{"title":"循环肿瘤DNA分析在癌症诊断中的挑战","authors":"Y. Hu, Shuya Li, Yanmin Gao, Hao Qi","doi":"10.15406/JNMR.2018.07.00180","DOIUrl":null,"url":null,"abstract":"People knew that the DNA molecule existed outside of cell even before finding out its famous double helix structure. Mandel and colleagues identified DNA molecule, termed as cell-free nucleic acids (cfDNA) later, in human bloodstream in as early as 1948.1 However, at that time no people realized how these DNA molecules associate with human diseases. Thing started turning around until 1964, DNA was found being released into sera for certain systemic lupus erythematosus patients.2 Since then, many clinical studies were carried out, more evidences demonstrated the strong correlation between cell free DNA and human diseases, especially for cancer.3,4 It was observed that even DNA could be isolated from blood of healthy people, but the amount of DNA significantly increased in the blood sample from patients with serious tumor. Particularly, as the earliest research, DNA fragments from mutant Kras gene were found in blood of pancreatic carcinoma patients5 and mutant N-ras gene fragment for myelodysplastic syndrome patients.6 These studies successfully demonstrated the direct correlation between circulating DNA and tumor. Recently it has been widely accepted that the levels of circulating nucleic acids strongly connected with tumor burden and malignant progression.7–11 For not being confused with cell-free DNA in healthy people, tumor cell related DNA circulating in human cardiovascular system were specially termed as circulating tumor DNA, ctDNA. Generally, it is widely considered that most DNA in circulation system is the debris of dead tumor cells. However, due to the complexity of cancer development, more fundamental studies are required to investigate questions, such as which processes contribute to ctDNA release from tumor cells12 and how the release process change the state of ctDNA in the circulation system. Besides being the debris left behind by dead cells, DNA is the key component of neutrophil extracellular traps (NETs), a host immune defense system against invading pathogens. Recently, increasing studies have demonstrated that NETs got involved in cancer development at every stages.13–15 With the development of molecular oncology, more and more tumor specific gene mutations were identified,16 and detail information about relevant tumor specific mutation could be found in systematically organized database, such as My Cancer Genome (www. mycancergenome.org). Up to now, ctDNA has been investigated with numerous of prevalent tumors, including Breast,17,18 Colorectal,7,19 Hepatocellular carcinoma,20,21 lung,22–24 Melanoma,25,26 Ovarian,27 Pancreatic28 and so on. In comparison with other biomarkers, e.g. protein, ctDNA is more informative with more precise analysis methods.29 Due to its nature, ctDNA is becoming a remarkable clinical tool. Especially, the convenience in collecting blood sample grant the liquid biopsy application great potential through ctDNA analysis in cancer diagnosis. However, precise analysis of ctDNA is still a challenge for some technique and biophysical reasons. For becoming a solid tool for tumor diagnosis, more clinical researches are still necessary to address some crucial questions about the physiological mechanism and analysis technical issues. In this review, we put the spotlight on the crucial issues in ctDNA based cancer diagnosis, especially the experimental issues which have led to contradictory results in different studies.","PeriodicalId":16465,"journal":{"name":"Journal of Nanomedicine Research","volume":"31 1","pages":"1-5"},"PeriodicalIF":0.0000,"publicationDate":"2018-03-21","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"2","resultStr":"{\"title\":\"Challenges in circulating tumor DNA analysis for cancer diagnosis\",\"authors\":\"Y. Hu, Shuya Li, Yanmin Gao, Hao Qi\",\"doi\":\"10.15406/JNMR.2018.07.00180\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"People knew that the DNA molecule existed outside of cell even before finding out its famous double helix structure. Mandel and colleagues identified DNA molecule, termed as cell-free nucleic acids (cfDNA) later, in human bloodstream in as early as 1948.1 However, at that time no people realized