The GAMYB protein from barley interacts with the DOF transcription factor BPBF and activates endosperm‐specific genes during seed development
SummaryHvGAMYB, a MYB transcription factor previously shown to be expressed in barley aleurone cells in response to gibberellin during germination, also has an important role in gene regulation during endosperm development. The mRNA was detected early (10 DAF) in the seeds where it accumulates, not only in the aleurone layer, starchy endosperm, nucellar projection and vascular tissue, but also in the immature embryo as shown by in situ hybridization analysis. The HvGAMYB protein, expressed in bacteria, binds to oligonucleotides containing the 5¢-TAACAAC-3¢ or 5¢-CAACTAAC-3¢ sequences, derived from the promoter regions of the endosperm-speci®c genes Hor2 and Itr1, encoding a B-hordein and trypsin-inhibitor BTI-CMe, respectively. Binding is prevented when these motifs are mutated to 5¢-TgACAAg-3¢ and 5¢-CgACTgAC-3¢. Transient expression experiments in co-bombarded developing endosperms demonstrate that HvGAMYB trans-activates transcription from native Hor2 and Itr1 promoters through binding to the intact motifs described above. Trans-activation of the Hor2 promoter also requires an intact prolamine box (PB). This suggests that HvGAMYB interacts in developing barley endosperms with the PB-binding factor BPBF, an endosperm-speci®c DOF transcriptional activator of the Hor2 gene. The in vivo interaction experiment between HvGAMYB and BPBF was done in the yeast twohybrid system, where HvGAMYB potentiates the BPBF trans-activation capacity through interaction with its C-terminal domain.
Synergistic Activation of Seed Storage Protein Gene Expression in Arabidopsis by ABI3 and Two bZIPs Related to OPAQUE2
The expression of many seed storage protein genes in cereals relies on transcription factors of the bZIP class, belonging to the maize OPAQUE2 family. Here, we describe a survey of such factors in the genome of Arabidopsis thaliana, and the characterization of two of them, AtbZIP10 and AtbZIP25. Expression analysis by in situ hybridization shows that the occurrence of their mRNAs in the seed starts from early stages of development, peaks at maturation, and declines later in seed development, matching temporally and spatially those of the seed storage protein genes encoding 2S albumins and cruciferins. Gel mobility shift assays showed that AtbZIP10 and AtbZIP25 bind the ACGT boxes present in At2S and CRU3 promoters. Moreover, using the yeast two-hybrid system we show that AtbZIP10 and AtbZIP25 can interact in vivo with ABI3, an important regulator of gene expression in the seed of Arabidopsis. Transient expression analyses of a reporter gene under the control of the At2S1 promoter in transgenic plants overexpressing ectopically AtbZIP10, AtbZIP25, and ABI3 reveal that none of these factors could activate significantly the reporter gene when expressed individually. However, co-expression of AtbZIP10/25 with ABI3 resulted in a remarkable increase in the activation capacity over the At2S1 promoter, suggesting that they are part of a regulatory complex involved in seed-specific expression. This study shows a common mechanism of ABI3 in regulating different seed-specific genes through combinatorial interactions with particular bZIP proteins and a conserved role of O2-like bZIPs in monocot and dicot species.During seed development, storage reserves accumulate mostly in the form of carbohydrates and proteins, whose degradation upon germination will provide nutrients to the growing seedling before the photosynthetic capacity is fully acquired. Seed storage proteins (SSP) 1 are specifically synthesized in developing seeds, both in the endosperm and in the embryo. In the seed of monocotyledoneous species, the former is the predominant reserve tissue, whereas in dicotyledoneous plants the endosperm is commonly re-absorbed as maturation proceeds, and storage proteins are preferentially accumulated in the embryo. Because SSP-encoding genes are specifically induced and tightly regulated during seed development, they represent an interesting model system for studying the mechanisms of temporal and tissue-specific gene regulation.In the developing seed, different programs of gene expression have been defined that comprise distinct classes of genes that are coordinately regulated (1, 2). The MAT (maturation) class includes major SSP genes (like 2S albumins and 12S globulins) expressed at early and mid-maturation phases, whereas the LEA (late embryogenesis abundant) class includes primarily genes involved in the acquisition of desiccation tolerance expressed at later stages of maturation (3, 4). Unraveling the molecular basis of seed-specific gene expression has been mainly focused on the identification of cis-acting promoter el...
