A conformational switch driven by phosphorylation regulates the activity of the evolutionarily conserved SNARE Ykt6.

Ykt6 is a soluble N-ethylmaleimide sensitive factor activating protein receptor (SNARE) critically involved in diverse vesicular fusion pathways. While most SNAREs rely on transmembrane domains for their activity, Ykt6 dynamically cycles between the cytosol and membrane-bound compartments where it is active. The mechanism that regulates these transitions and allows Ykt6 to achieve specificity toward vesicular pathways is unknown. Using a Parkinson's disease (PD) model, we found that Ykt6 is phosphorylated at an evolutionarily conserved site which is regulated by Ca2+ signaling. Through a multidisciplinary approach, we show that phosphorylation triggers a conformational change that allows Ykt6 to switch from a closed cytosolic to an open membrane-bound form. In the phosphorylated open form, the spectrum of protein interactions changes, leading to defects in both the secretory and autophagy pathways, enhancing toxicity in PD models. Our studies reveal a mechanism by which Ykt6 conformation and activity are regulated with potential implications for PD.

Intersectin 2 nucleotide exchange factor regulates Cdc42 activity during Xenopus early development.

Intersectin 2 (ITSN2) is an evolutionarily conserved scaffold protein involved in endocytic internalization, regulation of actin cytoskeleton and epithelial morphogenesis. Recent studies of different Itsn-deficient organisms revealed that this gene is essential for the functioning of the nervous system and for organism viability. Here we report investigations on a possible role of the ITSN2 long isoform in the early embryonic development of Xenopus laevis. In vertebrates, alternative splicing generates several alternatively spliced isoforms of ITSN2. To date the long splice variant of ITSN2 (ITSN2-L) has been reported only for mammals. We show that transcripts of ITSN2-L can be detected in Xenopus embryos from the first cleavage onwards. Overexpression of functional domains of ITSN2-L in embryos resulted in aberrant phenotypes. The strongest phenotype was produced by the C-terminal extension of ITSN2-L. Embryos displayed hyperpigmentation and gastrulation failure that were incompatible with survival. The C-terminus of ITSN2-L includes the DH-PH tandem, a nucleotide exchange factor for the small GTPase Cdc42 and the C2 domain. Further investigations revealed that the DH-PH tandem was responsible for the development of the phenotype affecting the actin cytoskeleton in embryos. Observed developmental defects depended on Cdc42. The effect of expression of the constitutively active GTPase strongly resembled that of the DH-PH tandem. The dominant negative Cdc42 partially rescued developmental defects induced by the expression of the DH-PH tandem. Thus, our data indicate that the ITSN2 exchange factor regulates the activity of Cdc42 during embryo development affecting actin cytoskeleton in Xenopus embryos.

BET1 variants establish impaired vesicular transport as a cause for muscular dystrophy with epilepsy.

BET1 is required, together with its SNARE complex partners GOSR2, SEC22b, and Syntaxin-5 for fusion of endoplasmic reticulum-derived vesicles with the ER-Golgi intermediate compartment (ERGIC) and the cis-Golgi. Here, we report three individuals, from two families, with severe congenital muscular dystrophy (CMD) and biallelic variants in BET1 (P1 p.(Asp68His)/p.(Ala45Valfs*2); P2 and P3 homozygous p.(Ile51Ser)). Due to aberrant splicing and frameshifting, the variants in P1 result in low BET1 protein levels and impaired ER-to-Golgi transport. Since in silico modeling suggested that p.(Ile51Ser) interferes with binding to interaction partners other than SNARE complex subunits, we set off and identified novel BET1 interaction partners with low affinity for p.(Ile51Ser) BET1 protein compared to wild-type, among them ERGIC-53. The BET1/ERGIC-53 interaction was validated by endogenous co-immunoprecipitation with both proteins colocalizing to the ERGIC compartment. Mislocalization of ERGIC-53 was observed in P1 and P2's derived fibroblasts; while in the p.(Ile51Ser) P2 fibroblasts specifically, mutant BET1 was also mislocalized along with ERGIC-53. Thus, we establish BET1 as a novel CMD/epilepsy gene and confirm the emerging role of ER/Golgi SNAREs in CMD.

