VHS Domain Research Articles

Ubiquitylation and cell signaling

Ubiquitylation is an emerging mechanism implicated in a variety of nonproteolytic cellular functions. The attachment of a single ubiquitin (Ub) or poly-Ub (lysine 63) chains to proteins control gene transcription, DNA repair and replication, intracellular trafficking and virus budding. In these processes, protein ubiquitylation exhibits inducibility, reversibility and recognition by specialized domains, features similar to protein phosphorylation, which enable Ub to act as a signaling device. Here, we highlight several recent examples on how Ub regulates signaling and how signaling regulates ubiquitylation during physiological and pathological cellular processes.

Essential role of Hrs in a recycling mechanism mediating functional resensitization of cell signaling

Hepatocyte growth factor-regulated tyrosine kinase substrate (Hrs) is well known to terminate cell signaling by sorting activated receptors to the MVB/lysosomal pathway. Here we identify a distinct role of Hrs in promoting rapid recycling of endocytosed signaling receptors to the plasma membrane. This function of Hrs is specific for receptors that recycle in a sequence-directed manner, in contrast to default recycling by bulk membrane flow, and is distinguishable in several ways from previously identified membrane-trafficking functions of Hrs/Vps27p. In particular, Hrs function in sequence-directed recycling does not require other mammalian Class E gene products involved in MVB/lysosomal sorting, nor is receptor ubiquitination required. Mutational studies suggest that the VHS domain of Hrs plays an important role in sequence-directed recycling. Disrupting Hrs-dependent recycling prevented functional resensitization of the beta(2)-adrenergic receptor, converting the temporal profile of cell signaling by this prototypic G protein-coupled receptor from sustained to transient. These studies identify a novel function of Hrs in a cargo-specific recycling mechanism, which is critical to controlling functional activity of the largest known family of signaling receptors.

Endofin recruits clathrin to early endosomes via TOM1

TOM1 and its related proteins, TOM1-like1 (TOM1-L1) and TOM1-like2 (TOM1-L2), constitute a subfamily of the VHS domain protein family. We have recently shown that endofin, a FYVE domain protein associated with the early endosome, is able to recruit cytosolic TOM1 onto endosomal membranes. To reveal the biological consequence of endofin-mediated endosomal recruitment of TOM1, we have identified the clathrin heavy chain as a major interacting protein for TOM1. Optimal clathrin binding by TOM1 involves three sites: residues 300-321, 321-326 and a putative clathrin-binding box at residues 362-366 ((362)LEDEF(366)). Although residues 321-326 could function independently as a weak clathrin-binding motif, deletion of amino acids 300-321 or mutation of (362)Leu and (364)Asp to Ala residues reduced the binding of clathrin to TOM1. A fragment lacking amino acids 300-322 and containing (362)Leu and (364)Asp to Ala mutations lost the ability to interact with clathrin. Remarkably, overexpression of endofin led to a massive and specific recruitment of clathrin [but not dynamin, or the adaptor protein (AP) complexes, AP1, AP2 or AP3] onto endofin-positive endosomes. Although SARA is homologous to endofin, it did not interact with the C-terminal region of TOM1. Examination of chimeric proteins of endofin and SARA suggests that the C-terminal half of endofin is responsible for interaction with the C-terminal region of TOM1 and for recruitment of TOM1 and clathrin to endosomes. The correlation between the ability of endofin to interact with the C-terminal domain of TOM1 and clathrin recruitment suggests that endofin may recruit clathrin via TOM1. Indeed, a chimeric protein consisting of TOM1 fused to two FYVE domains derived from endofin has the ability to recruit clathrin onto endosomal structures. Moreover, we show that affinity-purified TOM1 antibody can abolish binding of clathrin to the C-terminal region of TOM1. Upon microinjection into cells, this antibody reduced the membrane association of clathrin. These results, taken together, suggest that TOM1 is an important molecule for membrane recruitment of clathrin, and that endofin is able to exploit this recruitment at the endosome.

