Identification of ABCG2⁺ cells in nasopharyngeal carcinoma cells

Tumor stem cells are a small subset of tumor cells with the ability of self-renewal and differentiation and are regarded as a cause of tumor growth and recurrence. Previously we have shown that stem-like label-retaining cells (LRCs) can be detected in nasopharynx, tongue, esophagus and xenograft tumors formed by nasopharyngeal carcinoma (NPC) cell lines (5-8F, 6-10B and TMNE). The present study aimed to identify ABCG2? cells in 5-8F NPC cells and compare their tumorigenic potential with ABCG2? cells, expecting that we can obtain insight into the mechanism of the differential phenotypes of ABCG2? and ABCG2? cells. By using magnetic cell sorting (MACS) method, we isolated ABCG2? cells and ABCG2? cells from 5-8F cells. Among these two subpopulations and unsorted 5-8F cells, the rate of ABCG2? cells at G1 phase was highest, while the rate of ABCG2? cells at S phase was highest, indicating that ABCG2? cells were mostly quiescent. However, ABCG2? cells showed lower cloning efficiency and tumorigenicity than ABCG2? cells. We also used Affymetrix U133 plus 2.0 human whole genome expression chip to identify the gene expression profile of ABCG2? and ABCG2? cells and found that both subpopulations expressed some stem cell associated genes, e.g., PSCA, ABCG2 and ALPI were expressed in ABCG2? cells, and K19, integrin α6, integrin β4, CD44 and K14 were expressed in ABCG2? cells, suggesting there were stem cells in both ABCG2? and ABCG2? cells. Our data demonstrated that there exist ABCG2? cells in NPC cells, but ABCG2 alone is not sufficient for isolating cancer stem cells in 5-8F NPC cells.     

Stem cells of ependymoma

Ependymomas are tumours that arise throughout the central nervous system. Little is known regarding the aberrant cellular and molecular processes that generate these tumours.[第一段]     

Tumor-evoked regulatory B cells promote breast cancer metastasis by converting resting CD4⁺ T cells to T-regulatory cells

Pulmonary metastasis of breast cancer requires recruitment and expansion of T-regulatory cells (Treg) that promote escape from host protective immune cells. However, it remains unclear precisely how tumors recruit Tregs to support metastatic growth. Here we report the mechanistic involvement of a unique and previously undescribed subset of regulatory B cells. These cells, designated tumor-evoked Bregs (tBreg), phenotypically resemble activated but poorly proliferative mature B2 cells (CD19(+) CD25(High) CD69(High)) that express constitutively active Stat3 and B7-H1(High) CD81(High) CD86(High) CD62L(Low) IgM(Int). Our studies with the mouse 4T1 model of breast cancer indicate that the primary role of tBregs in lung metastases is to induce TGF-β-dependent conversion of FoxP3(+) Tregs from resting CD4(+) T cells. In the absence of tBregs, 4T1 tumors cannot metastasize into the lungs efficiently due to poor Treg conversion. Our findings have important clinical implications, as they suggest that tBregs must be controlled to interrupt the initiation of a key cancer-induced immunosuppressive event that is critical to support cancer metastasis.     

NF-κB localization in multiple myeloma plasma cells and mesenchymal cells

Several reports demonstrated that the activation of Nuclear Factor-kappa B NF-κB is essential for the pathogenesis of multiple myeloma (MM). We analyzed the nuclear localization of NF-κB in MM-cells derived from 60 different patients with MM at presentation and in relapse, as well as in three myeloma cell lines. Nuclear localization (the active form) of NF-κB was detected in only one MM-sample from a refractory patient and in two samples from relapsed patients, while all the other samples, including the MM-cell lines, almost exclusively express the cytoplasmic (inactive) form of NF-κB. In mesenchymal cells from MM-patients NF-κB was clearly present in the nucleus. In addition, the proteasome inhibitor Bortezomib, which is described to antagonize NF-κB activity, had a consistent antitumor activity against both chemoresistant and chemosensitive MM-cells, regardless the NF-κB localization, thus suggesting the existence of other molecular targets of proteasome inhibitors in MM.     

