuated on macroevolutionary time scales.

References

[1]	Rex MA, Etter RJ (2010) Deep-Sea Biodiversity: Pattern and Scale. MA: Harvard University Press. 354 p.
[2]	Thomson CW (1873) The Depths of the Sea. London: Macmillan & Co. 527 p.
[3]	Jablonski D (2005) Evolutionary innovations in the fossil record: The intersection of ecology, development and macroeveolution. J Exp Zool (Mol Dev Evol) 304: 504–519.
[4]	Jacobs DK, Lindberg DR (1998) Oxygen and evolutionary patterns in the sea: Onshore/offshore trends and recent recruitment of deep-sea faunas. Proc Natl Acad Sci USA 95: 9396–9401.
[5]	Menzies RJ, George RY, Rowe GT (1973) Abyssal Environment and Ecology of the World Oceans. New York: Wiley-Interscience. 488 p.
[6]	Smith AB, Stockley B (2005) The geological history of deep-sea colonization by echinoids: roles of surface productivity and deep-water ventilation. Proc R Soc B 272: 865–869.
[7]	Strugnell JM, Rogers AD, Prod？hl PA, Collins M, Allcock AL (2008) The thermohaline expressway: the Southern Ocean as a centre of origin for deep-sea octopuses. Cladistics 24: 853–860.
[8]	Wilson GDF (1999) Some of the deep-sea fauna is ancient. Crustaceana 72: 1019–1030.
[9]	Gage JD, Tyler PA (1991) Deep-Sea Biology: A Natural History of Organisms at the Deep-Sea Floor. Cambridge: Cambridge University Press. 504 p.
[10]	Tyler PA, Rice AL, Young CM, Gebruk AA (1996) Walk on the deep side: animals in the deep sea. In: Summerhayes CP, Thorpe SA, editors. Oceanography – An Illustrated Guide. London: Manson. 195–211.
[11]	Jagt JWM (2000) Late Cretaceous-Early Palaeogene echinoderms and the K/T boundary in the southeast Netherlands and northeast Belgium. Part 5: Asteroids. Scripta Geologica 121: 377–503.
[12]	Hess H (1975) Die fossilen Echinodermen des Schweizer Juras. Ver？ff Naturhist Mus Basel 8: 1–130.
[13]	Norris RD, Kroon D, Klaus A, Alexander IT, Bardot LP, et al.. (1998) Proceedings of the Ocean Drilling Program, Initial Reports 171B. College Station, TX (Ocean Drilling Program): 1–749.
[14]	Huber BT, Leckie RM (2011) Planktic foraminiferal species turnover across deep-sea Aptian-Albian boundary sections. J Foram Res 41: 53–95.
[15]	Huber BT, MacLeod KG, Gr？cke DR, Kucera M (2011) Paleotemperature and paleosalinity inferences and chemostratigraphy across the Aptian/Albian boundary in the subtropical North Atlantic. Paleoceanography 26: PA4221.
[16]	Holbourn A, Kuhnt W (2001) No extinctions during Oceanic Anoxic Event 1b: the Aptian–Albian benthic foraminiferal record of ODP Leg 171. In: Geol Soc London, Spec Publ Kroon D, Norris RD, Klaus A, editors. Western North Atlantic Palaeogene and Cretaceous Palaeoceanography. 183: 73–92.
[17]	Thuy B, St？hr S (2011) Lateral arm plate morphology in brittle stars (Echinodermata: Ophiuroidea): new perspectives for ophiuroid micropalaeontology and classification. Zootaxa 3013: 1–47.
[18]	Tyler PA (1980) Deep-sea ophiuroids. Oceanogr Mar Biol Ann Rev 18: 125–153.
[19]	Litvinova NM (1992) Revision of the genus Ophiotholia (Echinodermata, Ophiuroidea). Zool Zh 72: 47–57.
[20]	Gale AS (2011) The phylogeny of post-Palaeozoic Asteroidea (Neoasteroidea, Echinodermata). Spec Pap Palaeont 85: 5–112.
[21]	Clark AM, Downey ME (1992) Starfishes of the Atlantic. London, New York, Tokyo, Melbourne, Madras: Chapman & Hall. 794 p.
[22]	Hansen B (1975) Systematics and biology of the deep-sea holothurians. Part 1. Elasipoda. Galathea Rep Sc Res Danish Deep-Sea Exp (1950–1952) 13: 1–262.
[23]	Barras CG (2007) Phylogeny of the Jurassic to Early Cretaceous ‘disasteroid’ echinoids (Echinoidea; Echinodermata) and the origins of spatangoids and holasteroids. J Syst Palaeontol 5: 134–161.
[24]	Kroh A, Smith AB (2010) The phylogeny and classification of post-Palaeozoic echinoids. J Syst Palaeontol 8: 147–212.
[25]	Hess H (2011) Treatise on Invertebrate Paleontology, Part T, Revised, Echinodermata 2, volume 3, Crinoidea Articulata. Lawrence: KU Paleontological Institute, Univ. of Kansas. xxix +261 p.
