Human impacts on the species?area relationship in reef fish assemblages

We studied species-area and diversity-dominance patterns in fish communities of a mosaic of urban ponds (Rome, Italy). We detected 10 fish species (all introduced) in 40 isolated ponds (12.9% of the total; n = 311). The log-transformed species-area relationship (logS = 0.04 logA + 0.16) was significant. Assuming the lack of mechanisms of natural immigration between totally isolated ponds, the number of fish species in this mosaic of ponds may depend exclusively on progressive extinctions and on random and arbitrary events of introduction (acting as human-mediated immigration), these latter explaining the apparently low taxon-related isolation indicated by a low z value (= 0.04). We observed a significantly lower number of species in the smallest ponds and a further threshold under 1 ha in size: these values could represent an interesting threshold for pond management. The diversity-dominance approach evidenced pond size effect acting as a factor of stress on these assemblages.

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Climate change, species–area curves and the extinction crisis

Philosophical Transactions of the Royal Society B Biological Sciences ◽

10.1098/rstb.2005.1712 ◽

2005 ◽

Vol 361 (1465) ◽

pp. 163-171 ◽

Cited By ~ 64

Author(s):

Owen T Lewis

Keyword(s):

Climate Change ◽

Human Impacts ◽

Scientific Basis ◽

Habitat Destruction ◽

Species Loss ◽

Species Area ◽

Species Area Relationship ◽

The Tropics ◽

Ecological Pattern ◽

Made In

An article published in the journal Nature in January 2004—in which an international team of biologists predicted that climate change would, by 2050, doom 15–37% of the earth's species to extinction—attracted unprecedented, worldwide media attention. The predictions conflict with the conventional wisdom that habitat change and modification are the most important causes of current and future extinctions. The new extinction projections come from applying a well-known ecological pattern, the species–area relationship (SAR), to data on the current distributions and climatic requirements of 1103 species. Here, I examine the scientific basis to the claims made in the Nature article. I first highlight the potential and pitfalls of using the SAR to predict extinctions in general. I then consider the additional complications that arise when applying SAR methods specifically to climate change. I assess the extent to which these issues call into question predictions of extinctions from climate change relative to other human impacts, and highlight a danger that conservation resources will be directed away from attempts to slow and mitigate the continuing effects of habitat destruction and degradation, particularly in the tropics. I suggest that the most useful contributions of ecologists over the coming decades will be in partitioning likely extinctions among interacting causes and identifying the practical means to slow the rate of species loss.

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Combination of trophic group habitat preferences determines coral reef fish assemblages

Marine Ecology Progress Series ◽

10.3354/meps12378 ◽

2018 ◽

Vol 586 ◽

pp. 141-154 ◽

Cited By ~ 1

Author(s):

S Suzuki ◽

T Kawai ◽

T Sakamaki

Keyword(s):

Coral Reef ◽

Reef Fish ◽

Coral Reef Fish ◽

Fish Assemblages ◽

Habitat Preferences ◽

Trophic Group

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Spatial assemblage structure of shallow-water reef fish in Southwest Australia

Marine Ecology Progress Series ◽

10.3354/meps13445 ◽

2020 ◽

Vol 649 ◽

pp. 125-140

Author(s):

DS Goldsworthy ◽

BJ Saunders ◽

JRC Parker ◽

ES Harvey

Keyword(s):

Shallow Water ◽

Reef Fish ◽

Marine Environment ◽

Fish Assemblages ◽

Canopy Cover ◽

Reef Fishes ◽

Reef Fish Assemblage ◽

Reef Type ◽

Present Distribution ◽

Southwest Australia

Bioregional categorisation of the Australian marine environment is essential to conserve and manage entire ecosystems, including the biota and associated habitats. It is important that these regions are optimally positioned to effectively plan for the protection of distinct assemblages. Recent climatic variation and changes to the marine environment in Southwest Australia (SWA) have resulted in shifts in species ranges and changes to the composition of marine assemblages. The goal of this study was to determine if the current bioregionalisation of SWA accurately represents the present distribution of shallow-water reef fishes across 2000 km of its subtropical and temperate coastline. Data was collected in 2015 using diver-operated underwater stereo-video surveys from 7 regions between Port Gregory (north of Geraldton) to the east of Esperance. This study indicated that (1) the shallow-water reef fish of SWA formed 4 distinct assemblages along the coast: one Midwestern, one Central and 2 Southern Assemblages; (2) differences between these fish assemblages were primarily driven by sea surface temperature, Ecklonia radiata cover, non-E. radiata (canopy) cover, understorey algae cover, reef type and reef height; and (3) each of the 4 assemblages were characterised by a high number of short-range Australian and Western Australian endemic species. The findings from this study suggest that 4, rather than the existing 3 bioregions would more effectively capture the shallow-water reef fish assemblage patterns, with boundaries having shifted southwards likely associated with ocean warming.

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