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Marine Biodiversity

, Volume 49, Issue 1, pp 247–262 | Cite as

Consistent variability in beta-diversity patterns contrasts with changes in alpha-diversity along an onshore to offshore environmental gradient: the case of Red Sea soft-bottom macrobenthos

  • Zahra AlsaffarEmail author
  • João Cúrdia
  • Angel Borja
  • Xabier Irigoien
  • Susana Carvalho
Original Paper

Abstract

Patterns of variability in diversity (alpha and beta), abundance, and community structure of soft-bottom macrobenthic assemblages were investigated across an inshore/offshore environmental gradient in the central Red Sea. A total of three distinct soft-substrate biotopes were identified through multivariate techniques: seagrass meadows, nearshore, and offshore. While the seagrass biotope was associated with higher organic matter content, the two coastal biotopes presented higher redox potential in the sediments and dissolved oxygen in the water. Depth and medium sand increased toward the offshore, while the percentage of fine particles was a determinant of nearshore communities. Regardless of the prevailing environmental conditions, the three biotopes were characterized by high numbers of exclusive taxa, most of which were singletons. Changes in species richness were not related to depth or organic matter, peaking at intermediate depths (nearshore). However, the number of taxa increased exponentially with abundance. On the other hand, density decreased logarithmically with depth and organic matter in sediments, probably linked to a reduced availability of food. One of the most conspicuous features of the macrobenthic assemblages inhabiting soft substrates in the central oligotrophic Red Sea is the low level of dominance resulting from a high species richness: abundance ratio. Despite the differences observed for alpha-diversity across the three biotopes, beta-diversity patterns were rather consistent. These findings suggest that mechanisms driving biodiversity are similar across the depth gradient. The partitioning of beta-diversity also show that assemblages are mainly driven by the substitution of species (turnover or replacement), most likely as a result of environmental filtering. The heterogeneity of the seafloor in shallow waters of the Red Sea promoted by the co-existence of coral reefs inter-spaced by sedimentary habitats may increase the regional pool of colonizers and potentiate the stochasticity of the distribution patterns.

Keywords

Macrobenthic assemblages Biotopes Seagrass Coastal area Spatial distribution Tropics 

Notes

Acknowledgements

The authors would like to thank Richard Payumo, Miguel Viegas, and Holger Anlauf for their help in the field and in the laboratory. Also, the authors would like to thank the skippers and staff of the Costal and Marine Resources Core Lab for their invaluable support in fieldwork activities. We are also grateful to Dr. Joanne Ellis and Dr. John Pearman for proofreading this manuscript and for their invaluable comments on an earlier version that helped to improve it. Five anonymous reviewers and the Editor provided constructive comments to the submitted manuscript. This research was supported by baseline funding provided by KAUST to Prof. Xabier Irigoien. S. Carvalho and J. Cúrdia are funded by the Saudi Aramco-KAUST center for Marine Environmental Observations.

Supplementary material

12526_2017_791_MOESM1_ESM.xlsx (20 kb)
ESM 1 (XLSX 19 kb)

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Copyright information

© Senckenberg Gesellschaft für Naturforschung and Springer-Verlag GmbH Germany 2017

Authors and Affiliations

  1. 1.King Abdullah University of Science and Technology (KAUST), Red Sea Research Center (RSRC)ThuwalSaudi Arabia
  2. 2.AZTI, Marine Research DivisionPasaiaSpain
  3. 3.IKERBASQUEBasque Foundation for ScienceBilbaoSpain

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