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Taiwan

  • Vianney DenisEmail author
  • Derek Soto
  • Stéphane De Palmas
  • Yu Ting Vicky Lin
  • Yehuda Benayahu
  • Yusheng Michael Huang
  • Shao-Lun Liu
  • Jian-Wen Chen
  • Qi Chen
  • Nicolas Sturaro
  • Ming-Jay Ho
  • Yeng Su
  • Chang Feng Dai
  • Chaolun Allen Chen
Chapter
Part of the Coral Reefs of the World book series (CORW, volume 12)

Abstract

Taiwan straddles tropical and subtropical latitudes in the North Pacific Ocean. While shallow-water coral reefs in Taiwan have been studied for many years, mesophotic coral ecosystems (MCEs) have recently enjoyed a surge of interest because they are hypothesized to provide a refuge for some reef species in distress. The distribution of MCEs in Taiwan is influenced by numerous biophysical and environmental variables including substrate availability, temperature, light irradiance, and sedimentation. In 1991, an early survey of the diversity of MCEs off Taiwan’s southern coast highlighted sedimentation and the lack of suitable substrates as important factors restricting reef communities at depths below 30 m. The steeply sloping east coast of Taiwan supports well-developed and more accessible MCEs and has therefore been the focus of recent research. Preliminary surveys have documented 18 macroalgal, 95 scleractinian, 33 octocoral, 2 antipatharian, 14 sponge, and 76 fish species. With the exception of a few scleractinians recorded for the first time and possibly restricted to mesophotic waters, the majority of species have a wide bathymetric distribution in Taiwan. However, low-light conditions at mesophotic depths in the north restrict the distribution of photosynthetic organisms to shallow waters. Only one zooxanthellate scleractinian species was found at depths below 40 m where benthic communities are dominated by fan- and whip-shaped octocorals. Historically, MCEs have received little research interest in Taiwan, and most current research is focused on descriptive studies. Future research should examine the ecological importance of these habitats and the roles they play in reef survival.

Keywords

Mesophotic coral ecosystems Distribution Reef diversity Coral reefs Marginal reefs 

Notes

Acknowledgments

We would like to thank Tom Bridge, Chao-Yang Kuo, George Roff, and an anonymous reviewer for their comments and advice on this chapter. Authors also thank the Green Island Marine Research Station, Academia Sinica, and its staff for logistic support during fieldwork at Ludao. YB also acknowledges A. Shlagman for curatorial skills. This work was supported by grants from the Ministry of Science and Technology of Taiwan to VD (no. 104-2611-M-002-020-MY2, 106-2611-M-002-008), YMH (no. 105-2621-B-346-002), SLL (no. 105-2621-B-029-002), and CAC (no. 103-2621-B-001-004-MY3, 106-2611-M-001-005). This research was in part supported by the Israel Cohen Chair in Environmental Zoology to YB. In addition, SDP and DS are supported by PhD fellowships from the Taiwan International Graduate Program, Academia Sinica. NS benefits from a National Taiwan University postdoctoral fellowship (Taiwan, 106R4000). All specimens collected for this study were sampled under permits issued by Kenting National Park (no. 1050004090, Kenting), Taitung County Government (no. 1040000285, 1050083633, Green Island), Fisheries and Fishing Port Affairs Management office, New Taipei City Government (no. 1053205245, Longdong), and Keelung City Government (no. 1050115641, Keelung Island).

This work would not have been possible without the contribution of our respected colleague and friend Su Yeng. Master Su was a pioneer scuba diver in Taiwan, and inspired many of us. We would like to dedicate this chapter on Taiwan to him.

