Regulation of cellulose synthesis in response to stress.

The cell wall is a complex polysaccharide network that provides stability and protection to the plant and is one of the first layers of biotic and abiotic stimuli perception. A controlled remodeling of the primary cell wall is essential for the plant to adapt its growth to environmental stresses. Cellulose, the main component of plant cell walls is synthesized by plasma membrane-localized cellulose synthases moving along cortical microtubule tracks. Recent advancements demonstrate a tight regulation of cellulose synthesis at the primary cell wall by phytohormone networks. Stress-induced perturbations at the cell wall that modify cellulose synthesis and microtubule arrangement activate similar phytohormone-based stress response pathways. The integration of stress perception at the primary cell wall and downstream responses are likely to be tightly regulated by phytohormone signaling pathways in the context of cellulose synthesis and microtubule arrangement.

[1]  I. Sharma,et al.  Versatile roles of brassinosteroid in plants in the context of its homoeostasis, signaling and crosstalks , 2015, Front. Plant Sci..

[2]  C. Simmons,et al.  Establishment of a Wolbachia Superinfection in Aedes aegypti Mosquitoes as a Potential Approach for Future Resistance Management , 2016, PLoS pathogens.

[3]  Xuelu Wang,et al.  Brassinosteroids can regulate cellulose biosynthesis by controlling the expression of CESA genes in Arabidopsis , 2011, Journal of experimental botany.

[4]  M. S. Mukhtar,et al.  Independently Evolved Virulence Effectors Converge onto Hubs in a Plant Immune System Network , 2011, Science.

[5]  Qing Liu,et al.  Overexpression of the brassinosteroid biosynthetic gene DWF4 in Brassica napus simultaneously increases seed yield and stress tolerance , 2016, Scientific Reports.

[6]  Iko T. Koevoets,et al.  The Arabidopsis leucine-rich repeat receptor kinase MIK2/LRR-KISS connects cell wall integrity sensing, root growth and response to abiotic and biotic stresses , 2017, PLoS genetics.

[7]  Ana I. Caño-Delgado,et al.  Reduced cellulose synthesis invokes lignification and defense responses in Arabidopsis thaliana. , 2003, The Plant journal : for cell and molecular biology.

[8]  Patanjali Varanasi,et al.  Loss of Cellulose Synthase-Like F6 Function Affects Mixed-Linkage Glucan Deposition, Cell Wall Mechanical Properties, and Defense Responses in Vegetative Tissues of Rice1[C][W][OA] , 2012, Plant Physiology.

[9]  Yufeng Wang,et al.  Cellular Tracking and Gene Profiling of Fusarium graminearum during Maize Stalk Rot Disease Development Elucidates Its Strategies in Confronting Phosphorus Limitation in the Host Apoplast , 2016, PLoS pathogens.

[10]  L. Trindade,et al.  The Cellulase KORRIGAN Is Part of the Cellulose Synthase Complex1[W] , 2014, Plant Physiology.

[11]  F. Ausubel,et al.  Activation of defense response pathways by OGs and Flg22 elicitors in Arabidopsis seedlings. , 2008, Molecular plant.

[12]  Mark F. Davis,et al.  Down-Regulation of KORRIGAN-Like Endo-β-1,4-Glucanase Genes Impacts Carbon Partitioning, Mycorrhizal Colonization and Biomass Production in Populus , 2016, Front. Plant Sci..

[13]  Lior Artzi,et al.  Cellulosomes: bacterial nanomachines for dismantling plant polysaccharides , 2016, Nature Reviews Microbiology.

[14]  René Schneider,et al.  A Mechanism for Sustained Cellulose Synthesis during Salt Stress , 2015, Cell.

[15]  A. Bottin,et al.  Cellulose Binding Domains of a Phytophthora Cell Wall Protein Are Novel Pathogen-Associated Molecular Patterns[W] , 2006, The Plant Cell Online.

[16]  Martin Bringmann,et al.  POM-POM2/CELLULOSE SYNTHASE INTERACTING1 Is Essential for the Functional Association of Cellulose Synthase and Microtubules in Arabidopsis[W][OA] , 2012, Plant Cell.

[17]  M. Yuan,et al.  Salt tolerance requires cortical microtubule reorganization in Arabidopsis. , 2007, Plant & cell physiology.

[18]  Sebastian Wolf Plant cell wall signalling and receptor-like kinases. , 2017, The Biochemical journal.

[19]  C. Zipfel,et al.  Cellulose-Derived Oligomers Act as Damage-Associated Molecular Patterns and Trigger Defense-Like Responses1 , 2017, Plant Physiology.

[20]  Jacob L.W. Morgan,et al.  Crystallographic snapshot of cellulose synthesis and membrane translocation , 2012, Nature.

[21]  C. Voigt,et al.  Callose biosynthesis in Arabidopsis with a focus on pathogen response: what we have learned within the last decade. , 2014, Annals of botany.

