Your search keyword '"Igor A. Kryvoruchko"' showing total 10 results

1. GmVTL1 is an iron transporter on the symbiosome membrane of soybean with an important role in nitrogen fixation

Author

Ivone Torres-Jerez, Frank Bedon, Penelope M. C. Smith, Igor S. Kryvoruchko, David A. Day, Michael K. Udvardi, Ella M. Brear, and Aleksandr Gavrin

Subjects

biology, Chemistry, fungi, Lotus japonicus, food and beverages, Nitrogenase, biology.organism_classification, Yeast, Rhizobia, Complementation, Symbiosome, Biochemistry, Nitrogen fixation, Bacteria

Abstract

SummaryLegumes establish symbiotic relationships with soil bacteria (rhizobia), housed in nodules on plant roots. The plant supplies carbon substrates and other nutrients to the bacteria in exchange for fixed nitrogen. The exchange occurs across a plant-derived symbiosome membrane (SM), which encloses rhizobia to form a symbiosome. Iron supplied by the plant is crucial for the rhizobial enzyme nitrogenase that catalyses N2 fixation, but the SM iron transporter has not been identified.We use complementation of yeast and plant mutants, real-time PCR, hairy root transformation, microscopy and proteomics to demonstrate the role of soybean GmVTL1 and 2.Both are members of the vacuolar iron transporter family and homologous to Lotus japonicus SEN1 (LjSEN1), previously shown to be essential for N2 fixation. GmVTL1 expression is enhanced in nodule infected cells and both proteins are localised to the SM.GmVTL1 and 2 transport iron in yeast and GmVTL1 restores N2 fixation when expressed in the Ljsen1 mutant.Three GmVTL1 amino acid substitutions that reduce iron transport in yeast also block N2 fixation in Ljsen1 plants.We conclude GmVTL1 is responsible for transport of iron across the SM to bacteroids and plays a crucial role in the N2-fixing symbiosis.

Published

2020

2. GmVTL1a is an iron transporter on the symbiosome membrane of soybean with an important role in nitrogen fixation

Author

Ella M. Brear, David A. Day, Aleksandr Gavrin, Penelope M. C. Smith, Ivone Torres-Jerez, Frank Bedon, Michael K. Udvardi, and Igor S. Kryvoruchko

Subjects

0106 biological sciences, 0301 basic medicine, Physiology, Iron, Lotus japonicus, Plant Science, 01 natural sciences, Rhizobia, 03 medical and health sciences, Nitrogen Fixation, Symbiosis, Plant Proteins, biology, Chemistry, fungi, food and beverages, Nitrogenase, biology.organism_classification, Yeast, Complementation, 030104 developmental biology, Biochemistry, Symbiosome, Nitrogen fixation, Soybeans, Root Nodules, Plant, Bacteria, 010606 plant biology & botany

Abstract

Legumes establish symbiotic relationships with soil bacteria (rhizobia), housed in nodules on roots. The plant supplies carbon substrates and other nutrients to the bacteria in exchange for fixed nitrogen. The exchange occurs across a plant-derived symbiosome membrane (SM), which encloses rhizobia to form a symbiosome. Iron supplied by the plant is crucial for rhizobial enzyme nitrogenase that catalyses nitrogen fixation, but the SM iron transporter has not been identified. We use yeast complementation, real-time PCR and proteomics to study putative soybean (Glycine max) iron transporters GmVTL1a and GmVTL1b and have characterized the role of GmVTL1a using complementation in plant mutants, hairy root transformation and microscopy. GmVTL1a and GmVTL1b are members of the vacuolar iron transporter family and homologous to Lotus japonicus SEN1 (LjSEN1), which is essential for nitrogen fixation. GmVTL1a expression is enhanced in nodule infected cells and both proteins are localized to the SM. GmVTL1a transports iron in yeast and restores nitrogen fixation when expressed in the Ljsen1 mutant. Three GmVTL1a amino acid substitutions that block nitrogen fixation in Ljsen1 plants reduce iron transport in yeast. We conclude GmVTL1a is responsible for transport of iron across the SM to bacteroids and plays a crucial role in the nitrogen-fixing symbiosis.

