Your search keyword '"Kohki Yoshimoto"' showing total 34 results

1. Autophagy triggered by iron‐mediated <scp>ER</scp> stress is an important stress response to the early phase of Pi starvation in plants

Author

Yushi Yoshitake, Daiki Shinozaki, and Kohki Yoshimoto

Subjects

Membrane Lipids, Iron, Autophagy, Genetics, Cell Biology, Plant Science, Endoplasmic Reticulum, Endoplasmic Reticulum Stress

Abstract

Inorganic phosphate (Pi) is essential for plant growth. However, Pi is often limiting in soil. Hence, plants have established several mechanisms of response to Pi starvation. One of the important mechanisms is Pi recycling, which includes membrane lipid remodeling and plastid DNA degradation via catabolic enzymes. However, the involvement of other degradation systems in Pi recycling remains unclear. Autophagy, a system for degradation of intracellular components, contributes to recycling of some nutrients, such as nitrogen, carbon, and zinc, under starvation. In the present study, we found that autophagy-deficient mutants depleted Pi early and exhibited severe leaf growth defects under Pi starvation. The main cargo of autophagy induced by early Pi depleted conditions was the endoplasmic reticulum (ER), indicating that ER-phagy, a type of autophagy that selectively degrades the ER, is involved in the response to the early phase of Pi starvation for contribution to Pi recycling. This ER-phagy was suppressed in an INOSITOL-REQUIRING ENZYME 1 double mutant, ire1a ire1b, in which ER stress responses are defective, suggesting that the early Pi starvation induced ER-phagy is induced by ER stress. Furthermore, iron limitation and inhibition of lipid-reactive oxygen species accumulation suppressed the ER-phagy. Interestingly, membrane lipid remodeling, a response to late Pi starvation, was accelerated in the ire1a ire1b under early Pi-depleted conditions. Our findings reveal the existence of two different phases of responses to Pi starvation (i.e. early and late) and indicate that ER stress-mediated ER-phagy is involved in Pi recycling in the early phase to suppress acceleration of the late phase.

Published

2022

2. Seed dormancy 4 like1 of Arabidopsis is a key regulator of phase transition from embryo to vegetative development

Author

Lipeng Zheng, Masahiko Otani, Yuri Kanno, Mitsunori Seo, Yushi Yoshitake, Kohki Yoshimoto, Kazuhiko Sugimoto, and Naoto Kawakami

Subjects

Arabidopsis Proteins, Gene Expression Regulation, Plant, Seedlings, Seeds, Genetics, Arabidopsis, Germination, Oryza, Cell Biology, Plant Science, Plant Dormancy

Abstract

Seed dormancy is an adaptive trait that enables plants to survive adverse conditions and restart growth in a season and location suitable for vegetative and reproductive growth. Control of seed dormancy is also important for crop production and food quality because it can help induce uniform germination and prevent preharvest sprouting. Rice preharvest sprouting quantitative trait locus analysis has identified Seed dormancy 4 (Sdr4) as a positive regulator of dormancy development. Here, we analyzed the loss-of-function mutant of the Arabidopsis ortholog, Sdr4 Like1 (SFL1), and found that the sfl1-1 seeds showed precocious germination at the mid- to late-maturation stage similar to rice sdr4 mutant, but converted to become more dormant than the wild type during maturation drying. Coordinated with the dormancy levels, expression levels of the seed maturation and dormancy master regulator genes, ABI3, FUS3, and DOG1 in sfl1-1 seeds were lower than in wild type at early- and mid-maturation stages, but higher at the late-maturation stage. In addition to the seed dormancy phenotype, sfl1-1 seedlings showed a growth arrest phenotype and heterochronic expression of LAFL (LEC1, ABI3, FUS3, LEC2) and DOG1 in the seedlings. These data suggest that SFL1 is a positive regulator of initiation and termination of the seed dormancy program. We also found genetic interaction between SFL1 and the SFL2, SFL3, and SFL4 paralogs of SFL1, which impacts on the timing of the phase transition from embryo maturation to seedling growth.

Published

2022

3. Autophagy balances the zinc–iron seesaw caused by Zn-stress

Author

Daiki Shinozaki and Kohki Yoshimoto

Subjects

inorganic chemicals, biology, Iron, Autophagy, Arabidopsis, chemistry.chemical_element, Plant Science, Zinc, biology.organism_classification, Cell biology, chemistry, Seesaw molecular geometry, Gene Expression Regulation, Plant, Arabidopsis thaliana, Homeostasis, Intracellular

Abstract

Under zinc (Zn) deficiency, plants take up excess iron (Fe), but the uptake is inhibited under Zn excess. Coordination between intracellular recycling, transport, and sensing is essential for Zn–Fe homeostasis. A new study shows that autophagy resupplies Zn2+ and Fe2+ to correct intracellular Zn–Fe imbalances.

Published

2021

4. A proposed role for endomembrane trafficking processes in regulating tonoplast content and vacuole dynamics under ammonium stress conditions in Arabidopsis root cells

Author

Mako Yagyu, Germán Robert, Hernán Ramiro Lascano, Céline Masclaux-Daubresse, Kohki Yoshimoto, Unidad de estudios agropecuarios (UDEA), Instituto Nacional de Tecnología Agropecuaria (INTA), Universidad Nacional de Córdoba [Argentina], Meiji University [Tokyo], Institut Jean-Pierre Bourgin (IJPB), AgroParisTech-Université Paris-Saclay-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Fondo para la Investigación Científica y Tecnológica [FONCyT PICT-2017-2863], Ministry of Education, Culture, Sports, Science and Technology, Program for Strategic Research Foundation at Private Universities [S1411023], Institute of Science and Technology, Meiji University [Research Project Grant], Meiji University, Researcher Mobility Grant [MU-RMG 2019-11], Proyecto INTA [2019-PD-E6-I116-001], and Grant-in-Aid for Scientific Research on Innovative Areas, Research in a Proposed Research Area [19H05713]

Subjects

0106 biological sciences, 0301 basic medicine, inorganic chemicals, microautophagy, Short Communication, Arabidopsis, Plant Science, Vacuole, Endocytosis, Plant Roots, 01 natural sciences, 03 medical and health sciences, Stress, Physiological, Ammonium Compounds, Autophagy, endocytosis, [SDV.BV]Life Sciences [q-bio]/Vegetal Biology, Endomembrane system, [SDV.BBM]Life Sciences [q-bio]/Biochemistry, Molecular Biology, Microautophagy, cell elongation, endomembrane trafficking, biology, vacuole morphology, Plant physiology, food and beverages, biology.organism_classification, Adaptation, Physiological, Cell biology, Ammonium toxicity, macroautophagy, 030104 developmental biology, Vacuoles, Flux (metabolism), 010606 plant biology & botany

Abstract

Ammonium (NH(4)(+)) stress has multiple effects on plant physiology, therefore, plant responses are complex, and multiple mechanisms are involved in NH(4)(+) sensitivity and tolerance in plants. Root growth inhibition is an important quantitative readout of the effects of NH(4)(+) stress on plant physiology, and cell elongation appear as the principal growth inhibition target. We recently proposed autophagy as a relevant physiological mechanisms underlying NH(4)(+) sensitivity response in Arabidopsis. In a brief overview, the impaired macro-autophagic flux observed under NH(4)(+) stress conditions has a detrimental impact on the cellular energetic balance, and therefore on the energy-demanding plant growth. In contrast to its inhibitory effect on the autophagosomes flux to vacuole, NH(4)(+) toxicity induced a micro-autophagy-like process. Consistent with the reduced membrane flux to the vacuole related to macro-autophagy inhibition and the increased tonoplast degradation due to enhanced micro-autophagy, the vacuoles of the root cells of the NH(4)(+)-stressed plants showed lower tonoplast content and a decreased perimeter/area ratio. As the endosome-to-vacuole trafficking is another important process that contributes to membrane flux toward the vacuole, we evaluated the effects of NH(4)(+) stress on this process. This allows us to propose that autophagy could contribute to vacuole development as well as possible avenues to follow for future studies.

