Your search keyword '"Brent N. Kaiser"' showing total 41 results

1. The preceding root system drives the composition and function of the rhizosphere microbiome

Author

Huan Liu, David Coventry, Brent N. Kaiser, Shuheng Gan, Andrew Merchant, Yanli Wei, Matthew D. Denton, Jishun Li, Yayu Wang, David Fuentes, Yi Zhou, and Vadakattu V. S. R. Gupta

Subjects

lcsh:QH426-470, ved/biology.organism_classification_rank.species, Root system, Biology, Plant Roots, Tillage, Soil management, Soil, 03 medical and health sciences, Agricultural system, Terrestrial plant, Botany, Microbiome, Symbiosis, lcsh:QH301-705.5, Soil Microbiology, Triticum, 030304 developmental biology, 2. Zero hunger, 0303 health sciences, Rhizosphere, Soil microbiome, ved/biology, Microbiota, Research, food and beverages, Molecular Sequence Annotation, 04 agricultural and veterinary sciences, 15. Life on land, Crop rotation, Cicer, lcsh:Genetics, Root, lcsh:Biology (General), Metagenomics, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Metagenome, Genes, Microbial

Abstract

Background The soil environment is responsible for sustaining most terrestrial plant life, yet we know surprisingly little about the important functions carried out by diverse microbial communities in soil. Soil microbes that inhabit the channels of decaying root systems, the detritusphere, are likely to be essential for plant growth and health, as these channels are the preferred locations of new root growth. Understanding the microbial metagenome of the detritusphere, and how it responds to agricultural management such as crop rotations and soil tillage, is vital for improving global food production. Results This study establishes an in-depth soil microbial gene catalogue based on the living-decaying rhizosphere niches in a cropping soil. The detritusphere microbiome regulates the composition and function of the rhizosphere microbiome to a greater extent than plant type: rhizosphere microbiomes of wheat and chickpea were homogenous (65–87% similarity) in the presence of decaying root (DR) systems but were heterogeneous (3–24% similarity) where DR was disrupted by tillage. When the microbiomes of the rhizosphere and the detritusphere interact in the presence of DR, there is significant degradation of plant root exudates by the rhizosphere microbiome, and genes associated with membrane transporters, carbohydrate and amino acid metabolism are enriched. Conclusions The study describes the diversity and functional capacity of a high-quality soil microbial metagenome. The results demonstrate the contribution of the detritusphere microbiome in determining the metagenome of developing root systems. Modifications in root microbial function through soil management can ultimately govern plant health, productivity and food security.

Published

2020

2. Maize NPF6 Proteins Are Homologs of Arabidopsis CHL1 That Are Selective for Both Nitrate and Chloride

Author

Kanwarpal S. Dhugga, Zhengyu Wen, Stephen D. Tyerman, Evgenia Ovchinnikova, Brent N. Kaiser, and Julie Dechorgnat

Subjects

0106 biological sciences, 0301 basic medicine, Anion Transport Proteins, Arabidopsis, Plant Science, Zea mays, 01 natural sciences, Chloride, 03 medical and health sciences, chemistry.chemical_compound, Chlorides, Nitrate, Gene Expression Regulation, Plant, medicine, Arabidopsis thaliana, Research Articles, Plant Proteins, Nitrates, biology, Membrane transport protein, Transporter, Cell Biology, biology.organism_classification, Transport protein, 030104 developmental biology, chemistry, Biochemistry, Nitrate transport, biology.protein, 010606 plant biology & botany, medicine.drug

Abstract

Nitrate uptake by plant cells requires both high- and low-affinity transport activities. Arabidopsis thaliana nitrate transporter 1/peptide transporter family (NPF) 6.3 is a dual-affinity plasma membrane transport protein that has both high- and low-affinity functions. At-NPF6.3 imports and senses nitrate and is regulated by phosphorylation at Thr-101 (T101). A detailed functional analysis of two maize (Zea mays) homologs of At-NPF6.3 (Zm-NPF6.6 and Zm-NPF6.4) showed that Zm-NPF6.6 was a pH-dependent nonbiphasic high-affinity nitrate-specific transport protein. By contrast, maize NPF6.4 was a low-affinity nitrate transporter with efflux activity. When supplied chloride, NPF6.4 switched to a high-affinity chloride selective transporter, while NPF6.6 had only a low-affinity chloride transport activity. Structural predictions identified a nitrate binding His (H362) in NPF6.6 but not in NPF6.4. Mutation of NPF6.4 Tyr-370 to His (Y370H) resulted in saturable high-affinity nitrate transport activity and nitrate selectivity. Loss of H362 in NPF6.6 (H362Y) eliminated both nitrate and chloride transport. Furthermore, alterations to Thr-104, a conserved phosphorylation site in NPF6.6, resulted in a similar high-affinity nitrate transport activity with increased Km, whereas equivalent changes in NPF6.4 (T106) disrupted high-affinity chloride transport activity. NPF6 proteins exhibit different substrate specificity in plants and regulate nitrate transport affinity/selectivity using a conserved His residue.

Published

2017

3. Tissue and nitrogen-linked expression profiles of ammonium and nitrate transporters in maize

Author

Julie Dechorgnat, Karen Francis, J. Antony Rafalski, Kanwarpal S. Dhugga, Brent N. Kaiser, and Stephen D. Tyerman

Subjects

0106 biological sciences, 0301 basic medicine, Nitrogen, Anion Transport Proteins, chemistry.chemical_element, Plant Science, Nitrate, 01 natural sciences, Zea mays, 03 medical and health sciences, chemistry.chemical_compound, Gene Expression Regulation, Plant, lcsh:Botany, Arabidopsis, Botany, Gene expression, Ammonium, Gene, Cation Transport Proteins, Plant Proteins, 2. Zero hunger, Maize (Zea mays), biology, Gene Expression Profiling, food and beverages, Nitrate Transporters, 15. Life on land, biology.organism_classification, lcsh:QK1-989, Transporters, 030104 developmental biology, chemistry, Nitrate transport, Transcriptome, 010606 plant biology & botany, Ammonium transport, Research Article

Abstract

Background In order to grow, plants rely on soil nutrients which can vary both spatially and temporally depending on the environment, the soil type or the microbial activity. An essential nutrient is nitrogen, which is mainly accessible as nitrate and ammonium. Many studies have investigated transport genes for these ions in Arabidopsis thaliana and recently in crop species, including Maize, Rice and Barley. However, in most crop species, an understanding of the participants in nitrate and ammonium transport across the soil plant continuum remains undefined. Results We have mapped a non-exhaustive set of putative nitrate and ammonium transporters in maize. The selected transporters were defined based on previous studies comparing nitrate transport pathways conserved between Arabidopsis and Zea mays (Plett D et. al, PLOS ONE 5:e15289, 2010). We also selected genes from published studies (Gu R et. al, Plant and Cell Physiology, 54:1515-1524, 2013, Garnett T et. al, New Phytol 198:82-94, 2013, Garnett T et. al, Frontiers in Plant Sci 6, 2015, Dechorgnat J et. al, Front Plant Sci 9:531, 2018). To analyse these genes, the plants were grown in a semi-hydroponic system to carefully control nitrogen delivery and then harvested at both vegetative and reproductive stages. The expression patterns of 26 putative nitrogen transporters were then tested. Six putative genes were found not expressed in our conditions. Transcripts of 20 other genes were detected at both the vegetative and reproductive stages of maize development. We observed the expression of nitrogen transporters in all organs tested: roots, young leaves, old leaves, silks, cobs, tassels and husk leaves. We also followed the gene expression response to nitrogen starvation and resupply and uncovered mainly three expression patterns: (i) genes unresponsiveness to nitrogen supply; (ii) genes showing an increase of expression after nitrogen starvation; (iii) genes showing a decrease of expression after nitrogen starvation. Conclusions These data allowed the mapping of putative nitrogen transporters in maize at both the vegetative and reproductive stages of development. No growth-dependent expression was seen in our conditions. We found that nitrogen transporter genes were expressed in all the organs tested and in many cases were regulated by the availability of nitrogen supplied to the plant. The gene expression patterns in relation to organ specificity and nitrogen availability denote a speciality of nitrate and ammonium transporter genes and their probable function depending on the plant organ and the environment. Electronic supplementary material The online version of this article (10.1186/s12870-019-1768-0) contains supplementary material, which is available to authorized users.

Published

2019

4. The response of mesophyll conductance to nitrogen and water availability differs between wheat genotypes

Author

Brent N. Kaiser and Margaret M. Barbour

Subjects

0106 biological sciences, 0301 basic medicine, Conservation of Natural Resources, Stomatal conductance, Genotype, Nitrogen, chemistry.chemical_element, Plant Science, Biology, Photosynthesis, 01 natural sciences, Crop, 03 medical and health sciences, chemistry.chemical_compound, Stress, Physiological, Genetics, Water-use efficiency, Triticum, Biomass (ecology), fungi, Water, food and beverages, Conductance, General Medicine, Carbon Dioxide, 030104 developmental biology, chemistry, Agronomy, Plant Stomata, Carbon dioxide, Mesophyll Cells, Agronomy and Crop Science, 010606 plant biology & botany

Abstract

Increased mesophyll conductance (gm) has been suggested as a target for selection for high productivity and high water-use efficiency in crop plants, and genotypic variability in gm has been reported in several important crop species. However, effective selection requires an understanding of how gm varies with growth conditions, to ensure that the ranking of genotypes is consistent across environments. We assessed the genotypic variability in gm and other leaf gas exchange traits, as well as growth and biomass allocation for six wheat genotypes under different water and nitrogen availabilities. The wheat genotypes differed in their response of gm to growth conditions, resulting in genotypic differences in the mesophyll limitation to photosynthesis and a significant increase in the mesophyll limitation to photosynthesis under drought. In this experiment, leaf intrinsic water-use efficiency was more closely related to stomatal conductance than to mesophyll conductance, and stomatal limitation to photosynthesis increased more in some genotypes than in others in response to drought. Screening for gm should be carried out under a range of growth conditions.

Published

2016

5. Unraveling the Functional Role of NPF6 Transporters

Author

Brent N. Kaiser and Zhengyu Wen

Subjects

0106 biological sciences, 0301 basic medicine, Mini Review, Arabidopsis, Plant Science, lcsh:Plant culture, 01 natural sciences, 03 medical and health sciences, chemistry.chemical_compound, Nitrate, Auxin, Arabidopsis thaliana, lcsh:SB1-1110, nitrate transport, chemistry.chemical_classification, biology, Lateral root, Transporter, biology.organism_classification, Transport protein, dual-affinity, 030104 developmental biology, chemistry, Biochemistry, Nitrate transport, NRT1.1, NPF6.3, 010606 plant biology & botany

Abstract

The nitrate transporter 1/peptide transporter (NPF) family represents a growing list of putative nitrate permeable transport proteins expressed within multiple cell types and tissues across a diverse range of plant species. Their designation as nitrate permeable and/or selective transporters is slowly being defined as more genes are characterized and their functional activities tested both in planta and in vitro. The most notable of the NPF family has been the Arabidopsis thaliana homolog, AtNPF6.3, previously known as AtNRT1.1 or CHL1. AtNPF6.3 has traditionally been characterized as a dual-affinity nitrate transporter contributing to root nitrate uptake in Arabidopsis. It has also been identified as a nitrate sensor which regulates the expression of high-affinity nitrate transport proteins NRT2s and lateral root development as a part of the primary nitrate response in plants. The sensor function of AtNPF6.3 has also been attributed to its auxin transport activity. Other homologs of AtNPF6.3 are now being described highlighting the variability in their functional capabilities (alternative substrates and kinetics) linking to structural aspects of the proteins. This review focusses on NPF6.3-like transport proteins and the knowledge that has been gained since their initial discovery over two decades ago. The review will investigate from a structural point of view how NPF6.3-like proteins may transport nitrate as well as other ions and what can be learned from structural uniqueness about predicted activities in plants.

