[1. Alcock R., 2003 – The effects of climate change on rocky shore communities in the bay of Biscay, 1895-2050, Southampton, 21.]Search in Google Scholar
[2. Aguilar C. and González S. G., 2007 – Composición de la ictiofauna costera de Ciudad de la Habana y evaluación preliminar de los factores que la determinan, Revista de Investigaciones Marinas, 28, 1, 43-56. (in Spanish)]Search in Google Scholar
[3. Aguilar C., 2005 – La ictiofauna costera de Ciudad de La Habana: Efectos acumulativos de agentes estresantes múltiples en varios niveles de organización biológica, Thesis presented as an option to the scientific degree of Doctor in Biological Sciences, Centro de Investigaciones Marinas, Universidad de La Habana, Cuba, 122. (in Spanish)]Search in Google Scholar
[4. AGRRA, 2000 – The AGRRA, Rapid Assessment Protocol, Atlantic and Gulf rapid reef assessment methodology, 9, URL: http://coral.aoml.noaa.gov/agrra/methodhome.htm.]Search in Google Scholar
[5. Angulo V. J., Borrego R. A., Borrego H. R. and Gonzáles S. G., 2007 – Effects of tourism activities on coral reef communities in the Punta Frances national marine park, Cuba, Revista Investigaciones Marinas, 28, 2, 159-175.]Search in Google Scholar
[6. Alcolado P. M., 1998 – Conceptos e índices relacionados con la diversidad, Avicennia, 8, 9, 7-21. (in Spanish)]Search in Google Scholar
[7. Alcolado P. M. and Durán A., 2011 – Sistema de escalas para la clasificación y puntaje de condición del bentos e ictiofauna de arrecifes coralinos de Cuba y del Gran Caribe, Serie Oceanológica, 8, 25-29. (in Spanish)]Search in Google Scholar
[8. Aviles-Torres S., Schmitter-Soto J. J. and Barrientos-Medina R. C., 2001 – Patrones espaciales de la riqueza de peces en lagunas costeras del sur de Quintana Roo, México, Hidrobiológica, 11, 2, 141-148. (in Spanish)]Search in Google Scholar
[9. Ayala-Pérez L. A., Terán-Gonzáles G. J., Flores-Hernández D., Rams-Miranda J. and Sosa- López A., 2012 ‒ Spatial and temporal variability of fish community abundance and diversity off the coast of Campeche, Mexico, Latin American Journal of Aquatic Research, 40, 1, 63-78.]Search in Google Scholar
[10. Badii M. H. and Landeros J., 2007 – Invasión de especies o el tercer jinete de Apocalipsis ambiental, Una amenaza a sustentabilidad Daena, 2, 1, 39-53, www.daenajournal.org. (in Spanish)]Search in Google Scholar
[11. Bellwood D. R. and Hughes T. P., 2001 – Regional-scale assembly rules and biodiversity of coral reefs, Science, 292, 1532-1534.10.1126/science.105863511375488]Search in Google Scholar
[12. Begon M., Townsend C. R. and Harper J. L., 2006 – The influence of population interactions on community structure, 550-577, in Ecology from individuals to ecosystems, Cuarta Edición, Blackwell, Publishing Ltd., 738.]Search in Google Scholar
[13. Baisre J. A., 2018 ‒ An overview of Cuban commercial marine fisheries: the last 80 years, Bulletin Marine Sciences, 94, 2, 359-375, https://doi.org/10.5343/bms.2017.1015.10.5343/bms.2017.1015]Search in Google Scholar
[14. Blaber S. J. M., 1985 – The ecology of fishes of estuaries and lagoons of the Indopacifíc with particular referente to Southeast Africa, Chapter 12, 247-266, in Fish community ecology in estuaries and coastal lagoons, towards an ecosystem integration, Yaiiez-Arancibia A. (ed.), UNAM, Mexico, 654.]Search in Google Scholar
[15. Bellwood D. R., Hughes T. P. and Nyström M., 2004 – Confronting the coral reef crisis, Nature, 429, 6994, 827-833.10.1038/nature0269115215854]Search in Google Scholar
[16. Brock V. E., 1954 – A preliminary report on a method of estimating reef fish’s populations, Journal Wildlife Management, 18, 3, 297-308.10.2307/3797016]Search in Google Scholar