References

  1. Asher J, Williams I, Harvey E (2017) Mesophotic depth gradients impact reef fish assemblage composition and functional group partitioning in the main Hawaiian Islands. Front Mar Sci 4:98CrossRefGoogle Scholar
  2. Baker E, Puglise KA, Colin PL, Harris PT, Kahng SE, Rooney JJ, Sherman C, Slattery M, Spalding HL (2016) What are mesophotic coral ecosystems? In: Baker EK, Puglise KA, Harris PT (eds) Mesophotic coral ecosystems – a lifeboat for coral reefs? The United Nations Environment Programme and GRID-Arendal, Nairobi, pp 11–19Google Scholar
  3. Ballesteros E (2006) Mediterranean coralligenous assemblages: a synthesis of present knowledge. Oceanogr Mar Biol Annu Rev 44:123–195Google Scholar
  4. Bo M, Bertolino M, Borghini M, Castellano M, Harriague AC, Di Camillo CG, Pietro GG, Misic C, Povero P, Pusceddu A, Schroeder K, Bavestrello G (2011) Characteristics of the mesophotic megabenthic assemblages of the Vercelli seamount (north Tyrrhenian Sea). PLoS ONE 6:e16357CrossRefGoogle Scholar
  5. Bongaerts P, Smith TB (2019) Beyond the “Deep Reef Refuge” hypothesis: a conceptual framework to characterize persistence at depth. In: Loya Y, Puglise KA, Bridge TCL (eds) Mesophotic coral ecosystems. Springer, New York, pp 881–895Google Scholar
  6. Bongaerts P, Ridgway T, Sampayo EM, Hoegh-Guldberg O (2010) Assessing the “Deep Reef Refuge” hypothesis: focus on Caribbean reefs. Coral Reefs 29:309–327CrossRefGoogle Scholar
  7. Brokovich E, Einbinder S, Shashar N, Kiflawi M, Kark S (2008) Descending to the twilight-zone: changes in coral reef fish assemblages along a depth gradient down to 65 m. Mar Ecol Prog Ser 371:253–262CrossRefGoogle Scholar
  8. Brokovich E, Ayalon I, Einbinder S, Segev N, Shaked Y, Genin A, Kark S, Kiflawi M (2010) Grazing pressure on coral reefs decreases across a wide depth gradient in the Gulf of Aqaba, Red Sea. Mar Ecol Prog Ser 399:69–80CrossRefGoogle Scholar
  9. Burrows MT, Schoeman DS, Buckley LB, Moore P, Poloczanska ES, Brander KM, Brown C, Bruno JF, Duarte CM, Halpern BS, Holding J, Kappel CV, Kiessling W, O’Connor MI, Pandolfi JM, Parmesan C, Schwing FB, Sydeman WJ, Richardson AJ (2011) The pace of shifting climate in marine and terrestrial ecosystems. Science 334:652–655CrossRefGoogle Scholar
  10. Central Weather Bureau (2018) II. Typhoon’s impact on Taiwan. http://www.cwb.gov.tw/V7e/knowledge/encyclopedia/ty014.htm. Accessed 1 Feb 2018
  11. Chao S, Chang K (1989) The shallow-water holothurians (Echinodermata: Holothuroidea) of southern Taiwan. Bull Inst Zool Acad Sin 28:107–137Google Scholar
  12. Chen CA (1999) Analysis of scleractinian distribution in Taiwan indicating a pattern congruent with sea surface temperatures and currents: examples from Acropora and Faviidae corals. Zool Stud 38:119–129Google Scholar
  13. Chen JP (2004) Biodiversity and conservation of Kenting National Park fish fauna. Kenting Natl Park Rep. (In Chinese)Google Scholar
  14. Chen CC, Chang KH (1991) Gorgonacea (Coelenterata: Anthozoa: Octocorallia) of southern Taiwan. Bull Inst Zool Acad Sin 30:149–183Google Scholar
  15. Chen CA, Shashank K (2009) Taiwan as a connective stepping-stone in the Kuroshio triangle and the conservation of coral ecosystems under the impacts of climate change. Kuroshio Sci 3:15–22Google Scholar
  16. Chen JC, Lee CS, Wang CS, Leu FJ, Shyu CT (1974) Report on the geophysical survey in Nan Wan. Institute of Oceanography, National Taiwan University, Taipei 26 pGoogle Scholar
  17. Chen JC, Chang KH, Chen CP (1988) Shallow water crinoids of Kenting National Park, Taiwan. Bull Inst Zool Acad Sin 27:73–90Google Scholar
  18. Colin PL (2016) Spotlight on the Palau Island group. In: Baker EK, Puglise KA, Harris PT (eds) Mesophotic coral ecosystems – a lifeboat for coral reefs? The United Nations Environment Programme and GRID-Arendal, Nairobi, pp 31–36Google Scholar
  19. Dai CF (1988) Coral communities of southern Taiwan. Proc 6th Int Coral Reef Symp 2:647–652Google Scholar
  20. Dai CF (2006) Distribution and species diversity of reef corals in Taiwan (II) Eastern Taiwan. Fish Agent, Council of Agriculture, Taipei. (In Chinese)Google Scholar
  21. Dai CF (2007) Distribution and species diversity of reef corals in Taiwan (III) southern Taiwan including Xiaoliuchiu. Fish Agent, Council of Agriculture, Taipei. (In Chinese)Google Scholar
  22. Dai CF, Fan TY (1996) Coral fauna of Taiping Island (Itu Aba Island) in the Spratlys of the South China Sea. Atoll Res Bull 436:1–21Google Scholar
