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41 results on '"McKenna, Brigid A."'

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

Author

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

Subjects
Life on Land, Climate Action, Animals, Ecosystem, Fin Whale, Humans, Humpback Whale, Seasons, Sexually Transmitted Diseases, phenology, climate change, Gulf of Maine, ocean warming, North Atlantic right whale, humpback whale, fin whale, endangered species, Environmental Sciences, Biological Sciences, Ecology
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

5. Engagement and Performance in a First Year Natural Resource Science Course

Author

McKenna, Brigid A. and Kopittke, Peter M.

Abstract

Quantifying student engagement with online learning resources on virtual learning environments such as BlackBoard is important in understanding how these technologies enhance the student learning. In the present study, it was examined when, and how often, first-year students accessed lecture recordings, lecture slides, and lecture notes via BlackBoard, in an introductory natural resource course taken by both on campus students and remote students. The findings demonstrated that lecture recordings were not well utilized by students--although only 58% of on campus students attended face-to-face lectures, less than 15% of absent students downloaded the missed lecture. Overall, more students downloaded lecture slides (an average of 63% per week) than notes (38%) or recordings (16%). Indeed, the average student downloaded only 1.1 types of the 3 online resources (recordings, slides, and notes) that were available each week, with 5.7% of students downloading all 3 types of resources, 23% downloading 2 types of resources, 42% downloading only 1 type of resource, and 29% downloading none of the 3 types of resources. Finally, remote students were more likely to download lecture notes and recordings than were on campus students. The information presented here is important in understanding student behaviour and engagement.

Published
2018
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7. Healthy soil for healthy humans and a healthy planet.

Author

Kopittke, Peter M., Minasny, Budiman, Pendall, Elise, Rumpel, Cornelia, and McKenna, Brigid A.

Subjects
SOIL degradation, SOILS, AGRICULTURAL intensification, BIOMASS production, SOIL erosion, HUMAN origins
Abstract

Soil provides multiple, diverse functions, with these underpinning both planetary and human health. For planetary health, soil contributes to multiple critical processes, including through biomass production, by regulating the carbon pool, providing a habitat for 25% of global biodiversity, cycling the nutrients upon which terrestrial systems depend, and cycling water. Soil also underpins human health; humans use soil to provide 98.8% of our food and sustain our nutrition, regulate pathogens, and supply medicines. However, humans have tended to focus on soil almost solely for producing biomass (food, fiber, and energy) through intensive agriculture, and this narrow focus now causes rapid soil degradation, including through loss of soil organic matter, erosion, and salinization. This degradation directly harms planetary health and reduces the ability of soil to support health of future human generations. We argue that a healthy soil is a soil that is multifunctional and is capable of underpinning human and planetary health. Using this definition, a broad conceptual framework is provided for quantifying soil health, with such an approach enabling a shift in the way that we think about, plan, and manage systems to ensure ongoing planetary and human health. [ABSTRACT FROM AUTHOR]

Published
2024
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8. 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, and Tollenaere, Alina

Published
2015

14. Individual North Atlantic right whales identified from space.

Author

Hodul, Matus, Knudby, Anders, McKenna, Brigid, James, Amy, Mayo, Charles, Brown, Moira, Durette‐Morin, Delphine, and Bird, Stephen

Subjects
WHALES, LOCATION data, REMOTE-sensing images, HABITATS, ELEVATING platforms, LANDSAT satellites
Abstract

The population of the critically endangered North Atlantic right whale, Eubalaena glacialis, numbers approximately 336 individuals, and continues to decline. Current development and implementation of protection measures and monitoring of right whale presence relies on visual surveys from vessel and aerial platforms, and passive acoustic monitoring, which contribute to location data. Here we demonstrate that satellite imagery can be used to detect and confirm the North Atlantic right whales at a species level using newly available imaging methods, providing another tool to inform conservation efforts. Using optical satellite imagery with 15 cm resolution, 25 right whales were observed in Cape Cod Bay on April 24, 2021. Species confirmation was possible due to clearly visible callosity patterns indicative of their species within this range. Although the variations in callosity patterns commonly used to identify individuals were too small to be resolved at this image resolution, one whale with large distinctive markings visible on his body was identified at an individual level from satellite imagery alone. Although visual and acoustic survey methods can be combined for monitoring this species in critical habitats, satellite‐based monitoring can be especially helpful to understand whale presence outside the areas monitored with existing visual and acoustic detection methods. [ABSTRACT FROM AUTHOR]

Published
2023
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18. Use of [beta]-blockers and effects on heart rate and blood pressure post-acute coronary syndromes: Are we on target?

Author

Herman, Michael, Donovan, Jennifer, Tran, Maichi, McKenna, Brigid, Gore, Joel M., Goldberg, Robert J., and Tighe, Dennis A.

