Analysis of N6-methyladenosine reveals a new important mechanism regulating the salt tolerance of sugar beet (Beta vulgaris).

[1]  Yanzhou Xie,et al.  Genome-wide analysis and identification of light-harvesting chlorophyll a/b binding (LHC) gene family and BSMV-VIGS silencing TaLHC86 reduced salt tolerance in wheat. , 2023, International journal of biological macromolecules.

[2]  Zhenyi Chang,et al.  N6-methyladenosine RNA modification regulates photosynthesis during photodamage in plants , 2022, Nature Communications.

[3]  F. Ding,et al.  A plastid-targeted heat shock cognate 70-kDa protein confers osmotic stress tolerance by enhancing ROS scavenging capability , 2022, Frontiers in Plant Science.

[4]  Baoliang Zhou,et al.  GhALKBH10 negatively regulates salt tolerance in cotton. , 2022, Plant physiology and biochemistry : PPB.

[5]  R. Sederoff,et al.  Genome-wide identification of the AlkB homologs gene family, PagALKBH9B and PagALKBH10B regulated salt stress response in Populus , 2022, Frontiers in Plant Science.

[6]  M. Huang,et al.  The plasma membrane-localized OsNIP1;2 mediates internal aluminum detoxification in rice , 2022, Frontiers in Plant Science.

[7]  M. Malnoy,et al.  MdMTA-mediated m6 A modification enhances drought tolerance by promoting mRNA stability and translation efficiency of genes involved in lignin deposition and oxidative stress. , 2022, The New phytologist.

[8]  Zhikang Li,et al.  Global N6-Methyladenosine Profiling Revealed the Tissue-Specific Epitranscriptomic Regulation of Rice Responses to Salt Stress , 2022, International journal of molecular sciences.

[9]  G. Jia,et al.  FIONA1 is an RNA N6-methyladenosine methyltransferase affecting Arabidopsis photomorphogenesis and flowering , 2022, Genome biology.

[10]  Junli Liu,et al.  Genome-wide sequence identification and expression analysis of N6-methyladenosine demethylase in sugar beet (Beta vulgaris L.) under salt stress , 2022, PeerJ.

[11]  Hong Liu,et al.  Unique features of the m6A methylome and its response to drought stress in sea buckthorn (Hippophae rhamnoides Linn.) , 2021, RNA biology.

[12]  Tao Xu,et al.  Unique Features of mRNA m6A Methylomes During Expansion of Tomato (Solanum lycopersicum) Fruits. , 2021, Plant physiology.

[13]  F. Ma,et al.  The m6A reader MhYTP2 regulates MdMLO19 mRNA stability and antioxidant genes translation efficiency conferring powdery mildew resistance in apple , 2021, Plant biotechnology journal.

[14]  Hunseung Kang,et al.  ALKBH10B, an m6 A mRNA demethylase, plays a role in salt stress and ABA responses in Arabidopsis thaliana. , 2021, Physiologia plantarum.

[15]  Chuan He,et al.  RNA demethylation increases the yield and biomass of rice and potato plants in field trials , 2021, Nature Biotechnology.

[16]  Ken-ichiro Hayashi,et al.  Local regulation of auxin transport in root-apex transition zone mediates aluminium-induced Arabidopsis root growth inhibition. , 2021, The Plant journal : for cell and molecular biology.

[17]  R. Liu,et al.  Citrus NIP5;1 aquaporin regulates cell membrane water permeability and alters PIPs plasma membrane localization , 2021, Plant Molecular Biology.

[18]  G. Qin,et al.  N6-methyladenosine RNA modification regulates strawberry fruit ripening in an ABA-dependent manner , 2021, Genome Biology.

[19]  Jae-Young Yun,et al.  n6 -methyladenosine mrna methylation is important for salt stress tolerance in arabidopsis. , 2021, The Plant journal : for cell and molecular biology.

[20]  Dong-Mei Wang,et al.  A Golgi-Localized Sodium/Hydrogen Exchanger Positively Regulates Salt Tolerance by Maintaining Higher K+/Na+ Ratio in Soybean , 2021, Frontiers in Plant Science.

[21]  Jing Sun,et al.  CPSF30-L-mediated recognition of mRNA m6A modification controls alternative polyadenylation of nitrate signaling-related gene transcripts in Arabidopsis. , 2021, Molecular plant.

