The multi-PDZ domain protein-1 (MUPP-1) expression regulates cellular levels of the PALS-1/PATJ polarity complex

MUPP-1 (multi-PDZ domain protein-1) and PATJ (PALS-1-associated tight junction protein) proteins are closely related scaffold proteins and bind to many common interactors including PALS-1 (protein associated with Lin seven) a member of the Crumbs complex. Our goal is to understand how MUPP-1 and PATJ and their interaction with PALS-1 are regulated in the same cells. We have shown that in MCF10A cells there are at least two different and co-existing complexes, PALS-1/MUPP-1 and PALS-1/PATJ. Surprisingly, MUPP-1 levels inversely correlated with PATJ protein levels by acting on the stabilization of the PATJ/PALS-1 complex. Upon MUPP-1 depletion, the increased amounts of PATJ are in part localized at the migrating front of MCF10A cells and are able to recruit more PAR3 (partition defective 3). All together these data indicate that a precise balance between MUPP-1 and PATJ is achieved in epithelial cells by regulating their association with PALS-1.     

Phosphorylation of cold shock domain/Y-box proteins by ERK2 and GSK3beta and repression of the human VEGF promoter

The hypoxia responsive region (HRR) of the VEGF promoter plays a key role in regulating VEGF expression. We found that the cold shock domain (Y-box) repressor proteins, dbpA and dbpB/YB-1, bind distinct strands of the human VEGF HRR. We find both dbpA and dbpB are phosphorylated by ERK2 and GSK3beta in vitro, and the binding of dbpB to single-strand VEGF HRR DNA is regulated by this phosphorylation. These findings suggest the ERK/MAPK and PI3K pathways may regulate VEGF expression in part through regulating the action of these repressor proteins.     

Protein tyrosine phosphatase receptor type Z is inactivated by ligand-induced oligomerization

Receptor-type protein tyrosine phosphatases (RPTPs) are considered to transduce extracellular signals across the membrane through changes in their PTP activity, however, our understanding of the regulatory mechanism is still limited. Here, we show that pleiotrophin (PTN), a natural ligand for protein tyrosine phosphatase receptor type Z (Ptprz) (also called PTPzeta/RPTPbeta), inactivates Ptprz through oligomerization and increases the tyrosine phosphorylation of substrates for Ptprz, G protein-coupled receptor kinase-interactor 1 (Git1) and membrane associated guanylate kinase, WW and PDZ domain containing 1 (Magi1). Oligomerization of Ptprz by an artificial dimerizer or polyclonal antibodies against its extracellular region also leads to inactivation, indicating that Ptprz is active in the monomeric form and inactivated by ligand-induced oligomerization.     

An Oligomeric Equilibrium Intermediate as the Precursory Nucleus of Globular and Fibrillar Supramacromolecular Assemblies in a PDZ Domain

The equilibrium unfolding at neutral pH of the third PDZ domain of PSD95, as followed by DSC, is characterized by the presence of an equilibrium intermediate with clear signs of oligomerization. DLS and SEC measurements indicate that at 60-70°C small oligomers populate, showing a typical β-sheet far-UV CD spectrum. These intermediate species lead to the formation of rodlike particulates of ∼12 nm, which remain in solution after 2 weeks incubation and grow until they adopt annular/spherical shapes of ∼50 nm and protofibrils, which are subsequently fully transformed into fibrils. The fibrils can also disaggregate after the addition of 1:1 buffer dilution followed by cooling to room temperature, thus returning to the initial monomeric state. Growth kinetics, as shown by ThT and ANS fluorescence, show that the organization of the different supramacromolecular structures comes from a common nucleation unit, the small oligomers, which organize themselves before reaching the incubation temperature of 60°C. Our experiments point toward the existence of a well-defined reversible, stepwise, and downhill organization of the processes involved in the association-dissociation of the intermediate. We estimate the enthalpy change accompanying the association-dissociation equilibria to be 130 kJ × mol⁻¹. Furthermore, the coalescence under essentially reversible conditions of different kinds of supramacromolecular assemblies renders this protein system highly interesting for biophysical studies aimed at our further understanding of amyloid pathological conditions.     