Published

2021

5. Ammonium stress increases microautophagic activity while impairing macroautophagic flux in Arabidopsis roots

Author

Céline Masclaux-Daubresse, Germán Robert, Kohki Yoshimoto, Takaya Koizumi, Loreto Naya, Mako Yagyu, Institut Jean-Pierre Bourgin (IJPB), AgroParisTech-Université Paris-Saclay-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Instituto Nacional de Tecnología Agropecuaria (INTA), Department of Life Sciences, School of Agriculture, Meiji University [Tokyo]-Meiji University [Tokyo], and IJPB's Plant Observatory technological platforms INRA Package program, IJPB Saclay Plant Sciences-SPS ANR-17-EUR-0007National Institute of Agronomical Technology (INTA, Argentina) LabEx Saclay Plant Sciences-SPS ANR-10-LABX-0040-SPSFondo para la Investigacion Cientifica y Tecnologica FONCyT PICT-2017-2863Proyecto Especifico INTA PNCYO112703326484INTA 2019-PD-E6-I116-001Institute of Science and Technology, Meiji University Meiji University, Researcher Mobility Grant MU-RMG 2019-11Ministry of Education, Culture, Sports, Science and Technology, Program for Strategic Research Foundation at Private Universities S1411023INRA Package program (2012-2015) ANR-12-ADAPT-001-01-AUTOADAPT 19H05713

Subjects

0106 biological sciences, 0301 basic medicine, inorganic chemicals, microautophagy, Arabidopsis, CCZ1&#8208, Plant Science, Vacuole, Plant Roots, 01 natural sciences, 03 medical and health sciences, chemistry.chemical_compound, Stress, Physiological, Ammonium Compounds, Genetics, vacuole fusion, [SDV.BV]Life Sciences [q-bio]/Vegetal Biology, Ammonium, Microautophagy, NH4 (+) toxicity, biology, Vesicle, Autophagy, vacuole morphology, Autophagosomes, food and beverages, Cell Biology, biology.organism_classification, to&#8208, macroautophagy, 030104 developmental biology, chemistry, Cytoplasm, Biophysics, MON1, Flux (metabolism), autophagosome&#8208, 010606 plant biology & botany

Abstract

International audience; Plant responses to NH4 (+) stress are complex, and multiple mechanisms underlying NH4 (+) sensitivity and tolerance in plants may be involved. Here, we demonstrate that macro- and microautophagic activities are oppositely affected in plants grown under NH4 (+) toxicity conditions. When grown under NH4 (+) stress conditions, macroautophagic activity was impaired in roots. Root cells accumulated autophagosomes in the cytoplasm, but showed less autophagic flux, indicating that late steps of the macroautophagy process are affected under NH4 (+) stress conditions. Under this scenario, we also found that the CCZ1-MON1 complex, a critical factor for vacuole delivery pathways, functions in the late step of the macroautophagic pathway in Arabidopsis. In contrast, an accumulation of tonoplast-derived vesicles was observed in vacuolar lumens of root cells of NH4 (+)-stressed plants, suggesting the induction of a microautophagy-like process. In this sense, some SYP22-, but mainly VAMP711-positive vesicles were observed inside vacuole in roots of NH4 (+)-stressed plants. Consistent with the increased tonoplast degradation and the reduced membrane flow to the vacuole due to the impaired macroautophagic flux, the vacuoles of root cells of NH4 (+)-stressed plants showed a simplified structure and lower tonoplast content. Taken together, this study presents evidence that postulates late steps of the macroautophagic process as a relevant physiological mechanism underlying the NH4 (+) sensitivity response in Arabidopsis, and additionally provides insights into the molecular tools for studying microautophagy in plants.

Published

2021

6. Optimal Distribution of Iron to Sink Organs via Autophagy Is Important for Tolerance to Excess Zinc in Arabidopsis

Author

Kohki Yoshimoto, Daiki Shinozaki, and Keitaro Tanoi

Subjects

Chlorophyll, Physiology, Iron, ATG5, Arabidopsis, chemistry.chemical_element, Plant Science, Zinc, Gene Expression Regulation, Plant, Stress, Physiological, Autophagy, Arabidopsis thaliana, Chlorosis, biology, Chemistry, food and beverages, Cell Biology, General Medicine, Iron Deficiencies, Meristem, biology.organism_classification, Cell biology, Plant Leaves, Sink (computing), Reactive Oxygen Species

Abstract

Zinc (Zn) is nutritionally an essential metal element, but excess Zn in the environment is toxic to plants. Autophagy is a major pathway responsible for intracellular degradation. Here, we demonstrate the important role of autophagy in adaptation to excess Zn stress. We found that autophagy-defective Arabidopsis thaliana (atg2 and atg5) exhibited marked excess Zn-induced chlorosis and growth defects relative to wild-type (WT). Imaging and biochemical analyses revealed that autophagic activity was elevated under excess Zn. Interestingly, the excess Zn symptoms of atg5 were alleviated by supplementation of high levels of iron (Fe) to the media. Under excess Zn, in atg5, Fe starvation was especially severe in juvenile true leaves. Consistent with this, accumulation levels of Fe3+ near the shoot apical meristem remarkably reduced in atg5. Furthermore, excision of cotyledons induced severe excess Zn symptoms in WT, similar to those observed in atg5. Our data suggest that Fe3+ supplied from source leaves (cotyledons) via autophagy is distributed to sink leaves (true leaves) to promote healthy growth under excess Zn, revealing a new dimension, the importance of heavy-metal stress responses by the intracellular recycling.

Published

2020

7. Editorial: Organelle Autophagy in Plant Development

Author

Henri Batoko, Masanori Izumi, and Kohki Yoshimoto

Subjects

selective autophagy, autophagy, Carbon metabolism, carbon metabolism, Autophagy, Lipid metabolism, Plant Science, Biology, lcsh:Plant culture, Cell biology, Selective autophagy, Plant development, organelles, Organelle, lcsh:SB1-1110, plant development, autophagy receptors

Published

2020

8. Importance of non-systemic leaf autophagy for suppression of zinc starvation induced-chlorosis

Author

Kohki Yoshimoto, Michitaka Notaguchi, and Daiki Shinozaki

Subjects

0106 biological sciences, 0301 basic medicine, Starvation, Chlorosis, Short Communication, Autophagy, chemistry.chemical_element, Intracellular zinc, Plant Science, Zinc, Biology, 01 natural sciences, Cell biology, Plant Leaves, 03 medical and health sciences, 030104 developmental biology, chemistry, medicine, medicine.symptom, Rootstock, 010606 plant biology & botany

Abstract

Autophagy, which is one of the self-degradation systems, promotes intracellular zinc (Zn) recycling under Zn deficiency (−Zn) in plants. Therefore, autophagy defective plants show severe chlorosis under −Zn. Root is the plant organ which directly exposed to Zn deficient environment, however, in our recent study, −Zn symptom was prominently observed in leaves as chlorosis. Here, we conducted micrografting to determine which organ’s autophagic activities are important to suppress the −Zn induced chlorosis. Grafted plants that have autophagic activities only in roots or leaves were grown under −Zn and then compared chlorotic phenotypes among them. As a result, regardless of the autophagic activities in rootstocks, −Zn induced-chlorosis in leaves was occurred only when autophagy in scion was defective. This data indicates that Zn resupplied by autophagic degradation in root cells could not contribute to suppress the chlorosis in leaves. Thus, autophagy in the aerial part is critical for controlling −Zn induced-chlorosis in leaves. Taken together, along with our recently reported data, we conclude that the mechanism of Zn resupply by autophagic degradation is not systemic throughout the plant but rather a local system.

Published

2020

9. Autophagy Increases Zinc Bioavailability to Avoid Light-Mediated Reactive Oxygen Species Production under Zinc Deficiency

Author

Kohki Yoshimoto, Ekaterina A. Merkulova, Céline Masclaux-Daubresse, Yuri Kanno, Tetsuro Horie, Loreto Naya, Yoshinori Ohsumi, Mitsunori Seo, Daiki Shinozaki, Department of Life Science, School of Agriculture, Meiji University [Tokyo]-Meiji University [Tokyo], Life Science Program, Graduate School of Agriculture, Institut Jean-Pierre Bourgin (IJPB), AgroParisTech-Université Paris-Saclay-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Research Center for Odontology, School of Life Dentistry at Tokyo, The Nippon Dental University-The Nippon Dental University, Research Unit for Cell Biology, Institute of Innovative Research, Tokyo Institute of Technology [Tokyo] (TITECH)-Tokyo Institute of Technology [Tokyo] (TITECH), RIKEN Center for Sustainable Resource Science [Yokohama] (RIKEN CSRS), and RIKEN - Institute of Physical and Chemical Research [Japon] (RIKEN)

Subjects

0106 biological sciences, Chloroplasts, Physiology, [SDV]Life Sciences [q-bio], Mutant, Arabidopsis, Plant Science, 01 natural sciences, chemistry.chemical_compound, Gene Expression Regulation, Plant, Zinc deficiency (plant disorder), Genetics, Autophagy, Arabidopsis thaliana, Research Articles, 2. Zero hunger, chemistry.chemical_classification, Reactive oxygen species, biology, Chemistry, Superoxide, Arabidopsis Proteins, biology.organism_classification, Cell biology, Chloroplast, Zinc, Reactive Oxygen Species, 010606 plant biology & botany

Abstract

Zinc (Zn) is an essential micronutrient for plant growth. Accordingly, Zn deficiency (−Zn) in agricultural fields is a serious problem, especially in developing regions. Autophagy, a major intracellular degradation system in eukaryotes, plays important roles in nutrient recycling under nitrogen and carbon starvation. However, the relationship between autophagy and deficiencies of other essential elements remains poorly understood, especially in plants. In this study, we focused on Zn due to the property that within cells most Zn is tightly bound to proteins, which can be targets of autophagy. We found that autophagy plays a critical role during −Zn in Arabidopsis (Arabidopsis thaliana). Autophagy-defective plants (atg mutants) failed to grow and developed accelerated chlorosis under −Zn. As expected, −Zn induced autophagy in wild-type plants, whereas in atg mutants, various organelle proteins accumulated to high levels. Additionally, the amount of free Zn(2+) was lower in atg mutants than in control plants. Interestingly, −Zn symptoms in atg mutants recovered under low-light, iron-limited conditions. The levels of hydroxyl radicals in chloroplasts were elevated, and the levels of superoxide were reduced in −Zn atg mutants. These results imply that the photosynthesis-mediated Fenton-like reaction, which is responsible for the chlorotic symptom of −Zn, is accelerated in atg mutants. Together, our data indicate that autophagic degradation plays important functions in maintaining Zn pools to increase Zn bioavailability and maintain reactive oxygen species homeostasis under −Zn in plants.