Subjects
Heart attack -- Usage, Adrenergic beta blockers -- Usage, Blood pressure -- Usage, Cardiac patients -- Usage, Health
Abstract

To link to full-text access for this article, visit this link: http://dx.doi.org/10.1016/j.ahj.2009.06.023 Byline: Michael Herman (a)(c), Jennifer Donovan (a)(c), Maichi Tran (a)(b)(c), Brigid McKenna (a)(b), Joel M. Gore (a)(b), Robert J. Goldberg (a)(b), Dennis A. Tighe (a)(b) Abstract: [beta]-Blockers have been shown to benefit patients after myocardial infarction by decreasing mortality, sudden cardiac death, and reinfarction. Although [beta]-blockers are recommended for all patients with acute coronary syndromes (ACS) without contraindications, a target heart rate (HR) is recommended only for patients with unstable angina/non ST-elevation myocardial infarction. A contemporary series documenting trends in [beta]-blocker usage and achieved HR and blood pressures (BP) is not available. The study objectives were to monitor trends in HR and BP in relation to [beta]-blocker use in a contemporary series of patients with ACS. Author Affiliation: (a) Division of Cardiovascular Medicine, UMass-Memorial Medical Center, Worcester, MA (b) Division of Cardiovascular Medicine, University of Massachusetts Medical School, Worcester, MA (c) Massachusetts College of Pharmacy and Health Sciences, Worcester, MA Article History: Received 26 February 2009; Accepted 13 June 2009

Published
2009

19. Online Engagement during COVID-19: Comparing a Course Previously Delivered Traditionally with Emergency Online Delivery.

Author

McKenna, Brigid A., Horton, Ciara, and Kopittke, Peter M.

Subjects
*STUDENT engagement, *COVID-19, *ACADEMIC motivation, *STUDENT participation, *STUDENT activities, *VIRTUAL communities
Abstract

The COVID-19 pandemic caused major disruptions worldwide to teaching and learning activities across the education sector. We investigated the impact of COVID-19 on student engagement and performance in a third-year undergraduate science course by comparing student activity during emergency online delivery and traditional mode delivery. We found that the rapid transition to fully online teaching without any physical face-to-face teaching caused by COVID-19 resulted in learning resources being accessed at a slower rate throughout the semester. Student engagement decreased as evidenced by lower attendance at tutorials, despite this being the only virtual face-to-face activity available to students in this course. Thus, despite the smooth transition to fully online mode, it was not sufficient to prevent a decrease in student activity and participation in the online environment, and we observed a downward spiral in student engagement and motivation. Results indicate the importance of providing structure and teacher-student-peer interaction in online delivery modes. [ABSTRACT FROM AUTHOR]

Published
2022
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20. Examining a synchrotron‐based approach for in situ analyses of Al speciation in plant roots.

Author

Li, Zhigen, Wang, Peng, Menzies, Neal W., McKenna, Brigid A., Karunakaran, Chithra, Dynes, James J., Arthur, Zachary, Liu, Na, Zuin, Lucia, Wang, Dongniu, and Kopittke, Peter M.

Subjects
PLANT species, PLANT roots, DETECTION limit, BUCKWHEAT, SPECIATION analysis, PLANT cells & tissues
Abstract

Aluminium (Al) K‐ and L‐edge X‐ray absorption near‐edge structure (XANES) has been used to examine Al speciation in minerals but it remains unclear whether it is suitable for in situ analyses of Al speciation within plants. The XANES analyses for nine standard compounds and root tissues from soybean (Glycine max), buckwheat (Fagopyrum tataricum), and Arabidopsis (Arabidopsis thaliana) were conducted in situ. It was found that K‐edge XANES is suitable for differentiating between tetrahedral coordination (peak of 1566 eV) and octahedral coordination (peak of 1568 to 1571 eV) Al, but not suitable for separating Al binding to some of the common physiologically relevant compounds in plant tissues. The Al L‐edge XANES, which is more sensitive to changes in the chemical environment, was then examined. However, the poorer detection limit for analyses prevented differentiation of the Al forms in the plant tissues because of their comparatively low Al concentration. Where forms of Al differ markedly, K‐edge analyses are likely to be of value for the examination of Al speciation in plant tissues. However, the apparent inability of Al K‐edge XANES to differentiate between some of the physiologically relevant forms of Al may potentially limit its application within plant tissues, as does the poorer sensitivity at the L‐edge. [ABSTRACT FROM AUTHOR]

Published
2020
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21. Minimizing experimental artefacts in synchrotron‐based X‐ray analyses of Fe speciation in tissues of rice plants.

Author

Wang, Peng, McKenna, Brigid A., Menzies, Neal W., Li, Cui, Glover, Chris J., Zhao, Fang-Jie, and Kopittke, Peter M.

Subjects
*SYNCHROTRONS, *SPECIATION analysis, *PLANT cells & tissues, *X-rays, *X-ray absorption, *COORDINATE covalent bond
Abstract

Iron (Fe) plays an important role within environmental systems. Synchrotron‐based X‐ray approaches, including X‐ray absorption spectroscopy (XAS), provide powerful tools for in situ analyses of Fe speciation, but beam damage during analysis may alter Fe speciation during its measurement. XAS was used to examine whether experimental conditions affect the analysis of Fe speciation in plant tissues. Even when analyzed in a cryostat at 12 K, it was found that FeIII can rapidly (within 0.5–1 min) photoreduce to FeII, although the magnitude of photoreduction varied depending upon the hydration of the sample, the coordination chemistry of the Fe, as well as other properties. For example, photoreduction of FeIII was considerably higher for aqueous standard compounds than for hydrated plant‐root tissues. The use of freeze‐dried samples in the cryostat (12 K) markedly reduced the magnitude of this FeIII photoreduction, and there was no evidence that the freeze‐drying process itself resulted in experimental artefacts under the current experimental conditions, such as through the oxidation of FeII, although some comparatively small differences were observed when comparing spectra of hydrated and freeze‐dried FeII compounds. The results of this study have demonstrated that FeIII photoreduction can occur during X‐ray analysis, and provides suitable conditions to preserve Fe speciation to minimize the extent of beam damage when analyzing environmental samples. All studies utilizing XAS are encouraged to include a preliminary experiment to determine if beam damage is occurring, and, where appropriate, to take the necessary steps (such as freeze drying) to overcome these issues. [ABSTRACT FROM AUTHOR]

Published
2019
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22. Manganese distribution and speciation help to explain the effects of silicate and phosphate on manganese toxicity in four crop species.

