肿瘤干细胞及肝癌肿瘤干细胞

肿瘤干细胞理论认为只有存在于肿瘤中的少量干细胞性质的细胞群体对肿瘤发生和发展起着决定作用,肿瘤是由干细胞突变积累而形成的无限增殖的异常组织,这一理论的提出使人们对肿瘤发生机制的认识上升到了一个新的高度,也引起了研究者的广泛关注;肝癌是我国常见的恶性肿瘤之一,我国肝癌死亡率居世界之首,目前对肝癌的研究是我国恶性肿瘤防治的重点工作,现对当前肿瘤干细胞与肝癌肿瘤干细胞相关方面的最新研究进展作一概述。     

Place Cells,Grid Cells,and Memory

The hippocampal system is critical for storage and retrieval of declarative memories, including memories for locations and events that take place at those locations. Spatial memories place high demands on capacity. Memories must be distinct to be recalled without interference and encoding must be fast. Recent studies have indicated that hippocampal networks allow for fast storage of large quantities of uncorrelated spatial information. The aim of the this article is to review and discuss some of this work, taking as a starting point the discovery of multiple functionally specialized cell types of the hippocampal–entorhinal circuit, such as place, grid, and border cells. We will show that grid cells provide the hippocampus with a metric, as well as a putative mechanism for decorrelation of representations, that the formation of environment-specific place maps depends on mechanisms for long-term plasticity in the hippocampus, and that long-term spatiotemporal memory storage may depend on offline consolidation processes related to sharp-wave ripple activity in the hippocampus. The multitude of representations generated through interactions between a variety of functionally specialized cell types in the entorhinal–hippocampal circuit may be at the heart of the mechanism for declarative memory formation.The scientific study of human memory started with Herman Ebbinghaus, who initiated the quantitative investigation of associative memory processes as they take place (Ebbinghaus 1885). Ebbinghaus described the conditions that influence memory formation and he determined several basic principles of encoding and recall, such as the law of frequency and the effect of time on forgetting. With Ebbinghaus, higher mental functions were brought to the laboratory. In parallel with the human learning tradition that Ebbinghaus started, a new generation of experimental psychologists described the laws of associative learning in animals. With behaviorists like Pavlov, Watson, Hull, Skinner, and Tolman, a rigorous program for identifying the laws of animal learning was initiated. By the middle of the 20th century, a language for associative learning processes had been developed, and many of the fundamental relationships between environment and behavior had been described. What was completely missing, though, was an understanding of the neural activity underlying the formation of the memory. The behaviorists had deliberately shied away from physiological explanations because of the intangible nature of neural activity at that time.Then the climate began to change. Karl Lashley had shown that lesions in the cerebral cortex had predictable effects on behavior in animals (Lashley 1929, 1950), and Donald Hebb introduced concepts and ideas to account for complex brain functions at the neural circuit level, many of which have retained a place in modern neuroscience (Hebb 1949). Both Lashley and Hebb searched for the engram, but they found no specific locus for it. A significant turning point was reached when Scoville and Milner (1957) reported severe loss of memory in an epileptic patient, patient H.M., after bilateral surgical removal of the hippocampal formation and the surrounding medial temporal lobe areas. “After operation this young man could no longer recognize the hospital staff nor find his way to the bathroom, and he seemed to recall nothing of the day-to-day events of his hospital life.” This tragic misfortune inspired decades of research on the function of the hippocampus in memory. H.M.’s memory impairment could be reproduced in memory tasks in animals and studies of H.M., as well as laboratory animals, pointed to a critical role for the hippocampus in declarative memory—memory, which, in humans, can be consciously recalled and declared, such as memories of experiences and facts (Milner et al. 1968; Mishkin 1978; Cohen and Squire 1980; Squire 1992; Corkin 2002). What was missing from these early studies, however, was a way to address the neuronal mechanisms that led information to be stored as memory.The aim of this article is to show how studies of hippocampal neuronal activity during the past few decades have brought us to a point at which a mechanistic basis of memory formation is beginning to surface. An early landmark in this series of investigations was the discovery of place cells, cells that fire selectively at one or few locations in the environment. At first, these cells seemed to be part of the animal’s instantaneous representation of location, independent of memory, but gradually, over the course of several decades, it has become clear that place cells express current as well as past and future locations. In many ways, place cells can be used as readouts of the memories that are stored in the hippocampus. More recent work has also shown that place cells are part of a wider network of spatially modulated neurons, including grid, border, and head direction cells, each with distinct roles in the representation of space and spatial memory. In this article, we shall discuss potential mechanisms by which these cell types, particularly place and grid cells, in conjunction with synaptic plasticity, may form the basis of a mammalian system for fast high-capacity declarative memory.     

