Your search keyword '"McKenna, Brigid A."' showing total 12 results

1. 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

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

Published

2015

2. In Situ Speciation and Distribution of Toxic Selenium in Hydrated Roots of Cowpea

Author

Wang, Peng, 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.

Published

2013

3. Examination of the Distribution of Arsenic in Hydrated and Fresh Cowpea Roots Using Two- and Three-Dimensional Techniques

Author

Kopittke, Peter M., de Jonge, Martin D., Menzies, Neal W., Wang, Peng, Donner, Erica, McKenna, Brigid A., Paterson, David, Howard, Daryl L., and Lombi, Enzo

Published

2012

4. In Situ Distribution and Speciation of Toxic Copper, Nickel, and Zinc in Hydrated Roots of Cowpea

Author

Kopittke, Peter M., Menzies, Neal W., de Jonge, Martin D., McKenna, Brigid A., Donner, Erica, Webb, Richard I., Paterson, David J., Howard, Daryl L., Ryan, Chris G., Glover, Chris J., Scheckel, Kirk G., and Lombi, Enzo

Published

2011

5. 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

6. 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

7. 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

8. 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

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

Subjects

Absorption (pharmacology), selenium uptake, Physiology, Fluorescence-XANES imaging, media_common.quotation_subject, chemistry.chemical_element, translocation, Plant Science, Selenic Acid, Selenious Acid, Selenate, Plant Roots, fluorescence-XANES imaging, chemistry.chemical_compound, Selenium, Botany, Triticum, media_common, Oryza sativa, transformation, food and beverages, Spectrometry, X-Ray Emission, Biological Transport, Oryza, Rhizodermis, Methylselenocysteine, Plant Leaves, Speciation, X-Ray Absorption Spectroscopy, chemistry, laterally resolved speciation, speciation, Plant nutrition, Synchrotrons, Nuclear chemistry, Research Paper

Abstract

Highlight Using synchrotron-based XANES imaging, in situ laterally resolved speciation of Se in hydrated tissues was obtained, which assists in understanding the Se uptake, translocation, and transformation in fresh plants., 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 μM 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.

Published

2015

9. In Situ Speciation and Distribution of Toxic Selenium in Hydrated Roots of Cowpea

Author

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

Absorption (pharmacology), Physiology, media_common.quotation_subject, water, Inorganic chemistry, chemistry.chemical_element, Plant Science, Selenate, Vigna, chemistry.chemical_compound, Genetics, Sulfate, selenium, media_common, biology, plant roots, fabaceae, biology.organism_classification, Apex (geometry), Speciation, chemistry, soil pollutants, Endodermis, absorption, Selenium, Nuclear chemistry

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. Refereed/Peer-reviewed

Published

2013

10. In Situ Distribution and Speciation of Toxic Copper, Nickel, and Zinc in Hydrated Roots of Cowpea

Author

Kirk G. Scheckel, Christopher Glover, Neal W. Menzies, Martin D. de Jonge, Chris Ryan, Richard I. Webb, Peter M. Kopittke, Erica Donner, Brigid A. McKenna, Enzo Lombi, David Paterson, Daryl L. Howard, Kopittke, Peter M, Menzies, Neal W, de Jonge, Martin D, McKenna, Brigid A, Donner, Erica, Webb, Richard I, Paterson, David J, Howard, Daryl L, Ryan, C, Glover, CJ, Scheckel, K.G, and Lombi, Enzo

Subjects

In situ, spectroscopy, plant tissue, biology, Physiology, media_common.quotation_subject, chemistry.chemical_element, Plant Science, Zinc, biology.organism_classification, Copper, Rhizodermis, Vigna, xray, Speciation, Nickel, chemistry, Botany, microscopy, Genetics, Phytotoxicity, media_common, Nuclear chemistry

