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dc.contributor.advisorBRITTO, SANDANARAJ S.en_US
dc.contributor.authorMULLAPUDI, MOHAN REDDYen_US
dc.date.accessioned2020-07-31T11:27:33Z-
dc.date.available2020-07-31T11:27:33Z-
dc.date.issued2020-04en_US
dc.identifier.citation480en_US
dc.identifier.urihttp://dr.iiserpune.ac.in:8080/xmlui/handle/123456789/4928-
dc.description.abstractNature has evolved to make a diverse set of protein architectures to perform the complex fundamental life processes such as transcription, translation, catalysis, metabolism, and transport. These naturally occurring protein assemblies serve as an inspiration for the design of synthetic and semi-synthetic protein assemblies. This is primarily achieved through two complementary technologies, such as genetic and chemical methods. In the past decade, genetic methods have matured as robust technology for accurate design of protein assemblies with a defined geometry. Compared to the genetic method, chemical methods are in their infancy. Most of the studies in this area are largely focused on a couple of model proteins. More importantly, there are no robust methods for purification, and therefore synthesized protein assemblies lack detailed analytical and biophysical characterization. My thesis work is directed towards developing new chemical strategies to convert monomeric proteins into protein complexes. This method is based on the generation of a simple scaffold, which we call "Facially Amphiphilic Proteins (FAPs)" from native proteins. The generation of FAP was achieved using a micelle-assisted protein labeling (MAPLab) technology. First, using serine proteases, we have demonstrated that monomeric proteins can be converted into protein complexes of bigger sizes. This was done by targeting active site Ser using fluorophosphonate chemistry. The simple design allowed us to systematically study the scaffold (FAP) with respect to individual units, i.e., protein, linker, and hydrophobic tail length/branching. This study also provided us with an opportunity to control the molecular weights, oligomeric states, and dimensions of the synthesized protein complexes precisely. Then, using a similar design and MAPLab Technology, we have also designed stimuli-responsive protein complexes. Further, we used the same method to make protein-synthetic peptide conjugates. Finally, in order to make this method more universal, we extended this technology for site-specific labeling of N-terminus. In addition, the same technology was explored for site-specific thiol bioconjugation.en_US
dc.description.sponsorshipDST, DBT, IISER Puneen_US
dc.language.isoenen_US
dc.subjectActivity-based Probesen_US
dc.subjectAmphiphilic Activity-based Probesen_US
dc.subjectSite-specific Labellingen_US
dc.subjectBio-conjugationen_US
dc.subjectSelf-assemblyen_US
dc.subjectFacially Amphiphilic Proteinsen_US
dc.subjectProtein Conjugatesen_US
dc.subjectProtein Engineeringen_US
dc.subjectProtein Nanotechnologyen_US
dc.subjectProtein Complexen_US
dc.subjectProtein Assemblyen_US
dc.subjectMAPLab Technologyen_US
dc.subjectVaccine Designen_US
dc.subject2020en_US
dc.titleRational Design, Synthesis and Self-assembly Studies of Facially Amphiphilic Proteins (FAPs)en_US
dc.typeThesisen_US
dc.publisher.departmentDept. of Chemistryen_US
dc.type.degreePh.Den_US
dc.contributor.departmentDept. of Chemistryen_US
dc.contributor.registration20143333en_US
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