Discovery of novel cold-induced CISP genes encoding small RNA-binding proteins related to cold adaptation in barley.

To adapt to cold conditions, barley plants rely on specific mechanisms, which have not been fully understood. In this study, we characterized a novel barley cold-induced gene identified using a PCR-based high coverage gene expression profiling method. The identified gene encodes a small protein that we named CISP1 (Cold-induced Small Protein 1). Homology searches of sequence databases revealed that CISP1 homologs (CISP2 and CISP3) exist in barley genome. Further database analyses showed that the CISP1 homologs were widely distributed in cold-tolerant plants such as wheat and rye. Quantitative reverse transcription PCR analyses indicated that the expression of barley CISP genes was markedly increased in roots exposed to cold conditions. In situ hybridization analyses showed that the CISP1 transcripts were localized in the root tip and lateral root primordium. We also demonstrated that the CISP1 protein bound to RNA. Taken together, these findings indicate that CISP1 and its homologs encoding small RNA-binding proteins may serve as RNA chaperones playing a vital role in the cold adaptation of barley root. This is the first report describing the likely close relationship between root-specific genes and the cold adaptation process, as well as the potential function of the identified genes.

Apple FLOWERING LOCUS T proteins interact with transcription factors implicated in cell growth and organ development.

Understanding the flowering process in apple (Malus × domestica Borkh.) is essential for developing methods to shorten the breeding period and regulate fruit yield. It is known that FLOWERING LOCUS T (FT) acts as a transmissible floral inducer in the Arabidopsis flowering network system. To clarify the molecular network of two apple FT orthologues, MdFT1 and MdFT2, we performed a yeast two-hybrid screen to identify proteins that interact with MdFT1. We identified several transcription factors, including two members of the TCP (TEOSINTE BRANCHED1, CYCLOIDEA and PROLIFERATING CELL FACTORs) family, designated MdTCP2 and MdTCP4, and an Arabidopsis thaliana VOZ1 (Vascular plant One Zinc finger protein1)-like protein, designated MdVOZ1. MdTCP2 and MdVOZ1 also interacted with MdFT2 in yeast. The expression domain of MdTCP2 and MdVOZ1 partially overlapped with that of MdFT1 and MdFT2, most strikingly in apple fruit tissue, further suggesting a potential interaction in vivo. Constitutive expression of MdTCP2, MdTCP4 and MdVOZ1 in Arabidopsis affected plant size, leaf morphology and the formation of leaf primordia on the adaxial side of cotyledons. On the other hand, chimeric MdTCP2, MdTCP4 and MdVOZ1 repressors that included the ethylene-responsive transcription factors (ERF)-associated amphiphilic repression (EAR) domain motif influenced reproduction and inflorescence architecture in transgenic Arabidopsis. These results suggest that MdFT1 and/or MdFT2 might be involved in the regulation of cellular proliferation and the formation of new tissues and that they might affect leaf and fruit development by interacting with TCP- and VOZ-family proteins. DDBJ accession nos. AB531019 (MdTCP2a mRNA), AB531020 (MdTCP2b mRNA), AB531021 (MdTCP4a mRNA), AB531022 (MdTCP4b mRNA) and AB531023 (MdVOZ1a mRNA).

Molecular characterization of FLOWERING LOCUS T-like genes of apple (Malus x domestica Borkh.).

The two FLOWERING LOCUS T (FT)-like genes of apple (Malus x domestica Borkh.), MdFT1 and MdFT2, have been isolated and characterized. MdFT1 and MdFT2 were mapped, respectively, on distinct linkage groups (LGs) with partial homoeology, LG 12 and LG 4. The expression pattern of MdFT1 and MdFT2 differed in that MdFT1 was expressed mainly in apical buds of fruit-bearing shoots in the adult phase, with little expression in the juvenile tissues, whereas MdFT2 was expressed mainly in reproductive organs, including flower buds and young fruit. On the other hand, both genes had the potential to induce early flowering since transgenic Arabidopsis, which ectopically expressed MdFT1 or MdFT2, flowered earlier than wild-type plants. Furthermore, overexpression of MdFT1 conferred precocious flowering in apple, with altered expression of other endogenous genes, such as MdMADS12. These results suggest that MdFT1 could function to promote flowering by altering the expression of those genes and that, at least, other genes may play an important role as well in the regulation of flowering in apple. The long juvenile period of fruit trees prevents early cropping and efficient breeding. Our findings will be useful information to unveil the molecular mechanism of flowering and to develop methods to shorten the juvenile period in various fruit trees, including apple.

Genomic diversity of germinating scutellum specific gene P23k in barley and wheat.