Dendritic Cells and Regulatory T Cells in Atherosclerosis

Although macrophages and other immune system cells, especially T cells, have been shown to play disease-promoting roles in atherosclerosis, less is known about the role of antigen presenting cells. Functional, immune stimulating dendritic cells (DCs) have recently been detected in aortic intima, the site of origin of atherosclerosis. We had compared DCs with macrophages in mice with experimental atherosclerosis, to clearly define cell types by developmental and functional criteria. This review summarizes recent advances in studies of DCs in humans and in mouse models of atherosclerosis, as well as providing a simple strategy to measure regulatory T (Treg) cells in the mouse aorta.     

Cells and Organizers

This article evaluates historically some of the factors otherthan the new "cell biology" that have influenced embryologiststo think in terms of cells rather than supracellular agencies.Evidence of Spemann's emphasis on organizers as supracellularphenomena is presented, but it is pointed out that Spemann raisedsome cellular questions that were by-passed at the time. Vogtand others who studied morphogenetic movements in the 1920'salso considered these as supracellular processes, although Vogtpreviously (1913) had studied the movements of individual amphibianembryonic cells isolated in vitro. It is pointed out that the number of investigators who studiedisolated cells in vitro before the development of tissue culturewas considerable, including Remak (1855), Stricker (1864), andHis (1899), among others. Holtfreter observed the actions ofisolated cells from 1931 on, in part, at first, because thecells isolated themselves from cell groups in vitro. His studiesof explants, in the 1930's, 1940's, and 1950's, emphasized thatsupracellular phenomena must be explained in terms of cell properties,including membrane properties. In addition, the dramatic resultsof his experiments demonstrating affinity drew attention tocells as organized individuals, just as Spemann's experimentshad done earlier to demonstrate the integrative qualities ofembryos-as-wholes.     

Immunomodulatory Cross-Talk between Conjunctival Goblet Cells and Dendritic Cells

Goblet cells are secretory epithelial cells of mucosal tissues that confer protection from environmental agents or pathogens via expression and secretion of soluble mucins. Loss of these cells is associated with several chronic inflammatory disorders of the mucosa. Although demonstrated to transfer antigens from the luminal surface to stromal cells in the intestinal mucosa, it is not known if goblet cells contribute to the regulation of an immune response. In this study we report that similar to intestinal and respiratory mucosal epithelia, mouse ocular surface epithelia predominantly express the TGF-ß2 isoform. Specifically, we demonstrate the ability of goblet cells to express TGF-ß2 and increase it in response to Toll-Like Receptor 4 mediated stimulus in cultures. Goblet cells not only express TGF-ß2, but are also able to activate it in a thrombospondin-1 (TSP-1) dependent manner via their cell surface receptor CD36. Furthermore, goblet cell derived soluble factors that possibly include TGF-ß2, alter dendritic cell (DC) phenotype to a tolerogenic type by downregulating DC expression of MHC class II and co-stimulatory molecules CD80, CD86 and CD40. Thus our study demonstrates goblet cells as a cellular source of active TGF-ß2 in ocular mucosa and implicates their immunomodulatory function in maintaining mucosal immune homeostasis.     

