大鼠肝癌发生过程中NF-κB的表达

目的探讨核转录因子-κB(NF-κB)在大鼠肝癌发生发展中的作用和意义。方法应用免疫组织化学SP法,对二乙基亚硝胺(DEN)诱发的大鼠肝癌发生过程中NF-κB的动态表达进行了检测。结果 DEN诱发的肝癌为肝细胞癌,诱癌率为100%,大鼠肝癌癌变过程大致经过肝细胞损伤期、肝细胞增生-硬化期和肝细胞癌变期等三个阶段。在正常大鼠肝组织,偶见少量肝细胞呈阳性表达,随着肝癌发生发展,NF-κB阳性表达细胞逐渐增多,至诱癌晚期,可见大量NF-κB阳性表达细胞,均比正常肝组织表达高(P<0.05)。结论本研究表明肝细胞NF-κB的过度表达与肝癌的发生和发展密切有关。     

Can promotion of initiated cells be explained by excess replacement of radiation-inactivated neighbor cells?

Recently, the observed promotion in the clonal expansion of a two-stage cancer model was attributed to a small excess replacement probability for the initiated cells. The proposed mechanism of excess replacement was evaluated for single intermediate cells surrounded by normal cells. This paper investigates this mechanism further using the same biological parameters. If the formation of clones of intermediate cells is taken into account in a quantitative analysis of the proposed mechanism, it turns out that (1) for the initial strong increase of the promotional effect with exposure, a much larger and unlikely excess replacement probability is needed, and (2) the leveling of the promotional effect for high exposures cannot be explained by multiple normal neighbors of an intermediate cell being inactivated within one cell cycle, as it had been suggested. Perhaps these discrepancies could be partly resolved by a re-scaling of the original parameters, but this should be investigated further.     

Hepatitis C virus drives the unconstrained monoclonal expansion of VH1-69-expressing memory B cells in type II cryoglobulinemia: a model of infection-driven lymphomagenesis

Chronic hepatitis C virus infection causes B cell lymphoproliferative disorders that include type II mixed cryoglobulinemia and lymphoma. This virus drives the monoclonal expansion and, occasionally, the malignant transformation of B cells producing a polyreactive natural Ab commonly encoded by the V(H)1-69 variable gene. Owing to their property of producing natural Ab, these cells are reminiscent of murine B-1 and marginal zone B cells. We used anti-Id Abs to track the stages of differentiation and clonal expansion of V(H)1-69(+) cells in patients with type II mixed cryoglobulinemia. By immunophenotyping and cell size analysis, we could define three discrete stages of differentiation of V(H)1-69(+) B cells: naive (small, IgM(high)IgD(high)CD38(+)CD27(-)CD21(high)CD95(-)CD5(-)), "early memory" (medium-sized, IgM(high)IgD(low)CD38(-)CD27(+)CD21(low)CD95(+)CD5(+)), and "late memory" (large-sized, IgM(low)IgD(low-neg)CD38(-)CD27(low)CD21(low-neg)CD5(-)CD95(-)). The B cells expanded in cryoglobulinemia patients have a "memory" phenotype; this fact, together with the evidence for intraclonal variation, suggests that antigenic stimulation by hepatitis C virus causes the unconstrained expansion of activated V(H)1-69(+) B cells. In some cases, these cells replace the entire pool of circulating B cells, although the absolute B cell number remains within normal limits. Absolute monoclonal V(H)1-69(+) B lymphocytosis was seen in three patients with cryoglobulinemia and splenic lymphoma; in two of these patients, expanded cells carried trisomy 3q. The data presented here indicate that the hepatitis C virus-driven clonal expansion of memory B cells producing a V(H)1-69(+) natural Ab escapes control mechanisms and subverts B cell homeostasis. Genetic alterations may provide a further growth advantage leading to an overt lymphoproliferative disorder.     