The tumor suppressor Scrib selectively interacts with specific members of the zyxin family of proteins

The zyxin family of proteins consists of five members, ajuba, LIMD1, LPP, TRIP6 and zyxin, which localize at cell adhesion sites and shuttle to the nucleus. Previously, we established that LPP interacts with the tumor suppressor Scrib, a member of the leucine-rich repeat and PDZ (LAP) family of proteins. Here, we demonstrate that Scrib also interacts with TRIP6, but not with zyxin, ajuba, or LIMD1. We show that TRIP6 directly binds to the third PDZ domain of Scrib via its carboxy-terminus. Both proteins localize in cell-cell contacts but are not responsible to target each other to these structures. In the course of our experiments, we also characterized the nuclear export signal of human TRIP6, and show that LIMD1 is localized in focal adhesions. The binding between two of zyxin's family members and Scrib links Scrib to a communication pathway between cell-cell contacts and the nucleus, and implicates these zyxin family members in Scrib-associated functions.     

Mapping Cellular Polarity Networks Using Mass Spectrometry-based Strategies

Cell polarity is a vital biological process involved in the building, maintenance and normal functioning of tissues in invertebrates and vertebrates. Unsurprisingly, molecular defects affecting polarity organization and functions have a strong impact on tissue homeostasis, embryonic development and adult life, and may directly or indirectly lead to diseases. Genetic studies have demonstrated the causative effect of several polarity genes in diseases; however, much remains to be clarified before a comprehensive view of the molecular organization and regulation of the protein networks associated with polarity proteins is obtained. This challenge can be approached head-on using proteomics to identify protein complexes involved in cell polarity and their modifications in a spatio-temporal manner. We review the fundamental basics of mass spectrometry techniques and provide an in-depth analysis of how mass spectrometry has been instrumental in understanding the complex and dynamic nature of some cell polarity networks at the tissue (apico-basal and planar cell polarities) and cellular (cell migration, ciliogenesis) levels, with the fine dissection of the interconnections between prototypic cell polarity proteins and signal transduction cascades in normal and pathological situations. This review primarily focuses on epithelial structures which are the fundamental building blocks for most metazoan tissues, used as the archetypal model to study cellular polarity. This field offers broad perspectives thanks to the ever-increasing sensitivity of mass spectrometry and its use in combination with recently developed molecular strategies able to probe in situ proteomic networks.     

Characterisation of the interaction between syndecan-2, neurofibromin and CASK: Dependence of interaction on syndecan dimerization

Neurofibromin and calcium/calmodulin-dependent serine protein kinase (CASK) are membrane-associated signalling and scaffolding proteins which are mutated in human genetic neurological disorders. Syndecan-2 is a highly glycosylated transmembrane protein whose intracellular C-terminus has previously been shown to interact with the post-synaptic density 95/discs large/zonula occludens-1 (PDZ) domain of CASK and with two separate regions of neurofibromin. These three proteins collaborate to orchestrate the induction of filopodia and dendritic spines. We have used systematic mutagenesis of the intracellular region of syndecan-2 and a quantitative yeast two-hybrid (Y2H) assay to study the determinants of their interactions. We show that syndecan’s interactions with both CASK and neurofibromin are dependent on syndecan homodimerization and that neurofibromin largely interacts with the membrane-proximal part of the dimeric syndecan intracellular domain, leaving the membrane-distal C-terminus free to interact with CASK. We conducted a phylogenetic study of syndecan sequences, finding correspondence between conserved residues and mutations affecting both dimerization and interactions; we also find that fish have a very different syndecan repertoire from tetrapods. Further Y2H screens reveal that syndecan-2 interacts with a third distinct region of neurofibromin, and that the multiple neurofibromin regions bind competitively, rather than co-operatively, to syndecan. We combine these results to propose a model for the ternary syndecan-neurofibromin-CASK complex.     