Microexon-based regulation of ITSN1 and Src SH3 domains specificity relies on introduction of charged amino acids into the interaction interface.

SH3 domains function as protein-protein interaction modules in assembly of signalling and endocytic protein complexes. Here we report investigations of the mechanism of regulation of the binding properties of the SH3 domains of intersectin (ITSN1) and Src kinase by alternative splicing. Comparative sequence analysis of ITSN1 and Src genes revealed the conservation of alternatively spliced microexons affecting the structure of the SH3 domains in vertebrates. We show that neuron-specific ITSN1 transcripts containing the microexon 20 that encodes five amino acid residues within the SH3A domain are expressed in zebrafish from the earliest stages of the development of the nervous system. Models of alternative isoforms of the ITSN1 SH3A domain revealed that the insertion encoded by the microexon is located at the beginning of the n-Src loop of this domain causing a shift of negatively charged amino acids towards the interaction interface. Mutational analysis confirmed the importance of translocation of these negatively charged amino acids for interaction with dynamin 1. We also identified a residue within the microexon-encoded insert in the SH3 domain of brain-specific variant of Src that abolishes interaction of the domain with dynamin 1. Thus microexons provide a mechanism for the control of tissue-specific interactions of ITSN1 and Src with their partners.

Intersectin 1 forms complexes with SGIP1 and Reps1 in clathrin-coated pits.

Intersectin 1 (ITSN1) is an evolutionarily conserved adaptor protein involved in clathrin-mediated endocytosis, cellular signaling and cytoskeleton rearrangement. ITSN1 gene is located on human chromosome 21 in Down syndrome critical region. Several studies confirmed role of ITSN1 in Down syndrome phenotype. Here we report the identification of novel interconnections in the interaction network of this endocytic adaptor. We show that the membrane-deforming protein SGIP1 (Src homology 3-domain growth factor receptor-bound 2-like (endophilin) interacting protein 1) and the signaling adaptor Reps1 (RalBP associated Eps15-homology domain protein) interact with ITSN1 in vivo. Both interactions are mediated by the SH3 domains of ITSN1 and proline-rich motifs of protein partners. Moreover complexes comprising SGIP1, Reps1 and ITSN1 have been identified. We also identified new interactions between SGIP1, Reps1 and the BAR (Bin/amphiphysin/Rvs) domain-containing protein amphiphysin 1. Immunofluorescent data have demonstrated colocalization of ITSN1 with the newly identified protein partners in clathrin-coated pits. These findings expand the role of ITSN1 as a scaffolding molecule bringing together components of endocytic complexes.

Structural diversity and differential expression of novel human intersectin 1 isoforms.

Intersectin 1 (ITSN1) is an evolutionarily conserved adaptor protein that functions in clathrin-mediated endocytosis, cell signalling and cytoskeleton rearrangements. The ITSN1 gene encodes two main isoforms: a short form (ITSN1-s), which is ubiquitously expressed and consists of two Eps15 homology (EH) domains and five Src homology 3 (SH3) domains, and a long form (ITSN1-l), which is predominantly expressed in the brain and contains three additional domains, a Dbl homology (DH) domain, a Pleckstrin homology (PH) domain and a C2 domain. Using computational analysis of the EST database and 3' RACE we determined the length of the 3' untranslated region of ITSN1-l and demonstrated that the polyadenylation site is located 11,559 nt downstream of the stop codon of the ITSN1-l mRNA. Recently, additional splicing events affecting ITSN1 transcripts were reported, but full-length transcriptional isoforms with different combinations of alternatively spliced exons remained unknown. Here we report the identification of fifteen novel transcriptional isoforms of the human ITSN1 gene with full-length coding sequences that are the result of different combinations of the alternatively spliced exons 5, 6/6', 20, 23, 25, 26, 26a and 35. The isoforms identified differ in domain organization and expression level in different tissues and more likely contribute to the modulation of many complex protein interactions in which ITSN1 participates.

