Your search keyword '"Conn, Simon J."' showing total 9 results

1. Calcium delivery and storage in plant leaves: exploring the link with water flow.

Author

Gilliham M, Dayod M, Hocking BJ, Xu B, Conn SJ, Kaiser BN, Leigh RA, and Tyerman SD

Subjects

Aquaporins metabolism, Biological Transport, Plant Proteins metabolism, Plants metabolism, Calcium metabolism, Plant Leaves metabolism, Water metabolism

Abstract

Calcium (Ca) is a unique macronutrient with diverse but fundamental physiological roles in plant structure and signalling. In the majority of crops the largest proportion of long-distance calcium ion (Ca(2+)) transport through plant tissues has been demonstrated to follow apoplastic pathways, although this paradigm is being increasingly challenged. Similarly, under certain conditions, apoplastic pathways can dominate the proportion of water flow through plants. Therefore, tissue Ca supply is often found to be tightly linked to transpiration. Once Ca is deposited in vacuoles it is rarely redistributed, which results in highly transpiring organs amassing large concentrations of Ca ([Ca]). Meanwhile, the nutritional flow of Ca(2+) must be regulated so it does not interfere with signalling events. However, water flow through plants is itself regulated by Ca(2+), both in the apoplast via effects on cell wall structure and stomatal aperture, and within the symplast via Ca(2+)-mediated gating of aquaporins which regulates flow across membranes. In this review, an integrated model of water and Ca(2+) movement through plants is developed and how this affects [Ca] distribution and water flow within tissues is discussed, with particular emphasis on the role of aquaporins.

Published

2011

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

Author

Conn SJ, Gilliham M, Athman A, Schreiber AW, Baumann U, Moller I, Cheng NH, Stancombe MA, Hirschi KD, Webb AA, Burton R, Kaiser BN, Tyerman SD, and Leigh RA

Subjects

Antiporters genetics, Arabidopsis genetics, Arabidopsis Proteins genetics, Cation Transport Proteins genetics, Cell Wall metabolism, Gene Expression Profiling, Gene Expression Regulation, Plant, Mutagenesis, Insertional, Mutation, Oligonucleotide Array Sequence Analysis, Phenotype, Plant Leaves cytology, Plant Leaves metabolism, Plant Stomata metabolism, RNA, Plant genetics, Single-Cell Analysis, Antiporters metabolism, Arabidopsis metabolism, Arabidopsis Proteins metabolism, Calcium metabolism, Cation Transport Proteins metabolism, Vacuoles metabolism

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 <10 mM versus mesophyll >60 mM) were compared using a microarray screen and single-cell quantitative PCR. Three tonoplast-localized Ca(2+) transporters, CAX1 (Ca(2+)/H(+)-antiporter), ACA4, and ACA11 (Ca(2+)-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, CO(2) assimilation, and leaf growth rate; increased transcript abundance of other Ca(2+) 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 [Ca(2+)], which is threefold greater in cax1/cax3 than in wild-type plants. We establish CAX1 as a key regulator of apoplastic [Ca(2+)] through compartmentation into mesophyll vacuoles, a mechanism essential for optimal plant function and productivity.

Published

2011

3. Heterodimerization of Arabidopsis calcium/proton exchangers contributes to regulation of guard cell dynamics and plant defense responses

Author

Hocking, Bradleigh, Conn, Simon J., Manohar, Murli, Xu, Bo, Athman, Asmini, Stancombe, Matthew A., Webb, Alex R., Hirschi, Kendal D., and Gilliham, Matthew

Published

2017

4. Calcium Compartmentation in Arabidopsis Mesophyll Cells, A Mechanism to Regulate Apoplastic Calcium, Photosynthetic Rates and Growth, Involves Low-affinity, High-capacity Ca2+/H+ Antiporters

Author

Conn, Simon J, Gilliham, Matthew, Tyerman, Stephen, Kaiser, Brent, and Leigh, Roger

Subjects

Calcium, Arabidopsis, SiCSA, Photosynthesis, Homeostasis

Abstract

The way calcium (Ca) is stored in plants impacts upon plant, human and animal nutrition. An X-ray microanalysis study of over 40 angiosperm species has highlighted conserved accumulation patterns for Ca across different plant families; Ca is often stored in specific leaf cell-types. For instance, in grass monocots Ca accumulation occurs within vacuoles of epidermal cells whereas in the majority of eudicots Ca is predominantly stored within mesophyll cell vacuoles. To correlate gene expression with Ca accumulation profiles we micropipetted RNA from epidermal and mesophyll cells of the eudicot Arabidopsis thaliana. Cell specific RNA libraries were analysed by microarray and qPCR revealing a number of candidate membrane transporters with greater relative expression in the Ca-rich mesophyll. Knockout mutagenesis of one candidate AtCAX1, a tonoplast-localized Ca2+/H+-antiporter, resulted in no mutant phenotype. When the expression of AtCAX3, a complementing family member was also abolished, this resulted in a reduction in total leaf [Ca] and perturbance of the Ca distribution pattern. The double knockout plant had a 3-fold higher apoplastic [Ca] which correlated with reduced stomatal conductance, photosynthetic rate and consequently growth. Apoplastic [Ca], stomatal conductance and growth rate could be recovered to wild-type levels by reducing [Ca] in the growth medium. We implicate CAX1 and its homologues as major regulators of Ca distribution and apoplastic [Ca] in leaves within and between plant orders. Such information will be helpful for the manipulation of Ca within specific cell types of leafy vegetables as a tool for improving human and animal nutrition.

