肿瘤干细胞与胃癌

最近的一项研究报导,采用流式细胞仪分选技术从人胃癌细胞株中分离出CD44^＋胃癌干细胞. 20～30×10³个CD44＋细胞入NOD/SCID 鼠腹部皮下和胃浆膜下能形成胃癌移植瘤, 100×10³个CD44^－的细胞入NOD/SCID 鼠体内不形成肿瘤.采用无血清、无粘附间质的干细胞体外培养方法,发现CD44^＋的细胞能形成肿瘤微球体,具有自我更新能力,而CD44^－的细胞则不形成球形克隆.上述的实验结果说明,在人胃癌细胞株中存在胃癌肿瘤干细胞.据此可以相信,胃癌干细胞是胃癌细胞中具有自我更新及分化潜能的一小群细胞,不能被目前的化疗、放疗等抗癌治疗措施所杀灭,是胃癌术后复发、肿瘤进展扩散转移的根源.胃癌干细胞可能来源于骨髓干细胞.随着对胃癌肿瘤干细胞生物学研究的深入,必将为胃癌的临床诊断和治疗提供新的策略.     

Phosphorylation of EZH2 by CDK1 and CDK2

Histone H3 lysine 27 trimethylation (H3K27me3) catalyzed by the enzymatic subunit EZH2 in the Polycomb repressive complex 2 (PRC2) is essential for cells to ‘memorize’ gene expression patterns through cell divisions and plays an important role in establishing and maintaining cell identity during development. However, how the epigenetic mark is inherited through cell generations remains poorly understood. Recently, we and others demonstrate that CDK1 and CDK2 phosphorylate EZH2 at threonine 350 (T350) and that T350 phosphorylation is important for the binding of EZH2 to PRC2 recruiters, such as noncoding RNAs (ncRNAs) HOTAIR and XIST, and for the effective recruitment of PRC2 to EZH2 target loci in cells. These findings imply that phosphorylation of EZH2 by CDK1 and CDK2 may provide cells a mechanism that enhances EZH2 function during S and G2 phases of the cell cycle, thereby ensuring K27me3 on de novo synthesized H3 incorporated in nascent nucleosomes before sister chromosomes are divided into two daughter cells. Additionally, a potential role of T350 phosphorylation of EZH2 in differing EZH2 from its homolog EZH1 in catalyzing H3K27me3 as well as the interplay between phosphorylation at T350 and other residues (e.g. phosphorylation by p38 at threonine 372 (T372)) in governing EZH2 activity in proliferating versus non-dividing cells are also discussed. Together, CDK phosphorylation of EZH2 at T350 may represent a key regulatory mechanism of EZH2 function that is essential for the maintenance of H3K27me3 marks through cell divisions.     

肿瘤干细胞研究进展及临床应用前景

肿瘤干细胞是肿瘤中具有自我更新能力和分化潜能,能产生异质性细胞的细胞。我们简要阐述了肿瘤干细胞存在的证据、分离技术及来源,并对以肿瘤干细胞为靶标的肿瘤治疗途径、临床应用前景和问题进行了综述。     

肿瘤干细胞的光动力治疗研究进展

肿瘤干细胞(cancerstem cells,CSCs)是在肿瘤组织中具有干细胞特性的细胞亚群,它具有正常干细胞的多向分化潜能,能够无限增值和自主分化为各种具有异质性的肿瘤细胞。CSCs在肿瘤的发生、生长、转移中起着重要作用。同时,CSCs对目前大多数治疗如化疗、放疗不敏感,甚至具有耐药性,这也就导致了恶性肿瘤在治疗后容易复发。鉴于此,针对肿瘤干细胞的治疗日益受到关注,光动力疗法(photodynamictherapy,PDT)由于其微创性,不良反应少,靶向性强等特点在肿瘤的治疗研究中不断得到发展。本文将从CSCs的特性入手,结合PDT治疗的最新进展,探讨PDT治疗在肿瘤干细胞治疗中的应用。     

