Seagrass meadows are vital ecosystems in coastal zones worldwide, but are also under global threat. One of the major hurdles restricting the success of seagrass conservation and restoration is our limited understanding of ecological feedback mechanisms. In these ecosystems, multiple, self-reinforcing feedbacks can undermine conservation efforts by masking environmental impacts until the decline is precipitous, or alternatively they can inhibit seagrass recovery in spite of restoration efforts. However, no clear framework yet exists for identifying or dealing with feedbacks to improve the management of seagrass ecosystems. Here we review the causes and consequences of multiple feedbacks between seagrass and biotic and/or abiotic processes. We demonstrate how feedbacks have the potential to impose or reinforce regimes of either seagrass dominance or unvegetated substrate, and how the strength and importance of these feedbacks vary across environmental gradients. Although a myriad of feedbacks have now been identified, the co-occurrence and likely interaction among feedbacks has largely been overlooked to date due to difficulties in analysis and detection. Here we take a fundamental step forward by modelling the interactions among two distinct above- and belowground feedbacks to demonstrate that interacting feedbacks are likely to be important for ecosystem resilience. On this basis, we propose a five-step adaptive management plan to address feedback dynamics for effective conservation and restoration strategies. The management plan provides guidance to aid in the identification and prioritisation of likely feedbacks in different seagrass ecosystems.
Despite the importance of coastal ecosystems for the global carbon budgets, knowledge of their carbon storage capacity and the factors driving variability in storage capacity is still limited. Here we provide an estimate on the magnitude and variability of carbon stocks within a widely distributed marine foundation species throughout its distribution area in temperate Northern Hemisphere. We sampled 54 eelgrass (Zostera marina) meadows, spread across eight ocean margins and 36° of latitude, to determine abiotic and biotic factors influencing organic carbon (Corg) stocks in Zostera marina sediments. The Corg stocks (integrated over 25‐cm depth) showed a large variability and ranged from 318 to 26,523 g C/m2 with an average of 2,721 g C/m2. The projected Corg stocks obtained by extrapolating over the top 1 m of sediment ranged between 23.1 and 351.7 Mg C/ha, which is in line with estimates for other seagrasses and other blue carbon ecosystems. Most of the variation in Corg stocks was explained by five environmental variables (sediment mud content, dry density and degree of sorting, and salinity and water depth), while plant attributes such as biomass and shoot density were less important to Corg stocks. Carbon isotopic signatures indicated that at most sites <50% of the sediment carbon is derived from seagrass, which is lower than reported previously for seagrass meadows. The high spatial carbon storage variability urges caution in extrapolating carbon storage capacity between geographical areas as well as within and between seagrass species.
Seagrass meadows are declining globally at an unprecedented rate, yet these valuable ecosystem service providers remain marginalized within many conservation agendas. In the Indo-Pacific, this is principally because marine conservation priorities do not recognize the economic and ecological value of the goods and services that seagrasses provide. Dependency on coastal marine resources in the Indo-Pacific for daily protein needs is high relative to other regions and has been found in some places to be up to 100%. Habitat loss therefore may have negative consequences for food security in the region. Whether seagrass resources comprise an important contribution to this dependency remains largely untested. Here, we assemble information sources from throughout the Indo-Pacific region that discuss shallow water fisheries, and examine the role of seagrass meadows in supporting production, both directly, and indirectly through process of habitat connectivity (e.g., nursery function and foraging areas). We find information to support the premise that seagrass meadows are important for fisheries production. They are important fishery areas, and they support the productivity and biodiversity of coral reefs. We argue the value of a different paradigm to the current consensus on marine conservation priorities within the Indo-Pacific that places seagrass conservation as a priority.
BackgroundDeclining water quality coupled with the effects of climate change are
rapidly increasing coral diseases on reefs worldwide, although links between
coral diseases and environmental parameters remain poorly understood. This
is the first study to document a correlation between coral disease and water
quality on an inshore reef.Methodology/Principal FindingsThe temporal dynamics of the coral disease atramentous necrosis (AN) was
investigated over two years within inshore populations of Montipora
aequituberculata in the central Great Barrier Reef, in relation
to rainfall, salinity, temperature, water column chlorophyll
a, suspended solids, sedimentation, dissolved organic
carbon, and particulate nitrogen, phosphorus and organic carbon. Overall,
mean AN prevalence was 10-fold greater during summer wet seasons than winter
dry seasons. A 2.5-fold greater mean disease abundance was detected during
the summer of 2009 (44 ± SE 6.7 diseased colonies per 25
m2), when rainfall was 1.6-fold greater than in the summer of
2008. Two water quality parameters explained 67% of the variance in
monthly disease prevalence in a Partial Least Squares regression analysis;
disease abundance was negatively correlated with salinity
(R2 = −0.6) but positively correlated with water
column particulate organic carbon concentration
(R2 = 0.32). Seasonal temperature patterns were also
positively correlated with disease abundance, but explained only a small
portion of the variance.Conclusions/SignificanceThe results suggest that rainfall and associated runoff may facilitate
seasonal disease outbreaks, potentially by reducing host fitness or by
increasing pathogen virulence due to higher availability of nutrients and
organic matter. In the future, rainfall and seawater temperatures are likely
to increase due to climate change which may lead to decreased health of
inshore reefs.
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