Improving rice tolerance to potassium deficiency by enhancing OsHAK16p:WOX11‐controlled root development

Potassium (K) deficiency in plants confines root growth and decreases root‐to‐shoot ratio, thus limiting root K acquisition in culture medium. A WUSCHEL‐related homeobox (WOX) gene, WOX11, has been reported as an integrator of auxin and cytokinin signalling that regulates root cell proliferation. Here, we report that ectopic expression of WOX11 gene driven by the promoter of OsHAK16 encoding a low‐K‐enhanced K transporter led to an extensive root system and adventitious roots and more effective tiller numbers in rice. The WOX11‐regulated root and shoot phenotypes in the OsHAK16p:WOX11 transgenic lines were supported by K‐deficiency‐enhanced expression of several RR genes encoding type‐A cytokinin‐responsive regulators, PIN genes encoding auxin transporters and Aux/IAA genes. In comparison with WT, the transgenic lines showed increases in root biomass, root activity and K concentrations in the whole plants, and higher soluble sugar concentrations in roots particularly under low K supply condition. The improvement of sugar partitioning to the roots by the expression of OsHAK16p:WOX11 was further indicated by increasing the expression of OsSUT1 and OsSUT4 genes in leaf blades and several OsMSTs genes in roots. Expression of OsHAK16p:WOX11 in the rice grown in moderate K‐deficient soil increased total K uptake by 72% and grain yield by 24%–32%. The results suggest that enlarging root growth and development by the expression of WOX11 in roots could provide a useful option for increasing K acquisition efficiency and cereal crop productivity in low K soil.     

TDIF Peptide Signaling Regulates Vascular Stem Cell Proliferation via the WOX4 Homeobox Gene in Arabidopsis

The indeterminate nature of plant growth and development depends on the stem cell system found in meristems. The Arabidopsis thaliana vascular meristem includes procambium and cambium. In these tissues, cell–cell signaling, mediated by a ligand-receptor pair made of the TDIF (for tracheary element differentiation inhibitory factor) peptide and the TDR/PXY (for TDIF RECEPTOR/ PHLOEM INTERCALATED WITH XYLEM) membrane protein kinase, promotes proliferation of procambial cells and suppresses their xylem differentiation. Here, we report that a WUSCHEL-related HOMEOBOX gene, WOX4, is a key target of the TDIF signaling pathway. WOX4 is expressed preferentially in the procambium and cambium, and its expression level was upregulated upon application of TDIF in a TDR-dependent manner. Genetic analyses showed that WOX4 is required for promoting the proliferation of procambial/cambial stem cells but not for repressing their commitment to xylem differentiation in response to the TDIF signal. Thus, at least two intracellular signaling pathways that diverge after TDIF recognition by TDR might regulate independently the behavior of vascular stem cells. Detailed observations in loss-of-function mutants revealed that TDIF-TDR-WOX4 signaling plays a crucial role in the maintenance of the vascular meristem organization during secondary growth.     

The Interaction between Rice ERF3 and WOX11 Promotes Crown Root Development by Regulating Gene Expression Involved in Cytokinin Signaling

Crown roots are the main components of the fibrous root system in rice (Oryza sativa). WOX11, a WUSCHEL-related homeobox gene specifically expressed in the emerging crown root meristem, is a key regulator in crown root development. However, the nature of WOX11 function in crown root development has remained elusive. Here, we identified a rice AP2/ERF protein, ERF3, which interacts with WOX11 and was expressed in crown root initials and during crown root growth. Functional analysis revealed that ERF3 was essential for crown root development and acts in auxin- and cytokinin-responsive gene expression. Downregulation of ERF3 in wox11 mutants produced a more severe root phenotype. Also, increased expression of ERF3 could partially complement wox11, indicating that the two genes functioned cooperatively to regulate crown root development. ERF3 and WOX11 shared a common target, the cytokinin-responsive gene RR2. The expression of ERF3 and WOX11 only partially overlapped, underlining a spatio-temporal control of RR2 expression and crown root development. Furthermore, ERF3-regulated RR2 expression was involved in crown root initiation, while the ERF3/WOX11 interaction likely repressed RR2 during crown root elongation. These results define a mechanism regulating gene expression involved in cytokinin signaling during different stages of crown root development in rice.     