[17. Brower J., Zar J. and von Ende C. N., 1997 – Field and laboratory methods for general ecology, McGraw-Hill, Boston, ISBN-13: 978-0697243584, 288.]Search in Google Scholar
[18. Brown J. H. and Gibson A. C., 1983 – Biogeography, St. Louis, Mosby Company, ISBN 0-8016-0824-4.]Search in Google Scholar
[19. Buddemeier R. W., Kleypas J. A. and Aronson R. B., 2004 – Coral reefs and global climate change: potential contributions of climate change to stresses on coral reef ecosystems, Pew Centre for Global Climate Change, www.pewclimate.org, 44.]Search in Google Scholar
[20. Busutil L., Reynaldo-de la Cruz. E., García-Férnandez F., González-Sánchez P. M., Rodríguez-Machado S. and Vega-Torres. A., 2015 ‒ Evaluación del estado de conservación de los sitios de buceo comtemplativo en el sector costero turístico de Holguín, Cuba, Servicio científico Técnico, CISAT-CITMA, 86. (in Spanish)]Search in Google Scholar
[21. Caballero H., Chevalier P. P., Varona G., Cárdenas A. L., Pastor L., Pérez-Hernández A. and García Y., 2006 – Componentes más comunes de la fauna del arrecife de coral de la costa oriental de Bahía de Cochinos, Cuba, corales, esponjas, gorgonaceos y peces, Revista de Investigaciones Marinas, 25, 1, 37-44. (in Spanish)10.15359/revmar.1.5]Search in Google Scholar
[22. Campos C. A., 2012 – Efecto de la invasión del Pez León (Pterois volitans) sobre los patrones de coexistencias en las comunidades de peces marinos, Diploma Thesis, Universidad de Oriente, Santiago de Cuba, 77. (in Spanish)]Search in Google Scholar
[23. Capote R. P., Mitrani-Arenal I. and Suárez A. G., 2012 – Conservación de la biodiversidad cubana y cambio climático en el archipiélago cubano, Anales de la Academia de Ciencias de Cuba, 1, 1-25. (in Spanish)]Search in Google Scholar
[24. Chevalier P. and Cárdenas A. C., 2006 – Estudio diagnóstico del arrecife coralino del Rincón de Guanabo, Ciudad de La Habana, Cuba, 2, Peces, Revista de Investigaciones Marinas, 27, 2, 121—132. (in Spanish)]Search in Google Scholar
[25. Clarke K. R., 1993 – Non-parametric multivariate analysis of changes in community structure, Australian Journal of Ecology, 18, 117-143.10.1111/j.1442-9993.1993.tb00438.x]Search in Google Scholar
[26. Claro R., 2006 – La biodiversidad marina de Cuba, Instituto de Oceanología, 256.]Search in Google Scholar
[27. Claro R. and García-Arteaga J. P., 1994 – Estructura de las comunidades de peces en los arrecifes del grupo insular Sabana-Camagüey, Cuba, Avicennia, 2, 83-107. (in Spanish)]Search in Google Scholar
[28. Claro R., Sadovy-de Micheson Y., Lindeman K. C. and García-Cagide A. R., 2009 – Historical analysis of Cuban commercial fishing effort and the effects of management interventions on important reef fishes from 1960–2005, Fish Research, 99, 7-16, https://doi.org/10.1016/j.fihres.2009.04.004.]Search in Google Scholar
[29. Claro R. and García-Arteaga P., 2001 – La ictiofauna de los fondos blandos del archipiélago, Sabana-Camagüey, Cuba, Revista de Investigaciones Marinas, 22, 2, 117-127. (in Spanish)]Search in Google Scholar
[30. Cobián R. D. and Chevalier M. P., 2009 – Evaluación de las asociaciones de peces de los arrecifes coralinos del centro internacional de buceo maría la gorda, parque nacional Guanahacabibes, Cuba, Revista Ciencias Marinas y Costeras, 1, 6, 111-125, DOI: 10.15359/revmar.1.6. (in Spanish)10.15359/revmar.1.6]Search in Google Scholar
[31. Connell J. H., 1983 – On the prevalence and relative importance of interspecific competition: evidence from field experiments, American Naturalist, 122, 661-696.10.1086/284165]Search in Google Scholar
