Proximity to competitors changes secondary metabolites of non-indigenous cup corals, Tubastraea spp., in the southwest Atlantic

详细信息    查看全文

• 作者：Bruno G. Lages (1)
  Beatriz G. Fleury (2)
  Ana M. C. Hovell (3)
  Claudia M. Rezende (3)
  Angelo C. Pinto (3)
  Joel C. Creed (2) jcreed@uerj.br
• 刊名：Marine Biology
• 出版年：2012
• 出版时间：July 2012
• 年：2012
• 卷：159
• 期：7
• 页码：1551-1559
• 全文大小：465.6 KB
• 参考文献：1. Aerts LAM, van Soest RWM (1997) Quantification of sponges/coral interactions in a physically stressed reef community, NE Colombia. Mar Ecol Prog Ser 148:125–134
  2. Becerro MA, Paul VJ, Starmer J (1998) Intracolonial variation in chemical defenses of the sponge Cacospongia sp. and its consequences on generalist fish predators and the specialist nudibranch Glossodoris pallida. Mar Ecol Prog Ser 168:187–196
  3. Brusca RC, Brusca GJ (2003) Invertebrates. Sinauer Associates, Inc., Sunderland
  4. Budzikiewicz H, Djerassi C, Williams DH (1964) Interpretation of mass spectra of compounds. Holden-Day, San Francisco
  5. Chiang IZ, Huang WY, Wu JT (2004) Allelochemicals of Botryococcus braunii (Chlorophyceae). J Phycol 40:474–480
  6. Coll JC (1992) The chemistry and chemical ecology of octocorals (Coelenterata, Anthozoa, Octocorallia). Chem Rev 92:613–631
  7. Coll JC, Sammarco PW (1983) Terpenoid toxins of soft corals (Cnidaria, Octocoralllia): their nature, toxicity, and ecological significance. Toxicon 3:69–72
  8. Creed JC (2006) Two invasive alien azooxanthellate corals, Tubastraea coccinea and Tubastraea tagusensis, dominate the native zooxanthellate Mussismilia hispida in Brazil. Coral Reefs 25:350
  9. Davies PS (1991) Effect of daylight variation on the energy budgets of shallow-water corals. Mar Biol 108:137–144
  10. De Paula AF (2007) Biologia reprodutiva, crescimento e competi莽茫o dos corais invasores Tubastraea coccinea e Tubastraea tagusensis (Scleractinia: Dendrophylliidae) com esp茅cies nativas. Dissertation, Federal University of Rio de Janeiro
  11. De Paula AF, Creed JC (2004) Two species of the coral Tubastraea (Cnidaria, Scleractinia) in Brazil: a case of accidental introduction. Bull Mar Sci 74:175–183
  12. De Paula AF, Creed JC (2005) Spatial distribution and abundance of nonindigenous coral genus Tubastraea (Cnidaria, Scleractinia) around Ilha Grande, Brazil. Braz J Biol 65:661–673
  13. Dworjanyn S, De Nys R, Steinberg PD (1999) Localization of secondary metabolites in the red alga Delisea pulchra. Mar Biol 133:727–736
  14. Epifanio RA, Maia LF, Pawlik JR, Fenical W (2007) Antipredatory secosterols from the octocoral Pseudopterogorgia americana. Mar Ecol Prog Ser 329:307–310
  15. Fleury BG, Coll JC, Sammarco PW, Tentori E, Duquesne S (2004) Complementary (secondary) metabolites in an octocoral competing with a scleractinian coral: effects of varying nutrient regimes. J Exp Mar Biol Ecol 303:115–131
  16. Fleury BG, Lages BG, Barbosa JP, Kaiser CR, Pinto AC (2008) New hemiketal steroid from the introduced soft coral Chromonephthea braziliensis is a chemical defense against predatory fishes. J Chem Ecol 34:1–5
  17. Glynn PW, Colley SB, Mat茅 JL, Cot茅s J, Guzman HM, Bailey RL, Feingold JS, Enochs IC (2007) Reproductive ecology of the azooxanthelate coral Tubastraea coccinea in the Equatorial Eastern Pacific: part V. Dendrophylliidae. Mar Biol 153:529–544
  18. Harland AD, Spencer Davies P, Fixter LM (1992) Lipid content of some Caribbean corals in relation to depth and light. Mar Biol 113:357–361
  19. Harvell CD, Fenical W (1989) Chemical and structural defenses of Caribbean gorgonians (Pseudopterogorgia spp.): intracolony localization of defense. Limnol Oceanogr 34:382–389
  20. Harvell CD, Fenical W, Roussis V, Ruesink JL, Griggs CC, Greene CH (1993) Local and geographic variation in the defensive chemistry of a West Indian gorgonian coral (Briaerum asbestinum). Mar Ecol Prog Ser 93:165–173
  21. Hay ME, Duffy JE, Fenical W, Gustafson K (1988) Chemical defense in the seaweed Dictyopteris delicatula: differential effects against reef fishes and amphipods. Mar Ecol Prog Ser 48:185–192
  22. Hill M (1998) Spongivory on Caribbean reefs releases corals from competition with sponges. Oecologia 117:143–150
  23. Kakisawa H, Asari F, Kusumi T, Toma T, Sakurai T, Oohusa T, Hara Y, Chihara M (1988) An allelopathic fatty acid from the brown alga Cladosiphon okamuranus. Phytochemistry 27:731–735