how these DNA molecules associate with human diseases. Thing started turning around until 1964, DNA was found being released into sera for certain systemic lupus erythematosus patients.2 Since then, many clinical studies were carried out, more evidences demonstrated the strong correlation between cell free DNA and human diseases, especially for cancer.3,4 It was observed that even DNA could be isolated from blood of healthy people, but the amount of DNA significantly increased in the blood sample from patients with serious tumor. Particularly, as the earliest research, DNA fragments from mutant Kras gene were found in blood of pancreatic carcinoma patients5 and mutant N-ras gene fragment for myelodysplastic syndrome patients.6 These studies successfully demonstrated the direct correlation between circulating DNA and tumor. Recently it has been widely accepted that the levels of circulating nucleic acids strongly connected with tumor burden and malignant progression.7–11 For not being confused with cell-free DNA in healthy people, tumor cell related DNA circulating in human cardiovascular system were specially termed as circulating tumor DNA, ctDNA. Generally, it is widely considered that most DNA in circulation system is the debris of dead tumor cells. However, due to the complexity of cancer development, more fundamental studies are required to investigate questions, such as which processes contribute to ctDNA release from tumor cells12 and how the release process change the state of ctDNA in the circulation system. Besides being the debris left behind by dead cells, DNA is the key component of neutrophil extracellular traps (NETs), a host immune defense system against invading pathogens. Recently, increasing studies have demonstrated that NETs got involved in cancer development at every stages.13–15 With the development of molecular oncology, more and more tumor specific gene mutations were identified,16 and detail information about relevant tumor specific mutation could be found in systematically organized database, such as My Cancer Genome (www. mycancergenome.org). Up to now, ctDNA has been investigated with numerous of prevalent tumors, including Breast,17,18 Colorectal,7,19 Hepatocellular carcinoma,20,21 lung,22–24 Melanoma,25,26 Ovarian,27 Pancreatic28 and so on. In comparison with other biomarkers, e.g. protein, ctDNA is more informative with more precise analysis methods.29 Due to its nature, ctDNA is becoming a remarkable clinical tool. Especially, the convenience in collecting blood sample grant the liquid biopsy application great potential through ctDNA analysis in cancer diagnosis. However, precise analysis of ctDNA is still a challenge for some technique and biophysical reasons. For becoming a solid tool for tumor diagnosis, more clinical researches are still necessary to address some crucial questions about the physiological mechanism and analysis technical issues. In this review, we put the spotlight on the crucial issues in ctDNA based cancer diagnosis, especially the experimental issues which have led to contradictory results in different studies.\",\"PeriodicalId\":16465,\"journal\":{\"name\":\"Journal of Nanomedicine Research\",\"volume\":\"31 1\",\"pages\":\"1-5\"},\"PeriodicalIF\":0.0000,\"publicationDate\":\"2018-03-21\",\"publicationTypes\":\"Journal Article\",\"fieldsOfStudy\":null,\"isOpenAccess\":false,\"openAccessPdf\":\"\",\"citationCount\":\"2\",\"resultStr\":null,\"platform\":\"Semanticscholar\",\"paperid\":null,\"PeriodicalName\":\"Journal of Nanomedicine Research\",\"FirstCategoryId\":\"1085\",\"ListUrlMain\":\"https://doi.org/10.15406/JNMR.2018.07.00180\",\"RegionNum\":0,\"RegionCategory\":null,\"ArticlePicture\":[],\"TitleCN\":null,\"AbstractTextCN\":null,\"PMCID\":null,\"EPubDate\":\"\",\"PubModel\":\"\",\"JCR\":\"\",\"JCRName\":\"\",\"Score\":null,\"Total\":0}","platform":"Semanticscholar","paperid":null,"PeriodicalName":"Journal of Nanomedicine Research","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.15406/JNMR.2018.07.00180","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 2
摘要
