​Načrtovanje dimerizacijskih sistemov odvisnih od malih molekul za nadzor celičnih procesov

Rihtar, Erik

Načrtovanje dimerizacijskih sistemov odvisnih od malih molekul za nadzor celičnih procesov
ID Rihtar, Erik (Avtor), ID Jerala, Roman (Mentor) Več o mentorju... Povezava se odpre v novem oknu

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Izvleček

Proteinski dimerizacijski sistemi, ki so odvisni od majhnih molekul, so pomembno sintezno-biološko orodje, ki omogoča zunanji nadzor bioloških procesov. Vendar pa je terapevtska uporaba obstoječih sistemov omejena zaradi neugodnih lastnosti ligandov ali imunskega odziva na proteinske domene, ki niso človeškega izvora. Zato smo razvili nove dimerizacijske sisteme, ki temeljijo na uporabi človeških proteinskih komponent in se odzivajo na zdravila, ki so že odobrena za klinično uporabo, ali na endogene ligande. Prva od naših strategij za oblikovanje takih sistemov temelji na cepitvi človeških ligand-vezavnih proteinov na dva fragmenta, ki se pogojno združita v prisotnosti tarčnega liganda (sistemi INSPIRE). Z uporabo platforme INSPIRE smo pokazali, da lahko dinamično, ortogonalno in multipleksno nadzorujemo izražanje genov v sesalskih celicah. Poleg tega smo pokazali uporabnost platforme INSPIRE in vivo in jo uporabili za preoblikovanje endogene regulatorne poti. INSPIRE predstavlja univerzalen pristop za oblikovanje sistemov, ki se odzivajo na majhne molekule, in ima potencial za načrtovanje novih senzorjev, regulatornih omrežij in terapevtskih aplikacij. Poleg platforme INSPIRE smo razvili dimerizacijske sisteme, ki temeljijo na uporabi ločenih ligand-vezavnih variabilnih fragmentov (Fv) protiteles. Ta pristop vključuje uporabo ločenih domen Fv protiteles, ki se sestavijo v prisotnosti tarčnega liganda. Prikazali smo tri različne primere, ki nakazujejo na uporabnost tovrstnih sistemov. Prvič, pokazali smo, da je mogoče z ločenim Fv nadzirati izražanje genov in načrtovati logične funkcije v sesalskih celicah. Drugič, razvili smo sistem, ki je odziven na fluorescein in ga uporabili za vezavo tumor-specifičnih adapterskih molekul scFv na univerzalen receptor CAR izražen na celicah T. Nazadnje, pokazali smo od fluoresceina odvisno uravnavanje aktivnosti bispecifičnega T celičnega povezovalca (BiTE), ki omogoča preusmeritev celic T proti tumorskim celicam. Razviti dimerizacijski sistemi predstavljajo zanimivo možnost za hitro razširitev obstoječih sistemov, ki se odzivajo na majhne molekule, in se lahko uporabljajo tako v raziskovalne kot terapevtske namene. Ti sistemi omogočajo nadzor genskih, proteinskih in celičnih terapij z majhnimi molekulami, kar lahko izboljša varnost in učinkovitost teh terapij v primerjavi s sedanjimi načini zdravljenja.

Jezik:	Slovenski jezik
Ključne besede:	sintezna biologija, dimerizacijski sistemi, cepljeni proteini, celice CAR T, genska terapija, sistem CRISPR/Cas9
Vrsta gradiva:	Doktorsko delo/naloga
Organizacija:	MF - Medicinska fakulteta
Leto izida:	2023
PID:	20.500.12556/RUL-151820
Datum objave v RUL:	21.10.2023
Število ogledov:	832
Število prenosov:	153
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Sekundarni jezik

Izvleček:
Jezik:	Angleški jezik
Naslov:	Engineering chemically inducible dimerization systems for control of cellular processes
Chemically inducible systems represent valuable synthetic biology tools that enable the external control of biological processes. However, their translation to therapeutic applications has been limited due to unfavorable ligand characteristics or immunogenicity of non-human protein domains. Therefore, we developed novel dimerization systems that are based on human protein components and respond to clinically approved drugs or physiologically important ligands. First, we developed a strategy, where ligand-binding proteins of human origin are split into two fragments that reassemble in the presence of a ligand (INSPIRE). We show that the INSPIRE platform can be used for the dynamic, orthogonal, and multiplex control of gene expression in mammalian cells. Furthermore, we demonstrate the functionality of our INSPIRE platform in vivo and apply it for perturbing an endogenous regulatory network. INSPIRE presents a generalizable approach toward designing small molecule-responsive systems that can be implemented for the construction of new sensors, regulatory networks, and therapeutic applications. In addition to the INSPIRE platform, we have also developed dimerization systems utilizing separated antibody variable fragments (Fv) that bind to small molecules. This approach involves saperating Fv into two domains, which dimerize in the presence of the target ligand. To illustrate the broad utility of this approach, we present three examples. First, we demonstrate that saperated Fv can be employed to regulate gene expression and construction of logic gate functions. Second, we develop a fluorescein-responsive CID system and apply it for the recruitment of tumor-targeting scFv adaptor molecules to the universal CAR receptor expressed on T cells. Lastly, we showcase the fluorescein inducible regulation of a bispecific T cell engager (BiTE) complex capable of redirecting T cells to kill tumor cells. Additionally, we have developed two-input switches that are based on ligand-binding domains of nuclear receptors and their interacting peptides. These switches integrate two distinct competing signals, enabling precise control over cellular processes. We exemplify this controllability through the fine regulation of gene expression in mammalian cells. The designed dimerization systems offer an exciting opportunity to rapidly expand the current repertoire of small molecule-responsive systems for use in research and therapeutic applications. Together, these systems hold great potential for achieving chemogenetic control over gene, protein, and cell-based therapeutics, ultimately leading to enhanced safety and efficacy compared to existing treatments.
Ključne besede:	synthetic biology, dimerization systems, split proteins, CAR T cells, gene therapy, CRISPR/Cas9 system

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