Published

2018

6. <scp>VAMP</scp>721a and<scp>VAMP</scp>721d are important for pectin dynamics and release of bacteria in soybean nodules

Author

David Chiasson, Aleksandr Gavrin, Ton Bisseling, Brent N. Kaiser, Evgenia Ovchinnikova, and Elena Fedorova

Subjects

0106 biological sciences, 0301 basic medicine, food.ingredient, Root nodule, Pectin, Physiology, Plant Science, 01 natural sciences, Exocytosis, Rhizobia, Legume-rhizobia symbiosis, Cell wall, 03 medical and health sciences, food, Laboratorium voor Moleculaire Biologie, Gene Silencing, Plant cell wall, Cellulose, Symbiosis, Plant Proteins, Polysaccharide-Lyases, Esterification, Endosymbiosis, biology, food and beverages, biology.organism_classification, Medicago truncatula, Protein Transport, Intracellular infection, 030104 developmental biology, Biochemistry, Pectate lyase, Pectins, Rhizobium, Soybeans, Laboratory of Molecular Biology, EPS, Root Nodules, Plant, Soybean, Bacteria, 010606 plant biology & botany

Abstract

In root nodules rhizobia enter host cells via infection threads. The release of bacteria to a host cell is possible from cell wall-free regions of the infection thread. We hypothesized that the VAMP721d and VAMP721e exocytotic pathway, identified before in Medicago truncatula, has a role in the local modification of cell wall during the release of rhizobia. To clarify the role of VAMP721d and VAMP721e we used Glycine max, a plant with a determinate type of nodule. The localization of the main polysaccharide compounds of primary cell walls was analysed in control vs nodules with partially silenced GmVAMP721d. The silencing of GmVAMP721d blocked the release of rhizobia. Instead of rhizobia-containing membrane compartments - symbiosomes - the infected cells contained big clusters of bacteria embedded in a matrix of methyl-esterified and de-methyl-esterified pectin. These clusters were surrounded by a membrane. We found that GmVAMP721d-positive vesicles were not transporting methyl-esterified pectin. We hypothesized that they may deliver the enzymes involved in pectin turnover. Subsequently, we found that GmVAMP721d is partly co-localized with pectate lyase. Therefore, the biological role of VAMP721d may be explained by its action in delivering pectin-modifying enzymes to the site of release.

Published

2016

7. A Comparison of Petiole Hydraulics and Aquaporin Expression in an Anisohydric and Isohydric Cultivar of Grapevine in Response to Water-Stress Induced Cavitation

Author

Stephen D. Tyerman, Rebecca K. Vandeleur, Megan C. Shelden, and Brent N. Kaiser

Subjects

0106 biological sciences, 0301 basic medicine, Stomatal conductance, Vine, anisohydric, isohydric, Aquaporin, Plant Science, Biology, lcsh:Plant culture, 01 natural sciences, Petiole (botany), 03 medical and health sciences, cavitation, Botany, lcsh:SB1-1110, Cultivar, water-stress, Original Research, Transpiration, Xylem, food and beverages, petiole, aquaporin, 030104 developmental biology, Cavitation, hydraulic conductivity, xylem embolism, 010606 plant biology & botany

Abstract

We report physiological, anatomical and molecular differences in two economically important grapevine (Vitis vinifera L.) cultivars cv. Grenache (near-isohydric) and Chardonnay (anisohydric) in their response to water-stress induced cavitation. The aim of the study was to compare organ vulnerability (petiole and stem) to cavitation by measuring ultrasonic acoustic emissions (UAE) and percent loss of conductance of potted grapevines subject to the onset of water-stress. Leaf (ψL) and stem water potential (ψS), stomatal conductance (gs), transpiration (E), petiole hydraulics (KPet), and xylem diameter were also measured. Chardonnay displayed hydraulic segmentation based on UAE, with cavitation occurring at a less negative ψL in the petiole than in the stem. Vulnerability segmentation was not observed in Grenache, with both petioles and stems equally vulnerable to cavitation. Leaf water potential that induced 50% of maximum UAE was significantly different between petioles and stems in Chardonnay (ψ50Petiole = -1.14 and ψ50Stem = -2.24 MPa) but not in Grenache (ψ50Petiole = -0.73 and ψ50Stem = -0.78 MPa). Grenache stems appeared more susceptible to water-stress induced cavitation than Chardonnay stems. Grenache displayed (on average) a higher KPet likely due to the presence of larger xylem vessels. A close relationship between petiole hydraulic properties and vine water status was observed in Chardonnay but not in Grenache. Transcriptional analysis of aquaporins in the petioles and leaves (VvPIP1;1, VvPIP2;1, VvPIP2;2 VvPIP2;3, VvTIP1;1, and VvTIP2;1) showed differential regulation diurnally and in response to water-stress. VvPIP2;1 showed strong diurnal regulation in the petioles and leaves of both cultivars with expression highest predawn. Expression of VvPIP2;1 and VvPIP2;2 responded to ψL and ψS in both cultivars indicating the expression of these two genes are closely linked to vine water status. Expression of several aquaporin genes correlated with gas exchange measurements, however, these genes differed between cultivars. In summary, the data shows two contrasting responses in petiole hydraulics and aquaporin expression between the near-isohydric cultivar, Grenache and anisohydric cultivar, Chardonnay.

Published

2017

8. Effect of N supply on the carbon economy of barley when accounting for plant size

Author

A. Harvey Millar, Brent N. Kaiser, Owen K. Atkin, Buddhima C. Kariyawasam, John R. Evans, and Ana Clarissa Alves Negrini

Subjects

Specific leaf area, Nitrogen, Leaf mass, fungi, food and beverages, chemistry.chemical_element, Hordeum, Plant Science, Biology, Carbon, Plant Leaves, chemistry.chemical_compound, Animal science, Nitrate, chemistry, Relative growth rate, Root mass, Biomass, Hordeum vulgare, Agronomy and Crop Science

Abstract

Nitrogen availability and ontogeny both affect the relative growth rate (RGR) of plants. In this study of barley (Hordeum vulgare L.) we determined which growth parameters are affected by nitrate (N) availability, and whether these were confounded by differences in plant size, reflecting differences in growth. Plants were hydroponically grown on six different nitrate (N) concentrations for 28 days, and nine harvests were performed to assess the effect of N on growth parameters. Most growth parameters showed similar patterns of responses to N supply whether compared at common time points or common plant sizes. N had a significant effect on the biomass allocation: increasing N increased leaf mass ratio (LMR) and decreased root mass ratio (RMR). Specific leaf area (SLA) was not significantly affected by N. RGR increased with increasing N supply up to 1 mM, associated with increases in both LMR and net assimilation rate (NAR). Increases in N supply above 1 mM did not increase RGR as increases in LMR were offset by decreases in NAR. The high RGR at suboptimal N supply suggest a higher nitrogen use efficiency (biomass/N supply). The reasons for the homeostasis of growth under suboptimal N levels are discussed.

Published

2020

9. Adjustment of Host Cells for Accommodation of Symbiotic Bacteria: Vacuole Defunctionalization, HOPS Suppression, and TIP1g Retargeting in Medicago

Author

Zhengyu Wen, Elena Fedorova, Dietmar Geiger, Brent N. Kaiser, Ton Bisseling, Aleksandr Gavrin, and Stephen D. Tyerman

Subjects

legume symbiosis, 0106 biological sciences, osmotic-stress, Plant Science, Vacuole, 01 natural sciences, Cell membrane, Gene Expression Regulation, Plant, major intrinsic proteins, aquaporins, pea root-nodules, Research Articles, Plant Proteins, 2. Zero hunger, 0303 health sciences, EPS-1, food and beverages, Hydrogen-Ion Concentration, Plants, Genetically Modified, Medicago truncatula, Cell biology, Protein Transport, medicine.anatomical_structure, RNA Interference, Laboratory of Molecular Biology, Root Nodules, Plant, h+-atpase, Symbiotic bacteria, n-2-fixing symbiosomes, Aquaporin, Biology, 03 medical and health sciences, Nitrogen Fixation, Organelle, medicine, Laboratorium voor Moleculaire Biologie, Symbiosis, 030304 developmental biology, Staining and Labeling, Cell Membrane, endoplasmic-reticulum, Cell Biology, ph homeostasis, biochemical phenomena, metabolism, and nutrition, Plant cell, biology.organism_classification, arabidopsis, Symbiosome, Multiprotein Complexes, Vacuoles, Acids, Biomarkers, 010606 plant biology & botany

Abstract

In legume–rhizobia symbioses, the bacteria in infected cells are enclosed in a plant membrane, forming organelle-like compartments called symbiosomes. Symbiosomes remain as individual units and avoid fusion with lytic vacuoles of host cells. We observed changes in the vacuole volume of infected cells and thus hypothesized that microsymbionts may cause modifications in vacuole formation or function. To examine this, we quantified the volumes and surface areas of plant cells, vacuoles, and symbiosomes in root nodules of Medicago truncatula and analyzed the expression and localization of VPS11 and VPS39, members of the HOPS vacuole-tethering complex. During the maturation of symbiosomes to become N2-fixing organelles, a developmental switch occurs and changes in vacuole features are induced. For example, we found that expression of VPS11 and VPS39 in infected cells is suppressed and host cell vacuoles contract, permitting the expansion of symbiosomes. Trafficking of tonoplast-targeted proteins in infected symbiotic cells is also altered, as shown by retargeting of the aquaporin TIP1g from the tonoplast membrane to the symbiosome membrane. This retargeting appears to be essential for the maturation of symbiosomes. We propose that these alterations in the function of the vacuole are key events in the adaptation of the plant cell to host intracellular symbiotic bacteria.