MAIT Cells Detect and Efficiently Lyse Bacterially-Infected Epithelial Cells

Mucosal associated invariant T cells (MAIT) are innate T lymphocytes that detect a large variety of bacteria and yeasts. This recognition depends on the detection of microbial compounds presented by the evolutionarily conserved major-histocompatibility-complex (MHC) class I molecule, MR1. Here we show that MAIT cells display cytotoxic activity towards MR1 overexpressing non-hematopoietic cells cocultured with bacteria. The NK receptor, CD161, highly expressed by MAIT cells, modulated the cytokine but not the cytotoxic response triggered by bacteria infected cells. MAIT cells are also activated by and kill epithelial cells expressing endogenous levels of MRI after infection with the invasive bacteria Shigella flexneri. In contrast, MAIT cells were not activated by epithelial cells infected by Salmonella enterica Typhimurium. Finally, MAIT cells are activated in human volunteers receiving an attenuated strain of Shigella dysenteriae-1 tested as a potential vaccine. Thus, in humans, MAIT cells are the most abundant T cell subset able to detect and kill bacteria infected cells.     

甲肝病毒在猴胚肾细胞和Vero细胞上的分离与适应

使用恒河猴胚肾(MEK)细胞从临床标本中分离和适应了甲肝病毒W和X,通过阻断实验、中和实验、免疫荧光和免疫电镜实验、RT-PCR对其进行特异性鉴定,证明是甲肝病毒.W株和X株第7代在MEK细胞上的抗原滴度分别为1∶512、1∶1024,感染滴度(logTCID50/mL)分别为8.17、8.50.只有分离株W可以适应于Vero细胞,第6代21d抗原滴度为1∶256,感染滴度(logTCID50/mL)为8.00.     

甲肝病毒在猴胚肾细胞和Vero细胞上的分离与适应

使用恒河猴胚肾 (MEK)细胞从临床标本中分离和适应了甲肝病毒W和X ,通过阻断实验、中和实验、免疫荧光和免疫电镜实验、RT PCR对其进行特异性鉴定 ,证明是甲肝病毒。W株和X株第 7代在MEK细胞上的抗原滴度分别为 1∶5 12、1∶10 2 4,感染滴度 (logTCID50 /mL)分别为 8.17、8.5 0。只有分离株W可以适应于Vero细胞 ,第 6代 2 1d抗原滴度为 1∶2 5 6 ,感染滴度 (logTCID50 /mL)为 8.0 0。     

自然杀伤细胞和树突状细胞相互作用

近年来,自然杀伤(NK)细胞和树突状细胞(DCs)的相互作用逐渐成为免疫学领域的一个研究热点。越来越多的实验表明,两种细胞可通过细胞-细胞接触并分泌细胞因子在炎症组织和次级淋巴结中相互作用,在机体抗肿瘤、抗病毒及抗移植排斥等效应中发挥重要作用。现对NK细胞和DCs相互作用及生物学意义等方面的研究进展进行综述。     

Responsiveness of Thymus Cells to Syngeneic and Allogeneic Lymphoid Cells

THE thymus is necessary for the normal development of cell-mediated immunity in mice as shown by the immunological defects after neonatal thymectomy¹. Thymus cells themselves can be stimulated by allogeneic lymphoid cells in mixed leucocyte reaction (MLR)² and become killer cells or cytotoxic lymphocytes after stimulation with allogeneic spleen cells in vitro (H. Wagner and M. Feldmann, unpublished work) and in vivo^3,4. This suggests that the thymus as well as peripheral lymphoid tissues contain T cells which can be stimulated by foreign histocompatibility antigen to divide and differentiate into the cytotoxic lymphocytes which mediate cellular immunity. There have been suggestions that thymus cells might be stimulated to divide by “self” antigen, as well as foreign cells: incorporation of ³H-thymidine above background levels has been found in cultures with syngeneic spleen and thymus cells of adult rats⁵, although the experiments do not determine whether thymus or spleen cells have been stimulated. In contrast to these experiments, Howe et al. reported that only thymus cells of neonatal CBA mice reacted to allogeneic and syngeneic spleen cells of adult animals in “one way” MLR cultures^6,7. Whether the reaction of neonatal thymus cells to syngeneic adult spleen cells is recognition of “self” antigens is uncertain, since spleens of adult mice could carry antigens which do not occur in neonatal animals and are therefore “unknown” for neonatal thymus cells. We demonstrate here that neonatal thymus cells do not react to 4-day-old CBA spleen cells, but adult thymus cells do react against both allogeneic and syngeneic adult spleen cells.     