Published

2020

3. An Iron-Activated Citrate Transporter, MtMATE67, Is Required for Symbiotic Nitrogen Fixation

Author

Vagner A. Benedito, Catalina I. Pislariu, Michael K. Udvardi, Jin Nakashima, Igor S. Kryvoruchko, Manuel Tejada-Jiménez, Ivone Torres-Jerez, Pratyush Routray, Daniel M. Roberts, Lydia Finney, Manuel González-Guerrero, and Senjuti Sinharoy

Subjects

0106 biological sciences, 0301 basic medicine, Root nodule, Membranes, Transport and Bioenergetics, Physiology, Iron, Plant Science, 01 natural sciences, 03 medical and health sciences, chemistry.chemical_compound, Gene Expression Regulation, Plant, Nitrogen Fixation, Medicago truncatula, Genetics, Citrates, Nicotianamine, Symbiosis, Leghemoglobin, Phylogeny, Plant Proteins, biology, fungi, food and beverages, Nitrogenase, biochemical phenomena, metabolism, and nutrition, Citrate transport, Plants, Genetically Modified, biology.organism_classification, 030104 developmental biology, Symbiosome, chemistry, Biochemistry, Mutation, Nitrogen fixation, Carrier Proteins, Root Nodules, Plant, 010606 plant biology & botany

Abstract

Iron (Fe) is an essential micronutrient for symbiotic nitrogen fixation in legume nodules, where it is required for the activity of bacterial nitrogenase, plant leghemoglobin, respiratory oxidases, and other Fe proteins in both organisms. Fe solubility and transport within and between plant tissues is facilitated by organic chelators, such as nicotianamine and citrate. We have characterized a nodule-specific citrate transporter of the multidrug and toxic compound extrusion family, MtMATE67 of Medicago truncatula The MtMATE67 gene was induced early during nodule development and expressed primarily in the invasion zone of mature nodules. The MtMATE67 protein was localized to the plasma membrane of nodule cells and also the symbiosome membrane surrounding bacteroids in infected cells. In oocytes, MtMATE67 transported citrate out of cells in an Fe-activated manner. Loss of MtMATE67 gene function resulted in accumulation of Fe in the apoplasm of nodule cells and a substantial decrease in symbiotic nitrogen fixation and plant growth. Taken together, the results point to a primary role of MtMATE67 in citrate efflux from nodule cells in response to an Fe signal. This efflux is necessary to ensure Fe(III) solubility and mobility in the apoplasm and uptake into nodule cells. Likewise, MtMATE67-mediated citrate transport into the symbiosome space would increase the solubility and availability of Fe(III) for rhizobial bacteroids.

Published

2017

4. MtSWEET11, a Nodule-Specific Sucrose Transporter of Medicago truncatula

Author

Jeremy D. Murray, Wolf B. Frommer, Vagner A. Benedito, Dian Guan, Catalina I. Pislariu, Davide Sosso, Senjuti Sinharoy, Igor S. Kryvoruchko, Michael K. Udvardi, and Ivone Torres-Jerez

Subjects

0106 biological sciences, 0301 basic medicine, Root nodule, biology, Physiology, fungi, food and beverages, Plant Science, Root hair, Meristem, biology.organism_classification, 01 natural sciences, Medicago truncatula, Rhizobia, 03 medical and health sciences, 030104 developmental biology, Symbiosome, Biochemistry, Genetics, Nitrogen fixation, Rhizobium, 010606 plant biology & botany