LBD18/ASL20 Regulates Lateral Root Formation in Combination with LBD16/ASL18 Downstream of ARF7 and ARF19 in Arabidopsis

The LATERAL ORGAN BOUNDARIES DOMAIN/ASYMMETRIC LEAVES2-LIKE (LBD/ASL) genes encode proteins harboring a conserved amino acid domain, referred to as the LOB (for lateral organ boundaries) domain. While recent studies have revealed developmental functions of some LBD genes in Arabidopsis (Arabidopsis thaliana) and in crop plants, the biological functions of many other LBD genes remain to be determined. In this study, we have demonstrated that the lbd18 mutant evidenced a reduced number of lateral roots and that lbd16 lbd18 double mutants exhibited a dramatic reduction in the number of lateral roots compared with lbd16 or lbd18. Consistent with this observation, significant β-glucuronidase (GUS) expression in Pro_LBD18:GUS seedlings was detected in lateral root primordia as well as in the emerged lateral roots. Whereas the numbers of primordia of lbd16, lbd18, and lbd16 lbd18 mutants were similar to those observed in the wild type, the numbers of emerged lateral roots of lbd16 and lbd18 single mutants were reduced significantly. lbd16 lbd18 double mutants exhibited additively reduced numbers of emerged lateral roots compared with single mutants. This finding indicates that LBD16 and LBD18 may function in the initiation and emergence of lateral root formation via a different pathway. LBD18 was shown to be localized into the nucleus. We determined whether LBD18 functions in the nucleus using a steroid regulator-inducible system in which the nuclear translocation of LBD18 can be regulated by dexamethasone in the wild-type, lbd18, and lbd16 lbd18 backgrounds. Whereas LBD18 overexpression in the wild-type background induced lateral root formation to some degree, other lines manifested the growth-inhibition phenotype. However, LBD18 overexpression rescued lateral root formation in lbd18 and lbd16 lbd18 mutants without inducing any other phenotypes. Furthermore, we demonstrated that LBD18 overexpression can stimulate lateral root formation in auxin response factor7/19 (arf7 arf19) mutants with blocked lateral root formation. Taken together, our results suggest that LBD18 functions in the initiation and emergence of lateral roots, in conjunction with LBD16, downstream of ARF7 and ARF19.The LATERAL ORGAN BOUNDARIES DOMAIN/ASYMMETRIC LEAVES2-LIKE (LBD/ASL) genes (hereafter referred to as LBD) encode proteins harboring a LOB (for lateral organ boundaries) domain, which is a conserved amino acid domain that is detected only in plants, indicative of its function in plant-specific processes (Iwakawa et al., 2002; Shuai et al., 2002). There are 42 Arabidopsis (Arabidopsis thaliana) LBD genes, which have been assigned to two classes. Class I comprises 36 genes and class II comprises six genes (Iwakawa et al., 2002; Shuai et al., 2002). The class I proteins harbor LOB domains similar to those observed in the LOB protein, whereas the class II proteins are less similar to the class I proteins, which include the LOB domain as well as regions outside of the LOB domain. The LOB domain is approximately 100 amino acids in length and harbors a conserved 4-Cys motif with CX₂CX₆CX₃C spacing, a Gly-Ala-Ser block, and a predicted coiled-coil motif with LX₆LX₃LX₆L spacing, reminiscent of the Leu zipper found in the majority of class I proteins (Shuai et al., 2002). None of the class II proteins were predicted to form coiled-coil structures.Although we currently understand very little about the biological roles of the LBD genes, there have been some reports describing the developmental functions of LBD genes in Arabidopsis on the basis of gain-of-function studies. The gain-of-function mutants of LBD36/ASL1, designated downwards siliques1, showed shorter internodes and downward lateral organs such as flowers (Chalfun-Junior et al., 2005). Although the lbd36 loss-of-function mutants did not show morphological phenotypes, the analysis of lbd36 as2 double mutants showed that these two members act redundantly to control cell fate determination in the petals. Another Arabidopsis