Published

2009

5. Exploiting natural variation to uncover candidate genes that control element accumulation in Arabidopsis thaliana.

Author

Conn, Simon J., Berninger, Philipp, Broadley, Martin R., and Gilliham, Matthew

Subjects

*GENES, *PHENOTYPES, *BIOFORTIFICATION, *ARABIDOPSIS, *TRANSCRIPTOMES

Abstract

Summary: The plant ionome varies both inter‐ and intraspecifically despite the highly conserved roles for particular elements across the plant kingdom. Element storage requires transport across the plasma membrane and commonly deposition within the central vacuole. Therefore, tonoplast transport characteristics can be highly influential in controlling the plant ionome. As a result, individual cell types of the same plant, each with unique transcriptomes and vacuolar proteomes, can display very different elemental profiles. Here we address the use of natural variation in Arabidopsis thaliana for identifying genes involved in elemental accumulation. We present a conceptual framework, exploiting publicly available leaf ionomic and transcriptomic data across 31 Arabidopsis accessions, that promises to accelerate conventional forward genetics approaches for candidate gene discovery. Utilizing this framework, we identify numerous genes with documented roles in accumulation of calcium, magnesium and zinc and implicate additional candidate genes. Where appropriate, we discuss their role in cell‐specific elemental accumulation. Currently, this framework could represent an alternate approach for identifying genes suitable for element biofortification of plants. Integration of additional cell‐specific and whole‐plant 'omics' datasets across Arabidopsis accessions under diverse environmental conditions should enable this concept to be developed into a scalable and robust tool for linking genotype and phenotype. [ABSTRACT FROM AUTHOR]

Published

2012

6. Heterodimerization of Arabidopsis calcium/proton exchangers contributes to regulation of guard cell dynamics and plant defense responses

Author

Matthew Gilliham, Simon J. Conn, Kendal D. Hirschi, Bo Xu, Murli Manohar, Matthew A. Stancombe, Asmini Athman, Alex R. Webb, Bradleigh Hocking, Hocking, Bradleigh, Conn, Simon J, Manohar, Murli, Xu, Bo, Athman, Asmini, Stancombe, Matthew A, Webb, Alex R, Hirschi, Kendal D, Gilliham, Matthew, Conn, Simon J [0000-0002-1376-4515], Gilliham, Matthew [0000-0003-0666-3078], and Apollo - University of Cambridge Repository

Subjects

0106 biological sciences, 0301 basic medicine, Physiology, Saccharomyces cerevisiae, Mutant, guard cells, Arabidopsis, Plant Science, 01 natural sciences, Antiporters, 03 medical and health sciences, Guard cell, homeostasis, Homomeric, Arabidopsis thaliana, protein interaction, Cation Transport Proteins, calcium, biology, Arabidopsis Proteins, fungi, biology.organism_classification, Research Papers, Cell biology, Transport protein, 030104 developmental biology, Biochemistry, Plant Stomata, transport, Calcium, Growth and Development, Protons, Protein Multimerization, mesophyll, Mesophyll Cells, signaling, Intracellular, 010606 plant biology & botany

Abstract

The cation exchanger family members CAX1 and CAX3 form homomeric and heteromeric complexes that are likely to modulate calcium transport during signaling events., Arabidopsis thaliana cation exchangers (CAX1 and CAX3) are closely related tonoplast-localized calcium/proton (Ca2+/H+) antiporters that contribute to cellular Ca2+ homeostasis. CAX1 and CAX3 were previously shown to interact in yeast; however, the function of this complex in plants has remained elusive. Here, we demonstrate that expression of CAX1 and CAX3 occurs in guard cells. Additionally, CAX1 and CAX3 are co-expressed in mesophyll tissue in response to wounding or flg22 treatment, due to the induction of CAX3 expression. Having shown that the transporters can be co-expressed in the same cells, we demonstrate that CAX1 and CAX3 can form homomeric and heteromeric complexes in plants. Consistent with the formation of a functional CAX1-CAX3 complex, CAX1 and CAX3 integrated into the yeast genome suppressed a Ca2+-hypersensitive phenotype of mutants defective in vacuolar Ca2+ transport, and demonstrated enzyme kinetics different from those of either CAX protein expressed by itself. We demonstrate that the interactions between CAX proteins contribute to the functioning of stomata, because stomata were more closed in cax1-1, cax3-1, and cax1-1/cax3-1 loss-of-function mutants due to an inability to buffer Ca2+ effectively. We hypothesize that the formation of CAX1-CAX3 complexes may occur in the mesophyll to affect intracellular Ca2+ signaling during defense responses.

