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3. Coast-wide recruitment dynamics of Olympia oysters reveal limited synchrony and multiple predictors of failure

Author

Paul A. Dinnel, Andrew L. Chang, Matthew C. Ferner, Jennifer L. Ruesink, Danielle C. Zacherl, Charlie Endris, Alan C. Trimble, Dick Vander Schaaf, Sarah E. Dudas, John S. Berriman, Chela J. Zabin, Kerstin Wasson, Anna Deck, Brent B. Hughes, Michael Espinoza, Edwin D. Grosholz, and David L. Kimbro

Subjects
0106 biological sciences, Canada, Oyster, Population Dynamics, Population, Biology, 010603 evolutionary biology, 01 natural sciences, Propagule, Abundance (ecology), biology.animal, Animals, Ostrea lurida, 14. Life underwater, education, Ecology, Evolution, Behavior and Systematics, geography, education.field_of_study, Pacific Ocean, geography.geographical_feature_category, Ecology, 010604 marine biology & hydrobiology, Estuary, Population ecology, biology.organism_classification, Ostreidae, United States, Fishery, Population cycle, Animal Distribution
Abstract

Recruitment of new propagules into a population can be a critical determinant of adult density. We examined recruitment dynamics in the Olympia oyster (Ostrea lurida), a species occurring almost entirely in estuaries. We investigated spatial scales of interannual synchrony across 37 sites in eight estuaries along 2500 km of Pacific North American coastline, predicting that high vs. low recruitment years would coincide among neighboring estuaries due to shared exposure to regional oceanographic factors. Such synchrony in recruitment has been found for many marine species and some migratory estuarine species, but has never been examined across estuaries in a species that can complete its entire life cycle within the same estuary. To inform ongoing restoration efforts for Olympia oysters, which have declined in abundance in many estuaries, we also investigated predictors of recruitment failure. We found striking contrasts in absolute recruitment rate and frequency of recruitment failure among sites, estuaries, and years. Although we found a positive relationship between upwelling and recruitment, there was little evidence of synchrony in recruitment among estuaries along the coast, and only limited synchrony of sites within estuaries, suggesting recruitment rates are affected more strongly by local dynamics within estuaries than by regional oceanographic factors operating at scales encompassing multiple estuaries. This highlights the importance of local wetland and watershed management for the demography of oysters, and perhaps other species that can complete their entire life cycle within estuaries. Estuaries with more homogeneous environmental conditions had greater synchrony among sites, and this led to the potential for estuary-wide failure when all sites had no recruitment in the same year. Environmental heterogeneity within estuaries may thus buffer against estuary-wide recruitment failure, analogous to the portfolio effect for diversity. Recruitment failure was correlated with lower summer water temperature, higher winter salinity, and shorter residence time, all indicators of stronger marine influence on estuaries. Recruitment failure was also more common in estuaries with limited networks of nearby adult oysters. Large existing oyster networks are thus of high conservation value, while estuaries that lack them would benefit from restoration efforts to increase the extent and connectivity of sites supporting oysters. This article is protected by copyright. All rights reserved.

Published
2016
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4. Dry and wet periods drive rapid shifts in community assembly in an estuarine ecosystem

Author

Andrew L. Chang, Gregory M. Ruiz, Jeffrey A. Crooks, and Christopher W. Brown

Subjects
0106 biological sciences, Salinity, Climate, Climate Change, Climate change, Fresh Water, Context (language use), 010603 evolutionary biology, 01 natural sciences, Water Cycle, Animals, Humans, Environmental Chemistry, Ecosystem, Water cycle, General Environmental Science, Global and Planetary Change, geography, geography.geographical_feature_category, Ecology, 010604 marine biology & hydrobiology, Estuary, Invertebrates, Bays, Habitat, Disturbance (ecology), Environmental science, San Francisco, Seasons, Estuaries, Bay
Abstract

The impacts of changing climate regimes on emergent processes controlling the assembly of ecological communities remain poorly understood. Human alterations to the water cycle in the western United States have resulted in greater interannual variability and more frequent and severe extremes in freshwater flow. The specific mechanisms through which such extremes and climate regime shifts may alter ecological communities have rarely been demonstrated, and baseline information on current impacts of environmental variation is widely lacking for many habitats and communities. Here, we used observations and experiments to show that interannual variation in winter salinity levels in San Francisco Bay controls the mechanisms determining sessile invertebrate community composition during the following summer. We found consistent community changes in response to decadal-scale dry and wet extremes during a 13-year period, producing strikingly different communities. Our results match theoretical predictions of major shifts in species composition in response to environmental forcing up to a threshold, beyond which we observed mass mortality and wholesale replacement of the former community. These results provide a window into potential future community changes, with environmental forcing altering communities by shifting the relative influences of the mechanisms controlling species distributions and abundances. We place these results in the context of historical and projected future environmental variation in the San Francisco Bay Estuary.

Published
2017
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5. A NEW RECORD AND ERADICATION OF THE NORTHERN ATLANTIC ALGAASCOPHYLLUM NODOSUM(PHAEOPHYCEAE) FROM SAN FRANCISCO BAY, CALIFORNIA, USA

Author

Andrew L. Chang, Gregory M. Ruiz, A. Whitman Miller, and Natalie Cosentino-Manning

Subjects
Shore, geography, geography.geographical_feature_category, biology, Ecology, Intertidal zone, Asexual reproduction, macromolecular substances, Plant Science, Aquatic Science, biology.organism_classification, Wrack, Fishery, Habitat, Algae, Bay, Ascophyllum
Abstract

A new record of the Northern Atlantic fucoid Ascophyllum nodosum (L.) Le Jolis (Knotted wrack) was discovered on a shoreline in San Francisco Bay, California during a survey of intertidal habitats in 2001–2002. The alga showed no signs of deterioration 2.5 months after its initial detection. The healthy condition, presence of receptacles with developing oogonia, potential for asexual reproduction, and ability to withstand environmental conditions, both inside the Bay and on the outer Pacific coast, prompted a multiagency eradication effort. Given the relatively small area of shoreline inhabited by the alga, in combination with its absence in 125 other surveyed locations, we decided that manual removal of the seaweed would be the most environmentally sensitive yet effective eradication approach. No A. nodosum has been detected at the site since December 2002, and the species is thought to have been locally eradicated. The site continues to be monitored to assess the success of the eradication efforts.

Published
2004
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