Rumi Tominaga

Role of a positive regulator of root hair development, CAPRICE ,in Arabidopsis root epidermal cell differentiation

In Arabidopsis, root hairs are formed only from a set of epidermal cells named trichoblasts or hair-forming cells. Previous studies showed CAPRICE (CPC) promotes differentiation of hair-forming cells by controlling a negative regulator, GLABRA2 (GL2), which is preferentially expressed in hairless cells. Here, we show that CPC is also predominantly expressed in the hairless cells, but not in the neighboring hair-forming cells, and that CPC protein moves to the hair-forming cells and represses the GL2 expression. We also show that the N terminus of bHLH protein interacts with CPC and is responsible for the GL2 expression. We propose a model in which CPC plays a key role in the fate-determination of hair-forming cells.

Cell-to-cell movement of the CAPRICE protein in Arabidopsis root epidermal cell differentiation.

CAPRICE (CPC), a small, R3-type Myb-like protein, is a positive regulator of root hair development in Arabidopsis. Cell-to-cell movement of CPC is important for the differentiation of epidermal cells into trichoblasts (root hair cells). CPC is transported from atrichoblasts (hairless cells), where it is expressed, to trichoblasts, and generally accumulates in their nuclei. Using truncated versions of CPC fused to GFP, we identified a signal domain that is necessary and sufficient for CPC cell-to-cell movement. This domain includes the N-terminal region and a part of the Myb domain. Amino acid substitution experiments indicated that W76 and M78 in the Myb domain are critical for targeted transport, and that W76 is crucial for the nuclear accumulation of CPC:GFP. To evaluate the tissue-specificity of CPC movement, CPC:GFP was expressed in the stele using the SHR promoter and in trichoblasts using the EGL3 promoter. CPC:GFP was able to move from trichoblasts to atrichoblasts but could not exit from the stele, suggesting the involvement of tissue-specific regulatory factors in the intercellular movement of CPC. Analyses with a secretion inhibitor, Brefeldin A, and with an rhd3 mutant defective in the secretion process in root epidermis suggested that intercellular CPC movement is mediated through plasmodesmata. Furthermore, the fusion of CPC to tandem-GFPs defined the capability of CPC to increase the size exclusion limit of plasmodesmata.

Arabidopsis CAPRICE-LIKE MYB 3 (CPL3) controls endoreduplication and flowering development in addition to trichome and root hair formation.

CAPRICE (CPC) encodes a small protein with an R3 MYB motif and promotes root hair cell differentiation in Arabidopsis thaliana. Three additional CPC-like MYB genes, TRY (TRIPTYCHON), ETC1 (ENHANCER OF TRY AND CPC 1) and ETC2 (ENHANCER OF TRY AND CPC 2) act in a redundant manner with CPC in trichome and root hair patterning. In this study, we identified an additional homolog, CPC-LIKE MYB 3 (CPL3), which has high sequence similarity to CPC, TRY, ETC1 and ETC2. Overexpression of CPL3 results in the suppression of trichomes and overproduction of root hairs, as has been observed for CPC, TRY, ETC1 and ETC2. Morphological studies with double, triple and quadruple homolog mutants indicate that the CPL3 gene cooperatively regulates epidermal cell differentiation with other CPC homologs. Promoter-GUS analyses indicate that CPL3 is specifically expressed in leaf epidermal cells, including stomate guard cells. Notably, the CPL3 gene has pleiotropic effects on flowering development, epidermal cell size and trichome branching through the regulation of endoreduplication.

Functional Analysis of the Epidermal-Specific MYB Genes CAPRICE and WEREWOLF in Arabidopsis

Epidermis cell differentiation in Arabidopsis thaliana is a model system for understanding the developmental end state of plant cells. Two types of MYB transcription factors, R2R3-MYB and R3-MYB, are involved in cell fate determination. To examine the molecular basis of this process, we analyzed the functional relationship of the R2R3-type MYB gene WEREWOLF (WER) and the R3-type MYB gene CAPRICE (CPC). Chimeric constructs made from the R3 MYB regions of WER and CPC used in reciprocal complementation experiments showed that the CPC R3 region cannot functionally substitute for the WER R3 region in the differentiation of hairless cells. However, WER R3 can substantially substitute for CPC R3. There are no differences in yeast interaction assays of WER or WER chimera proteins with GLABRA3 (GL3) or ENHANCER OF GLABRA3 (EGL3). CPC and CPC chimera proteins also have similar activity in preventing GL3 WER and EGL3 WER interactions. Furthermore, we showed by gel mobility shift assays that WER chimera proteins do not bind to the GL2 promoter region. However, a CPC chimera protein, which harbors the WER R3 motif, still binds to the GL2 promoter region.