甚至在发现DNA分子著名的双螺旋结构之前,人们就知道它存在于细胞外。曼德尔和他的同事早在1948年就在人类血液中发现了DNA分子,后来被称为无细胞核酸(cfDNA)。然而,当时没有人意识到这些DNA分子与人类疾病的关系。事情开始好转,直到1964年,DNA被发现释放到某些系统性红斑狼疮患者的血清中此后,许多临床研究的开展,越来越多的证据表明游离细胞DNA与人类疾病,特别是癌症之间存在很强的相关性。3、4观察到,即使从健康人的血液中也能分离出DNA,但在严重肿瘤患者的血液样本中,DNA的含量明显增加。特别是,作为最早的研究,在胰腺癌患者的血液中发现了Kras基因突变的DNA片段5,在骨髓增生异常综合征患者的血液中发现了N-ras基因突变片段6这些研究成功地证明了循环DNA与肿瘤之间的直接关系。近年来,人们普遍认为循环核酸水平与肿瘤负荷和恶性进展密切相关。7-11为了不与健康人的无细胞DNA相混淆,在人类心血管系统中循环的肿瘤细胞相关DNA被专门命名为循环肿瘤DNA, ctDNA。一般认为,循环系统中的DNA大部分是死亡肿瘤细胞的碎片。然而,由于癌症发展的复杂性,需要更多的基础研究来调查问题,例如哪些过程有助于肿瘤细胞释放ctDNA,以及释放过程如何改变循环系统中ctDNA的状态。除了作为死细胞留下的碎片外,DNA还是中性粒细胞胞外陷阱(NETs)的关键组成部分,NETs是宿主抵御入侵病原体的免疫防御系统。最近,越来越多的研究表明,net参与了癌症发展的各个阶段。13-15随着分子肿瘤学的发展,越来越多的肿瘤特异性基因突变被发现,16在系统组织的数据库中可以找到相关肿瘤特异性突变的详细信息,如My Cancer Genome (www。mycancergenome.org)。到目前为止,ctDNA已经在许多常见肿瘤中进行了研究,包括乳腺癌,17、18结肠直肠癌,7、19肝细胞癌,20、21肺癌,22-24黑色素瘤,25、26卵巢,27胰腺等。与其他生物标记物(如蛋白质)相比,ctDNA具有更精确的分析方法,信息更丰富由于其性质,ctDNA正在成为一种非凡的临床工具。特别是血液采集的便捷性,使ctDNA分析在癌症诊断中的应用具有很大的潜力。然而,由于一些技术和生物物理原因,ctDNA的精确分析仍然是一个挑战。为了成为肿瘤诊断的可靠工具,还需要更多的临床研究来解决生理机制和分析技术方面的一些关键问题。本文综述了基于ctDNA的癌症诊断的关键问题,特别是导致不同研究结果相互矛盾的实验问题。
Challenges in circulating tumor DNA analysis for cancer diagnosis
People knew that the DNA molecule existed outside of cell even before finding out its famous double helix structure. Mandel and colleagues identified DNA molecule, termed as cell-free nucleic acids (cfDNA) later, in human bloodstream in as early as 1948.1 However, at that time no people realized how these DNA molecules associate with human diseases. Thing started turning around until 1964, DNA was found being released into sera for certain systemic lupus erythematosus patients.2 Since then, many clinical studies were carried out, more evidences demonstrated the strong correlation between cell free DNA and human diseases, especially for cancer.3,4 It was observed that even DNA could be isolated from blood of healthy people, but the amount of DNA significantly increased in the blood sample from patients with serious tumor. Particularly, as the earliest research, DNA fragments from mutant Kras gene were found in blood of pancreatic carcinoma patients5 and mutant N-ras gene fragment for myelodysplastic syndrome patients.6 These studies successfully demonstrated the direct correlation between circulating DNA and tumor. Recently it has been widely accepted that the levels of circulating nucleic acids strongly connected with tumor burden and malignant progression.7–11 For not being confused with cell-free DNA in healthy people, tumor cell related DNA circulating in human cardiovascular system were specially termed as circulating tumor DNA, ctDNA. Generally, it is widely considered that most DNA in circulation system is the debris of dead tumor cells. However, due to the complexity of cancer development, more fundamental studies are required to investigate questions, such as which processes contribute to ctDNA release from tumor cells12 and how the release process change the state of ctDNA in the circulation system. Besides being the debris left behind by dead cells, DNA is the key component of neutrophil extracellular traps (NETs), a host immune defense system against invading pathogens. Recently, increasing studies have demonstrated that NETs got involved in cancer development at every stages.13–15 With the development of molecular oncology, more and more tumor specific gene mutations were identified,16 and detail information about relevant tumor specific mutation could be found in systematically organized database, such as My Cancer Genome (www. mycancergenome.org). Up to now, ctDNA has been investigated with numerous of prevalent tumors, including Breast,17,18 Colorectal,7,19 Hepatocellular carcinoma,20,21 lung,22–24 Melanoma,25,26 Ovarian,27 Pancreatic28 and so on. In comparison with other biomarkers, e.g. protein, ctDNA is more informative with more precise analysis methods.29 Due to its nature, ctDNA is becoming a remarkable clinical tool. Especially, the convenience in collecting blood sample grant the liquid biopsy application great potential through ctDNA analysis in cancer diagnosis. However, precise analysis of ctDNA is still a challenge for some technique and biophysical reasons. For becoming a solid tool for tumor diagnosis, more clinical researches are still necessary to address some crucial questions about the physiological mechanism and analysis technical issues. In this review, we put the spotlight on the crucial issues in ctDNA based cancer diagnosis, especially the experimental issues which have led to contradictory results in different studies.