  24. Kelman D, Benayahu Y, Kashman Y (2000) Variation in secondary metabolite concentrations in yellow and grey morphs of the Red Sea soft coral Parerythropodium fulvum fulvum: possible ecological implications. J Chem Ecol 26:1123–1133
  25. Kelman D, Kashman Y, Hill R, Rosenberg E, Loya Y (2009) Chemical warfare in the sea. The search for antibiotics from Red Sea corals and sponges. Pure Appl Chem 81:1113–1121
  26. Kim K, Lasker HR (1997) Flow-mediated resource competition in the suspension feeding gorgonian Plexaura homomalla (Esper). J Exp Mar Biol Ecol 215:49–64
  27. Koh EGL (1997) Do scleractinian corals engage in chemical warfare against microbes? J Chem Ecol 23:379–398
  28. Koh EGL, Sweatman H (2000) Chemical warfare among scleractinians: bioactive natural products from Tubastraea falkneri Wells kill larvae of potential competitors. J Exp Mar Biol Ecol 251:141–160
  29. Lages BG, Fleury BG, Ferreira CEL, Pereira RC (2006) Chemical defense of an exotic coral as invasion strategy. J Exp Mar Biol Ecol 328:127–135
  30. Lages BG, Fleury BG, Pinto AC, Creed JC (2010) Chemical defenses against generalist fish predators and fouling organisms in two invasive ahermatypic corals in the genus Tubastraea. Mar Ecol 31:473–482
  31. Lages BG, Fleury BG, Menegola C, Creed JC (2011) Change in tropical rocky shore communities due to an alien coral invasion. Mar Ecol Prog Ser 438:85–96
  32. Latyshev NA, Naumenko NV, Svetashev VI, Latypov YY (1991) Fatty acids of reef-building corals. Mar Ecol Prog Ser 76:295–301
  33. Leoni PA, Bowden BF, Carroll AR, Coll JC (1995) Chemical consequences of relocation of the soft coral Lobophytum compactum and its placement in contact with the red alga Plocamium hamatum. Mar Biol 122:675–679
  34. L贸pez-Legentil S, Turon X, Schupp P (2006) Chemical and physical defenses against predators in Cystodytes (Ascidiacea). J Exp Mar Biol Ecol 332:27–36
  35. Maida M, Carroll AR, Coll JC (1993) Variability of terpene content in the soft coral Sinlularia flexibilis (Coelenterata: Octocorallia), and its ecological implications. J Chem Ecol 19:2285–2296
  36. Maida M, Sammarco PW, Coll JC (2006) A diffusion chamber for assessing efficacy of natural anti-fouling defenses in marine organisms. J Exp Mar Biol Ecol 337:59–64
  37. Mariscal RN (1974) Nematocysts. In: Muscatine L, Lenhoff HM (eds) Coelenterate biology (reviews and new perspectives). Academic Press, New York, pp 129–178
  38. M谩rquez JC, Zea S, L贸pez-Victoria M (2006) Is competition for space between the encrusting excavating sponge Cliona tenuis and corals influenced by higher-than-normal temperatures? Bol Invest Mar Cost 35:259–265
  39. Mart铆 R, Uriz MJ, Turon X (2005) Spatial and temporal variation of natural toxicity in cnidarians, bryozoans and tunicates in Mediterranean caves. Sci Mar 69:485–492
  40. Mclean EL, Yoshioka PM (2008) Substratum effects on the growth and survivorship of the sponge Desmapsamma anchorata. Caribb J Sci 44:83–89
  41. Meurer BC, Lages NS, Pereira AO, Palhano S, Magalh茫es GM (2010) First record of native species of sponge overgrowing invasive corals Tubastraea coccinea and Tubastraea tagusensis in Brazil. Mar Biodivers Rec 3:e62
  42. Nishiyama GK, Bakus GJ (1999) Release of allelochemicals by tree tropical sponges (Demospongiae) and their toxic effects on coral substrate competitors. Mem Queensl Mus 44:411–417
  43. O’Neal W, Pawlik JR (2002) A reappraisal of the chemical and physical defenses of Caribbean gorgonian corals against predatory fishes. Mar Ecol Prog Ser 240:117–126
  44. Occhipinti-Ambrogi A (2007) Global change and marine communities: alien species and climate change. Mar Pollut Bull 55:342–352
  45. 脰zbek S, Balasubramanian PG, Holstein TW (2009) Cnidocyst structure and the biomechanics of discharge. Toxicon 54:1038–1045
  46. Parker JD, Hay M (2005) Biotic resistance to plant invasions? Native herbivores prefer non-native plants. Ecol Lett 8:959–967
  47. Paul VJ, Ritson-Williams R (2008) Current developments in natural products chemistry. Nat Prod Rep 25:637–832
  48. Pawlik JR (1993) Marine invertebrate chemical defense. Chem Rev 93:1911–1922
  49. Pawlik JR, Chanas B, Toonen RJ, Fenical W (1995) Defenses of Caribbean sponges against predatory reef fish. I. Chemical deterrency. Mar Ecol Prog Ser 127:183–194