Cancer stem cells: the lessons from pre-cancerous stem cells

How a cancer is initiated and established remains elusive despite all the advances in decades of cancer research. Recently the cancer stem cell (CSC) hypothesis has been revived, challenging the long-standing model of "clonal evolution" for cancer development and implicating the dawning of a potential cure for cancer [1]. The recent identification of precancerous stem cells (pCSCs) in cancer, an early stage of CSC development, however, implicates that the "clonal evolution" is not contradictory to the CSC hypothesis, but is rather an aspect of the process of CSC development [2]. The discovery of pCSC has revealed and will continue to reveal the volatile properties of CSC with respects to their phenotype, differentiation and tumorigenic capacity during initiation and progression. Both pCSC and CSC might also serve as precursors of tumor stromal components such as tumor vasculogenic stem/progenitor cells (TVPCs). Thus, the CSC hypothesis covers the developing process of tumor-initiating cells (TIC) --> pCSC --> CSC --> cancer, a cellular process that should parallel the histological process of hyperplasia/metaplasia (TIC) --> precancerous lesions (pCSC) --> malignant lesions (CSC --> cancer). The embryonic stem (ES) cell and germline stem (GS) cell genes are subverted in pCSCs. Especially the GS cell protein piwil2 may play an important role during the development of TIC --> pCSC --> CSC, and this protein may be used as a common biomarker for early detection, prevention, and treatment of cancer. As cancer stem cell research is yet in its infancy, definitive conclusions regarding the role of pCSC can not be made at this time. However this review will discuss what we have learned from pCSC and how this has led to innovative ideas that may eventually have major impacts on the understanding and treatment of cancer.     

胃癌干细胞研究进展

胃癌是仅次于肺癌的第二大致死率癌症,尽管近年来对胃癌研究有了很大进展,但由于缺乏良好的动物模型,对胃癌的发病机理仍然不是很清楚.近年的研究表明,肿瘤组织不是由均一细胞构成的,其中存在一些少量细胞可以自我更新并可以分化为肿瘤组织的其他细胞,这类细胞具有类似成体组织干细胞（tissue stem cells）的特性称之为肿瘤干细胞（cancer stem cells）.肿瘤干细胞被认为在肿瘤的生长、转移、复发中发挥着重要作用.有证据表明在胃癌组织中存在胃癌干细胞（gastric cancer stem cells）,但是对胃癌干细胞的来源仍然不是十分明确.对肿瘤干细胞的研究有助于癌症的治疗,改变目前药物针对所有癌细胞的治疗策略.     

微小RNA与肿瘤干细胞耐药的研究进展

肿瘤干细胞（Cancer stem cells,CSCs）是肿瘤组织中一小部分具有自我更新和致瘤性的细胞,具有特殊的耐药机制,与肿瘤的复发和治疗失败关系密切。微小RNA（microRNAs,miRNAs）是一类长度约为19～25个核苷酸的内源性非编码单链RNA,能够通过调控相关靶基因的表达,参与调控肿瘤干细胞增殖、凋亡、上皮-间质转化等重要的生命过程,引起CSCs对化疗药物产生原发性多药耐药性。本论文就miRNAs在调控CSCs多药耐药性方面的研究进展作一综述。     

Harnessing the apoptotic programs in cancer stem‐like cells

Elimination of malignant cells is an unmet challenge for most human cancer types even with therapies targeting specific driver mutations. Therefore, a multi‐pronged strategy to alter cancer cell biology on multiple levels is increasingly recognized as essential for cancer cure. One such aspect of cancer cell biology is the relative apoptosis resistance of tumor‐initiating cells. Here, we provide an overview of the mechanisms affecting the apoptotic process in tumor cells emphasizing the differences in the tumor‐initiating or stem‐like cells of cancer. Further, we summarize efforts to exploit these differences to design therapies targeting that important cancer cell population.     

Evolution of Relapse-Proficient Subclones Constrained by Collateral Sensitivity to Oncogene Overdose in Wnt-Driven Mammary Cancer

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Progress of Breast Cancer basic research in China

Breast cancer is the most commonly diagnosed and the most lethal cancer in females both in China and worldwide. Currently, the origin of cancer stem cells, the heterogeneity of cancer cells, the mechanism of cancer metastasis and drug resistance are the most important issues that need to be addressed. Chinese investigators have recently made new discoveries in basic breast cancer researches, especially regarding cancer stem cells, cancer metabolism, and microenvironments. These efforts have led to a deeper understanding of drug resistance and metastasis and have also indicated new biomarkers and therapeutic targets. These findings emphasized the importance of the cancer stem cells for targeted therapy. In this review, we summarized the latest important findings in this field in China.     

