A Common Position-Dependent Mechanism Controls Cell-Type Patterning and GLABRA2 Regulation in the Root and Hypocotyl Epidermis of Arabidopsis

A position-dependent pattern of epidermal cell types is produced during root development in Arabidopsis thaliana. This pattern is reflected in the expression pattern of GLABRA2 (GL2), a homeobox gene that regulates cell differentiation in the root epidermis. GL2 promoter::GUS fusions were used to show that the TTG gene, a regulator of root epidermis development, is necessary for maximal GL2 activity but is not required for the pattern of GL2 expression. Furthermore, GL2-promoter activity is influenced by expression of the myc-like maize R gene (35S::R) in Arabidopsis but is not affected by gl2 mutations. A position-dependent pattern of cell differentiation and GL2-promoter activity was also discovered in the hypocotyl epidermis that was analogous to the pattern in the root. Non-GL2-expressing cell files in the hypocotyl epidermis located outside anticlinal cortical cell walls exhibit reduced cell length and form stomata. Like the root, the hypocotyl GL2 activity was shown to be influenced by ttg and 35S::R but not by gl2. The parallel pattern of cell differentiation in the root and hypocotyl indicates that TTG and GL2 participate in a common position-dependent mechanism to control cell-type patterning throughout the apical-basal axis of the Arabidopsis seedling.     

Localization of Superoxide in the Root Apex of Arabidopsis

Reactive oxygen species (ROS) fulfil many functions in plants. They have a signaling role in several physiological mechanisms, but they are also directly involved as substrates in important reactions, especially in the apoplast. Two ROS, superoxide and hydrogen peroxide, were shown to exhibit a typical accumulation pattern in the Arabidopsis root apex. While hydrogen peroxide is mainly present in the cell wall of fully elongated cells in the region of root hair formation, superoxide accumulation roughly coincides with the transition zone, between the meristem and the fast elongating zone. Developing lateral roots also exhibit a strong superoxide labeling with the same localization.Key Words: superoxide, hydrogen peroxide, cell elongation, transition zone, nitroblue tetrazoliumIn a recent work,¹ we have shown that superoxide radical and hydrogen peroxide have different accumulation sites in Arabidopsis root tip. Hydrogen peroxide is mainly present in a region identified as “differentiation zone”, according to the nomenclature used by Scheres et al.² This localization fits well with the role that was assigned to this ROS in the formation of root hairs.³ This hypothesis was strengthened by the fact that umbelliferone, which promotes the in vitro and in vivo formation of hydrogen peroxide by peroxidases, induces the formation and the elongation of root hairs. In contrast, potassium iodide, a H₂O₂ scavenger, prevents the formation of root hairs, but does not completely abolished their initiation.As for superoxide radical, it accumulates mainly in apoplast of cells ranging from the proximal part of root meristem to the point where cells initiate their fast elongation. This localization is in agreement with a role of superoxide in the cell elongation process.¹ This conclusion can be refined, taking into account the work of Baluška and coll.^4,5 Using various functional and structural criteria, these authors identified four distinct zones in the root apex of Arabidopsis. They introduced an additional zone, between the meristem and the fast elongating cells, named “transition zone”. This region comprises cells which do not divide any more and are preparing their elongation. A reappraisal of the localization of superoxide accumulation in the light of this classification could suggest that this ROS is actually mainly associated with this transition zone, rather than with the beginning of the elongation zone. Figure 1 shows an Arabidopsis root stained for the presence of superoxide with nitroblue tetrazolium. It appears that the strong superoxide staining ranges from about 80 to 250 µm away from the root tip. The respective sizes of the various zones somewhat differ from the sizes reported (in ref. ⁵). It is difficult to precisely determine the border between the meristem and the transition zone, which should be around 120 µm. The fast elongation zone begins at about 240 µm. Fast elongating cells exhibit only a slight superoxide staining in their cell wall. Therefore, it appears that superoxide accumulates mainly in the wall of cells preparing their rapid elongation. It has been reported that cells in the transition zone undergo several modifications to prepare their growth. This includes reactions leading to cell wall loosening.^6,7 The presence of superoxide in the cell wall of those cells could participate in the onset of the loosening process, for example by interacting with peroxidases to produce hydroxyl radicals.⁸Open in a separate windowFigure 1Distribution of superoxide radical in the root of a 7-day old Arabidopsis seedling stained with nitroblue tetrazolium. Growth conditions and staining procedure were as described (in ref. ¹). The scale indicates µm, starting from the root cap junction. The picture was taken with a MZ 16 Leica stereomicroscope. Arrowheads point to root hairs in formation. Black arrow, basal limit of meristem. White arrow, onset of the fast elongation zone.When roots get older, the intensity of superoxide staining in the main root tip decreases, while the apex of the newly formed lateral roots exhibits a stronger reaction (Fig. 2). This could be related to the important growth potential of young lateral roots. The emerging root primordium is usually clearly positive (Fig. 2A) and in a fully formed lateral root, superoxide staining is concentrated in a zone between the meristem and elongated cells, most likely corresponding to the transition zone (Fig. 2B). In conclusion, superoxide radical seems to accumulate in the wall of cells preparing their elongation in the transition zone of Arabidopsis root apex.Open in a separate windowFigure 2Detection of superoxide radical by nitroblue tetrazolium in a lateral root primordium marked by an arrow (A) and in a developing lateral root (B). mr, main root. Scale bar: 100 µm.     

