Phosphorylation-dependent interactions between enzymes of plant metabolism and 14-3-3 proteins

Far-Western overlays of soluble extracts of cauliflower revealed many proteins that bound to digoxygenin (DIG)-labelled 14-3-3 proteins. Binding to DIG-14-3-3s was prevented by prior dephosphorylation of the extract proteins or by competition with 14-3-3-binding phosphopeptides, indicating that the 14-3-3 proteins bind to phosphorylated sites. The proteins that bound to the DIG-14-3-3s were also immunoprecipitated from extracts with anti-14-3-3 antibodies, demonstrating that they were bound to endogenous plant 14-3-3 proteins. 14-3-3-binding proteins were purified from cauliflower extracts, in sufficient quantity for amino acid sequence analysis, by affinity chromatography on immobilised 14-3-3 proteins and specific elution with a 14-3-3-binding phosphopeptide. Purified 14-3-3-binding proteins included sucrose–phosphate synthase, trehalose-6-phosphate synthase, glutamine synthetases, a protein (LIM17) that has been implicated in early floral development, an approximately 20 kDa protein whose mRNA is induced by NaCl, and a calcium-dependent protein kinase that was capable of phosphorylating and rendering nitrate reductase (NR) sensitive to inhibition by 14-3-3 proteins. In contrast to the phosphorylated NR-14-3-3 complex which is activated by dissociation with 14-3-3-binding phosphopeptides, the total sugar–phosphate synthase activity in plant extracts was inhibited by up to 40% by a 14-3-3-binding phosphopeptide and the phosphopeptide-inhibited activity was reactivated by adding excess 14-3-3 proteins. Thus, 14-3-3 proteins are implicated in regulating several aspects of primary N and C metabolism. The procedures described here will be valuable for determining how the phosphorylation and 14-3-3-binding status of defined target proteins change in response to extracellular stimuli.     

Regulatory role of SH3 domain-mediated protein-protein interactions in synaptic vesicle endocytosis.

Src homology (SH) 3 domains are small modules found in a diverse array of proteins. The presence of an SH3 domain confers upon its resident protein the ability to interact with specific proline-rich sequences in protein binding partners. A major focus of research has highlighted a role for SH3 domain-mediated interactions in the regulation of signal transduction events. However, more recent data has suggested an important function for SH3 domains in vesicular trafficking. This review will focus on this newly emerging role with a particular emphasis on the molecular components involved in synaptic vesicle endocytosis and the regulatory role of SH3 domain-mediated protein-protein interactions in this process.     

Imaging protein-protein interactions in living cells

The complex organization of plant cells makes it likely that the molecular behaviour of proteins in the test tube and the cell is different. For this reason, it is essential though a challenge to study proteins in their natural environment. Several innovative microspectroscopic approaches provide such possibilities, combining the high spatial resolution of microscopy with spectroscopic techniques to obtain information about the dynamical behaviour of molecules. Methods to visualize interaction can be based on FRET (fluorescence detected resonance energy transfer), for example in fluorescence lifetime imaging microscopy (FLIM). Another method is based on fluorescence correlation spectroscopy (FCS) by which the diffusion rate of single molecules can be determined, giving insight into whether a protein is part of a larger complex or not. Here, both FRET- and FCS-based approaches to study protein-protein interactions in vivo are reviewed.     

Multifunctional 14-3-3 proteins of plant cell

The 14-3-3 proteins are a family of highly conserved proteins found in all eukaryotes - from the yeasts to mammals. They regulate several cellular processes recognizing unique conservative, mostly phosphorylated motif of partner proteins. Binding of the 14-3-3 proteins regulates their partners through a variety of mechanisms, such as altering their catalytic activity, subcellular localization, stability or altering their interactions with other protein molecules. The native 14-3-3 proteins are present in form of homo- and hetero-dimers. The most structurally variable N-and C-termini are responsible for isoform specific protein-protein interactions, and cellular localization. In plant cell, 14-3-3 proteins appear to play an important role in regulation of key enzymes of carbon and nitrogen metabolism, modulation ion pumps and channels. They are also involved in signal transduction pathways and even in gene expression.     