Abstract

Optimization of nitrogen fixation by rhizobia in legumes is a key area of research for sustainable agriculture. Symbiotic nitrogen fixation (SNF) occurs in specialized organs called nodules and depends on a steady supply of carbon to both plant and bacterial cells. Here we report the functional characterization of a nodule-specific Suc transporter, MtSWEET11 from Medicago truncatula. MtSWEET11 belongs to a clade of plant SWEET proteins that are capable of transporting Suc and play critical roles in pathogen susceptibility. When expressed in mammalian cells, MtSWEET11 transported sucrose (Suc) but not glucose (Glc). The MtSWEET11 gene was found to be expressed in infected root hair cells, and in the meristem, invasion zone, and vasculature of nodules. Expression of an MtSWEET11-GFP fusion protein in nodules resulted in green fluorescence associated with the plasma membrane of uninfected cells and infection thread and symbiosome membranes of infected cells. Two independent Tnt1-insertion sweet11 mutants were uncompromised in SNF. Therefore, although MtSWEET11 appears to be involved in Suc distribution within nodules, it is not crucial for SNF, probably because other Suc transporters can fulfill its role(s).

Published

2016

5. MtMTP2-Facilitated Zinc Transport Into Intracellular Compartments Is Essential for Nodule Development in Medicago truncatula

Author

Javier León-Mediavilla, Marta Senovilla, Jesús Montiel, Patricia Gil-Díez, Ángela Saez, Igor S. Kryvoruchko, María Reguera, Michael K. Udvardi, Juan Imperial, and Manuel González-Guerrero

Subjects

0106 biological sciences, 0301 basic medicine, symbiotic nitrogen fixation, Root nodule, metal nutrition, Plant Science, lcsh:Plant culture, 01 natural sciences, Rhizobia, 03 medical and health sciences, lcsh:SB1-1110, nodulation, metal transport protein, Original Research, biology, Chemistry, fungi, zinc, Nitrogenase, food and beverages, biology.organism_classification, Plant cell, Apoplast, Medicago truncatula, Cell biology, 030104 developmental biology, Nitrogen fixation, cation diffusion facilitator, 010606 plant biology & botany, Cation diffusion facilitator

Abstract

Zinc (Zn) is an essential nutrient for plants that is involved in almost every biological process. This includes symbiotic nitrogen fixation, a process carried out by endosymbiotic bacteria (rhizobia) living within differentiated plant cells of legume root nodules. Zn transport in nodules involves delivery from the root, via the vasculature, release into the apoplast and uptake into nodule cells. Once in the cytosol, Zn can be used directly by cytosolic proteins or delivered into organelles, including symbiosomes of infected cells, by Zn efflux transporters. Medicago truncatula MtMTP2 (Medtr4g064893) is a nodule-induced Zn-efflux protein that was localized to an intracellular compartment in root epidermal and endodermal cells, as well as in nodule cells. Although the MtMTP2 gene is expressed in roots, shoots, and nodules, mtp2 mutants exhibited growth defects only under symbiotic, nitrogen-fixing conditions. Loss of MtMTP2 function resulted in altered nodule development, defects in bacteroid differentiation, and severe reduction of nitrogenase activity. The results presented here support a role of MtMTP2 in intracellular compartmentation of Zn, which is required for effective symbiotic nitrogen fixation in M. truncatula.

Published

2018

6. Medicago truncatula copper transporter 1 (MtCOPT1) delivers copper for symbiotic nitrogen fixation

Author

Viviana Escudero, Igor S. Kryvoruchko, Marta Senovilla, Isidro Abreu, Michael K. Udvardi, Manuel González-Guerrero, Rosario Castro-Rodríguez, and Juan Imperial

Subjects

0301 basic medicine, Physiology, Plant Science, Saccharomyces cerevisiae, Electron Transport Complex IV, 03 medical and health sciences, Nitrogen Fixation, Medicago truncatula, Nitrogenase, Cytochrome c oxidase, Symbiosis, Gene, Cation Transport Proteins, Copper Transporter 1, Plant Proteins, biology, Chemistry, fungi, Cell Membrane, food and beverages, Biological Transport, Cell Differentiation, biology.organism_classification, Yeast, Apoplast, Complementation, 030104 developmental biology, Phenotype, Biochemistry, Multigene Family, Mutation, Nitrogen fixation, biology.protein, Root Nodules, Plant, Copper

