Current status and issues in cancer stem cell study

Cancer stem cells (CSCs) have been positively identified and successfully isolated from some but not all cancers. The studies on CSCs to date suggest that these cells are rare among the tumor cell population, and they are capable of self-renewing and maintaining tumor growth and heterogeneity. Therapies aimed at CSCs have shown some promise, but their further development will require a more thorough understanding of the biology of CSCs and methods for identifying and isolating this cell subpopulation. This review examines what is known to date regarding the similarities and differences between cancer and somatic stem cells: CSC surface marker development and cell isolation (including a model isolation from our lab), the frequency, potential origin, and signal transduction of CSCs, and the current state of CSC-targeting therapeutic strategies.     

Sequencing of breast cancer stem cell populations indicates a dynamic conversion between differentiation states in vivo

Introduction

The cancer stem cell model implies a hierarchical organization within breast tumors maintained by cancer stem-like cells (CSCs). Accordingly, CSCs are a subpopulation of cancer cells with capacity for self-renewal, differentiation and tumor initiation. These cells can be isolated through the phenotypic markers CD44+/CD24-, expression of ALDH1 and an ability to form nonadherent, multicellular spheres in vitro. However, controversies to describe the stem cell model exist; it is unclear whether the tumorigenicity of CSCs in vivo is solely a proxy for a certain genotype. Moreover, in vivo evidence is lacking to fully define the reversibility of CSC differentiation.

Methods

In order to answer these questions, we undertook exome sequencing of CSCs from 12 breast cancer patients, along with paired primary tumor samples. As suggested by stem classical cell biology, we assumed that the number of mutations in the CSC subpopulation should be lower and distinct compared to the differentiated tumor cells with higher proliferation.

Results

Our analysis revealed that the majority of somatic mutations are shared between CSCs and bulk primary tumor, with similar frequencies in the two.

Conclusions

The data presented here exclude the possibility that CSCs are only a phenotypic consequence of certain somatic mutations, that is a distinct and non-reversible population of cells. In addition, our results imply that CSCs must be a population of cells that can dynamically switch from differentiated tumor cells, and vice versa. This finding increases our understanding of CSC function in tumor heterogeneity and the importance of identifying drugs to counter de-differentiation rather than targeting CSCs.     

Can lung cancer stem cells be targeted for therapies?

Lung cancer is the leading cause of cancer death, with a poor prognosis. Lung cancer stem cells (CSCs) are proposed as one of therapeutic targets for lung cancer. It is important to understand the exact role of lung CSC subpopulations in tumor initiation, recurrence, drug resistance and metastasis and explore biomarkers, signaling pathways and differentiation regulation specific to lung CSCs. Numerous measures targeting lung CSCs, e.g. genomics, proteomics and bioinformatics, have been used to investigate molecular mechanisms, eradicate cancer cells, and improve patient outcome. The present review overviewed the biological functions, biomarkers, signal pathways, differentiation regulation, genomics and proteomics, targeting roles of lung CSCs and related information on other CSCs as references. There are still a number of challenges to translate the research and understanding of lung CSCs to clinical applications and therapies, identify lung CSCs-specific and dynamic network biomarkers, study lung CSCs isolated from human samples, and clarify the source of lung CSCs. It is necessary to design effective therapies to target CSC biomarkers and signaling pathways, reverse drug resistance and induce differentiation of lung CSCs. Thus, lung CSCs as one of therapeutic target candidates for lung cancer need global forces and databases to integrate the genes, proteins, receptors, signal pathways and functions with clinical informatics and phenotypes together.     

Breast Cancer Heterogeneity: Need to Review Current Treatment Strategies

Although the heterogeneity of breast cancer has long been recognized, the hierarchical organization and existence of tumor initiating subpopulation within breast tumors was not known until the last decade. These tumor initiating cells called cancer stem cells (CSCs) display features of stem cells such as unlimited ability to self-renew and lineage differentiation. Accumulating evidence now suggests that by virtue of their relative resistance to both radiation and chemotherapy, these cells contribute to resistance and relapse following therapy. Utilizing cell cultures and mouse xenograft models, we and others demonstrated that breast CSCs have far greater invasive and metastatic potential than differentiated tumor cells which comprise the tumor bulk. Altogether, these studies suggest that targeting and elimination of breast CSCs may be required to improve patient outcome. In this review, we will discuss recent developments in breast CSC research and advances in CSC specific targeted therapies that are in preclinical and clinical trials.     

