Diversity and composition of algal epiphytes on the Mediterranean seagrass Cymodocea nodosa: a scale-based study-Reference-Cited by-同舟云学术

Diversity and composition of algal epiphytes on the Mediterranean seagrass Cymodocea nodosa: a scale-based study

Published:2021-03-15 Issue:2 Volume:64 Page:101-118
ISSN:1437-4323
Container-title:Botanica Marina
language:en
Short-container-title:

Author:

Tsioli Soultana¹²³,Papathanasiou Vasillis¹,Rizouli Anastasia⁴,Kosmidou Maria¹,Katsaros Christos²,Papastergiadou Eva³,Küpper Frithjof C.⁴⁵,Orfanidis Sotiris¹

Affiliation:

1. Benthic Ecology & Technology Laboratory , Fisheries Research Institute (ELGO-DIMITRA) , 64007 , Nea Peramos , Kavala , Greece

2. Department of Biology , Section of Botany, National and Kapodistrian University of Athens , Panepistimiopolis , Athens 157 84 , Greece

3. Department of Biology , University of Patras , Rio , Greece

4. School of Biological Sciences, Cruickshank Bldg , University of Aberdeen , St. Machar Drive , Aberdeen AB24 3UU , UK

5. Marine Biodiscovery Centre, Department of Chemistry , University of Aberdeen , Aberdeen AB24 3UE , UK

Abstract

Abstract Cymodocea nodosa, a typical marine angiosperm species in the Mediterranean Sea, hosts a range of epiphytic algae. Epiphyte abundance varies at different spatial scales, yet epiphyte diversity and community composition are poorly understood. This study explores the epiphytes on C. nodosa from two reference meadows (Thasos, Vrasidas) and one anthropogenically stressed meadow (Nea Karvali) in the northern Aegean Sea (Kavala Gulf, Greece). A nested destructive sampling design at three spatial scales (metres, hundreds of metres, kilometres) and stereoscopic/microscopic observations were used. Light microscopy revealed a total of 19 taxa of macroalgae populating the leaves of C. nodosa. The most commonly encountered taxa with highest cover (%) were Hydrolithon cruciatum and Feldmannia mitchelliae. DNA sequencing (18S rDNA) confirms the presence of a number of dinoflagellate and red algal epiphytes, and this represents the first application of DNA metabarcoding to study the diversity of seagrass epiphytes. Epiphytic communities studied at species/taxon and functional (Ecological Status Groups) levels separated the reference low-stressed meadows from the degraded one, with the functional approach having higher success. The ecological evaluation index classified the studied meadows into different Ecological Status Classes according to anthropogenic stress.

Publisher

Walter de Gruyter GmbH

Subject

Plant Science,Aquatic Science,Ecology, Evolution, Behavior and Systematics

Link

https://www.degruyter.com/document/doi/10.1515/bot-2020-0057/pdf

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