癌、干细胞和癌干细胞共同拥有的信号传导通路

干细胞（SC）是具有无限自我更新和分化能力的细胞,随着对SC研究的不断深入,人们发现SC与肿瘤细胞有许多共性,如无限增生能力、迁移能力及在某些条件下能相互转化,故提出了肿瘤起源于SC的学说。探讨癌、SC和癌干细胞（CSC）之间可能存在的共同信号传导通路,以便发现治疗CSC的靶位。     

Cancer stem cells as a therapeutic target in bladder cancer

Bladder cancer is one of the most prevalent genitourinary cancers responsible for about 150,000 deaths per year worldwide. Currently, several treatments, such as endoscopic and open surgery, appended by local or systemic immunotherapy, chemotherapy, and radiotherapy are used to treat this malignancy. However, the differences in treatment outcome among patients suffering from bladder cancer are considered as one of the important challenges. In recent years, cancer stem cells, representing a population of undifferentiated cells with stem-cell like properties, have been eyed as a major culprit for the high recurrence rate in superficial papillary bladder cancer. Cancer stem cells have been reported to be resistant to conventional treatments, such as chemotherapy, radiation, and immunotherapy, which induce selective pressure on tumoral populations resulting in selection and growth of the resistant cells. Therefore, targeting the therapeutic aspects of cancer stem cells in bladder cancer may be promising. In this study, we briefly discuss the biology of bladder cancer and then address the possible relationship between molecular biology of bladder cancer and cancer stem cells. Subsequently, the mechanisms of resistance applied by cancer stem cells against the conventional therapeutic tools, especially chemotherapy, are discussed. Moreover, by emphasizing the biomarkers described for cancer stem cells in bladder cancer, we have provided, described, and proposed targets on cancer stem cells for therapeutic interventions and, finally, reviewed some immunotargeting strategies against bladder cancer stem cells.     

Cancer Reviews 2021 series: Cancer evolution: Darwin and beyond

Clinical and laboratory studies over recent decades have established branched evolution as a feature of cancer. However, while grounded in somatic selection, several lines of evidence suggest a Darwinian model alone is insufficient to fully explain cancer evolution. First, the role of macroevolutionary events in tumour initiation and progression contradicts Darwin''s central thesis of gradualism. Whole‐genome doubling, chromosomal chromoplexy and chromothripsis represent examples of single catastrophic events which can drive tumour evolution. Second, neutral evolution can play a role in some tumours, indicating that selection is not always driving evolution. Third, increasing appreciation of the role of the ageing soma has led to recent generalised theories of age‐dependent carcinogenesis. Here, we review these concepts and others, which collectively argue for a model of cancer evolution which extends beyond Darwin. We also highlight clinical opportunities which can be grasped through targeting cancer vulnerabilities arising from non‐Darwinian patterns of evolution.     

Cancer progression by non-clonal chromosome aberrations

The establishment of the correct conceptual framework is vital to any scientific discipline including cancer research. Influenced by hematologic cancer studies, the current cancer concept focuses on the stepwise patterns of progression as defined by specific recurrent genetic aberrations. This concept has faced a tough challenge as the majority of cancer cases follow non-linear patterns and display stochastic progression. In light of the recent discovery that genomic instability is directly linked to stochastic non-clonal chromosome aberrations (NCCAs), and that cancer progression can be characterized as a dynamic relationship between NCCAs and recurrent clonal chromosome aberrations (CCAs), we propose that the dynamics of NCCAs is a key element for karyotypic evolution in solid tumors. To support this viewpoint, we briefly discuss various basic elements responsible for cancer initiation and progression within an evolutionary context. We argue that even though stochastic changes can be detected at various levels of genetic organization, such as at the gene level and epigenetic level, it is primarily detected at the chromosomal or genome level. Thus, NCCA-mediated genomic variation plays a dominant role in cancer progression. To further illustrate the involvement of NCCA/CCA cycles in the pattern of cancer evolution, four cancer evolutionary models have been proposed based on the comparative analysis of karyotype patterns of various types of cancer.     

Cancer stem cell impact on clinical oncology

Cancer is a widespread worldwide chronic disease. In most cases, the high mortality rate from cancer correlates with a lack of clear symptoms, which results in late diagnosis for patients, and consequently, advanced tumor disease with poor probabilities for cure, since many patients will show chemo-and radio-resistance. Several mechanisms have been studied to explain chemo-and radio-resistance to anti-tumor therapies, including cell signaling pathways, anti-apoptotic mechanisms, stemness, metabolism, and cellular phenotypes. Interestingly, the presence of cancer stem cells(CSCs), which are a subset of cells within the tumors, has been related to therapy resistance. In this review, we focus on evaluating the presence of CSCs in different tumors such as breast cancer, gastric cancer, lung cancer, and hematological neoplasias, highlighting studies where CSCs were identified in patient samples. It is evident that there has been a great drive to identify the cell surface phenotypes of CSCs so that they can be used as a tool for anti-tumor therapy treatment design. We also review the potential effect of nanoparticles, drugs, natural compounds, aldehyde dehydrogenase inhibitors, cell signaling inhibitors, and antibodies to treat CSCs from specific tumors. Taken together, we present an overview of the role of CSCs in tumorigenesis and how research is advancing to target these highly tumorigenic cells to improve oncology patient outcomes.     

