Variation in lignin content and composition mechanisms of control and implications for the genetic improvement of plants

Lignin, a complex phenolic polymer, is important for mechanical support, water transport, and defense in vascular plants. Compressive strength and hydrophobicity of xylem cell walls are imparted by the lignin polymer, which is deposited during the terminal differentiation of tracheids and other cell...

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Bibliographic Details
Published in:Plant physiology (Bethesda) 1996, Vol.110 (1), p.3-13
Main Authors: Campbell, Malcolm M., Sederoff, Ronald R.
Format: Article
Language:English
Subjects:
actividad enzimatica
activite enzymatique
Alcohols
amelioration des plantes
analisis cuantitativo
analyse quantitative
biochemical pathways
Biological and medical sciences
biosintesis
biosynthese
Biosynthesis
breeding methods
Cell walls
chemical composition
chemical structure
composicion quimica
composition chimique
Conifers
Enzymes
enzymic activity
estructura quimica
fitomejoramiento
Fundamental and applied biological sciences. Psychology
genetic variation
genetica
genetics
genetique
Lignification
Lignin
ligninas
lignine
lignins
Metabolism
Metabolism. Physicochemical requirements
methode d' amelioration genetique
metodos de mejoramiento genetico
mutant
mutantes
mutants
Pine trees
plant breeding
Plant physiology and development
plantas transgenicas
plante transgenique
Plants
polimerizacion
polymerisation
polymerization
quantitative analysis
structure chimique
transcripcion
transcription
Transgenic plants
Update on Genetic Improvement
variacion genetica
variation genetique
via bioquimica del metabolismo
voie biochimique du metabolisme
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Summary:Lignin, a complex phenolic polymer, is important for mechanical support, water transport, and defense in vascular plants. Compressive strength and hydrophobicity of xylem cell walls are imparted by the lignin polymer, which is deposited during the terminal differentiation of tracheids and other cell types. The resistance of xylem to compressive stresses imposed by water transport and by the mass of the plants is important to growth and development. In addition, the insolubility and complexity of the lignin polymer makes it resistant to degradation by most microorganisms. Therefore, lignin serves an important function in plant defense. Variation in lignin content, composition, and location is likely to affect these essential processes. The constraints on the amount, composition, and localization of lignin for normal xylem function and plant defense are not known. Lignin composition, quantity, and distribution also affect the agroindustrial uses of plant material. Digestibility and dietary conversion of herbaceous crops are affected by differences in lignin content and composition (Akin et al., 1986, 1991). Lignin is an undesirable component in the conversion of wood into pulp and paper; removal of lignin is a major step in the paper making process. Furthermore, the resistance of lignin to microbial degradation enhances its persistence in soils. Lignin is, therefore, a significant component in the global carbon cycle. The mechanisms of control of lignin composition and quantity have wide implications regarding the adaptation and evolution of land plants and provide a basis for improved genetic manipulation of lignin for agroindustrial end uses. In this Update, we will focus on the levels of control of lignin variation, including (a) metabolic control, (b) regulation of individual enzymes in the biosynthetic pathway, and (c) regulation of gene expression.
ISSN:0032-0889
1532-2548
DOI:10.1104/pp.110.1.3