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Analiza energijsko pomembnih interakcij v kompleksih nanotelo-antigen
ID Zgonik, Timotej (Author), ID Hadži, San (Mentor) More about this mentor... This link opens in a new window

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Abstract
Nanotelesa so proteini izvedeni iz posebne vrste imunoglobulinov, ki imajo samo težko verigo in imajo zaradi tega posebne lastnosti. Dodaten vpogled v način prepoznave antigenov z nanotelesi lahko dobimo z analizo energijsko močnejših interakcij (ang. hot-spot). Za iskanje teh interakcij in silico smo uporabili program FoldX, s katerim lahko izvedemo iskanje z mutacijo aminokislinskih ostankov v alanin in ovrednotimo nastalo spremembo proste energije pri nastanku kompleksa nanotelo-antigen. Na ta način smo našli 652 energijsko močnih interakcij v bazi 123 struktur kompleksov nanotelo-antigen. Ugotovili smo, da aminokislinski ostanek tirozin najpogosteje tvori energijsko močne interakcije, pretežno pa se te nahajajo v področju zanke CDR3. Zdi se tudi, da med številom interakcij in kontaktov ni nikakršne korelacije. Izsledki bi lahko bili eden od korakov za morebitno načrtovanje nanoteles za medicinsko uporabo.

Language:Slovenian
Keywords:energijsko pomembne interakcije, kontakt, nanotelo, epitop, FoldX
Work type:Bachelor thesis/paper
Typology:2.11 - Undergraduate Thesis
Organization:FKKT - Faculty of Chemistry and Chemical Technology
Year:2023
PID:20.500.12556/RUL-145072 This link opens in a new window
COBISS.SI-ID:148174851 This link opens in a new window
Publication date in RUL:03.04.2023
Views:961
Downloads:73
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Secondary language

Language:English
Title:Analysing hot spots in nanobody-antigen complexes
Abstract:
Nanobodies are proteins derived from heavy chain-only antibodies and as a result, have unique properties. To study how a nanobody binds to the appropriate antigen, we can analyse the places in the structure where energy interactions are the strongest, called hot spots. To find such interactions in silico, the FoldX program can be used to perform an alanine scanning method, because of which we can evaluate how free energy changes in the nanobody-antigen complex. With that method, we found 652 hot spots in a dataset of 123 nanobody-antigen complexes. We found that the amino acid most represented in hot spots is tyrosine and that the majority can be found in the CDR3 region of the nanobody. Furthermore, there appears to be no correlation between the number of hot spots and contacts in each nanobody. The results could be one of the steps on the way to designing nanobodies for medical use.

Keywords:hot spot, contact, nanobody, epitope, FoldX

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