{"id":51,"date":"2013-12-16T16:45:01","date_gmt":"2013-12-16T16:45:01","guid":{"rendered":"http:\/\/braybrookgroup.wordpress.com\/?page_id=51"},"modified":"2021-04-29T18:12:30","modified_gmt":"2021-04-30T01:12:30","slug":"publications","status":"publish","type":"page","link":"https:\/\/sites.lifesci.ucla.edu\/mcdb-braybrook\/publications\/","title":{"rendered":"Publications"},"content":{"rendered":"

M Linardi\u0107 and SA Braybrook. (2020) Identification and selection of optimal reference genes for qPCR-based gene expression analysis in Fucus distichus under various abiotic stresses. bioRxiv<\/a> (and PLoS One<\/a>)<\/p>\n

\"\"<\/p>\n

M Linardi\u0107, SJ Cokus, M Pellegrini, and SA Braybrook. (2020) Growth of the Fucus embryo: insights into wall-mediated cell expansion through mechanics and transcriptomics. bioRxiv<\/a><\/p>\n

\"\"<\/p>\n

 <\/p>\n

SA Braybrook. (2019)\u00a0Auxin and Organogenesis: Initiation of Organs and Nurturing a Scientific Spirit. Plant Cell<\/a>. *part of the Reflections on The Plant Cell Classics Series.<\/em><\/p>\n

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 <\/p>\n

JL Kaplan, TA Torode, F Bou Daher, and SA Braybrook. 2019.\u00a0On Pectin Methyl-esterification: Implications for In vitro and In vivo Viscoelasticity. bioRxiv<\/a>.<\/p>\n

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 <\/p>\n

RV Vofeley, J Gallagher, GD Pisano, M Bartlett, SA Braybrook. (2018).\u00a0Of puzzles and pavements: a quantitative exploration of leaf epidermal cell shape. bioRxiv\u00a0<\/a>and The New Phytologist<\/a><\/p>\n

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F Bou Daher, Y Chen, B Bozorg, J Clough, H Jonsson, SA Braybrook<\/strong>. (2018).\u00a0Anisotropic growth is achieved through the additive mechanical effect of material anisotropy and elastic asymmetry. bioRxiv<\/a>\u00a0and eLife<\/a><\/p>\n

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 <\/p>\n

S Robinson<\/span>,\u00a0M Huflejt<\/span>,\u00a0P Barbier de Reuille<\/span>,\u00a0SA Braybrook<\/span><\/strong>,\u00a0M Schorderet<\/span>,\u00a0D Reinhardt<\/span>,\u00a0C Kuhlemeier. (2017).\u00a0\u00a0An automated confocal micro-extensometer enables in vivo quantification of mechanical properties with cellular resolution. The Plant Cell<\/a>.\u00a0<\/span><\/p>\n

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TA Torode, RE O’Neill, SE Marcus, V Cornuault, S Pose-Albacete, RP Lauder, SK Kracun, MG Rydahl, MCF Andersen, WGT Willats, SA Braybrook<\/strong>, BJTownsend, MH Clausen, JP Knox. (2017).\u00a0Branched pectic galactan in phloem-sieve-element cell walls: implications for cell mechanics. Plant Physiology<\/a>.\"\"<\/a><\/p>\n

M Linardic and S Braybrook<\/strong>. (2017). Towards An Understanding Of Spiral Patterning In The Sargassum<\/em> muticum<\/em> Shoot Apex. bioRxiv<\/a>\u00a0<\/em>and\u00a0<\/em>Scientific Reports<\/a><\/p>\n

\"sargassum<\/p>\n

R Carter, H Woolfenden, A Baillie, S Amsbury, S Carroll, E Healicon, S Sovatzoglou, S Braybrook<\/strong>, JE Gray, J Hobbs, Richard J. Morris, AJ Fleming. (2017).\u00a0Stomatal Opening Involves Polar, Not Radial, Stiffening Of Guard Cells. Current Biology<\/a><\/p>\n

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A Weber, S Braybrook<\/strong>, M Huflejt<\/span>, G Mosca, A L Routier-Kierzkowska<\/span>, R S Smith. (2015). <\/span><\/span>Measuring the mechanical properties of plant cells by combining micro-indentation with osmotic treatments. Journal of Experimental Botany.<\/a><\/span> first published online <\/span>April 7, 2015<\/span><\/cite><\/p>\n

\"Screenshot<\/a><\/p>\n

Z Kong, M Ioki, SA Braybrook<\/strong>, S Li, Z-H Ye, Y-RJ Lee, T Hotta, A Chang, J Tian, G Wang, B Liu (2015). Kinesin-4 functions in vesicular transport on cortical microtubules and regulates cell wall mechanics during cell elongation in plants. Molecular Plant <\/a>Online Advance<\/p>\n

\"kinesin\"<\/a><\/p>\n

\u00a0SA Braybrook<\/strong> (2015) Measuring the elasticity of plant cells with Atomic Force Microscopy. In: Biophysical Methods in Cell Biology, eds. E Paluch. Elsevier<\/a>.<\/em><\/p>\n

\"methods\"<\/a><\/p>\n

SA Braybrook<\/strong>, A Peaucelle (2013) Mechano-Chemical Aspects of Organ Formation in Arabidopsis thaliana: The Relationship between Auxin and Pectin.\u00a0PLoS ONE<\/a>\u00a08(3): e57813. doi:10.1371\/journal.pone.0057813<\/p>\n

\"PLOSOne\"<\/a><\/p>\n

DH Chitwood, LR Headlan1, ARanjan,\u00a0SA Braybrook,<\/strong>\u00a0DP Koenig, C Martinez, C Kuhlemeier, RS Smith, and NR Sinha. 2012. Leaf asymmetry as a developmental constraint imposed by auxin-dependent phyllotactic patterning.\u00a0The Plant Cell<\/a>. 24:1-10.<\/p>\n