Characterization of Mammalian Ecm29, a 26 S Proteasome-associated Protein That Localizes to the Nucleus and Membrane Vesicles

In addition to its thirty or so core subunits, a number of accessory proteins associate with the 26 S proteasome presumably to assist in substrate degradation or to localize the enzyme within cells. Among these proteins is ecm29p, a 200-kDa yeast protein that contains numerous HEAT repeats as well as a putative VHS domain. Higher eukaryotes possess a well conserved homolog of yeast ecm29p, and we produced antibodies to three peptides in the human Ecm29 sequence. The antibodies show that Ecm29 is present exclusively on 26 S proteasomes in HeLa cells and that Ecm29 levels vary markedly among mouse organs. Confocal immunofluorescence microscopy localizes Ecm29 to the centrosome and a subset of secretory compartments including endosomes, the ER and the ERGIC. Ecm29 is up-regulated 2-3-fold in toxinresistant mutant CHO cells exhibiting increased rates of ER-associated degradation. Based on these results we propose that Ecm29 serves to couple the 26 S proteasome to secretory compartments engaged in quality control and to other sites of enhanced proteolysis.

Demonstration of BACE (beta-secretase) phosphorylation and its interaction with GGA1 in cells by fluorescence-lifetime imaging microscopy.

beta-Secretase (BACE) carries out the first of two proteolysis steps to generate the amyloid-beta peptides that accumulate in the senile plaques in Alzheimer's disease (AD). Because most BACE activity occurs in endosomes, signals regulating its trafficking to these compartments are important to an understanding of AD pathogenesis. A DISLL sequence near the BACE C-terminus mediates binding of BACE to the VHS domains of Golgi-localized gamma-ear-containing ARF-binding (GGA) proteins, which are involved in the sorting of proteins to endosomes. Phosphorylation of the motif's serine residue regulates BACE recycling back to the cell surface from early endosomes and enhances the interaction of BACE with GGA proteins in isolated protein assays. We found that BACE phosphorylation influences BACE-GGA interactions in cells using a new fluorescence-resonance-energy-transfer-based assay of protein proximity, fluorescence lifetime imaging. Although serine-phosphorylated BACE was distributed throughout the cell, interaction of GGA1 with the wild-type protein occurred in juxtanuclear compartments. Pseudo-phosphorylated and non-phosphorylated BACE mutants remained localized with GGA1 in the Golgi body, but the latter mutation diminished the two proteins' FRET signal. Because BACE phosphorylated at serine residues can be identified in human brain, these data suggest that serine phosphorylation of BACE is a physiologically relevant post-translational modification that regulates trafficking in the juxtanuclear compartment by interaction with GGA1.

Interactions of GGA3 with the ubiquitin sorting machinery

The Golgi-localized, gamma-ear-containing, Arf-binding (GGA) proteins constitute a family of clathrin adaptors that are mainly associated with the trans-Golgi network (TGN) and mediate the sorting of mannose 6-phosphate receptors. This sorting is dependent on the interaction of the VHS domain of the GGAs with acidic-cluster-dileucine signals in the cytosolic tails of the receptors. Here we demonstrate the existence of another population of GGAs that are associated with early endosomes. RNA interference (RNAi) of GGA3 expression results in accumulation of the cation-independent mannose 6-phosphate receptor and internalized epidermal growth factor (EGF) within enlarged early endosomes. This perturbation impairs the degradation of internalized EGF, a process that is normally dependent on the sorting of ubiquitinated EGF receptors (EGFRs) to late endosomes. Protein interaction analyses show that the GGAs bind ubiquitin. The VHS and GAT domains of GGA3 are responsible for this binding, as well as for interactions with TSG101, a component of the ubiquitin-dependent sorting machinery. Thus, GGAs may have additional roles in sorting of ubiquitinated cargo.

Tom1 (target of Myb 1) is a novel negative regulator of interleukin-1- and tumor necrosis factor-induced signaling pathways.

The Tom1 (target of Myb 1) protein has VHS and GAT domains in N-terminal and central parts, respectively. The VHS domain has been found in a number of proteins, some of which have been implicated in intracellular trafficking and sorting. We previously showed that Tom1 forms a complex with Tollip, which has been reported to function in interleukin-1 (IL-1)-dependent signaling. In this study, we carried out a reporter gene assay to investigate the function of Tom1 in inflammatory cytokine-dependent signaling. It was found that overexpression of Tom1 suppresses activation of transcription factors, NF-kappaB and AP-1, induced by either IL-1beta or tumor necrosis factor (TNF)-alpha and that the VHS domain of Tom1 is indispensable for its suppressive activity. Thus, we propose that Tom1 is a common negative regulator of the signaling pathways induced by IL-1beta and TNF-alpha.

