Your search keyword '"Petri Kursula"' showing total 15 results

1. Conformational analysis of membrane-proximal segments of GDAP1 in a lipidic environment using synchrotron radiation suggests a mode of assembly at the mitochondrial outer membrane

Author

Aleksi Sutinen, Nykola C. Jones, Søren Vrønning Hoffmann, Salla Ruskamo, and Petri Kursula

Abstract

The mitochondrial outer membrane creates a diffusion barrier between the cytosol and mitochondrial intermembrane space, allowing the exchange of metabolic products, important for efficient mitochondrial function in neurons. The ganglioside-induced differentiation-associated protein 1 (GDAP1) is a mitochondrial outer membrane protein with a critical role in mitochondrial dynamics and metabolic balance in neurons. Missense mutations in theGDAP1gene are linked to the most common human peripheral neuropathy, Charcot-Marie-Tooth disease (CMT). GDAP1 is a distant member of the glutathione-S-transferase (GST) superfamily, with unknown enzymatic properties or functions at the molecular level. The structure of the cytosol-facing GST-like domain has been described, but there is no consensus on how the protein interacts with the mitochondrial outer membrane. Here, we describe a model for GDAP1 assembly on the membrane using peptides vicinal to the GDAP1 transmembrane domain. We used oriented circular dichroism spectroscopy (OCD) with synchrotron radiation to study the secondary structure and orientation of GDAP1 segments at the outer and inner surfaces of the outer mitochondrial membrane. These experiments were complemented by small-angle X-ray scattering, providing the first experimental structural models for full-length human GDAP1. The results indicate that GDAP1 is bound into the membraneviaa single transmembrane helix, flanked by two peripheral helices interacting with the outer and inner leaflet of the mitochondrial outer membrane in different orientations. Impairment of such interactions could be a mechanism for CMT in the case of missense mutations affecting these segments instead of the GST-like domain.

Published

2023

2. The intrinsically disordered protein glue of myelin: Linking AlphaFold2 predictions to experimental data

Author

Oda C. Krokengen, Arne Raasakka, and Petri Kursula

Abstract

Numerous human proteins are either partially or fully classified as intrinsically disordered proteins (IDPs). Due to their properties, high-resolution structural information about IDPs is generally lacking. On the other hand, IDPs are known to adopt local ordered structures upon interactions with ligands, which could be e.g. other proteins or lipid membrane surfaces. While recent developments in protein structure prediction have been revolutionary, their impact on IDP research at high resolution remains limited. We took a specific example of two myelin-specific IDPs, the myelin basic protein (MBP) and the cytoplasmic domain of myelin protein zero (P0ct). Both of these IDPs are known to be crucial for normal nervous system development and function, and while they are disordered in solution, upon membrane binding, they partially fold into helices, being embedded into the lipid membrane. We carried out AlphaFold2 predictions of both proteins and analysed the models in light of previously published data related to solution structure and molecular interactions. We observe that the predicted models have helical segments that closely correspond to the characterised membrane-binding sites on both proteins. We furthermore analyse the fits of the models to SAXS data from the same IDPs. Artificial intelligence-based models of IDPs appear to be able to provide detailed information on the ligand-bound state of these proteins, instead of the form dominating free in solution. We further discuss the implications of the predictions for normal mammalian nervous system myelination and their relevance to understanding disease aspects of these IDPs.

Published

2022

3. Structural characterization of functionally important chloride binding sites in the marine Vibrio alkaline phosphatase