P23k is a 23 kDa protein involved in sugar translocation in the scutellum of germinating barley seeds. The present study was carried out to provide the genomic characterization for P23k gene in terms of copy number, chromosome mapping, genetic mapping and expression analysis in germinating sculletum in two major Triticeae crops, barley and wheat, and their relatives. Southern blotting showed that a variable copy number with different restriction fragment sizes was found among 15 Hordeum accessions, while low copy number were found to be conserved in 23 Triticum and 3 Aegilops accessions. Genetic and physical mapping study identified that the P23k gene is duplicated in wild and cultivated barley on chromosomes 1H, 2H, and 3H, and further tandem duplication on chromosomes 1H and 3H. In contrast, the wheat P23k is located on chromosome 3A of durum wheat and at the distal portion of the long arms of 3A and 3D chromosomes of bread wheat. Northern blotting showed remarkably high accumulation of P23k transcript in the germinating scutellum in cultivated and wild barley, whereas very few or no accumulation was detected in diploid, tetraploid, and hexaploid wheat accessions. The present study suggests a simple scenario where the ancestral P23k is encoded on the distal portion of an ancestral chromosome of homoeologous chromosome 3. Beside of polyploidy, dispersed and tandem duplications could trigger generation of the P23k family in the Hordeum lineage, while an ancestral P23k has been conserved in homoeologous 3A and 3D chromosomes in the wheat lineage.

FRIGIDA delays flowering in Arabidopsis via a cotranscriptional mechanism involving direct interaction with the nuclear cap-binding complex.

A major determinant of flowering time in natural Arabidopsis (Arabidopsis thaliana) variants is FRIGIDA (FRI). FRI up-regulates expression of the floral repressor FLOWERING LOCUS C (FLC), thereby conferring a vernalization requirement and a winter annual habit. FRI encodes a novel nuclear protein with no conserved domains except for two coiled-coil regions. A mutation in the large subunit of the nuclear cap-binding complex (CBC) suppresses FRI activity, so we have explored the connection between FRI and the nuclear CBC in order to gain further insight into FRI biochemical activity. Mutations in the small subunit of the CBC (CBP20) also suppress FRI up-regulation of FLC. CBP20 interacted directly with FRI in yeast and in planta, and this association of FRI with the 5' cap was reinforced by an RNA ligase-mediated rapid amplification of cDNA ends assay that showed FRI decreased the proportion of FLC transcripts lacking a 5' cap. Loss of CBP20 resulted in very low FLC mRNA levels and an increased proportion of unspliced FLC transcripts. FRI compensated for CBP20 loss, partially restoring FLC levels and normalizing the unspliced-spliced transcript ratio. Our data suggest that FRI up-regulates FLC expression through a cotranscriptional mechanism involving direct physical interaction with the nuclear CBC with concomitant effects on FLC transcription and splicing.

Rice shoot branching requires an ATP-binding cassette subfamily G protein.

* Shoot branching is important for the establishment of plant architecture and productivity. * Here, characterization of rice (Oryza sativa) reduced culm number 1 (rcn1) mutants revealed that Rcn1 positively controls shoot branching by promoting the outgrowth of lateral shoots. Molecular studies revealed that Rcn1 encodes a novel member of ATP-binding cassette protein subfamily G (ABCG subfamily), also known as the white-brown complex (WBC) subfamily, and is designated OsABCG5. * Rcn1 is expressed in leaf primordia of main and axillary shoots, and in the vascular cells and leaf epidermis of older leaves. In addition, Rcn1 is expressed in the crown root primordia, endodermis, pericycle and stele in the root. No effect on Rcn1 expression in shoots or roots was seen when the roots were treated with auxins. Phenotypic analyses of rcn1 and tillering dwarf 3 (d3) double mutants at the seedling stage clarified that Rcn1 works independently of D3 in the branching inhibitor pathway. * Rcn1 is the first functionally defined plant ABCG protein gene that controls shoot branching and could thus be significant in future breeding for high-yielding rice.

Virus-induced gene silencing of P23k in barley leaf reveals morphological changes involved in secondary wall formation.

P23k is a monocot-unique protein that is highly expressed in the scutellum of germinating barley seed. Previous expression analyses suggested that P23k is involved in sugar translocation and/or sugar metabolism. However, the role of P23k in barley physiology remains unclear. Here, to elucidate its physiological function, BSMV-based virus-induced gene silencing (VIGS) of P23k in barley leaves was performed. Expression and localization analyses of P23k mRNA in barley leaves showed up-regulation of P23k transcript with increased photosynthetic activity and the localization of these transcripts to the vascular bundles and sclerenchyma, where secondary wall formation is most active. VIGS of the P23k gene led to abnormal leaf development, asymmetric orientation of main veins, and cracked leaf edges caused by mechanical weakness. In addition, histochemical analyses indicated that the distribution of P23k in leaves coincides with the distribution of cell wall polysaccharides. Considering these results together, it is proposed that P23k is involved in the synthesis of cell wall polysaccharides and contributes to secondary wall formation in barley leaves.

Constitutive expression of two apple (Malus x domestica Borkh.) homolog genes of LIKE HETEROCHROMATIN PROTEIN1 affects flowering time and whole-plant growth in transgenic Arabidopsis.