Arabidopsis thaliana S-Phase Kinase-Associated Protein 2A (SKP2A) is an F-box protein that regulates the proteolysis of cell cycle transcription factors. The plant hormone auxin regulates multiple aspects of plant growth and development, including cell division. We found that auxin induces the ubiquitin-dependent degradation of SKP2A both in vivo and in vitro, suggesting that this hormone acts as a signal to trigger SKP2A proteolysis. In this article, we show that auxin binds directly and specifically to SKP2A. By TIR1-based superposition and docking analyzes, we identified an auxin binding site in SKP2A. Mutations in this binding site reduce the ability of SKP2A to bind to auxin and generate nondegradable SKP2A forms. In addition, these non-auxin binding proteins are unable to promote E2FC/DPB degradation in vivo or to induce cell division in the root meristem. Auxin binds to TIR1 to promote its interaction with the auxin/indole-3-acetic acid target proteins. Here, we show that auxin also enhanced the interaction between SKP2A and DPB. Finally, a mutation in SKP2A leads to auxinresistant root growth, an effect that is additive with the tir1-1 phenotype. Thus, our data indicate that SKP2A is an auxin binding protein that connects auxin signaling with cell division.
Ubiquitin (Ub) is a small peptide that is covalently attached to proteins in a posttranslational reaction. Ubiquitination is a precise regulatory system that is present in all eukaryotic organisms and regulates the stability, the activity, the localization and the transport of proteins. Ubiquitination involves different enzymatic activities, in which the E3 ligases catalyze the last step recruiting of the target for labelling with ubiquitin. Genomic analyses have shown that the ubiquitin-proteasome system involves a large number of proteins in plants, as approximately 5% of the total protein belongs to this pathway. In contrast to the high number of E3 ligases of ubiquitin identified, very few proteins regulated by ubiquitination have been described. To solve this, we have undertaken a new proteomic approach aimed to identify proteins modified with ubiquitin. This is based on affinity purification and identification for ubiquitinated proteins using the ubiquitin binding domain (UBA) polypeptide of the P62 protein attached to agarose beads. This P62-agarose matrix is capable of specifically binding ubiquitinated proteins. These bound proteins were digested with trypsin and the peptides separated by HPLC chromatography, spotted directly onto a MALDI target and analyzed by MALDI-TOF/TOF off-line coupled LC/MALDI-MS/MS. A total of 200 putative ubiquitinated proteins were identified. From these we found that several of the putative targets were already described in plants, as well as in other organisms, as ubiquitinated proteins. In addition, we have found that some of these proteins were indeed modified with ubiquitin in vivo. Taken together, we have shown that this approach is useful for identifying ubiquitinated protein in plants.
An EST, encoding a strawberry phytocystatin (PhyCys) obtained from a developing fruit of Fragariaxananassa cv. Elsanta has been characterized. The corresponding gene (Cyf1) had three introns interrupting its ORF that codes for a protein (FaCPI-1) of 235 amino acid residues with a putative signal peptide of 29 residues and an estimated molecular mass for the mature protein of 23.1 kDa. This protein contains, besides a C-terminal extension, several motifs conserved in all members of the PhyCys superfamily: (i) a GG and LARFAV-like motifs towards the N-terminal part of the protein; (ii) the reactive site QVVAG, and (iii) a conserved PW, downstream of the reactive site. Northern blot and in situ hybridization analyses indicated that the Cyf1 gene was expressed in fully expanded leaves, in roots and in achenes, but not in the receptacle (pseudocarp) during fruit development. The recombinant FaCPI-1 protein expressed in E. coli efficiently inhibited papain (K(i) 1.9 x 10(-9) M) and less so cathepsin H (K(i) 4.7 x 10(-7) M) and cathepsin B (K(i) 3.3 x 10(-6) M), and was a good inhibitor of the in vitro growth of phytopathogenic fungi Botrytis cinerea (EC(50): 1.90 microM) and Fusarium oxysporum (EC(50): 2.28 microM).
