Maturation Stress Generation in Poplar Tension Wood Studied by Synchrotron Radiation Microdiffraction

Clair, Bruno; Alméras, Tancrède; Pilate, Gilles; Jullien, Delphine; Sugiyama, Junji; Riekel, Christian

doi:10.1104/pp.109.149542

Cited by 48 publications

(29 citation statements)

References 53 publications

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“…Tension wood fibers are the cell type responsible for force generation, and the specialized G-layer is thought to be directly involved in force generation (Mellerowicz & Gorshkova, 2012). It is the last cell wall layer formed during fiber development, is highly enriched in cellulose and largely devoid of lignin, and has a cellulose microfibril angle (MFA) approaching zero,which makes the cell resistant to stretching but permissive to swelling (Clair et al, 2011). It has been reported that some angiosperms produce functional tension wood lacking a G-layer, most notably for a number of tropical rainforest species (Fisher & Stevenson, 1981;Clair et al, 2006).…”

Section: Anatomical and Chemical Characteristics Of Tension Woodmentioning

confidence: 99%

“…Tansley review New Phytologist reported to lack a G-layer will be required to determine whether the G-layer is universally required to produce functional tension wood. While the molecular mechanisms responsible for force generation are still uncertain, at least some key elements have been identified (Mellerowicz & Gorshkova, 2012;Fagerstedt et al, 2014), including cellulose MFA (Norberg & Meier, 1996;Bamber, 2001;Clair et al, 2011), xyloglucan endotransgylcosylase (XET) (Mellerowicz et al, 2008;Mellerowicz & Gorshkova, 2012), and fasciclin-like arabinogalactan proteins (MacMillan et al, 2010). Different hypotheses have been proposed for mechanisms of force generation, most of which are not necessarily mutually exclusive.…”

Section: Reviewmentioning

confidence: 99%

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Gravitropisms and reaction woods of forest trees – evolution, functions and mechanisms

Groover

2016

New Phytologist

109

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Summary The woody stems of trees perceive gravity to determine their orientation, and can produce reaction woods to reinforce or change their position. Together, graviperception and reaction woods play fundamental roles in tree architecture, posture control, and reorientation of stems displaced by wind or other environmental forces. Angiosperms and gymnosperms have evolved strikingly different types of reaction wood. Tension wood of angiosperms creates strong tensile force to pull stems upward, while compression wood of gymnosperms creates compressive force to push stems upward. In this review, the general features and evolution of tension wood and compression wood are presented, along with descriptions of how gravitropisms and reaction woods contribute to the survival and morphology of trees. An overview is presented of the molecular and genetic mechanisms underlying graviperception, initial graviresponse and the regulation of tension wood development in the model angiosperm, Populus. Critical research questions and new approaches are discussed.

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Section: Anatomical and Chemical Characteristics Of Tension Woodmentioning

confidence: 99%

Section: Reviewmentioning

confidence: 99%

Gravitropisms and reaction woods of forest trees – evolution, functions and mechanisms

Groover

2016

New Phytologist

109

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“…To ensure vertical growth, trees need both a 'skeletal' system, which is achieved through the stiffness and strength of the trunk material (Niklas, 1992) and a 'motor' system (Moulia et al, 2006) to control plant posture by generating forces to offset the effect of gravity during growth (Alm eras & Fournier, 2009). The motor function is driven by turgor pressure in unlignified organs (Moulia & Fournier, 2009) or results from cell wall maturation in wood (Clair et al, 2011). The vertical posture of trees was long thought to be controlled only by internal forces in the wood during the formation of fibres (Scurfield, 1973;Fournier et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

“…Tensile stress is generated in the gelatinous layer during maturation. Current description of the underlying mechanism is that swelling of the gelatinous polysaccharide matrix (Chang et al, 2015) bends the cellulose network (Clair et al, 2011;Alm eras & Clair, 2016), putting cellulose microfibrils into tension. In numerous species, the gelatinous layer is no longer visible as it is later lignified, after generation of the tensile force (Roussel & Clair, 2015).…”

Section: Introductionmentioning

confidence: 99%

Mechanical contribution of secondary phloem to postural control in trees: the bark side of the force

et al. 2018

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To grow straight, plants need a motor system that controls posture by generating forces to offset gravity. This motor function in trees was long thought to be only controlled by internal forces induced in wood. Here we provide evidence that bark is involved in the generation of mechanical stresses in several tree species. Saplings of nine tropical species were grown tilted and staked in a shadehouse and the change in curvature of the stem was measured after releasing from the pole and after removing the bark. This first experiment evidenced the contribution of bark in the up-righting movement of tree stems. Combined mechanical measurements of released strains on adult trees and microstructural observations in both transverse and longitudinal/tangential plane enabled us to identify the mechanism responsible for the development of asymmetric mechanical stress in the bark of stems of these species. This mechanism does not result from cell wall maturation like in wood, or from the direct action of turgor pressure like in unlignified organs, but is the consequence of the interaction between wood radial pressure and a smartly organized trellis structure in the inner bark.

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“…Within the secondary cell walls (SCWs) of tension wood fibres, there are marked differences in cellulose properties. Typically, a-cellulose is relatively increased in tension wood Okuyama et al, 1994;Yoshizawa et al, 2000), and the cellulose is more crystalline (Okuyama et al, 1994;Mü ller et al, 2006) and has a marked decrease in microfibril angle (MFA; Okuyama et al, 1994;Washusen et al, 2005;Ruelle et al, 2006Ruelle et al, , 2010Clair et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

Investigating the molecular underpinnings underlying morphology and changes in carbon partitioning during tension wood formation in Eucalyptus

et al. 2014

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SummaryTension wood has distinct physical and chemical properties, including altered fibre properties, cell wall composition and ultrastructure. It serves as a good system for investigating the genetic regulation of secondary cell wall biosynthesis and wood formation. The reference genome sequence for Eucalyptus grandis allows investigation of the global transcriptional reprogramming that accompanies tension wood formation in this global wood fibre crop.We report the first comprehensive analysis of physicochemical wood property changes in tension wood of Eucalyptus measured in a hybrid (E. grandis 9 Eucalyptus urophylla) clone, as well as genome-wide gene expression changes in xylem tissues 3 wk post-induction using RNA sequencing.We found that Eucalyptus tension wood in field-grown trees is characterized by an increase in cellulose, a reduction in lignin, xylose and mannose, and a marked increase in galactose. Gene expression profiling in tension wood-forming tissue showed corresponding down-regulation of monolignol biosynthetic genes, and differential expression of several carbohydrate active enzymes.We conclude that alterations of cell wall traits induced by tension wood formation in Eucalyptus are a consequence of a combination of down-regulation of lignin biosynthesis and hemicellulose remodelling, rather than the often proposed up-regulation of the cellulose biosynthetic pathway.

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Maturation Stress Generation in Poplar Tension Wood Studied by Synchrotron Radiation Microdiffraction

Cited by 48 publications

References 53 publications

Gravitropisms and reaction woods of forest trees – evolution, functions and mechanisms

Gravitropisms and reaction woods of forest trees – evolution, functions and mechanisms

Mechanical contribution of secondary phloem to postural control in trees: the bark side of the force

Investigating the molecular underpinnings underlying morphology and changes in carbon partitioning during tension wood formation in Eucalyptus

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