Alternative splicing affecting the SH3A domain controls the binding properties of intersectin 1 in neurons.

Intersectin 1 (ITSN1) is a conserved adaptor protein implicated in endocytosis, regulation of actin cytoskeleton rearrangements and mitogenic signaling. Its expression is characterized by multiple alternative splicing. Here we show neuron-specific expression of ITSN1 isoforms containing exon 20, which encodes five amino acid residues in the first SH3 domain (SH3A). In vitro binding experiments demonstrated that inclusion of exon 20 changes the binding properties of the SH3A domain. Endocytic proteins dynamin 1 and synaptojanin 1 as well as GTPase-activating protein CdGAP bound the neuron-specific variant of the SH3A domain with higher affinity than ubiquitously expressed SH3A. In contrast, SOS1, a guanine nucleotide exchange factor for Ras, and the ubiquitin ligase Cbl mainly interact with the ubiquitously expressed isoform. These results demonstrate that alternative splicing leads to the formation of two pools of ITSN1 with potentially different properties in neurons, affecting ITSN1 function as adaptor protein.

Ubiquitin-ligase AIP4 controls differential ubiquitination and stability of isoforms of the scaffold protein ITSN1.

At present, the role of ubiquitination of cargoes internalized from the plasma membrane is better understood than the consequences of ubiquitination of proteins comprising the endocytic machinery. Here, we show that the E3 ubiquitin ligase AIP4/ITCH contributes to the differential ubiquitination of isoforms of the endocytic scaffold protein intersectin1 (ITSN1). The major isoform ITSN1-s is monoubiquitinated, whereas the minor one, ITSN1-22a undergoes a combination of mono- and oligoubiquitination. The monoubiquitination is required for ITSN1-s stability, whereas the oligoubiquitination of ITSN1-22a causes its proteasomal degradation. This explains the observed low abundance of the minor isoform in cells. Thus, different modes of ubiquitination regulated by AIP4 have opposite effects on ITSN1 isoform stability.

Functional assays for the assessment of the pathogenicity of variants of GOSR2, an ER-to-Golgi SNARE involved in progressive myoclonus epilepsies.

Progressive myoclonus epilepsies (PMEs) are inherited disorders characterized by myoclonus, generalized tonic-clonic seizures, and ataxia. One of the genes that is associated with PME is the ER-to-Golgi Qb-SNARE GOSR2, which forms a SNARE complex with syntaxin-5, Bet1 and Sec22b. Most PME patients are homo-zygous for a p.Gly144Trp mutation and develop similar clinical presentations. Recently, a patient who was compound heterozygous for p.Gly144Trp and a previously unseen p.Lys164del mutation was identified. Because this patient presented with a milder disease phenotype, we hypothesized that the p.Lys164del mutation may be less severe compared to p.Gly144Trp. To characterize the effect of the p.Gly144Trp and p.Lys164del mutations, both of which are present in the SNARE motif of GOSR2, we examined the corresponding mutations in the yeast ortholog Bos1. Yeasts expressing the orthologous mutants in Bos1 showed impaired growth, suggesting a partial loss of function, which was more severe for the Bos1 p.Gly176Trp mutation. Using anisotropy and gel filtration, we report that Bos1 p.Gly176Trp and p.Arg196del are capable of complex formation, but with partly reduced activity. Molecular dynamics (MD) simulations showed that the hydrophobic core, which triggers SNARE complex formation, is compromised due to the glycine-to-tryptophan substitution in both GOSR2 and Bos1. In contrast, the deletion of residue p.Lys164 (or p.Arg196del in Bos1) interferes with the formation of hydrogen bonds between GOSR2 and syntaxin-5. Despite these perturbations, all SNARE complexes stayed intact during longer simulations. Thus, our data suggest that the milder course of disease in compound heterozygous PME is due to less severe impairment of the SNARE function.