Metastasis blood test by flow cytometry: In vivo cancer spheroids and the role of hypoxia

Cancer hypoxia correlates with therapeutic resistance and metastasis, suggesting that hypoxic adaptation is a critical survival advantage for cancer stem cells (CSCs). Hypoxic metabolism, however, may be a disadvantage in aerobic circulation as the extremely low incidence of metastasis—compared to the high circulating tumor‐cell numbers (CTCs)—appears to suggest. As rare metastatic CSCs still survive, we searched for a mechanism that protects them from oxygen in circulation. CSCs form multicellular spheroids in vitro from virtually all cancers tested. We asked, therefore, whether cancers also form spheroids in vivo and whether circulating spheroids play a role in metastasis. We used metabolic, apoptotic and hypoxia assays, we measured aerobic barriers and calculated hypoxia vs. spheroid‐size correlations. We detected metabolic/oxidative stress in spheroids, we found correlation between stem cell presence and hypoxia and we showed that the size of hypoxic spheroids is compatible with circulation. To detect spheroids in patients, we worked out a new light‐scatter flow cytometry blood test and assayed 67 metastatic and control cases. We found in vivo spheroids with positive stem cell markers in cancer blood and they showed exclusive correlation with metastasis. In conclusion, our data suggest that metastatic success depends on CSC‐association with in vivo spheroids. We propose that the mechanism involves a portable “micro‐niche” in spheroids that may support CSC‐survival/adaptation in circulation. The new assay may establish a potential early marker of metastatic progression.     

Stem cells in breast tumours: Are they ready for the clinic?

The concept of stem-like cells in cancer has been gaining currency over the last decade or so since evidence for stem cell activity in human leukaemia and solid tumours, including breast cancer, was first published. The evidence established that sub-populations of cells identified by antibodies to cell surface markers behaved like developmental stem cells in their capacity to re-grow the human tumour for several generations in experimental immune-deficient hosts. The experiments established that cells with tumourigenic capacity expressed ‘cancer stem cell’ (CSC) markers and that activity could also be measured by self-renewal of tumour sphere colonies in culture. In breast and other cancers, there is good evidence that CSCs are relatively resistant to radio- and chemotherapy indicating that novel CSC-targeted therapies are needed. Several pathways are promising targets in breast CSCs. There are several ways of combating CSC activity including inducing their apoptosis, inhibiting stem cell self-renewal to either stop their division or to promote their differentiation, or targeting the CSC niche that supports them. The first challenge for developing novel CSC therapies is to ascertain which of these CSC properties is being targeted. The second challenge is to determine suitable CSC biomarkers to measure the efficacy of the novel CSC therapies. We propose using biomarkers as a means to identify and assess CSC activity in clinical trials. This is likely to be demanding but feasible in the near future. Thus, we asked if CSCs are ready for the clinic, however, the emerging question becomes: is the clinic ready for cancer stem cells?     

First among equals: the cancer cell hierarchy

Primary cancer cells exhibit heterogeneity in their proliferative ability. The cancer stem cell (CSC) model accounts for this heterogeneity by proposing that each cancer consists of a small population of CSCs that are capable of unlimited growth and self-renewal and a much larger population of cells, descendants of the CSCs, that have lost self-renewal capacity. The CSC model has important implications for cancer therapy. Eradication of CSCs, the cells responsible for maintenance of the neoplasm, would be necessary and sufficient to achieve cure. By extension, both the frequency of stem cells in a tumor and their propensity to undergo self-renewal (P_sr) would have a direct impact on the curability of that tumor. The P_sr is a critical biological characteristic of CSCs—small differences in P_sr have enormous impact on the probability of success in cancer therapy. Differentiation therapy, defined as treatment that reduces the P_sr of CSCs, is one approach to targeting CSCs.     

Implications of cancer stem cells in the treatment of cancer

Identification of cancer stem cells (CSCs) in both hematological and solid malignancies suggests that CSCs may be a common phenomenon for most malignancies. Similarly to normal stem cells, CSCs can self-renew and differentiate into progeny cancer cells. Almost all current therapy against cancer targets differentiated cancer cells. CSCs are more resistant to therapy secondary to quiescence, increased expression of antiapoptotic proteins and drug efflux transporters. In this article, we review the current status of CSC research and propose the targeting of CSC cell-surface molecules, signal transduction pathways, the stem cell niche, stem cell differentiation and drug resistance.     

Cancer stem cell niche: the place to be

Tumors are being increasingly perceived as abnormal organs that, in many respects, recapitulate the outgrowth and differentiation patterns of normal tissues. In line with this idea is the observation that only a small fraction of tumor cells is capable of initiating a new tumor. Because of the features that these cells share with somatic stem cells, they have been termed cancer stem cells (CSC). Normal stem cells reside in a "stem cell niche" that maintains them in a stem-like state. Recent data suggest that CSCs also rely on a similar niche, dubbed the "CSC niche," which controls their self-renewal and differentiation. Moreover, CSCs can be generated by the microenvironment through induction of CSC features in more differentiated tumor cells. In addition to a role in CSC maintenance, the microenvironment is hypothesized to be involved in metastasis by induction of the epithelial-mesenchymal transition, leading to dissemination and invasion of tumor cells. The localization of secondary tumors also seems to be orchestrated by the microenvironment, which is suggested to form a premetastatic niche. Thus, the microenvironment seems to be of crucial importance for primary tumor growth as well as metastasis formation. Combined with its role in the protection of CSCs against genotoxic insults, these data strongly put forward the niche as an important target for novel therapies.     