Abstract

Copper is an essential nutrient for symbiotic nitrogen fixation. This element is delivered by the host plant to the nodule, where membrane copper (Cu) transporter would introduce it into the cell to synthesize cupro-proteins. COPT family members in the model legume Medicago truncatula were identified and their expression determined. Yeast complementation assays, confocal microscopy and phenotypical characterization of a Tnt1 insertional mutant line were carried out in the nodule-specific M. truncatula COPT family member. Medicago truncatula genome encodes eight COPT transporters. MtCOPT1 (Medtr4g019870) is the only nodule-specific COPT gene. It is located in the plasma membrane of the differentiation, interzone and early fixation zones. Loss of MtCOPT1 function results in a Cu-mitigated reduction of biomass production when the plant obtains its nitrogen exclusively from symbiotic nitrogen fixation. Mutation of MtCOPT1 results in diminished nitrogenase activity in nodules, likely an indirect effect from the loss of a Cu-dependent function, such as cytochrome oxidase activity in copt1-1 bacteroids. These data are consistent with a model in which MtCOPT1 transports Cu from the apoplast into nodule cells to provide Cu for essential metabolic processes associated with symbiotic nitrogen fixation.

Published

2017

7. Medicago truncatula copper transporter 1 (MtCOPT1) delivers copper for symbiotic nitrogen fixation

Author

Juan Imperial, Rosario Castro-Rodríguez, Viviana Escudero, Igor S. Kryvoruchko, Michael K. Udvardi, Isidro Abreu, Marta Senovilla, and Manuel González-Guerrero

Subjects

biology, fungi, Nitrogenase, chemistry.chemical_element, food and beverages, biology.organism_classification, Copper, Apoplast, Medicago truncatula, Yeast, Complementation, chemistry, Biochemistry, Botany, Nitrogen fixation, Gene

Abstract

Summary• Copper is an essential nutrient for symbiotic nitrogen fixation. This element is delivered by the host plant to the nodule, where membrane copper transporter would introduce it into the cell to synthesize cupro-proteins.• COPT family members in model legumeMedicago truncatulawere identified and their expression determined. Yeast complementation assays, confocal microscopy, and phenotypical characterization of aTnt1insertional mutant line were carried out in the nodule-specificM.truncatulaCOPT family member.•Medicago truncatulagenome encodes eight COPT transporters.MtCOPT1(Medtr4g019870) is the only nodule-specificCOPTgene. It is located in the plasma membrane of the differentiation, interzone and early fixation zones. Loss of MtCOPT1 function results in a copper-mitigated reduction of biomass production when the plant obtains its nitrogen exclusively from symbiotic nitrogen fixation. Mutation ofMtCOPT1results in diminished nitrogenase activity in nodules, likely an indirect effect from the loss of a copper-dependent function, such as cytochrome oxidase activity incopt1-1bacteroids.• These data are consistent with a model in which MtCOPT1 transports copper from the apoplast into nodule cells to provide copper for essential metabolic processes associated with symbiotic nitrogen fixation.

Published

2017

8. Medicago truncatula Natural Resistance Associated Macrophage Protein1 is required for iron uptake by rhizobia infected nodule cells

Author

Michael K. Udvardi, Rosario Castro-Rodríguez, Juan Imperial, Manuel Tejada-Jiménez, Manuel González-Guerrero, M. Mercedes Lucas, Igor S. Kryvoruchko, Ministerio de Economía y Competitividad (España), and European Research Council

Subjects

0106 biological sciences, Macrophage Protein, Root nodule, Physiology, Iron, Mutant, Plant Science, rhizobia-infected cells, 01 natural sciences, Rhizobia, Apoplast, 03 medical and health sciences, symbiotic nitrogen fixation (SNF), Medicago truncatula, Botany, Genetics, Leghemoglobin, 030304 developmental biology, 0303 health sciences, biology, Agricultura, fungi, Nodule Cells, Nitrogenase, food and beverages, biology.organism_classification, 3. Good health, Biochemistry, Nitrogen fixation, 010606 plant biology & botany

