Your search keyword '"McKenna, Brigid A."' showing total 5 results

1. Decadal-scale phenology and seasonal climate drivers of migratory baleen whales in a rapidly warming marine ecosystem.

Author

Pendleton, Daniel E, Pendleton, Daniel E, Tingley, Morgan W, Ganley, Laura C, Friedland, Kevin D, Mayo, Charles, Brown, Moira W, McKenna, Brigid E, Jordaan, Adrian, Staudinger, Michelle D, Pendleton, Daniel E, Pendleton, Daniel E, Tingley, Morgan W, Ganley, Laura C, Friedland, Kevin D, Mayo, Charles, Brown, Moira W, McKenna, Brigid E, Jordaan, Adrian, and Staudinger, Michelle D

Abstract

Species' response to rapid climate change can be measured through shifts in timing of recurring biological events, known as phenology. The Gulf of Maine is one of the most rapidly warming regions of the ocean, and thus an ideal system to study phenological and biological responses to climate change. A better understanding of climate-induced changes in phenology is needed to effectively and adaptively manage human-wildlife conflicts. Using data from a 20+ year marine mammal observation program, we tested the hypothesis that the phenology of large whale habitat use in Cape Cod Bay has changed and is related to regional-scale shifts in the thermal onset of spring. We used a multi-season occupancy model to measure phenological shifts and evaluate trends in the date of peak habitat use for North Atlantic right (Eubalaena glacialis), humpback (Megaptera novaeangliae), and fin (Balaenoptera physalus) whales. The date of peak habitat use shifted by +18.1 days (0.90 days/year) for right whales and +19.1 days (0.96 days/year) for humpback whales. We then evaluated interannual variability in peak habitat use relative to thermal spring transition dates (STD), and hypothesized that right whales, as planktivorous specialist feeders, would exhibit a stronger response to thermal phenology than fin and humpback whales, which are more generalist piscivorous feeders. There was a significant negative effect of western region STD on right whale habitat use, and a significant positive effect of eastern region STD on fin whale habitat use indicating differential responses to spatial seasonal conditions. Protections for threatened and endangered whales have been designed to align with expected phenology of habitat use. Our results show that whales are becoming mismatched with static seasonal management measures through shifts in their timing of habitat use, and they suggest that effective management strategies may need to alter protections as species adapt to climate change.

Published

2022

2. The role of soil in defining planetary boundaries and the safe operating space for humanity

Author

Kopittke, Peter M., Menzies, Neal W., Dalal, Ram C., McKenna, Brigid A., Husted, Søren, Wang, Peng, Lombi, Enzo, Kopittke, Peter M., Menzies, Neal W., Dalal, Ram C., McKenna, Brigid A., Husted, Søren, Wang, Peng, and Lombi, Enzo

Abstract

We use soils to provide 98.8% of our food, but we must ensure that the pressure we place on soils to provide this food in the short-term does not inadvertently push the Earth into a less hospitable state in the long-term. Using the planetary boundaries framework, we show that soils are a master variable for regulating critical Earth-system processes. Indeed, of the seven Earth-systems that have been quantified, soils play a critical and substantial role in changing the Earth-systems in at least two, either directly or indirectly, as well as smaller contributions for a further three. For the biogeochemical flows Earth-system process, soils contribute 66% of the total anthropogenic change for nitrogen and 38% for phosphorus, whilst for the land-system change Earth-system process, soils indirectly contribute 80% of global anthropogenic change. Furthermore, perturbations of soils contribute directly to 21% of climate change, 25% to ocean acidification, and 25% to stratospheric ozone depletion. We argue that urgent interventions are required to greatly improve soil management, especially for those Earth-system processes where the planetary boundary has already been exceeded and where soils make an important contribution, with this being for biogeochemical flows (both nitrogen and phosphorus), for climate change, and for land system change. Of particular importance, it is noted that the highly inefficient use of N fertilizers results in release of excess N into the broader environment, contributes to climate change, and results in release of ozone depleting substances. Furthermore, the use of soils for agricultural production results not only in land-system change, but also in the loss (mineralization) of organic matter with a concomitant release of CO2 contributing to both climate change and ocean acidification. Thus, there is a need to markedly improve the efficiency of fertilizer applications and to intensify usage of our most fertile soils in order to allow the res