Author

Blamey, F. Pax C., McKenna, Brigid A., Li, Cui, Cheng, Miaomiao, Tang, Caixian, Jiang, Haibo, Howard, Daryl L., Paterson, David J., Kappen, Peter, Wang, Peng, Menzies, Neal W., and Kopittke, Peter M.

Subjects
*SOIL acidity, *WATERLOGGING (Soils), *COWPEA, *SOYBEAN, *MASS spectrometry, *SYNCHROTRONS
Abstract

Summary: Soil acidity and waterlogging increase manganese (Mn) in leaf tissues to potentially toxic concentrations, an effect reportedly alleviated by increased silicon (Si) and phosphorus (P) supply. Effects of Si and P on Mn toxicity were studied in four plant species using synchrotron‐based micro X‐ray fluorescence (μ‐XRF) and nanoscale secondary ion mass spectrometry (NanoSIMS) to determine Mn distribution in leaf tissues and using synchrotron‐based X‐ray absorption spectroscopy (XAS) to measure Mn speciation in leaves, stems and roots. A concentration of 30 μM Mn in solution was toxic to cowpea and soybean, with 400 μM Mn toxic to sunflower but not white lupin. Unexpectedly, μ‐XRF analysis revealed that 1.4 mM Si in solution decreased Mn toxicity symptoms through increased Mn localization in leaf tissues. NanoSIMS showed Mn and Si co‐localized in the apoplast of soybean epidermal cells and basal cells of sunflower trichomes. Concomitantly, added Si decreased oxidation of Mn(II) to Mn(III) and Mn(IV). An increase from 5 to 50 μM P in solution changed some Mn toxicity symptoms but had little effect on Mn distribution or speciation. We conclude that Si increases localized apoplastic sorption of Mn in cowpea, soybean and sunflower leaves thereby decreasing free Mn2+ accumulation in the apoplast or cytoplasm. [ABSTRACT FROM AUTHOR]

Published
2018
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23. Alleviation of Al Toxicity by Si Is Associated with the Formation of Al–Si Complexes in Root Tissues of Sorghum.

Author

Kopittke, Peter M., Gianoncelli, Alessandra, Kourousias, George, Green, Kathryn, and McKenna, Brigid A.

Subjects
SILICON, SOYBEAN, SYNCHROTRONS
Abstract

Silicon is reported to reduce the toxic effects of Al on root elongation but the in planta mechanism by which this occurs remains unclear. Using seedlings of soybean (Glycine max) and sorghum (Sorghum bicolor), we examined the effect of up to 2 mM Si on root elongation rate (RER) in Al-toxic nutrient solutions. Synchrotron-based low energy X-ray fluorescence (LEXRF) was then used for the in situ examination of the distribution of Al and Si within cross-sections cut from the apical tissues of sorghum roots. The addition of Si potentially increased RER in Al-toxic solutions, with RER being up to ca. 0.3 mm h-1 (14%) higher for soybean and ca. 0.2 mm h-1 (17%) higher for sorghum relative to solutions without added Si. This improvement in RER could not be attributed to a change in Al-chemistry of the bulk nutrient solution, nor was it due to a change in the concentration of Al within the apical (0–10 mm) root tissues. Using LEXRF to examine sorghum, it was demonstrated that in roots exposed to both Al and Si, much of the Al was co-located with Si in the mucigel and outer apoplast. These observations suggest that Si reduces the toxicity of Al in planta through formation of Al–Si complexes in mucigel and outer cellular tissues, thereby decreasing the binding of Al to the cell wall where it is known to inhibit wall loosening as required for cell elongation. [ABSTRACT FROM AUTHOR]

Published
2017
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24. Aluminum Complexation with Malate within the Root Apoplast Differs between Aluminum Resistant and Sensitive Wheat Lines.

Author

Kopittke, Peter M., McKenna, Brigid A., Karunakaran, Chithra, Dynes, James J., Arthur, Zachary, Gianoncelli, Alessandra, Kourousias, George, Menzies, Neal W., Ryan, Peter R., Peng Wang, Green, Kathryn, and Blamey, F. P. C.

Subjects
WHEAT genetics, ALUMINUM, RHIZOSPHERE
Abstract

In wheat (Triticum aestivum), it is commonly assumed that Al is detoxified by the release of organic anions into the rhizosphere, but it is also possible that detoxification occurs within the apoplast and symplast of the root itself. Using Al-resistant (ET8) and Al-sensitive (ES8) near-isogenic lines of wheat, we utilized traditional and synchrotronbased approaches to provide in situ analyses of the distribution and speciation of Al within root tissues. Some Al appeared to be complexed external to the root, in agreement with the common assumption. However, root apical tissues of ET8 accumulated four to six times more Al than ES8 when exposed to Al concentrations that reduce root elongation rate by 50% (3.5 mM Al for ES8 and 50 mM for ET8). Furthermore, in situ analyses of ET8 root tissues indicated the likely presence of Al-malate and other forms of Al, predominantly within the apoplast. To our knowledge, this is the first time that X-ray absorption near edge structure analyses have been used to examine the speciation of Al within plant tissues. The information obtained in the present study is important in developing an understanding of the underlying physiological mode of action for improved root growth in systems with elevated soluble Al. [ABSTRACT FROM AUTHOR]

Published
2017
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26. Aluminium effects on mechanical properties of cell wall analogues.