[22]  Junliang Li,et al.  Whole-Transcriptome RNA Sequencing Reveals the Global Molecular Responses and CeRNA Regulatory Network of mRNAs, lncRNAs, miRNAs and circRNAs in Response to Salt Stress in Sugar Beet (Beta vulgaris) , 2020, International journal of molecular sciences.

[23]  F. Wang,et al.  Analysis of N6-methyladenosine reveals a new important mechanism regulating the salt tolerance of sweet sorghum. , 2020, Plant science : an international journal of experimental plant biology.

[24]  Wangze Wu,et al.  Osmotic stress-triggered stomatal closure requires Phospholipase Dδ and hydrogen sulfide in Arabidopsis thaliana. , 2020, Biochemical and biophysical research communications.

[25]  Ming Li,et al.  Advances on Plant Ubiquitylome—From Mechanism to Application , 2020, International journal of molecular sciences.

[26]  Ajay K. Singh Soil salinization management for sustainable development: A review. , 2020, Journal of environmental management.

[27]  Hunseung Kang,et al.  Functional Characterization of a Putative RNA Demethylase ALKBH6 in Arabidopsis Growth and Abiotic Stress Responses , 2020, International journal of molecular sciences.

[28]  V. Cristofori,et al.  Osmotin: A Cationic Protein Leads to Improve Biotic and Abiotic Stress Tolerance in Plants , 2020, Plants.

[29]  Junliang Li,et al.  iTRAQ protein profile analysis of sugar beet under salt stress: different coping mechanisms in leaves and roots , 2020, BMC Plant Biology.

[30]  Wenqiang Wang,et al.  The involvement of wheat (Triticum aestivum L.) U-box E3 ubiquitin ligase TaPUB1 in salt stress tolerance. , 2020, Journal of integrative plant biology.

[31]  Zhikang Li,et al.  A U-box E3 ubiquitin ligase OsPUB67 is positively involved in drought tolerance in rice , 2019, Plant Molecular Biology.

[32]  Dong-Mei Wang,et al.  A Glycine max sodium/hydrogen exchanger enhances salt tolerance through maintaining higher Na+ efflux rate and K+/Na+ ratio in Arabidopsis , 2019, BMC Plant Biology.

[33]  Chuang Ma,et al.  Evolution of the RNA N6-Methyladenosine Methylome Mediated by Genomic Duplication1[OPEN] , 2019, Plant Physiology.

[34]  D. Yun,et al.  Lignin biosynthesis genes play critical roles in the adaptation of Arabidopsis plants to high-salt stress , 2019, Plant signaling & behavior.

[35]  Xiaojun Nie,et al.  N6‐methyladenosine regulatory machinery in plants: composition, function and evolution , 2019, Plant biotechnology journal.

[36]  D. Yun,et al.  A Critical Role of Sodium Flux via the Plasma Membrane Na+/H+ Exchanger SOS1 in the Salt Tolerance of Rice1[OPEN] , 2019, Plant Physiology.

[37]  P. L. Rodriguez,et al.  ABA inhibits myristoylation and induces shuttling of the RGLG1 E3 ligase to promote nuclear degradation of PP2CA. , 2019, The Plant journal : for cell and molecular biology.

[38]  Yi Wang,et al.  The SOS2-SCaBP8 Complex Generates and Fine-Tunes an AtANN4-Dependent Calcium Signature under Salt Stress. , 2019, Developmental cell.

[39]  Rongrong Bi,et al.  Phosphatidic Acid Directly Regulates PINOID-Dependent Phosphorylation and Activation of the PIN-FORMED2 Auxin Efflux Transporter in Response to Salt Stress , 2018, Plant Cell.

[40]  D. Bar-Zvi,et al.  Overexpression of Arabidopsis ubiquitin ligase AtPUB46 enhances tolerance to drought and oxidative stress , 2018, bioRxiv.

[41]  Yan Guo,et al.  Unraveling salt stress signaling in plants. , 2018, Journal of integrative plant biology.

[42]  Sanchita,et al.  Modulations in primary and secondary metabolic pathways and adjustment in physiological behaviour of Withania somnifera under drought stress. , 2018, Plant science : an international journal of experimental plant biology.

[43]  Yu-Sheng Chen,et al.  Dynamic transcriptomic m6A decoration: writers, erasers, readers and functions in RNA metabolism , 2018, Cell Research.

