Lignin-polysaccharide interactions in plant secondary cell walls revealed by solid-state NMR
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[1] A. French,et al. Atomic resolution of cotton cellulose structure enabled by dynamic nuclear polarization solid-state NMR , 2018, Cellulose.
[2] P. Azadi,et al. Molecular architecture of fungal cell walls revealed by solid-state NMR , 2018, Nature Communications.
[3] J. R. Long,et al. A quasi-optical and corrugated waveguide microwave transmission system for simultaneous dynamic nuclear polarization NMR on two separate 14.1 T spectrometers. , 2018, Journal of magnetic resonance.
[4] M. Hong,et al. Direct Determination of Hydroxymethyl Conformations of Plant Cell Wall Cellulose Using 1H Polarization Transfer Solid-State NMR. , 2018, Biomacromolecules.
[5] M. Jarvis. Structure of native cellulose microfibrils, the starting point for nanocellulose manufacture , 2018, Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences.
[6] Thomas J. Simmons,et al. An even pattern of xylan substitution is critical for interaction with cellulose in plant cell walls , 2017, Nature Plants.
[7] N. Mosier,et al. Atomic-Level Structure Characterization of Biomass Pre- and Post-Lignin Treatment by Dynamic Nuclear Polarization-Enhanced Solid-State NMR. , 2017, The journal of physical chemistry. A.
[8] Thomas J. Simmons,et al. Folding of xylan onto cellulose fibrils in plant cell walls revealed by solid-state NMR , 2016, Nature Communications.
[9] Ying Gu,et al. Cellulose synthase complexes act in a concerted fashion to synthesize highly aggregated cellulose in secondary cell walls of plants , 2016, Proceedings of the National Academy of Sciences.
[10] Hui Yang,et al. Cellulose Structural Polymorphism in Plant Primary Cell Walls Investigated by High-Field 2D Solid-State NMR Spectroscopy and Density Functional Theory Calculations. , 2016, Biomacromolecules.
[11] Jonathan K. Williams,et al. Aromatic spectral editing techniques for magic-angle-spinning solid-state NMR spectroscopy of uniformly (13)C-labeled proteins. , 2015, Solid state nuclear magnetic resonance.
[12] Yong Bum Park,et al. Cellulose-Pectin Spatial Contacts Are Inherent to Never-Dried Arabidopsis Primary Cell Walls: Evidence from Solid-State Nuclear Magnetic Resonance1[OPEN] , 2015, Plant Physiology.
[13] M. Pauly,et al. Engineering of plant cell walls for enhanced biofuel production. , 2015, Current opinion in plant biology.
[14] Daniel Lee,et al. Is solid-state NMR enhanced by dynamic nuclear polarization? , 2015, Solid state nuclear magnetic resonance.
[15] Thomas J. Simmons,et al. Probing the molecular architecture of Arabidopsis thaliana secondary cell walls using two- and three-dimensional (13)C solid state nuclear magnetic resonance spectroscopy. , 2015, Biochemistry.
[16] R. Griffin,et al. Mechanisms of dynamic nuclear polarization in insulating solids. , 2015, Journal of magnetic resonance.
[17] Jonathan K. Williams,et al. Relaxation-compensated difference spin diffusion NMR for detecting 13C–13C long-range correlations in proteins and polysaccharides , 2014, Journal of biomolecular NMR.
[18] C. N. Stewart,et al. Altered lignin biosynthesis using biotechnology to improve lignocellulosic biofuel feedstocks. , 2014, Plant biotechnology journal.
[19] Y. Park,et al. Water-polysaccharide interactions in the primary cell wall of Arabidopsis thaliana from polarization transfer solid-state NMR. , 2014, Journal of the American Chemical Society.
[20] Paul Dupree,et al. The pattern of xylan acetylation suggests xylan may interact with cellulose microfibrils as a twofold helical screw in the secondary plant cell wall of Arabidopsis thaliana , 2014, The Plant journal : for cell and molecular biology.
[21] D. Mohnen,et al. A review of xylan and lignin biosynthesis: Foundation for studying Arabidopsis irregular xylem mutants with pleiotropic phenotypes , 2014, Critical reviews in biochemistry and molecular biology.
[22] C. Haigler,et al. Molecular Modeling and Imaging of Initial Stages of Cellulose Fibril Assembly: Evidence for a Disordered Intermediate Stage , 2014, PloS one.
[23] Michael Ladisch,et al. Disruption of Mediator rescues the stunted growth of a lignin-deficient Arabidopsis mutant , 2014, Nature.
[24] Jeremy C. Smith,et al. Common processes drive the thermochemical pretreatment of lignocellulosic biomass , 2014 .
[25] S. Hill,et al. Wide-Angle X-Ray Scattering and Solid-State Nuclear Magnetic Resonance Data Combined to Test Models for Cellulose Microfibrils in Mung Bean Cell Walls1 , 2013, Plant Physiology.
[26] M. Rosay,et al. Highly efficient, water-soluble polarizing agents for dynamic nuclear polarization at high frequency. , 2013, Angewandte Chemie.
[27] J. Kikuchi,et al. Comprehensive signal assignment of 13C-labeled lignocellulose using multidimensional solution NMR and 13C chemical shift comparison with solid-state NMR. , 2013, Analytical chemistry.
[28] T. Polenova,et al. Broadband homonuclear correlation spectroscopy driven by combined R2(n)(v) sequences under fast magic angle spinning for NMR structural analysis of organic and biological solids. , 2013, Journal of magnetic resonance.
[29] R. Griffin,et al. High frequency dynamic nuclear polarization. , 2013, Accounts of chemical research.