Author

McKenna, Brigid A., Wehr, J. Bernhard, Mikkelsen, Deirdre, Blamey, F. Pax C., and Menzies, Neal W.

Subjects
*PLANT productivity, *PHYSIOLOGICAL effects of aluminum, *TOXICOLOGY of aluminum, *EFFECT of aluminum on plants, *PLANT cell walls
Abstract

Aluminium (Al) toxicity adversely impacts plant productivity in acid soils by restricting root growth and although several mechanisms are involved the physiological basis of decreased root elongation remains unclear. Understanding the primary mechanisms of Al rhizotoxicity is hindered due to the rapid effects of soluble Al on root growth and the close proximity of many cellular components within the cell wall, plasma membrane, cytosol and nucleus with which Al may react. To overcome some of these difficulties, we report on a novel method for investigating Al interactions with Komagataeibacter xylinus bacterial cellulose (BC)-pectin composites as cell wall analogues. The growth of K. xylinus in the presence of various plant cell wall polysaccharides, such as pectin, has provided a unique in vitro model system with which to investigate the interactions of Al with plant cell wall polysaccharides. The BC-pectin composites reacted in a similar way with Al as do plant cell walls, providing insights into the effects of Al on the mechanical properties of the BC-pectin composites as cell wall analogues. Our findings indicated that there were no significant effects of Al (4-160 μM) on the tensile stress, tensile strain or Young's modulus of the composites. This finding was consistent with cellulose, not pectin, being the major load bearing component in BC-pectin composites, as is also the case in plant cell walls. [ABSTRACT FROM AUTHOR]

Published
2016
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27. Synchrotron-based X-ray absorption near-edge spectroscopy imaging for laterally resolved speciation of selenium in fresh roots and leaves of wheat and rice.

Author

Peng Wang, Menzies, Neal W., Lombi, Enzo, McKenna, Brigid A., James, Simon, Caixian Tang, and Kopittke, Peter M.

Subjects
ABSORPTION, SELENIUM, PLANT roots, LEAVES, MOLECULAR genetics
Abstract

Knowledge of the distribution of selenium (Se) species within plant tissues will assist in understanding the mechanisms of Se uptake and translocation, but in situ analysis of fresh and highly hydrated plant tissues is challenging. Using synchrotron-based fluorescence X-ray absorption near-edge spectroscopy (XANES) imaging to provide laterally resolved data, the speciation of Se in fresh roots and leaves of wheat (Triticum aestivum L.) and rice (Oryza sativa L.) supplied with 1 nM of either selenate or selenite was investigated. For plant roots exposed to selenate, the majority of the Se was efficiently converted to C-Se-C compounds (i.e. methylselenocysteine or selenomethionine) as selenate was transported radially through the root cylinder. Indeed, even in the rhizodermis which is exposed directly to the bulk solution, only 12-31% of the Se was present as uncomplexed selenate. The C-Se-C compounds were probably sequestered within the roots, whilst much of the remaining uncomplexed Se was translocated to the leaves--selenate accounting for 52-56% of the total Se in the leaves. In a similar manner, for plants exposed to selenite, the Se was efficiently converted to C-Se-C compounds within the roots, with only a small proportion of uncomplexed selenite observed within the outer root tissues. This resulted in a substantial decrease in translocation of Se from the roots to leaves of selenite-exposed plants. This study provides important information for understanding the mechanisms responsible for the uptake and subsequent transformation of Se in plants. [ABSTRACT FROM AUTHOR]

Published
2015
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28. Laterally resolved speciation of arsenic in roots of wheat and rice using fluorescence- XANES imaging.

Author

Kopittke, Peter M., Jonge, Martin D., Wang, Peng, McKenna, Brigid A., Lombi, Enzo, Paterson, David J., Howard, Daryl L., James, Simon A., Spiers, Kathryn M., Ryan, Chris G., Johnson, Alexander A. T., and Menzies, Neal W.

Subjects
GENETIC speciation, PHYSIOLOGICAL effects of arsenic, PLANT root physiology, PLANT cells & tissues, RICE, WHEAT, PHYSIOLOGY
Abstract

Accumulation of arsenic (As) within plant tissues represents a human health risk, but there remains much to learn regarding the speciation of As within plants., We developed synchrotron-based fluorescence-X-ray absorption near-edge spectroscopy (fluorescence- XANES) imaging in hydrated and fresh plant tissues to provide laterally resolved data on the in situ speciation of As in roots of wheat ( Triticum aestivum) and rice ( Oryza sativa) exposed to 2 μM As(V) or As( III)., When exposed to As(V), the As was rapidly reduced to As( III) within the root, with As(V) calculated to be present only in the rhizodermis. However, no uncomplexed As( III) was detected in any root tissues, because of the efficient formation of the As( III)-thiol complex - this As species was calculated to account for all of the As in the cortex and stele. The observation that uncomplexed As( III) was below the detection limit in all root tissues explains why the transport of As to the shoots is low, given that uncomplexed As( III) is the major As species transported within the xylem and phloem., Using fluorescence- XANES imaging, we have provided in situ data showing the accumulation and transformation of As within hydrated and fresh root tissues. [ABSTRACT FROM AUTHOR]

Published
2014
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29. The rhizotoxicity of metal cations is related to their strength of binding to hard ligands.