Published

2014

10. Soybean SAT1 ( Symbiotic Ammonium Transporter 1 ) encodes a bHLH transcription factor involved in nodule growth and NH 4 + transport

Author

David A. Day, Mamoru Okamoto, Patrick C. Loughlin, Elena Fedorova, Brent N. Kaiser, Anthony D. M. Glass, Ton Bisseling, Stephen D. Tyerman, David Chiasson, Manijeh Mohammadi-Dehcheshmeh, Sally E. Smith, Elizabeth H. McLean, and Danielle Mazurkiewicz

Subjects

lotus-japonicus, Root nodule, DNA, Plant, domain, Saccharomyces cerevisiae, arabidopsis-thaliana, er stress, Biology, chemistry.chemical_compound, Gene Expression Regulation, Plant, Ammonium Compounds, circadian clock, expression, Laboratorium voor Moleculaire Biologie, Ammonium, gene, Cation Transport Proteins, membrane, Cell wall modification, Transcription factor, Multidisciplinary, EPS-1, Basic Helix-Loop-Helix Leucine Zipper Transcription Factors, fungi, Cell Membrane, food and beverages, Biological Transport, Biological Sciences, biology.organism_classification, Transport protein, Symbiosome, Biochemistry, chemistry, Soybean Proteins, stress-response, Soybeans, Laboratory of Molecular Biology, Root Nodules, Plant, protein, Protein Binding

Abstract

Glycine max symbiotic ammonium transporter 1 was first documented as a putative ammonium (NH4(+)) channel localized to the symbiosome membrane of soybean root nodules. We show that Glycine max symbiotic ammonium transporter 1 is actually a membrane-localized basic helix-loop-helix (bHLH) DNA-binding transcription factor now renamed Glycine max bHLH membrane 1 (GmbHLHm1). In yeast, GmbHLHm1 enters the nucleus and transcriptionally activates a unique plasma membrane NH4(+) channel Saccharomyces cerevisiae ammonium facilitator 1. Ammonium facilitator 1 homologs are present in soybean and other plant species, where they often share chromosomal microsynteny with bHLHm1 loci. GmbHLHm1 is important to the soybean rhizobium symbiosis because loss of activity results in a reduction of nodule fitness and growth. Transcriptional changes in nodules highlight downstream signaling pathways involving circadian clock regulation, nutrient transport, hormone signaling, and cell wall modification. Collectively, these results show that GmbHLHm1 influences nodule development and activity and is linked to a novel mechanism for NH4(+) transport common to both yeast and plants.

Published

2014

11. A novel method based on combination of semi-in vitro and in vivo conditions in Agrobacterium rhizogenes-mediated hairy root transformation of Glycine species

Author

Brent N. Kaiser, Stephen D. Tyerman, Manijeh Mohammadi-Dehcheshmeh, and Esmaeil Ebrahimie

Subjects

Transformation (genetics), Tissue culture, Reporter gene, biology, Micropropagation, Agrobacterium, Botany, Rhizobium, Plant Science, biology.organism_classification, Developmental biology, Biotechnology, Transformation efficiency

Abstract

Despite numerous advantages of the many tissue culture-independent hairy root transformation protocols, the process is often compromised in the initial in vitro culture stage where inability to maintain high humidity and the delivery of nourishing culture medium decrease cellular morphogenesis and organ formation efficiency. Ultimately, this influences the effective transfer of produced plantlets during transfer from in vitro to in vivo conditions, where low survival rates occur during the acclimation period. We have developed an intermediate protocol for Agrobacterium rhizogenes transformation in Glycine species by combining a two-step in vitro and in vivo process that greatly enhances the efficiency of hairy root formation and which simplifies the maintenance of the transformed roots. In this protocol, cotyledonary nodes of Glycine max and Glycine canescens seedlings were infected by A. rhizogenes K599 carrying a reporter gene construct constitutively expressing green fluorescent protein (GFP). Glass containers containing sand and nutrient solution were employed to provide a moist clean microenvironment for the generation of hairy roots from inoculated seedlings. Transgenic roots were then noninvasively identified from nontransgenic roots based on the detection of GFP. Main roots and nontransgenic roots were removed leaving transgenic hairy roots to support seedling development, all within 1 mo of beginning the experiment. Overall, this protocol increased the transformation efficiency by more than twofold over traditional methods. Approximately 88% and 100% of infected plants developed hairy roots from G. max and G. canescens, respectively. On average, each infected plant produced 10.9 transformed hairy roots in G. max and 13–20 in G. canescens. Introduction of this simple protocol is a significant advance that eliminates the long and genotype-dependent tissue culture procedure while taking advantage of its optimum in vitro qualities to enhance the micropropagation rate. This research will support the increasing use of transient transgenic hairy roots for the study of plant root biology and symbiotic interactions with Rhizobium spp.

Published

2013

12. Rapid shoot-to-root signalling regulates root hydraulic conductance via aquaporins

Author

Rebecca K. Vandeleur, Matthew Gilliham, Asmini Athman, Charlotte Jordans, Brent N. Kaiser, Stephen D. Tyerman, and Wendy Sullivan

Subjects

Physiology, fungi, Turgor pressure, food and beverages, Aquaporin, Plant Science, Topping, Biology, Cortex (botany), Horticulture, Dry weight, Shoot, Botany, Shading, Half time

Abstract

We investigated how root hydraulic conductance (normalized to root dry weight, Lo ) is regulated by the shoot. Shoot topping (about 30% reduction in leaf area) reduced Lo of grapevine (Vitis vinifera L.), soybean (Glycine max L.) and maize (Zea mays L.) by 50 to 60%. More detailed investigations with soybean and grapevine showed that the reduction in Lo was not correlated with the reduction in leaf area, and shading or cutting single leaves had a similar effect. Percentage reduction in Lo was largest when initial Lo was high in soybean. Inhibition of Lo by weak acid (low pH) was smaller after shoot damage or leaf shading. The half time of reduction in Lo was approximately 5 min after total shoot decapitation. These characteristics indicate involvement of aquaporins. We excluded phloem-borne signals and auxin-mediated signals. Xylem-mediated hydraulic signals are possible since turgor rapidly decreased within root cortex cells after shoot topping. There was a significant reduction in the expression of several aquaporins in the plasma membrane intrinsic protein (PIP) family of both grapevine and soybean. In soybean, there was a five- to 10-fold reduction in GmPIP1;6 expression over 0.5-1 h which was sustained over the period of reduced Lo .

Published

2013

13. Chloride transport and compartmentation within main and lateral roots of two grapevine rootstocks differing in salt tolerance

Author

Nasser Abbaspour, Stephen D. Tyerman, and Brent N. Kaiser

Subjects

Ecology, Physiology, Lateral root, Plant physiology, Xylem, Forestry, Plant Science, Biology, Chloride, Salinity, Horticulture, Shoot, Botany, medicine, Efflux, Rootstock, medicine.drug

Abstract

Root Cl− transport was investigated using 36Cl− flux analysis in two grapevine (Vitis sp.) rootstock hybrids differing in salt tolerance; 1103 Paulsen (salt-tolerant) and K 51–40 (salt sensitive). Initial 36Cl− influx to the root was greater in Paulsen than K 51–40. This flux, attributed to the Cl− influx to the cytoplasm (Φ oc) increased with increasing external concentrations of Cl− for plants adapted to growth in 30 mM NaCl. The concentration kinetics in this high concentration range could be fit to a Michaeils–Menton equation. There was no significant difference between genotypes in Km (28.68 ± 15.76 and 24.27 ± 18.51 mM for Paulsen and K 51–40, respectively), but Paulsen had greater V max (0.127 ± 0.042) compared to K 51–40 (0.059 ± 0.026 μm g−1 FW min−1). In Paulsen, the main root had greater contribution to 36Cl− uptake than lateral roots, there being no significant difference in lateral root influx between the genotypes. 36Cl− transport to the shoot of K 51–40 was greater than for Paulsen. It was estimated that efflux rate from the xylem parenchyma cells to the xylem vessels (Φ cx) in K 51–40 was twice that of Paulsen. Compartmental analysis from 36Cl− efflux kinetics confirmed the larger Φ oc and the higher ratio of main to lateral root Φ oc for Paulsen. Efflux from the cytoplasm (Φ co) was higher than 95 % of Φ oc indicating a high degree of cycling across the plasma membrane in roots at these high external Cl− concentrations. Paulsen appears to keep the cytoplasmic Cl− concentration in roots lower than K 51–40 via greater efflux to the vacuole and to the outside medium. The difference in salt tolerance between the genotypes can be attributed to different Cl− transport properties at the plasma membrane and tonoplast and particularly in Cl− efflux to the xylem.

Published

2013

14. Nitrate transport capacity of the Arabidopsis thaliana NRT2 family members and their interactions with AtNAR2.1

Author

Zorica Kotur, Nenah Mackenzie, Stephen D. Tyerman, Brent N. Kaiser, Anthony D. M. Glass, and Sunita A. Ramesh

Subjects

Physiology, Recombinant Fusion Proteins, Xenopus, Nitrogen assimilation, Anion Transport Proteins, Arabidopsis, Plant Science, Plant Roots, RNA, Complementary, chemistry.chemical_compound, Bimolecular fluorescence complementation, Nitrate, Two-Hybrid System Techniques, Protein Interaction Mapping, Animals, Arabidopsis thaliana, Nitrates, Nitrogen Isotopes, biology, Arabidopsis Proteins, Protoplasts, Biological Transport, biology.organism_classification, Yeast, Plant Leaves, chemistry, Biochemistry, RNA, Plant, Nitrate transport, Mutation, Oocytes

Abstract

• Interactions between the Arabidopsis NitRate Transporter (AtNRT2.1) and Nitrate Assimilation Related protein (AtNAR2.1, also known as AtNRT3.1) have been well documented, and confirmed by the demonstration that AtNRT2.1 and AtNAR2.1 form a 150-kDa plasma membrane complex, thought to constitute the high-affinity nitrate transporter of Arabidopsis thaliana roots. Here, we have investigated interactions between the remaining AtNRT2 family members (AtNRT2.2 to AtNRT2.7) and AtNAR2.1, and their capacity for nitrate transport. • Three different systems were used to examine possible interactions with AtNAR2.1: membrane yeast split-ubiquitin, bimolecular fluorescence complementation in A. thaliana protoplasts and nitrate uptake in Xenopus oocytes. • All NRT2s, except for AtNRT2.7, restored growth and β-galactosidase activity in the yeast split-ubiquitin system, and split-YFP fluorescence in A. thaliana protoplasts only when co-expressed with AtNAR2.1. Thus, except for AtNRT2.7, all other NRT2 transporters interact strongly with AtNAR2.1. • Co-injection into Xenopus oocytes of cRNA of all NRT2 genes together with cRNA of AtNAR2.1 resulted in statistically significant increases of uptake over and above that resulting from single cRNA injections.