A Biomathematical Modeling Approach to Explain the Phenomenon of Radiation Hormesis

This study presents an improved version of a published biomathematical model, the Random Coincidence Model-Radiation Adapted (RCM-RA). That model describes how cancer mortality increases as dose rate increases in the high-dose rate range, as well as how mortality decreases as dose rate increases in the low-dose rate range. It was assumed that low-dose rates of ionizing radiation induce cellular defense mechanisms that also prevent or repair endogenous DNA damage caused by natural cell metabolism. The model presented describes the development of cancer by a phase of initiation that consists of a series of DNA lesions in the critical regions of tumor-associated genes such as proto-oncogenes or tumor-suppressor genes. Initiated cells can divide and form a clone of initiated cells. This clonal growth is called promotion and leads to premalignant cells. Premalignant clones can sustain further genomic damage that may lead to a malignant cell and ultimately a malignant tumor. The model thereby shares structural features with Moolgavkar's two-stage clonal expansion model. It was tested on published, U-shaped data of radon exposure in U.S. homes. The model correctly reflects the ratio of endogenous DNA damage to radiation-induced damage.     

The yin-yang of PR-domain family genes in tumorigenesis

Cancer is essentially caused by alterations in normal cellular genes. Multiple gene changes involving at least two types of cancer genes, protooncogenes and tumor suppressor genes, are required for the clonal expansion of a malignant cell. This discussion focuses on the recently recognized role of a small but expanding family of PR-domain genes in tumorigenesis. The protein products of these genes are involved in human cancers in an unusual yin-yang fashion. Two products are normally produced from a PR-domain family member which differ by the presence or absence of the PR domain; the PR-plus product is disrupted or underexpressed whereas the PR-minus product is present or overexpressed in cancer cells. This imbalance in the amount of the two products, a result of either genetic or epigenetic events, appears to be an important cause of malignancy.     

Biologically based analysis of the data for the Colorado uranium miners cohort: age, dose and dose-rate effects.

This study is a comprehensive analysis of the latest follow-up of the Colorado uranium miners cohort using the two-stage clonal expansion model with particular emphasis on effects related to age and exposure. The model provides a framework in which the hazard function for lung cancer mortality incorporates detailed information on exposure to radon and radon progeny from hard rock and uranium mining together with information on cigarette smoking. Even though the effect of smoking on lung cancer risk is explicitly modeled, a significant birth cohort effect is found which shows a linear increase in the baseline lung cancer risk with birth year of the miners in the cohort. The analysis based on the two-stage clonal expansion model suggests that exposure to radon affects both the rate of initiation of intermediate cells in the pathway to cancer and the rate of proliferation of intermediate cells. However, in contrast to the promotional effect of radon, which is highly significant, the effect of radon on the rate of initiation is found to be not significant. The model is also used to study the inverse dose-rate effect. This effect is evident for radon exposures typical for mines but is predicted to be attenuated, and for longer exposures even reversed, for the more protracted and lower radon exposures in homes. The model also predicts the drop in risk with time after exposure ceases. For residential exposures, lung cancer risks are compared with the estimates from the BEIR VI report. While the risk estimates are in agreement with those derived from residential studies, they are about two- to fourfold lower than those reported in the BEIR VI report.     

Early Bioenergetic Changes in Hepatocarcinogenesis: Preneoplastic Phenotypes Mimic Responses to Insulin And Thyroid Hormone

