Enhancement of secondary xylem cell proliferation by Arabidopsis cyclin D overexpression in tobacco plants.

UNLABELLED: Secondary xylem is composed of daughter cells produced by the vascular cambium in the stem. Cell proliferation of the secondary xylem is the result of long-range cell division in the vascular cambium. Most xylem cells have a thickened secondary cell wall, representing a large amount of biomass storage. Therefore, regulation of cell division in the vascular cambium and differentiation into secondary xylem is important for biomass production. Cell division is regulated by cell cycle regulators. In this study, we confirm that cell cycle regulators influence cell division in the vascular cambium in tobacco. We produced transgenic tobacco that expresses Arabidopsis thaliana cyclin D2;1 (AtcycD2;1) and AtE2Fa-DPa under the control of the CaMV35S promoter. Each gene is a positive regulator of the cell cycle, and is known to influence the transition from G1 phase to S phase. AtcycD2;1-overexpressing tobacco had more secondary xylem cells when compared with control plants. In order to evaluate cell division activity in the vascular cambium, we prepared a Populus trichocarpa cycB1;1 (PtcycB1;1) promoter containing a destruction box motif for ubiquitination and a ß-glucuronidase-encoding gene (PtcycB1;1pro:GUS). In transgenic tobacco containing PtcycB1;1pro:GUS, GUS staining was specifically observed in meristem tissues, such as the root apical meristem and vascular cambium. In addition, mitosis-monitoring plants containing AtcycD2;1 had stronger GUS staining in the cambium when compared with control plants. Our results indicated that overexpression of AtcycD enhances cell division in the vascular cambium and increases secondary xylem differentiation in tobacco. KEY MESSAGE: We succeeded in inducing cell proliferation of cambium and enlargement of secondary xylem region by AtcycD overexpression. We also evaluated mitotic activity in cambium using cyclin-GUS fusion protein from poplar.

The carbohydrate-binding module (CBM)-like sequence is crucial for rice CWA1/BC1 function in proper assembly of secondary cell wall materials.

We recently reported that the cwa1 mutation disturbed the deposition and assembly of secondary cell wall materials in the cortical fiber of rice internodes. Genetic analysis revealed that cwa1 is allelic to bc1, which encodes glycosylphosphatidylinositol (GPI)-anchored COBRA-like protein with the highest homology to Arabidopsis COBRA-like 4 (COBL4) and maize Brittle Stalk 2 (Bk2). Our results suggested that CWA1/BC1 plays a role in assembling secondary cell wall materials at appropriate sites, enabling synthesis of highly ordered secondary cell wall structure with solid and flexible internodes in rice. The N-terminal amino acid sequence of CWA1/BC1, as well as its orthologs (COBL4, Bk2) and other BC1-like proteins in rice, shows weak similarity to a family II carbohydrate-binding module (CBM2) of several bacterial cellulases. To investigate the importance of the CBM-like sequence of CWA1/BC1 in the assembly of secondary cell wall materials, Trp residues in the CBM-like sequence, which is important for carbohydrate binding, were substituted for Val residues and introduced into the cwa1 mutant. CWA1/BC1 with the mutated sequence did not complement the abnormal secondary cell walls seen in the cwa1 mutant, indicating that the CBM-like sequence is essential for the proper function of CWA1/BC1, including assembly of secondary cell wall materials.

Isolation of a novel cell wall architecture mutant of rice with defective Arabidopsis COBL4 ortholog BC1 required for regulated deposition of secondary cell wall components.

The plant secondary cell wall is a highly ordered structure composed of various polysaccharides, phenolic components and proteins. Its coordinated regulation of a number of complex metabolic pathways and assembly has not been resolved. To understand the molecular mechanisms that regulate secondary cell wall synthesis, we isolated a novel rice mutant, cell wall architecture1 (cwa1), that exhibits an irregular thickening pattern in the secondary cell wall of sclerenchyma, as well as culm brittleness and reduced cellulose content in mature internodes. Light and transmission electron microscopy revealed that the cwa1 mutant plant has regions of local aggregation in the secondary cell walls of the cortical fibers in its internodes, showing uneven thickness. Ultraviolet microscopic observation indicated that localization of cell wall phenolic components was perturbed and that these components abundantly deposited at the aggregated cell wall regions in sclerenchyma. Therefore, regulation of deposition and assembly of secondary cell wall materials, i.e. phenolic components, appear to be disturbed by mutation of the cwa1 gene. Genetic analysis showed that cwa1 is allelic to brittle culm1 (bc1), which encodes the glycosylphosphatidylinositol-anchored COBRA-like protein specifically in plants. BC1 is known as a regulator that controls the culm mechanical strength and cellulose content in the secondary cell walls of sclerenchyma, but the precise function of BC1 has not been resolved. Our results suggest that CWA1/BC1 has an essential role in assembling cell wall constituents at their appropriate sites, thereby enabling synthesis of solid and flexible internodes in rice.