Cell Wall Invertase 4 Governs Sucrose–Hexose Homeostasis in the Apoplast to Regulate Wood Development in Poplar

Cell Wall Invertase 4 Governs Sucrose–Hexose Homeostasis in the Apoplast to Regulate Wood Development in Poplar

In perennial trees, wood development is a carbon-demanding process, pivotal for secondary cell wall (SCW) formation and xylem development. Sugars, functioning both as carbon substrates and signaling molecules, orchestrate cambial proliferation and xylem differentiation. However, few molecular candid...

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Main Authors: Jing Lu, Qiao Ren, Qilin Wang, Yaqi Wen, Yanhong Wang, Ruiqi Liang, Dingxin Ran, Yifeng Jia, Xinyu Zhuo, Jiangtao Luo, Xianqiang Wang, Keming Luo
Format: Article
Language:English
Published: MDPI AG 2025-05-01
Series:Plants
Subjects:
poplar
xylem development
SCW
sugar metabolism
sugar signaling
Online Access:https://www.mdpi.com/2223-7747/14/9/1388
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Summary:In perennial trees, wood development is a carbon-demanding process, pivotal for secondary cell wall (SCW) formation and xylem development. Sugars, functioning both as carbon substrates and signaling molecules, orchestrate cambial proliferation and xylem differentiation. However, few molecular candidates involved in the sugar-mediated regulation of wood development have been characterized. Cell wall invertases (CWINs), a subclass of the invertase enzyme family localized in the apoplastic space, catalyze the irreversible hydrolysis of sucrose into glucose and fructose, thereby governing carbon allocation in sink tissues. Here, <i>PtoCWIN4</i> shows preferential expression in the stem of <i>Populus tomentosa</i> and has a high efficiency in sucrose cleavage activity. We demonstrated that the knockout of <i>PtoCWIN4</i> results in stunted growth, aberrant branching patterns, and compromised secondary xylem formation. In contrast, mutant lines displayed enhanced SCW thickness accompanied by elevated cellulose and hemicellulose accumulation. Following this, the knockout of <i>PtoCWIN4</i> led to impaired carbon partitioning from sucrose to hexose metabolites during wood development, corroborating the enzyme’s role in sustaining sucrose hydrolysis. Collectively, these findings establish <i>PtoCWIN4</i> as a master regulator of sucrose-to-hexose conversion, a metabolic gateway critical for balancing structural biomass production and developmental growth during wood formation.
ISSN:2223-7747

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