Published

2021

3. The role of soil in defining planetary boundaries and the safe operating space for humanity

Author

Kopittke, Peter M., Menzies, Neal W., Dalal, Ram C., McKenna, Brigid A., Husted, Søren, Wang, Peng, Lombi, Enzo, Kopittke, Peter M., Menzies, Neal W., Dalal, Ram C., McKenna, Brigid A., Husted, Søren, Wang, Peng, and Lombi, Enzo

Abstract

We use soils to provide 98.8% of our food, but we must ensure that the pressure we place on soils to provide this food in the short-term does not inadvertently push the Earth into a less hospitable state in the long-term. Using the planetary boundaries framework, we show that soils are a master variable for regulating critical Earth-system processes. Indeed, of the seven Earth-systems that have been quantified, soils play a critical and substantial role in changing the Earth-systems in at least two, either directly or indirectly, as well as smaller contributions for a further three. For the biogeochemical flows Earth-system process, soils contribute 66% of the total anthropogenic change for nitrogen and 38% for phosphorus, whilst for the land-system change Earth-system process, soils indirectly contribute 80% of global anthropogenic change. Furthermore, perturbations of soils contribute directly to 21% of climate change, 25% to ocean acidification, and 25% to stratospheric ozone depletion. We argue that urgent interventions are required to greatly improve soil management, especially for those Earth-system processes where the planetary boundary has already been exceeded and where soils make an important contribution, with this being for biogeochemical flows (both nitrogen and phosphorus), for climate change, and for land system change. Of particular importance, it is noted that the highly inefficient use of N fertilizers results in release of excess N into the broader environment, contributes to climate change, and results in release of ozone depleting substances. Furthermore, the use of soils for agricultural production results not only in land-system change, but also in the loss (mineralization) of organic matter with a concomitant release of CO2 contributing to both climate change and ocean acidification. Thus, there is a need to markedly improve the efficiency of fertilizer applications and to intensify usage of our most fertile soils in order to allow the res

Published

2021

4. Characterizing the uptake, accumulation and toxicity of silver sulfide nanoparticles in plants

Author

Wang, Peng, Lombi, Enzo, Sun, Shengkai, Scheckel, Kirk G., Malysheva, Anzhela, McKenna, Brigid A., Menzies, Neal W., Zhao, Fang-Jie, Kopittke, Peter M., Wang, Peng, Lombi, Enzo, Sun, Shengkai, Scheckel, Kirk G., Malysheva, Anzhela, McKenna, Brigid A., Menzies, Neal W., Zhao, Fang-Jie, and Kopittke, Peter M.

Published

2017

5. Identification of the primary lesion of toxic aluminum in plant roots

Author

Kopittke, Peter M., Moore, Katie L., Lombi, Enzo, Gianoncelli, Alessandra, Ferguson, Brett J., Blamey, F. Pax C., Menzies, Neal W., Nicholson, Timothy M., McKenna, Brigid A., Wang, Peng, Gresshoff, Peter M., Kourousias, George, Webb, Richard I., Green, Kathryn, Tollenaere, Alina, Kopittke, Peter M., Moore, Katie L., Lombi, Enzo, Gianoncelli, Alessandra, Ferguson, Brett J., Blamey, F. Pax C., Menzies, Neal W., Nicholson, Timothy M., McKenna, Brigid A., Wang, Peng, Gresshoff, Peter M., Kourousias, George, Webb, Richard I., Green, Kathryn, and Tollenaere, Alina

Abstract

Despite the rhizotoxicity of aluminum (Al) being identified over 100 years ago, there is still no consensus regarding the mechanisms whereby root elongation rate is initially reduced in the approximately 40% of arable soils worldwide that are acidic. We used high-resolution kinematic analyses, molecular biology, rheology, and advanced imaging techniques to examine soybean (Glycine max) roots exposed to Al. Using this multidisciplinary approach, we have conclusively shown that the primary lesion of Al is apoplastic. In particular, it was found that 75 µm Al reduced root growth after only 5 min (or 30 min at 30 µm Al), with Al being toxic by binding to the walls of outer cells, which directly inhibited their loosening in the elongation zone. An alteration in the biosynthesis and distribution of ethylene and auxin was a second, slower effect, causing both a transient decrease in the rate of cell elongation after 1.5 h but also a longer term gradual reduction in the length of the elongation zone. These findings show the importance of focusing on traits related to cell wall composition as well as mechanisms involved in wall loosening to overcome the deleterious effects of soluble Al.

Published

2015