Population ecology of the Sydney rock oyster saccostrea commercialis and the pacific oyster crassostrea gigas in a New South Wales estuary

Krassoi, FR

Population ecology of the Sydney rock oyster saccostrea commercialis and the pacific oyster crassostrea gigas in a New South Wales estuary

Krassoi, FR

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Publication Type:: Thesis
Issue Date:: 2001

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Field	Value	Language
dc.contributor.author	Krassoi, FR
dc.date.accessioned	2010-06-30T05:54:26Z
dc.date.accessioned	2012-12-15T03:53:17Z
dc.date.available	2010-06-30T05:54:26Z
dc.date.available	2012-12-15T03:53:17Z
dc.date.issued	2001
dc.identifier.uri	http://hdl.handle.net/10453/20307
dc.description	University of Technology Sydney. Faculty of Science.	en
dc.description.abstract	The Sydney rock oyster Saccostrea commercialis is a dominant sessile organism of intertidal rocky shore and mangrove communities of Port Stephens, New South Wales. This study describes patterns of distribution and abundance of S. commercialis in these habitats, as well as those of the recently introduced Pacific oyster Crassostrea gigas. Observations drawn from these mensurative studies were used to formulate and test hypotheses concerning the importance of some ecological processes in structuring intertidal oyster communities. A preliminary survey in the spring of 1990 revealed for the first time the presence of C. gigas among S. commercialis rocky shore and mangrove communities in the inner port of Port Stephens. However, few C. gigas were present in the definitive surveys performed 1-2 years later, demonstrating a failure of the 1990 recruits to survive. For the purposes of characterising the intertidal oyster communities, rocky shore and mangrove communities were divided into low, mid and upper intertidal zones. In both communities, the density of S. commercialis increased with intertidal height to above the mid tide level, although a comparison of sites within Port Stephens demonstrated that oyster densities were significantly different within each intertidal zone. The maximum density in the low and mid zone rocky shore plots was approximately 600m-2. The size class structure of both communities was unimodal, with juvenile oysters poorly represented. This low density of juvenile oysters was despite an apparently abundant supply of S. commercialis larvae. Oysters were found to occur in abundance on mangrove pneumatophores, with the degree of aggregation and size of oyster clumps decreasing with intertidal height. Space was not limited, as most pneumatophores were unoccupied by oysters. Recruitment onto experimental patches on a rocky shore and mangrove pneumatophore community was assessed over 1 year, and were examined biweekly during peak settlement times. Three to four episodes of recruitment were observed, with the first two suffering complete mortality over the summer period (December through March). Successful recruitment of S. Commercialis occurred in autumn, although initial mortalities were high across all intertidal zones. The density of recruits decreased with increasing intertidal height in both communities. The presence of adult conspecifics or shells of conspecifics significantly enhanced the density of S. commercialis recruits onto model pneumatophores, but this was not always apparent on rocky shore plots. However, densities of recruits did not differ between treatments over time. The upper limit of intertidal distribution in mangroves and on the rocky shore sites was similar. Recruitment of C. gigas was observed in July, but were few in number. Thermal tolerances of larvae, 1 month-post settlement spat and adults of both S. commercialis and C. gigas were determined to assess the role of thermal stress in structuring oyster communities. The thermal tolerances of the larvae of the two species were similar. Oysters were more resistant to elevated temperatures with age, although C. gigas was less tolerant than S. commercialis over short exposures of elevated temperatures. The body temperatures of insolated model oysters were observed in some instances to exceed the thermal tolerances of spat, but not adults. Shading by mangroves reduced oyster body temperatures by up to 13.5 degrees C, to below that where mortality may be expected in spat. The lower relative thermal tolerance of spat may explain the failure of recruits to survive the summer, and the low density of oysters in the upper intertidal zone. The effect of intra and inter-specific density on survival, size, and shape was tested at low, mid, and upper intertidal zones at 3 sites within Port Stephens. In the upper intertidal zone, high mortalities and reduced growth rates prevented any competitive interactions with both species. However in the low and mid intertidal zones, the presence of both high and low densities of C. gigas induced significant mortalities, reductions in size, and changes in shape in S. commercialis. This experiment demonstrated the potential competitive pressure faced by S. commerciaUs if density of C. gigas recruitment was to increase.	en
dc.format	Thesis (PhD)	en
dc.language.iso	en	en
dc.relation	https://opus.lib.uts.edu.au/bitstream/10453/20307/2/02whole.pdf
dc.relation.replaces	http://hdl.handle.net/2100/1107
dc.rights	The author owns the copyright in this thesis including all reproduction and reuse rights for the work. The work may not be altered without the permission of the copyright owner. Attribution is essential when quoting or paraphrasing from this thesis.
dc.rights	info:eu-repo/semantics/openAccess
dc.rights	au.edu.uts.lib/ppc
dc.title	Population ecology of the Sydney rock oyster saccostrea commercialis and the pacific oyster crassostrea gigas in a New South Wales estuary	en
dc.type	Thesis
utslib.copyright.status	open_access

