Glutathione Transferase P1: Potential Therapeutic Target in Ovarian Cancer.
Petar SimicIgor PljesaLazar NejkovicDjurdja JeroticVesna CoricJelena StulicNenad KokosarDunja PopovAna Savic RadojevicVladimir PazinMarija Plješa-ErcegovacPublished in: Medicina (Kaunas, Lithuania) (2022)
Chemotherapy resistance of ovarian cancer, regarded as the most lethal malignant gynecological disease, can be explained by several mechanisms, including increased activity of efflux transporters leading to decreased intracellular drug accumulation, increased efflux of the therapeutic agents from the cell by multidrug-resistance-associated protein (MRP1), enhanced DNA repair, altered apoptotic pathways, silencing of a number of genes, as well as drug inactivation, especially by glutathione transferase P1 (GSTP1). Indeed, GSTP1 has been recognized as the major enzyme responsible for the conversion of drugs most commonly used to treat metastatic ovarian cancer into less effective forms. Furthermore, GSTP1 may even be responsible for chemoresistance of non-GST substrate drugs by mechanisms such as interaction with efflux transporters or different signaling molecules involved in regulation of apoptosis. Recently, microRNAs (miRNAs) have been identified as important gene regulators in ovarian cancer, which are able to target GST-mediated drug metabolism in order to regulate drug resistance. So far, miR-186 and miR-133b have been associated with reduced ovarian cancer drug resistance by silencing the expression of the drug-resistance-related proteins, GSTP1 and MDR1. Unfortunately, sometimes miRNAs might even enhance the drug resistance in ovarian cancer, as shown for miR-130b. Therefore, chemoresistance in ovarian cancer treatment represents a very complex process, but strategies that influence GSTP1 expression in ovarian cancer as a therapeutic target, as well as miRNAs affecting GSTP1 expression, seem to represent promising predictors of chemotherapeutic response in ovarian cancer, while at the same time represent potential targets to overcome chemoresistance in the future.
Keyphrases
- dna repair
- poor prognosis
- cell death
- dna damage
- emergency department
- squamous cell carcinoma
- small cell lung cancer
- long non coding rna
- oxidative stress
- mesenchymal stem cells
- radiation therapy
- genome wide
- endoplasmic reticulum stress
- drug induced
- single cell
- adverse drug
- cell therapy
- signaling pathway
- bone marrow
- current status
- cell cycle arrest
- long noncoding rna
- amino acid