[30] C. Copéret,et al. Dynamic nuclear polarization surface enhanced NMR spectroscopy. , 2013, Accounts of chemical research.
[31] D. Wemmer,et al. Solution-state 2D NMR spectroscopy of plant cell walls enabled by a dimethylsulfoxide-d6/1-ethyl-3-methylimidazolium acetate solvent. , 2013, Analytical chemistry.
[32] Masato Yoshida,et al. Proposed supramolecular structure of lignin in softwood tracheid compound middle lamella regions , 2012 .
[33] O. Zabotina,et al. Pectin-cellulose interactions in the Arabidopsis primary cell wall from two-dimensional magic-angle-spinning solid-state nuclear magnetic resonance. , 2012, Biochemistry.
[34] K. Schmidt-Rohr,et al. Spectral editing of two-dimensional magic-angle-spinning solid-state NMR spectra for protein resonance assignment and structure determination , 2012, Journal of biomolecular NMR.
[35] Daniel J. Cosgrove,et al. Comparative structure and biomechanics of plant primary and secondary cell walls , 2012, Front. Plant Sci..
[36] S. Mansfield,et al. Whole plant cell wall characterization using solution-state 2D NMR , 2012, Nature Protocols.
[37] K. Mazeau,et al. Molecular modeling of the structural and dynamical properties of secondary plant cell walls: influence of lignin chemistry. , 2012, The journal of physical chemistry. B.
[38] H. Oschkinat,et al. Practical aspects of high-sensitivity multidimensional ¹³C MAS NMR spectroscopy of perdeuterated proteins. , 2012, Journal of magnetic resonance.
[39] V. T. Forsyth,et al. Nanostructure of cellulose microfibrils in spruce wood , 2011, Proceedings of the National Academy of Sciences.
[40] A. V. van Heiningen,et al. Fractionation and Characterization of Completely Dissolved Ball Milled Hardwood , 2011 .
[41] B. Sundberg,et al. Ultra-structural organisation of cell wall polymers in normal and tension wood of aspen revealed by polarisation FTIR microspectroscopy , 2011, Planta.
[42] Chris Somerville,et al. Feedstocks for Lignocellulosic Biofuels , 2010, Science.
[43] M. Paulsson,et al. 2D-NMR (HSQC) difference spectra between specifically 13C-enriched and unenriched protolignin of Ginkgo biloba obtained in the solution state of whole cell wall material , 2009 .
[44] P. Callaghan,et al. Nature's nanocomposites: a new look at molecular architecture in wood cell walls. , 2009 .
[45] John Ralph,et al. Lignin engineering. , 2008, Current opinion in plant biology.
[46] A. Lesage,et al. The refocused INADEQUATE MAS NMR experiment in multiple spin-systems: interpreting observed correlation peaks and optimising lineshapes. , 2007, Journal of magnetic resonance.
[47] R. Service. Biofuel Researchers Prepare to Reap a New Harvest , 2007, Science.
[48] M. Engelhard,et al. Secondary structure, dynamics, and topology of a seven-helix receptor in native membranes, studied by solid-state NMR spectroscopy. , 2007, Angewandte Chemie.
[49] Charlotte K. Williams,et al. The Path Forward for Biofuels and Biomaterials , 2006, Science.
[50] A. Lesage,et al. Proton to carbon-13 INEPT in solid-state NMR spectroscopy. , 2005, Journal of the American Chemical Society.
[51] B. Cathala,et al. Aggregation during coniferyl alcohol polymerization in pectin solution: a biomimetic approach of the first steps of lignification. , 2005, Biomacromolecules.
[52] P. Schopfer,et al. Structure and distribution of lignin in primary and secondary cell walls of maize coleoptiles analyzed by chemical and immunological probes , 1997, Planta.
[53] Lennart Salmén,et al. Micromechanical understanding of the cell-wall structure. , 2004, Comptes rendus biologies.
[54] T. Jeffries. Biodegradation of lignin-carbohydrate complexes , 1990, Biodegradation.
[55] J. Ralph,et al. Model studies of ferulate-coniferyl alcohol cross-product formation in primary maize walls: implications for lignification in grasses. , 2002, Journal of agricultural and food chemistry.
[56] G. Hoatson,et al. Modelling one‐ and two‐dimensional solid‐state NMR spectra , 2002 .
[57] L. Donaldson. Lignification and lignin topochemistry - an ultrastructural view. , 2001, Phytochemistry.
[58] J. Ralph,et al. Cross-linking of maize walls by ferulate dimerization and incorporation into lignin. , 2000, Journal of agricultural and food chemistry.
[59] H. Schnyder,et al. Kinetics and relative significance of remobilized and current C and N incorporation in leaf and root growth zones of Lolium perenne after defoliation: assessment by 13C and 15N steady-state labelling , 1997 .
[60] R. Atalla,et al. Cellulose-Lignin Interactions (A Computational Study) , 1995, Plant physiology.
[61] R. Atalla,et al. Raman Microprobe Evidence for Lignin Orientation in the Cell Walls of Native Woody Tissue , 1985, Science.
[62] G. Smakman,et al. ENERGY-METABOLISM OF PLANTAGO-LANCEOLATA, AS AFFECTED BY CHANGE IN ROOT TEMPERATURE , 1982 .
[63] S. Opella,et al. Protein dynamics by solid-state NMR: aromatic rings of the coat protein in fd bacteriophage. , 1982, Proceedings of the National Academy of Sciences of the United States of America.
[64] D. Torchia. The measurement of proton-enhanced carbon-13 T1 values by a method which suppresses artifacts , 1978 .