gain-of-function mutant, jagged lateral organs-D (jlo-D), generates strongly lobed leaves and the shoot apical meristem prematurely arrests organ initiation, terminating in a pin-like structure (Borghi et al., 2007). During embryogenesis, JLO (=LBD30/ASL19) is necessary for the initiation of cotyledons and development beyond the globular stage. The results of misexpression experiments indicate that during postembryonic development, JLO function is required for the initiation of plant lateral organs. A recent study showed that the LOB domain of AS2 cannot be functionally replaced by those of other members of the LOB family, indicating that dissimilar amino acid residues in the LOB domains are important for characteristic functions of the family members (Matsumura et al., 2009).Thirty-five LBD genes in rice (Oryza sativa) have been identified from the genome sequences of the two rice subspecies, a japonica rice (Nippobare) and an indica rice (9311; Yang et al., 2006). Analyses of rice mutants have provided evidence of the involvement of a variety of rice LBD genes in lateral organ development. CROWN ROOTLESS1 (CRL1), encoding a LBD protein, is crucial for crown root formation in rice (Inukai et al., 2005). The crl1 mutant showed auxin-related phenotypes, such as decreased lateral root number, auxin insensitivity in lateral root formation, and impaired root gravitropism. A rice AUXIN RESPONSE FACTOR (ARF) appears to directly regulate CRL1 expression in the auxin signaling pathway (Inukai et al., 2005). ADVENTITIOUS ROOTLESS1 encodes an auxin-responsive protein with a LOB domain that controls the initiation of adventitious root primordia in rice and turned out to be the same gene as CRL1 (Liu et al., 2005).Lateral roots of Arabidopsis are derived from a subset of the pericycle cells (pericycle founder cells), which are positioned at the xylem poles within the parent root tissues (Casimiro et al., 2003). The mature pericycle cells dedifferentiate to form lateral root primordium (LRP), which undergoes consistent anticlinal and periclinal cell divisions to generate a highly organized LRP (Malamy and Benfey, 1997). The LRP emerges from the parent root via cell expansion, and the activation of the lateral root meristem results in continued growth of the organized lateral root. A growing body of physiological and genetic evidence has been collected to suggest that auxin plays a profound role in lateral root formation. For example, many auxin-related mutants have been shown to affect lateral root formation (Casimiro et al., 2003). Lateral root formation in Arabidopsis was shown to be regulated by ARF7 and ARF19 via the direct activation of LBD16 and LBD29/ASL16 (Okushima et al., 2007). Overexpression of LBD16 and LBD29 induced lateral root formation in the absence of ARF7 and ARF19, and the dominant repression of LBD16 inhibited lateral root formation, thus suggesting that these LBDs function downstream of ARF7- and ARF19-mediated auxin signaling during lateral root formation. The results of selection and binding assays demonstrated that a truncated LOB protein harboring only the conserved LOB domain can preferentially bind to unique DNA sequences, which is indicative of a DNA-binding protein (Husbands et al., 2007). Recently, LBD18 was shown to regulate tracheary element differentiation (Soyano et al., 2008).In this study, we demonstrated that LBD18 is involved in the regulation of lateral root formation, based on the analysis of loss-of-function mutants and the complementation of lbd18 and lbd16 lbd18 mutants by dexamethasone (DEX)-inducible LBD18 expression. Double mutations in LBD16 and LBD18 resulted in a synergistic reduction in the number of lateral roots, particularly in initiation and emergence, compared with either the lbd16 or lbd18 single mutant. This finding is suggestive of a combinatorial interaction of LBD16 and LBD18 in the process of lateral root formation. LBD18 expression in arf7 and arf19 mutants by the DEX-inducible system increased the number of lateral roots, thus demonstrating that LBD18 functions downstream of ARF7 and ARF19 in lateral root formation.     