Author

Kopittke, Peter M., Menzies, Neal W., Wang, Peng, McKenna, Brigid A., Wehr, J. Bernhard, Lombi, Enzo, Kinraide, Thomas B., and Blamey, F. Pax C.

Subjects
CATIONS, LIGANDS (Chemistry), PROTEIN binding, BIOCHEMISTRY, ENVIRONMENTAL toxicology
Abstract

Mechanisms whereby metal cations are toxic to plant roots remain largely unknown. Aluminum, for example, has been recognized as rhizotoxic for approximately 100 yr, but there is no consensus on its mode of action. The authors contend that the primary mechanism of rhizotoxicity of many metal cations is nonspecific and that the magnitude of toxic effects is positively related to the strength with which they bind to hard ligands, especially carboxylate ligands of the cell-wall pectic matrix. Specifically, the authors propose that metal cations have a common toxic mechanism through inhibiting the controlled relaxation of the cell wall as required for elongation. Metal cations such as Al3+ and Hg2+, which bind strongly to hard ligands, are toxic at relatively low concentrations because they bind strongly to the walls of cells in the rhizodermis and outer cortex of the root elongation zone with little movement into the inner tissues. In contrast, metal cations such as Ca2+, Na+, Mn2+, and Zn2+, which bind weakly to hard ligands, bind only weakly to the cell wall and move farther into the root cylinder. Only at high concentrations is their weak binding sufficient to inhibit the relaxation of the cell wall. Finally, different mechanisms would explain why certain metal cations (for example, Tl+, Ag+, Cs+, and Cu2+) are sometimes more toxic than expected through binding to hard ligands. The data presented in the present study demonstrate the importance of strength of binding to hard ligands in influencing a range of important physiological processes within roots through nonspecific mechanisms. Environ Toxicol Chem 2014;33:268-277. © 2013 SETAC [ABSTRACT FROM AUTHOR]

Published
2014
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31. In Situ Speciation and Distribution of Toxic Selenium in Hydrated Roots of Cowpea.

Author

Peng Wang, Menzies, Neal W., Lombi, Enzo, McKenna, Brigid A., de Jonge, Martin D., Paterson, David J., Howard, Daryl L., Glover, Chris J., James, Simon, Kappen, Peter, Johannessen, Bernt, and Kopittke, Peter M.

Subjects
SELENIUM content of plants, COWPEA research, PLANT roots, MERISTEMS, PLANT cells & tissues
Abstract

The speciation and spatial distribution of selenium (Se) in hydrated plant tissues is not well understood. Using synchrotron-based x-ray absorption spectroscopy and x-ray fluorescence microscopy (two-dimensional scanning [and associated mathematical model] and computed tomography), the speciation and distribution of toxic Se were examined within hydrated roots of cowpea (Vigna unguiculata) exposed to either 20 µM selenite or selenate. Based upon bulk solution concentrations, selenate was 9-fold more toxic to the roots than selenite, most likely due to increased accumulation of organoselenium (e.g. selenomethionine) in selenate-treated roots. Specifically, uptake of selenate (probably by sulfate transporters) occurred at a much higher rate than for selenite (apparently by both passive diffusion and phosphate transporters), with bulk root tissue Se concentrations approximately 18-fold higher in the selenate treatment. Although the proportion of Se converted to organic forms was higher for selenite (100%) than for selenate (26%), the absolute concentration of organoselenium was actually approximately 5-fold higher for selenate-treated roots. In addition, the longitudinal and radial distribution of Se in roots differed markedly: the highest tissue concentrations were in the endodermis and cortex approximately 4 mm or more behind the apex when exposed to selenate but in the meristem (approximately 1 mm from the apex) when exposed to selenite. The examination of the distribution and speciation of Se in hydrated roots provides valuable data in understanding Se uptake, transport, and toxicity. [ABSTRACT FROM AUTHOR]

Published
2013
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32. Distribution and speciation of Mn in hydrated roots of cowpea at levels inhibiting root growth.

Author

Kopittke, Peter M., Lombi, Enzo, McKenna, Brigid A., Wang, Peng, Donner, Erica, Webb, Richard I., Blamey, F. Pax C., de Jonge, Martin D., Paterson, David, Howard, Daryl L., and Menzies, Neal W.

Subjects
COWPEA, PHYTOTOXICITY, ROOT growth, WATERLOGGING (Soils), SOIL solubility
Abstract

The phytotoxicity of Mn is important globally due to its increased solubility in acid or waterlogged soils. Short-term (≤24 h) solution culture studies with 150 µ M Mn were conducted to investigate the in situ distribution and speciation of Mn in apical tissues of hydrated roots of cowpea [Vigna unguiculata (L.) Walp. cv. Red Caloona] using synchrotron-based techniques. Accumulation of Mn was rapid; exposure to 150 µ M Mn for only 5 min resulting in substantial Mn accumulation in the root cap and associated mucigel. The highest tissue concentrations of Mn were in the root cap, with linear combination fitting of the data suggesting that ≥80% of this Mn(II) was associated with citrate. Interestingly, although the primary site of Mn toxicity is typically the shoots, concentrations of Mn in the stele of the root were not noticeably higher than in the surrounding cortical tissues in the short-term (≤24 h). The data provided here from the in situ analyses of hydrated roots exposed to excess Mn are, to our knowledge, the first of this type to be reported for Mn and provide important information regarding plant responses to high Mn in the rooting environment. [ABSTRACT FROM AUTHOR]

Published
2013
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33. Toxicity of metals to roots of cowpea in relation to their binding strength.

Author

Kopittke, Peter M., Blamey, F. Pax C., McKenna, Brigid A., Wang, Peng, and Menzies, Neal W.