Published

2012

15. Sexual compatibility and floral biology of some olive cultivars

Author

Jenny Guerin, Esmaeil Seifi, Brent N. Kaiser, and Margaret Sedgley

Subjects

Gynoecium, biology, Horticulture, biology.organism_classification, medicine.disease_cause, Inflorescence, Olea, Pollen, Botany, Shoot, medicine, Pollen tube, Cultivar, Agronomy and Crop Science, Hand-pollination

Abstract

Pollen tube observation was used to assess the self- and cross-incompatibility of the olive (Olea europaea L.) cultivars ‘Frantoio’, ‘Koroneiki’ and ‘Kalamata’. The pistils were harvested 1 week after hand pollination and stained with 0.1% aniline blue. The styles and ovules were separated, mounted in 80% glycerol and observed under a fluorescence microscope. All the cultivars studied were self-incompatible. ‘Frantoio’ (as a host) was incompatible with ‘Koroneiki’ and ‘Barnea’ but partially compatible with ‘Mission’. ‘Koroneiki’ (as a host) was incompatible with ‘Barnea’ but partially compatible with ‘Frantoio’ and ‘Mission’. ‘Kalamata’ (as a host) was compatible with ‘Barnea’, incompatible with ‘Mission’ and ‘Koroneiki’ in 2004, but partially compatible with them in 2005. The effects of shoot orientation and inflorescence location on inflorescence characteristics were also studied. For each cultivar, inflorescence characteristics in three sections of shoots (top, middle and base) and four sides ...

Published

2011

16. Magnesium transporters, MGT2/MRS2‐1 and MGT3/MRS2‐5, are important for magnesium partitioning within Arabidopsis thaliana mesophyll vacuoles

Author

Vanessa M. Conn, Roger Allen Leigh, Brent N. Kaiser, Matthew Gilliham, Simon J. Conn, Stephen D. Tyerman, Conn, Simon J, Conn, Vanessa, Tyerman, Stephen D, Kaiser, Brent N, Leigh, Roger A, and Gilliham, Matthew

Subjects

Chlorophyll, DNA, Bacterial, Time Factors, single cell sampling, Physiology, Mutant, Arabidopsis, chemistry.chemical_element, Plant Science, Vacuole, Genes, Plant, Gene Expression Regulation, Plant, Arabidopsis thaliana, Magnesium, Cation Transport Proteins, Gene, biology, Arabidopsis Proteins, Protoplasts, Osmolar Concentration, Mutagenesis, Biological Transport, Transporter, biology.organism_classification, tonoplast, Mutagenesis, Insertional, arabidopsis, magnesium transport, Biochemistry, chemistry, MGT/MRS2, Vacuoles, Mesophyll Cells, Subcellular Fractions

Abstract

Magnesium accumulates at high concentrations in dicotyledonous leaves but it is not known in which leaf cell types it accumulates, by what mechanism this occurs and the role it plays when stored in the vacuoles of these cell types. Cell-specific vacuolar elemental profiles from Arabidopsis thaliana (Arabidopsis) leaves were analysed by X-ray microanalysis under standard and serpentine hydroponic growth conditions and correlated with the cell-specific complement of magnesium transporters identified through microarray analysis and quantitative polymerase chain reaction (qPCR). Mesophyll cells accumulate the highest vacuolar concentration of magnesium in Arabidopsis leaves and are enriched for members of the MGT/MRS2 family of magnesium transporters. Specifically, AtMGT2/AtMRS2-1 and AtMGT3/AtMRS2-5 were shown to be targeted to the tonoplast and corresponding T-DNA insertion lines had perturbed mesophyll-specific vacuolar magnesium accumulation under serpentine conditions. Furthermore, transcript abundance of these genes was correlated with the accumulation of magnesium under serpentine conditions, in a low calcium-accumulating mutant and across 23 Arabidopsis ecotypes varying in their leaf magnesium concentrations. We implicate magnesium as a key osmoticum required to maintain growth in low calcium concentrations in Arabidopsis. Furthermore, two tonoplast-targeted members of the MGT/MRS2 family are shown to contribute to this mechanism under serpentine conditions. Refereed/Peer-reviewed

Published

2011

17. Inflorescence architecture of olive

Author

Jenny Guerin, Esmaeil Seifi, Brent N. Kaiser, and Margaret Sedgley

Subjects

Gynoecium, Horticulture, Inflorescence, Raceme, Oleaceae, Botany, Stamen, Floral biology, Petal, Cultivar, Biology, biology.organism_classification

Abstract

The influence of flower position on the inflorescence on opening day, gender, and petal persistence was studied in three olive cultivars: Manzanillo, Mission, and Frantoio. In each cultivar, 45 inflorescences were checked every morning from flower opening to petal fall. Perfect flowers opened mainly in the beginning of the flower opening period, and staminate flowers opened later. Flower position on the inflorescence had a highly significant effect on the opening day in all cultivars. Terminal flowers and the flowers located on the primary branches opened earlier than the flowers located on the secondary branches. Flower position had also a highly significant effect on gender in Manzanillo and Mission. In Manzanillo, the secondary branches had fewer perfect flowers than the primary branches. In Mission, the secondary branches had no perfect flowers at all. Among the primary branches, the branch arising immediately next to the terminal flower had the latest flowers to open and the lowest percent of perfect flowers. In Manzanillo, perfect flowers had significantly longer petal persistence than staminate flowers. To study flower competition within the inflorescence, the distal half of 120 inflorescences, on which the flowers tend to be perfect, in three trees of Manzanillo were removed about 1 month before full bloom. There was a highly significant effect on the percent of perfect flowers that opened on the proximal half. Flower competition may be a reason for pistil abortion in flowers located on secondary branches.

Published

2008

18. Maize maintains growth in response to decreased nitrate supply through a highly dynamic and developmental stage-specific transcriptional response

Author

Luke R. Holtham, Mark Tester, Brent N. Kaiser, John Toubia, Darren Plett, Mary Beatty, Trevor Garnett, Elena Kalashyan, Ute Baumann, Andreas W. Schreiber, John Nau, Antoni Rafalski, Kanwarpal S. Dhugga, Plett, Darren, Baumann, Ute, Schreiber, Andreas W, Holtham, Luke, Kalashyan, Elena, Toubia, John, Nau, John, Beatty, Mary, Rafalski, Antoni, Dhugga, Kanwarpal S, Tester, Mark, Garnett, Trevor, and Kaiser, Brent N

Subjects

0106 biological sciences, 0301 basic medicine, Candidate gene, Time Factors, Transcription, Genetic, Microarray, Gene regulatory network, Plant Science, Biology, Zea mays, 01 natural sciences, Transcriptome, 03 medical and health sciences, Gene Expression Regulation, Plant, Transcription (biology), Gene expression, lipid metabolism, Cluster Analysis, Gene Regulatory Networks, RNA, Messenger, Gene, Oligonucleotide Array Sequence Analysis, Genetics, Nitrates, Gene Expression Profiling, Gene Expression Regulation, Developmental, Lipid metabolism, gene cluster analysis, Gene Ontology, 030104 developmental biology, Agronomy and Crop Science, microarray, 010606 plant biology & botany, Biotechnology

Abstract

Refereed/Peer-reviewed Elucidation of the gene networks underlying the response to N supply and demand will facilitate the improvement of the N uptake efficiency of plants. We undertook a transcriptomic analysis of maize to identify genes responding to both a non-growth-limiting decrease in NO3- provision and to development-based N demand changes at seven representative points across the life cycle. Gene co-expression networks were derived by cluster analysis of the transcript profiles. The majority of NO3--responsive transcription occurred at 11 (D11), 18 (D18) and 29 (D29) days after emergence, with differential expression predominating in the root at D11 and D29 and in the leaf at D18. A cluster of 98 probe sets was identified, the expression pattern of which is similar to that of the high-affinity NO3- transporter (NRT2) genes across the life cycle. The cluster is enriched with genes encoding enzymes and proteins of lipid metabolism and transport, respectively. These are candidate genes for the response of maize to N supply and demand. Only a few patterns of differential gene expression were observed over the entire life cycle; however, the composition of the classes of the genes differentially regulated at individual time points was unique, suggesting tightly controlled regulation of NO3--responsive gene expression. usc

Published

2016

19. Improved methods in Agrobacterium–mediated transformation of almond using positive (mannose/pmi) or negative (kanamycin resistance) selection-based protocols

Author

Brent N. Kaiser, Margaret Sedgley, Sunita A. Ramesh, Graham Collins, and Tricia K. Franks

Subjects

Kanamycin Resistance, DNA, Plant, Agrobacterium, Mannose, Plant Science, Plant Roots, Polymerase Chain Reaction, chemistry.chemical_compound, Negative selection, Transformation, Genetic, medicine, Regeneration, Southern blot, Genetics, biology, fungi, food and beverages, Kanamycin, General Medicine, Plants, Genetically Modified, biology.organism_classification, Molecular biology, Plant Leaves, Blotting, Southern, Transformation (genetics), chemistry, Agrobacterium tumefaciens, Prunus, Agronomy and Crop Science, Plant Shoots, Transformation efficiency, medicine.drug

Abstract

A protocol for Agrobacterium-mediated transformation with either kanamycin or mannose selection was developed for leaf explants of the cultivar Prunus dulcis cv. Ne Plus Ultra. Regenerating shoots were selected on medium containing 15 muM kanamycin (negative selection), while in the positive selection strategy, shoots were selected on 2.5 g/l mannose supplemented with 15 g/l sucrose. Transformation efficiencies based on PCR analysis of individual putative transformed shoots from independent lines relative to the initial numbers of leaf explants tested were 5.6% for kanamycin/nptII and 6.8% for mannose/pmi selection, respectively. Southern blot analysis on six randomly chosen PCR-positive shoots confirmed the presence of the nptII transgene in each, and five randomly chosen lines identified to contain the pmi transgene by PCR showed positive hybridisation to a pmi DNA probe. The positive (mannose/pmi) and the negative (kanamycin) selection protocols used in this study have greatly improved transformation efficiency in almond, which were confirmed with PCR and Southern blot. This study also demonstrates that in almond the mannose/pmi selection protocol is appropriate and can result in higher transformation efficiencies over that of kanamycin/nptII selection protocols.

Published

2006

20. AN INTEGRATED GENETIC LINKAGE MAP FOR ALMOND BASED ON RAPD, ISSR, SSR AND MORPHOLOGICAL MARKERS

Author

Brent N. Kaiser, Graham Collins, M. Sedgley, Pere Arús, D. Gregory, and Michelle Wirthensohn

Subjects

Genetics, Prunus dulcis, Gene mapping, Microsatellite, Genetic linkage map, Horticulture, Biology, RAPD

Published

2005

21. The Role of Molybdenum in Agricultural Plant Production

Author

Brent N. Kaiser, Joanne Ngaire Brady, Stephen D. Tyerman, Kate L. Gridley, and Thomas Phillips

Subjects

Crops, Agricultural, inorganic chemicals, chemistry.chemical_element, Plant Science, Molybdate, Biology, Nitrate reductase, chemistry.chemical_compound, Nutrient, Sulfite oxidase, medicine, Invited Reviews, Molybdenum, Molybdenum deficiency, fungi, food and beverages, Agriculture, Biological Transport, medicine.disease, Sulfate transport, enzymes and coenzymes (carbohydrates), chemistry, Biochemistry, bacteria, Carrier Proteins, Plant nutrition

Abstract

• Background The importance of molybdenum for plant growth is disproportionate with respect to the absolute amounts required by most plants. Apart from Cu, Mo is the least abundant essential micronutrient found in most plant tissues and is often set as the base from which all other nutrients are compared and measured. Molybdenum is utilized by selected enzymes to carry out redox reactions. Enzymes that require molybdenum for activity include nitrate reductase, xanthine dehydrogenase, aldehyde oxidase and sulfite oxidase. • Scope Loss of Mo-dependent enzyme activity (directly or indirectly through low internal molybdenum levels) impacts upon plant development, in particular, those processes involving nitrogen metabolism and the synthesis of the phytohormones abscisic acid and indole-3 butyric acid. Currently, there is little information on how plants access molybdate from the soil solution and redistribute it within the plant. In this review, the role of molybdenum in plants is discussed, focusing on its current constraints in some agricultural situations and where increased molybdenum nutrition may aid in agricultural plant development and yields. • Conclusions Molybdenum deficiencies are considered rare in most agricultural cropping areas; however, the phenotype is often misdiagnosed and attributed to other downstream effects associated with its role in various enzymatic redox reactions. Molybdenum fertilization through foliar sprays can effectively supplement internal molybdenum deficiencies and rescue the activity of molybdoenzymes. The current understanding on how plants access molybdate from the soil solution or later redistribute it once in the plant is still unclear; however, plants have similar physiological molybdenum transport phenotypes to those found in prokaryotic systems. Thus, careful analysis of existing prokaryotic molybdate transport mechanisms, as well as a re-examination of know anion transport mechanisms present in plants, will help to resolve how this important trace element is accumulated.