Published

2020

10. Unveiling the molecular mechanisms of plant autophagy – from autophagosomes to vacuoles in plants

Author

Kohki Yoshimoto and Yoshinori Ohsumi

Subjects

0301 basic medicine, biology, Physiology, Saccharomyces cerevisiae, Autophagy, Autophagosomes, food and beverages, Cell Biology, Plant Science, General Medicine, Vacuole, biology.organism_classification, Phenotype, Yeast, Cell biology, 03 medical and health sciences, 030104 developmental biology, Plant Cells, Vacuoles, Identification (biology), Gene, Intracellular, Plant Proteins

Abstract

Autophagy is an evolutionarily conserved intracellular vacuolar process. Since Christian de Duve first coined the term 'autophagy' in 1963, it had not been well understood at the molecular level until much later, due to limitations in biochemical approaches and/or morphological approaches posed by electron microscopy. An important milestone was achieved with the isolation and identification of autophagy-related (ATG) genes by genetic screening using yeast Saccharomyces cerevisiae. ATG genes are well conserved in most eukaryotic organisms, which allowed the subsequent isolation of ATG gene-knockouts in plants. From the phenotypic analyses of the autophagy-defective plants, the physiological roles of autophagy have been predicted. However, in some cases, all the phenotypes cannot be simply explained by defects in autophagy. Therefore, in order to fully understand the physiological implications of plant autophagy, it is quite important to elucidate the molecular mechanisms involved in each process in macro-/micro-autophagy. Although, until recently, our understanding of the molecular mechanisms of plant autophagy was lagging compared to similar research in yeast and animals, current studies have made many great advances in the plant research field. In this review, we discuss current knowledge of the molecular mechanisms of plant autophagy, from autophagy-induction/autophagosome-formation to vacuolar degradation, comparing these to processes in yeast and mammals. We also review aspects of plant autophagy research that require further investigation in the future.

Published

2018

11. Autophagy controls resource allocation and protein storage accumulation in Arabidopsis seeds

Author

Gwendal Cueff, Fabien Chardon, Kohki Yoshimoto, Julien Di Berardino, Michèle Reisdorf-Cren, Anne Marmagne, Céline Masclaux-Daubresse, Adeline Berger, Institut Jean-Pierre Bourgin (IJPB), Institut National de la Recherche Agronomique (INRA)-AgroParisTech, Centre National de la Recherche Scientifique (CNRS), Université Paris Saclay (COmUE), Université de Versailles Saint-Quentin-en-Yvelines (UVSQ), ANR program [ANR-12-ADAPT-0010-0], Ministere de l'Enseignement Superieur et de la Recherche, and the LabEx Saclay Plant Sciences-SPS [ANR-10-LABX-0040-SPS]

Subjects

0106 biological sciences, 0301 basic medicine, grain protein content, Physiology, [SDV]Life Sciences [q-bio], ATG5, Mutant, Arabidopsis, Plant Science, 01 natural sciences, 12S globulin, 03 medical and health sciences, 2S albumin, Gene Expression Regulation, Plant, atg5, [SDV.IDA]Life Sciences [q-bio]/Food engineering, Autophagy, Storage protein, [SDV.BV]Life Sciences [q-bio]/Vegetal Biology, [SPI.GPROC]Engineering Sciences [physics]/Chemical and Process Engineering, seed filling, 2. Zero hunger, chemistry.chemical_classification, biology, Arabidopsis Proteins, food and beverages, Embryo, biology.organism_classification, Research Papers, Cell biology, 030104 developmental biology, chemistry, Seeds, Phloem, seed abortion, Silique, 010606 plant biology & botany

Abstract

Autophagy takes place in seeds, as evidenced by detection of autophagosomes and high expression of ATG genes in Arabidopsis, and the seeds of the atg5 mutant exhibit early browning as well as low and early accumulation of 12S globulin., Autophagy is essential for nutrient recycling and plays a fundamental role in seed production and grain filling in plants. Autophagy participates in nitrogen remobilization at the whole-plant level, and the seeds of autophagy mutants present abnormal C and N contents relative to wild-type (WT) plants. It is well known that autophagy (ATG) genes are induced in leaves during senescence; however, expression of such genes in seeds has not yet been reported. In this study we show that most of the ATG genes are induced during seed maturation in Arabidopsis siliques. Promoter–ATG8f::UIDA and promoter–ATG8f::GFP fusions showed the strong expression of ATG8f in the phloem companion cells of pericarps and the funiculus, and in the embryo. Expression was especially strong at the late stages of development. The presence of many GFP-ATG8 pre-autophagosomal structures and autophagosomes confirmed the presence of autophagic activity in WT seed embryos. Seeds of atg5 and WT plants grown under low- or high-nitrate conditions were analysed. Nitrate-independent phenotypes were found with higher seed abortion in atg5 and early browing, higher total protein concentrations in the viable seeds of this mutant as compared to the WT. The higher total protein accumulation in atg5 viable seeds was significant from early developmental stages onwards. In addition, relatively low and early accumulation of 12S globulins were found in atg5 seeds. These features led us to the conclusion that atg5 seed development is accelerated and that the protein storage deposition pathway is somehow abnormal or incomplete.

Published

2018

12. Autophagy, plant senescence, and nutrient recycling

Author

Liliana Avila-Ospina, Céline Masclaux-Daubresse, Kohki Yoshimoto, Michaël Moison, Institut Jean-Pierre Bourgin (IJPB), Institut National de la Recherche Agronomique (INRA)-AgroParisTech, CETIOM (Centre Technique des Oleagineux), Biologie et Amelioration des Plantes, INRA, INRA Package programme, European Project: 264394, Avila-Ospina, Liliana, and Moison, Michaël

Subjects

0106 biological sciences, Senescence, proteolysis, Chloroplasts, Nitrogen, Physiology, [SDV]Life Sciences [q-bio], Proteolysis, media_common.quotation_subject, Cell, Flowers, Plant Science, Biology, proteolyse, 01 natural sciences, 03 medical and health sciences, Autophagy, medicine, vesicular trafficking, Organism, 030304 developmental biology, media_common, Plant senescence, Nitrogen remobilization, Rubisco containing bodies, plant cell death, 0303 health sciences, medicine.diagnostic_test, Longevity, Plants, Cell biology, Plant Leaves, medicine.anatomical_structure, Adaptation, 010606 plant biology & botany

Abstract

Large numbers of publications have appeared over the last few years, dealing with the molecular details of the regulation and process of the autophagy machinery in animals, plants, and unicellular eukaryotic organisms. This strong interest is caused by the fact that the autophagic process is involved in the adaptation of organisms to their environment and to stressful conditions, thereby contributing to cell and organism survival and longevity. In plants, as in other eukaryotes, autophagy is associated with longevity as mutants display early and strong leaf senescence symptoms, however, the exact role of autophagy as a pro-survival or pro-death process is unclear. Recently, evidence that autophagy participates in nitrogen remobilization has been provided, but the duality of the role of autophagy in leaf longevity and/or nutrient recycling through cell component catabolism remains. This review aims to give an overview of leaf senescence-associated processes from the physiological point of view and to discuss relationships between nutrient recycling, proteolysis, and autophagy. The dual role of autophagy as a pro-survival or pro-death process is discussed.