[44]  Zhike Lu,et al.  The m6A Reader ECT2 Controls Trichome Morphology by Affecting mRNA Stability in Arabidopsis[OPEN] , 2018, Plant Cell.

[45]  C. Poulsen,et al.  An m6A-YTH Module Controls Developmental Timing and Morphogenesis in Arabidopsis[OPEN] , 2018, Plant Cell.

[46]  C. Raynaud,et al.  The YTH Domain Protein ECT2 Is an m6A Reader Required for Normal Trichome Branching in Arabidopsis[OPEN] , 2018, Plant Cell.

[47]  E. Valenzuela-Soto,et al.  Glycine betaine rather than acting only as an osmolyte also plays a role as regulator in cellular metabolism. , 2018, Biochimie.

[48]  J. Marc,et al.  Phospholipase Dδ assists to cortical microtubule recovery after salt stress , 2018, Protoplasma.

[49]  Yingfang Zhu,et al.  Reciprocal Regulation of the TOR Kinase and ABA Receptor Balances Plant Growth and Stress Response. , 2018, Molecular cell.

[50]  T. Le Bihan,et al.  Nucleoredoxin guards against oxidative stress by protecting antioxidant enzymes , 2017, Proceedings of the National Academy of Sciences.

[51]  J. Kudla,et al.  A phosphoinositide-specific phospholipase C pathway elicits stress-induced Ca2+ signals and confers salt tolerance to rice. , 2017, The New phytologist.

[52]  Jian‐Kang Zhu Abiotic Stress Signaling and Responses in Plants , 2016, Cell.

[53]  Zhiqiang Zhang,et al.  MsZEP, a novel zeaxanthin epoxidase gene from alfalfa (Medicago sativa), confers drought and salt tolerance in transgenic tobacco , 2016, Plant Cell Reports.

[54]  Guodong Yang,et al.  SCF E3 ligase PP2-B11 plays a positive role in response to salt stress in Arabidopsis , 2015, Journal of experimental botany.

[55]  B. Khan,et al.  Abiotic stress induces change in Cinnamoyl CoA Reductase (CCR) protein abundance and lignin deposition in developing seedlings of Leucaena leucocephala , 2015, Physiology and Molecular Biology of Plants.

[56]  Kazuki Saito,et al.  Roles of lipids as signaling molecules and mitigators during stress response in plants. , 2014, The Plant journal : for cell and molecular biology.

[57]  S. Natarajan,et al.  Characterization of Developmental- and Stress-Mediated Expression of Cinnamoyl-CoA Reductase in Kenaf (Hibiscus cannabinus L.) , 2014, TheScientificWorldJournal.

[58]  Alexander Goesmann,et al.  The genome of the recently domesticated crop plant sugar beet (Beta vulgaris) , 2013, Nature.

[59]  D. Murphy,et al.  Glycine betaine biosynthesis in saltbushes (Atriplex spp.) under salinity stress , 2013, Biologia.

[60]  Nobutoshi Yamaguchi,et al.  The role of CORYMBOSA1/BIG and auxin in the growth of Arabidopsis pedicel and internode. , 2013, Plant science : an international journal of experimental plant biology.

[61]  R. Bressan,et al.  The Salt Overly Sensitive (SOS) pathway: established and emerging roles. , 2013, Molecular plant.

[62]  M. Kupiec,et al.  Topology of the human and mouse m6A RNA methylomes revealed by m6A-seq , 2012, Nature.

[63]  A. Banaś,et al.  The upregulation of thiamine (vitamin B1) biosynthesis in Arabidopsis thaliana seedlings under salt and osmotic stress conditions is mediated by abscisic acid at the early stages of this stress response , 2012, BMC Plant Biology.

[64]  Chengqi Yi,et al.  N6-Methyladenosine in Nuclear RNA is a Major Substrate of the Obesity-Associated FTO , 2011, Nature chemical biology.

[65]  S. Balzergue,et al.  Characterization of a cinnamoyl-CoA reductase 1 (CCR1) mutant in maize: effects on lignification, fibre development, and global gene expression , 2011, Journal of experimental botany.

[66]  Zhujun Zhu,et al.  Functional divergence of the NIP III subgroup proteins involved altered selective constraints and positive selection , 2010, BMC Plant Biology.

