A tale of two systems: peptide ligand-receptor pairs in plant development.

Plants have developed intercellular signaling systems that use secreted peptides and plasma membrane-localized receptor-like kinases (RLKs). Although there has been little experimental evidence linking specific peptide ligands to receptors, recent studies of several ligand-receptor pairs have revealed their increasingly important roles in cell-cell communications during plant development. In this review, we focus on two specific families of plant peptides: the CLAVATA3/ENDOSPERM SURROUNDING REGION (CLE) peptide family and the EPIDERMAL PATTERING FACTOR (EPF) family, along with their corresponding RLKs. We discuss how these two unrelated peptide-mediated signaling systems control plant cell fate and development using similar receptor kinases as well as the mechanisms for how these peptide ligand-receptor pairs precisely regulate various distinct aspects of plant development at the level of ligand-receptor recognition and signal transduction.

Receptor kinase activation and signal transduction in plants: an emerging picture.

Plant receptor kinases play key roles in the cell-cell recognition process during development, defense against pathogens, and self incompatibility. Recent identification of potential ligand molecules and downstream signaling components, together with biochemical studies on receptor-complex formation, have revealed an emerging picture of receptor-kinase activation and signal transduction in plants.

The RING finger motif of photomorphogenic repressor COP1 specifically interacts with the RING-H2 motif of a novel Arabidopsis protein.

The constitutive photomorphogenic 1 (COP1) protein of Arabidopsis functions as a molecular switch for the seedling developmental fates: photomorphogenesis under light conditions and skotomorphogenesis in darkness. The COP1 protein contains a cysteine-rich zinc-binding RING finger motif found in diverse groups of regulatory proteins. To understand the role of the COP1 RING finger in mediating protein-protein interaction, we have performed a yeast two-hybrid screen and isolated a novel protein with a RING-H2 motif, a variant type of the RING finger. This protein, designated COP1 Interacting Protein 8 (CIP8), is encoded by a single copy gene and localized to cytosol in a transient assay. In addition to the RING-H2 motif, the predicted protein has a C4 zinc finger, an acidic region, a glycine-rich cluster, and a serine-rich cluster. The COP1 RING finger and the CIP8 RING-H2 domains are sufficient for their interaction with each other both in vitro and in yeast, whereas neither motif displayed significant self-association. Moreover, site-directed mutagenesis studies demonstrated that the expected zinc-binding ligands of the RING finger and RING-H2 fingers are essential for their interaction. Our findings indicate that the RING finger motif, in this case, serves as autonomous protein-protein interaction domain. The allele specific effect of cop1 mutations on the CIP8 protein accumulation in seedlings indicates that its stability in vivo is dependent on the COP1 protein.

Short communication: the N-terminal fragment of Arabidopsis photomorphogenic repressor COP1 maintains partial function and acts in a concentration-dependent manner.

Arabidopsis seedlings exhibit distinct developmental patterns according to their light environment: photomorphogenesis in the light and etiolation or skotomorphogenesis in darkness. COP1 acts within the nucleus to repress photomorphogenesis in darkness, while light depletes COP1 from nucleus and abrogates this repression. COP1 contains three structural modules: a RING finger followed by a coiled-coil domain, and a WD40 repeat domain at the C-terminus. By introducing various domain deletion mutants of COP1 into cop1 null mutant backgrounds, we show that all three domains are essential for the function of COP1 in vivo. Interestingly, a fragment containing the N-terminal 282 amino acids of COP1 (N282) with both the RING finger and coiled-coil modules is sufficient to rescue the lethality of the cop1 null mutations at low expression level. However, high expression levels of the N282 fragment result in a phenocopy of the cop1 null mutation. The sensitivity of the seedling to levels of N282 could reflect the importance of the abundance of COP1 for the appropriate regulation of photomorphogenic development.

Functional dissection of Arabidopsis COP1 reveals specific roles of its three structural modules in light control of seedling development.