Published

2014

13. Autophagy Negatively Regulates Cell Death by Controlling NPR1-Dependent Salicylic Acid Signaling during Senescence and the Innate Immune Response inArabidopsis

Author

Yoshinori Ohsumi, Ken Shirasu, Kohki Yoshimoto, Yuji Kamiya, Chiara Consonni, Yusuke Jikumaru, Miyako Kusano, and Ralph Panstruga

Subjects

Senescence, Programmed cell death, Arabidopsis, Cyclopentanes, Plant Science, Autophagy-Related Protein 5, chemistry.chemical_compound, Plant Growth Regulators, Gene Expression Regulation, Plant, Autophagy, Oxylipins, Research Articles, Innate immune system, biology, Arabidopsis Proteins, Jasmonic acid, Hydrogen Peroxide, Cell Biology, Ethylenes, biology.organism_classification, Phosphoric Monoester Hydrolases, Cell biology, chemistry, RNA, Plant, Signal transduction, Salicylic Acid, Intracellular, Signal Transduction

Abstract

Autophagy is an evolutionarily conserved intracellular process for vacuolar degradation of cytoplasmic components. In higher plants, autophagy defects result in early senescence and excessive immunity-related programmed cell death (PCD) irrespective of nutrient conditions; however, the mechanisms by which cells die in the absence of autophagy have been unclear. Here, we demonstrate a conserved requirement for salicylic acid (SA) signaling for these phenomena in autophagy-defective mutants (atg mutants). The atg mutant phenotypes of accelerated PCD in senescence and immunity are SA signaling dependent but do not require intact jasmonic acid or ethylene signaling pathways. Application of an SA agonist induces the senescence/cell death phenotype in SA-deficient atg mutants but not in atg npr1 plants, suggesting that the cell death phenotypes in the atg mutants are dependent on the SA signal transducer NONEXPRESSOR OF PATHOGENESIS-RELATED GENES1. We also show that autophagy is induced by the SA agonist. These findings imply that plant autophagy operates a novel negative feedback loop modulating SA signaling to negatively regulate senescence and immunity-related PCD.

Published

2009

14. OsATG10b, an autophagosome component, is needed for cell survival against oxidative stresses in rice

Author

Jun-Hye Shin, Jong-Seong Jeon, Gynheung An, Yoshinori Ohsumi, and Kohki Yoshimoto

Subjects

DNA, Bacterial, Paraquat, Autophagosome, DNA, Complementary, Cell Survival, Molecular Sequence Data, Mutant, GUS reporter system, Sodium Chloride, Biology, Genes, Plant, Gene Expression Regulation, Plant, Phagosomes, Gene expression, Organelle, Autophagy, Amino Acid Sequence, Molecular Biology, Gene, Vascular tissue, Glucuronidase, Plant Proteins, Gene Expression Profiling, Oryza, Cell Biology, General Medicine, Mutagenesis, Insertional, Oxidative Stress, Protein Transport, Biochemistry, Mutation, Subcellular Fractions

Abstract

Autophagy degrades toxic materials and old organelles, and recycles nutrients in eukaryotic cells. Whereas the studies on autophagy have been reported in other eukaryotic cells, its functioning in plants has not been well elucidated. We analyzed the roles of OsATG10 genes, which are autophagy-related. Two rice ATG10 genes - OsATG10a and OsATG10b - share significant sequence homology (about 75%), and were ubiquitously expressed in all organs examined here. GUS assay indicated that OsATG10b was highly expressed in the mesophyll cells and vascular tissue of younger leaves, but its level of expression decreased in older leaves. We identified T-DNA insertional mutants in that gene. Those osatg10b mutants were sensitive to treatments with high salt and methyl viologen (MV). Monodansylcadaverine-staining experiments showed that the number of autophagosomes was significantly decreased in the mutants compared with the WT. Furthermore, the amount of oxidized proteins increased in MV-treated mutant seedlings. These results demonstrate that OsATG10b plays an important role in the survival of rice cells against oxidative stresses.

Published

2009

15. An Arabidopsis Homolog of YeastATG6/VPS30Is Essential for Pollen Germination

Author

Yuki Fujiki, Yoshinori Ohsumi, and Kohki Yoshimoto

Subjects

Genetics, biology, Physiology, Autophagy, Mutant, Saccharomyces cerevisiae, Plant Science, biology.organism_classification, Carboxypeptidase, Yeast, Transport protein, Cell biology, Arabidopsis, biology.protein, Arabidopsis thaliana

Abstract

Yeast (Saccharomyces cerevisiae) Atg6/Vps30 is required for autophagy and the sorting of vacuolar hydrolases, such as carboxypeptidase Y. In higher eukaryotes, however, roles for ATG6/VPS30 homologs in vesicle sorting have remained obscure. Here, we show that AtATG6, an Arabidopsis (Arabidopsis thaliana) homolog of yeast ATG6/VPS30, restored both autophagy and vacuolar sorting of carboxypeptidase Y in a yeast atg6/vps30 mutant. In Arabidopsis cells, green fluorescent protein-AtAtg6 protein localized to punctate structures and colocalized with AtAtg8, a marker protein of the preautophagosomal structure. Disruption of AtATG6 by T-DNA insertion resulted in male sterility that was confirmed by reciprocal crossing experiments. Microscopic analyses of AtATG6 heterozygous plants (AtATG6/atatg6) crossed with the quartet mutant revealed that AtATG6-deficient pollen developed normally, but did not germinate. Because other atatg mutants are fertile, AtAtg6 likely mediates pollen germination in a manner independent of autophagy. We propose that Arabidopsis Atg6/Vps30 functions not only in autophagy, but also plays a pivotal role in pollen germination.

Published

2007

16. Autophagy in development and stress responses of plants

Author

Yoshinori Ohsumi, Francis Marty, Yuji Moriyasu, Kohki Yoshimoto, Diane C. Bassham, Laura J. Olsen, and Marianne M. Laporte

Subjects

Autophagosome, Senescence, Programmed cell death, biology, Arabidopsis Proteins, Autophagy, Arabidopsis, food and beverages, Cell Biology, Vacuole, biology.organism_classification, Genes, Plant, Cell biology, Biochemistry, Molecular Biology, Gene, Function (biology)

Abstract

The uptake and degradation of cytoplasmic material by vacuolar autophagy in plants has been studied extensively by electron microscopy and shown to be involved in developmental processes such as vacuole formation, deposition of seed storage proteins and senescence, and in the response of plants to nutrient starvation and to pathogens. The isolation of genes required for autophagy in yeast has allowed the identification of many of the corresponding Arabidopsis genes based on sequence similarity. Knockout mutations in some of these Arabidopsis genes have revealed physiological roles for autophagy in nutrient recycling during nitrogen deficiency and in senescence. Recently, markers for monitoring autophagy in whole plants have been developed, opening the way for future studies to decipher the mechanisms and pathways of autophagy, and the function of these pathways in plant development and stress responses.

Published

2005

17. The Crystal Structure of Plant ATG12 and its Biological Implication in Autophagy

Author

Kohki Yoshimoto, Yoshinori Ohsumi, Yuko Fujioka, Fuyuhiko Inagaki, and Nobuo Suzuki

Subjects

Models, Molecular, Protein Folding, Arabidopsis Proteins, Molecular Sequence Data, ATG5, Autophagy, Arabidopsis, Cell Biology, Crystal structure, Biology, Conjugated system, Crystallography, X-Ray, Cell biology, ATG12, Biochemistry, Plant protein, Amino Acid Sequence, Hydrophobic and Hydrophilic Interactions, Molecular Biology, Conjugate

Abstract

Atg12 is a post-translational modifier that is activated and conjugated to its single target, Atg5, by a ubiquitin-like conjugation system. The Atg12-Atg5 conjugate is essential for autophagy, the bulk degradation process of cytoplasmic components by the vacuolar/lysosomal system. Here, we demonstrate that the Atg12 conjugation system exists in Arabidopsis and is essential for plant autophagy as well as in yeast and mammals. We also report the crystal structure of Arabidopsis thaliana (At) ATG12 at 1.8 A resolution. Despite no obvious sequence homology with ubiquitin, the structure of AtATG12 shows a ubiquitin fold strikingly similar to those of mammalian homologs of Atg8, the other ubiquitin-like modifier essential for autophagy, which is conjugated to phosphatidylethanolamine. Two types of hydrophobic patches are present on the surface of AtATG12: one is conserved in both Atg12 and Atg8 orthologs, while the other is unique to Atg12 orthologs. Considering that they share Atg7 as an E1-like enzyme, we suggest that the first hydrophobic patch is responsible for the conjugation reaction, while the latter is involved in Atg12-specific functions.