Cancer stem cell hypothesis: a brief summary and two proposals

The investigation and development of the cancer stem cell (CSC) model has received much focus during these years. CSC is characterized as a small fraction of cancer cells that have an indefinite ability for self-renewal and pluripotency and are responsible for initiating and sustaining of the bulk of cancer. So, whether current treatment strategies, most of which target the rapid division of cancer cells, could interfere with the slow-cycling CSCs is broadly questioned. Meanwhile, however, the new understanding of tumorigenesis has led to the development of new drug screening strategies. Both stem cells and mesenchymal stem cells have been vigorously used in pre-clinical studies of their anti-tumor potential, mainly due to their inherent tumoritropic migratory properties and their ability to carry anti-tumor transgenes. Here, based on the tumorigenic and tumoritropic characteristics of CSCs, we proposed two hypotheses exploring possible usage of CSCs as novel anti-tumor agents and potential sources for tissue regeneration. Further experimental validation of these hypotheses may unravel some new research topics.     

Pancreatic cancer stem cells and relevance to cancer treatments

Pancreatic cancer continues to be a malignancy with few therapeutic options. The majority of patients that present for an evaluation have locally advanced or metastatic disease that is incurable by surgical approaches. Chemotherapy and radiotherapy resistance of pancreatic adenocarcinomas limits the efficacy of these therapeutic approaches. Recent evidence supports the existence of human pancreatic cancer stem cells, which appear to drive tumor initiation and progression and are particularly resistant to cell death induced by radiation or chemotherapy. Understanding the mechanisms of pancreatic cancer stem cell self‐renewal and resistance to standard therapies may lead to new, more effective therapies to treat this dismal disease. J. Cell. Biochem. 107: 40–45, 2009. © 2009 Wiley‐Liss, Inc.     

Revisiting the role of lysophosphatidic acid in stem cell biology

Stem cells possess unique biological characteristics such as the ability to self-renew and to undergo multilineage differentiation into specialized cells. Whereas embryonic stem cells (ESC) can differentiate into all cell types of the body, somatic stem cells (SSC) are a population of stem cells located in distinct niches throughout the body that differentiate into the specific cell types of the tissue in which they reside in. SSC function mainly to restore cells as part of normal tissue homeostasis or to replenish cells that are damaged due to injury. Cancer stem-like cells (CSC) are said to be analogous to SSC in this manner where tumor growth and progression as well as metastasis are fueled by a small population of CSC that reside within the corresponding tumor. Moreover, emerging evidence indicates that CSC are inherently resistant to chemo- and radiotherapy that are often the cause of cancer relapse. Hence, major research efforts have been directed at identifying CSC populations in different cancer types and understanding their biology. Many factors are thought to regulate and maintain cell stemness, including bioactive lysophospholipids such as lysophosphatidic acid (LPA). In this review, we discuss some of the newly discovered functions of LPA not only in the regulation of CSC but also normal SSC, the similarities in these regulatory functions, and how these discoveries can pave way to the development of novel therapies in cancer and regenerative medicine.     

Somatic mutations and the hierarchy of hematopoiesis

Clonal disease is often regarded as almost synonymous with cancer. However, it is becoming increasingly clear that our bodies harbor numerous mutant clones that are not tumors, and mostly give rise to no disease at all. Here we discuss three somatic mutations arising within the hematopoietic system: BCR‐ABL, characteristic of chronic myeloid leukemia; mutations of the PIG‐A gene, characteristic of paroxysmal nocturnal hemoglobinuria; the V617F mutation in the JAK2 gene, characteristic of myeloproliferative diseases. The population frequencies of these three blood disorders fit well with a hierarchical model of hematopoiesis. The fate of any mutant clone will depend on the target cell and on the fitness advantage, if any, that the mutation confers on the cell. In general, we can expect that only a mutation in a hematopoietic stem cell will give long‐term disease; the same mutation taking place in a cell located more downstream may produce just a ripple in the hematopoietic ocean.