Published

2017

7. Exploiting natural variation to uncover candidate genes that control element accumulation in Arabidopsis thaliana

Author

Simon J. Conn, Martin R. Broadley, Matthew Gilliham, Philipp Berninger, Conn, Simon J, Berninger, Philipp, Broadley, Martin R, and Gilliham, Matthew

Subjects

Candidate gene, Physiology, Arabidopsis, Biofortification, Plant Science, Computational biology, magnesium, biofortification, Botany, Arabidopsis thaliana, Magnesium, natural variation, ionome, Gene, Arabidopsis thaliana (Arabidopsis), calcium, biology, Arabidopsis Proteins, fungi, zinc, food and beverages, biology.organism_classification, Forward genetics, Plant Leaves, Zinc, Proteome, Calcium, Transcriptome, transcriptome, Ionomics

Abstract

The plant ionome varies both inter- and intraspecifically despite the highly conserved roles for particular elements across the plant kingdom. Element storage requires transport across the plasma membrane and commonly deposition within the central vacuole. Therefore, tonoplast transport characteristics can be highly influential in controlling the plant ionome. As a result, individual cell types of the same plant, each with unique transcriptomes and vacuolar proteomes, can display very different elemental profiles. Here we address the use of natural variation in Arabidopsis thaliana for identifying genes involved in elemental accumulation. We present a conceptual framework, exploiting publicly available leaf ionomic and transcriptomic data across 31 Arabidopsis accessions, that promises to accelerate conventional forward genetics approaches for candidate gene discovery. Utilizing this framework, we identify numerous genes with documented roles in accumulation of calcium, magnesium and zinc and implicate additional candidate genes. Where appropriate, we discuss their role in cell-specific elemental accumulation. Currently, this framework could represent an alternate approach for identifying genes suitable for element biofortification of plants. Integration of additional cell-specific and whole-plant 'omics' datasets across Arabidopsis accessions under diverse environmental conditions should enable this concept to be developed into a scalable and robust tool for linking genotype and phenotype. Refereed/Peer-reviewed

Published

2012

8. 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

9. Cell-specific compartmentation of mineral nutrients is an essential mechanism for optimal plant productivity-another role for TPC1?

Author

Simon J. Conn, Stephen D. Tyerman, Asmini Athman, Matthew Gilliham, Gilliham, Matthew, Athman, Asmini, Tyerman, Stephen D, and Conn, Simon J

Subjects

GLR, Short Communication, Antiporter, Arabidopsis, chemistry.chemical_element, cell-specific, Plant Science, Vacuole, Calcium, magnesium, Plant Epidermis, Cell wall, Cell Wall, Gene Expression Regulation, Plant, compartmentation, Arabidopsis thaliana, Magnesium, MRS2, calcium, biology, Voltage-dependent calcium channel, vacuole, Arabidopsis Proteins, Biological Transport, TPC1, biology.organism_classification, Vascular bundle, apoplast, Apoplast, Plant Leaves, Mutagenesis, Insertional, CAX1, nutrition, chemistry, Biochemistry, MGT, Vacuoles, Potassium, Biophysics, Calcium Channels, mesophyll, Mesophyll Cells

Abstract

Vacuoles of different leaf cell-types vary in their capacity to store specific mineral elements. In Arabidopsis thaliana potassium (K) accumulates preferentially in epidermal and bundle sheath cells whereas calcium (Ca) and magnesium (Mg) are stored at high concentrations only in mesophyll cells. Accumulation of these elements in a particular vacuole can be reciprocal, i.e., as [K] increases [Ca] decreases. Mesophyll-specific Ca-storage involves CAX1 (a Ca 2+/H + antiporter transcript) and Mg-storage involves MRS2-1/MGT2 and MRS2-5/MGT3 (both Mg 2+-transporter transcripts), all of which are preferentially expressed in the mesophyll and encode tonoplast-localized proteins. However, what controls leaf-cell [K] is less well understood. TPC1 encodes the two-pore Ca 2+ channel protein responsible for the tonoplast-localized SV cation conductance, and is highly expressed in cell-types that do not preferentially accumulate Ca. Here, we evaluate evidence that TPC1 has a role in maintaining differential K and Ca storage across the leaf, and propose a function for TPC1 in releasing Ca 2+ from epidermal and bundle sheath cell vacuoles to maintain low [Ca] Mesophyll-specific Ca storage is essential to maintain a poplastic free Ca concentration at a level that does not perturb a range of physiological parameters including leaf gas exchange, cell wall extensibility and growth. When plants are grown under serpentine conditions (high Mg/Ca ratio), MGT2/MRS2-1 and MGT3/MRS2-5 are required to sequester additional Mg 2+ in vacuoles to replace Ca 2+ as an osmoticum to maintain growth. An updated model of Ca 2+ and Mg 2+ transport in leaves is presented as a reference for future interrogation of nutritional flows and elemental storage in plant leaves. Refereed/Peer-reviewed

Published

2011