Author

Sigurbjörn Markússon, Jens G. Hjörleifsson, Petri Kursula, and Bjarni Ásgeirsson

Subjects

Biochemistry

Abstract

Enzyme stability and function can be affected by various environmental factors, such as temperature, pH and ionic strength. Enzymes that are located outside the relatively unchanging environment of the cytosol, such as those residing in the periplasmic space of bacteria or extracellularly secreted, are challenged by more fluctuations in the aqueous medium. Bacterial alkaline phosphatases (APs) are generally affected by ionic strength of the medium, but this varies substantially between species. An AP from the marine bacterium Vibrio splendidus (VAP) shows complex pH-dependent activation and stabilization in the 0 – 1.0 M range of halogen salts and has been hypothesized to specifically bind chloride anions. Here, using X-ray crystallography and anomalous scattering, we have located two chloride binding sites in the structure of VAP, one in the active site and another one at a peripheral site. Further characterization of the binding sites using site-directed mutagenesis and small angle X-ray scattering (SAXS) showed that upon binding of chloride to the peripheral site, structural dynamics decreased locally, resulting in thermal stabilization of the VAP active conformation. Binding of the chloride ion in the active site did not displace the bound inorganic phosphate product, but it may promote product release by facilitating rotational stabilization of the substrate-binding Arg129. Overall, these results reveal the complex nature and dynamics of chloride binding to enzymes through long-range modulation of electronic potential in the vicinity of the active site, resulting in increased catalytic efficiency and stability.

Published

2022

4. Structural and biophysical characterization of HNF-1A as a tool to study MODY3 diabetes variants

Author

Laura Kind, Arne Raasakka, Janne Molnes, Ingvild Aukrust, Lise Bjørkhaug, Pål Rasmus Njølstad, Petri Kursula, and Thomas Arnesen

Abstract

Hepatocyte nuclear factor 1A (HNF-1A) is a transcription factor expressed in several embryonic and adult tissues, modulating expression of numerous target genes. Pathogenic variants in the HNF1A gene cause maturity-onset diabetes of the young 3 (MODY3 or HNF1A MODY), characterized by dominant inheritance, age of onset before 25-35 years of age, and pancreatic β-cell dysfunction. A precise diagnosis alters management as insulin can be exchanged with sulfonylurea tablets and genetic counselling differs from polygenic forms of diabetes. More knowledge on mechanisms of HNF-1A function and the level of pathogenicity of the numerous HNF1A variants identified by exome sequencing is required for precise diagnostics. Here, we have structurally and biophysically characterized an HNF-1A protein containing both the DNA binding domain and the dimerization domain. We also present a novel approach to characterize HNF-1A variants. The folding and DNA binding capacity of two established MODY3 HNF-1A variant proteins (P112L, R263C) and one variant of unknown significance (N266S) were determined. All three variants showed reduced functionality compared to the wild-type protein. While the R263C and N266S variants displayed reduced binding to an HNF-1A target promoter, the P112L variant was unstable in vitro and in cells. Our results support and mechanistically explain disease causality for all investigated variants and allow for the dissection of structurally unstable and DNA binding defective variants. This points towards structural and biochemical investigation of HNF-1A being a valuable aid in reliable variant classification needed for precision diagnostics and management.

Published

2021

5. High-affinity nanobodies as tools for structural and functional studies on mammalian Arc

Author

Sigurbjörn Markússon, Erik I. Hallin, Helene J. Bustad, Arne Raasakka, Ju Xu, Gopinath Muruganandam, Remy Loris, Aurora Martinez, Clive R. Bramham, and Petri Kursula

Abstract

Activity-regulated cytoskeleton-associated protein (Arc) is a multidomain protein of retroviral origin with a vital role in the regulation of synaptic plasticity and memory formation in mammals. However, the mechanistic and structural basis of Arc function is little understood. Arc has an NTD involved in membrane binding and a CTD which binds postsynaptic protein ligands. In addition, the NTD and CTD both function in Arc oligomerization, including assembly of retrovirus-like capsid involved in intercellular signaling. We produced and characterised six ultra-high-affinity anti-Arc nanobodies (Nb). The CTD of both rat and human Arc could be crystallised in ternary complexes with two Nbs simultaneously bound (H11 and C11). H11 binding deep into the stargazing-binding pocket of Arc CTD suggested competitive binding with Arc ligand peptides, which was confirmed in vitro. This indicates that the H11 Nb could serve as a genetically-encoded tool for inhibition of endogenous Arc N-lobe interactions in study of neuronal function and plasticity. The crystallisation of the human Arc CTD in two different conformations, accompanied by SAXS data and molecular dynamics simulations, paints a dynamic picture of the mammalian Arc CTD. Dynamics were affected by mutations known to inhibit capsid formation, implying a role for Arc CTD dynamics in oligomerisation. Dimerisation of the NTD, together with structural dynamics of the CTD, suggest a mechanism, by which structural dynamics of the CTD may promote capsomer formation, and dimerisation of the NTD links capsomers, facilitating the formation of capsids. The described recombinant ultrahigh-affinity anti-Arc Nbs are versatile tools that can be further developed for studying mammalian Arc structure and function in vitro and in vivo.

