Ovarian cancer,particularly high-grade serous ovariancancer(HGSOC),remains the most lethal gynecologicalmalignancy,with a 5-year survival rate of around 40%due to late diagnosis,recurrence,and the developmentof chemor...Ovarian cancer,particularly high-grade serous ovariancancer(HGSOC),remains the most lethal gynecologicalmalignancy,with a 5-year survival rate of around 40%due to late diagnosis,recurrence,and the developmentof chemoresistance[1,2].Mutations in tumor protein 53(TP53)occur in over 96%of HGSOC cases,impairing itstumor-suppressive functions,including cell cycle control,DNA repair,and apoptosis.Mutant TP53 promotes tumorprogression,genomic instability,and resistance to stan-dard therapies,thereby worsening patient outcomes[3,4].Death-associated protein kinase 1(DAPK1)is a key reg-ulator of apoptosis and autophagy[5,6].展开更多
Background:The cellular tumor protein p53(TP53)is a tumor suppressor gene that is frequently mutated in human cancers.Among various cancer types,the very aggressive high-grade serous ovarian carcinoma(HGSOC)exhibits t...Background:The cellular tumor protein p53(TP53)is a tumor suppressor gene that is frequently mutated in human cancers.Among various cancer types,the very aggressive high-grade serous ovarian carcinoma(HGSOC)exhibits the high-est prevalence of TP53 mutations,present in>96%of cases.Despite intensive efforts to reactivate p53,no clinical drug has been approved to rescue p53 func-tion.In this study,our primary objective was to administer in vitro-transcribed(IVT)wild-type(WT)p53-mRNA to HGSOC cell lines,primary cells,and ortho-topic mouse models,with the aim of exploring its impact on inhibiting tumor growth and dissemination,both in vitro and in vivo.Methods:To restore the activity of p53,WT p53 was exogenously expressed in HGSOC cell lines using a mammalian vector system.Moreover,IVT WT p53 mRNA was delivered into different HGSOC model systems(primary cells and patient-derived organoids)using liposomes and studied for proliferation,cell cycle progression,apoptosis,colony formation,and chromosomal instabil-ity.Transcriptomic alterations induced by p53 mRNA were analyzed using RNA sequencing in OVCAR-8 and primary HGSOC cells,followed by ingenuity path-way analysis.In vivo effects on tumor growth and metastasis were studied using orthotopic xenografts and metastatic intraperitoneal mouse models.Results:Reactivation of the TP53 tumor suppressor gene was explored in differ-ent HGSOC model systems using newly designed IVT mRNA-based methods.The introduction of WT p53 mRNA triggered dose-dependent apoptosis,cell cycle arrest,and potent long-lasting inhibition of HGSOC cell proliferation.Transcriptome analysis of OVCAR-8 cells upon mRNA-based p53 reactivation revealed significant alterations in gene expression related to p53 signaling,such as apoptosis,cell cycle regulation,and DNA damage.Restoring p53 function concurrently reduces chromosomal instability within the HGSOC cells,under-scoring its crucial contribution in safeguarding genomic integrity by moderating the baseline occurrence of double-strand breaks arising from replication stress.Furthermore,in various mouse models,treatment with p53 mRNA reduced tumor growth and inhibited tumor cell dissemination in the peritoneal cavity in a dose-dependent manner.Conclusions:The IVT mRNA-based reactivation of p53 holds promise as a potential therapeutic strategy for HGSOC,providing valuable insights into the molecular mechanisms underlying p53 function and its relevance in ovarian cancer treatment.展开更多
基金supported by grants from Deutsche Kreb-shilfe(70116875)the German Cancer Consortium(DKTK,Heidelberg).
文摘Ovarian cancer,particularly high-grade serous ovariancancer(HGSOC),remains the most lethal gynecologicalmalignancy,with a 5-year survival rate of around 40%due to late diagnosis,recurrence,and the developmentof chemoresistance[1,2].Mutations in tumor protein 53(TP53)occur in over 96%of HGSOC cases,impairing itstumor-suppressive functions,including cell cycle control,DNA repair,and apoptosis.Mutant TP53 promotes tumorprogression,genomic instability,and resistance to stan-dard therapies,thereby worsening patient outcomes[3,4].Death-associated protein kinase 1(DAPK1)is a key reg-ulator of apoptosis and autophagy[5,6].
基金This work was supported by grants from the Deutsche Krebshilfe(70114007)Wilhelm Sander Stiftung(Nr.2021.023.1),German Cancer Consortium(DKTK),Heidelberg.
文摘Background:The cellular tumor protein p53(TP53)is a tumor suppressor gene that is frequently mutated in human cancers.Among various cancer types,the very aggressive high-grade serous ovarian carcinoma(HGSOC)exhibits the high-est prevalence of TP53 mutations,present in>96%of cases.Despite intensive efforts to reactivate p53,no clinical drug has been approved to rescue p53 func-tion.In this study,our primary objective was to administer in vitro-transcribed(IVT)wild-type(WT)p53-mRNA to HGSOC cell lines,primary cells,and ortho-topic mouse models,with the aim of exploring its impact on inhibiting tumor growth and dissemination,both in vitro and in vivo.Methods:To restore the activity of p53,WT p53 was exogenously expressed in HGSOC cell lines using a mammalian vector system.Moreover,IVT WT p53 mRNA was delivered into different HGSOC model systems(primary cells and patient-derived organoids)using liposomes and studied for proliferation,cell cycle progression,apoptosis,colony formation,and chromosomal instabil-ity.Transcriptomic alterations induced by p53 mRNA were analyzed using RNA sequencing in OVCAR-8 and primary HGSOC cells,followed by ingenuity path-way analysis.In vivo effects on tumor growth and metastasis were studied using orthotopic xenografts and metastatic intraperitoneal mouse models.Results:Reactivation of the TP53 tumor suppressor gene was explored in differ-ent HGSOC model systems using newly designed IVT mRNA-based methods.The introduction of WT p53 mRNA triggered dose-dependent apoptosis,cell cycle arrest,and potent long-lasting inhibition of HGSOC cell proliferation.Transcriptome analysis of OVCAR-8 cells upon mRNA-based p53 reactivation revealed significant alterations in gene expression related to p53 signaling,such as apoptosis,cell cycle regulation,and DNA damage.Restoring p53 function concurrently reduces chromosomal instability within the HGSOC cells,under-scoring its crucial contribution in safeguarding genomic integrity by moderating the baseline occurrence of double-strand breaks arising from replication stress.Furthermore,in various mouse models,treatment with p53 mRNA reduced tumor growth and inhibited tumor cell dissemination in the peritoneal cavity in a dose-dependent manner.Conclusions:The IVT mRNA-based reactivation of p53 holds promise as a potential therapeutic strategy for HGSOC,providing valuable insights into the molecular mechanisms underlying p53 function and its relevance in ovarian cancer treatment.