[22]  Sang Yeol Lee,et al.  Salt tolerance of Arabidopsis thaliana requires maturation of N-glycosylated proteins in the Golgi apparatus , 2008, Proceedings of the National Academy of Sciences.

[23]  H. Xue,et al.  The Arabidopsis ARCP Protein, CSI1, Which Is Required for Microtubule Stability, Is Necessary for Root and Anther Development[W] , 2012, Plant Cell.

[24]  Staffan Persson,et al.  Toward a Systems Approach to Understanding Plant Cell Walls , 2004, Science.

[25]  S. Schornack,et al.  Host Protein BSL1 Associates with Phytophthora infestans RXLR Effector AVR2 and the Solanum demissum Immune Receptor R2 to Mediate Disease Resistance[C][W] , 2012, Plant Cell.

[26]  Weidong Tian,et al.  Cellulose synthesis genes CESA6 and CSI1 are important for salt stress tolerance in Arabidopsis. , 2016, Journal of integrative plant biology.

[27]  C. Albenne,et al.  Plant cell wall proteomics: mass spectrometry data, a trove for research on protein structure/function relationships. , 2009, Molecular plant.

[28]  B. Henrissat,et al.  Understanding plant cell-wall remodelling during the symbiotic interaction between Tuber melanosporum and Corylus avellana using a carbohydrate microarray , 2016, Planta.

[29]  D. Ehrhardt,et al.  Arabidopsis cortical microtubules position cellulose synthase delivery to the plasma membrane and interact with cellulose synthase trafficking compartments , 2009, Nature Cell Biology.

[30]  I. Burgert,et al.  CHITINASE-LIKE1/POM-POM1 and Its Homolog CTL2 Are Glucan-Interacting Proteins Important for Cellulose Biosynthesis in Arabidopsis[W][OA] , 2012, Plant Cell.

[31]  Sandra Pelletier,et al.  A Receptor-like Kinase Mediates the Response of Arabidopsis Cells to the Inhibition of Cellulose Synthesis , 2007, Current Biology.

[32]  Ying Gu,et al.  Cellulose synthase interactive protein 1 (CSI1) mediates the intimate relationship between cellulose microfibrils and cortical microtubules , 2012, Plant signaling & behavior.

[33]  A. Timmers,et al.  Comparative analysis of the tubulin cytoskeleton organization in nodules of Medicago truncatula and Pisum sativum: bacterial release and bacteroid positioning correlate with characteristic microtubule rearrangements. , 2016, The New phytologist.

[34]  D. Ehrhardt,et al.  Arabidopsis MICROTUBULE DESTABILIZING PROTEIN40 Is Involved in Brassinosteroid Regulation of Hypocotyl Elongation[C][W][OA] , 2012, Plant Cell.

[35]  R. Reimer,et al.  Nanoscale glucan polymer network causes pathogen resistance , 2014, Scientific Reports.

[36]  S. Angers,et al.  A Bacterial Acetyltransferase Destroys Plant Microtubule Networks and Blocks Secretion , 2012, PLoS pathogens.

[37]  A. Bacic,et al.  The barley (Hordeum vulgare) cellulose synthase-like D2 gene (HvCslD2) mediates penetration resistance to host-adapted and nonhost isolates of the powdery mildew fungus. , 2016, The New phytologist.

[38]  S. Clouse Brassinosteroid Signal Transduction: From Receptor Kinase Activation to Transcriptional Networks Regulating Plant Development , 2011, Plant Cell.

[39]  Y. Saijo,et al.  A look at plant immunity through the window of the multitasking coreceptor BAK1. , 2017, Current opinion in plant biology.

[40]  Sun-Hee Kim,et al.  Arabidopsis hot2 encodes an endochitinase-like protein that is essential for tolerance to heat, salt and drought stresses. , 2007, The Plant journal : for cell and molecular biology.

[41]  C. Staiger MAPping the Function of Phytopathogen Effectors. , 2016, Cell host & microbe.

[42]  V. Lionetti,et al.  Plant cell wall dynamics and wall-related susceptibility in plant–pathogen interactions , 2014, Front. Plant Sci..

[43]  Trevor M. Nolan,et al.  Selective Autophagy of BES 1 Mediated by DSK 2 Balances Plant Growth and Survival , 2019 .

[44]  Benoit Landrein,et al.  Mechanical Stress Acts via Katanin to Amplify Differences in Growth Rate between Adjacent Cells in Arabidopsis , 2012, Cell.

[45]  Shuai Ding,et al.  Decision Support for Personalized Cloud Service Selection through Multi-Attribute Trustworthiness Evaluation , 2014, PloS one.

[46]  Sandra Pelletier,et al.  Resistance against Herbicide Isoxaben and Cellulose Deficiency Caused by Distinct Mutations in Same Cellulose Synthase Isoform CESA61 , 2002, Plant Physiology.