Published

2005

22. Variation for N uptake system in maize: genotypic response to N supply

Author

Trevor Garnett, Vanessa M. Conn, Darren Plett, Kanwarpal S. Dhugga, J. Antoni Rafalski, Mark Tester, Huwaida Rabie, Simon J. Conn, Brent N. Kaiser, Garnett, Trevor, Plett, Darren, Conn, Vanessa, Conn, Simon, Rabie, Huwaida, Rafalski, J Antoni, Dhugga, Kanwarpal, Tester, Mark A, and Kaiser, Brent N

Subjects

inorganic chemicals, Nitrogen, Biomass, chemistry.chemical_element, Plant Science, transporters, Biology, lcsh:Plant culture, Zea mays, nitrogen use efficiency, zea mays, chemistry.chemical_compound, NUE, Animal science, Nitrate, nitrate, Genotype, Ammonium, lcsh:SB1-1110, Original Research, food and beverages, Hydroponics, Maize, ammonium, Agronomy, chemistry, uptake, Shoot

Abstract

An understanding of the adaptations made by plants in their nitrogen (N) uptake systems in response to reduced N supply is important to the development of cereals with enhanced N uptake efficiency (NUpE). Twenty seven diverse genotypes of maize (Zea mays, L.) were grown in hydroponics for 3 weeks with limiting or adequate N supply. Genotypic response to N was assessed on the basis of biomass characteristics and the activities of the nitrate ([Formula: see text]) and ammonium ([Formula: see text]) high-affinity transport systems. Genotypes differed greatly for the ability to maintain biomass with reduced N. Although, the N response in underlying biomass and N transport related characteristics was less than that for biomass, there were clear relationships, most importantly, lines that maintained biomass at reduced N maintained net N uptake with no change in size of the root relative to the shoot. The root uptake capacity for both [Formula: see text] and [Formula: see text] increased with reduced N. Transcript levels of putative [Formula: see text] and [Formula: see text] transporter genes in the root tissue of a subset of the genotypes revealed that predominately ZmNRT2 transcript levels responded to N treatments. The correlation between the ratio of transcripts of ZmNRT2.2 between the two N levels and a genotype's ability to maintain biomass with reduced N suggests a role for these transporters in enhancing NUpE. The observed variation in the ability to capture N at low N provides scope for both improving NUpE in maize and also to better understand the N uptake system in cereals.

Published

2015

23. Functional Analysis of an Arabidopsis T-DNA 'Knockout' of the High-Affinity NH4+ Transporter AtAMT1;1

Author

Anthony D. M. Glass, Brent N. Kaiser, Suman Rawat, M. Yaeesh Siddiqi, and Josette Masle

Subjects

inorganic chemicals, Messenger RNA, Physiology, Mutant, Wild type, food and beverages, Transporter, Plant Science, Biology, biology.organism_classification, Molecular biology, Yeast, Arabidopsis, Botany, Genetics, Gene, Bacteria

Abstract

NH4 acquisition by plant roots is thought to involve members of the NH4 transporter family (AMT) found in plants, yeast, bacteria, and mammals. In Arabidopsis, there are six AMT genes of which AtAMT1;1 demonstrates the highest affinity for NH4 . Ammonium influx into roots and AtAMT1;1 mRNA expression levels are highly correlated diurnally and when plant nitrogen (N) status is varied. To further investigate the involvement of AtAMT1;1 in high-affinity NH4 influx, we identified a homozygous T-DNA mutant with disrupted AtAMT1;1 activity. Contrary to expectation, high-affinity 13 NH4 influx in the amt1;1:T-DNA mutant was similar to the wild type when grown with adequate N. Removal of N to increase AtAMT1;1 expression decreased high-affinity 13 NH4 influx in the mutant by 30% compared with wild-type plants, whereas lowaffinity 13 NH4 influx (250 m–10 mm NH4 ) exceeded that of wild-type plants. In these N-deprived plants, mRNA copy numbers of root AtAMT1;3 and AtAMT2;1 mRNA were significantly more increased in the mutant than in wild-type plants. Under most growth conditions, amt1;1:T-DNA plants were indistinguishable from the wild type, however, leaf morphology was altered. However, when grown with NH4 and sucrose, the mutant grew poorly and died. Our results are the first in planta evidence that AtAMT1;1 is a root NH4 transporter and that redundancies within the AMT family may allow compensation for the loss of AtAMT1;1.

Published

2002

24. A Glimpse at Regulation of Nitrogen Homeostasis

Author

Maria Hrmova and Brent N. Kaiser

Subjects

Genetics, Phylum, Structural Biology, Biology, Gene, Transcription factor, Molecular Biology, Homeostasis, Article

Abstract

Plants and microorganisms reduce environmental inorganic nitrogen to ammonium, which then enters various metabolic pathways solely via conversion of 2-oxoglutarate (2OG) to glutamate and glutamine. Cellular 2OG concentrations increase during nitrogen starvation. We recently identified a novel family of 2OG-sensing proteins – the nitrogen regulatory protein NrpR – that bind DNA and repress transcription of nitrogen assimilation genes. We used X-ray crystallography to determine the structure of NrpR regulatory domain. We identified the NrpR 2OG-binding cleft and show that residues predicted to interact directly with 2OG are conserved among diverse classes of 2OG-binding proteins. We show that high levels of 2OG inhibit NrpRs ability to bind DNA. Electron microscopy analyses document that NrpR adopts different quaternary structures in its inhibited 2OG-bound state compared with its active apo state. Our results indicate that upon 2OG release, NrpR re-positions its DNA-binding domains correctly for optimal interaction with DNA thereby enabling gene repression.

Published

2010

25. Role of oxygen limitation and nitrate metabolism in the nitrate inhibition of nitrogen fixation by pea

Author

Barry J. Shelp, Brent N. Kaiser, and David B. Layzell

Subjects

biology, Physiology, food and beverages, Nitrogenase, chemistry.chemical_element, Cell Biology, Plant Science, General Medicine, Metabolism, biology.organism_classification, Nitrate reductase, Nitrogen, Pisum, chemistry.chemical_compound, Horticulture, Nitrate, chemistry, Botany, Genetics, Nitrogen fixation, Bacteria

Abstract

The impact of nitrate (5–15 mM, 2 to 7 days) on nitrogenase activity and nodule-oxygen limitation was investigated in nodulated, 21-day-old plants of a near-isogenic nitrate reductase-deficient pea mutant (A3171) and its wild-type parent (Pisum sativum L. cv. Juneau). Within 2 days, 10 or 15 mM nitrate, but not 5 mM nitrate, inhibited the apparent nitrogenase activity (measured as in situ hydrogen evolution from nodules of intact plants) of wild-type plants; none of these nitrate levels inhibited the apparent nitrogenase activity of A3171 plants. Nodule-oxygen limitation, measured as the ratio of total nitrogenase activity to potential nitrogenase activity, was increased in both wild-type and A3171 plants by all nitrate treatments. By 3 to 4 days the apparent nitrogenase activity of A3171 and wild-type plants supplied with 5 mM nitrate declined to 53 to 69% of control plants not receiving nitrate. By 6 to 7 days the apparent nitrogenase activity of A3171 plants was similar to the control value whereas that of the wild-type plants continued to decline. From 3 to 7 days, no significant differences in nodule-oxygen limitation were observed between the nitrate (5 mM) and control treatments. The results are interpreted as evidence for separate mechanisms in the initial (O2 limitation) and longer-term (nitrate metabolism) effects of nitrate on nitrogen fixation by effectively nodulated pea.

Published

1997

26. The response of the maize nitrate transport system to nitrogen demand and supply across the lifecycle

Author

Antony Bacic, Berin A. Boughton, Darren Plett, Simon J. Conn, Kanwarpal S. Dhugga, Luke R. Holtham, Karen Francis, Ute Roessner, Mark Tester, Nenah Mackenzie, Trevor Garnett, Neil J. Shirley, Brent N. Kaiser, Akiko Enju, Antoni Rafalski, Jürgen Zanghellini, Vanessa M. Conn, Garnett, Trevor, Conn, Vanessa, Plett, Darren, Conn, Simon, Zanghellini, Juergen, Mackenzie, Nenah, Enju, Akiko, Francis, Karen, Holtham, Luke, Roessner, Ute, Boughton, Berin, Bacic, Antony, Shirley, Neil, Rafalski, Antoni, Dhugga, Kanwarpal, Tester, Mark, and Kaiser, Brent N

Subjects

inorganic chemicals, Physiology, Nitrogen, Anion Transport Proteins, chemistry.chemical_element, Plant Science, Root system, Biology, maize, Plant Roots, Zea mays, nitrogen, chemistry.chemical_compound, Nitrate, nitrate, Gene Expression Regulation, Plant, Arabidopsis thaliana, Ammonium, Biomass, RNA, Messenger, Amino Acids, Plant Proteins, Biomass (ecology), Nitrates, organic chemicals, food and beverages, Biological Transport, Nitrate Transporters, biology.organism_classification, Plant Leaves, chemistry, Agronomy, Nitrate transport, uptake, Shoot, nitrogen use efficiency (NUE)

