A common adaptation in angiosperms is the deposition of hydrophilic mucilage into the apoplast of seed coat epidermal cells during the course of their differentiation. Upon imbibition, seed mucilage, composed mainly of carbohydrates (i.e. pectins, hemicelluloses and glycans) expands rapidly, encapsulating the seed and aiding in seed dispersal and germination. The FEI1/FEI2 receptor-like kinases and the SOS5 extracellular GPI-anchored protein were previously shown to act on a pathway regulating cellulose biosynthesis during Arabidopsis root elongation. In the highlighted study, we demonstrated that FEI2 and SOS5 regulate the production of the cellulosic rays deposited across the inner adherent-layer of seed mucilage. Mutations in either fei2 or sos5 disrupted the formation of rays, which was associated with an increase in the soluble, outer layer of pectin mucilage and accompanied by a reduction in the inner adherent-layer. Mutations in CELLULOSE SYNTHASE 5 also led to reduced rays and mal-partitioning of the pectic component of seed mucilage, further establishing a structural role for cellulose in seed mucilage. Here, we show that FEI2 expressed from a CaMV 35S promoter complemented both root and seed mucilage defects of the fei1 fei2 double mutant. In contrast, expression of FEI1 from a 35S promoter complemented the root, but not the seed phenotype of the fei1 fei2 double mutant, suggesting that unlike in the root, FEI2 plays a unique and non-redundant role in the regulation of cellulose synthesis in seed mucilage. Altogether, these data suggest a novel role for cellulose in anchoring the pectic component of seed mucilage to the seed surface and indicate that the FEI2 protein has a function distinct from that of FEI1, despite the high sequence similarity of these RLKs

Harpaz-Saad, Smadar

Kieber, Joseph J.

Western, Tamara L.

