European Ocean Biodiversity Information System

[ report an error in this record ]basket (1): add | show Print this page

one publication added to basket [75232]
A field colonization experiment with meiofauna and seagrass mimics: effect of time, distance and leaf surface area
De Troch, M.; Vandepitte, L.; Raes, M.; Suàrez-Morales, E.; Vincx, M. (2005). A field colonization experiment with meiofauna and seagrass mimics: effect of time, distance and leaf surface area. Mar. Biol. (Berl.) 148(1): 73-86. dx.doi.org/10.1007/s00227-005-0062-x
In: Marine Biology: International Journal on Life in Oceans and Coastal Waters. Springer: Heidelberg; Berlin. ISSN 0025-3162; e-ISSN 1432-1793
Peer reviewed article  

Available in  Authors 
    Vlaams Instituut voor de Zee: Open Marine Archive 72199 [ download pdf ]

Keywords
    Aquatic communities > Benthos > Meiobenthos
    Colonization
    Flora > Weeds > Marine organisms > Seaweeds > Sea grass
    Temporal variations
    Thalassia testudinum K.D.Koenig, 1805 [WoRMS]
    ASW, Mexico, Yucatan, Punta Allen [Marine Regions]
    Marine/Coastal

Authors  Top 
  • De Troch, M.
  • Vandepitte, L.
  • Raes, M.
  • Suàrez-Morales, E.
  • Vincx, M.

Abstract
    From a conservation point of view, it is essential to know how fast an ecosystem can recover after physical disturbance. Meiofauna and especially harpacticoid copepods are abundant in seagrass beds and are therefore useful to study ecosystem recovery after disturbance. In the western Caribbean coast, a fragmented Thalassia testudinum seagrass bed was selected to conduct a colonization field experiment by means of plastic seagrass mimics. Meiofauna colonization, with special emphasis on harpacticoid copepods, was followed in relation to: (1) colonization time (2, 4, 6, 10, 14 and 21 days); (2) distance to source of colonizers (close and far series) and (3) leaf surface area to colonize (small, medium, large). Colonization was recorded after 2 days with average meiofauna densities of 480 ind/100 cm2 (close) and 1350 ind/100 cm2 (far) of leaf surface area, while on average 400 ind/100 cm2 were collected from the natural seagrass plants. In this early phase, the meiofauna diversity was high, with on average 8 taxa. A longer period of colonization (21 days) showed an increased meiofaunal density and diversity (average density: 3220 ind/100 cm2, 13 taxa). Increasing meiofauna colonization with time is probably related to the development of a biofilm making the leaf more attractive for meiofauna. The effect of distance was not so pronounced as that of time. Total absolute densities were highest in the far series (5 m away from natural seagrass patch), mainly because of nematode densities. Meiofauna diversity was lower in the far series than in the close series (at the border of the natural seagrass patch). A larger individual leaf surface area did not affect the overall meiofauna densities but had a significant positive effect on copepod densities. Larger surface areas promoted the presence of epiphytic copepod families such as Tegastidae and Dactylopusiidae. Overall, we found a rapid recovery of meiofauna in fragmented seagrass beds with primary colonizers (both nematodes and benthic opportunistic copepods) originating from the sediment and later colonizers as epiphytic copepods and their nauplii from the local seagrass regeneration pool.

All data in the Integrated Marine Information System (IMIS) is subject to the VLIZ privacy policy Top | Authors