Fruit trees, such as apple (Malus x domestica Borkh.), are woody perennial plants with a long juvenile phase. The biological analysis for the regulation of flowering time provides insights into the reduction of juvenile phase and the acceleration of breeding in fruit trees. In Arabidopsis, LIKE HETEROCHROMATIN PROTEIN1 (LHP1) is involved in epigenetic silencing of the target genes such as flowering genes. We isolated and characterized twin apple LHP1 homolog genes, MdLHP1a and MdLHP1b. These genes may have been generated as a result of ancient genome duplication. Although the putative MdLHP1 proteins showed lower similarity to any other known plant LHP1 homologs, a chromo domain, a chromo shadow domain, and the nuclear localization signal motifs were highly conserved among them. RT-PCR analysis showed that MdLHP1a and MdLHP1b were expressed constantly in developing shoot apices of apple trees throughout the growing season. Constitutive expression of MdLHP1a or MdLHP1b could compensate for the pleiotropic phenotype of lhp1/tfl2 mutant, suggesting that apple LHP1 homolog genes are involved in the regulation of flowering time and whole-plant growth. Based on these results, LHP1 homolog genes might have rapidly evolved among plant species, but the protein functions were conserved, at least between Arabidopsis and apple.

Localization of actin filaments on mitotic apparatus in tobacco BY-2 cells.

Actin filaments are among the major components of the cytoskeleton, and participate in various cellular dynamic processes. However, conflicting results had been obtained on the localization of actin filaments on the mitotic apparatus and their participation in the process of chromosome segregation. We demonstrated by using rhodamine-phalloidin staining, the localization of actin filaments on the mitotic spindles of tobacco BY-2 cells when the cells were treated with cytochalasin D. At prophase, several clear spots were observed at or near the kinetochores of the chromosomes. At anaphase, the actin filaments that appeared to be pulling chromosomes toward the division poles were demonstrated. However, as there was a slight possibility that these results might have been the artifacts of cytochalasin D treatment or the phalloidin staining, we analyzed the localization of actin filaments at the mitotic apparatus immunologically. We cloned a novel BY-2 alpha-type actin cDNA and prepared a BY-2 actin antibody. The fluorescence of the anti-BY-2 actin antibody was clearly observed at the mitotic apparatus in both non-treated and cytochalasin D-treated BY-2 cells during mitosis. The facts that similar results were obtained in both actin staining with rhodamine-phalloidin and immunostaining with actin antibody strongly indicate the participation of actin in the organization of the spindle body or in the process of chromosome segregation. Furthermore, both filamentous actin and spindle bodies disappeared in the cells treated with propyzamide, which depolymerizes microtubules, supporting the notion that actin filaments are associated with microtubules organizing the spindle body.

Interaction between elongation factors 1beta and 1gamma from Bombyx mori silk gland.

Elongation factor 1 (EF-1) from the silk gland of Bombyx mori consists of four subunits: alpha (51 kDa), beta (26 kDa), gamma (49 kDa), and delta (33 kDa). The EF-1alpha subunit catalyzes the binding of aminoacyl-tRNA to the ribosome concomitant with the hydrolysis of GTP. The EF-1alpha-bound GDP is then exchanged for GTP by the EF-1betagammadelta complex. To facilitate analysis of the roles of the individual EF-1beta, gamma, and delta subunits in GDP/GTP exchange on EF-1alpha, we cloned the cDNAs for these subunits and expressed them in Escherichia coli. EF-1beta, EF-1gamma, and the carboxyl-terminal half of EF-1delta were expressed, purified, and examined for protein:protein interactions by gel filtration chromatography and by a quartz-crystal microbalance method. An 80-kDa species containing EF-1beta and gamma subunits in a 1:1 molar ratio was detected by gel filtration. A higher molecular weight species containing an excess of EF-1gamma relative to EF-1beta was also detected. The amino-terminal region of EF-1beta (amino acid residues 1-129) was sufficient for binding to EF-1gamma. The carboxyl-terminal half of EF-1delta did not appear to form a complex with EF-1gamma.

Cloning and expression of Bombyx mori silk gland elongation factor 1gamma in Escherichia coli.

Elongation factor 1 (EF-1) from the silk gland of Bombyx mori consists of alpha-, beta-, gamma-, and delta-subunits. EF-1alpha GTP catalyzes the binding of aminoacyl-tRNA to ribosomes concomitant with the hydrolysis of GTP. EF-1betagammadelta catalyzes the exchange of EF-1alpha-bound GDP for exogenous GTP and stimulates the EF-1alpha-dependent binding of aminoacyl-tRNA to ribosomes. EF-1gamma cDNA, which contains an open reading frame (ORF) encoding a polypeptide of 423 amino acid residues, was amplified and cloned by PCR from a silk gland cDNA library. The calculated molecular mass and predicted pI of the product were 48,388 Da and 5.84, respectively. The silk gland EF-1gamma shares 67.3% amino acid identity with Artemia salina EF-lgamma. The N-terminal domain (amino acid residues 1-211) of silk gland EF-lgamma is 29.3% identical to maize glutathione S-transferase. We demonstrated that silk gland EF-lgamma bound to glutathione Sepharose, suggesting that the N-terminal domain of EF-1gamma may have the capacity to bind to glutathione.