PubMed

Carolina Digital Repository

© 2012 Landes Bioscience.Do not distribute.The FEI2-SOS5 pathway and CELLULOSE SYNTHASE 5 are requiredfor cellulose biosynthesis in the Arabidopsis seed coat and affect pectinmucilage structureSmadar Harpaz-Saad,1 Tamara L. Western2 and Joseph J. Kieber1,*1Biology Department; University of North Carolina; Chapel Hill, NC USA; 2Biology Department; McGill University; Montreal, QC CanadaKeywords: cellulose, seed coat, mucilage,RLK, AGPSubmitted: 11/18/11Accepted: 11/21/11http://dx.doi.org/10.4161/psb.18819*Correspondence to: Joseph J. Kieber;Email: jkieber@unc.eduAddendum to: Harpaz-Saad S, McFarlane HE,Xu S, Divi UK, Forward B, Western TL, et al.Cellulose synthesis via the FEI2 RLK/SOS5 path-way and CELLULOSE SYNTHASE 5 is required forthe structure of seed coat mucilage inArabidopsis. Plant J 2011; 68:941–53;PMID:21883548; http://dx.doi.org/10.1111/j.1365-313X.2011.04760.xA common adaptation in angiospermsis the deposition of hydrophilicmucilage into the apoplast of seed coatepidermal cells during the course of theirdifferentiation. Upon imbibition, seedmucilage, composed mainly of carbohy-drates (i.e. pectins, hemicelluloses andglycans) expands rapidly, encapsulatingthe seed and aiding in seed dispersal andgermination. The FEI1/FEI2 receptor-like kinases and the SOS5 extracellularGPI-anchored protein were previouslyshown to act on a pathway regulatingcellulose biosynthesis during Arabidopsisroot elongation. In the highlighted study,we demonstrated that FEI2 and SOS5regulate the production of the cellulosicrays deposited across the inner adherent-layer of seed mucilage. Mutations ineither fei2 or sos5 disrupted the formationof rays, which was associated with anincrease in the soluble, outer layer ofpectin mucilage and accompanied by areduction in the inner adherent-layer.Mutations in CELLULOSE SYNTHASE5 also led to reduced rays and mal-partitioning of the pectic componentof seed mucilage, further establishinga structural role for cellulose in seedmucilage. Here, we show that FEI2expressed from a CaMV 35S promotercomplemented both root and seed mucil-age defects of the fei1 fei2 double mutant.In contrast, expression of FEI1 from a35S promoter complemented the root,but not the seed phenotype of the fei1fei2 double mutant, suggesting thatunlike in the root, FEI2 plays a uniqueand non-redundant role in the regulationof cellulose synthesis in seed mucilage.Altogether, these data suggest a novel rolefor cellulose in anchoring the pecticcomponent of seed mucilage to the seedsurface and indicate that the FEI2 proteinhas a function distinct from that of FEI1,despite the high sequence similarity ofthese RLKs.During differentiation, the maternallyderived seed coat epidermal cells (alsocalled mucilage secretory cells; MSC) fromArabidopsis thaliana secrete mucilagecomposed primarily of pectins into theapoplast. Upon hydration of the matureseed, the mucilage expands, rupturing thetangential cell wall and encapsulating theseed.1,2 Once released, the seed coatmucilage is organized in two distinctdomains: an inner, dense layer, tightlyattached to the seed surface and an outer,water soluble, diffuse layer. Both layers arecomposed primarily of the pectin rham-nogalacturonan I (RG-I), with the innerlayer also containing other pectins andminor amounts of hemicellulose andβ-glucans.1,3-6 Genetic and biochemicalanalyses of seed coat mucilage secretorycells has led to new insights regarding thecomplex mechanism involved in pectinbiosynthesis and in muro modification,and has demonstrated the utility of seedmucilage as a system for further study ofcell wall polymer biosynthesis and modi-fication.7-9 The precise physiological roleof seed mucilage is yet to be determined,but has been proposed to play a role inseed dispersal and germination.5,9-11A number of previous studies have pro-vided data supporting a role for cellulose inseed mucilage: (1) Calcofluor and CongoARTICLE ADDENDUMPlant Signaling & Behavior 7:2, 285–288; February 2012; G 2012 Landes Biosciencewww.landesbioscience.com Plant Signaling & Behavior 285© 2012 Landes Bioscience.Do not distribute.red stains suggested that β-glucans arepresent in a set of rays deposited across theinner layer of seed mucilage3,4,12; (2) Theseβ-glucan rays were resistant to pectolyticenzymes, unless these were combined withcellulases,3 (3) Fluorescently labeled cel-lulose binding modules identified cellulosein seed mucilage with distinct bindingpatterns for crystalline and amorphouscellulose.6,13,14Cellulose microfibrils are synthesized atthe plasma membrane by protein complexescomprised primarily of CELLULOSESYNTHASE A (CESA), which is encodedby a family of ten genes in Arabidopsis.15 Inprimary cell wall biosynthesis, CESA1 and 3are unique, non-redundant components ofthe cellulose synthase complex, whileCESA2, 5, 6 and 9 act as a third componentin a partially redundant manner.16,17CESA4, 