Biochemical and molecular biological approaches in situ have provided compelling evidence for early bioenergetic changes in hepatocarcinogenesis. Hepatocellular neoplasms regularly develop from preneoplastic foci of altered hepatocytes, irrespective of whether they are caused by chemicals, radiation, viruses, or transgenic oncogenes. Two striking early metabolic aberrations were discovered: (1) a focal excessive storage of glycogen (glycogenosis) leading via various intermediate stages to neoplasms, the malignant phenotype of which is poor in glycogen but rich in ribosomes (basophilic), and (2) an accumulation of mitochondria in so-called oncocytes and amphophilic cells, giving rise to well-differentiated neoplasms. The metabolic pattern of human and experimentally induced focal hepatic glycogenosis mimics the phenotype of hepatocytes exposed to insulin. The conversion of the highly differentiated glycogenotic hepatocytes to the poorly differentiated cancer cells is usually associated with a reduction in gluconeogenesis, an activation of the pentose phosphate pathway and glycolysis, and an ever increasing cell proliferation. The metabolic pattern of preneoplastic amphophilic cell populations has only been studied to a limited extent. The few available data suggest that thyromimetic effects of peroxisomal proliferators and hepadnaviral infection may be responsible for the emergence of the amphophilic cell lineage of hepatocarcinogenesis. The actions of both insulin and thyroid hormone are mediated by intracellular signal transduction. It is, thus, conceivable that the early changes in energy metabolism during hepatocarcinogenesis are the consequence of alterations in the complex network of signal transduction pathways, which may be caused by genetic as well as epigenetic primary lesions, and elicit adaptive metabolic changes eventually resulting in the malignant neoplastic phenotype.     

An immunocytochemical study of normal and abnormal human cerebrospinal fluid with monoclonal antibodies to glial fibrillary acidic protein

The presence of astrocytes in the cerebrospinal fluid (CSF) of patients may be of diagnostic importance. However, the frequency with which astrocytes are shed into normal and abnormal human CSF is unknown. This issue was studied using monoclonal antibodies to an astrocyte-specific antigen, glial fibrillary acidic protein (GFAP), and immunoperoxidase cytochemistry. The study was prospectively conducted on 108 CSF preparations diagnosed as normal, reactive, metastatic malignancy or suspicious for metastatic malignancy. To validate these methods, cells from a clonal human glioma cell line, which contains astrocytes rich in GFAP, were processed in a manner identical to that used for the CSFs obtained from patients. Studies of the human glioma cell line demonstrated intense GFAP immunoreactivity in the majority of the malignant astrocytes. In contrast, none of the CSFs contained GFAP-positive cells. We conclude that immunocytochemical methods can detect GFAP in neoplastic human astrocytes but that nonneoplastic GFAP-positive cells are uncommon in human CSF; such cells were not seen in our large series of normal and abnormal human CSFs. The immunocytochemical detection of GFAP may be a useful criterion for distinguishing malignant astrocytes from other types of malignant cells in human CSF.     

The Wellcome Foundation lecture, 1986. The molecular regulators of normal and leukaemic blood cells

The development of a cell-culture system for the cloning and clonal differentiation of different types of blood cell has made it possible to identify: (i), the proteins that regulate growth and differentiation of different cell lineages in normal and leukaemic blood cells; (ii), the molecular basis of normal and abnormal control of cell development in blood-forming tissue; and (iii), how to suppress malignancy in leukaemic cells. By using myeloid blood cells as a model system, it has been shown that normal blood cells require different proteins to induce cell viability and multiplication (growth-inducers) and differentiation (differentiation-inducers), that there is a hierarchy of growth-inducers which act at various stages of cell development, and that a growth-inducer can switch on production of a differentiation-inducer. Gene cloning has established a multigene family for these proteins. Identification of these proteins and their interaction has shown how growth and differentiation are regulated in normal development and demonstrated the mechanisms that uncouple growth and differentiation so as to produce malignant cells. Normal cells require an external source of growth-inducing protein for cell viability and multiplication. Cells can become leukaemic by genetically changing this normal requirement for growth without blocking response to normal differentiation-inducers. The mature cells induced by adding these normal protein-inducers are then no longer malignant. Other genetic changes which inhibit differentiation by the normal blood-cell regulatory proteins can occur in the evolution of leukaemia. But even these leukaemic cells may still be induced to differentiate by other compounds that can induce differentiation by alternative pathways. The differentiation of leukaemic to mature cells, which stops the cells from multiplying, results in the suppression of malignancy by bypassing genetic changes that produce the malignant phenotype. The activity of blood-cell growth- and differentiation-inducing proteins has been shown in culture and in the body. They can, therefore, be clinically useful to correct defects in the development of normal and leukaemic blood cells.     