Abstract

30 páginas, 9 figuras, 1 tabla, 13 páginas de explicaciones suplementarias de las figuras, más otras 10 figuras suplementarias, Iron is critical for symbiotic nitrogen fixation (SNF) as a key component of multiple ferroproteins involved in this biological process. In the model legume Medicago truncatula, iron is delivered by the vasculature to the infection/maturation zone (zone II) of the nodule, where it is released to the apoplast. From there, plasma membrane iron transporters move it into rhizobia-containing cells, where iron is used as the cofactor of multiple plant and rhizobial proteins (e.g. plant leghemoglobin and bacterial nitrogenase). MtNramp1 (Medtr3g088460) is the M. truncatula Natural Resistance-Associated Macrophage Protein family member, with the highest expression levels in roots and nodules. Immunolocalization studies indicate that MtNramp1 is mainly targeted to the plasma membrane. A loss-of-function nramp1 mutant exhibited reduced growth compared with the wild type under symbiotic conditions, but not when fertilized with mineral nitrogen. Nitrogenase activity was low in the mutant, whereas exogenous iron and expression of wild-type MtNramp1 in mutant nodules increased nitrogen fixation to normal levels. These data are consistent with a model in which MtNramp1 is the main transporter responsible for apoplastic iron uptake by rhizobia-infected cells in zone II., This work was supported by the Spanish Ministry of Economy and Competitiveness (grant no. AGL–2012–32974 to M.G.-G. and Formación del Personal Investigador fellowship no. BES–2013– 062674 to R.C.-R.), a Marie Curie International Reintegration grant (grant no. IRG–2010–276771 to M.G.-G.), a European Research Council Starting grant (grant no. ERC–2013–StG–335284 to M.G.-G.), and a Ramón y Cajal fellowship (no. RYC–2010–06363 to M.G.-G.)., ACKNOWLEDGMENTS We thank Dr. Alonso Rodríguez-Navarro (Universidad Politécnica deMadrid) for providing plasmid pYPGE15, Dr. David Eide (University of Wisconsin, Madison) for the strain fet3/fet4 and its parental strain, Dr. Benoit Lefebvre (Laboratoire des Interactions Plantes Microorganismes) for the pBI101 vector, Dr. Florian Frugier (Institut des Sciences du Vegétal) for the pFRN vector, Dr. Rosario Haro (Universidad Politécnica de Madrid) for the organelle-specific markers, Dr. Regla Bustos (Instituto Nacional de Investigaciones Agroalimentarias) for the agroinfiltration protocol, Dr. Larry Peterson for the Casparian strip visualization method, and Dr. Tsuyoshi Nakagawa (Shiimane University) for the pGWB vectors.

Published

2015

9. The H+-ATPase HA1 of Medicago truncatula Is Essential for Phosphate Transport and Plant Growth during Arbuscular Mycorrhizal Symbiosis

Author

Franziska Krajinski, Pierre-Emmanuel Courty, Bettina Hause, Daniela Zoeller, Marcel Bucher, Igor S. Kryvoruchko, Philipp Franken, Michael K. Udvardi, Haoqiang Zhang, Nina Gerlach, Daniela Sieh, Max Planck Institute of Molecular Plant Physiology (MPI-MP), Max-Planck-Gesellschaft, University of Basel (Unibas), Leibniz Institute of Vegetable and Ornamental Crops (IVOC), University of Cologne, The Samuel Roberts Noble Foundation, and Leibniz Institute of Plant Biochemistry (IPB)

Subjects

Rhizophagus irregularis, biology, Hypha, [SDV]Life Sciences [q-bio], Mutant, fungi, Wild type, food and beverages, Cell Biology, Plant Science, biology.organism_classification, Medicago truncatula, Apoplast, Cell biology, Periarbuscular membrane, Botany, Host cell cytoplasm, Research Articles

