0000000001214982

AUTHOR

Kalle Saksela

showing 6 related works from this author

Structure of SNX9 SH3 in complex with a viral ligand reveals the molecular basis of its unique specificity for alanine-containing class I SH3 motifs

2021

Class I SH3 domain-binding motifs generally comply with the consensus sequence [R/K]x0PxxP, the hydrophobic residue 0 being proline or leucine. We have studied the unusual 0 = Ala-specificity of SNX9 SH3 by determining its complex structure with a peptide present in eastern equine encephalitis virus (EEEV) nsP3. The structure revealed the length and composition of the n-Src loop as important factors determining specificity. We also compared the affinities of EEEV nsP3 peptide, its mutants, and cellular ligands to SNX9 SH3. These data suggest that nsP3 has evolved to minimize reduction of conformational entropy upon binding, hence acquiring stronger affinity, enabling takeover of SNX9. The R…

DYNAMICSPROLINE-RICH PEPTIDESviruksetPROTEINSvirusesHTLV-1 GagLigandsEVOLUTIONARY CONSERVATIONalfaviruksetsrc Homology DomainsHIGH-AFFINITYretroviruksetDOMAINStructural BiologyBINDINGAnimalsHorsesMolecular Biologysoluviestintä11832 Microbiology and virologyAlanineBinding SitesPXXP MOTIFSisothermal titration calorimetrySH3solution NMR spectroscopyEEEV nsP3HIV-11182 Biochemistry cell and molecular biologyproteiinitCHEMICAL-SHIFTS3111 BiomedicinePeptidesSNX9Protein Binding
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Evolutionary plasticity of SH3 domain binding by Nef proteins of the HIV-1/SIVcpz lentiviral lineage

2021

ABSTRACTThe accessory protein Nef of human and simian immunodeficiency viruses (HIV and SIV) is an important pathogenicity factor known to interact with cellular protein kinases and other signaling proteins. A canonical SH3 domain binding motif in Nef is required for most of these interactions. For example, HIV-1 Nef activates the tyrosine kinase Hck by tightly binding to its SH3 domain. An archetypal contact between a negatively charged SH3 residue and a highly conserved arginine in Nef (Arg77) plays a key role here. Combining structural analyses with functional assays, we here show that Nef proteins have also developed a distinct structural strategy - termed the “R-clamp” - that favors th…

Geneticschemistry.chemical_classification0303 health sciencesLineage (genetic)Kinaseviruses030302 biochemistry & molecular biologyHuman immunodeficiency virus (HIV)virus diseasesBiologymedicine.disease_causeSH3 domainAmino acid03 medical and health scienceschemistrymedicineSalt bridgeBinding siteTyrosine kinase030304 developmental biology
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Evolutionary plasticity of SH3 domain binding by Nef proteins of the HIV-1/SIVcpz lentiviral lineage

2021

The accessory protein Nef of human and simian immunodeficiency viruses (HIV and SIV) is an important pathogenicity factor known to interact with cellular protein kinases and other signaling proteins. A canonical SH3 domain binding motif in Nef is required for most of these interactions. For example, HIV-1 Nef activates the tyrosine kinase Hck by tightly binding to its SH3 domain. An archetypal contact between a negatively charged SH3 residue and a highly conserved arginine in Nef (Arg77) plays a key role here. Combining structural analyses with functional assays, we here show that Nef proteins have also developed a distinct structural strategy—termed the "R-clamp”—that favors the formation …

RNA virusesviruksetvirusesSimian Acquired Immunodeficiency SyndromeHIV InfectionsPathology and Laboratory MedicineSH3 domainWhite Blood CellsImmunodeficiency VirusesAnimal CellsMedicine and Health SciencesBiology (General)MammalsGenetics11832 Microbiology and virology0303 health sciencesKinase030302 biochemistry & molecular biologyEukaryotavirus diseasesTransfection3. Good healthSIVMedical MicrobiologyViral PathogensViral evolutionVirusesVertebratesProto-Oncogene Proteins c-hckApesSimian Immunodeficiency VirusPathogensCellular TypesTyrosine kinaseResearch ArticlePrimateskinaasitEvolutionary ImmunologyLineage (genetic)QH301-705.5Immune CellsImmunologyevoluutioBiologyTransfectionResearch and Analysis MethodsHIV-tartuntaMicrobiologyViral EvolutionEvolution Molecularsrc Homology Domains03 medical and health sciencesVirologyRetrovirusesGeneticsAnimalsHumansLuciferaseAmino Acid Sequencenef Gene Products Human Immunodeficiency VirusChimpanzeesMolecular Biology TechniquesMicrobial PathogensMolecular Biology030304 developmental biologyEvolutionary BiologyBlood CellsSequence Homology Amino AcidMacrophagesLentivirusOrganismsBiology and Life SciencesHIVCell BiologyRC581-607Organismal Evolution3121 General medicine internal medicine and other clinical medicineMicrobial EvolutionAmniotesHIV-1ParasitologySalt bridgeproteiinitImmunologic diseases. AllergyZoology
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Guidelines for the use and interpretation of assays for monitoring autophagy (4th edition) 1

