Alphaviral nonstructural protease and its polyprotein substrate: arrangements for the perfect marriage
Kuupäev
2012-04-20
Autorid
Ajakirja pealkiri
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Kirjastaja
Abstrakt
Alfaviirused (sugukond Togaviridae) on artriiti ja entsefaliiti põhjustavad RNA genoomsed viirused. Nende paljunemise strateegia aluseks on viiruse replikaasi valkude süntees ühe nn. mittestruktuurse eelvalgu P1234 kujul ning selle ajaliselt reguleeritud lõikamine valmis valkudeks nsP2 proteaasi abil. Käesoleva väitekirja aluseks olevad uurimistööd viisid nsP2 substraat-spetsiifilisust tagavate mehhanismide väljaselgitamiseni; muu hulgas kirjeldati uudset proteolüütiliste lõikamiste regulatsioonimehhanismi, mis põhineb liitvalgu erinevate regioonide vahelisel „suhtlemisel“ viiruse replikatsiooni kompleksi moodustamise käigus. Sellest saab järeldada, et P1234 lõikamise ajaline regulatsioon sõltub otseselt replikatsioonikompleksi konfiguratsioonidest, millised omakorda on määratud selle komponentide vaheliste interaktsioonide poolt. Seega tõuseb viiruse nsP2 proteaas esile kui keerulise signaalvõrgustiku keskne element, mille roll viirus infektsiooni regulatsioonis seisneb replikatsiooniga kaasnevate sündmuste „jälgimises“ ja nendele reageerimises. Viimane põhineb sellel, et kui viiruse paljunemine jõuab kindla vahe-etapini, siis kaasneb sellega lõikamiskohtade ja/või muude oluliste struktuuride „esitlemine“ proteaasile, mis reageerib toimunud muudatustele lokaalse signaalülekande, mis lõppkokkuvõttes viib replikaasi kompleksi struktuuri järjestikulistele muudatustele, käivitamisega. Kokkuvõttes, tõid läbiviidud uurimised välja asjaolu, et lisaks varem teada olnud lõikamisjärjestuste äratundmisele, omab ka makromolekulaarsete struktuuride moodustamine viiruse valkude poolt olulist (ja mitmel juhul isegi määravat) rolli viiruse proteaasi töö reguleerimisel. Veel enam, eeldati, et seesugune mitmetahuline regulatsioon võib olla paljukomponentsete proteolüütiliste süsteemide üldine omadus. Kirjeldatud avastused ja nende lahtimõtestamine omavad olulist rolli uurimistöödele, mille eesmärgiks on alfaviiruste paljunemist takistavate lähenemiste väljatöötamine. Nii võib saadud tulemuste põhjal järeldada, et lisaks proteaasi aktiivsuse otsesele mõjutamisele võib viiruse replikatsiooni takistada ka mõjutades proteolüüsi regulatsiooni tagavaid molekulide vahelised seoseid.
Alphaviruses from the Togaviridae family are RNA viruses that may cause arthritic syndroms and encephalitis. The alphavirus replication strategy relies on the production of replicase proteins initially in the form of non-structural (ns) polyprotein precursor P1234, which during the course of replication becomes proteolytically processed by the virus-encoded nsP2 protease in a temporally regulated manner. The studies that constitute the basis of this thesis led to identification of the requirements for substrate specificity of nsP2 protease and revealed novel mechanism for the regulation of processing based on the specific communication between distant parts of the viral polyprotein brought together during assembly of replication complex. It was concluded that the order of alphaviral ns-polyprotein processing is mostly dependent on the configuration of the replication complex imposed by intermolecular interactions meant to guarantee timely cleavages. The alphaviral protease therefore emerges as an integral part of the sophisticated signaling mechanism, in which the regulatory task of the protease consists of monitoring the succession and completion of the events of viral infection. Once the respective replication status-induced conformational changes within replicase allow the presentation of the scissile bond and/or other essential determinants of substrate recognition like exosites, the local protease signaling is initiated, which apparently leads to further reconfiguration of the viral replication complex. Combined, the studies unveiled the decisive role played by the macromolecular assembly-dependent component of substrate recognition in addition to the sequence-dependent component, the combination of which may be expected to constitute the basis of regulation in multi-site proteolytic systems in general. Described findings and their interpretations are expected to provide with essential grounds and directions for further studies on the restriction of alphaviral replication through affecting the center of viral proteolytic activity or via intervention with its regulation by targeting intramolecular interactions.
Alphaviruses from the Togaviridae family are RNA viruses that may cause arthritic syndroms and encephalitis. The alphavirus replication strategy relies on the production of replicase proteins initially in the form of non-structural (ns) polyprotein precursor P1234, which during the course of replication becomes proteolytically processed by the virus-encoded nsP2 protease in a temporally regulated manner. The studies that constitute the basis of this thesis led to identification of the requirements for substrate specificity of nsP2 protease and revealed novel mechanism for the regulation of processing based on the specific communication between distant parts of the viral polyprotein brought together during assembly of replication complex. It was concluded that the order of alphaviral ns-polyprotein processing is mostly dependent on the configuration of the replication complex imposed by intermolecular interactions meant to guarantee timely cleavages. The alphaviral protease therefore emerges as an integral part of the sophisticated signaling mechanism, in which the regulatory task of the protease consists of monitoring the succession and completion of the events of viral infection. Once the respective replication status-induced conformational changes within replicase allow the presentation of the scissile bond and/or other essential determinants of substrate recognition like exosites, the local protease signaling is initiated, which apparently leads to further reconfiguration of the viral replication complex. Combined, the studies unveiled the decisive role played by the macromolecular assembly-dependent component of substrate recognition in addition to the sequence-dependent component, the combination of which may be expected to constitute the basis of regulation in multi-site proteolytic systems in general. Described findings and their interpretations are expected to provide with essential grounds and directions for further studies on the restriction of alphaviral replication through affecting the center of viral proteolytic activity or via intervention with its regulation by targeting intramolecular interactions.
Kirjeldus
Väitekirja elektrooniline versioon ei sisalda publikatsioone.
Märksõnad
alfaviirus, proteaasid, substraat, replikatsioon, ensüümi aktiivsus, alphavirus, proteases, substrate, replication, enzyme activity