Subjects
METAL toxicology, COWPEA, ROOT diseases, PHYTOTOXICITY, LIGANDS (Chemistry), PLANT plasma membranes
Abstract

Metal phytotoxicity is important in both environmental and agricultural systems. A solution culture study examined the toxicity of 26 metals to roots of cowpea (Vigna unguiculata (L.) Walp.); new data were collected for 15 metals and published data for 11 metals. Metal toxicity, calculated as causing a 50% reduction in root elongation rate, was determined based on either the measured concentration in the bulk solution (EC50b) or the calculated activity at the outer surface of the plasma membrane (EA50o0 ). The EC50b values ranged from 0.007 mM for Tl to 98,000mM for K, with the order of rhizotoxicity to cowpea, from most to least toxic, beingTl¼Ag>Cu>Hg¼Ni¼Ga¼Ru¼In Sc¼Cd¼Gd¼La¼Co¼Cs¼Pb>Zn¼Al¼H>Mn>Ba¼Sr>Li>Mg>Ca¼ b>Zn¼Al¼H>Mn>Ba¼Sr>Li>Mg>Ca¼ Na>K. The EA50o0 values suggest that the binding of metals to hard ligands is an important, general, nonspecific mechanism of toxicity, a hypothesis supported by the similar toxicity symptoms to roots of cowpea by many metals. However, additional mechanisms, such as strong binding to soft ligands, substantially increase rhizotoxicity of some metals, especially Tl, Ag, and Cs. Besides direct toxic effects, osmotic effects or reduced activity of Ca2þ at the outer surface of the root plasma membrane (and resultant Ca deficiency) may decrease short-term root growth. [ABSTRACT FROM AUTHOR]

Published
2011
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34. Metal ion effects on hydraulic conductivity of bacterial cellulose–pectin composites used as plant cell wall analogs.

Author

McKenna, Brigid A., Kopittke, Peter M., Wehr, J. Bernhard, Blamey, F. Pax C., and Menzies, Neal W.

Subjects
*METAL ions, *BACTERIA, *CELLULOSE, *PLANT cell walls, *CELLS, *PECTINS, *POROSITY, *SCANNING electron microscopy, *TURGOR
Abstract

Low concentrations of some trace metals markedly reduce root elongation rate and cause ruptures to root rhizodermal and outer cortical cells in the elongation zone. The interactions between the trace metals and plant components responsible for these effects are not well understood but may be linked to changes in water uptake, cell turgor and cell wall extensibility. An experiment was conducted to investigate the effects of Al, La, Cu, Gd, Sc and Ru on the saturated hydraulic conductivity of bacterial cellulose (BC)–pectin composites, used as plant cell wall analogs. Hydraulic conductivity was reduced to ≈30% of the initial flow rate by 39 µ M Al and 0.6 µ M Cu, ≈40% by 4.6 µ M La, 3 µ M Sc and 4.4 µ M Ru and ≈55% by 3.4 µ M Gd. Scanning electron microscopy (SEM) revealed changes in the ultrastructure of the composites. The results suggest that trace metal binding decreases the hydraulic conductivity through changes in pectin porosity. The experiment illustrates the importance of metal interactions with pectin, and the implications of such an interaction in plant metal toxicity and in normal cell wall processes. [ABSTRACT FROM AUTHOR]

Published
2010
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35. Effect of 50 Years of No-Tillage, Stubble Retention, and Nitrogen Fertilization on Soil Respiration, Easily Extractable Glomalin, and Nitrogen Mineralization.

Author

Jha, Pramod, Hati, Kuntal M., Dalal, Ram C., Dang, Yash P., Kopittke, Peter M., McKenna, Brigid A., and Menzies, Neal W.

Subjects
SOIL respiration, NITROGEN in soils, MINERALIZATION, NO-tillage, MICROBIAL respiration
Abstract

In subtropical regions, we have an incomplete understanding of how long-term tillage, stubble, and nitrogen (N) fertilizer management affects soil biological functioning. We examined a subtropical site managed for 50 years using varying tillage (conventional till (CT) and no-till (NT)), stubble management (stubble burning (SB) and stubble retention (SR)), and N fertilization (0 (N0), 30 (N30), and 90 (N90) kg ha−1 y−1) to assess their impact on soil microbial respiration, easily extractable glomalin-related soil protein (EEGRSP), and N mineralization. A significant three-way tillage × stubble × N fertilizer interaction was observed for soil respiration, with NT+SB+N0 treatments generally releasing the highest amounts of CO2 over the incubation period (1135 mg/kg), and NT+SR+N0 treatments releasing the lowest (528 mg/kg). In contrast, a significant stubble × N interaction was observed for both EEGRSP and N mineralization, with the highest concentrations of both EEGRSP (2.66 ± 0.86 g kg−1) and N mineralization (30.7 mg/kg) observed in SR+N90 treatments. Furthermore, N mineralization was also positively correlated with EEGRSP (R2 = 0.76, p < 0.001), indicating that EEGRSP can potentially be used as an index of soil N availability. Overall, this study has shown that SR and N fertilization have a positive impact on soil biological functioning. [ABSTRACT FROM AUTHOR]

Published
2022
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36. Time-resolved X-ray fluorescence analysis of element distribution and concentration in living plants: An example using manganese toxicity in cowpea leaves.

Author

Blamey, F. Pax C., Paterson, David J., Walsh, Adam, Afshar, Nader, McKenna, Brigid A., Cheng, Miaomiao, Tang, Caixian, Horst, Walter J., Menzies, Neal W., and Kopittke, Peter M.