  23. Dai CF, Horng S (2009) Scleractinia fauna of Taiwan I. The complex group. National Taiwan University, TaipeiGoogle Scholar
  24. Dai CF, Stewart LL, Cooper RA, Sprunk HJ (1992) Distribution of substrates and macrobenthos at depths between 35 and 120 m in southern Taiwan. Acta Oceanogr Taiwan 28:1–18Google Scholar
  25. Dai CF, Fan TY, Wu CS (1995) Coral fauna of Tungsha Tao (Pratas Islands). Acta Oceanogr Taiwan 34:1–16Google Scholar
  26. Dai CF, Soong K, Jeng MS, Chen CA, Fan TY (2004) Status of coral reefs in Taiwan. Fish Agent, Council of Agriculture, Taipei. (In Chinese)Google Scholar
  27. De Palmas S, Soto D, Denis V, Ho MJ, Chen CA (2018) Molecular assessment of Pocillopora verrucosa (Scleractinia; Pocilloporidae) distribution along a depth gradient in Ludao, Taiwan. PeerJ 6:e5797CrossRefGoogle Scholar
  28. Denis V, De Palmas S, Benzoni F, Chen CA (2015) Extension of the known distribution and depth range of the scleractinian coral Psammocora stellata: first record from a Taiwanese mesophotic reef. Mar Biodivers 45:619–620CrossRefGoogle Scholar
  29. Denis V, Lin YTV, Ho MJ (2019) A new association between goblet worms (Entoprocta) and xeniid corals (Cnidaria). Mar Biodivers 49:487–493CrossRefGoogle Scholar
  30. Eguchi M (1968) The hydrocorals and scleractinian corals of Sagami Bay collected by HM the Emperor of Japan. Maruz, Tokyo, pp C1–C74Google Scholar
  31. Fricke H, Meischner D (1985) Depth limits of Bermudan scleractinian corals: a submersible survey. Mar Biol 88:175–187CrossRefGoogle Scholar
  32. Fricke H, Schuhmacher H (1983) The depth limits of Red Sea stony corals: an ecophysiological problem (a deep diving survey by submersible). Mar Ecol 4:163–194CrossRefGoogle Scholar
  33. Friedlander AM, DeMartini EE (2002) Contrasts in density, size, and biomass of reef fishes between the northwestern and the main Hawaiian islands: the effects of fishing down apex predators. Mar Ecol Prog Ser 230:253–264CrossRefGoogle Scholar
  34. Froese R, Pauly D (2017) FishBase. www.fishbase.org. Accessed 31 July 2017
  35. Gori A, Rossi S, Berganzo E, Pretus JL, Dale MRT, Gili JM (2011) Spatial distribution patterns of the gorgonians Eunicella singularis, Paramuricea clavata, and Leptogorgia sarmentosa (Cape of Creus, northwestern Mediterranean Sea). Mar Biol 158:143–158CrossRefGoogle Scholar
  36. Hinderstein LM, Marr JCA, Martinez FA, Dowgiallo MJ, Puglise KA, Pyle RL, Zawada DG, Appeldoorn R (2010) Theme section on “Mesophotic coral ecosystems: characterization, ecology, and management.” Coral Reefs 29:247–251CrossRefGoogle Scholar
  37. Hsieh HJ, Hsien YL, Jeng MS, Tsai WS, Su WC, Chen CA (2008) Tropical fishes killed by the cold. Coral Reefs 27:599CrossRefGoogle Scholar
  38. Jan RQ, Chen JP (2010) The ecological resource survey in Houbihu marine protected areas (2nd year). Kenting Natl Park Hqrs. (In Chinese)Google Scholar
  39. Jeng MS, Dai CF, Chen JP, Wang WL, Meng PJ (2008) Survey and monitoring of coral reef ecology resources at Dongsha Atoll (II). Mar Natl Park Headquarters, Gaoxiong (In Chinese)Google Scholar
  40. Jones O, Randall R, Cheng Y, Kami H, Mak SM (1972) A marine biological survey of southern Taiwan with emphasis on corals and fishes. Inst Oceanogr Natl Taiwan Univ Spec Publ 1:1–93Google Scholar
  41. Kahng SE, García-Sais JR, Spalding HL, Brokovich E, Wagner D, Weil E, Hinderstein L, Toonen RJ (2010) Community ecology of mesophotic coral reef ecosystems. Coral Reefs 29:255–275CrossRefGoogle Scholar
  42. Kawaguti S (1942) Coral fauna of the Taiwan waters. Kagaku no Taiwan 11:1–6. (In Japanese)Google Scholar
  43. Kawaguti S (1943) Coral fauna of Garampi. Trans Nat Hist Soc Formosa 33:258–259. (In Japanese)Google Scholar
  44. Kawaguti S (1953) Coral fauna of the island of Botel Tobago, Formosa with a list of corals from the Formosan waters. Biol J Okayama Univ 1:185–198Google Scholar
  45. Kleypas JA, McManus JW, Meñez LAB (1999) Environmental limits to coral reef development: where do we draw the line? Am Zool 39:146–159CrossRefGoogle Scholar
  46. Ma T (1957) The effect of warm and cold currents in the southern western Pacific on the growth rate of reef corals. Oceanogr Sin 5:1–34Google Scholar
  47. Ma T (1958) The relation of growth rate of reef corals to surface temperature of sea water as basis for study of causes of diastrophisms instigating evolution of life. Research on the part climate and continental drift, vol 14. World Book Corporation, TaipeiGoogle Scholar
  48. Ma T (1959) Effect of water temperature on growth rate of corals. Oceanogr Sin Spec 1:1–116Google Scholar