MicroRNA regulation of cancer stem cells

Cancer stem cells (CSC), or cancer cells with stem cell properties, have been reported in many human tumors and are thought to be responsible for tumor initiation, therapy resistance, progression, relapse, and metastasis. Despite their potential clinical importance, how CSCs are regulated at the molecular level is not well understood. MicroRNAs (miRNA), small noncoding RNAs that play critical roles in normal stem cell functions during development, have emerged as important regulators of CSCs as well. In this review, we summarize the current major findings of miRNA regulation of various CSCs and discuss our recent findings that miR-34a suppresses prostate CSCs and metastasis by directly repressing CD44. This recent progress has important implications for understanding how CSCs are intricately regulated by networks of miRNAs and for developing novel mechanism-based miRNA therapeutics that specifically target CSCs.     

Differentiation and transdifferentiation potentials of cancer stem cells

Tumor cells actively contribute to constructing their own microenvironment during tumorigenesis and tumor progression. The tumor microenvironment contains multiple types of stromal cells that work together with the extracellular matrix and local and systemic factors to coordinately contribute to tumor initiation and progression. Tumor cells and their stromal compartments acquire many genetic and/or epigenetic alternations to facilitate tumor growth and metastasis. The cancer stem cell (CSC) concept has been widely applied to interpreting tumor initiation, growth, metastasis, dormancy and relapse. CSCs have differentiation abilities to generate the original lineage cells that are similar to their normal stem cell counterparts. Interestingly, recent evidence demonstrates that CSCs also have the potential to transdifferentiate into vascular endothelial cells and pericytes, indicating that CSCs can transdifferentiate into other lineage cells for promoting tumor growth and metastasis in some tissue contexts instead of only recruiting stromal cells from local or distant tissues. Although the transdifferentiation of CSCs into tumor stromal cells provides a new dimension that explains tumor heterogeneity, many aspects of CSC transdifferentiation remain elusive. In this review, we summarize the multi-lineage differentiation and transdifferentiation potentials of CSCs as well as discuss their potential contributions to tumor heterogeneity and tumor microenvironment in tumor progression.     

Human renal cancer stem cells

Cancer stem cells (CSCs), isolated in renal carcinomas, exhibit tumor-initiating capabilities and pluripotency. No specific CSC markers have been identified so far; therefore, their characterization is mainly based on functional studies. As they are resistant to chemo and radio therapy, renal CSCs may have a relevant role in tumor establishment, progression, and recurrence. CSCs were also shown to contribute to intra-tumor vasculogenesis through an endothelial differentiation and to favor the generation of the pre-metastatic niche through the release of exosomes/microvesicles.     

肿瘤干细胞的临床意义

肿瘤干细胞(cancer stem cell, CSC)是近年来在许多肿瘤组织中发现的一类特殊干细胞。肿瘤干细胞具有自我更新和分化的能力,可以通过不断分化肿瘤细胞使新的肿瘤产生;肿瘤干细胞具有很强的耐药性和放射抗拒,这可以用来解释肿瘤的复发和转移。肿瘤干细胞可用于对肿瘤的诊断和治疗：通过对肿瘤干细胞标志物的鉴定可实现对一些肿瘤的早期诊断;一些新的治疗手段则通过作用于肿瘤干细胞的信号转导途径、表面标记和其生存的微环境,以及诱导其分化,从而达到靶向治疗肿瘤的目的。深入研究肿瘤干细胞的耐药性以及确定更多的肿瘤干细胞标志物,可为肿瘤治疗提供新途径。     

Ovarian cancer stem cells: Working towards the root of stemness

Despite medical advances made over the past decade, ovarian cancer remains one of the more lethal gynecologic cancers in the United States. While current therapeutic strategies are relatively effective, there is a high incidence of recurrent chemoresistant disease. This has been attributed, in part, to a regenerative tumor cell sub-population that has acquired stem cell properties which allows these cells to escape standard chemotherapeutics and drive recurrent disease. To date, a number of laboratories have identified these cancer stem cell (CSC) sub-populations in ovarian cancer cell lines, tumors or ascites and the collective findings suggest ovarian CSCs are likely to be as heterogeneous as the disease itself. Moreover, the multiple ovarian histophenotypes and possible sites of disease origin together with the potential for differential hierarchal contributions of multiple CSCs populations represent significant challenges to the identification, functional characterization and therapeutic targeting of ovarian CSC. This review will highlight the markers and methodology currently used to identify and isolate these cells. We will discuss some of the underlying ovarian CSC biology, the signaling pathways implicated in their survival, replication and differentiation and potential therapeutic targeting strategies.     