Evolutionary Changes on the Way to Clathrin-Mediated Endocytosis in Animals.

Endocytic pathways constitute an evolutionarily ancient system that significantly contributed to the eukaryotic cell architecture and to the diversity of cell type-specific functions and signaling cascades, in particular of metazoans. Here we used comparative proteomic studies to analyze the universal internalization route in eukaryotes, clathrin-mediated endocytosis (CME), to address the issues of how this system evolved and what are its specific features. Among 35 proteins crucially required for animal CME, we identified a subset of 22 proteins common to major eukaryotic branches and 13 gradually acquired during evolution. Based on exploration of structure-function relationship between conserved homologs in sister, distantly related and early diverged branches, we identified novel features acquired during evolution of endocytic proteins on the way to animals: Elaborated way of cargo recruitment by multiple sorting proteins, structural changes in the core endocytic complex AP2, the emergence of the Fer/Cip4 homology domain-only protein/epidermal growth factor receptor substrate 15/intersectin functional complex as an additional interaction hub and activator of AP2, as well as changes in late endocytic stages due to recruitment of dynamin/sorting nexin 9 complex and involvement of the actin polymerization machinery. The evolutionary reconstruction showed the basis of the CME process and its subsequent step-by-step development. Documented changes imply more precise regulation of the pathway, as well as CME specialization for the uptake of specific cargoes and cell type-specific functions.

The LMP2A protein of Epstein-Barr virus regulates phosphorylation of ITSN1 and Shb adaptors by tyrosine kinases.

Latent Membrane Protein 2A (LMP2A) is an Epstein-Barr virus-encoded protein that is important for the maintenance of latent infection. Its activity affects cellular differentiation, migration, proliferation and B cell survival. LMP2A resembles a constitutively activated B cell antigen receptor and exploits host kinases to activate a set of downstream signaling pathways. In the current study we demonstrate the interaction of LMP2A with intersectin 1 (ITSN1), a key endocytic adaptor protein. This interaction occurs via both the N- and C-tails of LMP2A and is mediated by the SH3 domains of ITSN1. Additionally, we identified the Shb adaptor and the Syk kinase as novel binding ligands of ITSN1. The Shb adaptor interacts simultaneously with the phosphorylated tyrosines of LMP2A and the SH3 domains of ITSN1 and mediates indirect interaction of ITSN1 to LMP2A. Syk kinase promotes phosphorylation of both ITSN1 and Shb adaptors in LMP2A-expressing cells. In contrast to ITSN1, Shb phosphorylation depends additionally on Lyn kinase activity. Considering that Shb and ITSN1 are implicated in various receptor tyrosine kinase signaling, our results indicate that LMP2A can affect a number of signaling pathways by regulating the phosphorylation of the ITSN1 and Shb adaptors.

Adaptor proteins intersectin 1 and 2 bind similar proline-rich ligands but are differentially recognized by SH2 domain-containing proteins.