14-3-3 proteins fine-tune plant nutrient metabolism

14-3-3 Proteins regulate many cellular processes by binding to phosphorylated proteins. Previous findings suggest a connection between three 14-3-3 isoforms and plant nutrient signaling. To better understand how these 14-3-3s regulate metabolism in response to changes in plant nutrient status, putative new targets involved in nitrogen (N) and sulfur (S) metabolisms have been identified. The interactions between these 14-3-3s and multiple proteins involved in N and S metabolism and altered activity of the target proteins were confirmed in planta. Using a combination of methods, this work elucidates how 14-3-3s function as modulators of plant N and S metabolic pathways.     

14-3-3蛋白家族的调控机制和生物学功能

14-3-3蛋白家族在真核细胞中广泛表达并高度保守,它们主要以同源／异源二聚体形式存在,可以同时与两个靶蛋白或一个靶蛋白的两个结构域相互作用。14-3-3蛋白通过磷酸化丝氨酸／苏氨酸介导和靶蛋白结合,从而发挥其调控功能。现对14-3-3蛋白的识别序列、与配体相互作用的特点,及其在细胞周期、凋亡、信号转导、线粒体／叶绿体前体蛋白跨膜转运中的调控机制和发挥的生物学功能进行综述。     

Phosphorylation-dependent 14-3-3 protein interactions regulate CFTR biogenesis

Cystic fibrosis transmembrane conductance regulator (CFTR) is a cAMP/protein kinase A (PKA)-regulated chloride channel whose phosphorylation controls anion secretion across epithelial cell apical membranes. We examined the hypothesis that cAMP/PKA stimulation regulates CFTR biogenesis posttranslationally, based on predicted 14-3-3 binding motifs within CFTR and forskolin-induced CFTR expression. The 14-3-3β, γ, and ε isoforms were expressed in airway cells and interacted with CFTR in coimmunoprecipitation assays. Forskolin stimulation (15 min) increased 14-3-3β and ε binding to immature and mature CFTR (bands B and C), and 14-3-3 overexpression increased CFTR bands B and C and cell surface band C. In pulse-chase experiments, 14-3-3β increased the synthesis of immature CFTR, reduced its degradation rate, and increased conversion of immature to mature CFTR. Conversely, 14-3-3β knockdown decreased CFTR B and C bands (70 and 55%) and elicited parallel reductions in cell surface CFTR and forskolin-stimulated anion efflux. In vitro, 14-3-3β interacted with the CFTR regulatory region, and by nuclear magnetic resonance analysis, this interaction occurred at known PKA phosphorylated sites. In coimmunoprecipitation assays, forskolin stimulated the CFTR/14-3-3β interaction while reducing CFTR's interaction with coat protein complex 1 (COP1). Thus 14-3-3 binding to phosphorylated CFTR augments its biogenesis by reducing retrograde retrieval of CFTR to the endoplasmic reticulum. This mechanism permits cAMP/PKA stimulation to make more CFTR available for anion secretion.     