The Glycerophosphoryl Diester Phosphodiesterase-Like Proteins SHV3 and its Homologs Play Important Roles in Cell Wall Organization

Despite the importance of extracellular events in cell wall organization and biogenesis, the mechanisms and related factors are largely unknown. We isolated an allele of the shaven3 (shv3) mutant of Arabidopsis thaliana, which exhibits ruptured root hair cells during tip growth. SHV3 encodes a novel protein with two tandemly repeated glycerophosphoryl diester phosphodiesterase-like domains and a glycosylphosphatidylinositol anchor, and several of its paralogs are found in Arabidopsis. Here, we report the detailed characterization of mutants of SHV3 and one of its paralogs, SVL1. The shv3 and svl1 double mutant exhibited additional defects, including swollen guard cells, aberrant expansion of the hypocotyl epidermis and ectopic lignin deposits, suggesting decreased rigidity of the cell wall. Fourier-transform infrared spectroscopy and measurement of the cell wall components indicated an altered cellulose content and pectin modification with cross-linking in the double mutant. Furthermore, we found that the ruptured root hair phenotype of shv3 was suppressed by increasing the amount of borate, which is supposed to be involved in pectic polysaccharide cross-linking, in the medium. These findings indicate that SHV3 and its paralogs are novel important factors involved in primary cell wall organization.

A NIMA-related protein kinase suppresses ectopic outgrowth of epidermal cells through its kinase activity and the association with microtubules

To study cellular morphogenesis genetically, we isolated loss-of-function mutants of Arabidopsis thaliana, designated ibo1. The ibo1 mutations cause local outgrowth in the middle of epidermal cells of the hypocotyls and petioles, resulting in the formation of a protuberance. In Arabidopsis, the hypocotyl epidermis differentiates into two alternate cell files, the stoma cell file and the non-stoma cell file, by a mechanism involving TRANSPARENT TESTA GLABRA1 (TTG1) and GLABRA2 (GL2). The ectopic protuberances of the ibo1 mutants were preferentially induced in the non-stoma cell files, which express GL2. TTG1-dependent epidermal patterning is required for protuberance formation in ibo1, suggesting that IBO1 functions downstream from epidermal cell specification. Pharmacological and genetic analyses demonstrated that ethylene promotes protuberance formation in ibo1, implying that IBO1 acts antagonistically to ethylene to suppress radial outgrowth. IBO1 is identical to NEK6, which encodes a Never In Mitosis A (NIMA)-related protein kinase (Nek) with sequence similarity to Neks involved in microtubule organization in fungi, algae, and animals. The ibo1-1 mutation, in which a conserved Glu residue in the activation loop is substituted by Arg, completely abolishes its kinase activity. The intracellular localization of GFP-tagged NEK6 showed that NEK6 mainly accumulates in cytoplasmic spots associated with cortical microtubules and with a putative component of the gamma-tubulin complex. The localization of NEK6 is regulated by the C-terminal domain, which is truncated in the ibo1-2 allele. These results suggest that the role of NEK6 in the control of cellular morphogenesis is dependent on its kinase action and association with the cortical microtubules.

Cellulose as a biological sink of CO2

One strategy to enhance CO 2 fixation is to increase the biological deposition of cellulose in woody plants, because cellulose which is the most abundant organic compound on the earth is made from CO 2 through photosynthetic pathways in the walls of plant cells. Cellulose has a strong tendency to self-associate into fibrils which are not easily hydrolyzed, either chemically or biologically, and accumulate in the walls. Certainly, cellulose is a good biological sink for CO 2 on the earth, but the mechanism of cellulose biosynthesis is still unknown (the cellulose synthase activity in vitro in higher plants has not been completely identified or defined by anyone yet, and its gene is unknown [1]). In addition, the cellulose biosynthesis has not only been identified and defined as chain polymerization but is also involved in a dynamism of cortical microtubule association during the developmental growth of woody plants. W e report here our lab update on cellulose biosynthesis in higher plants to improve woody plants by genetic engineering through studies on the biosynthetic mechanism.