BACKGROUND: Scaffolding proteins of the intersectin (ITSN) family, ITSN1 and ITSN2, are crucial for the initiation stage of clathrin-mediated endocytosis. These proteins are closely related but have implications in distinct pathologies. To determine how these proteins could be separated in certain cell pathways we performed a comparative study of ITSNs. METHODOLOGY/PRINCIPAL FINDINGS: We have shown that endogenous ITSN1 and ITSN2 colocalize and form a complex in cells. A structural comparison of five SH3 domains, which mediated most ITSNs protein-protein interactions, demonstrated a similarity of their ligand-binding sites. We showed that the SH3 domains of ITSN2 bound well-established interactors of ITSN1 as well as newly identified ITSNs protein partners. A search for a novel interacting interface revealed multiple tyrosines that could be phosphorylated in ITSN2. Phosphorylation of ITSN2 isoforms but not ITSN1 short isoform was observed in various cell lines. EGF stimulation of HeLa cells enhanced tyrosine phosphorylation of ITSN2 isoforms and enabled their recognition by the SH2 domains of the Fyn, Fgr and Abl1 kinases, the regulatory subunit of PI3K, the adaptor proteins Grb2 and Crk, and phospholipase C gamma. The SH2 domains mentioned were unable to bind ITSN1 short isoform. CONCLUSIONS/SIGNIFICANCE: Our results indicate that during evolution of vertebrates ITSN2 acquired a novel protein-interaction interface that allows its specific recognition by the SH2 domains of signaling proteins. We propose that these data could be important to understand the functional diversity of paralogous ITSN proteins.

Intersectin multidomain adaptor proteins: regulation of functional diversity.

Adaptor/scaffold proteins serve as platforms for the assembly of multiprotein complexes and regulate the efficiency and specificity of signalling cascades. Intersectins (ITSNs) are an evolutionarily conserved adaptor protein family engaged in endo- and exocytosis, actin cytoskeleton rearrangement and signal transduction. This review summarizes recent advances in the function of ITSNs in neuronal and non-neuronal cells, the role of alternative splicing and alternative transcription in regulating the structural and functional diversity of ITSNs, their expression patterns in different tissues and during development, their interactions with proteins, as well as the potential relevance of ITSNs for neurodegenerative diseases and cancer. The diversity of mechanisms in the regulation of ITSN expression and specificity in different cells emphasizes the important role of ITSN proteins in vesicle trafficking and signalling.

Identification and characterization of a novel mammalian isoform of the endocytic adaptor ITSN1.

Intersectin 1 (ITSN1) is an evolutionarily conserved adaptor protein engaged in clathrin-mediated endocytosis, cell signaling and actin cytoskeleton rearrangements. Two major ITSN1 isoforms were initially described, the ubiquitous short isoform (ITSN1-s) and the long isoform (ITSN1-l) expressed predominantly in neurons. Numerous alternative splicing events for ITSN1 pre-mRNA were later identified. Here we describe a novel isoform ITSN1-22a with an alternative C-terminus encoded by exon 22a. This exon is only found in placental mammals. The transcript of ITSN1-22a is detected in a wide range of human and mouse tissues. We show here that two alternative splicing events affect the coding sequence of the ITSN1-22a isoform. Moreover, alternative polyadenylation of these transcripts was demonstrated in human tissues. The protein encoded by the ITSN1-22a transcript possesses two EH domains, a coiled-coil region, an SH3A domain and a specific C-terminal domain (CTD) but lacks four SH3 domains in comparison with ITSN1-s. The level of ITSN1-22a protein varies in different mouse tissues and human cell lines. The highest amounts of this isoform occur in mouse brain, spleen, lung and the human B cell line DG75. ITSN1-22a binds via its CTD to the SH3 domain of the endocytic protein amphiphysin 1 and the SH3A domain of ITSN1. Furthermore association in vivo and codistribution of ITSN1-22a and ITSN1-s were demonstrated suggesting that these isoforms could function in concert. We have revealed differential binding of ITSN1-s and ITSN1-22a to the ubiquitin ligase Cbl. Both isoforms possess the SH3A domain capable of binding to Cbl; however ITSN1-22a in contrast to ITSN1-s did not interact with Cbl in vivo. In vitro binding experiments demonstrated that the CTD of ITSN1-22a negatively regulated its binding to Cbl; at the same time interaction with another partner, dynamin 1 was not affected by the presence of the CTD. These data suggest that intramolecular interaction within ITSN1-22a could specifically regulate its binding to protein partners. Thus, this novel mammalian ITSN1 isoform possesses a significantly altered domain structure and performs specific protein-protein interactions.