Published

2021

6. Human myelin protein P2: From crystallography to time-lapse membrane imaging and neuropathy-associated variants

Author

Petri Kursula, M. Uusitalo, Saara Laulumaa, Matthew P. Blakeley, Adam Cohen Simonsen, Salla Ruskamo, and Martin Berg Klenow

Subjects

Crystallography, Circular dichroism, Myelin, Membrane, medicine.anatomical_structure, Chemistry, Fatty acid binding, medicine, Stacking, PMP2, Lipid bilayer, Lipid Transport

Abstract

Peripheral myelin protein 2 (P2) is a fatty acid-binding protein expressed in vertebrate peripheral nervous system myelin, as well as in human astrocytes. Suggested functions of P2 include membrane stacking and lipid transport. Mutations in the PMP2 gene, encoding P2, are associated with Charcot-Marie-Tooth disease (CMT). Recent studies have revealed three novel PMP2 mutations in CMT patient families. To shed light on the structure and function of the corresponding P2 variants, we used X-ray and neutron crystallography, small-angle X-ray scattering, circular dichroism spectroscopy, computer simulations, and lipid binding assays. The crystal and solution structures of the I50del, M114T, and V115A variants of P2 showed only minor differences to the wild-type protein, whereas the thermal stability of the disease variants was reduced. Lipid vesicle aggregation assays revealed no change in membrane stacking characteristics, while the variants showed slightly altered fatty acid binding. Time-lapse imaging of lipid bilayers indicated membrane blebbing induced by P2, which could be related to its function in stacking of two curved membrane surfaces in myelin in vivo. All variants caused blebbing of membranes on similar timescales. In order to better understand the links between structure, dynamics, and function, the crystal structure of perdeuterated P2 was refined from room temperature data collected using both neutrons and X-rays, and the results were compared to molecular dynamics simulations and cryocooled crystal structures. Taken together, our data indicate similar properties of all known CMT variants of human P2; while crystal structures are nearly identical, stability and function of the disease variants are impaired compared to the wild-type protein. Our data provide new insights into the structure-function relationships and dynamics of P2 in health and disease.

Published

2021

7. Structural properties and peptide ligand binding of the capsid homology domains of human Arc

Author

Petri Kursula, Erik I. Hallin, and Clive R. Bramham

Subjects

0301 basic medicine, QH301-705.5, Biophysics, Peptide, Peptide binding, QD415-436, Biochemistry, Homology (biology), 03 medical and health sciences, 0302 clinical medicine, Postsynaptic potential, Capsid homology, ddc:530, Short linear motif, Biology (General), chemistry.chemical_classification, Arc (protein), Chemistry, Crystal structure, Protein interaction, Protein dynamics, Protein turnover, Postsynaptic density, 030104 developmental biology, Capsid, 030220 oncology & carcinogenesis, Specificity, Phosphorylation, Research Article

Abstract

Biochemistry and biophysics reports 26, 100975 (2021). doi:10.1016/j.bbrep.2021.100975, The activity-regulated cytoskeleton-associated protein (Arc) is important for synaptic plasticity and the normal function of the brain. Arc interacts with neuronal postsynaptic proteins, but the mechanistic details of its function have not been fully established. The C-terminal domain of Arc consists of tandem domains, termed the N- and C-lobe. The N-lobe harbours a peptide binding site, able to bind multiple targets. By measuring the affinity of human Arc towards various peptides from stargazin and guanylate kinase-associated protein (GKAP), we have refined its specificity determinants. We found two sites in the GKAP repeat region that bind to Arc and confirmed these interactions by X-ray crystallography. Phosphorylation of the stargazin peptide did not affect binding affinity but caused changes in thermodynamic parameters. Comparison of the crystal structures of three high-resolution human Arc-peptide complexes identifies three conserved C���H����� interactions at the binding cavity, explaining the sequence specificity of short linear motif binding by Arc. We further characterise central residues of the Arc lobe fold, show the effects of peptide binding on protein dynamics, and identify acyl carrier proteins as structures similar to the Arc lobes. We hypothesise that Arc may affect protein-protein interactions and phase separation at the postsynaptic density, affecting protein turnover and re-modelling of the synapse. The present data on Arc structure and ligand binding will help in further deciphering these processes., Published by Elsevier, Amsterdam [u.a.]