Comparative phylogenetic analysis of cystatin gene families from arabidopsis, rice and barley
The plant cystatins or phytocystatins comprise a family of specific inhibitors of cysteine proteinases. Such inhibitors are thought to be involved in the regulation of several endogenous processes and in defence against pests and pathogens. Extensive searches in the complete rice and Arabidopsis genomes and in barley EST collections have allowed us to predict the presence of twelve different cystatin genes in rice, seven in Arabidopsis, and at least seven in barley. Structural comparisons based on alignments of all the protein sequences using the CLUSTALW program and searches for conserved motifs using the MEME program have revealed broad conservation of the main motifs characteristic of the plant cystatins. Phylogenetic analyses based on their deduced amino acid sequences have allowed us to identify groups of orthologous cystatins, and to establish homologies and define examples of gene duplications mainly among the rice and barley cystatin genes. Moreover, the absence of a counterpart between the two monocots, as well as strong variations in the motifs that interact with the cysteine proteinases, may be related to a species-specific evolutionary process. This cystatin classification should facilitate the assignment of proteinase specificities and functions to other cystatins as new information is obtained.
The ubiquitin pathway is emerging as a powerful system that controls the stability of key regulatory proteins. In plants, this pathway plays an important role in controlling several developmental processes, responses to environmental changes and also cell division. Arabidopsis SKP2A is an F-box protein that regulates the stability of the E2FC-DPB transcription factor, a repressor of cell proliferation. Although the function of SKP2A is to recruit targets for degradation, we have shown that SKP2A is also degraded through the Ub/26S pathway and, interestingly, auxin stimulates such degradation. Overexpression of SKP2A positively regulates cell division, increasing the number of cells in G(2)/M, reducing the level of ploidy and developing higher number of lateral root primordia. In addition, we showed in this report that overexpression of SKP2A increased the survival of Arabidopsis plants when they grown on a medium with high levels of sucrose, likely by maintaining cell division active. Thus, it is likely that SKP2A connects cell division with stress responses.
Structural and functional diversity within the cystatin gene family of Hordeum vulgare
Phytocystatins are inhibitors of cysteine proteinases from plants putatively involved in defence and as endogenous regulators of protein turnover. Seven genes encoding cystatins (HvCPI-1 to HvCPI-7), identified from EST collections and from an endosperm cDNA library, have been characterized. The intron-exon structure of their corresponding ORFs has been determined and the predicted three-dimensional models for the seven barley cystatins have been established, based on the known crystal structure of oryzacystatin I from rice. Only one out of the seven deduced proteins, HvCPI-7, had sequence variations affecting the three conserved motifs implicated in the enzyme-inhibitor interaction. In three cases, HvCPI-5, HvCPI-6, and HvCPI-7, amino acid differences lead to the prediction of important structural changes in their three-dimensional structures. Northern blot analysis indicated that the seven genes have different expression patterns in barley tissues. The recombinant proteins expressed in Escherichia coli showed distinct inhibitory properties in vitro, with different K(i) values, against the three cysteine proteinases tested: papain, cathepsin B, and cathepsin H. Moreover, these recombinant proteins presented differential fungicidal characteristics inhibiting the growth of phytopathogenic fungi Botrytis cinerea and Fusarium oxysporum in vitro. The resulting implications for the structural and functional diversity of the seven barley cystatins studied are discussed.
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