1P020 GGA蛋白質2量体形成のおけるVHSドメインの関与(蛋白質 B) 構造・機能相関)

1P020 GGA蛋白質2量体形成のおけるVHSドメインの関与(蛋白質 B) 構造・機能相関)

The 3D Solution Structure of the C-terminal Region of Ku86 (Ku86CTR)

In eukaryotes the non-homologous end-joining repair of double strand breaks in DNA is executed by a series of proteins that bring about the synapsis, preparation and ligation of the broken DNA ends. The mechanism of this process appears to be initiated by the obligate heterodimer (Ku70/Ku86) protein complex Ku that has affinity for DNA ends. Ku then recruits the DNA-dependent protein kinase catalytic subunit (DNA-PKcs). The three-dimensional structures of the major part of the Ku heterodimer, representing the DNA-binding core, both free and bound to DNA are known from X-ray crystallography. However, these structures lack a region of ca 190 residues from the C-terminal region (CTR) of the Ku86 subunit (also known as Lupus Ku autoantigen p86, Ku80, or XRCC5) that includes the extreme C-terminal tail that is reported to be sufficient for DNA-PKcs-binding. We have examined the structural characteristics of the Ku86CTR protein expressed in bacteria. By deletion mutagenesis and heteronuclear NMR spectroscopy we localised a globular domain consisting of residues 592–709. Constructs comprising additional residues either to the N-terminal side (residues 543–709), or the C-terminal side (residues 592–732), which includes the putative DNA-PKcs-binding motif, yielded NMR spectra consistent with these extra regions lacking ordered structure. The three-dimensional solution structure of the core globular domain of the C-terminal region of Ku86 (Ku86CTR 592–709) has been determined using heteronuclear NMR spectroscopy and dynamical simulated annealing using structural restraints from nuclear Overhauser effect spectroscopy, and scalar and residual dipolar couplings. The polypeptide fold comprises six regions of α-helical secondary structure that has an overall superhelical topology remotely homologous to the MIF4G homology domain of the human nuclear cap binding protein 80 kDa subunit and the VHS domain of the Drosophila protein Hrs, though strict analysis of the structures suggests that these domains are not functionally related. Two prominent hydrophobic pockets in the gap between helices α2 and α4 suggest a potential ligand-binding characteristic for this globular domain.

Tom1, a VHS Domain-containing Protein, Interacts with Tollip, Ubiquitin, and Clathrin

The gene for Tom1 was initially identified as a specific target of the oncogene v-myb. The Tom1 protein belongs to the VHS domain-containing protein family, and it has a GAT domain in a central part as well as an N-terminal VHS domain. VHS domain-containing proteins, including Hrs/Vps27, STAM, and GGA proteins, have been implicated in intracellular trafficking and sorting, but the role of Tom1 has not yet been elucidated. In this study, we found that Tom1 binds directly with ubiquitin chains and Tollip, which was initially isolated as a mediator of interleukin-1 signaling and has a capacity to bind ubiquitin chains. Gel filtration and subsequent Western blot analysis showed that endogenous Tom1 associates with Tollip to form a complex. In addition, Tom1 was found to be capable of binding to clathrin heavy chain through a typical clathrin-binding motif. Fluorescence microscopic analysis revealed that green fluorescent protein-Tom1 was localized predominantly in the cytoplasm, whereas its mutant with deletion of the clathrin-binding motif had a diffuse localization throughout the cell. Thus, we propose that a Tom1-Tollip complex functions as a factor that links polyubiquitinated proteins to clathrin.

Biochemical and structural characterization of the interaction of memapsin 2 (beta-secretase) cytosolic domain with the VHS domain of GGA proteins.