CAPRICE positively regulates stomatal formation in the Arabidopsis hypocotyl

In the Arabidopsis hypocotyl, stomata develop only from a set of epidermal cell files. Previous studies have identified several negative regulators of stomata formation. Such regulators also trigger non-hair cell fate in the root. Here, it is shown that TOO MANY MOUTHS (TMM) positively regulates CAPRICE (CPC) expression in differentiating stomaless-forming cell files, and that the CPC protein might move to the nucleus of neighbouring stoma-forming cells, where it promotes stomata formation in a redundant manner with TRIPTYCHON (TRY). Unexpectedly, the CPC protein was also localized in the nucleus and peripheral cytoplasm of hypocotyl fully differentiated epidermal cells, suggesting that CPC plays an additional role to those related to stomata formation. These results identify CPC and TRY as positive regulators of stomata formation in the embryonic stem, which increases the similarity between the genetic control of root hair and stoma cell fate determination.Key words: arabidopsis, epidermis, CPC, stomata, TMM     

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.     

Nuclear Localization of Cyclin B1 Controls Mitotic Entry After DNA Damage

Mitosis in human cells is initiated by the protein kinase Cdc2-cyclin B1, which is activated at the end of G2 by dephosphorylation of two inhibitory residues, Thr14 and Tyr15. The G2 arrest that occurs after DNA damage is due in part to stabilization of phosphorylation at these sites. We explored the possibility that entry into mitosis is also regulated by the subcellular location of Cdc2-cyclin B1, which is suddenly imported into the nucleus at the end of G2. We measured the timing of mitosis in HeLa cells expressing a constitutively nuclear cyclin B1 mutant. Parallel studies were performed with cells expressing Cdc2AF, a Cdc2 mutant that cannot be phosphorylated at inhibitory sites. Whereas nuclear cyclin B1 and Cdc2AF each had little effect under normal growth conditions, together they induced a striking premature mitotic phenotype. Nuclear targeting of cyclin B1 was particularly effective in cells arrested in G2 by DNA damage, where it greatly reduced the damage-induced G2 arrest. Expression of nuclear cyclin B1 and Cdc2AF also resulted in significant defects in the exit from mitosis. Thus, nuclear targeting of cyclin B1 and dephosphorylation of Cdc2 both contribute to the control of mitotic entry and exit in human cells.     

Erratum to: Ethylene Controls Adventitious Root Initiation Sites in Arabidopsis Hypocotyls Independently of Strigolactones

Journal of Plant Growth Regulation -     

The Hidden Geometries of the Arabidopsis thaliana Epidermis

The quest for the discovery of mathematical principles that underlie biological phenomena is ancient and ongoing. We present a geometric analysis of the complex interdigitated pavement cells in the Arabidopsis thaliana (Col.) adaxial epidermis with a view to discovering some geometric characteristics that may govern the formation of this tissue. More than 2,400 pavement cells from 10, 17 and 24 day old leaves were analyzed. These interdigitated cells revealed a number of geometric properties that remained constant across the three age groups. In particular, the number of digits per cell rarely exceeded 15, irrespective of cell area. Digit numbers per 100 µm² cell area reduce with age and as cell area increases, suggesting early developmental programming of digits. Cell shape proportions as defined by length∶width ratios were highly conserved over time independent of the size and, interestingly, both the mean and the medians were close to the golden ratio 1.618034. With maturity, the cell area∶perimeter ratios increased from a mean of 2.0 to 2.4. Shape properties as defined by the medial axis transform (MAT) were calculated and revealed that branch points along the MAT typically comprise one large and two small angles. These showed consistency across the developmental stages considered here at 140° (± 5°) for the largest angles and 110° (± 5°) for the smaller angles. Voronoi diagram analyses of stomatal center coordinates revealed that giant pavement cells (≥500 µm²) tend to be arranged along Voronoi boundaries suggesting that they could function as a scaffold of the epidermis. In addition, we propose that pavement cells have a role in spacing and positioning of the stomata in the growing leaf and that they do so by growing within the limits of a set of ‘geometrical rules’.