Published

2005

18. Processing of ATG8s, ubiquitin-like proteins, and their deconjugation by ATG4s are essential for plant autophagy

Author

Shusei Sato, Kohki Yoshimoto, Satoshi Tabata, Yoshinori Ohsumi, Takeshi Noda, Hideki Hanaoka, and Tomohiko Kato

Subjects

DNA, Bacterial, Vacuolar Proton-Translocating ATPases, Nitrogen, Recombinant Fusion Proteins, ATG8, Transgene, Arabidopsis, Plant Science, Vacuole, Plant Roots, Microscopy, Electron, Transmission, Gene Expression Regulation, Plant, Autophagy, Arabidopsis thaliana, Enzyme Inhibitors, Gene, Research Articles, biology, Arabidopsis Proteins, Ubiquitin, Genetic Complementation Test, Gene Expression Regulation, Developmental, Cell Biology, Plants, Genetically Modified, biology.organism_classification, Cell biology, Biochemistry, Cytoplasm, Mutation, Vacuoles, Microtubule-Associated Proteins

Abstract

Autophagy is an intracellular process for vacuolar degradation of cytoplasmic components. Thus far, plant autophagy has been studied primarily using morphological analyses. A recent genome-wide search revealed significant conservation among autophagy genes ( ATG s) in yeast and plants. It has not been proved, however, that Arabidopsis thaliana ATG genes are required for plant autophagy. To evaluate this requirement, we examined the ubiquitination-like Atg8 lipidation system, whose component genes are all found in the Arabidopsis genome. In Arabidopsis, all nine ATG8 genes and two ATG4 genes were expressed ubiquitously and were induced further by nitrogen starvation. To establish a system monitoring autophagy in whole plants, we generated transgenic Arabidopsis expressing each green fluorescent protein–ATG8 fusion (GFP-ATG8). In wild-type plants, GFP-ATG8s were observed as ring shapes in the cytoplasm and were delivered to vacuolar lumens under nitrogen-starved conditions. By contrast, in a T-DNA insertion double mutant of the ATG4 s ( atg4a4b-1 ), autophagosomes were not observed, and the GFP-ATG8s were not delivered to the vacuole under nitrogen-starved conditions. In addition, we detected autophagic bodies in the vacuoles of wild-type roots but not in those of atg4a4b-1 in the presence of concanamycin A, a V-ATPase inhibitor. Biochemical analyses also provided evidence that autophagy in higher plants requires ATG proteins. The phenotypic analysis of atg4a4b-1 indicated that plant autophagy contributes to the development of a root system under conditions of nutrient limitation.

Published

2004

19. Plant autophagy is responsible for peroxisomal transition and plays an important role in the maintenance of peroxisomal quality

Author

Michitaro Shibata, Kazusato Oikawa, Kenji Yamada, Kohki Yoshimoto, Maki Kondo, Yoshinori Ohsumi, Makoto Hayashi, Shino Goto-Yamada, Wataru Sakamoto, Shoji Mano, Mikio Nishimura, Department of Cell Biology, National Institute for Basic Biology [Okazaki], Department of Basic Biology, School of Life Science, The Graduate University for Advanced Studies, Department of Applied Biological Chemistry, Niigata University, Institut Jean-Pierre Bourgin (IJPB), Institut National de la Recherche Agronomique (INRA)-AgroParisTech, Department of Bioscience, Nagahama Institute of Bio-Science and Technology, Institute of Plant Science and Resources, Okayama University, Frontier Research Center, and Tokyo Institute of Technology [Tokyo] (TITECH)

Subjects

0106 biological sciences, Arabidopsis thaliana, Membrane lipids, [SDV]Life Sciences [q-bio], Arabidopsis, hydrogen peroxide, 01 natural sciences, 03 medical and health sciences, Glyoxysome, Autophagy, Peroxisomes, peroxisome, Molecular Biology, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, Reactive oxygen species, biology, glyoxysome leaf peroxisome, Cell Biology, Peroxisome, Plants, Genetically Modified, biology.organism_classification, pexophagy, Autophagic Punctum, Cell biology, Plant Leaves, Metabolic pathway, Biochemistry, chemistry, Photorespiration, peroxisome transition, Reactive Oxygen Species, Oxidation-Reduction, Metabolic Networks and Pathways, 010606 plant biology & botany

Abstract

In photosynthetic cells, a large amount of hydrogen peroxide is produced in peroxisomes through photorespiration, which is a metabolic pathway related to photosynthesis. Hydrogen peroxide, a reactive oxygen species, oxidizes peroxisomal proteins and membrane lipids, resulting in a decrease in peroxisomal quality. We demonstrate that the autophagic system is responsible for the elimination of oxidized peroxisomes in plant. We isolated Arabidopsis mutants that accumulated oxidized peroxisomes, which formed large aggregates. We revealed that these mutants were defective in autophagy-related (ATG) genes and that the aggregated peroxisomes were selectively targeted by the autophagic machinery. These findings suggest that autophagy plays an important role in the quality control of peroxisomes by the selective degradation of oxidized peroxisomes. In addition, the results suggest that autophagy is also responsible for the functional transition of glyoxysomes to leaf peroxisomes.

Published

2014

20. Stitching together the multiple dimensions of autophagy using metabolomics and transcriptomics reveals impacts on metabolism, development, and plant responses to the environment in arabidopsis

Author

Pauline Anne, Jean-Marc Routaboul, Ken Shirasu, Céline Masclaux-Daubresse, Kohki Yoshimoto, Gilles Clément, Fabienne Soulay, Anne Guiboileau, Institut Jean-Pierre Bourgin (IJPB), Institut National de la Recherche Agronomique (INRA)-AgroParisTech, Génomique et Biotechnologie des Fruits (GBF), Institut National de la Recherche Agronomique (INRA)-Ecole Nationale Supérieure Agronomique de Toulouse-Institut National Polytechnique (Toulouse) (Toulouse INP), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées, Plant Science Center, RIKEN - Institute of Physical and Chemical Research [Japon] (RIKEN), Ministere de l'Education et de la Recherche of France, Ministry of Education, Culture, Sports, Science, and Technology of Japan [18770040, 19039033, 2020061], French Ministere des Affaires Etrangeres et Europeennes [21124QA], Japan Society for the Promotion of Science [21124QA], and Institut National de la Recherche Agronomique (INRA)-École nationale supérieure agronomique de Toulouse [ENSAT]-Institut National Polytechnique (Toulouse) (Toulouse INP)

Subjects

2. Zero hunger, plant responses to the environment, autophagy, biology, [SDV]Life Sciences [q-bio], Autophagy, fungi, food and beverages, Cell Biology, Plant Science, Vacuole, biology.organism_classification, Cell biology, Metabolic pathway, arabidopsis, Flavonoid biosynthesis, Biochemistry, Arabidopsis, Plant defense against herbivory, Large-Scale Biology Article, COP9 signalosome, Functional genomics, transcriptome, metabolism

Abstract

Autophagy is a fundamental process in the plant life story, playing a key role in immunity, senescence, nutrient recycling, and adaptation to the environment. Transcriptomics and metabolomics of the rosette leaves of Arabidopsis thaliana autophagy mutants (atg) show that autophagy is essential for cell homeostasis and stress responses and that several metabolic pathways are affected. Depletion of hexoses, quercetins, and anthocyanins parallel the overaccumulation of several amino acids and related compounds, such as glutamate, methionine, glutathione, pipecolate, and 2-aminoadipate. Transcriptomic data show that the pathways for glutathione, methionine, raffinose, galacturonate, and anthocyanin are perturbed. Anthocyanin depletion in atg mutants, which was previously reported as a possible defect in flavonoid trafficking to the vacuole, appears due to the downregulation of the master genes encoding the enzymes and regulatory proteins involved in flavonoid biosynthesis. Overexpression of the PRODUCTION OF ANTHOCYANIN PIGMENT1 transcription factor restores anthocyanin accumulation in vacuoles of atg mutants. Transcriptome analyses reveal connections between autophagy and (1) salicylic acid biosynthesis and response, (2) cytokinin perception, (3) oxidative stress and plant defense, and possible interactions between autophagy and the COP9 signalosome machinery. The metabolic and transcriptomic signatures identified for the autophagy mutants are discussed and show consistencies with the observed phenotypes.

Published

2014

21. Quality control of plant peroxisomes in organ specific manner via autophagy

Author

Michitaro Shibata, Kiminori Toyooka, Mayuko Sato, Yoshinori Ohsumi, Mikio Nishimura, Kohki Yoshimoto, Kazusato Oikawa, Ken Shirasu, and Maki Kondo

Subjects

biology, Autophagy, Cell Biology, Vacuole, Peroxisome, biology.organism_classification, Cell biology, Biochemistry, Catalase, Arabidopsis, Organelle, Glyoxysome, biology.protein, Arabidopsis thaliana

Abstract

Peroxisomes are essential organelles characterized by the possession of enzymes that produce hydrogen peroxide (H2O2) as part of their normal catalytic cycle. During the metabolic process, peroxisomal proteins are inevitably damaged by H2O2 and the integrity of the peroxisomes is impaired. Here, we show that autophagy, an intracellular process for vacuolar degradation, selectively degrades dysfunctional peroxisomes. Marked accumulation of peroxisomes was observed in the leaves but not roots of autophagy-related (ATG) gene-knockout Arabidopsis thaliana mutants. The peroxisomes in leaf cells contained markedly increased levels of catalase in an insoluble and inactive aggregate form. The chemically inducible complementation system in ATG5 knockout Arabidopsis provided the evidence that these accumulated peroxisomes were delivered to vacuoles by autophagy for degradation. Interestingly, autophagosomal membrane structures specifically recognized the abnormal peroxisomes at the site of the aggregates. Thus, autophagy is essential for the quality control of peroxisomes in leaves for proper plant development under natural growth conditions.