Pancreatic stellate cells radioprotect pancreatic cancer cells through β1-integrin signaling

Pancreatic ductal adenocarcinoma (PDAC) is characterized by a strong desmoplastic reaction where the stromal compartment often accounts for more than half of the tumor volume. Pancreatic stellate cells (PSC) are a central mediator of desmoplasia. There is increasing evidence that desmoplasia is contributing to the poor therapeutic response of PDAC. We show that PSCs promote radioprotection and stimulate proliferation in pancreatic cancer cells (PCC) in direct coculture. Our in vivo studies show PSC-dependent radioprotection in response to a single dose and to fractionated radiation. Abrogating β1-integrin signaling abolishes the PSC-mediated radioprotection in PCCs. Furthermore, this effect is independent of PI3K (phosphoinositide 3-kinase) but dependent on FAK. Taken together, we show for the first time that PSCs promote radioprotection of PCCs in a β1-integrin-dependent manner.     

Dendritic cells: indispensable?

Dendritic cells (DCs) control the initiation and differentiation of T cells. In the steady state, DCs mediate tolerance. To achieve immunization, the tolerogenic function of DCs must be switched off by inducing their maturation with appropriate "adjuvants." Dendritic cells form a system composed of distinct subsets that differ in their expression of endocytic and signaling receptors. These subsets have different capacities to differentiate and polarize T cells and to cross-present antigen to expand CD8+ T cells. Optimization of vaccines is possible by exploiting the unique biological properties of DCs.     

Neural stem cells, tumour stem cells and brain tumours： Dangerous relationships？

Institute of Cell and Molecular Science, Barts and the London, Queen Mary School of Medicine and Dentistry, 4 Newark Street, London E1 2AT, United Kingdom. Neural stem cells （NSC） have been implicated not only in brain development and neurogenesis but also in tumourigenesis. Brain tumour stem cells （BTSC） have been isolated from several paediatric or adult human brain tumours,[第一段]     

Perforin-mediated lysis of tumor cells by Mycobacterium bovis Bacillus Calmette-Guérin-activated killer cells.

Immunotherapy with Bacillus Calmette-Guérin (BCG) is clinically established in the treatment of superficial bladder cancer. In our attempt to clarify the underlying immunological mechanism, we could previously show that stimulation of PBMC with BCG leads to the generation of cytotoxic BCG-activated killer (BAK) cells. Among others, these BAK cells as well as lymphokine-activated killer (LAK) cells have been suggested as possible effector cells during BCG therapy. To understand BCG-induced activation of effector lymphocytes more precisely, we investigated the lytic pathways of human BAK cells and compared BAK cell cytotoxicity with LAK cell cytotoxicity. Perforin and Fas ligand (FasL) are the major cytolytic molecules of cytotoxic lymphocytes. Our results demonstrate that BAK and LAK cells showed an increased expression of perforin and FasL as compared with unstimulated controls. Killing of T-24 bladder tumor as well as Jurkat cells by BAK and LAK cells was predominantly mediated via perforin as demonstrated by a drastically reduced lysis in the presence of concanamycin A and EGTA/MgCl2, respectively. In contrast, lysis (radioactive release assay) and membrane disintegration (Annexin V binding) of both targets by BAK and LAK cells could not be blocked with an inhibitory anti-FasL monoclonal antibody (NOK-1). Nevertheless, T-24 and Jurkat were susceptible to killing by recombinant soluble FasL and by Chinese hamster ovary cells expressing membrane-bound FasL. We conclude that cellular mediators of BCG effector mechanisms, such as BAK and LAK cells, kill their targets via perforin and independent of the FasL pathway. Because we also found increased numbers of perforin-expressing lymphocytes in patients after BCG therapy, our findings have potential clinical relevance because BCG therapy would not be impaired by FasL resistance of target cells, which recently has been described for some tumors.     

Sarcoma arising from Langerhans cellsĭ

A rare case of tumor arising from Langerhans cells in the tongue and neck area in a 37 year-old man is presented. It was a polymorphocellular sarcoma with bean-like twisted nuclei. Electron microscopy identified granules of Langerhans (Bierbeck), multiple tubulo-vesicular structures, ring-like plates, Golgi apparatus, lysosomes and dendritic processes. Total leukocytic antigen was assayed in tumor cells but no expression of S-100 protein found.     

Are cancer stem cells radioresistant?