Monitoring protein-protein interactions in mammalian cells by trans-SUMOylation

Protein-protein interactions are essential for almost all cellular processes, hence understanding these processes mainly depends on the identification and characterization of the relevant protein-protein interactions. In the present paper, we introduce the concept of TRS (trans-SUMOylation), a new method developed to identify and verify protein-protein interactions in mammalian cells in vivo. TRS utilizes Ubc9-fusion proteins that trans-SUMOylate co-expressed interacting proteins. Using TRS, we analysed interactions of 65 protein pairs co-expressed in HEK (human embryonic kidney)-293 cells. We identified seven new and confirmed 16 known protein interactions, which were determined via endogenous SUMOylation sites of the binding partners or by using SUMOylation-site tags respectively. Four of the new protein interactions were confirmed by GST (glutathione transferase) pull-down and the p38α-Edr2 interaction was verified by co-localization analysis. Functionally, this p38α-Edr2 interaction could possibly be involved in the recruitment of p38α to the polycomb chromatin-remodelling complex to phosphorylate Bmi1. We also used TRS to characterize protein-interaction domains of the protein kinase pairs p38α-MK2 [MK is MAPK (mitogen-activated protein kinase)-activated protein kinase] and ERK3 (extracellular-signal-regulated kinase 3)-MK5 and of the p38α-p53 complex. The ability of TRS to monitor protein interactions in mammalian cells in vivo at levels similar to endogenous expression makes it an excellent new tool that can help in defining the protein interactome of mammalian cells.     

Evolution and isoform specificity of plant 14-3-3 proteins

The 14-3-3 proteins, once thought of as obscure mammalian brain proteins, are fast becoming recognized as major regulators of plant primary metabolism and of other cellular processes. Their presence as large gene families in plants underscores their essential role in plant physiology. We have examined the Arabidopsis thaliana 14-3-3 gene family, which currently is the largest and most complete 14-3-3 family with at least 12 expressed members and 15 genes from the now completed Arabidopsis thaliana genome project. The phylogenetic branching of this family serves as the prototypical model for comparison with other large plant 14-3-3 families and as such may serve to rationalize clustering in a biological context. Equally important for ascribing common functions for the various 14-3-3 isoforms is determining an isoform-specific correlation with localization and target partnering. A summary of localization information available in the literature is presented. In an effort to identify specific 14-3-3 isoform location and participation in cellular processes, we have produced a panel of isoform-specific antibodies to Arabidopsis thaliana 14-3-3s and present initial immunolocalization studies that suggest biologically relevant, discriminative partnering of 14-3-3 isoforms.     

Conservation of protein-protein interactions - lessons from ascomycota

Interacting proteins from Saccharomyces cerevisiae are evolutionarily conserved and their likelihood of having an ortholog in other ascomycota species correlates with the number of interaction partners. Moreover, interacting proteins show a clear preference to be conserved as a pair, indicating that nature maintains selection pressure on the interaction links between proteins. The conservation of interacting protein pairs between different organisms does not exhibit any bias with respect to protein functional roles.     

Non-additivity in protein-protein interactions

The energy of binding between proteins may be seen as the sum of the contributions of the individual amino acid residues. These contributions are additive when the binding energy, due to different amino acid residues, is independent of the interactions between amino acids in the same polypeptide chain. A measure of non-additivity is the coupling free energy. In this communication it is shown that: (1) the coupling free energy is the sum of intramolecular and intermolecular contributions; and (2), when additivity exists, experimentally determined values for the free energy of transfer of amino acids from water to the hydrophobic protein-protein interface are a very good approximation of their contribution to the energy of binding. Additivity cycles can be useful in determining the precise conditions where this approximation holds.     

Smart role of plant 14-3-3 proteins in response to phosphate deficiency

Higher plants adapt to phosphorus deficiency through a complex of biological processes. Among of them, two adaptive processes are very important for the response of higher plants to phosphorus deficiency. One is the enhancement of root growth by regulating carbohydrate metabolism and allocation, and the other is rhizosphere acidification to acquire phosphorus efficiently from soil. TFT6 and TFT7, two different members of tomato 14-3-3 gene family, play the distinct roles in the adaption of plants to phosphorus deficiency by taking part in the two processes respectively. TFT6 which acts mainly in leaves is involved in the systemic response to phosphorus deficiency by regulating leaf carbon allocation and increasing phloem sucrose transport to promote root growth, while TFT7 directly functions in root by activating root plasma membrane H⁺-ATPase to release more protons under phosphorus deficiency. Based on these results, we propose that 14-3-3 proteins play the smart role in response to phosphorus deficiency in higher plants.