Histological and biochemical parameters of Crocus sativus during in vitro root and shoot organogenesis

Content of malondialdehyde (MDA), proline, phenolics, and saccharides was analyzed during different developmental stages of in vitro root and shoot organogenesis in saffron. The highest content of MDA, proline, and phenolics was detected in nodular calli. Significant changes were also found in the content of polysaccharides, soluble saccharides, oligosaccharides, and reducing saccharides during developmental stages. Histological investigation of nodular calli showed meristematic zones with small and densely stained cells situated at peripheral zones of calli. The meristematic zones surrounded some vascular areas from which de novo organs originated. The parenchymatic cells of inner zones of calli converted to procambium cells that produced vascular tissues.     

Adventitious lateral rooting: the plasticity of root system architecture

Root formation under natural conditions is plastic in response to multiple signals. Recent studies suggested that the WUSCHEL‐RELATED HOMEOBOX11 (WOX11)‐mediated adventitious root formation pathway can occur in the primary root (PR) in Arabidopsis thaliana, resulting in the production of a specific type of lateral roots (LRs) in response to wounding or environmental signals. This process differs from the previously characterized process for LR development, which does not require WOX11. The WOX11‐mediated PR‐derived roots can be considered like LRs that exhibit an ‘adventitious’ feature. Therefore, we consider these roots to be adventitious lateral roots (adLRs). The identification of WOX11‐mediated adLRs implies that studying the formation of roots in response to wounding and environmental signals is important for characterizing the plasticity of the root system architecture.     

SHOOT APEX ORGANIZATION AND ORIGIN OF THE RHIZOME-BORNE ROOTS AND THEIR ASSOCIATED GAPS IN DENNSTAEDTIA CICUTARIA

The shoot apex of Dennstaedtia cicutaria consists of three zones—a zone of surface initials, a zone of subsurface initials, and a cup-shaped zone that is subdivided into a peripheral region and central region. A diffuse primary thickening meristem, which is continuous with the peripheral region of the cup-shaped zone, gives rise to a broad cortex. The roots occurring on the rhizomes are initiated very near the shoot apex in the outer derivatives of the primary thickening meristem. The roots that occur on the leaf bases also differentiate from cortical cells. Eventually, those cortical cells situated between the newly formed root apical cell and the rhizome procambium (or leaf trace) differentiate into the procambium of the root trace, thus establishing procambial continuity with that of the rhizome or leaf trace. Parenchymatous root gaps are formed in the rhizome stele and leaf traces when a few of their procambial cells located directly above the juncture of the root trace procambium differentiate into parenchyma. As the rhizome procambium or leaf trace continues to elongate, the parenchyma cells of the gap randomly divide and enlarge, thus extending the gap.     

TIAF1 self-aggregation in peritumor capsule formation, spontaneous activation of SMAD-responsive promoter in p53-deficient environment, and cell death

Self-aggregation of transforming growth factor β (TGF-β)1-induced antiapoptotic factor (TIAF1) is known in the nondemented human hippocampus, and the aggregating process may lead to generation of amyloid β (Aβ) for causing neurodegeneration. Here, we determined that overexpressed TIAF1 exhibits as aggregates together with Smad4 and Aβ in the cancer stroma and peritumor capsules of solid tumors. Also, TIAF1/Aβ aggregates are shown on the interface between brain neural cells and the metastatic cancer cell mass. TIAF1 is upregulated in developing tumors, but may disappear in established metastatic cancer cells. Growing neuroblastoma cells on the extracellular matrices from other cancer cell types induced production of aggregated TIAF1 and Aβ. In vitro induction of TIAF1 self-association upregulated the expression of tumor suppressors Smad4 and WW domain-containing oxidoreductase (WOX1 or WWOX), and WOX1 in turn increased the TIAF1 expression. TIAF1/Smad4 interaction further enhanced Aβ formation. TIAF1 is known to suppress SMAD-regulated promoter activation. Intriguingly, without p53, self-aggregating TIAF1 spontaneously activated the SMAD-regulated promoter. TIAF1 was essential for p53-, WOX1- and dominant-negative JNK1-induced cell death. TIAF1, p53 and WOX1 acted synergistically in suppressing anchorage-independent growth, blocking cell migration and causing apoptosis. Together, TIAF1 shows an aggregation-dependent control of tumor progression and metastasis, and regulation of cell death.