7 and 8 play a role in cellulosebiosynthesis in secondary cell walls, andCESA10 has not as yet been assigned anyfunction.18-20The leucine rich repeat receptor likekinases (RLKs) FEI1 and FEI2 actredundantly in the regulation of cellulosebiosynthesis during root elongation.21 Thefei1 fei2 double mutant displays rootgrowth arrest, root tip swelling and areduction in the biosynthesis of crystallinecellulose in the presence of elevated sucroseor salt.21 SALT OVERLY SENSITIVE 5,which encodes a GPI-anchored fasciclin-likearabinogalactan protein,21,22 was shown bygenetic interaction to act on the samepathway as the FEIs in the regulation ofcellulose biosynthesis.21 Interestingly, theroot phenotype of both fei1 fei2 and sos5 issuppressed by inhibitors of ethylene bio-synthesis, but not by disruption of theethylene signaling pathway, suggesting arole for ACC as a signaling molecule in thispathway.21,22The FEI-SOS Pathway Playsa Non-Conditional Rolein Seed Coat MucilageUpon imbibition of wild type Arabidopsisseeds, the transparent mucilage rapidlyexpands, resulting in the gaps observedbetween the seeds and leading to anincrease in the overall volume occupiedby the hydrated seeds. In both fei1 fei2and sos5 mutant seeds, these gaps aregreatly reduced compared to wild-type,leading to the reduced overall volumeoccupied by the seeds (Fig. 1). Staining ofthe seed mucilage for acidic pectins usingthe cationic dye ruthenium red confirmedthat the adherent inner layer of seedmucilage, which remains attached tothe seed surface following mild shaking,is reduced in both fei1 fei2 and sos5mutant seeds. These data were supportedby immunolabeling with the CCRC-M36 antibody, which recognizes theunbranched backbone of RGI in seedmucilage and by monosaccharide analysisof soluble vs. adherent seed mucilageextracts. Interestingly, the reduced innerlayer of mucilage in the mutants, wasassociated with a corresponding increase inthe outer-soluble layer of seed mucilage, asobserved by both ruthenium red stain andmonosaccharide analysis. The role of FEI1and FEI2 in the regulation of cellulosebiosynthesis during root elongation sug-gested they may affect cellulose biosyn-thesis also in seed mucilage. We thereforeFigure 1. FEI2 plays a non-redundant role in the regulation of cellulose synthesis in seed mucilage and cannot be replaced by ectopic expression of FEI1.Phenotypes of the wild-type (WT) or fei1 fei2 mutants transformed with FEI1 or FEI2 expressed from their native promoter of a CaMV 35S promoter asindicated above each column. (A) Seed volumes of 10mg of seeds suspended in water. (B) Pontamine staining for cellulose following gentle shaking in water.Pontamine stain labels the columella, tangential cell wall remnants and rays deposited across the inner layer of mucilage in the wild-type. (C) Root phenotypeof seedlings grown on MS medium plus 0% sucrose for 4days and then transferred to medium supplemented with 4.5% sucrose for another 5 days.286 Plant Signaling & Behavior Volume 7 Issue 2© 2012 Landes Bioscience.Do not distribute.used both calcofluor and pontamine fastscarlet S4B stains in order to visualizecrystalline cellulose in seed mucilage. Inwild-type, both calcofluor and pontaminestains revealed a set of rays radiating theseed, deposited from the tip of thecolumella and across the inner layer ofseed mucilage. This set of rays was almostcompletely absent or substantially com-promised in either fei1 fei2 or sos5 seedmucilage, respectively. Together these datasuggest that the depleted cellulose rays infei1 fei2 and sos5 leads to mal-partitioningof the pectic component between the innerand outer domains of seed mucilage.CESA5 Plays a Role in CelluloseBiosynthesis in Seed MucilageIn order to further investigate the mech-anism involved in crystalline cellulosedeposition into the rays of Arabidopsisseed mucilage, we examined the structureof seed mucilage in cesA2, cesA5, cesA6 andcesA9 mutants. Calcofluor and pontaminestaining revealed that only the disruptionof cesA5 compromised the rays across theinner layer of seed mucilage, resulting ina phenotype similar to that observed infei1 fei2 and sos5. Consistent with this,Sullivan et al., 2011 and Mendu et al.,2011 recently observed similar phenotypesfor other mutant alleles of cesA5, as well asadditional, partially redundant roles forCESA2, CESA5 and CESA9 in cellulosedeposition during seed development.23,24Together, these studies demonstrate thatcellulose is an essential component of seedmucilage and that it acts to anchor thepectic component of seed mucilage to theseed surface, resulting in an inner layer ofseed mucilage that remains attached to theseed most likely in order to maintain ahydrated environment during the firstphase of seed germination.FEI2, But Not FEI1, Plays aUnique and Non-Redundant Rolein Seed MucilageThe fei1 fei2 double mutant displays aswollen root phenotype as a result ofreduced cellulose