[47]  Seth Debolt,et al.  Acetobixan, an Inhibitor of Cellulose Synthesis Identified by Microbial Bioprospecting , 2014, PloS one.

[48]  K. Shinozaki,et al.  NLR locus-mediated trade-off between abiotic and biotic stress adaptation in Arabidopsis , 2017, Nature Plants.

[49]  M. Reichelt,et al.  N-Acyl-Homoserine Lactone Primes Plants for Cell Wall Reinforcement and Induces Resistance to Bacterial Pathogens via the Salicylic Acid/Oxylipin Pathway[C][W][OPEN] , 2014, Plant Cell.

[50]  Damian Gruszka,et al.  The Brassinosteroid Signaling Pathway—New Key Players and Interconnections with Other Signaling Networks Crucial for Plant Development and Stress Tolerance , 2013, International journal of molecular sciences.

[51]  Arun Sampathkumar,et al.  Subcellular and supracellular mechanical stress prescribes cytoskeleton behavior in Arabidopsis cotyledon pavement cells , 2014, eLife.

[52]  D. Douchkov,et al.  Down-regulation of the glucan synthase-like 6 gene (HvGsl6) in barley leads to decreased callose accumulation and increased cell wall penetration by Blumeria graminis f. sp. hordei. , 2016, The New phytologist.

[53]  Trevor M. Nolan,et al.  Selective Autophagy of BES1 Mediated by DSK2 Balances Plant Growth and Survival. , 2017, Developmental cell.

[54]  C. Médigue,et al.  Genome Features of the Endophytic Actinobacterium Micromonospora lupini Strain Lupac 08: On the Process of Adaptation to an Endophytic Life Style? , 2014, PloS one.

[55]  A. Fernie,et al.  Cellulose-Microtubule Uncoupling Proteins Prevent Lateral Displacement of Microtubules during Cellulose Synthesis in Arabidopsis. , 2016, Developmental cell.

[56]  D. Mohnen Pectin structure and biosynthesis. , 2008, Current opinion in plant biology.

[57]  B. Dumas,et al.  Pathogen-associated molecular pattern-triggered immunity and resistance to the root pathogen Phytophthora parasitica in Arabidopsis , 2013, Journal of experimental botany.

[58]  Lili Huang,et al.  PSTha5a23, a candidate effector from the obligate biotrophic pathogen Puccinia striiformis f. sp. tritici, is involved in plant defense suppression and rust pathogenicity , 2017, Environmental microbiology.

[59]  E. Weiler,et al.  Oligogalacturonides and chitosan activate plant defensive genes through the octadecanoid pathway. , 1995, Proceedings of the National Academy of Sciences of the United States of America.

[60]  S. Persson,et al.  The impact of abiotic factors on cellulose synthesis. , 2016, Journal of experimental botany.

[61]  Tobias I. Baskin,et al.  On the alignment of cellulose microfibrils by cortical microtubules: A review and a model , 2005, Protoplasma.

[62]  Grant Calder,et al.  The rotation of cellulose synthase trajectories is microtubule dependent and influences the texture of epidermal cell walls in Arabidopsis hypocotyls , 2010, Journal of Cell Science.

[63]  H. Nakayashiki,et al.  Cellulases belonging to glycoside hydrolase families 6 and 7 contribute to the virulence of Magnaporthe oryzae. , 2012, Molecular plant-microbe interactions : MPMI.

[64]  C. Somerville,et al.  BRASSINOSTEROID INSENSITIVE2 negatively regulates cellulose synthesis in Arabidopsis by phosphorylating cellulose synthase 1 , 2017, Proceedings of the National Academy of Sciences.

[65]  Staffan Persson,et al.  The cell biology of cellulose synthesis. , 2014, Annual review of plant biology.

[66]  D. Ehrhardt,et al.  Visualization of Cellulose Synthase Demonstrates Functional Association with Microtubules , 2006, Science.

[67]  K. Shinozaki,et al.  MCA1 and MCA2 That Mediate Ca2+ Uptake Have Distinct and Overlapping Roles in Arabidopsis1[W][OA] , 2010, Plant Physiology.

[68]  Patrick Schweizer,et al.  Differential accumulation of callose, arabinoxylan and cellulose in nonpenetrated versus penetrated papillae on leaves of barley infected with Blumeria graminis f. sp. hordei. , 2014, The New phytologist.

[69]  Christian G Elowsky,et al.  A Bacterial Effector Co-opts Calmodulin to Target the Plant Microtubule Network. , 2016, Cell host & microbe.

[70]  Staffan Persson,et al.  Phytohormones and the cell wall in Arabidopsis during seedling growth. , 2010, Trends in plant science.

[71]  John P. Rathjen,et al.  Plant immunity: towards an integrated view of plant–pathogen interactions , 2010, Nature Reviews Genetics.

[72]  M. Aluru,et al.  Mechanisms and networks for brassinosteroid regulated gene expression. , 2013, Current opinion in plant biology.