Tyrosine-phosphorylated Hic-5 inhibits epidermal growth factor-induced lamellipodia formation

The focal adhesion protein Hic-5, a homologue to paxillin, has been shown to be tyrosine-phosphorylated in fibroblasts in response to stimuli such as osmotic stress, serum, LPA and endothelin. However, the function of this modification to Hic-5 is unclear. Herein, we show that Hic-5 is tyrosine-phosphorylated on residues 38 and 60 following epidermal growth factor (EGF) treatment of COS-7 cells, coincident with an increase in peripheral actin reorganization. To explore the role of Hic-5 phosphorylation in this process, we introduced wild-type (WT) and mutant Hic-5 constructs into COS-7 cells and determined that EGF-induced lamellipodia formation was suppressed by WT Hic-5. This effect required localization to focal adhesions as well as phosphorylation of Hic-5 as overexpression of both a non-targeting and a non-phosphorylatable Hic-5 failed to inhibit peripheral actin reorganization. Interestingly, overexpression of non-phosphorylatable Y31/118F or WT paxillin did not affect lamellipodia formation, indicating that this effect is specific to Hic-5. The EGF-induced lamellipodia were Rac-dependent and overexpressed WT Hic-5, but not non-phosphorylatable Hic-5 inhibited Rac activation. Our data suggest that Hic-5 tyrosine phosphorylation functions to regulate signaling associated with lamellipodia formation, a process fundamental to cell motility.     

Superfamily of ankyrin repeat proteins in tomato

The ankyrin repeat (ANK) protein family plays a crucial role in plant growth and development and in response to biotic and abiotic stresses. However, no detailed information concerning this family is available for tomato (Solanum lycopersicum) due to the limited information on whole genome sequences. In this study, we identified a total of 130 ANK genes in tomato genome (SlANK), and these genes were distributed across all 12 chromosomes at various densities. And chromosomal localizations of SlANK genes indicated 25 SlANK genes were involved in tandem duplications. Based on their domain composition, all of the SlANK proteins were grouped into 13 subgroups. A combined phylogenetic tree was constructed with the aligned SlANK protein sequences. This tree revealed that the SlANK proteins comprise five major groups. An analysis of the expression profiles of SlANK genes in tomato in different tissues and in response to stresses showed that the SlANK proteins play roles in plant growth, development and stress responses. To our knowledge, this is the first report of a genome-wide analysis of the tomato ANK gene family. This study provides valuable information regarding the classification and putative functions of SlANK genes in tomato.     

Regulation of serotonin receptor function in the nervous system by lipid rafts and adaptor proteins

5-HT is a phylogenetically conserved monoaminergic neurotransmitter which is crucial for a number of physiological processes and is dysregulated in several disease states including depression, anxiety and schizophrenia. 5-HT neurons in the central nervous system are localized in the raphe nuclei and project to a wide range of target areas. 5-HT exerts its functions through 14 subtypes of 5-HT receptors. The tertiary structures of seven transmembrane 5-HT receptors contain several important features, including cholesterol consensus motifs, prominent intracellular loops and free C-termini. Alterations of cholesterol levels affect binding of ligands to 5-HT receptors and cholesterol-enriched microdomains in the cell membrane, termed lipid rafts, regulate 5-HT receptor internalization and signaling. The intracellular loops and the C-termini of 5-HT receptors provide binding sites for interacting adaptor proteins. Adaptor proteins affect internalization, desensitization as well as G-protein dependent and independent signaling via 5-HT receptors. We will here briefly review recent progress on the role of lipid rafts and adaptor proteins in the regulation of localization, trafficking, signaling and ligand bias of 5-HT receptors.     

Akt activation through the phosphorylation of erythropoietin receptor at tyrosine 479 is required for myeloproliferative disorder-associated JAK2 V617F mutant-induced cellular transformation

