P. Psarianos, Camilla Giovino, Sangeetha Paramathas, N. Patel, Rajesh Gupta, Ran Kafri, D. Malkin
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There remains a significant clinical need for better prognostication of LFS patients to predict disease outcomes and improve treatment options. An emerging body of literature is focused on the identification of non-invasive biomarkers to stratify patient populations. To this end, dermal skin fibroblasts (DSFs) have been shown to contain patient-specific disease correlates in a variety of conditions. Importantly, it has been shown that different TP53 mutations may underlie differential metabolic patterns in LFS fibroblasts; hence, we hypothesize that the metabolic signatures of DSFs from LFS patients can be utilized as prognostic biomarkers of cancer risk and response to treatment. Methods and Results: To understand the phenotypic diversity of LFS fibroblasts, our lab created a mouse xenograft model and co-cultured human LFS-derived DSFs with a sarcoma cancer cell line. LFS fibroblasts initiated earlier tumor onset in the mice compared to DSFs from healthy individuals, suggesting that these fibroblasts may secrete tumorigenic factors. Moreover, this effect was abrogated by exposure to rapamycin, an inhibitor of the mTORC1 protein kinase, suggesting that mTORC1 activity may govern the paracrine activity of these divergent fibroblast phenotypes. Next, to explore the role of mTORC1 in LFS, we used inducible expression of mutant p53 in DSFs. p53 mutants promoted mTORC1 hyperactivation, leading to increased anabolic activity, basal respiration and ATP production, suggesting that mTORC1 may alter fibroblast metabolism in a p53-dependent manner. Overall, these data provide evidence for divergent metabolic profiles of LFS skin fibroblasts which may reflect LFS phenotype variability. Ongoing work in our lab aims to further characterize the metabolic profiles of LFS fibroblasts through RNA sequencing and metabolomic profiling. Machine learning techniques will then be employed to identify molecular signatures correlating with clinical features such as age of tumor onset. Significance: This work will advance our understanding of how metabolism may underpin the clinical heterogeneity of LFS. The discovery of metabolic biomarkers will provide prognostic information with the potential to improve the early detection and treatment of cancers in LFS patients. Citation Format: Pamela Psarianos, Camilla Giovino, Sangeetha Paramathas, Nish Patel, Rajesh Gupta, Ran Kafri, David Malkin. Characterizing the metabolic landscape of dermal fibroblasts in Li-Fraumeni Syndrome for the prediction of cancer risk and drug response [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2021; 2021 Apr 10-15 and May 17-21. 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This condition affects 1 in 5000 individuals and is largely driven by germline mutations in the TP53 tumor suppressor gene, which has a broad spectrum of functions including metabolic regulation. While LFS is highly penetrant, there is a wide degree of variability in clinical phenotype, including age of onset and tumor type. This variability suggests a role for patient-specific genetic factors, such as the type of TP53 mutation, which may define each individual9s cancer risk and response to therapy. There remains a significant clinical need for better prognostication of LFS patients to predict disease outcomes and improve treatment options. An emerging body of literature is focused on the identification of non-invasive biomarkers to stratify patient populations. To this end, dermal skin fibroblasts (DSFs) have been shown to contain patient-specific disease correlates in a variety of conditions. Importantly, it has been shown that different TP53 mutations may underlie differential metabolic patterns in LFS fibroblasts; hence, we hypothesize that the metabolic signatures of DSFs from LFS patients can be utilized as prognostic biomarkers of cancer risk and response to treatment. Methods and Results: To understand the phenotypic diversity of LFS fibroblasts, our lab created a mouse xenograft model and co-cultured human LFS-derived DSFs with a sarcoma cancer cell line. LFS fibroblasts initiated earlier tumor onset in the mice compared to DSFs from healthy individuals, suggesting that these fibroblasts may secrete tumorigenic factors. Moreover, this effect was abrogated by exposure to rapamycin, an inhibitor of the mTORC1 protein kinase, suggesting that mTORC1 activity may govern the paracrine activity of these divergent fibroblast phenotypes. Next, to explore the role of mTORC1 in LFS, we used inducible expression of mutant p53 in DSFs. p53 mutants promoted mTORC1 hyperactivation, leading to increased anabolic activity, basal respiration and ATP production, suggesting that mTORC1 may alter fibroblast metabolism in a p53-dependent manner. Overall, these data provide evidence for divergent metabolic profiles of LFS skin fibroblasts which may reflect LFS phenotype variability. Ongoing work in our lab aims to further characterize the metabolic profiles of LFS fibroblasts through RNA sequencing and metabolomic profiling. Machine learning techniques will then be employed to identify molecular signatures correlating with clinical features such as age of tumor onset. Significance: This work will advance our understanding of how metabolism may underpin the clinical heterogeneity of LFS. The discovery of metabolic biomarkers will provide prognostic information with the potential to improve the early detection and treatment of cancers in LFS patients. Citation Format: Pamela Psarianos, Camilla Giovino, Sangeetha Paramathas, Nish Patel, Rajesh Gupta, Ran Kafri, David Malkin. Characterizing the metabolic landscape of dermal fibroblasts in Li-Fraumeni Syndrome for the prediction of cancer risk and drug response [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2021; 2021 Apr 10-15 and May 17-21. 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引用次数: 0