Abstract:

The Sydney rock oyster Saccostrea commercialis is a dominant sessile organism of intertidal rocky shore and mangrove communities of Port Stephens, New South Wales. This study describes patterns of distribution and abundance of S. commercialis in these habitats, as well as those of the recently introduced Pacific oyster Crassostrea gigas. Observations drawn from these mensurative studies were used to formulate and test hypotheses concerning the importance of some ecological processes in structuring intertidal oyster communities. A preliminary survey in the spring of 1990 revealed for the first time the presence of C. gigas among S. commercialis rocky shore and mangrove communities in the inner port of Port Stephens. However, few C. gigas were present in the definitive surveys performed 1-2 years later, demonstrating a failure of the 1990 recruits to survive. For the purposes of characterising the intertidal oyster communities, rocky shore and mangrove communities were divided into low, mid and upper intertidal zones. In both communities, the density of S. commercialis increased with intertidal height to above the mid tide level, although a comparison of sites within Port Stephens demonstrated that oyster densities were significantly different within each intertidal zone. The maximum density in the low and mid zone rocky shore plots was approximately 600m-2. The size class structure of both communities was unimodal, with juvenile oysters poorly represented. This low density of juvenile oysters was despite an apparently abundant supply of S. commercialis larvae. Oysters were found to occur in abundance on mangrove pneumatophores, with the degree of aggregation and size of oyster clumps decreasing with intertidal height. Space was not limited, as most pneumatophores were unoccupied by oysters. Recruitment onto experimental patches on a rocky shore and mangrove pneumatophore community was assessed over 1 year, and were examined biweekly during peak settlement times. Three to four episodes of recruitment were observed, with the first two suffering complete mortality over the summer period (December through March). Successful recruitment of S. Commercialis occurred in autumn, although initial mortalities were high across all intertidal zones. The density of recruits decreased with increasing intertidal height in both communities. The presence of adult conspecifics or shells of conspecifics significantly enhanced the density of S. commercialis recruits onto model pneumatophores, but this was not always apparent on rocky shore plots. However, densities of recruits did not differ between treatments over time. The upper limit of intertidal distribution in mangroves and on the rocky shore sites was similar. Recruitment of C. gigas was observed in July, but were few in number. Thermal tolerances of larvae, 1 month-post settlement spat and adults of both S. commercialis and C. gigas were determined to assess the role of thermal stress in structuring oyster communities. The thermal tolerances of the larvae of the two species were similar. Oysters were more resistant to elevated temperatures with age, although C. gigas was less tolerant than S. commercialis over short exposures of elevated temperatures. The body temperatures of insolated model oysters were observed in some instances to exceed the thermal tolerances of spat, but not adults. Shading by mangroves reduced oyster body temperatures by up to 13.5 degrees C, to below that where mortality may be expected in spat. The lower relative thermal tolerance of spat may explain the failure of recruits to survive the summer, and the low density of oysters in the upper intertidal zone. The effect of intra and inter-specific density on survival, size, and shape was tested at low, mid, and upper intertidal zones at 3 sites within Port Stephens. In the upper intertidal zone, high mortalities and reduced growth rates prevented any competitive interactions with both species. However in the low and mid intertidal zones, the presence of both high and low densities of C. gigas induced significant mortalities, reductions in size, and changes in shape in S. commercialis. This experiment demonstrated the potential competitive pressure faced by S. commerciaUs if density of C. gigas recruitment was to increase.

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