Abstract

An understanding of nitrate (NO3 -) uptake throughout the lifecycle of plants, and how this process responds to nitrogen (N) availability, is an important step towards the development of plants with improved nitrogen use efficiency (NUE). NO3 - uptake capacity and transcript levels of putative high- and low-affinity NO3 - transporters (NRTs) were profiled across the lifecycle of dwarf maize (Zea mays) plants grown at reduced and adequate NO3 - Plants showed major changes in high-affinity NO3 - uptake capacity across the lifecycle, which varied with changing relative growth rates of roots and shoots. Transcript abundances of putative high-affinity NRTs (predominantly ZmNRT2.1 and ZmNRT2.2) were correlated with two distinct peaks in high-affinity root NO3 - uptake capacity and also N availability. The reduction in NO3 - supply during the lifecycle led to a dramatic increase in NO3 - uptake capacity, which preceded changes in transcript levels of NRTs, suggesting a model with short-term post-translational regulation and longer term transcriptional regulation of NO3 - uptake capacity. These observations offer new insight into the control of NO3 - uptake by both plant developmental processes and N availability, and identify key control points that may be targeted by future plant improvement programmes to enhance N uptake relative to availability and/or demand. Refereed/Peer-reviewed

Published

2012

27. Compatibilidad sexual del cultivar 'Kalamata' de olivo evaluada mediante un análisis de paternidad

Author

Margaret Sedgley, Jenny Guerin, Esmaeil Seifi, and Brent N. Kaiser

Subjects

autocompatible, Olea europaea L, biology, Pollination, Paternity analysis, self-compatible, polleniser, biology.organism_classification, medicine.disease_cause, autoincompatibilidad, self-incompatibility, Fruit set, Pollenizer, Olea, Pollen, polinizador, Botany, medicine, Microsatellite, Cultivar, Agronomy and Crop Science

Abstract

Paternity analysis was used to assess the self-incompatibility of the olive (Olea europaea L.) cultivar ‘Kalamata’ and to identify some compatible pollenisers under a Mediterranean-type climate. Eight microsatellite markers were used for genotyping three ‘Kalamata’ mother trees, 120 embryos, and all potential pollen donors. The identified alleles were analysed using FaMoz software and showed that ‘Kalamata’ was highly self-incompatible. Only three ‘Kalamata’ embryos were assigned to ‘Kalamata’ self-fertilisation, even though it was the most available pollen donor. The alleles were also analysed using NTSYS-pc (version 2.02 k) software and identified 54 potential pollen donors in the study site; however, not all of them were located within the effective pollination distance of the mother trees (30 m in olive). According to the results of this study, ‘Kalamata’ (as a host) was compatible with ‘Barnea’, ‘Benito’, and ‘Katsourela’ (six ‘Kalamata’ embryos assigned in each) but incompatible with ‘Arbequina’, ‘Azapa’, and ‘Picual’ (zero ‘Kalamata’ embryos assigned in each). The olive growers could use some of these compatible pollenisers with ‘Kalamata’ to guarantee good fruit set. Se utilizó un análisis de paternidad para evaluar la auto-incompatibilidad del olivo (Olea europaea L.) 'Kalamata' e identificar, en un clima de tipo mediterráneo, algunos polinizadores compatibles. Se utilizaron ocho marcadores microsatélites para el genotipado de tres árboles madre 'Kalamata', 120 embriones y todos los potenciales donantes de polen. Los alelos identificados fueron analizados mediante el software de FaMoz, que mostró que 'Kalamata' fue altamente auto-incompatible. Sólo tres embriones de 'Kalamata' fueron asignados a la autofecundación de 'Kalamata', a pesar de que fue el donante de polen más disponible. Los alelos también fueron analizados mediante NTSYS-pc, que identificó 54 posibles donantes de polen en el sitio de estudio; sin embargo, no todos ellos se encontraban dentro de la distancia de polinización efectiva de los árboles madre (30 m en olivo). De acuerdo con los resultados de este estudio, 'Kalamata' (como huésped) fue compatible con 'Barnea', 'Benito', y 'Katsourela (seis embriones 'Kalamata' asignados a cada uno), pero incompatible con 'Arbequina', 'Azapa' y 'Picual' (cero embriones 'Kalamata' asignados a cada uno). Los olivareros podrían utilizar algunos de estos polinizadores compatibles con 'Kalamata' para garantizar una buena fructificación.

Published

2012

28. Cell-specific vacuolar calcium storage mediated by CAX1 regulates apoplastic calcium concentration, gas exchange, and plant productivity in Arabidopsis

Author

Andreas W. Schreiber, Brent N. Kaiser, Ninghui Cheng, Rachel A. Burton, Roger Allen Leigh, Alex A. R. Webb, Matthew Gilliham, Simon J. Conn, Asmini Athman, Matthew A. Stancombe, Stephen D. Tyerman, Ute Baumann, Isabel Moller, Kendal D. Hirschi, Conn, Simon J, Gilliham, Matthew, Athman, Asmini, Schreiber, Andreas W, Baumann, Ute, Moller, Isabel, Cheng, Ning-Hui, Stancombe, Matthew A, Hirschi, Kendal D, Webb, Alex AR, Burton, Rachel, Kaiser, Brent N, Tyerman, Stephen D, and Leigh, Roger A

Subjects

Mutant, Arabidopsis, antiporter, Plant Science, Vacuole, Biology, Calcium in biology, Antiporters, cation transport protein, Cell wall, Expansin, Cell Wall, Gene Expression Regulation, Plant, Pectinase, calcium hydrogen antiporters, Cation Transport Proteins, Research Articles, arabidopsis protein, Oligonucleotide Array Sequence Analysis, plant RNA, calcium, Arabidopsis Proteins, Gene Expression Profiling, Cell Biology, biology.organism_classification, calcium-hydrogen antiporters, Apoplast, Cell biology, Plant Leaves, Mutagenesis, Insertional, Phenotype, Biochemistry, RNA, Plant, Mutation, Plant Stomata, Vacuoles, Calcium, Single-Cell Analysis

Abstract

The physiological role and mechanism of nutrient storage within vacuoles of specific cell types is poorly understood. Transcript profiles from Arabidopsis thaliana leaf cells differing in calcium concentration ([Ca], epidermis 60 mM) were compared using a microarray screen and single-cell quantitative PCR. Three tonoplast-localized Ca2+ transporters, CAX1 (Ca2+/H+-antiporter), ACA4, and ACA11 (Ca2+-ATPases), were identified as preferentially expressed in Ca-rich mesophyll. Analysis of respective loss-of-function mutants demonstrated that only a mutant that lacked expression of both CAX1 and CAX3, a gene ectopically expressed in leaves upon knockout of CAX1, had reduced mesophyll [Ca]. Reduced capacity for mesophyll Ca accumulation resulted in reduced cell wall extensibility, stomatal aperture, transpiration, CO2 assimilation, and leaf growth rate; increased transcript abundance of other Ca2+ transporter genes; altered expression of cell wall–modifying proteins, including members of the pectinmethylesterase, expansin, cellulose synthase, and polygalacturonase families; and higher pectin concentrations and thicker cell walls. We demonstrate that these phenotypes result from altered apoplastic free [Ca2+], which is threefold greater in cax1/cax3 than in wild-type plants. We establish CAX1 as a key regulator of apoplastic [Ca2+] through compartmentation into mesophyll vacuoles, a mechanism essential for optimal plant function and productivity.

Published

2011

29. Dichotomy in the NRT gene families of dicots and grass species

Author

Darren Plett, Mark Tester, Brent N. Kaiser, Ute Baumann, Trevor Garnett, and John Toubia

Subjects

DNA, Plant, Sequence analysis, Agricultural Biotechnology, Science, Arabidopsis, Gene Identification and Analysis, Cereals, Crops, Genes, Plant, Genome, Chromosomes, Plant, Molecular Genetics, Species Specificity, Phylogenetics, Gene Expression Regulation, Plant, Botany, Databases, Genetic, Genome Databases, Arabidopsis thaliana, Gene family, Biology, Phylogeny, Plant Proteins, Genetics, Multidisciplinary, Nitrates, biology, Phylogenetic tree, Models, Genetic, Computational Biology, food and beverages, Agriculture, Sequence Analysis, DNA, Genomics, biology.organism_classification, Medicine, Brachypodium, Genome, Plant, Research Article

Abstract

A large proportion of the nitrate (NO(3)(-)) acquired by plants from soil is actively transported via members of the NRT families of NO(3)(-) transporters. In Arabidopsis, the NRT1 family has eight functionally characterised members and predominantly comprises low-affinity transporters; the NRT2 family contains seven members which appear to be high-affinity transporters; and there are two NRT3 (NAR2) family members which are known to participate in high-affinity transport. A modified reciprocal best hit (RBH) approach was used to identify putative orthologues of the Arabidopsis NRT genes in the four fully sequenced grass genomes (maize, rice, sorghum, Brachypodium). We also included the poplar genome in our analysis to establish whether differences between Arabidopsis and the grasses may be generally applicable to monocots and dicots. Our analysis reveals fundamental differences between Arabidopsis and the grass species in the gene number and family structure of all three families of NRT transporters. All grass species possessed additional NRT1.1 orthologues and appear to lack NRT1.6/NRT1.7 orthologues. There is significant separation in the NRT2 phylogenetic tree between NRT2 genes from dicots and grass species. This indicates that determination of function of NRT2 genes in grass species will not be possible in cereals based simply on sequence homology to functionally characterised Arabidopsis NRT2 genes and that proper functional analysis will be required. Arabidopsis has a unique NRT3.2 gene which may be a fusion of the NRT3.1 and NRT3.2 genes present in all other species examined here. This work provides a framework for future analysis of NO(3)(-) transporters and NO(3)(-) transport in grass crop species.

Published

2010

30. Characterization of GmCaMK1, a member of a soybean calmodulin-binding receptor-like kinase family

Author

Thomas A. DeFalco, David Chiasson, Brent N. Kaiser, Wayne A. Snedden, and Kim Munro

Subjects

CaM-binding protein, DNA, Complementary, Glycine max, Calmodulin, Molecular Sequence Data, Biophysics, Arabidopsis, Signal transduction, Biology, Biochemistry, DNA-binding protein, Structural Biology, Gene Expression Regulation, Plant, Medicago truncatula, Genetics, Protein phosphorylation, Amino Acid Sequence, Cloning, Molecular, Phosphorylation, Receptor-like kinase, Molecular Biology, Conserved Sequence, Gel electrophoresis, Sequence Homology, Amino Acid, Kinase, Arabidopsis Proteins, Cell Biology, Molecular biology, Protein Structure, Tertiary, Glutathione S-transferase, Protein kinase domain, GenBank, Calcium-Calmodulin-Dependent Protein Kinases, biology.protein, Calcium, Soybeans

