Indicators
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  • Biomass of species interest (particularly harvested, invading, keystone or vulnerable species)

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IndicatorAttributePurposeIf restricted to taxa, list which onesEcosystem applicabilityIdentified capabilityBiological classification levelResponse variableDriversRobustness
Biomass of species of interestcommunity Community structure; trophic Trophic structure, population Population structure; predatorPredator-prey balancefisheriesFisheries Should be suitable for all ecosystemsD or ADemonstrableEcosystem; communityCommunity; populationtrophodynamictrophodynamicPopulation

Size-baaed, Trophodynamic, Environmental

TrophodynamicPotentially high

Examples of how the indicators is used for ecosystem management and ecosystem status and trends

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In traditional single species management measures of biomass (frequently trends over time in biomass / pristine biomass) have been used to judge the health of the stock, and thus the fishery. Thus, measures in biomass can be informative at a population level, but by extending the number of species tracked or choosing species carefully (e.g. using keystone or vulnerable species) more system-level information maybe encapsulated in these simple measures.


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Figure 5.3: The model output of biomass (wet weight) when all fish components are fished after 39 years of simulation. It shows the response of the coral ecosystem to overfishing, in particular, the increased biomass of sea urchins, which are keystone species in this system (after McClanahan 1995).

need to add figure 5.3 

Abundance of keystone species

Keystone species are those that play a pivotal role in the ecology of a community. There are some examples in the marine environment that could be used as indicator species (such as some shark species; sea urchins; some seagrass species), particularly if their densities are monitored. 

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Substantial changes in the abundance of keystone species can have immense and widespread impacts on marine ecosystems. As a result, measuring changes in abundance of keystone species can be an effective indicator for some effects of fishing. For example, the overfishing of urchin predators (e.g. rock lobster, sea otter and grey nurse sharks) has been shown to lead to urchin dominance and subsequent overgrazing of algal communities in temperate habitats and the erosion of coral reefs in tropical habitats (McClanahan and Shafir 1990, McClanahan 1992, Goni 1998, Estes et al. 1998, Tegner and Dayton 2000).

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Biomass of prey species

The biomass of certain groups can also be used to consider aspects of the system such as community composition. Predator-prey responses to fishing impacts can provide important and potentially robust indicators of biomass changes in an ecosystem. This is true not only of field data, but also of the output of simulation models. There have been numerous simulation modelling studies recently investigating the impacts of removing key predators from an ecosystem (e.g. for chondrichthyans, Stevens et al. 2000), the over-harvesting of prey species on seabird species (Furness 1999), and the over-harvesting of prey species in Port Phillip Bay, Victoria (Fulton and Smith in press). An example of the time-series output of these kinds of models is given in Figure 5.4.

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Figure 5.4: ECOSIM simulation of the functional response to an aggressive sand lance fishery showing biomass declines in seabirds (which prey on sand lance) and other species (after Okey and Pauly 1999)need to add figure 5.4

Attribute

Community structure; trophic structure; population structure; predator-prey balance

Purpose

fisheriesFisheries

Taxa

This indicator is not restricted to any particular species but there are possible taxa that could be used as an indicator species include some shark species; , sea urchins; , and some seagrass species.

Data required

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The following is from Fulton et al 2004a -

 

Should be suitable for all ecosystems. For certain species of interest the method may be more restricted. For example, the use of the biomass of keystone species will only be applicable in ecosystems where there is a keystone species that determines system state. Unfortunately, the existence of such a species may not be apparent before large-scale changes in an ecosystem have already occurred.

Identified capability

Is there any additional information that would be of interest in regards to the identified capability?

Otherwise can leave this section blank and just fill in the table instead.

Biological classification level

Is there any additional information that would be of interest in regards to the biological classification?

Otherwise can leave this section blank and just fill in the table instead.

Response variable

Is there any additional information that would be of interest in regards to the response variable?

Otherwise can leave this section blank and just fill in the table instead.

Drivers

Is there any additional information that would be of interest in regards to ecological drivers?

If not can leave this section blank and just fill in the table instead.

Robustness

The following is from Fulton et al 2004a -

Potentially high: Measures of biomass may be simple, but they can be immensely informative even if only used in a qualitative sense to track system state. This is particularly true, if a suite of species is followed as this allows for a summary of the entire state of the system and may allow for the identification of the cause of any changes in system state (Fulton and Smith in press). One draw back to many indicators reviewed in this report is the requirement that data must be collected on all, or the majority of species in a system. One way to avoid this problem is to only measure indicator assemblages, on the proviso that these species really do summarise system state, as fishing effects are largely confined to these groups. The major limitation to using measures of biomass as an indicator is the collection of reliable data either through time or between locations so that reliable baselines can be established and any trends in biomass can be identified. Changes in biomass are only informative so long as the data collected is representative of the true state of the system. Thus, fisheries dependent data is not always reliable (due to changes in effort and market driven targeting). Fisheries independent and ecological data will be required. Data from reference areas would also be useful, as it would highlight any widespread decreases in biomass that may result from large-scale environmental cycles, displacement by invading species, pathogens and anthropogenic activities other than fishing.

 

Keystone species: potentially medium to high (especially for fished coral reef systems and macrophyte dominated temperate systems), but the limitations are that other environmental or trophic interactions may produce the same effects and the identity and impact of keystone species may not be known until the system is heavily impacted.

 

Simulation modelling: Medium to high, if used in a qualitative sense of predicting likely (and potentially unforeseen) effects of fishing. Major limitations are concerned with model specification and the quality of the data used to tune the model.

 

Current status and trends

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