Arabidopsis COP1 acts as a repressor of photomorphogenesis in darkness, and light stimuli abrogate the repressive ability and nuclear abundance of COP1. COP1 has three known structural modules: an N-terminal RING-finger, followed by a predicted coiled-coil and C-terminal WD-40 repeats. A systematic study was undertaken to dissect the functional roles of these three COP1 domains in light control of Arabidopsis seedling development. Our data suggest that COP1 acts primarily as a homodimer, and probably dimerizes through the coiled-coil domain. The RING-finger and the coiled-coil domains can function independently as light-responsive modules mediating the light-controlled nucleocytoplasmic partitioning of COP1. The C-terminal WD-40 domain functions as an autonomous repressor module since the overexpression of COP1 mutant proteins with intact WD-40 repeats are able to suppress photomorphogenic development. This WD-40 domain-mediated repression can be at least in part accounted for by COP1's direct interaction with and negative regulation of HY5, a bZIP transcription factor that positively regulates photomorphogenesis. However, COP1 self-association is a prerequisite for the observed interaction of the COP1 WD-40 repeats with HY5. This work thus provides a structural basis of COP1 as a molecular switch.

The Arabidopsis ERECTA gene is expressed in the shoot apical meristem and organ primordia.

In Arabidopsis thaliana (L.) Heynh, the mutation in ERECTA is known to confer a compact inflorescence by a reduction in the lengths of internodes and pedicels. We analyzed the expression pattern of this gene during plant development. In situ hybridization and histochemical analysis using transgenic plants carrying chimeric gene fusions, with the ERECTA promoter fused to the beta-glucuronidase (GUS) gene, showed that ERECTA was predominantly expressed in the shoot apical meristems and organ primordia. ERECTA expression in the shoot apical meristem was weak early in plant development but increased with the transition from the vegetative to the reproductive growth phase. ERECTA was also strongly expressed in organ primordia and immature organs but weakly in mature organs. Thus, ERECTA was expressed in a cell-specific and developmentally regulated manner. In order to identify the regulatory mechanism responsible for the expression pattern of ERECTA, the cis-acting regions in the ERECTA promoter were defined by study of the expression of the chimeric genes that consist of the 5'- or internal deleted promoter and a GUS reporter gene in transgenic plants. The results showed that the essential cis-regulatory elements governing the spatially and temporally specific expression of ERECTA are located between positions -462 and -228 bp and between positions -228 and -153 bp with respect to the transcriptional initiation site.

Expression of an N-terminal fragment of COP1 confers a dominant-negative effect on light-regulated seedling development in Arabidopsis.

CONSTITUTIVE PHOTOMORPHOGENIC1 (COP1) is an essential regulatory gene that plays a role in light control of seedling development in Arabidopsis. The COP1 protein possesses three recognizable structural domains: a RING finger zinc binding domain near the N terminus, followed by a coiled-coll domain and a domain with WD-40 repeats in the C-terminal half. To determine whether COP1 acts specifically as a light-inactivable repressor of photomorphogenic development and to elucidate the functional roles of the specific structural domains, mutant cDNAs encoding the N-terminal 282 amino acids (N282) of COP1 were expressed and analyzed in transgenic plants. High-level expression of the N282 fragment caused a dominant-negative phenotype similar to that of the loss-of-function cop1 mutants. The phenotypic characteristics include hypersensitivity of hypocotyl elongation to inhibition by white, blue, red, and far-red light stimuli. In the dark, N282 expression led to pleiotropic photomorphogenic cotyledon development, including cellular differentiation, plastid development, and gene expression, although it has no significant effect on the hypocotyl elongation. However, N282 expression had a minimal effect on the expression of stress- and pathogen-inducible genes. These observations support the hypothesis that COP1 is directly involved in the light control of seedling development and that it acts as a repressor of photomorphogenesis. Further, the results imply that the N282 COP1 fragment, which contains the zinc binding and colled-coil domains, is capable of interacting with either downstream targets or with the endogenous wild-type COP1, thus interfering with normal regulatory processes. The fact the N282 is able to interact with N282 and full-length COP1 in yeast provided evidence for the latter possibility.

The Arabidopsis ERECTA gene encodes a putative receptor protein kinase with extracellular leucine-rich repeats.

Arabidopsis Landsberg erecta is one of the most popular ecotypes and is used widely for both molecular and genetic studies. It harbors the erecta (er) mutation, which confers a compact inflorescence, blunt fruits, and short petioles. We have identified five er mutant alleles from ecotypes Columbia and Wassilewskija. Phenotypic characterization of the mutant alleles suggests a role for the ER gene in regulating the shape of organs originating from the shoot apical meristem. We cloned the ER gene, and here, we report that it encodes a putative receptor protein kinases. The deduced ER protein contains a cytoplasmic protein kinase catalytic domain, a transmembrane region, and an extracellular domain consisting of leucine-rich repeats, which are thought to interact with other macromolecules. Our results suggest that cell-cell communication mediated by a receptor kinase has an important role in plant morphogenesis.