[32. Del Monte-Luna P. and Lluch-Belda D., 2016 – Approaching the potential of world marine fisheries, Transylvanian Review of Systematical and Ecological Research, 18.1, The Wetlands Diversity, 45-56, DOI: 10.1515/trser-2015-0079.10.1515/trser-2015-0079]Search in Google Scholar
[33. De la Guardia González-Díaz P., Valdivia A. and González-Sansón G., 2005 ‒ Características generales de los arrecifes coralinos en la zona de buceo de Cayo Levisa, Archipiélago de los Colorados, Cuba, Revista de Investigaciones Marinas, 26, 1, 37-44. (in Spanish)]Search in Google Scholar
[34. Duran A., Shantz A. A., Burkepile D. E., Collado-Vides L., Ferrer V. M., Palma L., Ramos A. and González-Díaz P., 2018 – Fishing, pollution, climate change, and the longterm decline of coral reefs of Havana, Cuba, Bulletin Marine Sciences, 94, 2, 213-228, https://doi.org/10.5343/bms.2017.106110.5343/bms.2017.1061]Search in Google Scholar
[35. Esslemont G., 1999 – Heavy metals in corals from Heron Island and Darwin Harbour, Australia, Marine Pollution Bulletin, 38, 1051-1054.10.1016/S0025-326X(99)00183-6]Search in Google Scholar
[36. Feinsinger P., (ed.) 2003 – El diseño de estudios de campo para la conservación de la biodiversidad, FAN, Santa Cruz Bolivia, 242. (in Spanish)]Search in Google Scholar
[37. Fischer A. G., 1960 – Latitudinal variation in organic diversity, Evolution, 14, 64-81.10.1111/j.1558-5646.1960.tb03057.x]Search in Google Scholar
[38. Fischer A. G., 1961 – Latitudinal variation in organic diversity, America Sciences, 49, 50-74.]Search in Google Scholar
[39. Forman R. T. and Gordon M. (eds), 1986 – Landscape ecology, John Wiley and Sons, New York, 1-169.]Search in Google Scholar
[40. Froese R., 1998 ‒ Length-weight relationships for 18 less-studied fish species, Journal Application Ichthyology, 14, 117-118.10.1111/j.1439-0426.1998.tb00626.x]Search in Google Scholar
[41. Gaston K. J. (ed.), 1996 – Species richness: measure and measurement, in Biodiversity, a biology of numbers and difference, Blackwell Science, Cambridge, 77-113.]Search in Google Scholar
[42. González S. G. and Aguilar C., 2000 – Influencia de la contaminación de la Bahía de La Habana (Cuba) sobre las asociaciones de peces costeros, 2, Análisis multidimensional, Revista de Investigaciones Marinas, 21, 1-3, 60-70. (in Spanish)]Search in Google Scholar
[43. González-Sansón G. and Betancourt C. A., 2003 – Variaciones espaciales y temporales en la abundancia de las especies dominantes de peces de arrecife de coral en la costa de ciudad de La Habana, Cuba, Revista de Investigaciones Marinas, 24, 2, 99-110. (in Spanish)]Search in Google Scholar
[44. Gotelli N. J. and Ellison A. M., 2004 – A primer of ecological statistics, Sunderland: Sinauer Associates, 102.]Search in Google Scholar
[45. Graham N. A. J., Jennings S., MacNeil A. A., Mouillot D. and Wilson S. K., 2015 – Predicting climate-driven regime shifts versus rebound potential in coral reefs, Research Letter Naturalist, 518, 94-97, https://doi.org/10.1038/nature14140.10.1038/nature1414025607371]Search in Google Scholar
[46. Gutiérrez F., 2006 – Estado de conocimiento de especies invasoras, Propuesta de lineamientos para el control de los impactos, Bogotá: Instituto de Investigación de Recursos Biológicos Alexander von Humboldt, 576. (in Spanish)]Search in Google Scholar
[47. INSMET, 2020 – Pronóstico mensual de totales de precipitación y temperaturas medias extremas del archipiélago de cuba para septiembre de 2020, Copyright © 1997-2020, INSMET ® Todos los derechos reservados, http://www.insmet.cu. (in Spanish)]Search in Google Scholar