Published

2020

8. Structure of the complete dimeric human GDAP1 core domain provides insights into ligand binding and clustering of disease mutations

Author

Giang Thi Tuyet Nguyen, Petri Kursula, Gopinath Muruganandam, Arne Raasakka, Remy Loris, and Aleksi Sutinen

Subjects

chemistry.chemical_classification, Residue (chemistry), Protein structure, Biochemistry, chemistry, Helix, Allosteric regulation, Fatty acid, Inner mitochondrial membrane, Ligand (biochemistry), Function (biology)

Abstract

Charcot-Marie-Tooth disease (CMT) is one of the most common inherited neurological disorders. Despite the common involvement of ganglioside-induced differentiation-associated protein 1 (GDAP1) in CMT, the protein structure and function, as well as the pathogenic mechanisms, remain unclear. We determined the crystal structure of the complete human GDAP1 core domain, which shows a novel mode of dimerization within the glutathione S-transferase (GST) family. The long GDAP1-specific insertion forms an extended helix and a flexible loop. GDAP1 is catalytically inactive towards classical GST substrates. Through metabolite screening, we identified a ligand for GDAP1, the fatty acid hexadecanedioic acid, which is relevant for mitochondrial membrane permeability and Ca2+homeostasis. The fatty acid binds to a pocket next to a CMT-linked residue cluster, increases protein stability, and induces changes in protein conformation and oligomerization. The closest homologue of GDAP1, GDAP1L1, is monomeric in its full-length form. Our results highlight the uniqueness of GDAP1 within the GST family and point towards allosteric mechanisms in regulating GDAP1 oligomeric state and function.

Published

2020

9. Structure and substrate specificity determinants of the taurine biosynthetic enzyme cysteine sulphinic acid decarboxylase

Author

Jan Haavik, Elaheh Mahootchi, Petri Kursula, Remy Loris, Arne Raasakka, Weisha Luan, and Gopinath Muruganandam

Subjects

chemistry.chemical_classification, Taurine, biology, Decarboxylation, Active site, Substrate (chemistry), Hypotaurine, Amino acid, Serine, chemistry.chemical_compound, chemistry, Biochemistry, biology.protein, Cysteine

Abstract

Pyridoxal 5′-phosphate (PLP) is an important cofactor for amino acid decarboxylases with many biological functions, including the synthesis of signalling molecules, such as serotonin, dopamine, histamine, γ-aminobutyric acid, and taurine. Taurine is an abundant amino acid with multiple physiological functions, including osmoregulation, pH regulation, antioxidative protection, and neuromodulation. In mammalian tissues, taurine is mainly produced by decarboxylation of cysteine sulphinic acid to hypotaurine, catalysed by the PLP-dependent cysteine sulphinic acid decarboxylase (CSAD), followed by non-enzymatic oxidation of the product to taurine. We determined the crystal structure of mouse CSAD and compared it to other PLP-dependent decarboxylases in order to identify determinants of substrate specificity and catalytic activity. Recognition of the substrate involves distinct side chains forming the substrate-binding cavity. In addition, the backbone conformation of a buried active-site loop appears to be a critical determinant for substrate side chain binding in PLP-dependent decarboxylases. Phe94 was predicted to affect substrate specificity, and its mutation to serine altered both the catalytic properties of CSAD and its stability. Using small-angle X-ray scattering, we further showed that similarly to its closest homologue, GADL1, CSAD presents open/close motions in solution. The structure of apo-CSAD indicates that the active site gets more ordered upon internal aldimine formation. Taken together, the results highlight details of substrate recognition in PLP-dependent decarboxylases and provide starting points for structure-based inhibitor design with the aim of affecting the biosynthesis of taurine and other abundant amino acid metabolites.