Abstract

Calmodulin(CaM)-regulated protein phosphorylation forms an important component of Ca 2+ signaling in animals but is less understood in plants. We have identified a CaM-binding receptor-like kinase from soybean nodules, GmCaMK1, a homolog of Arabidopsis CRLK1. We delineated the CaM-binding domain (CaMBD) of GmCaMK1 to a 24-residue region near the C-terminus, which overlaps with the kinase domain. We have demonstrated that GmCaMK1 binds CaM with high affinity in a Ca 2+ -dependent manner. We showed that GmCaMK1 is expressed broadly across tissues and is enriched in roots and developing nodules. Finally, we examined the CaMBDs of the five-member GmCaMK family in soybean, and orthologs present across taxa. Structured summary MINT- 8051564 : AtCRLK2 (uniprotkb: Q9LFV3 ) binds (MI: 0407 ) to CaM (uniprotkb: P62199 ) by filter binding (MI: 0049 ) MINT- 8051416 : GmCaMK3 (uniprotkb: C6ZRS6 ) binds (MI: 0407 ) to CaM (uniprotkb: P62199 ) by filter binding (MI: 0049 ) MINT- 8051258 : CaM (uniprotkb: P62199 ) and GmCaMK1 (genbank_protein_gi: 223452504 ) bind (MI: 0407 ) by isothermal titration calorimetry (MI: 0065 ) MINT- 8051400 : GmCaMK2 (uniprotkb: C6ZRY5 ) binds (MI: 0407 ) to CaM (uniprotkb: P62199 ) by filter binding (MI: 0049 ) MINT- 8051242 , MINT- 8051295 , MINT- 8051313 , MINT- 8051327 , MINT- 8051341 , MINT- 8051355 : GmCaMK1 (genbank_protein_gi: 223452504 ) binds (MI: 0407 ) to CaM (uniprotkb: P62199 ) by filter binding (MI: 0049 ) MINT- 8051467 : GmCaMK4 (uniprotkb: C6TIQ0 ) binds (MI: 0407 ) to CaM (uniprotkb: P62199 ) by filter binding (MI: 0049 ) MINT- 8051276 : CaM (uniprotkb: P62199 ) and GmCaMK1 (genbank_protein_gi: 223452504 ) bind (MI: 0407 ) by comigration in non denaturing gel electrophoresis (MI: 0404 ) MINT- 8051374 : CaM (uniprotkb: P62199 ) and GmCaMK1 (genbank_protein_gi: 223452504 ) bind (MI: 0407 ) by mass spectrometry studies of complexes (MI: 0069 )

Published

2010

31. Root based approaches to improving nitrogen use efficiency in plants

Author

Brent N. Kaiser, Vanessa M. Conn, Trevor Garnett, Garnett, Trevor, Conn, Vanessa, and Kaiser, Brent

Subjects

Pollution, Crops, Agricultural, Physiology, Nitrogen, media_common.quotation_subject, crop production, Plant Science, Biology, Plant Roots, nitrogen use efficiency, Soil, fertilizer management, Agricultural productivity, Fertilizers, root morphology, Nitrogen cycle, media_common, business.industry, Fossil fuel, food and beverages, Agriculture, crop yields, Plant ecology, Agronomy, Shoot, business, Edible Grain, exogenous nitrogen fertilizers, Plant nutrition

Abstract

In the majority of agricultural growing regions, crop production is highly dependent on the supply of exogenous nitrogen (N) fertilizers. Traditionally, this dependency and the use of N‐fertilizers to restore N depleted soils has been rewarded with increased plant health and yields. In recent years, increased competition for non‐renewable fossil fuel reserves has directly elevated prices of N‐fertilizers and the cost of agricultural production worldwide. Furthermore, N‐fertilizer based pollution is becoming a serious issue for many regions where agriculture is highly concentrated. To help minimize the N footprint associated with agricultural production there is significant interest at the plant level to develop technologies which can allow economically viable production while using less applied N. To complement recent reviews examining N utilization efficiency in agricultural plants, this review will explore those strategies operating specifically at the root level, which may directly contribute to improved N use efficiencies in agricultural crops such as cereals, where the majority of N‐fertilizers are used and lost to the environment. Root specific phenotypes that will be addressed in the context of improvements to N acquisition and assimilation efficiencies include: root morphology; root to shoot ratios; root vigour, root length density; and root N transport and metabolism. Refereed/Peer-reviewed

Published

2009

32. The role of plasma membrane intrinsic protein aquaporins in water transport through roots: diurnal and drought stress responses reveal different strategies between isohydric and anisohydric cultivars of grapevine

Author

Brent N. Kaiser, Rebecca K. Vandeleur, Megan C. Shelden, Matthew Gilliham, Stephen D. Tyerman, and Gwenda M. Mayo

Subjects

Periodicity, Physiology, Xenopus, Drought tolerance, Molecular Sequence Data, Aquaporin, Plant Science, Biology, Aquaporins, Plant Roots, Hydraulic conductivity, Gene Expression Regulation, Plant, Stress, Physiological, Exodermis, Botany, Genetics, Animals, Vitis, RNA, Messenger, Transpiration, Water transport, Dehydration, Plant physiology, food and beverages, Plant Transpiration, Apoplast, RNA, Plant, Oocytes, Research Article

Abstract

We report physiological and anatomical characteristics of water transport across roots grown in soil of two cultivars of grapevine (Vitis vinifera) differing in response to water stress (Grenache, isohydric; Chardonnay, anisohydric). Both cultivars have similar root hydraulic conductances (L o; normalized to root dry weight) that change diurnally. There is a positive correlation between L o and transpiration. Under water stress, both cultivars have reduced minimum daily L o (predawn) attributed to the development of apoplastic barriers. Water-stressed and well-watered Chardonnay had the same diurnal change in amplitude of L o, while water-stressed Grenache showed a reduction in daily amplitude compared with well-watered plants. Hydraulic conductivity of root cortex cells (L pcell) doubles in Chardonnay but remains unchanged in Grenache. Of the two most highly expressed plasma membrane intrinsic protein (PIP) aquaporins in roots (VvPIP1;1 and VvPIP2;2), only VvPIP2;2 functions as a water channel in Xenopus laevis oocytes. VvPIP1;1 interacts with VvPIP2;2 to induce 3-fold higher water permeability. These two aquaporins are colocated in the root from in situ hybridization and immunolocalization of VvPIP1 and VvPIP2 subfamily members. They occur in root tip, exodermis, root cortex (detected up to 30 mm), and stele. VvPIP2;2 mRNA does not change diurnally or with water stress, in contrast to VvPIP1;1, in which expression reflects the differences in L o and L pcell between cultivars in their responses to water stress and rewatering. VvPIP1;1 may regulate water transport across roots such that transpirational demand is matched by root water transport capacity. This occurs on a diurnal basis and in response to water stress that corresponds to the difference in drought tolerance between the cultivars.

Published

2008

33. The soybean NRAMP homologue, GmDMT1, is a symbiotic divalent metal transporter capable of ferrous iron transport

Author

Annie Lambert, Joanne Castelli, Alain Puppo, Rowena Thomson, Brent N. Kaiser, David A. Day, Stéphanie Bogliolo, and Sophie Moreau

Subjects

Root nodule, DNA, Plant, Iron, Molecular Sequence Data, Plant Science, Saccharomyces cerevisiae, Genes, Plant, Peribacteroid membrane, Transformation, Genetic, Gene Expression Regulation, Plant, Iron-Binding Proteins, Nitrogen Fixation, Genetics, Amino Acid Sequence, Cloning, Molecular, Leghemoglobin, Symbiosis, Cation Transport Proteins, Plant Proteins, Ion Transport, biology, Base Sequence, fungi, food and beverages, Nitrogenase, Cell Biology, DMT1, Recombinant Proteins, Symbiosome, Biochemistry, biology.protein, Nitrogen fixation, Soybeans, Ferrous iron transport

Abstract

Iron is an important nutrient in N2-fixing legume root nodules. Iron supplied to the nodule is used by the plant for the synthesis of leghemoglobin, while in the bacteroid fraction, it is used as an essential cofactor for the bacterial N2-fixing enzyme, nitrogenase, and iron-containing proteins of the electron transport chain. The supply of iron to the bacteroids requires initial transport across the plant-derived peribacteroid membrane, which physically separates bacteroids from the infected plant cell cytosol. In this study, we have identified Glycine max divalent metal transporter 1 (GmDmt1), a soybean homologue of the NRAMP/Dmt1 family of divalent metal ion transporters. GmDmt1 shows enhanced expression in soybean root nodules and is most highly expressed at the onset of nitrogen fixation in developing nodules. Antibodies raised against a partial fragment of GmDmt1 confirmed its presence on the peribacteroid membrane (PBM) of soybean root nodules. GmDmt1 was able to both rescue growth and enhance 55Fe(II) uptake in the ferrous iron transport deficient yeast strain (fet3fet4). The results indicate that GmDmt1 is a nodule-enhanced transporter capable of ferrous iron transport across the PBM of soybean root nodules. Its role in nodule iron homeostasis to support bacterial nitrogen fixation is discussed.

Published

2003

34. Oxygen limitation of N2 fixation in various legume symbioses

Author

David B. Layzell, Brent N. Kaiser, P. Thumfort, and Barry J. Shelp

Subjects

biology, chemistry.chemical_element, Plant Science, Horticulture, biology.organism_classification, Oxygen, Pisum, N2 Fixation, Sativum, Symbiosis, chemistry, Botany, Nitrogen fixation, Phaseolus, Agronomy and Crop Science, Legume

Abstract

Two O2 ramping techniques (linear versus exponential) were used to investigate the response of H2 evolution from intact nodules of soybean (Glycine max (L.) Merr. 'Maple Arrow'), stem-girdled soybean, pea (Pisum sativum L. 'Juneau'), and common bean (Phaseolus vulgaris L. 'Ex Rico 23') to increasing O2 concentrations from 20 to 100% over a 30-min period. The data indicate symbiosis-specific responses to the two ramps, and possible implications for determination of O2 limitation of N2 fixation. Key words: Hydrogen evolution, legume, nitrogen fixation

Published

1994

35. The regulation of nitrate and ammonium transport systems in plants

Author

Shiela E. Unkles, M. Y. Siddiqi, Mamoru Okamoto, Herbert J. Kronzucker, Brent N. Kaiser, Anshuman Kumar, James R. Kinghorn, Dev T. Britto, Anthony D. M. Glass, Suman Rawat, and Joseph John Vidmar

Subjects

Physiology, Anion Transport Proteins, Down-Regulation, Plant Science, Models, Biological, Plant Roots, Soil, Aspergillus nidulans, Gene Expression Regulation, Plant, Arabidopsis, Arabidopsis thaliana, Cation Transport Proteins, Plant Proteins, Regulation of gene expression, Nitrates, biology, Arabidopsis Proteins, Chlamydomonas, Biological Transport, Nitrate Transporters, Plants, biology.organism_classification, Transport protein, Quaternary Ammonium Compounds, Biochemistry, Heterologous expression, Carrier Proteins, Plant Shoots, Ammonium transport

Abstract

Inorganic nitrogen concentrations in soil solutions vary across several orders of magnitude among different soils and as a result of seasonal changes. In order to respond to this heterogeneity, plants have evolved mechanisms to regulate and influx. In addition, efflux analysis using (13)N has revealed that there is a co-ordinated regulation of all component fluxes within the root, including biochemical fluxes. Physiological studies have demonstrated the presence of two high-affinity transporter systems (HATS) for and one HATS for in roots of higher plants. By contrast, in Arabidopsis thaliana there exist seven members of the NRT2 family encoding putative HATS for and five members of the AMT1 family encoding putative HATS for. The induction of high-affinity transport and Nrt2.1 and Nrt2.2 expression occur in response to the provision of, while down-regulation of these genes appear to be due to the effects of glutamine. High-affinity transport and AMT1.1 expression also appear to be subject to down-regulation by glutamine. In addition, there is evidence that accumulated and may act post-transcriptionally on transporter function. The present challenge is to resolve the functions of all of these genes. In Aspergillus nidulans and Chlamydomonas reinhardtii there are but two high-affinity transporters and these appear to have undergone kinetic differentiation that permits a greater efficiency of absorption over the wide range of concentration normally found in nature. Such kinetic differentiation may also have occurred among higher plant transporters. The characterization of transporter function in higher plants is currently being inferred from patterns of gene expression in roots and shoots, as well as through studies of heterologous expression systems and knockout mutants.