肿瘤干细胞的来源

肿瘤干细胞是肿瘤演化的单位,阐明肿瘤干细胞的来源对于肿瘤的防治有重要意义.综合近年相关文献和工作中的体会探讨肿瘤干细胞的可能来源、产生途径和机制.正常干细胞转化为肿瘤干细胞需要经历漫长的基因突变积累过程;诱导重编程形成多潜能干细胞是体细胞产生肿瘤干细胞的可能途径之一;肿瘤细胞返分化为肿瘤干细胞是肿瘤干细胞来源之一;上皮-间充质转换(EMT)是细胞可塑性的重要机制,在肿瘤细胞转移和肿瘤细胞干性形成中起重要作用,细胞融合诱导EMT可能是肿瘤干细胞形成的另一重要机制;此外,一些病毒感染可能与肿瘤干细胞形成相关.文章对肿瘤生物学性状复杂性的机制也进行了讨论.     

Concepts of human leukemic development

Two fundamental problems in cancer research are identification of the normal cell within which cancer initiates and identification of the cell type capable of sustaining the growth of the neoplastic clone. There is overwhelming evidence that virtually all cancers are clonal and represent the progeny of a single cell. What is less clear for most cancers is which cells within the tumor clone possess tumorigenic or 'cancer stem cell' (CSC) properties and are capable of maintaining tumor growth. The concept that only a subpopulation of rare CSC is responsible for maintenance of the neoplasm emerged nearly 50 years ago. Testing of this hypothesis is most advanced for the hematopoietic system due to the establishment of functional in vitro and in vivo assays for stem and progenitor cells at all stages of development. This body of work led to conclusive proof for CSC with the identification and purification of leukemic stem cells capable of repopulating NOD/SCID mice. This review will focus on the historical development of the CSC hypothesis, the mechanisms necessary to subvert normal developmental programs, and the identification of the cell in which these leukemogenic events first occur.     

Breast cancer stem cells and epithelial mesenchymal plasticity – Implications for chemoresistance

Tumour heterogeneity is a key characteristic of cancer and has significant implications relating to tumour response to chemotherapy as well as patient prognosis and potential relapse. It is being increasingly accepted that tumours are clonal in origin, suggestive of a tumour arising from a deregulated or mutated cell. Cancer stem cells (CSC) possess these capabilities, and with appropriate intracellular triggers and/or signalling from extracellular environments, can purportedly differentiate to initiate tumour formation. Additionally through epithelial mesenchymal plasticity (EMP), where cells gain and maintain characteristics of both epithelial and mesenchymal cell types, epithelial-derived tumour cells have been shown to de-differentiate to acquire cancer stem attributes, which also impart chemotherapy resistance. This new paradigm places EMP centrally in the process of tumour progression and metastasis, as well as modulating drug response to current forms of chemotherapy. Furthermore, EMP and CSCs have been identified in cancers arising from different tissue types making it a possible generic therapeutic target in cancer biology. Using breast cancer (BrCa) as an example, we summarise here the current understanding of CSCs, the role of EMP in cancer biology – especially in CSCs and different molecular subtypes, and the implications this has for current and future cancer treatment strategies.     

Stem cell-like cancer cells in cancer cell lines

Both stem cells and cancer cells are thought to be capable of unlimited proliferation. Moreover, a small number of cancer cells express stem cell markers, including CD133 and ATP-binding cassette transporters, by which the cells can pump out specific fluorescence dyes, such as Hoechst33342, as well as anti-cancer drugs, suggesting that either cancer cells resemble stem cells or cancers contain stem cell-like cancer cells, called "cancer stem cells (CSCs)". Using the common characteristics of tissue-specific stem cells, it was demonstrated that many types of tumors and cancer cell lines contain CSCs, which self-renew, express stem cell markers, and are tumorigenic. It was also shown that CSCs are resistant to anti-cancer drugs and irradiation. Thus CSCs might be a crucial target for the therapy. Because tumors contain CSCs and recruited normal stem cells, both of which contribute to tumorigenesis, it is difficult to separate CSCs from tumors. By contrast, cancer cell lines do not have any contaminating normal stem cells that quickly loose mulitpotentiality and differentiate in normal culture condition, suggesting that cancer cell lines could be an attractive alternative source of cells for CSC research. In this review I summarize the recent progress in CSC research using cancer cell lines.