\"PlCell\"<\/a><\/p>\n

A Peaucelle*,\u00a0SA Braybrook*<\/strong>, L Le Guillou, E Bron, C Kuhlemeier, H Hofte. 2011. Pectin-Induced Changes in Cell Wall Mechanics Underlie Organ Initiation in Arabidopsis.Current Biology<\/a>. Online Oct. 6th. *Co-first authors<\/p>\n

\"CurrBiol\"<\/a><\/p>\n

SL Stone,\u00a0SA Braybrook<\/strong>, SL Paula, LW Kwong, J Meuser, J Pelletier, T-F Hsieh, RL Fischer, RB Goldberg, JJ Harada. 2008. Arabidopsis LEAFY COTYLEDON2 Induces Maturation Traits and Auxin Activity: Implications for Somatic Embryogenesis.\u00a0Proc Natl Acad Sci USA<\/a>. 105:3151-3156.<\/p>\n

SA Braybrook<\/strong>, SL Stone, S Park, AQ Bui, BH Le, RL Fischer, RB Goldberg, JJ Harada. 2006. Genes directly regulated by LEAFY COTYLEDON2 provide insight into the control of embryo maturation and somatic embryogenesis.\u00a0Proc Natl Acad Sci USA<\/a>\u00a0. Feb 28;103(9):3468-73.<\/p>\n

Recent Review Publications<\/h3>\n

G Arsuffi and S A Braybrook. 2017. Acid growth: an ongoing trip. J Ex Bot<\/a>.<\/p>\n

\"ACID<\/p>\n

S A Braybrook<\/strong>. 2017.\u00a0Plant Development: Lessons from Getting It Twisted (Dispatch on Saffer et. al. 2017<\/a>). Current Biology<\/a>, 27(15):R758-R760.<\/p>\n

\"twist<\/p>\n

A Bucksch, A Atta-Boateng, A F Azihou, D Battogtokh, A Baumgartner, B M Binder, S Braybrook<\/strong>, C Chang, V Coneva, T DeWitt, A Fletcher, M Gehan, D H Diaz Martinez, L Hong, A Iyer-Pascuzzi, LL Klein, S A Leiboff, M Li, J Lynch, A Maizel, J N Maloof, RJ C Markelz, C Martinez, L A Miller, W Mio, W Palubicki, H Poorter, C Pradal, C Price, E Puttonen, J Reese, R Rell\u00e1n-\u00c1lvarez, E P Spalding, E E. Sparks, C N Topp, J H Williams, D H Chitwood. 2017<\/strong>. Morphological plant modeling: Unleashing geometric and topological potential within the plant sciences. Frontiers in Plant Science<\/a>.<\/p>\n

\"morphology<\/p>\n

SA Braybrook and H Jonsson. 2015. Shifting foundations: the mechanical cell wall and development. Current Opinion in Plant Biology<\/a>. 29:115-120.<\/p>\n

\"jonsson<\/p>\n

G Levesque-Tremblay, J Pelloux, SA Braybrook, K Muller. 2015. Tuning of pectin methylesterification: consequences for cell wall biomechanics and development. Planta<\/a>. <\/em><\/p>\n

\"muller<\/a><\/p>\n

 <\/p>\n

F Bou Daher and SA Braybrook. 2015. How to let go: pectin and plant cell adhesion. Front. Plant Sci.<\/a><\/i> 6<\/b>:523.<\/p>\n

\"adhesion<\/a><\/p>\n

SA Braybrook. 2015. Film: Infinite freedom of creation. A review for Nature Plants. Nature Plants <\/a>1<\/b>, Article number:15059. You can watch the film here<\/a>!<\/p>\n

\"film<\/a><\/p>\n

SA Braybrook. 2014. Signalling in plant cell patterning- mechano-molecular theory and phyllotaxis. In: The Biochemist<\/a>. Invited contribution.<\/p>\n

\"Untitled-1\"<\/a><\/p>\n

P Milani,\u00a0SA Braybrook<\/strong>, A Boudaoud. 2013. Shrinking the hammer: micromechanical approaches to morphogenesis.\u00a0Journal of Experimental Botany<\/a>. (first published online July 19, 2013)<\/p>\n

\"JXB\"<\/a><\/p>\n

SA Braybrook<\/strong>, H Hofte, A Peaucelle. 2012. Probing the mechanical contributions of the pectin matrix: insights for cell growth.\u00a0Plant, Signaling, and Behavior<\/a>. 7(8):45-46.\"PSB\"<\/a>A Peaucelle,\u00a0SA Braybrook<\/strong>, H Hofte. 2012. Cell wall mechanics and growth control in plants: the role of pectins revisited. In:\u00a0Frontiers in Plant Physiology<\/a>, Research Topic: Current challenges in plant cell walls. Volume 3, article No. 121.<\/p>\n

\"Frontiers\"<\/a>SA Braybrook<\/strong>\u00a0and C Kuhlemeier. How a plant builds leaves. 2010.\u00a0The Plant Cell<\/a>. 22: 1006-1018.<\/p>\n

\"RevKuhl\"<\/a><\/p>\n","protected":false},"excerpt":{"rendered":"

M Linardi\u0107 and SA Braybrook. (2020) Identification and selection of optimal reference genes for qPCR-based gene expression analysis in Fucus distichus under various abiotic stresses. bioRxiv (and PLoS One) M Linardi\u0107, SJ Cokus, M Pellegrini, and SA Braybrook. (2020) Growth of the Fucus embryo: insights into wall-mediated cell expansion through mechanics and transcriptomics. bioRxiv   … <\/p>\n

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