Published

2014

22. Assessment and optimization of autophagy monitoring methods in Arabidopsis roots indicate direct fusion of autophagosomes with vacuoles

Author

Céline Masclaux-Daubresse, Kohki Yoshimoto, Anne Guiboileau, Ekaterina A. Merkulova, Loreto Naya, Institut Jean-Pierre Bourgin (IJPB), Institut National de la Recherche Agronomique (INRA)-AgroParisTech, and Institut National de la Recherche Agronomique (INRA) France [INRA package program]

Subjects

Autophagosome, Arabidopsis thaliana, Monitoring, Physiology, ATG8, Recombinant Fusion Proteins, [SDV]Life Sciences [q-bio], Cytological Techniques, Green Fluorescent Proteins, Arabidopsis, Plant Science, Vacuole, Membrane Fusion, Plant Roots, Green fluorescent protein, Wortmannin, chemistry.chemical_compound, Acidotropic dye, Leucine, Cadaverine, Phagosomes, Plant Cells, Tobacco, Autophagy, Amines, biology, Staining and Labeling, Arabidopsis Proteins, Cell Biology, General Medicine, biology.organism_classification, Plants, Genetically Modified, Fusion protein, Cell biology, Androstadienes, Kinetics, chemistry, Biochemistry, Vacuoles, Lysosomes

Abstract

Autophagy is a degradation pathway that recycles cell materials upon encountering stress conditions or during specific developmental processes. To better understand the physiological roles of autophagy, proper monitoring methods are very important. In mammals and yeast, monitoring of autophagy is often performed with a green fluorescent protein (GFP)-ATG8 fusion protein or with acidotropic dyes such as monodansylcadaverine (MDC) and LysoTracker Red (LTR). To evaluate these monitoring methods, here we examined these systems by inducing autophagy in Arabidopsis thaliana roots as a model for monitoring autophagy in planta. Under carbon- and nitrogen-starved conditions, the number and size of vesicles labeled by GFP-ATG8 was increased for several hours and then gradually decreased to a level higher than that observed before the start of the experiment. We also observed the disappearance of GFP-ATG8-labeled vesicles after treatment with wortmannin, a phosphatidylinositol 3-kinase inhibitor known as an autophagy inhibitor, showing that the GFP-ATG8 transgenic line constitutes an excellent method for monitoring autophagy. These data were compared with plants stained with MDC and LTR. There was no appreciable MDC/LTR staining of small organelles in the root under the induction of autophagy. Some vesicles were eventually observed in the root tip only, but co-localization experiments, as well as experiments with autophagy-deficient atg mutants, provided the evidence that these structures were located in the vacuole and were not manifestly autophagosomes and/or autolysosomes. Extreme caution should therefore be used when monitoring autophagy with the aid of MDC/LTR. Additionally, our observations strongly suggest that autophagosomes fuse directly to vacuoles in Arabidopsis roots.

Published

2014

23. Highly Oxidized Peroxisomes Are Selectively Degraded via Autophagy in Arabidopsis[C][W]

Author

Michitaro Shibata, Yoshinori Ohsumi, Mikio Nishimura, Maki Kondo, Kazusato Oikawa, Kenji Yamada, Makoto Hayashi, Kohki Yoshimoto, Wataru Sakamoto, Shoji Mano, Department of Cell Biology, National Institute for Basic Biology [Okazaki], School of Life Science, Department of Basic Biology, The Graduate University for Advanced Studies, Institut Jean-Pierre Bourgin (IJPB), Institut National de la Recherche Agronomique (INRA)-AgroParisTech, Institute of Plant Science and Resources, Okayama University, Frontier Research Center, Tokyo Institute of Technology [Tokyo] (TITECH), Japan Society for the Promotion of Science [5852], and 22120007

Subjects

0106 biological sciences, Autophagosome, ATG8, [SDV]Life Sciences [q-bio], Mutant, Arabidopsis, Plant Science, 01 natural sciences, In Brief, 03 medical and health sciences, Stress, Physiological, Phagosomes, Autophagy, Peroxisomes, Research Articles, 030304 developmental biology, 0303 health sciences, biology, Arabidopsis Proteins, Wild type, Hydrogen Peroxide, Cell Biology, Peroxisome, biology.organism_classification, Cell biology, Biochemistry, Catalase, Mutation, biology.protein, Oxidation-Reduction, 010606 plant biology & botany

Abstract

The legend for Figure 1B has been corrected; The positioning of peroxisomes in a cell is a regulated process that is closely associated with their functions. Using this feature of the peroxisomal positioning as a criterion, we identified three Arabidopsis thaliana mutants (peroxisome unusual positioning1 [peup1], peup2, and peup4) that contain aggregated peroxisomes. We found that the PEUP1, PEUP2, and PEUP4 were identical to Autophagy-related2 (ATG2), ATG18a, and ATG7, respectively, which are involved in the autophagic system. The number of peroxisomes was increased and the peroxisomal proteins were highly accumulated in the peup1 mutant, suggesting that peroxisome degradation by autophagy (pexophagy) is deficient in the peup1 mutant. These aggregated peroxisomes contained high levels of inactive catalase and were more oxidative than those of the wild type, indicating that peroxisome aggregates comprise damaged peroxisomes. In addition, peroxisome aggregation was induced in wild-type plants by exogenous application of hydrogen peroxide. The cat2 mutant also contained peroxisome aggregates. These findings demonstrate that hydrogen peroxide as a result of catalase inactivation is the inducer of peroxisome aggregation. Furthermore, an autophagosome marker, ATG8, frequently colocalized with peroxisome aggregates, indicating that peroxisomes damaged by hydrogen peroxide are selectively degraded by autophagy in the wild type. Our data provide evidence that autophagy is crucial for quality control mechanisms for peroxisomes in Arabidopsis.

Published

2013

24. Beginning to Understand Autophagy, an Intracellular Self-Degradation System in Plants

Author

Kohki Yoshimoto, Institut Jean-Pierre Bourgin (IJPB), Institut National de la Recherche Agronomique (INRA)-AgroParisTech, Ministry of Education, Culture, Sports, Science and Technology, Japan [22770049], and INRA, France

Subjects

0106 biological sciences, Autophagosome, [SDV.SA]Life Sciences [q-bio]/Agricultural sciences, Physiology, ATG8, Saccharomyces cerevisiae, Arabidopsis, Plant Science, Biology, 01 natural sciences, Plant life, SACCHAROMYCES-CEREVISIAE, 03 medical and health sciences, SUCROSE STARVATION CONDITIONS, organelle degradation, Plant Cells, Autophagy, POLLEN GERMINATION, SELECTIVE AUTOPHAGY, Plant Proteins, 030304 developmental biology, PROTEIN LIPIDATION, Organelles, 2. Zero hunger, 0303 health sciences, MONITORING AUTOPHAGY, Autophagy database, Protein, fungi, CONSTITUTIVE AUTOPHAGY, food and beverages, Cell Biology, General Medicine, Plants, biology.organism_classification, Cell biology, INNATE IMMUNE-RESPONSE, ROOT-TIP CELLS, Starvation, ARABIDOPSIS-THALIANA, Intracellular, 010606 plant biology & botany

Abstract

Autophagy is an evolutionarily conserved intracellular process for the vacuolar degradation of cytoplasmic components. There is no doubt that autophagy is very important to plant life, especially because plants are immobile and must survive in environmental extremes. Early studies of autophagy provided our first insights into the structural characteristics of the process in plants, but for a long time the molecular mechanisms and the physiological roles of autophagy were not understood. Genetic analyses of autophagy in the yeast Saccharomyces cerevisiae have greatly expanded our knowledge of the molecular aspects of autophagy in plants as well as in animals. Until recently our knowledge of plant autophagy was in its infancy compared with autophagy research in yeast and animals, but recent efforts by plant researchers have made many advances in our understanding of plant autophagy. Here I will introduce an overview of autophagy in plants, present current findings and discuss the physiological roles of self-degradation.