Based on findings that cancer cell clonogens exhibit stem cell features, it has been suggested that cancer stem-like cells are relatively radioresistant owing to different intrinsic and extrinsic factors, including quiescence, activated radiation response mechanisms (e.g., enhanced DNA repair, upregulated cell cycle control mechanisms and increased free-radical scavengers) and a surrounding microenvironment that enhances cell survival mechanisms (e.g., hypoxia and interaction with stromal elements). However, these radiosensitivity features are probably dynamic in nature and come into play at different times during the course of chemo/radiotherapy. Therefore, different molecularly targeted radiosensitization strategies may be needed at different stages of therapy. This article describes potential sensitization approaches based on the dynamics and changing properties of cancer stem-like cells during therapy.     

Glioma stem cells： Evidence and limitation

The Rausing Laboratory, Department of Neurosurgery, Lund University Hospital, Lund, Sweden; Section of Immunology, Lund Strategic Research Center for Stem Cell Biology and Cell Therapy, Lund University, Lund, Sweden; Section of Molecular Medicine and Gene Therapy, Lund Strategic Research Center for Stem Cell Biology and Cell Therapy, Lund University, Lund, Sweden. Gliomas, in particular the high-grade anaplastic glioma and glioblastoma multiforme （GBM）, are manifested by morphological, genetic and phenotypic heterogeneity. Most of the studies hitherto have been performed on bulk glioma cells, with limited understanding on the origin and the relative contribution of particular glioma cell populations to glioma growth and progression. Recent studies have demonstrated the existence of a small fraction of glioma cells endowed with features of primitive neural progenitor cells and tumor-initiating function. Such cells have been defined as glioma stem cells. However, questions remain as to whether the currently identified glioma stem cells are the cell-of-origin for glioma initiation and progression, or the results of such processes. In this review,     

Anti-tumor cytotoxicity of γδ T cells expanded from peripheral blood cells of patients with myeloma and lymphoma

In order to establish an efficient gammadelta T cell-mediated immunotherapy for hematological malignancies, we attempted to evaluate cytotoxicity against tumor cells by gammadelta T cells, which were generated from blood cells of patients with myeloma and lymphoma by culturing with zoledronate and a low dose of IL-2. Although gammadelta T cells were expanded in patients with myeloma and lymphoma as well as normal persons, the amplification rates of gammadelta T cells before and after culturing varied from patient to patient in myeloma and lymphoma. gammadelta T cells generated in patients with myeloma and lymphoma showed a potent cytotoxic ability against myeloma/lymphoma cell lines as shown in gammadelta T cells generated in normal subjects. In addition, gammadelta T cells generated in a patient with myeloma showed a cytotoxic ability against self myeloma cells freshly prepared from bone marrow. However, the same gammadelta T cells were demonstrated to be non-cytotoxic to normal cells of the patient. These data demonstrated that gammadelta T cells, which could be expanded in vitro from blood cells of patients with myeloma and lymphoma by culturing with zoledronate and IL-2, possess a sufficient cytotoxic ability against tumor cells. These findings suggested that in vitro generated patients' gammadelta T cells could be applied to gammadelta T cell-mediated immunotherapy for hematological malignancies.     

Sialyl Tn‐expressing bladder cancer cells induce a tolerogenic phenotype in innate and adaptive immune cells

Despite the wide acceptance that glycans are centrally implicated in immunity, exactly how they contribute to the tilt immune response remains poorly defined. In this study, we sought to evaluate the impact of the malignant phenotype‐associated glycan, sialyl‐Tn (STn) in the function of the key orchestrators of the immune response, the dendritic cells (DCs). In high grade bladder cancer tissue, the STn antigen is significantly overexpressed and correlated with the increased expression of ST6GALNAC1 sialyltransferase. Bladder cancer tissue presenting elevated expression of ST6GALNAC1 showed a correlation with increased expression of CD1a, a marker for bladder immature DCs and showed concomitant low levels of Th1‐inducing cytokines IL‐12 and TNF‐α. In vitro, human DCs co‐incubated with STn+ bladder cancer cells, had an immature phenotype (MHC‐II^low, CD80^low and CD86^low) and were unresponsive to further maturation stimuli. When contacting with STn⁺ cancer cells, DCs expressed significantly less IL‐12 and TNF‐α. Consistent with a tolerogenic DC profile, T cells that were primed by DCs pulsed with antigens derived from STn⁺ cancer cells were not activated and showed a FoxP3^high IFN‐γ^low phenotype. Blockade of STn antigens and of STn⁺ glycoprotein, CD44 and MUC1, in STn⁺ cancer cells was able to lower the induction of tolerance and DCs become more mature.Overall, our data suggest that STn‐expressing cancer cells impair DC maturation and endow DCs with a tolerogenic function, limiting their capacity to trigger protective anti‐tumour T cell responses. STn antigens and, in particular, STn⁺ glycoproteins are potential targets for circumventing tumour‐induced tolerogenic mechanisms.     