Abstract

A key feature of arbuscular mycorrhizal symbiosis is improved phosphorus nutrition of the host plant via the mycorrhizal pathway, i.e., the fungal uptake of Pi from the soil and its release from arbuscules within root cells. Efficient transport of Pi from the fungus to plant cells is thought to require a proton gradient across the periarbuscular membrane (PAM) that separates fungal arbuscules from the host cell cytoplasm. Previous studies showed that the H+-ATPase gene HA1 is expressed specifically in arbuscule-containing root cells of Medicago truncatula. We isolated a ha1-2 mutant of M. truncatula and found it to be impaired in the development of arbuscules but not in root colonization by Rhizophagus irregularis hyphae. Artificial microRNA silencing of HA1 recapitulated this phenotype, resulting in small and truncated arbuscules. Unlike the wild type, the ha1-2 mutant failed to show a positive growth response to mycorrhizal colonization under Pi-limiting conditions. Uptake experiments confirmed that ha1-2 mutants are unable to take up phosphate via the mycorrhizal pathway. Increased pH in the apoplast of abnormal arbuscule-containing cells of the ha1-2 mutant compared with the wild type suggests that HA1 is crucial for building a proton gradient across the PAM and therefore is indispensible for the transfer of Pi from the fungus to the plant.

Published

2014

10. Keel petal incision: a simple and efficient method for genetic crossing in Medicago truncatula

Author

Senjuti Sinharoy, Michael K. Udvardi, Mark Taylor, Naudin Alexis, Igor S. Kryvoruchko, Vijaykumar Veerappan, Rebecca Dickstein, Khem Kadel, and Ashley Scott

Subjects

0106 biological sciences, Pollination, Stamen, Plant Science, medicine.disease_cause, 01 natural sciences, 03 medical and health sciences, Pollen, Medicago truncatula, Botany, Artificial hybridization, medicine, Genetics, Genetic crossing, 030304 developmental biology, 0303 health sciences, Barrel medic, Ecotype, biology, Bud, fungi, Methodology, food and beverages, biology.organism_classification, Legume, Keel petal, Petal, Keel (bird anatomy), 010606 plant biology & botany, Biotechnology

Abstract

Background Genetic crossing is an essential tool in both forward and reverse genetic approaches to understand the biological functions of genes. For Medicago truncatula (barrel medic) various crossing techniques have been used which differ in the methods used to dissect the female parent’s unopened flower bud to remove immature anthers for prevention of self-pollination. Previously described methods including front, side or back incision methods may damage the flower bud, impeding successful fertilization and/or seed development because they may allow pollen to dislodge and floral organs to desiccate after crossing, all of which diminish the success rates of crossing. Results We report the keel petal incision method for genetic crossing in M. truncatula ecotype R108 and demonstrate successful crosses with two other M. truncatula ecotypes, A17 and A20. In the method presented here, an incision is made along the central line of the keel petal from the bottom 1/3rd of the female parent’s flower bud to its distal end. This allows easy removal of anthers from the flower bud and access for cross-pollination. After pollination, the stigma and the deposited pollen from the male donor are covered by the keel petal, wing petals and standard petal, forming a natural pouch. The pouch prevents dislodging of deposited pollen from the stigma and protects the internal floral organs from drying out, without using cling-film or water-containing chambers to maintain a humid environment. The keel petal incision method showed an approximate 80% success rate in the M. truncatula R108 ecotype and also in other ecotypes including Jemalong A17 and A20. Conclusions Our keel petal incision protocol shows marked improvement over existing methods with respect to the ease of crossing and the percentage of successful crosses. Developed for the M. truncatula R108 ecotype, the protocol has been demonstrated with A17 and A20 ecotypes and is expected to work with other ecotypes. Investigators of varying experience have achieved genetic crosses in M. truncatula using this method.