The Inducible Accumulation of Cell Wall-Bound -Hydroxybenzoates Is Involved in the Regulation of Gravitropic Response of Poplar

Overview

Journal Front Plant Sci

Date 2021 Dec 31

PMID 34970280

Citations 3

Authors

Yunjun Zhao

Xiao-Hong Yu

Chang-Jun Liu

Affiliations

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Abstract

Lignin in species is acylated with -hydroxybenzoate. Monolignol -hydroxybenzoyltransferase 1 (PHBMT1) mediates -hydroxybenzoylation of sinapyl alcohol, eventually leading to the modification of syringyl lignin subunits. Angiosperm trees upon gravistimulation undergo the re-orientation of their growth along with the production of specialized secondary xylem, i.e., tension wood (TW), that generates tensile force to pull the inclined stem or leaning branch upward. Sporadic evidence suggests that angiosperm TW contains relatively a high percentage of syringyl lignin and lignin-bound -hydroxybenzoate. However, whether such lignin modification plays a role in gravitropic response remains unclear. By imposing mechanical bending and/or gravitropic stimuli to the hybrid aspens in the wild type (WT), lignin -hydroxybenzoate deficient, and -hydroxybenzoate overproduction plants, we examined the responses of plants to gravitropic/mechanical stress and their cell wall composition changes. We revealed that mechanical bending or gravitropic stimulation not only induced the overproduction of crystalline cellulose fibers and increased the relative abundance of syringyl lignin, but also significantly induced the expression of and the increased accumulation of -hydroxybenzoates in TW. Furthermore, we found that although disturbing lignin-bound -hydroxybenzoate accumulation in the knockout and overexpression (OE) poplars did not affect the major chemical composition shifts of the cell walls in their TW as occurred in the WT plants, depletion of -hydroxybenzoates intensified the gravitropic curving of the plantlets in response to gravistimulation, evident with the enhanced stem secant bending angle. By contrast, hyperaccumulation of -hydroxybenzoates mitigated gravitropic response. These data suggest that PHBMT1-mediated lignin modification is involved in the regulation of poplar gravitropic response and, likely by compromising gravitropism and/or enhancing autotropism, negatively coordinates the action of TW cellulose fibers to control the poplar wood deformation and plant growth.

Citing Articles

Lignin engineering in forest trees: From gene discovery to field trials.

De Meester B, Vanholme R, Mota T, Boerjan W Plant Commun. 2022; 3(6):100465.

PMID: 36307984 PMC: 9700206. DOI: 10.1016/j.xplc.2022.100465.

Metabolic engineering of p-hydroxybenzoate in poplar lignin.

Mottiar Y, Karlen S, Goacher R, Ralph J, Mansfield S Plant Biotechnol J. 2022; 21(1):176-188.

PMID: 36161690 PMC: 9829402. DOI: 10.1111/pbi.13935.

Lignin -Hydroxybenzoylation Is Negatively Correlated With Syringyl Units in Poplar.

Mottiar Y, Mansfield S Front Plant Sci. 2022; 13:938083.

PMID: 35937345 PMC: 9355280. DOI: 10.3389/fpls.2022.938083.

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