Predicting reef fish connectivity from biogeographic patterns and larval dispersal modelling to inform the development of marine reserve networks
Authored by Rene A Abesamis, Brian L Stockwell, Lawrence P C Bernardo, Cesar L Villanoy, Garry R Russ
Date Published: 2016
DOI: 10.1016/j.ecolind.2016.02.032
Sponsors:
Commonwealth Government of Australia
Platforms:
No platforms listed
Model Documentation:
Other Narrative
Mathematical description
Model Code URLs:
Model code not found
Abstract
Developing networks of no-take marine reserves is often hindered by
uncertainty in the extent to which local marine populations are
connected to one another through larval dispersal and recruitment
(connectivity). While patterns of connectivity can be predicted by
larval dispersal models and validated by empirical methods, biogeographic approaches have rarely been used to investigate
connectivity at spatial scales relevant to reserve networks (10's-100's
of km). Here, species assemblage patterns in coral reef fish were used
together with an individual-based model of dispersal of reef fish larvae
to infer patterns of connectivity in a similar to 300 km wide region in
the Philippines that included the Bohol Sea and adjacent bodies of
water. A dominant current flows through the study region, which may
facilitate connectivity among >100 no-take reserves. Connectivity was
first investigated by analysing data on the presence/absence of 216
species of reef fish and habitat variables across 61 sites. Hierarchical
clustering of sites reflecting species assemblage patterns distinguished
a major group of sites in the Bohol Sea (Bray-Curtis similarity >70\%)
from sites situated in adjacent bodies of water (bays, channels between
islands and a local sea). The grouping of sites could be partly
explained by a combination of degree of embayment, \% cover of sand and
\% cover of rubble (Spearman rank correlation, rho(w) = 0.42). The
individual-based model simulated dispersal of reef fish larvae monthly
for three consecutive years in the region. The results of simulations, using a range of pelagic larval durations (15-45 days), were consistent
with the species assemblage patterns. Sites in the model that showed
strongest potential connectivity corresponded to the majority of sites
that comprised the Bohol Sea group suggested by hierarchical clustering.
Most sites in the model that exhibited weak connectivity were groups of
sites which had fish assemblages that were least similar to those in the
Bohol Sea group. Concurrent findings from the two approaches suggest a
strong influence of local oceanography and geography on broad spatial
patterns of connectivity. The predictions can be used as an initial
basis to organise existing reserves to form ecologically meaningful
networks. This study showed that species assemblage patterns could be a
viable supplementary indicator of connectivity if used together with
predictions from a larval dispersal model and if the potential effect of
habitat on the structuring of species assemblages is taken into
consideration. (C) 2016 Elsevier Ltd. All rights reserved.
Tags
Conservation
habitat
Philippines
Recruitment
Community structure
Population connectivity
Fisheries management
Pacific
Coral-reefs
Archipelago