The disruption of Janus kinase 2 (JAK2) signaling regulation by its point mutation, V617F, is involved in various myeloproliferative disorders (MPDs). JAK2 V617F mutant induced constitutive activation of Akt when erythropoietin receptor (EpoR) was coexpressed; however, the physiological role of Akt activation in MPDs has not been elucidated. LY294002, a phosphoinositide 3-kinase (PI3K) inhibitor, inhibited Akt activation and induced apoptotic cell death in cells expressing JAK2 V617F mutant and EpoR. Previously, it has been shown that the phosphorylation at Y479 in EpoR is critical for the interaction with PI3K, an upstream molecule of Akt. Hence, EpoR mutant with a point mutation of Y479F, which fails to activate Akt, is useful for addressing the role of Akt activation in JAK2 V617F mutant-induced tumorigenesis. Interestingly, under the expression of EpoR Y479F mutant, JAK2 V617F mutant failed to exhibit potent anti-apoptotic activity. In addition, JAK2 V617F mutant-induced phosphorylation of CREB and GSK-3β was significantly decreased in cells expressing EpoR Y479F mutant, resulting in the downregulation of Bcl-XL and Mcl-1 expression. Furthermore, compared with when nude mice were inoculated with cells expressing JAK2 V617F mutant and EpoR, the lifespan of nude mice inoculated with cells expressing JAK2 V617F mutant and EpoR Y479F mutant was effectively prolonged. Taken together, it was clarified that PI3K-Akt activation through the phosphorylation of EpoR at Y479 is required for oncogenic signaling of JAK2 V617F mutant and that targeted disruption of this pathway has therapeutic utility.     

The Molecular Basis of the Caskin1 and Mint1 Interaction with CASK

Calcium/calmodulin-dependent serine protein kinase (CASK) is a conserved multi-domain scaffolding protein involved in brain development, synapse formation, and establishment of cell polarity. To accomplish these diverse functions, CASK participates in numerous protein-protein interactions. In particular, CASK forms competing CASK/Mint1/Velis and CASK/Caskin1/Velis tripartite complexes that physically associate with the cytoplasmic tail of neurexin, a transmembrane protein enriched at presynaptic sites. This study shows that a short linear EEIWVLRK peptide motif from Caskin1 is necessary and sufficient for binding CASK. We also identified the conserved binding site for the peptide on the CASK calmodulin kinase domain. A related EPIWVMRQ peptide from Mint1 was also discovered to be sufficient for binding. Searching all human proteins for the Mint1/Caskin1 consensus peptide ExIWVxR revealed that T-cell lymphoma invasion and metastasis 1 (TIAM1) contains a conserved EEVIWVRRE peptide that was also found to be sufficient for CASK binding in vitro. TIAM1 is well known for its role in tumor metastasis, but it also possesses overlapping cellular and neurological functions with CASK, suggesting a previously unknown cooperation between the two proteins. This new peptide interaction motif also explains how Caskin1 and Mint1 form competing complexes and suggests a new role for the cellular hub protein CASK.     

Adaptor protein containing PH domain, PTB domain and leucine zipper (APPL1) regulates the protein level of EGFR by modulating its trafficking

The EGFR-mediated signaling pathway regulates multiple biological processes such as cell proliferation, survival and differentiation. Previously APPL1 (adaptor protein containing PH domain, PTB domain and leucine zipper 1) has been reported to function as a downstream effector of EGF-initiated signaling. Here we demonstrate that APPL1 regulates EGFR protein levels in response to EGF stimulation. Overexpression of APPL1 enhances EGFR stabilization while APPL1 depletion by siRNA reduces EGFR protein levels. APPL1 depletion accelerates EGFR internalization and movement of EGF/EGFR from cell surface to the perinuclear region in response to EGF treatment. Conversely, overexpression of APPL1 decelerates EGFR internalization and translocation of EGF/EGFR to the perinuclear region. Furthermore, APPL1 depletion enhances the activity of Rab5 which is involved in internalization and trafficking of EGFR and inhibition of Rab5 in APPL1-depleted cells restored EGFR levels. Consistently, APPL1 depletion reduced activation of Akt, the downstream signaling effector of EGFR and this is restored by inhibition of Rab5. These findings suggest that APPL1 is required for EGFR signaling by regulation of EGFR stabilities through inhibition of Rab5.     

Polarized Organization of the Cytoskeleton: Regulation by Cell Polarity Proteins

Polarity is one of the fundamental properties displayed by living organisms. In metazoans, cell polarity governs developmental processes and plays an essential role during maintenance of forms of tissues as well as their functions. The mechanisms of establishment and maintenance of cell polarity have been investigated extensively in the last two decades. This has resulted in identification of “core cell polarity modules” that control anterior–posterior, front–rear and apical–basal polarity across various cell types. Here, we review how these polarity modules interact closely with the cytoskeleton during establishment and maintenance of cytoskeletal polarity. We further suggest that reciprocal interactions between cell polarity modules and the cytoskeleton consolidate the initial weaker polarity, arising from an external cue, into a committed polarized system.     