[26]	McClain CR, Mincks Hardy S (2010) The dynamics of biogeographic ranges in the deep sea. Proc R Soc B 277: 3533–3546.
[27]	Jenkyns HC (2010) Geochemistry of Oceanic Anoxic Events. Geochem Geophys Geosyst 11: 1–30.
[28]	Kennett JP, Stott LD (1991) Abrupt deep-sea warming, palaeoceanographic changes and benthic extinctions at the ed of the Palaeocene. Nature 353: 225–229.
[29]	Benson RH (1975) The origin of the psychrosphere as recorded in changes of deep-sea ostracode assemblages. Lethaia 8: 69–83.
[30]	Blake DB, Jagt JWM (2005) New latest Cretaceous and earliest Paleogene asteroids (Echinodermata) from the Netherlands and Denmark and their palaeobiological significance. Bull Inst Royal Sc Nat Belg, Sci Terre 75: 183–200.
[31]	Charbonnier S, Vannier J, Gaillard C, Bourseau JP, Hantzpergue P (2007) The La Voulte Lagerst？tte (Callovian): Evidence for a deep water setting from sponge and crinoid communities. Palaeogeo Palaeoclim Palaeoecol 250: 216–236.
[32]	Gammon PR, James NP, Pisera A (2000) Eocene spiculites and spongiolites in southwestern Australia: Not deep, not polar, but shallow and warm. Geology 28: 855–858.
[33]	Kiel S, Little CTS (2006) Cold-seep molluscs are older than the general marine mollusc fauna. Science 313: 1429–1431.
[34]	Cronin TM, Raymo ME (1997) Orbital forcing of deep-sea benthic species diversity. Nature 385: 624–627.
[35]	Isozaki Y (1997) Permo-Triassic boundary superanoxia and stratified superocean: records from lost deep sea. Science 276: 235–238.
[36]	Ward PD, Haggart JW, Carter ES, Wilbur D, Tipper HW, et al. (2001) Sudden productivity collapse associated with the Triassic-Jurassic boundary mass extinction. Science 292: 1148–1151.
[37]	Boos K, Franke H-D (2006) Brittle stars (Echinodermata: Ophiuroidea) in the German Bight (North Sea) – species diversity during the past 130 years. J Mar Biol Ass UK 86: 1187–1197.
[38]	Clark HL (1911) North Pacific ophiurans in the collection of the United States National Museum. Bull US Nat Mus 75: 1–302.
[39]	Clark HL (1939) Ophiuroidea. Sci Rep John Murray Exped 6: 29–136.
[40]	Koehler R (1922) Ophiurans of the Philippine seas and adjacent waters. Bull US Nat Mus 100: 1–486.
[41]	Koehler R (1901) Echinides et ophiures. Résultats du voyage du S.Y. Belgica en 1897–1898–1899 sous le commandement de A. de Gerlache de Gomery. Anvers: Rapports Scientifiques (1901–1913) Buschmann. 42 p.
[42]	Koehler R (1914) Ophiures des mers profondes. Siboga-Exped 45: 1–176.
[43]	Koehler R (1914) A contribution to the study of ophiurans of the United States National Museum. Bull US Nat Mus 84: 1–173.
[44]	Manjón-Cabeza ME, Ramos A (2009) Ophiuroid community structure of the South Shetland Islands and Antarctic Peninsula region. Polar Biol 26: 691–699.
[45]	Hess H (1970) Schlangensterne und Seesterne aus dem oberen Hauterivien “Pierre jaune" von St-Blaise bei Neuchatel. Eclogae geol Helv 63: 1069–1091.
[46]	Storc R, Zitt J (2008) Late Turonian ophiuroids (Echinodermata) from the Bohemian Cretaceous Basin, Czech Republic. Bull Geosci 83: 123–140.
[47]	Vera JA (2004). editor. Geología de Espa？a. Madrid: SGE-IGME. 890 p.
[48]	Young JR, Gale AS, Knight RI, Smith AB (2010) Fossils of the Gault Clay. Palaeontological Association Field Guide to Fossils 12: 1–342.
[49]	Blake DB, Reid R III (1998) Some Albian (Cretaceous) asteroids (Echinodermata) from Texas and their paleobiological implications. J Paleont 72: 512–532.
[50]	Hammer ？, Harper DAT, Ryan PD (2001) PAST: Paleontological Statistics Software Package for Education and Data Analysis. Palaeontol Electron 4: 1–9.
[51]	Erbacher J, Huber BT, Norris RD, Markey M (2001) Increased thermohaline stratification as a possible cause for an ocean anoxic event in the Cretaceous period. Nature 409: 325–327.

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