Published

2020

10. Structure of an atypical homodimeric actin capping protein from the malaria parasite

Author

Petri Kursula, Ábris Ádám Bendes, and Inari Kursula

Subjects

biology, Chemistry, Skeletal muscle, Heterologous, biology.organism_classification, In vitro, Cell biology, Protein filament, medicine.anatomical_structure, Mechanism of action, medicine, Plasmodium berghei, medicine.symptom, Actin, Function (biology)

Abstract

Actin capping proteins (CPs) are essential regulators of actin dynamics in all eukaryotes. Their structure and function have been extensively characterized in higher eukaryotes but their role and mechanism of action in apicomplexan parasites remain enigmatic. Here, we present a crystal structure of a unique homodimeric CP from the rodent malaria parasite Plasmodium berghei. In addition, we compare homo- and heterodimeric arrangements of P. berghei CPs (PbCPs) in solution. We complement our findings by describing the regulatory effects of PbCPs on heterologous skeletal muscle α-actin as well as parasite actin. Comprehensive kinetic and steadystate measurements show atypical regulation of actin dynamics; PbCPs facilitate rapid turnover of parasite actin I without affecting the apparent critical concentration. Possibly to rescue actin filament capping in life cycle stages where the CP β-subunit is downregulated, homo- and heterodimeric PbCPs show redundant effects in vitro. However, our data suggest that homodimers may in addition influence actin kinetics by recruiting lateral actin dimers. This unusual function could arise from the absence of a β-subunit, as the asymmetric PbCP homodimer lacks the structural elements essential for canonical barbed end interactions, suggesting a novel CP binding mode. These findings facilitate further studies aimed at elucidating the precise actin filament capping mechanism in Plasmodium and the eligibility of PbCPs as drug targets against malaria.Significance statementMalaria parasites of the genus Plasmodium display a unique form of gliding motility, which depends on an unconventional actomyosin motor. Actin capping proteins (CPs) play a major role in regulating parasite motility. Here, we describe a unique Plasmodium berghei CP (PbCP) system, behaving contradictory to canonical heterodimeric CPs, more suited to regulate the fast dynamics of the parasite actin system. We present the crystal structure of a distinctive homodimeric form of PbCP and extensive biochemical data, describing the atypical behavior of each PbCP form. The PbCP homodimer displays capping even in the absence of canonical conserved structural elements, suggesting a novel actin-CP interaction mode. These distinct structural properties could provide opportunities for drug design against malaria.

Published

2020

11. Molecular determinants of Arc oligomerization and formation of virus-like capsids

Author

Clive R. Bramham, Gopinath Muruganandam, Remy Loris, Ian Merski, Marte I. Flydal, Jorge Cuéllar, James J. Chambers, Erik I. Hallin, Yasunori Hayashi, Margaret M. Stratton, Aurora Martinez, Tambudzai Kanhema, José M. Valpuesta, Sverre Grødem, Petri Kursula, Daniela Lascu, Helene J. Bustad, Shreeram Akerkar, Tomohisa Hosokawa, Maria S. Eriksen, Oleksii Nikolaienko, and Rory O’Connell

Subjects

education.field_of_study, Arc (protein), Capsid, Chemistry, Population, Mutant, HEK 293 cells, Biophysics, RNA, Alanine scanning, education, Green fluorescent protein

Abstract

Expression of activity-regulated cytoskeleton-associated protein (Arc) is critical for long-term synaptic plasticity, memory formation, and cognitive flexibility. The ability of Arc to self-associate and form virus-like capsid structures implies functionally distinct oligomeric states. However, the molecular mechanism of Arc oligomerization is unknown. Here, we identified a 28-amino-acid region necessary and sufficient for Arc oligomerization. This oligomerization region is located within the second coil of a predicted anti-parallel coiled-coil in the N-terminal domain (NTD). Using alanine scanning mutagenesis, we found a 7-amino-acid motif critical for oligomerization and Arc-mediated transferrin endocytosis in HEK cells. Intermolecular fluorescence lifetime imaging in hippocampal neurons confirmed self-association mediated by the motif. To quantify oligomeric size, we performed a single-molecule photobleaching analysis of purified Arc wild-type and mutant. This analysis revealed a critical role for the NTD motif in the formation of higher-order Arc oligomers (30-170 molecules). Moreover, assembly of higher-order wild-type Arc oligomers was significantly enhanced by addition of GFP RNA. Purified wild-type Arc formed virus-like capsids, as visualized by negative-stain EM, and was estimated by light scattering analysis to contain 40-55 Arc units. In contrast, mutant Arc formed a homogenous dimer population as demonstrated by single-molecule TIRF imaging, size-exclusion chromatography with multi-angle light scattering analysis, small-angle X-ray scattering analysis, and single-particle 3D EM reconstruction. Thus, the dimer appears to be the basic building block for assembly. Herein, we show that the NTD motif is essential for higher-order Arc oligomerization, assembly of virus-like capsid particles, and facilitation of oligomerization by exogenous RNA.SIGNIFICANCEArc protein is rapidly expressed in neurons in response to synaptic activity and plays critical roles in synaptic plasticity, postnatal cortical developmental, and memory. Arc has diverse molecular functions, which may be related to distinct oligomeric states of the protein. Arc has homology to retroviral Gag protein and self-assembles into retrovirus-like capsid structures that are capable of intercellular transfer of RNA. Here, we identified a motif in the N-terminal coiled-coil domain of mammalian Arc that mediates higher-order oligomerization and formation of virus-like capsids. The basic building block is the Arc dimer and exogenous RNA facilitates further assembly. The identified molecular determinants of Arc oligomerization will help to elucidate the functional modalities of Arc in the mammalian brain.