Application of a color-shift model with heterogeneous growth to a rat hepatocarcinogenesis experiment

Several hypotheses are established to describe the formation and progression of foci of altered hepatocytes (FAH). A common model of hepatocarcinogenesis is the mutation model (MM), which is based on the assumption that cells have to undergo multiple successive changes on their way from the normal to the malignant stage. This model describes growth and phenotype change of foci on the cellular level and is based on the assumption that single cells change their phenotype through mutation into the next stage and proliferate according to a linear stochastic birth-death process. In contrast, the color-shift model (CSM) was introduced by Kopp-Schneider et al. to describe that whole colonies of altered hepatocytes simultaneously alter their phenotype. In this paper two modifications of the color-shift model are considered which allow the growth rate to vary from focus to focus. All four models are compared with respect to their ability to predict number and radii of foci in a rat hepatocarcinogenesis experiment, in which rats were treated with the carcinogens N-nitrosomorpholine, 2-acetylaminofluoren and Phenobarbital. Maximum likelihood parameter estimates are given, and predicted and empirical FAH size distributions are visualized. The Cramer-von-Mises distance is used as a measure for the discrepancy between empirical and theoretical size distributions.     

乙型肝炎病毒驱动甲胎蛋白表达诱导肝细胞恶性转化的分子机制

肝癌细胞的恶性转化与感染乙型肝炎病毒（hepatitis B virus, HBV）和丙型肝炎病毒密切相关．但是HBV没有直接诱导肝癌发生的生物学功能,HBV可通过其x蛋白（HBx）激活生长信号,促进癌基因的表达从而诱导肝细胞恶性转化．在肝细胞恶性转化过程的早期,甲胎蛋白（alpha fetoprotein, AFP）基因被激活,而AFP能激发PI3K/AKT信号传递,由于PI3K/AKT信号途径具有促进细胞恶性转化的作用,所以AFP的表达在HBV诱导肝细胞恶性转化过程发挥关键性作用．本文就HBV通过优先驱动AFP表达促进肝癌细胞增殖和自然重编程从而诱发肝癌的分子机制进行阐述,对认识AFP在HBV相关性肝癌发生过程中的作用以及预警肝癌发生有重要的科学意义．     

Purification of Bone Marrow Clonal Cells from Patients with Myelodysplastic Syndrome via IGF-IR

Malignant clonal cells purification can greatly benefit basic and clinical studies in myelodysplastic syndrome (MDS). In this study, we investigated the potential of using type 1 insulin-like growth factor receptor (IGF-IR) as a marker for purification of malignant bone marrow clonal cells from patients with MDS. The average percentage of IGF-IR expression in CD34⁺ bone marrow cells among 15 normal controls was 4.5%, 70% of which also express the erythroid lineage marker CD235a. This indicates that IGF-IR mainly express in erythropoiesis. The expression of IGF-IR in CD34⁺ cells of 55 MDS patients was significantly higher than that of cells from the normal controls (54.0 vs. 4.5%). Based on the pattern of IGF-IR expression in MDS patients and normal controls, sorting of IGF-IR-positive and removal of CD235a-positive erythroid lineage cells with combination of FISH detection were performed on MDS samples with chromosomal abnormalities. The percentage of malignant clonal cells significantly increased after sorting. The enrichment effect was more significant in clonal cells with a previous percentage lower than 50%. This enrichment effect was present in samples from patients with +8, 5q-/-5, 20q-/-20 or 7q-/-7 chromosomal abnormalities. These data suggest that IGF-IR can be used as a marker for MDS bone marrow clonal cells and using flow cytometry for positive IGF-IR sorting may effectively purify MDS clonal cells.     