[67]  Wenhua Zhang,et al.  Phosphatidic acid mediates salt stress response by regulation of MPK6 in Arabidopsis thaliana. , 2010, The New phytologist.

[68]  A. Goyer Thiamine in plants: aspects of its metabolism and functions. , 2010, Phytochemistry.

[69]  S. Chen,et al.  The Arabidopsis Chaperone J3 Regulates the Plasma Membrane H+-ATPase through Interaction with the PKS5 Kinase[C][W] , 2010, Plant Cell.

[70]  Qun Zhang,et al.  Phospholipase Dα1 and Phosphatidic Acid Regulate NADPH Oxidase Activity and Production of Reactive Oxygen Species in ABA-Mediated Stomatal Closure in Arabidopsis[C][W][OA] , 2009, The Plant Cell Online.

[71]  R. Mittler,et al.  Thiamin Confers Enhanced Tolerance to Oxidative Stress in Arabidopsis1[W][OA] , 2009, Plant Physiology.

[72]  A. Murphy,et al.  Post-transcriptional regulation of auxin transport proteins: cellular trafficking, protein phosphorylation, protein maturation, ubiquitination, and membrane composition. , 2009, Journal of experimental botany.

[73]  K. Ostrowska,et al.  Modulation of thiamine metabolism in Zea mays seedlings under conditions of abiotic stress , 2008 .

[74]  Byeong-Ha Lee,et al.  Overexpression of Arabidopsis ZEP enhances tolerance to osmotic stress. , 2008, Biochemical and biophysical research communications.

[75]  Yoshihiro Yamanishi,et al.  KEGG for linking genomes to life and the environment , 2007, Nucleic Acids Res..

[76]  Jian-Kang Zhu,et al.  Arabidopsis Protein Kinase PKS5 Inhibits the Plasma Membrane H+-ATPase by Preventing Interaction with 14-3-3 Protein , 2007, The Plant Cell Online.

[77]  C. D'onofrio,et al.  Uptake of sodium in quince, sugar beet, and wheat protoplasts determined by the fluorescent sodium-binding dye benzofuran isophthalate. , 2005, Journal of plant physiology.

[78]  L. Herrera-Estrella,et al.  An Auxin Transport Independent Pathway Is Involved in Phosphate Stress-Induced Root Architectural Alterations in Arabidopsis. Identification of BIG as a Mediator of Auxin in Pericycle Cell Activation1 , 2005, Plant Physiology.

[79]  P. Berggren,et al.  Cytosolic Multiple Inositol Polyphosphate Phosphatase in the Regulation of Cytoplasmic Free Ca2+ Concentration* , 2003, Journal of Biological Chemistry.

[80]  M. Tamoi,et al.  Regulation and function of ascorbate peroxidase isoenzymes. , 2002, Journal of experimental botany.

[81]  Jian-Kang Zhu,et al.  The Putative Plasma Membrane Na+/H+ Antiporter SOS1 Controls Long-Distance Na+ Transport in Plants Article, publication date, and citation information can be found at www.plantcell.org/cgi/doi/10.1105/tpc.010371. , 2002, The Plant Cell Online.

[82]  J. Hsuan,et al.  The PITP family of phosphatidylinositol transfer proteins , 2001, Genome Biology.

[83]  J. Chory,et al.  BIG: a calossin-like protein required for polar auxin transport in Arabidopsis. , 2001, Genes & development.

[84]  P. A. Rea,et al.  Vacuolar H(+) pyrophosphatases: from the evolutionary backwaters into the mainstream. , 2001, Trends in plant science.

[85]  B. Drøbak,et al.  Inositol(1,4,5)trisphosphate production in plant cells: an early response to salinity and hyperosmotic stress , 2000, FEBS letters.

[86]  M. Ashburner,et al.  Gene Ontology: tool for the unification of biology , 2000, Nature Genetics.

[87]  I. Ferguson,et al.  Release of Ca2+ from plant hypocotyl microsomes by inositol-1,4,5-trisphosphate. , 1985, Biochemical and biophysical research communications.

[88]  N. Murata,et al.  Glycinebetaine protects plants against abiotic stress: mechanisms and biotechnological applications. , 2011, Plant, cell & environment.

[89]  B. Heuer,et al.  Adjustment, growth, photosynthesis and transpiration of sugar beet plants exposed to saline conditions , 1985 .