Published

2019

12. Ionic strength and calcium regulate the membrane interactions of myelin basic protein and the cytoplasmic domain of myelin protein zero

Author

Nykola C. Jones, Søren Vrønning Hoffmann, Petri Kursula, and Arne Raasakka

Subjects

0303 health sciences, biology, Chemistry, Myelin protein zero, Vesicle, Myelin basic protein, 03 medical and health sciences, Myelin, 0302 clinical medicine, medicine.anatomical_structure, Membrane, nervous system, Cytoplasm, Ionic strength, medicine, Biophysics, biology.protein, Lipid bilayer, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

The formation of a mature myelin sheath in the vertebrate nervous system requires specific protein-membrane interactions. Several myelin-specific proteins are involved in the stacking of lipid membranes into multilayered structures around neuronal axons, and misregulation of these processes may contribute to chronic demyelinating diseases. Two key proteins functioning in myelin membrane binding and stacking are the myelin basic protein (MBP) and protein zero (P0). Other factors, including Ca2+, are important for the regulation of myelination. Here, we studied the effects of ionic strength and Ca2+ on the direct molecular membrane interactions of MBP and the cytoplasmic domain of P0 (P0ct). While both MBP and P0ct bound and aggregated negatively charged lipid vesicles, while simultaneously folding, both ionic strength and calcium had systematic effects on these interactions. Especially when decreasing membrane net negative charge, the level and kinetics of vesicle aggregation, which is a functional assay for myelin membrane-stacking proteins, were affected by both salt and Ca2+. The results indicate that the effects on lipid membrane surfaces by ions can directly affect myelin protein-membrane interactions at the molecular level, in addition to signalling effects in myelinating glia.

Published

2019

13. Direct binding of the flexible C-terminal segment of periaxin to β4 integrin suggests a molecular basis for CMT4F

Author

Peter J. Brophy, Arne Raasakka, Helen Linxweiler, Petri Kursula, and Diane L. Sherman

Subjects

0301 basic medicine, integrin, Integrin, Schwann cell, Fibronectin type III domain, Charcot-Marie-Tooth disease, lcsh:RC321-571, Cellular and Molecular Neuroscience, 03 medical and health sciences, Myelin, 0302 clinical medicine, medicine, periaxin, Cytoskeleton, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Molecular Biology, Original Research, 030304 developmental biology, 0303 health sciences, biology, Chemistry, Dystroglycan complex, Cell biology, myelin, 030104 developmental biology, medicine.anatomical_structure, Membrane protein, protein structural & functional analysis, Cytoplasm, biology.protein, Basal lamina, 030217 neurology & neurosurgery, Neuroscience