Memapsin 2 (beta-secretase) is a membrane-associated aspartic protease that initiates the hydrolysis of beta-amyloid precursor protein (APP) leading to the production of amyloid-beta and the onset of Alzheimer's disease (AD). Both memapsin 2 and APP are transported from the cell surface to endosomes where APP hydrolysis takes place. Thus, the intracellular transport mechanism of memapsin 2 is important for understanding the pathogenesis of AD. We have previously shown that the cytosolic domain of memapsin 2 contains an acid-cluster-dileucine (ACDL) motif that binds the VHS domain of GGA proteins (He et al. (2002) FEBS Lett. 524, 183-187). This mechanism is the presumed recognition step for the vesicular packaging of memapsin 2 for its transport to endosomes. The phosphorylation of a serine residue within the ACDL motif has been reported to regulate the recycling of memapsin 2 from early endosomes back to the cell surface. Here, we report a study on the memapsin 2/VHS domain interaction. Using isothermal titration calorimetry, the dissociation constant, K(d), values are 4.0 x 10(-4), 4.1 x 10(-4), and 3.1 x 10(-4) M for VHS domains from GGA1, GGA2, and GGA3, respectively. With the serine residue replaced by phosphoserine, the K(d) decreased about 10-, 4-, and 14-fold for the same three VHS domains. A crystal structure of the complex between memapsin 2 phosphoserine peptide and GGA1 VHS was solved at 2.6 A resolution. The side chain of the phosphoserine group does not interact with the VHS domain but forms an ionic interaction with the side chain of the C-terminal lysine of the ligand peptide. Energy calculation of the binding of native and phosphorylated peptides to VHS domains suggests that this intrapeptide ionic bond in solution may reduce the change in binding entropy and thus increase binding affinity.

Molecular mechanism of membrane recruitment of GGA by ARF in lysosomal protein transport.

GGAs are critical for trafficking soluble proteins from the trans-Golgi network (TGN) to endosomes/lysosomes through interactions with TGN-sorting receptors, ADP-ribosylation factor (ARF) and clathrin. ARF-GTP bound to TGN membranes recruits its effector GGA by binding to the GAT domain, thus facilitating recognition of GGA for cargo-loaded receptors. Here we report the X-ray crystal structures of the human GGA1-GAT domain and the complex between ARF1-GTP and the N-terminal region of the GAT domain. When unbound, the GAT domain forms an elongated bundle of three a-helices with a hydrophobic core. Structurally, this domain, combined with the preceding VHS domain, resembles CALM, an AP180 homolog involved in endocytosis. In the complex with ARF1-GTP, a helix-loop-helix of the N-terminal part of GGA1-GAT interacts with the switches 1 and 2 of ARF1 predominantly in a hydrophobic manner. These data reveal a molecular mechanism underlying membrane recruitment of adaptor proteins by ARF-GTP.

Phosphorylation-induced Conformational Changes Regulate GGAs 1 and 3 Function at the Trans-Golgi Network

The GGAs (Golgi-localizing, gamma-adaptin ear homology domain, ARF-binding) are a family of multidomain proteins implicated in protein trafficking between the Golgi and the endosomes. All three GGAs (1, 2, and 3) bind to the mannose 6-phosphate receptor tail via their VHS domains, as well as to the adaptor protein complex-1 via their hinge domains. The latter interaction has been proposed to be important for cooperative packaging of cargo into forming clathrin-coated carriers at the trans-Golgi network. Here we present evidence that GGA1 function is highly regulated by cycles of phosphorylation and dephosphorylation. Cell fractionation showed that the phosphorylated pool of GGA1 resided predominantly in the cytosol and that recruitment onto membranes was associated with dephosphorylation. Okadaic acid inhibition studies and in vitro dephosphorylation assays indicated that dephosphorylation is mediated by a protein phosphatase 2A-like phosphatase. Dephosphorylation of GGA1 induced a change in the conformation to an "open" form as measured by gel filtration and sucrose gradient analyses. This was associated with enhanced binding to ligands because of release of autoinhibition and increased binding to the adaptor protein complex-1 gamma-appendage. A model is proposed for the regulation of GGA1 function at the trans-Golgi network.

Signals for sorting of transmembrane proteins to endosomes and lysosomes.