Hyperthermia on mesenchymal stem cells (MSCs) can sensitize tumor cells to undergo cell death†

Hyperthermia, the procedure of raising the temperature of tumor-loaded tissue to 40°–43°C, has been applied to various established cancer treatments. Although the mechanism of hyperthermia in cancer treatment is well-known, there are few or no studies regarding the effect of hyperthermia on the tumor-supportive stroma. Mesenchymal stem cells (MSCs) display the potential for differentiation into various tissues. MSCs are also reported to play a role as potential precursors for tumor stroma in providing a favorable environment for tumor progression. Here, we investigated the effects of hyperthermia-treated MSCs on the viability and growth of cancer cells. Culture supernatants from non-shocked or heat-shocked MSCs (NS-MSCs or HS-MSCs) were added to MCF7 cells. Morphological analysis and cell proliferation assay showed the reduced viability and growth of MCF7 cells by addition of culture medium conditioned by HS-MSCs. Additionally, exposure to the conditioned medium by HS-MSCs induced cell cycle arrest at G2/M phase, increased MHC class I, Fas receptor, and TNF-R expressions, and decreased MDR1 expression in the MCF7 cells. In particular, the conditioned medium of HS-MSCs accelerated the inhibition of tumor cell growth by several chemotherapeutic drugs. These data present new aspects of hyperthermia in cancer treatment, suggesting that hyperthermia can enable tumor stroma provide a sensitizing environment for tumor cells to undergo cell death.     

Cancer stem cells in human colon cancer

Cancer is composed of heterogeneous cell populations.Not every cell in the tumor has the capacity to initiate and sustain tumor growth.It has been postulated that only a subset of cells,the so-called cancer stem cells (CSCs),are able to initiate and propagate tumor development.In two papers published on Nov.19,2006 issue of Nature(doi:10.1038/nature 05372,and doi:10.1038/nature 05384),CSCs are shown to exist in human colon cancer.CSCs have the capacity to regenerate themselves and produce non-CSC progeny.To examine whether colon     

Regulatory T (Treg) cells in cancer: Can Treg cells be a new therapeutic target?

Regulatory T (Treg) cells suppress abnormal/excessive immune responses to self‐ and nonself‐antigens to maintain immune homeostasis. In tumor immunity, Treg cells are involved in tumor development and progression by inhibiting antitumor immunity. There are several Treg cell immune suppressive mechanisms: inhibition of costimulatory signals by CD80 and CD86 expressed by dendritic cells through cytotoxic T‐lymphocyte antigen‐4, interleukin (IL)‐2 consumption by high‐affinity IL‐2 receptors with high CD25 (IL‐2 receptor α‐chain) expression, secretion of inhibitory cytokines, metabolic modulation of tryptophan and adenosine, and direct killing of effector T cells. Infiltration of Treg cells into the tumor microenvironment (TME) occurs in multiple murine and human tumors. Regulatory T cells are chemoattracted to the TME by chemokine gradients such as CCR4‐CCL17/22, CCR8‐CCL1, CCR10‐CCL28, and CXCR3‐CCL9/10/11. Regulatory T cells are then activated and inhibit antitumor immune responses. A high infiltration by Treg cells is associated with poor survival in various types of cancer. Therefore, strategies to deplete Treg cells and control of Treg cell functions to increase antitumor immune responses are urgently required in the cancer immunotherapy field. Various molecules that are highly expressed by Treg cells, such as immune checkpoint molecules, chemokine receptors, and metabolites, have been targeted by Abs or small molecules, but additional strategies are needed to fine‐tune and optimize for augmenting antitumor effects restricted in the TME while avoiding systemic autoimmunity. Here, we provide a brief synopsis of these cells in cancer and how they can be controlled to achieve therapeutic outcomes.