Abstract

The process of myelination in the nervous system requires a coordinated formation of both transient and stable supramolecular complexes. Myelin-specific proteins play key roles in these assemblies, which may link membranes to each other or connect the myelinating cell cytoskeleton to the extracellular matrix. The myelin protein periaxin is known to play an important role in linking the Schwann cell cytoskeleton to the basal lamina through membrane receptors, such as the dystroglycan complex. Mutations that truncate periaxin from the C terminus cause demyelinating peripheral neuropathy, Charcot-Marie-Tooth (CMT) disease type 4F, indicating a function for the periaxin C-terminal region in myelination. We identified the cytoplasmic domain of β4 integrin as a specific high-affinity binding partner for periaxin. The C-terminal region of periaxin remains unfolded and flexible when bound to the third fibronectin type III domain of β4 integrin. Our data suggest that periaxin is able to link the Schwann cell cytoplasm to the basal lamina through a two-pronged interaction via different membrane protein complexes, which bind close to the N and C terminus of this elongated, flexible molecule. publishedVersion

Published

2019

14. Molecular structure and function of myelin protein P0 in membrane stacking

Author

Julia Kowal, Huijong Han, Rocco Rossano, Matti Myllykoski, Salla Ruskamo, A. Fasano, Anne S. Ulrich, Paolo Riccio, Anne Baumann, Petri Kursula, Jochen Bürck, Henning Stahlberg, and Arne Raasakka

Subjects

Models, Molecular, 0301 basic medicine, Protein Conformation, Cryo-electron microscopy, Chemistry & allied sciences, lcsh:Medicine, Article, 03 medical and health sciences, Myelin, 0302 clinical medicine, Protein structure, Compact myelin, Extracellular, medicine, Humans, lcsh:Science, Integral membrane protein, Multidisciplinary, Chemistry, Myelin protein zero, Cell Membrane, lcsh:R, Transmembrane domain, 030104 developmental biology, Membrane, medicine.anatomical_structure, nervous system, Cytoplasm, ddc:540, Biophysics, lcsh:Q, Myelin P0 Protein, 030217 neurology & neurosurgery

Abstract

Compact myelin forms the basis of nerve insulation essential for higher vertebrates. Dozens of myelin membrane bilayers undergo tight stacking, and in the peripheral nervous system, this is partially enabled by myelin protein zero (P0). Consisting of an immunoglobulin (Ig)-like extracellular domain, a single transmembrane helix, and a cytoplasmic extension (P0ct), P0 harbours an important task in ensuring the integrity of compact myelin in the extracellular compartment, referred to as the intraperiod line. Several disease mutations resulting in peripheral neuropathies have been identified for P0, reflecting its physiological importance, but the arrangement of P0 within the myelin ultrastructure remains obscure. We performed a biophysical characterization of recombinant P0ct. P0ct contributes to the binding affinity between apposed cytoplasmic myelin membrane leaflets, which not only results in changes of the bilayer properties, but also potentially involves the arrangement of the Ig-like domains in a manner that stabilizes the intraperiod line. Transmission electron cryomicroscopy of native full-length P0 showed that P0 stacks lipid membranes by forming antiparallel dimers between the extracellular Ig-like domains. The zipper-like arrangement of the P0 extracellular domains between two membranes explains the double structure of the myelin intraperiod line. Our results contribute to the understanding of PNS myelin, the role of P0 therein, and the underlying molecular foundation of compact myelin stability in health and disease., Scientific Reports, 9, ISSN:2045-2322

Published

2018

15. Sub-atomic resolution X-ray diffraction of the SH3 domain from the post-synaptic density protein Shank3

Author

S.K. Ponna, Petri Kursula, Matti Myllykoski, and Tobias M. Boeckers

Subjects

Scaffold protein, Diffraction, body regions, Atomic resolution, Resolution (electron density), X-ray crystallography, Biophysics, Mineralogy, Biology, Intracellular signalling, Postsynaptic density, SH3 domain

Abstract

The post-synaptic density multidomain scaffolding proteins of the Shank family are structurally poorly characterised. The Shank family consists of three members, and domain-specific interactions of Shank are involved in forming a network of proteins at the post-synaptic region for intracellular signalling and cellular scaffolding. While X-ray crystallography has provided some information on individual Shank domains, the structural basis of Shank interactions is still largely unknown. In this study, the production and crystallisation of the previously uncharacterised Shank3 SH3 domain is presented. The highly twinned crystals diffracted synchrotron X-rays to a resolution higher than 0.9 Å, and these crystals will eventually have the potential to provide an ultrahigh-resolution view into the Shank family SH3 domains and their interactions.

Published

2016