[48. Jones L., Warner G., Linton D., Alcolado P., Claro-Madrua R., Clerveaux W., Estrada R., Fisher T., Lockhart K. and Pardee M., 2004 ‒ Status of coral reefs in the Northern Caribbean and Western Atlantic node of the GCRMN, in Status of coral reefs of the world, Wilkinson C. R. (ed.), Townsville, Austrailia, Global Coral Reef Monitoring Network and Australian Institute of Marine Science, 451-472.]Search in Google Scholar
[49. Halffter G., Soberon J., Koleff P. and Melic A., 2005 – Sobre diversidad biológica: el significado de las diversidades alfa, beta y gamma, Guadalajara-México, m3m-Monografía 3er Milenio, 4, 1-242. (in Spanish)]Search in Google Scholar
[50. Hammer Ø., Harper D. A. T. and Ryan P. D., 2001 – PAST: Paleontological Statistics Software Package for Education and Data Analysis, Palaeontologia Electronica, 4, 1-9.]Search in Google Scholar
[51. Harborne R. A., Rogers A., Yves-Marie B., Mumby P. J., 2017 – Multiple stressors and the functioning of coral reefs, Annual Review of Marine Science, 9, 1, 445-468.10.1146/annurev-marine-010816-06055127575738]Search in Google Scholar
[52. Horn H. S., 1966 – Measurement of overlap in comparative ecological studies, American Naturalist, 100, 419-424.10.1086/282436]Search in Google Scholar
[53. Hughes T. P., Baird A. H., Bellwood D. R., Card M., Connolly S. R., Folke, C. and Lough J. M., 2003 – Climate change, human impacts, and the resilience of coral reefs, Science, 301, 5635, 929-933, DOI: 10.1126/science.1085046.10.1126/science.108504612920289]Search in Google Scholar
[54. Humann P. and Deloach N., 2002 – Reef fish identification (Florida-Caribbean-Bahamas), 3rd edition, New World Publications, 259.]Search in Google Scholar
[55. Huston M., 1979 – A general hypothesis of species diversity, American Naturalist, 113, 1, 81-101.10.1086/283366]Search in Google Scholar
[56. Kikkawa J., 1986 – Complexity, diversity and stability, 41-62, in Community Ecology Pattern and Process, Kikkawa J. and Anderson D. J. (eds), Blackwell Scientific Publications, Mass.]Search in Google Scholar
[57. Krebs C. J., 1996 – Ecological methodology, Harper Collines Publishers, New York, N.Y, 654.]Search in Google Scholar
[58. La O. J. A., Salinas E. and Licea J. E., 2012 – Aplicación del diagnóstico geoecológico del paisaje en la gestión del turismo litoral: Caso Destino Turístico Litoral Norte de Holguín, Cuba, Investigaciones Turísticas, 3, 1-18. (in Spanish)10.14198/INTURI2012.3.01]Search in Google Scholar
[59. Landen R., 1996 – Statistics and partitioning of species diversity, and similarity among multiple communities, Oikos, 76, 1, 5-13.10.2307/3545743]Search in Google Scholar
[60. Llorente B. J. and Morrone J. J., 2001 – Introducción a la biogeografía en Latinoamérica: teorías, concepto, métodos y aplicaciones, Facultad de Ciencia, U.N.A.M. México D.F, 137. (in Spanish)]Search in Google Scholar
[61. Maclaurin J. and Sterelny K., 2008 – What is biodiversity? The University of Chicago Press, Chicago, 224.10.7208/chicago/9780226500829.001.0001]Search in Google Scholar
[62. Magurran A. E., 1988 – Ecological diversity and its measurement, Princeton University Press, New Jersey, 179.10.1007/978-94-015-7358-0]Search in Google Scholar
[63. Magurran A. E., 2004 – Measuring biological diversity, Nueva York: John Wiley and Sons 306, McField M. and Richards K. P., 2007 ‒ Healthy reefs for healthy people: a guide to indicators of reef health and social well-being in the Mesoamerican reef region, with contributions from Gorrez M. and McPherson M., 208.]Search in Google Scholar
