Računalniška simulacija regeneracije flavina s kisikom v monoaminskih oksidazah

Černjavič, Tjaša

Računalniška simulacija regeneracije flavina s kisikom v monoaminskih oksidazah
ID Černjavič, Tjaša (Avtor), ID Obreza, Aleš (Mentor) Več o mentorju... Povezava se odpre v novem oknu

, ID Mavri, Janez (Komentor)

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Izvleček

Flavini so derivati riboflavina s triciklično strukturo, imenovano izoaloksazin. Znana encimsko aktivna flavina sta flavinmononukleotid (FMN) in flavinadenindinukleotid (FAD). Gre za redoks aktivne koencime, ki katalizirajo različne kemijske reakcije in skupaj z apoproteini tvorijo komplekse imenovane flavoencimi. Med imenovane encime spada monoamin oksidaza (MAO), ki vezana na zunanjo membrano mitohondrijev v reduktivni polreakciji reducira flavin do popolnoma reduciranega flavina (FADH2), v oksidativni polreakciji pa oksidacijo FADH2 nazaj do FAD. Dejstvo, da se flavin lahko popolnoma reducira do FADH2 je pomemben predpogoj za regeneracijo MAO z molekularnim kisikom. Pri regeneraciji nastane vodikov peroksid, ki lahko še naprej reagira in povzroči nastanek reaktivnih kisikovih zvrsti, ki so odgovorne za oksidativni stres in s tem povezano nevrodegeneracijo. Namen magistrske naloge je bil z uporabo molekulskega modeliranja in kvantne kemije določiti aktivacijsko prosto energijo reakcije flavina s kisikom. Za konstrukcijo tridimenzionalnih modelov smo uporabili program Molden, kvantnokemijske izračune pa smo izvedli s programom Gaussian. Izračune smo najprej izvedli v plinski fazi in nato za realnejšo simulacijo upoštevali še vpliv topila na reakcijo s pomočjo implicitnih modelov z metodo samouglašenega reakcijskega polja in z metodo Langevinovih dipolov. Izračunana aktivacijska energija za našo reakcijo v plinski fazi je bila 49,18 kcal/mol. Po vključitvi reakcijskega polja z implicitnimi modeli topila smo opazili, da so se energijske bariere znižale, in sicer za IEFPCM metodo oziroma model polarizabilnega kontinuuma, podprt s formalizmom integralskih enačb (ang. integral equation formalism polarizable continuum model) je bila vrednost bariere 40,91 kcal/mol, za CPCM oziroma model polarizabilnega kontinuuma s formalizmom prevodnika (ang. conductor-like polarizable continuum model) 40,85 kcal/mol, za SMD oziroma solvatacijski model, ki temelji na elektronski gostoti (ang. solvation model based on density) 33,65 kcal/mol in vrednost pri metodi Langevinovih dipolov 40,82 kcal/mol. Iz rezultatov smo zaključili, da voda znižuje aktivacijsko prosto energijo in pospešuje kemijsko reakcijo v primerjavi s plinsko fazo, in sicer najbolj v primeru SMD solvatacijskega modela. Uspeli smo izračunati proste energije aktivacije in potrditi, da je s kvantnokemijskimi metodami mogoče ovrednotiti reaktivnost regeneracije flavina s kisikom. Ugotovili smo, da reakcija v vodni raztopini brez upoštevanja encimske okolice, ne poteka. V prihodnje bi lahko raziskovali, ali je možno z zaviralci in drugimi učinkovinami vplivati na nastanek reaktivnih kisikovih zvrsti v flavoencimih.

Jezik:	Slovenski jezik
Ključne besede:	flavini, monoamin oksidaze (MAO), kvantna kemija, aktivacijska energija
Vrsta gradiva:	Magistrsko delo/naloga
Organizacija:	FFA - Fakulteta za farmacijo
Leto izida:	2020
PID:	20.500.12556/RUL-122219
Datum objave v RUL:	28.11.2020
Število ogledov:	1020
Število prenosov:	119
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Izvleček:
Jezik:	Angleški jezik
Naslov:	Computer simulation of flavin regeneration with oxygen in monoamine oxidases
Flavins are derivatives of riboflavin with a tricyclic structure called isoaloxazine. Known enzyme-active flavins are flavin mononucleotide (FMN) and flavin adenine dinucleotide (FAD). They are redox active coenzymes that catalyze various chemical reactions and together with apoproteins form complexes called flavoenzymes. These enzymes include monoamine oxidase (MAO) which, bound to the outer membrane of mitochondria in a reductive half-reaction, reduce flavin to fully reduced flavin (FADH2), and in the oxidative half-reaction, oxidizing FADH2 back to FAD. The fact that flavin can be completely reduced to FADH2 is an important prerequisite for MAO regeneration with molecular oxygen. Regeneration produces hydrogen peroxide which may continue to react and cause the formation of reactive oxygen species that are responsible for oxidative stress and related neurodegeneration. The purpose of the master's thesis was to determine the activation free energy of the reaction of flavin with oxygen using molecular modelling and quantum chemistry. The Molden programme was used to construct three-dimensional models, and the Gaussian programme to perform quantum chemical calculations. The calculations were first performed in the gas phase and then, for a more realistic simulation, the influence of the solvent on the reaction was taken into account with the help of implicit models using the self-attuned reaction field method and the Langevin dipole method. The calculated activation energy for our gas phase reaction was 49.18 kcal/mol. After integrating the reaction field with implicit solvent models, we noticed that the energy barriers were lowered, namely for the IEFPCM method (integral equation formalism polarizable continuum model), the barrier value was 40.91 kcal/mol, for CPCM (conductor-like polarizable continuum model) 40.85 kcal/mol, for SMD (solvation model based on density) 33.65 kcal/mol and the value with the Langevin dipole method was 40.82 kcal/mol. Based on the results, we concluded that water reduces the activation free energy and accelerates the chemical reaction compared to gas phase, most notably in the case of the SMD solvation model. We were able to calculate the free activation energies and confirm that the reactivity of flavin regeneration with oxygen can be evaluated by quantum chemical methods. We found out that the reaction in aqueous solution, without taking the enzymatic environment into account, does not take place. In the future, research could be carried out to prove whether it is possible to impact the formation of reactive oxygen species in flavoenzymes with inhibitors and other drugs.
Ključne besede:	flavins, monoamine oxidases (MAO), quantum chemistry, activation energy

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