2021

Contains fulltext : 232759.pdf (Publisher’s version ) (Closed access) In 2008, we published the first set of guidelines for standardizing research in autophagy. Since then, this topic has received increasing attention, and many scientists have entered the field. Our knowledge base and relevant new technologies have also been expanding. Thus, it is important to formulate on a regular basis updated guidelines for monitoring autophagy in different organisms. Despite numerous reviews, there continues to be confusion regarding acceptable methods to evaluate autophagy, especially in multicellular eukaryotes. Here, we present a set of guidelines for investigators to select and interpret methods to…

0301 basic medicineProgrammed cell deathSettore BIO/06AutophagosomeAutolysosome[SDV]Life Sciences [q-bio]lnfectious Diseases and Global Health Radboud Institute for Molecular Life Sciences [Radboudumc 4]Autophagy-Related ProteinsReviewComputational biology[SDV.BC]Life Sciences [q-bio]/Cellular BiologyBiologySettore MED/0403 medical and health sciencesstressChaperone-mediated autophagyddc:570AutophagyLC3AnimalsHumanscancerSettore BIO/10Autophagosome; cancer; flux; LC3; lysosome; macroautophagy; neurodegeneration; phagophore; stress; vacuoleSet (psychology)Molecular Biologyvacuole.phagophore030102 biochemistry & molecular biologyvacuolebusiness.industryInterpretation (philosophy)AutophagyAutophagosomesneurodegenerationCell BiologyfluxMulticellular organismmacroautophagy030104 developmental biologyKnowledge baselysosomeAutophagosome; LC3; cancer; flux; lysosome; macroautophagy; neurodegeneration; phagophore; stress; vacuoleBiological AssayLysosomesbusinessBiomarkers[SDV.MHEP]Life Sciences [q-bio]/Human health and pathology
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Structural Basis of the High Affinity Interaction between the Alphavirus Nonstructural Protein-3 (nsP3) and the SH3 Domain of Amphiphysin-2

2016

We show that a peptide from Chikungunya virus nsP3 protein spanning residues 1728–1744 binds the amphiphysin-2 (BIN1) Src homology-3 (SH3) domain with an unusually high affinity (Kd 24 nM). Our NMR solution complex structure together with isothermal titration calorimetry data on several related viral and cellular peptide ligands reveal that this exceptional affinity originates from interactions between multiple basic residues in the target peptide and the extensive negatively charged binding surface of amphiphysin-2 SH3. Remarkably, these arginines show no fixed conformation in the complex structure, indicating that a transient or fluctuating polyelectrostatic interaction accounts for this …

0301 basic medicinenuclear magnetic resonance (NMR)Amino Acid MotifsStatic ElectricityPeptideTarget peptidePlasma protein bindingViral Nonstructural ProteinsBiologyhost-pathogen interactionBiochemistrySH3 domainsrc Homology Domainsamphiphysin SH3Structure-Activity Relationship03 medical and health sciencesProtein structuredynaminHumansShort linear motifprotein structureNuclear Magnetic Resonance BiomolecularMolecular BiologySrc homology 3 domain (SH3 domain)Adaptor Proteins Signal Transducingchemistry.chemical_classificationTumor Suppressor Proteinsta1182Nuclear ProteinsIsothermal titration calorimetryCell Biologyintrinsically disordered protein030104 developmental biologychemistryBiochemistrynsP3Protein Structure and FoldingAmphiphysinBiophysicsPeptidesChikungunya virusProtein BindingJournal of Biological Chemistry
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Autophagy

2021

In 2008, we published the first set of guidelines for standardizing research in autophagy. Since then, this topic has received increasing attention, and many scientists have entered the field. Our knowledge base and relevant new technologies have also been expanding. Thus, it is important to formulate on a regular basis updated guidelines for monitoring autophagy in different organisms. Despite numerous reviews, there continues to be confusion regarding acceptable methods to evaluate autophagy, especially in multicellular eukaryotes. Here, we present a set of guidelines for investigators to select and interpret methods to examine autophagy and related processes, and for reviewers to provide…

macroautophagy;autophagyAutophagosome[SDV]Life Sciences [q-bio]canceLC3 macroautophagyautophagosomeneurodegeneration;[SDV.BC]Life Sciences [q-bio]/Cellular BiologyAutophagy AutophagosomeNOstress vacuolestressautophagic processesstrerfluxLC3cancerguidelinesAutophagosome; cancer; flux; LC3; lysosome; macroautophagy; neurodegeneration; phagophore; stress; vacuoleSettore BIO/06 - Anatomia Comparata E Citologia[SDV.BC] Life Sciences [q-bio]/Cellular BiologyComputingMilieux_MISCELLANEOUSMedaka oryzias latipesphagophorevacuoleQHneurodegenerationAutophagosome cancer flux LC3 lysosome macroautophagy neurodegeneration phagophore stress vacuoleautophagy; autophagic processes; guidelines; autophagosome; cancer; flux; LC3; lysosome; macroautophagy; neurodegeneration; phagophore; stress; vacuolefluxmacroautophagystress.lysosomeAutophagosome; LC3; cancer; flux; lysosome; macroautophagy; neurodegeneration; phagophore; stress; vacuoleSettore BIO/17 - ISTOLOGIARC
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