[64. Martínez-Iglesias J. C. and Serpa A., 1997 – Informe del diagnóstico ecológico de los principales ecosistemas marinos en Punta Francés, Isla de la Juventud, informe técnico, Instituto de Oceanología, 16.]Search in Google Scholar
[65. McField M. and Richards K. P., 2007 ‒ Healthy reefs for healthy people: a guide to indicators of reef health and social well-being in the Mesoamerican reef region, with contributions from Gorrez M. and McPherson M., 208.]Search in Google Scholar
[66. Moreno C. E., 2000 – Diversidad de quirópteros en un paisaje del centro de Veracruz, México, Thesis presented as an option to the scientific degree of Doctor in Biological Sciences, Instituto de Ecología, Xalapa A. C., Ver., México, 150.]Search in Google Scholar
[67. Moreno C. E., 2001 – Métodos para medir la biodiversidad, M. and T.-Manuales y Tesis SEA, 1, Zaragoza, 84.]Search in Google Scholar
[68. Moreno E. C., Barragán F., Pineda E. and Pavón P. N., 2011 ‒ Reanálisis de la diversidad alfa: alternativas para interpretar y comparar información sobre comunidades ecológicas, Revista Mexicana de Biodiversidad, 82, 1249-1261. (in Spanish)10.22201/ib.20078706e.2011.4.745]Search in Google Scholar
[69. Morisita M., 1959 – Measuring interspecific association and similarity between communities, University Series Edition Biology, 3, 65-80.]Search in Google Scholar
[70. Mumby P. J., Flower J., Chollett I., Box S. J., Bozec Y. M., Fitzsimmons C., Forster J., Gill D., Griffith-Mumby J. and Oxenford H. A., 2014 – Towards reefs resilience and sustainable livelihoods: a handbook for Caribbean coral reefs managers, University of Exeter, Exeter, 172.]Search in Google Scholar
[71. Núñez-Lara E., Arias-onzález J. E. and Legendre P., 2005 – Spatial patterns of Yucatan reef fish communities: Testing models using a multi–scale survey design, Journal of Exploratory Marine Biology and Ecolology, 324, 157-169.10.1016/j.jembe.2005.04.011]Search in Google Scholar
[72. Padilla C., 2000 – Evaluación del potencial de uso sustentable del coral negro en Isla Cozumel y parte sur de Quintana Roo, México: reporte técnico, Puerto Morelos, inp/fmcn, 70. (in Spanish)]Search in Google Scholar
[73. Paine R. T., 1966 – Food web complexity and species diversity, America Naturalist, 100, 65-75.10.1086/282400]Search in Google Scholar
[74. Pianka E. R., 1966 ‒ Latitudinal gradients in species diversity: a review of concepts, America Naturalist, 100, 33-46.10.1086/282398]Search in Google Scholar
[75. Pikitch E., Santora C., Babcock E., Bakun A., Bonfil R., Conover D., Dayton P., Doukakis P., Fluharty D. and Heneman B., 2004 ‒ Ecosystem-based fishery management, Science, 305, 346-347.10.1126/science.109822215256658]Search in Google Scholar
[76. Puga R., Valle S., Kritzer J. P., Delgado G., de León M. E., Giménez E., Ramos I., Moreno O. and Karr K. A., 2018 – Vulnerability of nearshore tropical fifih in Cuba: implications for scientifi and management planning, Bulletin Marine Sciences, 94, 2, 377-392, https://doi.org/10.5343/bms.2016.1127.10.5343/bms.2016.1127]Search in Google Scholar
[77. Reynaldo E., Vega A., Fernández A., Cruz J., Córdova E. and Cruz P., 2018 ‒ Distribución y abundancia del pez león Pterois volitans en la zona costera de uso turístico de Holguín, Cuba, Novitates Caribaea, 12, 63-73. (in Spanish)10.33800/nc.v0i12.85]Search in Google Scholar
[78. Reynaldo E., Vega T. A., Vega C. M. E., Fernández V. A., Cruz R.J., Córdova G. E. and Cruz R. P., 2019 – Preferencias tróficas de Pterois volitans (Scorpaenidae) en el área costera de Holguín, Cuba, Novitates Caribaea, 13, 1-12. (in Spanish)10.33800/nc.v0i13.188]Search in Google Scholar
[79. Ricklefs R. E., 1990 – Ecology, 3rd edition, New York: W. H. Freeman, 178.]Search in Google Scholar