  49. Nishihira M, Veron JEN (1995) Hermatypic corals of Japan. Kaiyusha, TokyoGoogle Scholar
  50. Pante E, Simon-Bouhet B (2013) Marmap: a package for importing, plotting and analyzing bathymetric and topographic data in R. PLoS ONE 8:e73051CrossRefGoogle Scholar
  51. Pyle RL, Boland R, Bolick H, Bowen BW, Bradley CJ, Kane C, Kosaki RK, Langston R, Longenecker K, Montgomery A, Parrish FA, Popp BN, Rooney J, Smith CM, Wagner D, Spalding HL (2016) A comprehensive investigation of mesophotic coral ecosystems in the Hawaiian archipelago. PeerJ 4:e2475CrossRefGoogle Scholar
  52. Ribas-Deulofeu L, Denis V, De Palmas S, Kuo CY, Hsieh HJ, Chen CA (2016) Structure of benthic communities along the Taiwan latitudinal gradient. PLoS ONE 11:e0160601CrossRefGoogle Scholar
  53. Richmond S, Stevens T (2014) Classifying benthic biotopes on sub-tropical continental shelf reefs: how useful are abiotic surrogates? Estuar Coast Shelf Sci 138:79–89CrossRefGoogle Scholar
  54. Sinniger F, Ballantine DL, Bejarano I, Colin PL, Pochon X, Pomponi SA, Puglise KA, Pyle RL, Reaka ML, SH L, Weil E (2016) Biodiversity of mesophotic coral ecosystems. In: Baker EK, Puglise KA, Harris PT (eds) Mesophotic coral ecosystems – a lifeboat for coral reefs? The United Nations Environment Programme and GRID-Arendal, Nairobi, pp 50–62Google Scholar
  55. Sinniger F, Harii S, Humblet M, Nakamura Y, Ohba H, Prasetia R (2019) Ryukyus Islands, Japan. In: Loya Y, Puglise KA, Bridge TCL (eds) Mesophotic coral ecosystems. Springer, New York, pp 231–247Google Scholar
  56. Soto D, De Palmas S, Ho MJ, Denis V, Chen CA (2018) Spatial variation in the morphological traits of Pocillopora verrucosa along a depth gradient in Taiwan. PLoS ONE 13:e0202586CrossRefGoogle Scholar
  57. Su C, Hung T, Chiang Y, Tan T, Chang K, Yang R, Cheng Y, Fan K, Chang H (1984) An ecological survey on the waters adjacent to the nuclear power plant in southern Taiwan. V. The progress report of the fifth year study (1983–1984) and the summary report of five years preoperational stage studies (1979–1984). Nat Sci Commun Prob Environ Spec Publ 27:214. (In Chinese)Google Scholar
  58. Sugiyama T (1937) On the recent reef-building corals found in the Japanese seas. Sci Rep Tohôku Imp Univ 2nd Ser Geol 26:1–60. (In Japanese)Google Scholar
  59. Syu MR, Lee PH, Leou TM, Shen Y (2016) Solar irradiance and pan evaporation estimation from meteorological satellite data. Terr Atmos Ocean Sci 27:221–239CrossRefGoogle Scholar
  60. Turner JA, Babcock RC, Hovey R, Kendrick GA (2017) Deep thinking: a systematic review of mesophotic coral ecosystems. ICES J Mar Sci fsx085:1–12Google Scholar
  61. Veron JEN (2000) Corals of the world, vol 1–3. Australian Institute of Marine Science, TownsvilleGoogle Scholar
  62. Veron JEN, Minchin PR (1992) Correlations between sea surface temperature, circulation patterns and the distribution of hermatypic corals of Japan. Cont Shelf Res 12:835–857CrossRefGoogle Scholar
  63. White KN, Ohara T, Fujii T, Kawamura I, Mizuyama M, Montenegro J, Shikiba H, Naruse T, McClelland T, Denis V, Reimer JD (2013) Typhoon damage on a shallow mesophotic reef in Okinawa, Japan. PeerJ 1:e151CrossRefGoogle Scholar
  64. White KN, Weinstein DK, Ohara T, Denis V, Montenegro J, Reimer JD (2017) Shifting communities after typhoon damage on an upper mesophotic reef in Okinawa, Japan. PeerJ 5:e3573CrossRefGoogle Scholar
  65. Yabe H, Sugiyama T (1932) Reef corals found in the Japanese sea. Sci Reports Tohôku Imp Univ 2nd Ser Geol 15:143–168Google Scholar
  66. Yabe H, Sugiyama T (1941) Recent reef-building corals from Japan and the South Sea Islands under the Japanese mandate. II. Sci Rep Tohôku Imp Univ 2nd Ser Geol Spec 2:67–91, pl 60–104Google Scholar
  67. Yabe H, Sugiyama T, Eguchi M (1936) Recent reef-building corals from Japan and the South Sea Islands under the Japanese mandate. I. Sci Rep Tohôku Imp Univ 2nd Ser Geol 1:1–166Google Scholar
  68. Yamano H, Sugihara K, Nomura K (2011) Rapid poleward range expansion of tropical reef corals in response to rising sea surface temperatures. Geophys Res Lett 38:L04601CrossRefGoogle Scholar
  69. Yamazato K (1972) Bathymetric distribution of corals in the Ryukyu Islands. In: Proceedings of the 1st International Symposium on Corals and Coral Reefs 1969, Marine Biological Association, India, pp 121–133Google Scholar
  70. Yang RT (1985) Coral communities in Nan-Wan Bay (Taiwan). Proc 5th Int Coral Reef Congr 6:273–278Google Scholar
  71. Yang RT, Dai CF (1982) Coral communities in Yenliao Bay, Taiwan. Acta Oceanogr Taiwan 13:167–180Google Scholar