Published

2012

25. A possible involvement of autophagy in amyloplast degradation in columella cells during hydrotropic response of Arabidopsis roots

Author

Ken Shirasu, Hideyuki Takahashi, Yutaka Miyazawa, Mikio Nishimura, Nobuharu Fujii, Kenji Yamada, Hiroyuki Ishida, Mayumi Nakayama, Nahoko Higashitani, Kohki Yoshimoto, Yasuko Kaneko, and Shinya Wada

Subjects

Autophagosome, Time Factors, Recombinant Fusion Proteins, Gravitropism, Arabidopsis, Autophagy-Related Proteins, Plant Science, Hydrotropism, Vacuole, Endoplasmic Reticulum, Plant Roots, Tropism, Microscopy, Electron, Transmission, Gene Expression Regulation, Plant, Stress, Physiological, Botany, Genetics, Autophagy, Amyloplast, Plastids, Cell Nucleus, Microscopy, Confocal, biology, Dehydration, Arabidopsis Proteins, Endoplasmic reticulum, Cell Polarity, biology.organism_classification, Plants, Genetically Modified, Cell biology, Vacuolization, Seedlings, Mutation, Vacuoles, Transcription Factors

Abstract

Seedling roots display not only gravitropism but also hydrotropism, and the two tropisms interfere with one another. In Arabidopsis (Arabidopsis thaliana) roots, amyloplasts in columella cells are rapidly degraded during the hydrotropic response. Degradation of amyloplasts involved in gravisensing enhances the hydrotropic response by reducing the gravitropic response. However, the mechanism by which amyloplasts are degraded in hydrotropically responding roots remains unknown. In this study, the mechanistic aspects of the degradation of amyloplasts in columella cells during hydrotropic response were investigated by analyzing organellar morphology, cell polarity and changes in gene expression. The results showed that hydrotropic stimulation or systemic water stress caused dramatic changes in organellar form and positioning in columella cells. Specifically, the columella cells of hydrotropically responding or water-stressed roots lost polarity in the distribution of the endoplasmic reticulum (ER), and showed accelerated vacuolization and nuclear movement. Analysis of ER-localized GFP showed that ER redistributed around the developed vacuoles. Cells often showed decomposing amyloplasts in autophagosome-like structures. Both hydrotropic stimulation and water stress upregulated the expression of AtATG18a, which is required for autophagosome formation. Furthermore, analysis with GFP-AtATG8a revealed that both hydrotropic stimulation and water stress induced the formation of autophagosomes in the columella cells. In addition, expression of plastid marker, pt-GFP, in the columella cells dramatically decreased in response to both hydrotropic stimulation and water stress, but its decrease was much less in the autophagy mutant atg5. These results suggest that hydrotropic stimulation confers water stress in the roots, which triggers an autophagic response responsible for the degradation of amyloplasts in columella cells of Arabidopsis roots.

Published

2011

26. The Rab GTPase RabG3b functions in autophagy and contributes to tracheary element differentiation in Arabidopsis

Author

Ohkmae K. Park, Soon Il Kwon, Hong Joo Cho, Jin Hee Jung, Ken Shirasu, and Kohki Yoshimoto

Subjects

Programmed cell death, biology, Cell, Autophagy, Mutant, Wild type, food and beverages, Cell Biology, Plant Science, biology.organism_classification, Cell biology, medicine.anatomical_structure, Tracheary element differentiation, Arabidopsis, Genetics, medicine, Rab

Abstract

The tracheary elements (TEs) of the xylem serve as the water-conducting vessels of the plant vascular system. To achieve this, TEs undergo secondary cell wall thickening and cell death, during which the cell contents are completely removed. Cell death of TEs is a typical example of developmental programmed cell death that has been suggested to be autophagic. However, little evidence of autophagy in TE differentiation has been provided. The present study demonstrates that the small GTP binding protein RabG3b plays a role in TE differentiation through its function in autophagy. Differentiating wild type TE cells were found to undergo autophagy in an Arabidopsis culture system. Both autophagy and TE formation were significantly stimulated by overexpression of a constitutively active mutant (RabG3bCA), and were inhibited in transgenic plants overexpressing a dominant negative mutant (RabG3bDN) or RabG3b RNAi (RabG3bRNAi), a brassinosteroid insensitive mutant bri1-301, and an autophagy mutant atg5-1. Taken together, our results suggest that autophagy occurs during TE differentiation, and that RabG3b, as a component of autophagy, regulates TE differentiation.

Published

2010

27. Physiological roles of autophagy in plants: does plant autophagy have a pro-death function?

Author

Kohki Yoshimoto

Subjects

Senescence, Programmed cell death, Cell Death, Mutant, Autophagy, fungi, food and beverages, Plant Science, Review, Biology, Plants, Models, Biological, Cell biology, Phenotype, Biochemistry, Apoptosis, Plant Cells, Signal transduction, Intracellular, Function (biology)

Abstract

Autophagy is an evolutionarily conserved intracellular process for vacuolar degradation of cytoplasmic components. Early morphological studies suggested that autophagy occurs in plant cells and predicted that autophagy has a variety of functions in plant growth and development. However, it is only since the identification of autophagy genes that the physiological roles of autophagy in plants have become apparent. Recent reverse genetic studies indicate that autophagy defects in higher plants result in early senescence and excessive immunity-related programmed cell death (PCD), irrespective of nutrient conditions, suggesting that plant autophagy has an important pro-survival function during these types of cell death. Further biochemical and pharmacological studies in combination with double mutant analyses revealed that excessive salicylic acid (SA) signaling is a major factor in autophagy-defective plant-dependent cell death and that the SA signal can induce autophagy. These results demonstrate a novel physiological function for plant autophagy that operates a negative feedback loop to modulate SA signaling.

Published

2010

28. Chloroplasts autophagy during senescence of individually darkened leaves

Author

Amane Makino, Masanori Izumi, Tadahiko Mae, Kohki Yoshimoto, Hiroyuki Ishida, Shinya Wada, and Yoshinori Ohsumi

Subjects

Chlorophyll, DNA, Bacterial, Chloroplasts, Physiology, Ribulose-Bisphosphate Carboxylase, Population, Arabidopsis, Plant Science, Vacuole, Photosynthesis, chemistry.chemical_compound, Botany, Autophagy, Genetics, Arabidopsis thaliana, education, Cellular Senescence, Plant Proteins, education.field_of_study, biology, Vacuolar lumen, RuBisCO, fungi, food and beverages, biology.organism_classification, Article Addendum, Cell biology, Plant Leaves, Chloroplast, Mutagenesis, Insertional, Cytosol, chemistry, Biochemistry, biology.protein, Chloroplast Proteins, Cell aging, Research Article

Abstract

We recently reported that autophagy plays a role in chloroplasts degradation in individually-darkened senescing leaves. Chloroplasts contain approximately 80% of total leaf nitrogen, mainly as photosynthetic proteins, predominantly ribulose 1, 5-bisphosphate carboxylase/oxygenase (Rubisco). During leaf senescence, chloroplast proteins are degraded as a major source of nitrogen for new growth. Concomitantly, while decreasing in size, chloroplasts undergo transformation to non-photosynthetic gerontoplasts. Likewise, over time the population of chloroplasts (gerontoplasts) in mesophyll cells also decreases. While bulk degradation of the cytosol and organelles is mediated by autophagy, the role of chloroplast degradation is still unclear. In our latest study, we darkened individual leaves to observe chloroplast autophagy during accelerated senescence. At the end of the treatment period chloroplasts were much smaller in wild-type than in the autophagy defective mutant, atg4a4b-1, with the number of chloroplasts decreasing only in wild-type. Visualizing the chloroplast fractions accumulated in the vacuole, we concluded that chloroplasts were degraded by two different pathways, one was partial degradation by small vesicles containing only stromal-component (Rubisco containing bodies; RCBs) and the other was whole chloroplast degradation. Together, these pathways may explain the morphological attenuation of chloroplasts during leaf senescence and describe the fate of chloroplasts.

Published

2009

29. In vitro reconstitution of plant Atg8 and Atg12 conjugation systems essential for autophagy

Author

Kohki Yoshimoto, Yuko Fujioka, Nobuo N. Noda, Fuyuhiko Inagaki, Yoshinori Ohsumi, and Kiyonaga Fujii

Subjects

Mammals, biology, Arabidopsis Proteins, Ubiquitin, ATG8, Phosphatidylethanolamines, Saccharomyces cerevisiae, Arabidopsis, Ubiquitination, Cell Biology, biology.organism_classification, Biochemistry, Yeast, In vitro, ATG12, Autophagy, Arabidopsis thaliana, Animals, Molecular Biology, Autophagy-Related Protein 12, Conjugate

Abstract

Genetic and biochemical analyses using yeast Saccharomyces cerevisiae showed that two ubiquitin-like conjugation systems, the Atg8 and Atg12 systems, exist and play essential roles in autophagy, the bulk degradation system conserved in yeast and mammals. These conjugation systems are also conserved in Arabidopsis thaliana; however, further detailed study of plant ATG (autophagy-related) conjugation systems in relation to those in yeast and mammals is needed. Here, we describe the in vitro reconstitution of Arabidopsis thaliana ATG8 and ATG12 (AtATG8 and AtATG12) conjugation systems using purified recombinant proteins. AtATG12b was conjugated to AtATG5 in a manner dependent on AtATG7, AtATG10, and ATP, whereas AtATG8a was conjugated to phosphatidylethanolamine (PE) in a manner dependent on AtATG7, AtATG3, and ATP. Other AtATG8 homologs (AtATG8b–8i) were similarly conjugated to PE. The AtATG8 conjugates were deconjugated by AtATG4a and AtATG4b. These results support the hypothesis that the ATG conjugation systems in Arabidopsis are very similar to those in yeast and mammals. Intriguingly, in vitro analyses showed that AtATG12-AtATG5 conjugates accelerated the formation of AtATG8-PE, whereas AtATG3 inhibited the formation of AtATG12-AtATG5 conjugates. The in vitro conjugation systems reported here will afford a tool with which to investigate the cross-talk mechanism between two conjugation systems.