[80. Rodríguez R. J., Abitia C. L. A., Galván M. F. and Chávez R. H., 1994 ‒ Composición, abundancia y riqueza especifica de la ictiofauna de Bahía concepción, Baja California sur, México, Ciencias Marinas, 20, 3, 321-350.10.7773/cm.v20i3.971]Search in Google Scholar
[81. Rodríguez-Zaragoza F. A., Cupul-Magaña A. L., Galván-Villa C. M., Ríos-Jara E., Ortiz M., Robles-Jarero, E. G. and Arias-González J. E., 2011 – Additive partitioning of reef fish diversity variation, a promising marine biodiversity management tool, Biodiversity and Conservation, 20, 8, 1655-1675, DOI: 10.1007/s10531-011-0053-9.10.1007/s10531-011-0053-9]Search in Google Scholar
[82. Rouphael A. B. and Inglis G. J., 2000 – Take only photographs and leave only footprints? An experimental study of the impacts of underwater photographers on coral reef dive sites, Biological Conservation, 100, 281-287.10.1016/S0006-3207(01)00032-5]Search in Google Scholar
[83. Santos T. and Tellería J. L. 2006 – Pérdida y fragmentación del hábitat: efecto sobre la conservación de las especies, Ecosistemas, 15, 2, 3-12. (in Spanish)]Search in Google Scholar
[84. Steneck R. S., Arnold S. N. and Mumby P. J., 2014 – Experiment mimics fihing on parrotfih: insights on coral reef recovery and alternative attractors, Marine Ecology Progress Series, 506, 115-127, https://doi.org/10.3354/meps10764.10.3354/meps10764]Search in Google Scholar
[85. Sonco S. R., 2013 – Estudio de la diversidad alfa y beta en tres localidades de un bosque montano en la región de Madidi, La Paz Bolivia, Tesis de grado, Facultad y Carrera de Ingeniera Agrónoma, Universidad Mayor de San Andrés, 1-154. (in Spanish)]Search in Google Scholar
[86. Southward A. J. and Boalch G. T., 1994 – The effect of changing climate on marine life: past events and future predictions, Exeter Maritime Studies, 9, 101-143. (in Spanish)]Search in Google Scholar
[87. Southward A. J., Hawkins S. J. and Burrows M. T., 1995 ‒ Seventy years observations in distribution and abundance of zooplankton and intertidal organisms in the western English Channel in relation to rising sea temperature, Journal of Thermal Biology, 20, 127-155.10.1016/0306-4565(94)00043-I]Search in Google Scholar
[88. Stehli F. G., Douglas R. G. and Nowell N. D., 1969 – Generation and maintenance of gradients in taxonomic diversity, Science, 164, 947-949.10.1126/science.164.3882.94717775598]Search in Google Scholar
[89. Stevens G. C., 1989 – The latitudinal gradient in geographical range: how so many species coexist in the tropics, American Naturalist, 133, 240-430.10.1086/284913]Search in Google Scholar
[90. Vega A., Zayas I., Zayas C., Fernández A. and Peña C., 2004 – Sea shell of Yuraguanal beach, Holguin province, Cuba, Of Sea and Shore, 26, 1, 4-9.]Search in Google Scholar
[91. Valdivia A., Cox C. E. and Bruno J. F., 2017 – Predatory fish depletion and recovery potential on Caribbean reefs, Sciences Advanced, 3, 160, 1303, https://doi.org/10.1126/sciadv.1601303.10.1126/sciadv.1601303533215328275730]Search in Google Scholar
[92. Williams I. D. and Polunin N. V. C., 2001 – Large scale associations between macro algal cover and grazer biomass on mid-depth reefs in the Caribbean, Coral Reefs, 19, 358-366.10.1007/s003380000121]Search in Google Scholar
[93. Whittaker R. H., 1972 – Evolution and measurement of species diversity, Taxon, 21, 2/3, 213-251.10.2307/1218190]Search in Google Scholar
[94. Zakai D. and Chadwick-Furman N. E., 2002 – Impacts of intensive recreational diving on reef corals at Eilat, northern Red Sea, Biology Conservation, 105, 179-187.10.1016/S0006-3207(01)00181-1]Search in Google Scholar