Copyright information

© Springer Nature Switzerland AG 2019

Authors and Affiliations

  • Vianney Denis
    • 1
    Email author
  • Derek Soto
    • 2
    • 3
    • 4
  • Stéphane De Palmas
    • 2
    • 3
    • 4
  • Yu Ting Vicky Lin
    • 1
  • Yehuda Benayahu
    • 5
  • Yusheng Michael Huang
    • 6
    • 7
  • Shao-Lun Liu
    • 8
  • Jian-Wen Chen
    • 1
  • Qi Chen
    • 1
  • Nicolas Sturaro
    • 1
  • Ming-Jay Ho
    • 9
  • Yeng Su
    • 6
  • Chang Feng Dai
    • 1
  • Chaolun Allen Chen
    • 2
    • 4
  1. 1.Institute of OceanographyNational Taiwan UniversityTaipeiTaiwan
  2. 2.Biodiversity Program, Taiwan International Graduate Program, Academia SinicaNational Taiwan Normal UniversityTaipeiTaiwan
  3. 3.Department of Life ScienceNational Taiwan Normal UniversityTaipeiTaiwan
  4. 4.Biodiversity Research CenterAcademia SinicaTaipeiTaiwan
  5. 5.Faculty of Life Sciences, School of ZoologyTel Aviv UniversityTel AvivIsrael
  6. 6.Department of Marine RecreationNational Penghu University of Science and TechnologyMagongTaiwan
  7. 7.Naturalis Biodiversity CentreLeidenThe Netherlands
  8. 8.Department of Life ScienceTunghai UniversityTaichungTaiwan
  9. 9.Green Island Marine Research Station, Biodiversity Research CenterAcademia SinicaTaipeiTaiwan

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