Sorting of transmembrane proteins to endosomes and lysosomes is mediated by signals present within the cytosolic domains of the proteins. Most signals consist of short, linear sequences of amino acid residues. Some signals are referred to as tyrosine-based sorting signals and conform to the NPXY or YXXO consensus motifs. Other signals known as dileucine-based signals fit [DE]XXXL[LI] or DXXLL consensus motifs. All of these signals are recognized by components of protein coats peripherally associated with the cytosolic face of membranes. YXXO and [DE]XXXL[LI] signals are recognized with characteristic fine specificity by the adaptor protein (AP) complexes AP-1, AP-2, AP-3, and AP-4, whereas DXXLL signals are recognized by another family of adaptors known as GGAs. Several proteins, including clathrin, AP-2, and Dab2, have been proposed to function as recognition proteins for NPXY signals. YXXO and DXXLL signals bind in an extended conformation to the mu2 subunit of AP-2 and the VHS domain of the GGAs, respectively. Phosphorylation events regulate signal recognition. In addition to peptide motifs, ubiquitination of cytosolic lysine residues also serves as a signal for sorting at various stages of the endosomal-lysosomal system. Conjugated ubiquitin is recognized by UIM, UBA, or UBC domains present within many components of the internalization and lysosomal targeting machinery. This complex array of signals and recognition proteins ensures the dynamic but accurate distribution of transmembrane proteins to different compartments of the endosomal-lysosomal system.

Arf regulates interaction of GGA with mannose-6-phosphate receptor.

The role of ADP-ribosylation factor (Arf) in Golgi associated, gamma-adaptin homologous, Arf-interacting protein (GGA)-mediated membrane traffic was examined. GGA is a clathrin adaptor protein that binds Arf through its GAT domain and the mannose-6-phosphate receptor through its VHS domain. The GAT and VHS domains interacted such that Arf and mannose-6-phosphate receptor binding to GGA were mutually exclusive. In vivo, GGA bound membranes through either Arf or mannose-6-phosphate receptor. However, mannose-6-phosphate receptor excluded Arf from GGA-containing structures outside of the Golgi. These data are inconsistent with predictions based on the model for Arf's role in COPI veside coat function. We propose that Arf recruits GGA to a membrane and then, different from the current model, 'hands-off' GGA to mannose-6-phosphate receptor. GGA and mannose-6-phosphate receptor are then incorporated into a transport intermediate that excludes Arf.

タンパク質結晶学のブレイクスルー ２． 構造生物学のブレイクスルー 輸送系の構造生物学

Many eukaryiotic proteins are glycosylated after translation to become mature proteins. Efficient sorting of such glycosylated proteins is essential for the cell's function and is achieved by vesicle transport. Mannose 6-phosphate (M6P) modification of lysosomal proteins is recognized by a M6P receptor (MPR) which incorporates the lysosomal proteins to vesicles. Recently GGA proteins have been identified and later verified as a new family of adapter proteins distinct from well known AP-1 to 4 complexes. They are responsible for vesicle transport of glycosylated human proteins from the Golgi apparatus to early endosomesl lysosomes. We have determined the crystal structures of the VHS domain of human GGA 1 and the ear domain of human γ1 adaptin. Combined with biochemical and cell-biological data, these structures reveal the recognition mechanisms of the acidic dileucine motif signal of mannose-6-phophate receptor by the VHS domain of human GGA protein and the interaction between the ear domain of γ1 adaptin of the AP-1 complex and γ-synergin and Rabaptin-5. They constitute part of a rapidly growing ensemble of structures of transport proteins, where protein-protein interactions, as elucidated by X-ray structural analyses, play critical roles.

Structural modeling of ataxin-3 reveals distant homology to adaptins.

Spinocerebellar ataxia type 3 (SCA3) is a polyglutamine disorder caused by a CAG repeat expansion in the coding region of a gene encoding ataxin-3, a protein of yet unknown function. Based on a comprehensive computational analysis, we propose a structural model and structure-based functions for ataxin-3. Our predictive strategy comprises the compilation of multiple sequence and structure alignments of carefully selected proteins related to ataxin-3. These alignments are consistent with additional information on sequence motifs, secondary structure, and domain architectures. The application of complementary methods revealed the homology of ataxin-3 to ENTH and VHS domain proteins involved in membrane trafficking and regulatory adaptor functions. We modeled the structure of ataxin-3 using the adaptin AP180 as a template and assessed the reliability of the model by comparison with known sequence and structural features. We could further infer potential functions of ataxin-3 in agreement with known experimental data. Our database searches also identified an as yet uncharacterized family of proteins, which we named josephins because of their pronounced homology to the Josephin domain of ataxin-3.

