Uloga žučnih kiselina u epigenetskoj regulaciji oksidativnog stresa i apoptoze u normalnim i malignim ćelijama

Abstract

Žučne kiseline deluju kao signalni molekuli u organizmu i uključene su u regulaciju brojnih metaboličkih, inflamatornih i imunomodulatornih procesa. Ova endogena jedinjenja ostvaruju svoje efekte najvećim delom putem nuklearnih receptora. Farnezoid X receptor (FXR) je glavni regulator homeostaze žučnih kiselina, a pokazano je da je značajno uključen i u procese inflamacije i kancerogeneze, prevashodno u jetri i intestinalnom traktu. Aktivacija FXR receptora predstavlja značajnu farmakološku strategiju za terapiju holestatskih bolesti jetre, inflamatorne bolesti creva i karcinoma kolona. Definisana je uloga žučnih kiselina u signalnim putevima koji regulišu ćelijski ciklus i doprinose razvoju ili regresiji maligniteta, ali je malo poznat uticaj ovih jedinjenja na epigenetske mehanizme regulacije ključnih ćelijskih procesa. Imajući u vidu da su efekti žučnih kiselina determinisani njihovom polarnošću, cilj istraživanja je bio da se ispita uticaj sintetski dobijenog keto derivata holne kiseline, 12-monoketoholne kiseline (MKH), u komparaciji sa prirodnim žučnim kiselinama, hidrofobnom henodeoksiholnom kiselinom (HDH) i hidrofilnom ursodeoksiholnom kiselinom (UDH), na ćelijske procese apoptoze, oksidativnog stresa i inflamacije, koji su od značaja za hemoprevenciju i terapiju karcinoma kolona, u in vitro i in vivo sistemima. Cilj istraživanja je takođe obuhvatao i ispitivanje uloge odabranih žučnih kiselina u epigenetskoj regulaciji ovih procesa u ćelijama karcinoma kolona. Na in vivo modelu intrahepatične holestaze kod eksperimentalnih životinja, pokazano je da UDH i MKH ispoljavaju antiapoptotski, antioksidativni i antiinflamatorni efekat u jetri i intestinumu. Utvrđeno je da UDH i MKH sprečavaju mitohondrijalni put aktivacije apoptoze u jetri, dok UDH ispoljava antiapoptotski efekat i u intestinumu eksperimentalnih životinja sa holestazom. Ove dve žučne kiseline su u značajnoj meri modulirale ekspresiju gena uključenih u antioksidativnu zaštitu, kao i aktivnost antioksidativnih enzima, u jetri i intestinumu eksperimentalnih životinja sa holestazom, ka nivoima ekspresije i aktivnosti kod zdravih, netretiranih životinja. Dok su UDH i MKH u dozi od 4 mg/kg ispoljile antiinflamatorno dejstvo u jetri i intestinumu smanjenjem ekspresije gena za proinflamatorni transkripcioni faktor NF-κB, primena HDH i MKH u dozi od 20 mg/kg je imala suprotan efekat. Na modelu HT-29 ćelijske linije adenokarcinoma kolona, utvrđeno je da polusintetska žučna kiselina MKH ispoljava značajno manju citotoksičnost u odnosu na HDH i nešto veću citotoksičnost u odnosu na UDH. Epigenetski lek vorinostat je ispoljio sinergističko citotoksično dejstvo sa sve tri ispitivane žučne kiseline. Vorinostat je ostvario proapoptotski i antiproliferativni efekat u HT-29 ćelijama, koji je bio najizraženiji u kombinaciji sa MKH, s obzirom da je došlo do značajnog povećanja odnosa ekspresije BAX i BCL2 gena i smanjenja ekspresije gena za marker proliferacije ciklin D1. Vorinostat je, takođe, značajno smanjio antioksidativni kapacitet HT-29 ćelija smanjenjem ekspresije NRF2 gena i sledstvenim smanjenjem ekspresije gena za antioksidativne enzime. HDH je dodatno smanjila, a MKH poboljšala antioksidativni kapacitet HT-29 ćelija modulacijom ekspresije NRF2 gena. U in vitro i in vivo sistemu u okviru ove doktorske disertacije je pokazano da, pored HDH kao poznatog endogenog agoniste FXR receptora, MKH takođe povećava ekspresiju gena za FXR i njegovog ciljnog gena za transkripcioni korepresor SHP, što ukazuje da ova polusintetska žučna kiselina može da aktivira FXR. Osim toga, utvrđeno je da žučne kiseline ispoljavaju različite efekte prema ekspresiji gena za histon deacetilaze HDAC1 i HDAC2 u jetri i intestinumu eksperimentalnih životinja, kao i u HT-29 ćelijama karcinoma kolona, a jedino je UDH značajno smanjila ekspresiju gena za oba ispitivana enzima uključena u epigenetsku regulaciju ćelijskih procesa, i u isptivanim tkivima i HT-29 ćelijama. Rezultati našeg rada ukazuju da bi se UDH i MKH mogle koristiti u hemoprevenciji karcinoma kolona u niskim dozama, s obzirom na utvrđene efekte u modulaciji ekspresije gena uključenih u procese apoptoze, oksidativnog stresa i inflamacije. Takođe, s obzirom na ostvaren sinergistički efekat žučnih kiselina sa epigenetskim antitumorskim agensom vorinostatom, otvara se mogućnost kombinovane farmakološke strategije u terapiji solidnih tumora, koji u najvećem procentu pokazuju rezistenciju prema samom vorinostatu.

