In this study, we report siderophore-type compounds found in coastal and Sub-Antarctic waters wit... more In this study, we report siderophore-type compounds found in coastal and Sub-Antarctic waters within a 60km transect off the south east coast of Otago Peninsula in New Zealand. The presence of siderophore activity was detected using chrome azurol S assay (CAS) ...
Global climate change is rapidly altering coastal marine ecosystems important for food production... more Global climate change is rapidly altering coastal marine ecosystems important for food production. A comprehensive understanding of how organisms will respond to these complex environmental changes can come only from observing and studying species within their natural environment. To this end, the effects of environmental drivers - pH, dissolved oxygen content, salinity, and temperature - on Crassostrea gigas physiology were evaluated in an outplant experiment. Sibling juvenile oysters were outplanted to eelgrass and unvegetated habitat at five different estuarine sites within the Acidification Nearshore Monitoring Network in Washington State, USA to evaluate how regional environmental drivers influenced molecular physiology. We tested the effects environmental conditions at outplant sites and habitat to determine if macrophyte presence and diurnal cycling buffered pH conditions and changed the oysters expressed proteome. A novel, two-step, gel-free proteomic approach was used to id...
In this study, we report siderophore-type compounds found in coastal and Sub-Antarctic waters wit... more In this study, we report siderophore-type compounds found in coastal and Sub-Antarctic waters within a 60km transect off the south east coast of Otago Peninsula in New Zealand. The presence of siderophore activity was detected using chrome azurol S assay (CAS) ...
Global climate change is rapidly altering coastal marine ecosystems important for food production... more Global climate change is rapidly altering coastal marine ecosystems important for food production. A comprehensive understanding of how organisms will respond to these complex environmental changes can come only from observing and studying species within their natural environment. To this end, the effects of environmental drivers - pH, dissolved oxygen content, salinity, and temperature - on Crassostrea gigas physiology were evaluated in an outplant experiment. Sibling juvenile oysters were outplanted to eelgrass and unvegetated habitat at five different estuarine sites within the Acidification Nearshore Monitoring Network in Washington State, USA to evaluate how regional environmental drivers influenced molecular physiology. We tested the effects environmental conditions at outplant sites and habitat to determine if macrophyte presence and diurnal cycling buffered pH conditions and changed the oysters expressed proteome. A novel, two-step, gel-free proteomic approach was used to id...
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