biosynthesis, but neithersingle mutant displays any detectableroot phenotype.21 In contrast, fei2 singlemutants, but not fei1 mutants, display amucilage defect similar to the double fei1fei2 mutant phenotype, suggesting thatFEI2 plays a non-redundant role in seedmucilage. Consistent with this, expressionof FEI2 from its endogenous promotercomplemented both the root and the seedmucilage defect of the double fei1 fei2mutant. Expression of FEI1 driven by itsendogenous promoter complemented onlythe root phenotype of the double mutant.Thus, only FEI2 is involved in the regula-tion of cellulose biosynthesis into thecellulosic rays deposited across the innerlayer of seed mucilage.The question arises is whether theunique and non-redundant function ofFEI2 in seed mucilage is a result of adistinct expression pattern of the gene ascompared to FEI1, or is due to differencesin the function of the two proteins, whichare highly similar in sequence (82% aminoacid identity). To address this question, weexpressed FEI1 and FEI2 from the CaMV35S promoter in fei1 fei2 double mutantbackground and assessed the ability ofeach to complement the root and seedphenotypes. As each transgene is expressedfrom the same constitutive promoter, anydifference in the ability to complementthese phenotypes must be due to differ-ences in the function of the encodedproteins. Consistent with the resultsobtained by the expression from its nativepromoter, expression of FEI2 from theCaMV 35S promoter complementedboth the root and seed phenotypes in thedouble fei1 fei2 mutant background(Fig. 1). Likewise, expression of FEI1from the CaMV 35S promoter comple-mented the root phenotype of the doublefei1 fei2 mutant (in all ten different linesexamined). However, the CaMV 35S::FEI1 transgene failed to complement theseed mucilage phenotype of the fei1 fei2double mutant (Fig. 1). These dataindicate that despite the high sequencesimilarity shared by these LRR-RLKs, theFEI2 protein has a distinct function in theregulation of cellulose biosynthesis inseed mucilage. This suggests that thereare likely distinct signaling inputs and/oroutputs acting through FEI2 to regulatecellulose biosynthesis during the pro-duction of seed coat mucilage. Theintracellular domain of both FEI1 andFEI2, encompassing the C-terminal kinasedomain, share more than 90% identityin sequence, while the extracellulardomain, containing the leucine-richrepeats is more variable (62% identity insequence). This suggests that perhaps theextracellular domain is more likely toharbor a unique function in seed mucilagerelated cellulose deposition, thoughfurther studies examining the structure-function relationship of FEI1 and FEI2will be required to clearly define thedomains imparting the unique functionto FEI2.Mucilage secretory cells have beenshown to be a powerful model systemfor the study of pectin metabolism andin muro modification.7,8 We have estab-lished cellulose as an essential componentof seed mucilage and identified CESA5,FEI2 and SOS5 as regulators of cellulosedeposition into the rays radiating the seedacross the inner layer of seed mucilage.Other recent studies have defined addi-tional, partially redundant functions forCESA2, CESA5 and CESA9 in cellulosedeposition into the radial cell walls ofmucilage secretory cells.23-25 These studiesset the stage for the use of mucilagesecretory cells as a novel tool for furtherresearch aimed to uncover new playersregulating cellulose biosynthesis.AcknowledgementsWe thank Gyeong Mee Yoon for fruitfuldiscussions. This project was supportedby National Science Foundation grantIOS 0624377 (to J.J.K.) and by a NaturalSciences and Engineering ResearchCouncil Discovery Grant (to T.L.W.).S.H-S. is a recipient of a Vaadia-BARDpostdoctoral fellowship award No. FI-411-2008 from BARD, The UnitedStates—Israel Binational AgriculturalResearch and Development Fund.www.landesbioscience.com Plant Signaling & Behavior 287© 2012 Landes Bioscience.Do not distribute.References1. Western TL, Skinner DJ, Haughn GW. Differentiationof mucilage secretory cells of the Arabidopsis seed coat.Plant Physiol 2000; 122:345-56; PMID:10677428;http://dx.doi.org/10.1104/pp.122.2.3452. Haughn G, Chaudhury A. Genetic analysis of seed coatdevelopment in Arabidopsis. Trends Plant Sci 2005;10:472-7; PMID:16153880; http://dx.doi.org/10.1016/j.tplants.2005.08.0053. Macquet A, Ralet M-C, Kronenberger J, Marion-PollA, North HM. In situ, chemical and macromolecularstudy of the composition of Arabidopsis thalianaseed coat mucilage. 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The FEI2-SOS5 pathway and CELLULOSE SYNTHASE 5 are required for cellulose biosynthesis in the Arabidopsis seed coat and affect pectin mucilage structure

The FEI2-SOS5 pathway and CELLULOSE SYNTHASE 5 are required for cellulose biosynthesis in the Arabidopsis seed coat and affect pectin mucilage structure

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