Bile acids act as signaling molecules in the organism and they are involved in the regulation of numerous metabolic, inflammatory and immunomodulatory processes. These endogenous compounds exert their effects mostly by binding and activation of nuclear receptors. Farnesoid X receptor (FXR) is the main regulator of bile acid homeostasis, and has been shown to be significantly involved in processes of inflammation and carcinogenesis, primarily in the liver and intestinal tract. Activation of FXR receptor represents a significant pharmacological strategy for the treatment of cholestatic liver disease, inflammatory bowel disease, and colon carcinoma. The role of bile acids in signaling pathways regulating the cell cycle and contributing to the development or regression of malignancies is well determined, but the effects of these compounds on epigenetic mechanisms of key cellular processes regulation is yet to be elucidated. Given that the effects of bile acids are mostly determined by their polarity, the aim of our study was to investigate in vitro and in vivo effects of semi-synthetic keto derivative of cholic acid, 12-monoketocholic acid (MKC), in comparison to natural bile acids, hydrophobic chenodeoxycholic acid (CDC) and hydrophilic ursodeoxycholic acid (UDC), on processes of apoptosis, oxidative stress and inflammation, which are significant for both chemoprevention and therapy of colon cancer. Besides, the aim of our study was to examine the role of selected bile acids in the epigenetic regulation of these processes in colon cancer cells. In in vivo model of intrahepatic cholestasis in experimental animals, it has been demonstrated that UDC and MKC exhibit antiapoptotic, antioxidant, and antiinflammatory effects in the liver and intestine. It was shown that UDC and MKC prevent the mitochondrial pathway of apoptosis activation in the liver, while UDC exhibits an antiapoptotic effect in the intestine of experimental animals with cholestasis as well. These two bile acids significantly modulated the expression of genes involved in antioxidant protection, as well as the activity of antioxidant enzymes, in the liver and intestine of experimental animals with cholestasis, towards levels of expression and activity in healthy, untreated animals. While UDC and MKC at a low dose of 4 mg/kg exhibited an antiinflammatory effect in the liver and intestine by reducing the expression of the gene encoding the proinflammatory transcription factor NF-κB, the application of CDC and MKC at a high dose of 20 mg/kg exerted the opposite effect. In HT-29 human adenocarcinoma cell line, it has been demonstrated that semi-synthetic bile acid MKC exhibits significantly lower cytotoxicity than CDC and slightly higher cytotoxicity than UDC. The epigenetic drug vorinostat has exhibited a synergistic cytotoxic effect with all three investigated bile acids. Vorinostat exerted proapoptotic and antiproliferative effects in HT-29 cells, which were most pronounced in combination with MKC, as there was a significant increase in the ratio of BAX and BCL2 genes expression and a decrease of the proliferation marker cyclin D1 gene expression. Vorinostat also significantly reduced the antioxidant capacity of HT-29 cells by reducing the expression of NRF2 gene and consequently decreasing the expression of genes encoding antioxidant enzymes. CDC further reduced, while MKC improved the antioxidant capacity of HT-29 cells by modulating the expression of NRF2 gene. In both in vitro and in vivo systems, it was demonstrated that, in addition to CDC as a known endogenous FXR agonist, MKC also increased the expression of the gene encoding FXR, and FXR target gene encoding transcriptional co-repressor SHP as well, indicating that this semi-synthetic bile acid can also activate FXR. Besides, bile acids have been shown to exert distinct effects on the expression of the histone deacetylases HDAC1 and HDAC2 gene in the liver and intestine of experimental animals, and in HT-29 colon cancer cells. Only UDC significantly reduced the expression of the genes for both studied enzymes involved in the epigenetic regulation of cell processes, in both tissues and HT-29 cells. The results of our work indicate that UDC and MKC could be used in chemoprevention of colon cancer at low doses, considering determined effects in the modulation of expression of the genes involved in processes of apoptosis, oxidative stress and inflammation. Furthermore, synergistic effects of bile acids with the epigenetic antitumor agent vorinostat open up the possibility of a combined pharmacological strategy in the treatment of solid tumors, which are at the high percentage resistant to the effects of vorinostat alone.