Published

2002

36. GmZIP1 encodes a symbiosis-specific zinc transporter in soybean

Author

David A. Day, Sophie Moreau, Mary Lou Guerinot, Rowena Thomson, Michael K. Udvardi, Ben Trevaskis, Alain Puppo, and Brent N. Kaiser

Subjects

DNA, Complementary, Time Factors, Molecular Sequence Data, chemistry.chemical_element, Zinc, Biology, Biochemistry, Peribacteroid membrane, Amino Acid Sequence, Cloning, Molecular, Symbiosis, Molecular Biology, Cation Transport Proteins, Phylogeny, Zinc finger, Dose-Response Relationship, Drug, Sequence Homology, Amino Acid, Cell Membrane, Genetic Complementation Test, Membrane Proteins, Biological Transport, Zinc Fingers, Cell Biology, Blotting, Northern, Transport protein, Protein Structure, Tertiary, Complementation, Transmembrane domain, Blotting, Southern, Kinetics, chemistry, Membrane protein, Multigene Family, Soybean Proteins, Soybeans, Carrier Proteins, Cadmium, Signal Transduction

Abstract

The importance of zinc in organisms is clearly established, and mechanisms involved in zinc acquisition by plants have recently received increased interest. In this report, the identification, characterization and location of GmZIP1, the first soybean member of the ZIP family of metal transporters, are described. GmZIP1 was found to possess eight putative transmembrane domains together with a histidine-rich extra-membrane loop. By functional complementation of zrt1zrt2 yeast cells no longer able to take up zinc, GmZIP1 was found to be highly selective for zinc, with an estimated K(m) value of 13.8 microm. Cadmium was the only other metal tested able to inhibit zinc uptake in yeast. An antibody raised against GmZIP1 specifically localized the protein to the peribacteroid membrane, an endosymbiotic membrane in nodules resulting from the interaction of the plant with its microsymbiont. The specific expression of GmZIP1 in nodules was confirmed by Northern blot, with no expression in roots, stems, or leaves of nodulated soybean plants. Antibodies to GmZIP1 inhibited zinc uptake by symbiosomes, indicating that at least some of the zinc uptake observed in isolated symbiosomes could be attributed to GmZIP1. The orientation of the protein in the membrane and its possible role in the symbiosis are discussed.

Published

2001

37. Identification and functional characterisation of aquaporins in the grapevine, Vitis vinifera

Author

Stephen D. Tyerman, Megan C. Shelden, Susan M. Howitt, and Brent N. Kaiser

Subjects

Water transport, Biochemistry, cDNA library, Complementary DNA, Botany, Major intrinsic proteins, Aquaporin, Plant Science, Biology, Agronomy and Crop Science, Genome, Gene, Homology (biology)

Abstract

Plant aquaporins belong to a large superfamily of conserved proteins called the major intrinsic proteins (MIPs). There is limited information about the diversity of MIPs in grapevine, and their water transport capacity. The aim of the present study was to identify MIPs from grapevine and functionally characterise water transport of a subset of MIPs. Candidate genes were identified, by screening a Vitis vinifera L. (cv. Cabernet Sauvignon) cDNA library with gene specific probes, for aquaporin cDNAs encoding members of the plasma membrane intrinsic protein (PIP) and tonoplast intrinsic protein (TIP) subfamilies. The screen resulted in the identification of 11 full-length and two partial length aquaporin cDNAs. VvTIP2;1 isoforms had different 3′ UTRs, immediately upstream of the poly(A) tail, suggesting the presence of multiple cleavage sites for polyadenylation. Using published genome sequences of grapevine, we conducted a phylogenetic analysis of the MIPs with previously characterised MIPs from Arabidopsis. We identified 23 full-length MIP genes from the V. vinifera genome sequence of a near homozygous line (PN40024) that cluster into the four main subfamilies (and subgroups within) identified in other species. However, based on the identification of PIP2 genes in Cabernet Sauvignon that were not present in the PN40024 genome, there are likely to be more than 23 MIP genes in other heterozygous grapevine cultivars. Water transport capacity was determined for several PIPs and TIPs, by expression in Xenopus oocytes. Only VvPIP2 and VvTIP proteins function as water channels with the exception of VvPIP2;5. VvPIP2;5 differs from the water conducting VvPIP2;1 by the substitution of two highly conserved amino acids in Loop B (G97S, G100W), which was shown by homology modelling to likely form a hydrophobic block of the water pore.

Published

2009

38. Erratum to: A seed coat cyanohydrin glucosyltransferase is associated with bitterness in almond (Prunus dulcis) kernels

Author

Tricia K. Franks, Abbas Yadollahi, Brent N. Kaiser, Jennifer R. Guerin, Michelle Wirthensohn, Christopher M. Ford, and Margaret Sedgley

Subjects

Amygdalin, Rosaceae, food and beverages, Plant Science, Biology, biology.organism_classification, food.food, Mandelonitrile, chemistry.chemical_compound, Prunus dulcis, food, stomatognathic system, chemistry, Glucoside, Biochemistry, Cyanogenic Glucoside, Prunasin, Prunus amygdalus, Agronomy and Crop Science

Abstract

The secondary metabolite amygdalin is a cyanogenic diglucoside that at high concentrations is associated with intense bitterness in seeds of the Rosaceae, including kernels of almond (Prunus dulcis (Mill.), syn. Prunus amygdalus D. A. Webb Batsch). Amygdalin is a glucoside of prunasin, itself a glucoside of R-mandelonitrile (a cyanohydrin). Here we report the isolation of an almond enzyme (UGT85A19) that stereo-selectively glucosylates R-mandelonitrile to produce prunasin. In a survey of developing kernels from seven bitter and 11 non-bitter genotypes with polyclonal antibody raised to UGT85A19, the enzyme was found to accumulate to higher levels in the bitter types in later development. This differential accumulation of UGT85A19 is associated with more than three-fold greater mandelonitrile glucosyltransferase activity in bitter kernels compared with non-bitter types, and transcriptional regulation was demonstrated using quantitative-PCR analysis. UGT85A19 and its encoding transcript were most concentrated in the testa (seed coat) of the kernel compared with the embryo, and prunasin and amygdalin were differentially compartmentalised in these tissues. Prunasin was confined to the testa and amygdalin was confined to the embryo. These results are consistent with the seed coat being an important site of synthesis of prunasin as a precursor of amygdalin accumulation in the kernel. The presence of UGT85A19 in the kernel and other tissues of both bitter and non-bitter types indicates that its expression is unlikely to be a control point for amygdalin accumulation and suggests additional roles for the enzyme in almond metabolism.

Published

2008

39. Functional characterisation of OsAMT1.1 overexpression lines of rice, Oryza sativa

Author

M. Yaeesh Siddiqi, Anthony D. M. Glass, Brent N. Kaiser, and Anshuman Kumar

Subjects

inorganic chemicals, Ecophysiology, Oryza sativa, Transgene, Wild type, food and beverages, Plant Science, Biology, Molecular biology, Botany, Cultivar, Efflux, Agronomy and Crop Science, Gene, Developmental biology

Abstract

In rice (Oryza sativa L.) OsAMT1.1 is the most active and / or most N-responsive gene responsible for high-affinity NH4+ transport (HATS) activity. We measured 13NH4+ influx and plant biomass in transgenic overexpression lines and two wild type cultivars of rice, Jarrah and Taipei, with one or more copies of OsAMT1.1. 13NH4+ influx was higher for the overexpression lines of Jarrah line when grown at 10 µm external NH4+ concentration, but not for the overexpression lines of Taipei. For seedlings grown at 2 mm external NH4+ concentration Jarrah lines 77-1 and 75-4 showed an increased influx; however, two overexpression lines of Taipei showed reduced influx rates. The biomasses of the transgenic lines grown at low and high external NH4+ concentrations were either reduced or showed no statistically significant differences compared with wild type lines. While 13NH4+ influx into roots of Jarrah line 75-4 grown at 10 µm external NH4+ concentration was significantly higher than in wild type, measurements of 13NH efflux revealed no differences, and thus net uptake of NH4+ was higher in this overexpression line.

Published

2006

40. Nutrient transport across symbiotic membranes from legume nodules

Author

David A. Day, Rowena Thomson, Michael K. Udvardi, Sophie Moreau, Alain Puppo, and Brent N. Kaiser

Subjects

Nutrient, Plant nodule, Botany, Nitrogen fixation, Plant Science, Biology, Plant biology, Agronomy and Crop Science, Cell permeability, Legume

Abstract

David A. Day , Brent N. Kaiser, Rowena Thomson, Michael K. Udvardi, Sophie Moreau and Alain Puppo

Published

2001

41. Characterization of an ammonium transport protein from the peribacteroid membrane of soybean nodules

Author

Patrick M. Finnegan, David A. Day, Stephen D. Tyerman, Michael K. Udvardi, F.J. Bergersen, Lynne F. Whitehead, and Brent N. Kaiser

Subjects

Root nodule, DNA, Complementary, Patch-Clamp Techniques, Molecular Sequence Data, Saccharomyces cerevisiae, Spheroplasts, Biology, Plant Roots, Ion Channels, Peribacteroid membrane, chemistry.chemical_compound, Methylamines, Transformation, Genetic, Complementary DNA, Ammonium, Amino Acid Sequence, Symbiosis, Cation Transport Proteins, Organelles, Multidisciplinary, Base Sequence, Cell Membrane, food and beverages, Biological Transport, Yeast, Quaternary Ammonium Compounds, Kinetics, chemistry, Membrane protein, Biochemistry, Nitrogen fixation, Potassium, Soybean Proteins, Soybeans, Carrier Proteins, Ammonium transport

Abstract

Nitrogen-fixing bacteroids in legume root nodules are surrounded by the plant-derived peribacteroid membrane, which controls nutrient transfer between the symbionts. A nodule complementary DNA ( GmSAT1 ) encoding an ammonium transporter has been isolated from soybean. GmSAT1 is preferentially transcribed in nodules and immunoblotting indicates that GmSAT1 is located on the peribacteroid membrane. [ 14 C]methylammonium uptake and patch-clamp analysis of yeast expressing GmSAT1 demonstrated that it shares properties with a soybean peribacteroid membrane NH 4 + channel described elsewhere. GmSAT1 is likely to be involved in the transfer of fixed nitrogen from the bacteroid to the host.