Subjects
*COWPEA, *MANGANESE, *X-ray fluorescence, *SYNCHROTRONS, *PLANT nutrients
Abstract

Highlights • A novel method using synchrotron-based micro X-ray fluorescence. • Provides laterally-resolved, multi-element, kinetic, in vivo analyses of plants. • Allows a wide range of studies for the examination of plant responses. Abstract The distribution and concentration of nutrients and contaminants affect almost every metabolic process in plants but analytical limitations have hindered the determination of microscopic changes over time within living plant tissues. We developed a novel method using synchrotron-based micro X-ray fluorescence (μ-XRF) that, for the first time, allows quantification of the spatial and temporal changes of multiple elements in the same area of living leaves. The utility of this approach was tested by examining changes over 48 h in unifoliate leaves of 7-d-old cowpea (Vigna unguiculata) plants simultaneously at 0.2 and 30 μM Mn in nutrient solution, with 30 μM Mn known to be toxic to cowpea and cause the formation of Mn-dense lesions. The fast X-ray fluorescence detector system reduced dwell on living leaf samples. This produced no evidence of tissue damage through repeated μ-XRF scanning, thereby overcoming previously noted experimental artifacts. This permitted, for the first time, visual and quantitative assessments of spatial and temporal changes in nutrient concentrations. By focusing on changes in Mn status, this study illustrated extension of two-dimensional μ-XRF scans to a three-dimensional geometry of Mn kinetics in the same area of leaves. The multi-element potential of this method was exemplified through the measurement of distributions and concentrations of K, Ca, Fe, Cu, and Zn within living plant leaves. This novel method and accompanying information on changes in Mn distribution showed the potential for microscopic, time-resolved, in vivo examination of changes in elemental distribution. We consider that this method will be of benefit for a wide range of studies, including functional characterization of molecular biology, examining changes in the distribution of nutrients, and understanding the movement and toxicity of contaminants. [ABSTRACT FROM AUTHOR]

Published
2018
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37. Avoiding the point of no return: Maintaining infiltration to remediate saline-sodic Vertosols in high rainfall environments.

Author

Das, Bianca T., Menzies, Neal W., Dalzell, Scott A., McKenna, Brigid A., and Kopittke, Peter M.

Subjects
*SODIC soils, *SOIL amendments, *SOIL profiles, *SOIL leaching, *IONIC strength, *SOIL solutions
Abstract

Saline-sodic soils are often too saline and alkaline for plant survival. These soils are prone to dispersing and eroding after high rainfall events when salinity is reduced before the sodicity. Cost-effective and water efficient methods are needed to leach salts while maintaining sufficient ionic strength of the soil solution. We tested the ability of gypsum, both alone and combined with elemental sulfur and organic matter to remediate the upper 15 cm of a strongly saline-sodic alkaline Vertosol when leached with deionised water in repacked columns. Prior to leaching, all amendment combinations reduced soil alkalinity by 80% and dispersion by 47% by displacing exchangeable sodium (Na). After leaching with 600 mm of deionised water, electrical conductivity of the soil solution (EC ss) decreased from an average of 38–4.8 dS m−1 at 8 cm depth. Importantly, structure was maintained in all amended soils, despite this decrease in EC ss. In contrast, for the control treatment, there was a concomitant loss of soil structural stability as EC ss decreased. This decrease in stability also occurred in the subsoils of all treatments (which were not amended) because the applied calcium (Ca) precipitated before it could be leached to remediate the deeper layers. This study demonstrated that it was critical to first apply amendments as deep in the soil profile as possible to prevent the development of a non-saline sodic soil. Leaching the soil with low ionic strength water removed excess soluble salts from the plant root zone. We estimated that > 300 mm of water (rainfall or irrigation) was required to leach through the root zone to ensure a suitable soil profile for establishing of salt tolerant pioneer species such as Rhodes grass (Chloris gayana Kunth). • Little is known about remediating saline-sodic soils in subtropical climates. • Applying gypsum initially increased salinity but reduced alkalinity and sodicity. • Adding organic matter and sulfur with gypsum did not improve soil remediation. • Infiltrating 600 mm deionised water decreased salinity by 87% at 8 cm depth. • A growth zone for a pioneer plant species was created with 300 mm infiltration. [ABSTRACT FROM AUTHOR]

Published
2022
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38. Quantitative determination of metal and metalloid spatial distribution in hydrated and fresh roots of cowpea using synchrotron-based X-ray fluorescence microscopy.

Author

Wang, Peng, Menzies, Neal W., Lombi, Enzo, McKenna, Brigid A., de Jonge, Martin D., Donner, Erica, Blamey, F. Pax C., Ryan, Chris G., Paterson, David J., Howard, Daryl L., James, Simon A., and Kopittke, Peter M.