Published

2007

30. AtATG genes, homologs of yeast autophagy genes, are involved in constitutive autophagy in Arabidopsis root tip cells

Author

Masaki Hattori, Takao Suzuki, Yuji Moriyasu, Yuko Inoue, Yoshinori Ohsumi, and Kohki Yoshimoto

Subjects

Sucrose, Physiology, Mutant, Meristem, Arabidopsis, Autophagy-Related Proteins, Plant Science, Vacuole, medicine.disease_cause, Genes, Plant, Aminopeptidases, Autophagy-Related Protein 5, Gene Expression Regulation, Plant, medicine, Autophagy, Gene, Mutation, biology, Arabidopsis Proteins, Adenine, Cell Biology, General Medicine, biology.organism_classification, Phosphoric Monoester Hydrolases, Cell biology, Biochemistry, Cytoplasm, Vacuoles

Abstract

In Arabidopsis root tips cultured in medium containing sufficient nutrients and the membrane-permeable protease inhibitor E-64d, parts of the cytoplasm accumulated in the vacuoles of the cells from the meristematic zone to the elongation zone. Also in barley root tips treated with E-64, parts of the cytoplasm accumulated in autolysosomes and pre-existing central vacuoles. These results suggest that vacuolar and/or lysosomal autophagy occurs constitutively in these regions of cells. 3-Methyladenine, an inhibitor of autophagy, inhibited the accumulation of such inclusions in Arabidopsis root tip cells. Such inclusions were also not observed in root tips prepared from Arabidopsis T-DNA mutants in which AtATG2 or AtATG5, an Arabidopsis homolog of yeast ATG genes essential for autophagy, is disrupted. In contrast, an atatg9 mutant, in which another homolog of ATG is disrupted, accumulated a significant number of vacuolar inclusions in the presence of E-64d. These results suggest that both AtAtg2 and AtAtg5 proteins are essential for autophagy whereas AtAtg9 protein contributes to, but is not essential for, autophagy in Arabidopsis root tip cells. Autophagy that is sensitive to 3-methyladenine and dependent on Atg proteins constitutively occurs in the root tip cells of Arabidopsis.

Published

2006

31. Plant autophagy puts the brakes on cell death by controlling salicylic acid signaling

Author

Kohki Yoshimoto

Subjects

Feedback, Physiological, Senescence, Physiological function, Programmed cell death, Cell Death, Acclimatization, Autophagy, food and beverages, Cell Biology, Plants, Biology, Plants, Genetically Modified, Cell biology, chemistry.chemical_compound, chemistry, Salicylic Acid, Molecular Biology, Gene, Plant Physiological Phenomena, Salicylic acid, Plant Diseases, Signal Transduction

Abstract

It has long been recognized that autophagy in plants is important for nutrient recycling and plays a critical role in the ability of plants to adapt to environmental extremes such as nutrient deprivation. Recent reverse genetic studies, however, hint at other roles for autophagy, showing that autophagy defects in higher plants result in early senescence and excessive immunity-related programmed cell death (PCD), irrespective of nutrient conditions. Until now, the mechanisms by which cells die in the absence of autophagy were unclear. In our study, using biochemical, pharmacological and genetic approaches, we reveal that excessive salicylic acid (SA) signaling is a major factor in autophagy-defective plant-dependent cell death and that the SA signal can induce autophagy. These findings suggest a novel physiological function for plant autophagy that operates via a negative feedback loop to modulate proper SA signaling.

Published

2010

32. Non-invasive quantitative detection and applications of non-toxic, S65T-type green fluorescent protein in living plants

Author

Yasuo Niwa, Masanori Shimizu, Hirokazu Kobayashi, Kohki Yoshimoto, and Takanori Hirano

Subjects

Light, Transgene, Mutant, Genetic Vectors, Green Fluorescent Proteins, Arabidopsis, Plant Science, medicine.disease_cause, Green fluorescent protein, Protein targeting, Botany, Tobacco, Genetics, medicine, Arabidopsis thaliana, Plastid, DNA Primers, biology, Base Sequence, fungi, food and beverages, Cell Biology, biology.organism_classification, Plants, Genetically Modified, Cell biology, Luminescent Proteins, Plants, Toxic, Organelle biogenesis

Abstract

Green fluorescent protein (GFP) has emerged as a powerful new tool in a variety of organisms. An engineered sGFP(S65T) sequence containing optimized codons of highly expressed eukaryotic proteins has provided up to 100-fold brighter fluorescence signals than the original jellyfish GFP sequence in plant and mammalian cells. It would be useful to establish a non-invasive, quantitative detection system which is optimized for S65T-type GFP, one of the brightest chromophore mutants among the various GFPs. We demonstrate here that highly fluorescent transgenic Arabidopsis can be generated, and the fluorescence intensity of whole plants can be measured under non-disruptive, sterile conditions using a quantitative fluorescent imaging system with blue laser excitation. Homozygous plants can be distinguished from heterozygous plants and fully fertile progenies can be obtained from the analyzed plants. In the case of cultured tobacco cells, GFP-positive cells can be quantitatively distinguished from non-transformed cells under non-selective conditions. This system will be useful in applications such as mutant screening, analysis of whole-body phenomena, including gene silencing and quantitative assessments of colonies from microorganisms to cultured eukaryotic cells. To facilitate the elucidation of protein targeting and organelle biogenesis in planta, we also generated transgenic Arabidopsis that stably express the plastid- or mitochondria-targeted sGFP(S65T). Etioplasts in dark-grown cotyledons and mitochondria in dry seed embryos could be visualized for the first time in transgenic Arabidopsis plants under normal growing conditions.

Published

1999

33. Chloroplasts are partially mobilized to the vacuole by autophagy

Author

Kohki Yoshimoto and Hiroyuki Ishida

Subjects

Chloroplasts, biology, Arabidopsis Proteins, Ribulose-Bisphosphate Carboxylase, Green Fluorescent Proteins, fungi, RuBisCO, Autophagy, Arabidopsis, food and beverages, Cell Biology, Vacuole, Photosynthesis, Cell biology, Chloroplast, Cytosol, Biochemistry, Vacuoles, Organelle, biology.protein, Chloroplast Proteins, Molecular Biology

Abstract

Excluding the central vacuole, chloroplasts constitute the largest compartment within the leaf cells of plants and contain approximately 80 percent of the total leaf nitrogen, mainly as proteins. Much of this nitrogen is allocated to the carbon-fixing enzyme in photosynthesis, Rubisco. During senescence, plants can mobilize nitrogen from chloroplasts in older leaves to other organs, such as developing seeds. Whereas bulk degradation of the cytosol and organelles in plants occurs by autophagy, the role of autophagy in the degradation of chloroplast proteins is still unclear. We have recently demonstrated that stroma-targeted green fluorescent protein (GFP), DsRed, and GFP-labeled Rubisco can be mobilized to the vacuole of living cells via Rubisco-containing bodies, in an ATG gene-dependent manner. Our results indicate the presence of a specific autophagic pathway for chloroplast stromal proteins, which does not cause chloroplast lysis. Here, we also discuss the involvement of stroma-filled tubules, stromules, which are important for the structural flexibility of the organelle, on the autophagic transfer of stromal proteins to the vacuole.

Published

2008

34. Several Strategies for Dissecting and Controlling Functions in Plant Cells

Author

Yasuo Niwa, Jen Sheen, Yoshihiro Narusaka, Hirokazu Kobayashi, Mao Sakaiya, and Kohki Yoshimoto

Subjects

biology, Transgene, Gene expression, food and beverages, Arabidopsis thaliana, RNA, Mutagenesis (molecular biology technique), biology.organism_classification, Molecular biology, Gene, Genome, Green fluorescent protein, Cell biology

Abstract

The strengths of gene promoters functional in chloroplasts have been evaluated for transient expression by particle bombardment to facilitate engineering of the chloroplast genome of Arabidopsis thaliana. The T7 RNA polymerase-recognized promoter was the most active in transgenic A. thaliana with T7 RNA polymcrase destined for chloroplasts. As a vital reporter of gene expression, an improved gene for green fluorescent protein (GFP) was chemically synthesized and resulted in approx. 100 times higher fluorescence intensity in A. thaliana. To overcome the limitations of experimentally designing of engineered proteins, we employed in vitro random mutagenesis of genes and subsequent selection of their transformants under certain conditions. The strategy was successfully applied to the photosystem II reaction center D1 protein to confer phototolerance on it.

Published

1998