  50. Pereira RC (2004) A qu铆mica defensiva como potencial invasor de esp茅cies marinhas. In: Silva JSV, Souza RCCL (eds) 脕gua de lastro e bioinvas茫o. Interci锚ncia, Rio de Janeiro, pp 173–189
  51. Puyana M, Fenical W, Pawlik JR (2003) Are there activated chemical defenses in sponges of the genus Aplysina from the Caribbean. Mar Ecol Prog Ser 246:127–135
  52. Sammarco PW, Coll JC (1992) Chemical adaptations in Octocorallia: evolutionary considerations. Mar Ecol Prog Ser 88:93–104
  53. Schupp P, Eder C, Paul VJ, Proksch P (1999) Distribution of secondary metabolites in the sponge Oceanapia sp. and ecological implications. Mar Biol 135:573–580
  54. Sears MA, Gerhart DJ, Rittschof D (1990) Antifouling agents from marine sponge Lissodendoryx isodictyalis Carter. J Chem Ecol 16:791–799
  55. Sebens KP, Miles JS (1988) Sweeper tentacles in a gorgonian octocoral: morphological modifications for interference competition. Biol Bull 175:378–387
  56. Suzuki M, Wakana I, Denboh T, Tatewaki M (1996) An allelopathic polyunsaturated fatty acid from red algae. Phytochem 43:63–65
  57. Van Alstyne KL, Paul VJ (1992) Chemical and structural defenses in the sea fan Gorgonia ventalina: effects against generalist carnivorous fishes and specialist molluscan predators. Coral Reefs 11:155–159
  58. Van Alstyne KL, Wylie CR, Paul VJ, Meyer K (1994) Antipredator defenses in tropical pacific soft corals (Coelenterata: Alcyonacea). II. The relative importance of chemical and structural defenses in three species of Sinularia. J Exp Mar Biol Ecol 178:17–34
  59. Van Alstyne KL, McCarthy JJ, Hustead CL, Duggins DO (1999) Geographic variation in polyphenolic levels of Northeastern Pacific kelps and rockweeds. Mar Biol 133:371–379
  60. Wada H (1994) Contribution of membrane lipids to the ability of the photosynthetic machinery to tolerate temperature stress. Proc Natl Acad Sci USA 91:4273–4277
  61. Witman JD (1993) Physical disturbance and community structure of exposed and protected reefs: a case study from St. John, USVI. Am Zool 32:641–654
  62. Wulff JL (2005) Trade-offs in resistance to competitors and predators, and their effects of the diversity of tropical marine sponges. J Anim Ecol 74:313–321
  63. Yamashiro H, Oku H, Higa H, Chinen I, Sakai K (1999) Composition of lipids, fatty acids and sterols in Okinawan corals. Comp Biochem Physiol 122:397–407
• 作者单位：1. Programa de P贸s-Gradua莽茫o em Ecologia e Evolu莽茫o, Instituto de Biologia Roberto Alc芒ntara Gomes, Universidade do Estado do Rio de Janeiro, UERJ, PHLC Sala 224, Avenida S茫o Francisco Xavier 524, Rio de Janeiro, RJ 20559-900, Brazil2. Departamento de Ecologia, Instituto de Biologia Roberto Alc芒ntara Gomes, Universidade do Estado do Rio de Janeiro-UERJ, PHLC Sala 220, Rua S茫o Francisco Xavier 524, Rio de Janeiro, RJ 20559-900, Brazil3. Departamento de Qu铆mica Org芒nica, Instituto de Qu铆mica, Universidade Federal do Rio de Janeiro, Bloco A, CT, Ilha do Fund茫o, Rio de Janeiro, RJ 21945-970, Brazil
• 刊物类别：Biomedical and Life Sciences
• 刊物主题：Life Sciences
  Ecology
  Biomedicine
  Oceanography
  Microbiology
  Zoology
  
• 出版者：Springer Berlin / Heidelberg
• ISSN：1432-1793

文摘

Competition for space changes species’ distributions and community organization on tropical rocky shores, and the presence of secondary metabolites in the tissues of non-indigenous species may aid them in establishing and expanding their range through negative competitive interactions. The aim of this study was to describe the range of chemical substances produced by the non-indigenous cup corals Tubastraea coccinea and T. tagusensis and to test whether they varied in the field when the corals were placed in proximity to two local competitors. Cholest-5-en-3β-ol and 9-octadecanoic acid were two common secondary metabolites found in the tissues of Tubastraea. In the competition interaction experiment, necrosis was detected on the tissues of the coral Mussismilia hispida, and this species induced variation in sterol, alkaloid, and fatty acid production in Tubastraea tissues. In contrast, a sponge overgrew Tubastraea colonies. These results indicate that chemical defense may contribute to the ability of these non-indigenous corals to invade native communities.