Subjects
*QUANTITATIVE chemical analysis, *SEMIMETALS, *HYDRATION, *PLANT roots, *COWPEA, *SYNCHROTRON radiation, *X-ray fluorescence
Abstract

Abstract: Many metals and metalloids, jointly termed metal(loid)s, are toxic to plants even at low levels. This has limited the study of their uptake, distribution, and modes of action in plant roots grown at physiologically relevant concentrations. Synchrotron-based X-ray fluorescence microscopy was used to examine metal(loid)s in hydrated cowpea (Vigna unguiculata L.) roots exposed to Zn(II), Ni(II), Mn(II), Cu(II), Hg(II), Se(IV), Se(VI), As(III), or As(V). Development of a mathematical model enabled in situ quantitative determination of their distribution in root tissues. The binding strength of metals influenced the extent of their movement through the root cylinder, which influenced the toxic effects exerted—metals (e.g. Cu, Hg) that bind more strongly to hard ligands had high concentrations in the rhizodermis and caused this tissue to rupture, while other metals (e.g. Ni, Zn) moved further into the root cylinder and did not cause ruptures. When longitudinal distributions were examined, the highest Se concentration in roots exposed to Se(VI) was in the more proximal root tissues, suggesting that Se(VI) is readily loaded into the stele. This contrasted with other metal(loid)s (e.g. Mn, As), which accumulated in the apex. These differences in metal(loid) spatial distribution provide valuable quantitative data on metal(loid) physiology, including uptake, transport, and toxicity in plant roots. [Copyright &y& Elsevier]

Published
2013
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39. 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, and Lombi, Enzo

Subjects
*OZONE layer depletion, *CARBON dioxide, *OZONE-depleting substances, *OCEAN acidification, *FERTILIZER application, *OZONE layer
Abstract

• Soils are under increasing stress to feed a rapidly growing human population. • We show that soils are a master variable regulating critical Earth-system processes. • Soils make major contributions to biogeochemical flows and land-system change. • Soils also contribute to climate change, ocean acidification, and ozone depletion. • Improving management of soils is critical to maintain Earth in a hospitable state. 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 CO 2 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 restoration of degraded soils and limit further areal expansion of agriculture. Understanding, and acting upon, the role of soils is critical in ensuring that planetary boundaries are not transgressed, with no other single variable playing such a strategic role across all of the planetary boundaries. [ABSTRACT FROM AUTHOR]

Published
2021
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40. Soil and the intensification of agriculture for global food security.

Author

Kopittke, Peter M., Menzies, Neal W., Wang, Peng, McKenna, Brigid A., and Lombi, Enzo

Subjects
*AGRICULTURAL intensification, *FOOD security, *SOIL degradation, *POPULATION, *CROP yields, *FOOD supply, *FERTILIZER application
Abstract

Soils are the most complex and diverse ecosystem in the world. In addition to providing humanity with 98.8% of its food, soils provide a broad range of other services, from carbon storage and greenhouse gas regulation, to flood mitigation and providing support for our sprawling cities. But soil is a finite resource, and rapid human population growth coupled with increasing consumption is placing unprecedented pressure on soils through the intensification of agricultural production – the increasing of crop yield per unit area of soil. Indeed, the human population has increased from ca. 250 million in the year 1000, to 6.1 billion in the year 2000, and is projected to reach 9.8 billion by the year 2050. The current intensification of agricultural practices is already resulting in the unsustainable degradation of soils. Major forms of this degradation include the loss of organic matter and the release of greenhouse gases, the over-application of fertilizers, erosion, contamination, acidification, salinization, and loss of genetic diversity. This ongoing soil degradation is decreasing the long-term ability of soils to provide humans with services, including future food production, and is causing environmental harm. It is imperative that the global society is not shortsighted by focusing solely on the near-immediate benefits of soils, such as food supply. A failure to identify the importance of soil within increasingly intensive agricultural systems will undoubtedly have serious consequences for humanity and represents a failure to consider intergenerational equity. Of utmost importance is the need to unequivocally recognize that the degradation of soils leads to a clear economic cost through the loss of services, with such principles needing to be explicitly considered in economic frameworks and decision-making processes at all levels of governance. We contend that the concept of the Water-Food-Energy nexus must be expanded, forming the Water-Soil-Food-Energy nexus. • Soils provide humans with 98.8% of our food. • Rapid population growth is unprecedented pressure on soils. • Agricultural intensification is already degrading soils unsustainably. • This degradation is decreasing the long-term ability of soils to produce food. • The Water-Food-Energy nexus must be expanded to the Water-Soil-Food-Energy nexus. [ABSTRACT FROM AUTHOR]

Published
2019
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41. Fast X-ray fluorescence microscopy provides high-throughput phenotyping of element distribution in seeds.

Author

Ren ZW, Yang M, McKenna BA, Lian XM, Zhao FJ, Kopittke PM, Lombi E, and Wang P

Subjects
Humans, X-Rays, Seeds genetics, Minerals, Microscopy, Fluorescence, Genome-Wide Association Study, Oryza genetics
Abstract

The concentration, chemical speciation, and spatial distribution of essential and toxic mineral elements in cereal seeds have important implications for human health. To identify genes responsible for element uptake, translocation, and storage, high-throughput phenotyping methods are needed to visualize element distribution and concentration in seeds. Here, we used X-ray fluorescence microscopy (μ-XRF) as a method for rapid and high-throughput phenotyping of seed libraries and developed an ImageJ-based pipeline to analyze the spatial distribution of elements. Using this method, we nondestructively scanned 4,190 ethyl methanesulfonate (EMS)-mutagenized M1 rice (Oryza sativa) seeds and 533 diverse rice accessions in a genome-wide association study (GWAS) panel to simultaneously measure concentrations and spatial distribution of elements in the embryo, endosperm, and aleurone layer. A total of 692 putative mutants and 65 loci associated with the spatial distribution of elements in rice seed were identified. This powerful method provides a basis for investigating the genetics and molecular mechanisms controlling the accumulation and spatial variations of mineral elements in plant seeds., Competing Interests: Conflict of interest statement. None declared., (© American Society of Plant Biologists 2022. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published
2023
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