Novel proteins linking the actin cytoskeleton to the endocytic machinery in Saccharomyces cerevisiae.

The importance of coupling the process of endocytosis to factors regulating actin dynamics has been clearly demonstrated in yeast, and many proteins involved in these mechanisms have been identified and characterized. Here we demonstrate the importance of two additional cortical components, Ysc84p and Lsb5p, which together are essential for the organization of the actin cytoskeleton and for fluid phase endocytosis. Both Ysc84p and Lsb5p were identified through two-hybrid screens with different domains of the adaptor protein Sla1p. Ysc84p colocalizes with cortical actin and requires the presence of an intact actin cytoskeleton for its cortical localization. Ycl034w/Lsb5p localizes to the cell cortex but does not colocalize with actin. The Lsb5 protein contains putative VHS and GAT domains as well as an NPF motif, which are all domains characteristic of proteins involved in membrane trafficking. Deletion of either gene alone does not confer any dramatic phenotype on cells. However, deletion of both genes is lethal at elevated temperatures. Furthermore, at all temperatures this double mutant has depolarized actin and an almost undetectable level of fluid phase endocytosis. Our data demonstrate that Ysc84p and Lsb5p are important components of complexes involved in overlapping pathways coupling endocytosis with the actin cytoskeleton in yeast.

Memapsin 2 (β-secretase) cytosolic domain binds to the VHS domains of GGA1 and GGA2: implications on the endocytosis mechanism of memapsin 2

Memapsin 2, or β-secretase, is a membrane-anchored aspartic protease that initiates the cleavage of β-amyloid precursor protein (APP) leading to the production of β-amyloid peptide in the brain and the onset of Alzheimer’s disease. Memapsin 2 and APP are both endocytosed into endosomes for cleavage. Here we show that the cytosolic domain of memapsin 2, but not that of memapsin 1, binds the VHS domains of GGA1 and GGA2. Gel-immobilized VHS domains of GGA1 and GGA2 also bound to full-length memapsin 2 from cell mammalian lysates. Mutagenesis studies established that Asp 496, Leu 499 and Leu 500 were essential for the binding. The spacing of these three residues in memapsin 2 is identical to those in the cytosolic domains of mannose-6-phosphate receptors, sortilin and low density lipoprotein receptor-related protein 3. These observations suggest that the endocytosis and intracellular transport of memapsin 2, mediated by its cytosolic domain, may involve the binding of GGA1 and GGA2.

ADP-ribosylation factor (ARF) interaction is not sufficient for yeast GGA protein function or localization.

Golgi-localized gamma-ear homology domain, ADP-ribosylation factor (ARF)-binding proteins (GGAs) facilitate distinct steps of post-Golgi traffic. Human and yeast GGA proteins are only ~25% identical, but all GGA proteins have four similar domains based on function and sequence homology. GGA proteins are most conserved in the region that interacts with ARF proteins. To analyze the role of ARF in GGA protein localization and function, we performed mutational analyses of both human and yeast GGAs. To our surprise, yeast and human GGAs differ in their requirement for ARF interaction. We describe a point mutation in both yeast and mammalian GGA proteins that eliminates binding to ARFs. In mammalian cells, this mutation disrupts the localization of human GGA proteins. Yeast Gga function was studied using an assay for carboxypeptidase Y missorting and synthetic temperature-sensitive lethality between GGAs and VPS27. Based on these assays, we conclude that non-Arf-binding yeast Gga mutants can function normally in membrane trafficking. Using green fluorescent protein-tagged Gga1p, we show that Arf interaction is not required for Gga localization to the Golgi. Truncation analysis of Gga1p and Gga2p suggests that the N-terminal VHS domain and C-terminal hinge and ear domains play significant roles in yeast Gga protein localization and function. Together, our data suggest that yeast Gga proteins function to assemble a protein complex at the late Golgi to initiate proper sorting and transport of specific cargo. Whereas mammalian GGAs must interact with ARF to localize to and function at the Golgi, interaction between yeast Ggas and Arf plays a minor role in Gga localization and function.