摘要
目的:Li-Fraumeni综合征(LFS)是一种与早发性癌症显著风险相关的遗传性疾病。这种情况每5000人中就有1人患病,主要是由肿瘤抑制基因TP53的种系突变引起的,该基因具有广泛的功能,包括代谢调节。虽然LFS具有高渗透性,但其临床表型(包括发病年龄和肿瘤类型)存在很大程度的可变性。这种差异表明了患者特异性遗传因素的作用,如TP53突变的类型,这可能决定了每个人的癌症风险和对治疗的反应。临床仍然需要更好地预测LFS患者的预后,以预测疾病结局并改进治疗方案。一个新兴的文献集中在非侵入性生物标志物的识别,以分层患者群体。为此,真皮皮肤成纤维细胞(dsf)已被证明在各种情况下含有患者特异性疾病相关因子。重要的是,研究表明,不同的TP53突变可能是LFS成纤维细胞代谢模式差异的基础;因此,我们假设LFS患者的dsf代谢特征可以用作癌症风险和治疗反应的预后生物标志物。方法和结果:为了了解LFS成纤维细胞的表型多样性,我们实验室建立了小鼠异种移植模型,并将人LFS衍生的DSFs与肉瘤癌细胞系共培养。与健康个体的DSFs相比,LFS成纤维细胞在小鼠中更早地引发肿瘤发作,这表明这些成纤维细胞可能分泌致瘤因子。此外,这种作用被暴露于雷帕霉素(mTORC1蛋白激酶的抑制剂)所消除,这表明mTORC1活性可能控制这些不同成纤维细胞表型的旁分泌活性。接下来,为了探索mTORC1在LFS中的作用,我们在DSFs中诱导表达突变型p53。p53突变体促进mTORC1过度活化,导致合成代谢活性、基础呼吸和ATP产生增加,表明mTORC1可能以p53依赖的方式改变成纤维细胞代谢。总的来说,这些数据为LFS皮肤成纤维细胞的不同代谢谱提供了证据,这可能反映了LFS表型的变异性。我们实验室正在进行的工作旨在通过RNA测序和代谢组学分析进一步表征LFS成纤维细胞的代谢谱。然后,机器学习技术将用于识别与临床特征(如肿瘤发病年龄)相关的分子特征。意义:这项工作将促进我们对代谢如何支持LFS临床异质性的理解。代谢生物标志物的发现将提供预后信息,有可能改善LFS患者癌症的早期发现和治疗。引文格式:Pamela Psarianos, Camilla Giovino, Sangeetha Paramathas, Nish Patel, Rajesh Gupta, Ran Kafri, David Malkin。表征Li-Fraumeni综合征真皮成纤维细胞的代谢景观,以预测癌症风险和药物反应[摘要]。见:美国癌症研究协会2021年年会论文集;2021年4月10日至15日和5月17日至21日。费城(PA): AACR;癌症杂志,2021;81(13 -增刊):2591。
Abstract 2591: Characterizing the metabolic landscape of dermal fibroblasts in Li-Fraumeni Syndrome for the prediction of cancer risk and drug response
Purpose: Li-Fraumeni Syndrome (LFS) is a genetic disorder associated with a significant risk of early-onset cancer. This condition affects 1 in 5000 individuals and is largely driven by germline mutations in the TP53 tumor suppressor gene, which has a broad spectrum of functions including metabolic regulation. While LFS is highly penetrant, there is a wide degree of variability in clinical phenotype, including age of onset and tumor type. This variability suggests a role for patient-specific genetic factors, such as the type of TP53 mutation, which may define each individual9s cancer risk and response to therapy. There remains a significant clinical need for better prognostication of LFS patients to predict disease outcomes and improve treatment options. An emerging body of literature is focused on the identification of non-invasive biomarkers to stratify patient populations. To this end, dermal skin fibroblasts (DSFs) have been shown to contain patient-specific disease correlates in a variety of conditions. Importantly, it has been shown that different TP53 mutations may underlie differential metabolic patterns in LFS fibroblasts; hence, we hypothesize that the metabolic signatures of DSFs from LFS patients can be utilized as prognostic biomarkers of cancer risk and response to treatment. Methods and Results: To understand the phenotypic diversity of LFS fibroblasts, our lab created a mouse xenograft model and co-cultured human LFS-derived DSFs with a sarcoma cancer cell line. LFS fibroblasts initiated earlier tumor onset in the mice compared to DSFs from healthy individuals, suggesting that these fibroblasts may secrete tumorigenic factors. Moreover, this effect was abrogated by exposure to rapamycin, an inhibitor of the mTORC1 protein kinase, suggesting that mTORC1 activity may govern the paracrine activity of these divergent fibroblast phenotypes. Next, to explore the role of mTORC1 in LFS, we used inducible expression of mutant p53 in DSFs. p53 mutants promoted mTORC1 hyperactivation, leading to increased anabolic activity, basal respiration and ATP production, suggesting that mTORC1 may alter fibroblast metabolism in a p53-dependent manner. Overall, these data provide evidence for divergent metabolic profiles of LFS skin fibroblasts which may reflect LFS phenotype variability. Ongoing work in our lab aims to further characterize the metabolic profiles of LFS fibroblasts through RNA sequencing and metabolomic profiling. Machine learning techniques will then be employed to identify molecular signatures correlating with clinical features such as age of tumor onset. Significance: This work will advance our understanding of how metabolism may underpin the clinical heterogeneity of LFS. The discovery of metabolic biomarkers will provide prognostic information with the potential to improve the early detection and treatment of cancers in LFS patients. Citation Format: Pamela Psarianos, Camilla Giovino, Sangeetha Paramathas, Nish Patel, Rajesh Gupta, Ran Kafri, David Malkin. Characterizing the metabolic landscape of dermal fibroblasts in Li-Fraumeni Syndrome for the prediction of cancer risk and drug response [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2021; 2021 Apr 10-15 and May 17-21. Philadelphia (PA): AACR; Cancer Res 2021;81(13_Suppl):Abstract nr 2591.