Diacylglycerol kinase ζ: at the crossroads of lipid signaling and protein complex organization

Diacylglycerol (DAG) and phosphatidic acid (PA) are lipids with unique functions as metabolic intermediates, basic membrane constituents, and second-signal components. Diacylglycerol kinases (DGK) regulate the levels of these two lipids, catalyzing the interconversion of one to the other. The DGK family of enzymes is composed of 10 isoforms, grouped into five subfamilies based on the presence of distinct regulatory domains. From its initial characterization as a type IV DGK to the generation of mouse models showing its importance in cardiac dysfunction and immune pathologies, diacylglycerol kinase ζ (DGKζ) has proved an excellent example of the critical role of lipid-metabolizing enzymes in the control of cell responses. Although the mechanism that regulates this enzyme is not well known, many studies demonstrate its subtle regulation and its strategic function in specific signaling and as part of adaptor protein complexes. These data suggest that DGKζ offers new opportunities for therapeutic manipulation of lipid metabolism.     

Regulation of PIKfyve phosphorylation by insulin and osmotic stress

PIKfyve is a protein and lipid kinase that plays an important role in membrane trafficking, including TGN to endosome retrograde sorting and in insulin-stimulated translocation of the GLUT4 glucose transporter from intracellular storage vesicles to the plasma membrane. We have previously demonstrated that PIKfyve is phosphorylated in response to insulin in a PI3-kinase and protein kinase B (PKB)-dependent manner. However, it has been implied that this was not due to direct phosphorylation of PIKfyve by PKB, but as a result of an insulin-induced PIKfyve autophosphorylation event. Here we demonstrate that purified PIKfyve is phosphorylated in vitro by a recombinant active PKB on two separate serine residues, S318 and S105, which flank the N-terminal FYVE domain of the protein. Only S318, however, becomes phosphorylated in intact cells stimulated with insulin. We further demonstrate that S318 is phosphorylated in response to hyperosmotic stress in a PI3-kinase- and PKB-independent manner. Importantly, the effects of insulin and sorbitol were not prevented by the presence of an ATP-competitive PIKfyve inhibitor (YM20163) or in a mutant PIKfyve lacking both lipid and protein kinase activity. Our results confirm, therefore, that PIKfyve is directly phosphorylated by PKB on a single serine residue in response to insulin and are not due to autophosphorylation of the enzyme. We further reveal that two stimuli known to promote glucose uptake in cells, both stimulate phosphorylation of PIKfyve on S318 but via distinct signal transduction pathways.     

Map2k4δ — Identification and functional characterization of a novel Map2k4 splice variant

Mitogen-activated protein kinase kinase 4 (Map2k4) is a dual specificity serin/threonine protein kinase that is unique among all MAP2Ks in activating two different subfamilies of mitogen-activated protein kinases, the c-Jun N-terminal kinases (JNKs) and p38 kinases. Map2k4 is essential during embryogenesis and involved in a variety of physiological and pathological processes. However, studies on its role in cancer development revealed partially conflicting data. In the present study, we report the identification of a novel splice variant of Map2k4, Map2k4δ, with an additional exon in front of the substrate binding D-domain. Map2k4δ is expressed together with Map2k4 in various tissues from rat, mouse and human. In PC12 cells, both splice variants control cell cycle progression and basal apoptosis by using different signaling pathways. If expression and activation of Map2k4 and Map2k4δ are at a certain, cell type-specific equilibrium, an appropriate cell growth is ensured. Overexpression of one kinase disrupts the intricate balance and either results in a highly proliferative or pro-apoptotic phenotype, partially reflecting the discrepancies in the literature on Map2k4 and its role in tumor development. Our findings contribute to the understanding of previous studies and point out that Map2k4 has not always a definite function, but rather triggers a cellular reaction in concert with other modulators.