Metabolomic Responses of Guard Cells and Mesophyll Cells to Bicarbonate

Anthropogenic CO₂ presently at 400 ppm is expected to reach 550 ppm in 2050, an increment expected to affect plant growth and productivity. Paired stomatal guard cells (GCs) are the gate-way for water, CO₂, and pathogen, while mesophyll cells (MCs) represent the bulk cell-type of green leaves mainly for photosynthesis. We used the two different cell types, i.e., GCs and MCs from canola (Brassica napus) to profile metabolomic changes upon increased CO₂ through supplementation with bicarbonate (HCO₃ ^-). Two metabolomics platforms enabled quantification of 268 metabolites in a time-course study to reveal short-term responses. The HCO₃ ^- responsive metabolomes of the cell types differed in their responsiveness. The MCs demonstrated increased amino acids, phenylpropanoids, redox metabolites, auxins and cytokinins, all of which were decreased in GCs in response to HCO₃ ^-. In addition, the GCs showed differential increases of primary C-metabolites, N-metabolites (e.g., purines and amino acids), and defense-responsive pathways (e.g., alkaloids, phenolics, and flavonoids) as compared to the MCs, indicating differential C/N homeostasis in the cell-types. The metabolomics results provide insights into plant responses and crop productivity under future climatic changes where elevated CO₂ conditions are to take center-stage.     

Isolation of Sertoli Cells and Peritubular Cells from Rat Testes

The testis, and in particular the male gamete, challenges the immune system in a unique way because differentiated sperm first appear at the time of puberty - more than ten years after the establishment of systemic immune tolerance. Spermatogenic cells express a number of proteins that may be seen as non-self by the immune system. The testis must then be able to establish tolerance to these neo-antigens on the one hand but still be able to protect itself from infections and tumor development on the other hand. Therefore the testis is one of a few immune privileged sites in the body that tolerate foreign antigens without evoking a detrimental inflammatory immune response. Sertoli cells play a key role for the maintenance of this immune privileged environment of the testis and also prolong survival of cotransplanted cells in a foreign environment. Therefore primary Sertoli cells are an important tool for studying the immune privilege of the testis that cannot be easily replaced by established cell lines or other cellular models. Here we present a detailed and comprehensive protocol for the isolation of Sertoli cells - and peritubular cells if desired - from rat testes within a single day.     

Muller细胞与视网膜病变

视网膜是一薄而半透明的、具有多层结构的神经组织,位于眼球后2/3部的内侧面。向前延伸达睫状体,止于不规则边界。Muller细胞是脊椎动物视网膜内最主要的神经胶质细胞,它贯穿整个视网膜。Muller细胞对于维持神经元的完整性、代谢、内环境稳态以及信号转导等均具有重要的作用。在视网膜病变时,Muller细胞参与整个过程,并且在视网膜的各种疾病中都发现伴有Muller细胞的神经胶质增生反应。Muller细胞同时也调控视网膜病变的整个过程。Muller细胞膜上的神经递质受体、谷氨酸受体、门控电压通道、所合成分泌的营养因子及自的身增殖分化都发生改变。近年来人们对Muller细胞的认识越来越多,研究的方向也从细胞的微观结构、主要功能转变成Muller细胞对不同视网膜病变过程的参与调控。本文对视网膜Muller细胞的形态和生理功能,病理状况下Muller细胞发生的改变作一综述。     

Hematopoietic Stem Cells,Leukemic Stem Cells and Chronic Myelogenous Leukemia

Blood-related cancers, or leukemias, have been shown to arise from a rare subset of cells that escape normal regulation and drive the formation and growth of the tumor. The finding that these so-called cancer stem cells, or leukemic stem cells (LSC), can be purified away from the other cells in the tumor allows their precise analysis to identify candidate molecules and regulatory pathways that play a role in progression, maintenance, and spreading of leukemias. The analyses of the other, numerically dominant, cells in the tumor, while also interesting, do not directly interrogate these key properties of malignancies. Mouse models of human myeloproliferative disorder and acute myelogenous leukemia have highlighted the remarkable conservation of disease mechanisms between both species. They can now be used to identify the LSC for each type of human leukemia and understand how they escape normal regulation and become malignant. Given the clinical importance of LSC identification, the insights gained through these approaches will quickly translate into clinical applications and lead to improved treatments for human leukemias.