B‐cell acute lymphoblastic leukaemia: towards understanding its cellular origin

B‐cell acute lymphoblastic leukaemia (B‐ALL) is a clonal malignant disease originated in a single cell and characterized by the accumulation of blast cells that are phenotypically reminiscent of normal stages of B‐cell differentiation. B‐ALL origin has been a subject of continuing discussion, given the fact that human disease is diagnosed at late stages and cannot be monitored during its natural evolution from its cell of origin, although most B‐ALLs probably start off with chromosomal changes in haematopoietic stem cells. However, the cells responsible for maintaining the disease appear to differ between the different types of B‐ALLs and this remains an intriguing and exciting topic of research, since these cells have been posited to be responsible for resistance to conventional therapies, recurrence and dissemination. During the last years this problem has been addressed primarily by transplantation of purified subpopulations of human B‐ALL cells into immunodeficient mice. The results from these different reconstitution experiments and their interpretations are compared in this review in the context of normal B‐cell developmental plasticity. While the results from different research groups might appear mutually exclusive, we discuss how they could be reconciled with the biology of normal B‐cells and propose research avenues for addressing these issues in the future.     

Promotion of initiated cells by radiation-induced cell inactivation

Cells on the way to carcinogenesis can have a growth advantage relative to normal cells. It has been hypothesized that a radiation-induced growth advantage of these initiated cells might be induced by an increased cell replacement probability of initiated cells after inactivation of neighboring cells by radiation. Here Monte Carlo simulations extend this hypothesis for larger clones: The effective clonal expansion rate decreases with clone size. This effect is stronger for the two-dimensional than for the three-dimensional situation. The clones are irregular, far from a circular shape. An exposure-rate dependence of the effective clonal expansion rate could come in part from a minimal recovery time of the initiated cells for symmetric cell division.     

Heterogeneity of cancer risk due to stochastic effects: emphasis on radiation-induced effects

Persons with exactly the same genetic background, behavior and environment may differ in radiation cancer risk, due to the stochastic nature of cancer development. These differences are estimated quantitatively by means of the two stage clonal expansion model, in which the number of intermediate cells on their way to malignancy varies stochastically between individuals. For liver cancer after injection of Thorotrast, the estimated relative risk for persons without intermediate cells at age 40 is a factor of more than 10 larger than that for persons with a large number of intermediate cells. The population-based estimate of the relative risk represents an underestimation for most persons at most ages, because for persons showing a large number of intermediate cells liver cancer is not a rare disease.     

Cell differentiation and malignancy

An understanding of the mechanism that controls growth and differentiation in normal cells would seem to be an essential requirement to elucidate the origin and reversibility of malignancy. For this approach I have mainly used normal and leukemic blood cells, and in most studies have used myeloid blood cells as a model system. Our development of systems for the in vitro cloning and clonal differentiation of normal blood cells made it possible to study the controls that regulate growth (multiplication) and differentiation of these normal cells and the changes in these controls in leukemia. Experiments with normal blood cell precursors have shown that normal cells require different proteins to induce growth and differentiation. We have also shown that in normal myeloid precursors, growth-inducing protein induces both growth and production of differentiation-inducing protein so this ensures the coupling between growth and differentiation that occurs in normal development. The origin of malignancy involves uncoupling of growth and differentiation. This can be produced by changes from inducible to constitutive expression of specific genes that result in asynchrony to the coordination required for the normal developmental program. Normal myeloid precursors require an external source of growth-inducing protein for growth, and we have identified different types of leukemic cells. Some no longer require and other constitutively produce their own growth-inducing protein. But addition of the normal differentiation-inducing protein to these malignant cells still induces their normal differentiation, and the mature cells are then no longer malignant. Genetic changes that produce blocks in the ability to be induced to differentiate by the normal inducer occur in the evolution of leukemia. But even these cells can be induced to differentiate by other compounds, including low doses of compounds now being used in cancer therapy, that induce the differentiation program by other pathways. This differentiation of leukemic cells has been obtained in vitro and in vivo, and our in vivo results indicate that this may be a useful approach to therapy. In some tumours, such as sarcomas, reversion from a malignant to a non-malignant phenotype can be a result of chromosome changes that suppress malignancy. But in myeloid leukemia, the stopping of growth in mature cells by induction of differentiation bypasses the genetic changes that produce the malignant phenotype. These conclusions can also be applied to other types of normal and malignant cells.