Abstract

The phytotoxicity of trace metals is of global concern due to contamination of the landscape by human activities. Using synchrotron-based x-ray fluorescence microscopy and x-ray absorption spectroscopy, the distribution and speciation of copper (Cu), nickel (Ni), and zinc (Zn) was examined in situ using hydrated roots of cowpea (Vigna unguiculata) exposed to 1.5 μm Cu, 5 μm Ni, or 40 μm Zn for 1 to 24 h. After 24 h of exposure, most Cu was bound to polygalacturonic acid of the rhizodermis and outer cortex, suggesting that binding of Cu to walls of cells in the rhizodermis possibly contributes to the toxic effects of Cu. When exposed to Zn, cortical concentrations remained comparatively low with much of the Zn accumulating in the meristematic region and moving into the stele; approximately 60% to 85% of the total Zn stored as Zn phytate within 3 h of exposure. While Ni concentrations were high in both the cortex and meristem, concentrations in the stele were comparatively low. To our knowledge, this is the first report of the in situ distribution and speciation of Cu, Ni, and Zn in hydrated (and fresh) plant tissues, providing valuable information on the potential mechanisms by which they are toxic.

Published

2011

11. Fate of ZnO nanoparticles in soils and cowpea (Vigna unguiculata)

Author

Christopher Glover, Bernt Johannessen, Brigid A. McKenna, Enzo Lombi, Peng Wang, Peter M. Kopittke, Peter Kappen, Neal W. Menzies, Wang, Peng, Menzies, Neal W, Lombi, Enzo, McKenna, Brigid A, Johannessen, Bernt, Glover, Chris J, Kappen, Peter, and Kopittke, Peter M

Subjects

inorganic chemicals, media_common.quotation_subject, ZnO nanoparticles, education, chemistry.chemical_element, Zinc, Plant Roots, Vigna, Soil, Environmental Chemistry, Soil Pollutants, Tissue Distribution, Dissolution, Incubation, soils, health care economics and organizations, media_common, biology, Chemistry, zinc, technology, industry, and agriculture, food and beverages, Soil chemistry, Fabaceae, General Chemistry, respiratory system, biology.organism_classification, Speciation, Transformation (genetics), X-Ray Absorption Spectroscopy, Agronomy, Organ Specificity, Environmental chemistry, Soil water, Nanoparticles, Zinc Oxide

Abstract

The increasing use of zinc oxide nanoparticles (ZnO-NPs) in various commercial products is prompting detailed investigation regarding the fate of these materials in the environment. There is, however, a lack of information comparing the transformation of ZnO-NPs with soluble Zn2+in both soils and plants. Synchrotron-based techniques were used to examine the uptake and transformation of Zn in various tissues of cowpea (Vigna unguiculata (L.) Walp.) exposed to ZnO-NPs or ZnCl2 following growth in either solution or soil culture. In solution culture, soluble Zn (ZnCl2) was more toxic than the ZnO-NPs, although there was substantial accumulation of ZnO-NPs on the root surface.When grown in soil, however, there was no significant difference in plant growth and accumulation or speciation of Zn between soluble Zn and ZnO-NP treatments, indicating that the added ZnO-NPs underwent rapid dissolution following their entry into the soil. This was confirmed by an incubation experiment with two soils, in which ZnO-NPs could not be detected after incubation for 1 h. The speciation of Zn was similar in shoot tissues for both soluble Zn and ZnO-NPs treatments and no upward translocation of ZnO-NPs from roots to shoots was observed in either solution or soil culture. Under the current experimental conditions, the similarity in uptake and toxicity of Zn from ZnO-NPs and soluble Zn in soils indicates that the ZnO-NPs used in this study did not constitute nanospecific risks. Refereed/Peer-reviewed

Published

2013

12. Distribution and speciation of Mn in hydrated roots of cowpea at levels inhibiting root growth

Author

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

Subjects

Physiology, media_common.quotation_subject, chemistry.chemical_element, Plant Science, Manganese, Plant Roots, Vigna, Botany, Genetics, Root cap, media_common, biology, Dose-Response Relationship, Drug, Fabaceae, Cell Biology, General Medicine, biology.organism_classification, Speciation, Horticulture, X-Ray Absorption Spectroscopy, chemistry, Microscopy, Fluorescence, Stele, Shoot, Mucigel, Phytotoxicity, Synchrotrons

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 µM 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 µM 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. Refereed/Peer-reviewed

Published

2012