Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0596263 (carcinogenesis)
64,820 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Microsatellite instability (MSI) and transforming growth factor-beta receptor type II (RII) gene mutation have been reported in many types of tumors and their instance seem to vary among the tumors investigated. To determine the relation between MSI and RII gene mutation in sporadic gastrointestinal cancer development, 21 esophageal, 19 gastric, and 27 colorectal cancers were investigated. The presence of MSI was screened by single strand conformation polymorphism (SSCP) method using six microsatellite markers. RII gene mutations were detected by SSCP method and direct sequencing. MSI was detected in seven of 21 (33.3%) esophageal cancers, three of 19 (15.8%) gastric cancers and seven of 27 (25.9%) colorectal cancers. However, RII gene mutations were observed in only two of seven (28.6%) MSI-positive colorectal cancers. Our data suggest that among sporadic gastrointestinal cancers, colorectal cancers seem to be the most frequent target organ involved in carcinogenesis through RII gene mutation, which thus appears to be related to organ specificity.
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PMID:Analyses of microsatellite instability and the transforming growth factor-beta receptor type II gene mutation in sporadic human gastrointestinal cancer. 1056 95

The transforming growth factor-beta (TGF-beta) signaling pathway subserves an essential tumor suppressor function in various cell types. A heteromeric complex composed of TGF-beta type I (RI) and type II (RII) receptors is required for TGF-beta signaling. We have identified a subset of human gastric cancer cell lines which are insensitive to TGF-beta and which express a low level of TGF-beta type I receptor mRNA relative to a gastric cancer cell line which is highly responsive to TGF-beta. Using these cells, we show that hypermethylation of a CpG island in the 5' region of the TGF-beta RI gene provides another potentially important mechanism of escape from negative growth control by TGF-beta. This hypermethylation was found in four of five human gastric cancer cell lines and five out of 40 (12.5%) primary tumors examined. In human gastric cancer cell lines, treatment with the demethylating agent, 5-aza-2'-deoxycytidine, resulted in increased expression of the TGF-beta RI gene, but not the RII gene. Transient transfection of an RI expression vector into the TGF-beta resistant SNU-601 cell line restores TGF-beta responsiveness. These findings suggest that one of the mechanisms of escape from autocrine or paracrine growth control by TGF-beta during carcinogenesis could involve aberrant methylation of CpG islands in the 5' region of the TGF-beta RI gene.
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PMID:Transcriptional repression of the transforming growth factor-beta type I receptor gene by DNA methylation results in the development of TGF-beta resistance in human gastric cancer. 1060 82

Genetic inactivation of the transforming growth factor-beta (TGF-beta) signaling pathway can accelerate tumor progression in the mouse epidermal model of multistage carcinogenesis. By using an in vitro model of keratinocyte transformation that parallels in vivo malignant conversion to squamous cell carcinoma, we show that v-ras(Ha) transduced primary TGF-beta1-/- keratinocytes and keratinocytes expressing a TGF-beta type II dominant-negative receptor transgene have significantly higher frequencies of spontaneous transformation than control genotypes. Malignant transformation in the TGF-beta1-/- keratinocytes is preceded by aneuploidy and accumulation of chromosomal aberrations. Similarly, transient inactivation of TGF-beta signaling with a type II dominant-negative receptor adenovirus causes rapid changes in ploidy. Exogenous TGF-beta1 can suppress aneuploidy, chromosome breaks, and malignant transformation of the TGF-beta1-/- keratinocytes at concentrations that do not significantly arrest cell proliferation. These results point to genomic instability as a mechanism by which defects in TGF-beta signaling could accelerate tumor progression in mouse multistage carcinogenesis.
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PMID:Defects in transforming growth factor-beta signaling cooperate with a Ras oncogene to cause rapid aneuploidy and malignant transformation of mouse keratinocytes. 1061 18

The relationships between transforming growth factor-beta (TGF-beta) and cancer are varied and complex. The paradigm that is emerging from the experimental evidence accumulated over the past decade or so is that TGF-beta can play two different and opposite roles with respect to the process of malignant progression. During early stages of carcinogenesis, TGF-beta acts predominantly as a potent tumor suppressor and may mediate the actions of chemopreventive agents such as retinoids and nonsteroidal anti-estrogens. However, at some point during the development and progression of malignant neoplasms, bioactive TGF-betas make their appearance in the tumor microenvironment and the tumor cells escape from TGF-beta-dependent growth arrest. In many cases, this resistance to TGF-beta is the consequence of loss or mutational inactivation of the genes that encode signaling intermediates. These include the types I and II TGF-beta receptors, as well as receptor-associated and common-mediator Smads. The stage of tumor development or progression at which TGF-beta-resistant clones come to dominate the tumor cell population in different types of neoplasm remains to be defined. The phenotypic switch from TGF-beta-sensitivity to TGF-beta-resistance that occurs during carcinogenesis has several important implications for cancer prevention and treatment.
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PMID:TGF-beta and cancer. 1061 61

In vitro models of human prostatic carcinogenesis are increasingly available and include representatives of normal, immortal, tumorigenic and metastatic phenotypes. In this study, growth regulation of immortal, but non-tumorigenic, human papillomavirus-transformed prostatic epithelial cells was compared to that of their tumorigenic variants. These variants were created either by exposure to a carcinogen or by passage through mice. In all cases, tumorigenic cells retained responsiveness to a potent mitogen, epidermal growth factor, and to a potent growth inhibitory factor, 1,25-dihydroxyvitamin D3. Responses to other growth regulatory factors were altered. One set of transformants, CA-HPV-10 and its tumorigenic variants 5019 and 5019IIc, lost their requirement for insulin-like growth factor. Another set, RWPE-1 and its tumorigenic variant 129Nu5002-1 Tu, became unresponsive to growth inhibition by transforming growth factor-beta. The only alteration uniquely correlated with the tumorigenic phenotype was loss of response to retinoic acid. This factor, which inhibits growth of normal and immortal but non-tumorigenic prostatic epithelial cells, had no effect on tumorigenic 129Nu5002-1 Tu cells. We previously reported that conversion of an SV40-immortalized prostatic epithelial cell line to tumorigenicity by introduction of the ras oncogene also resulted in loss of responsiveness to growth inhibitory activity of retinoic acid. 129Nu5002-1 Tu cells, which do not have an altered ras gene, gained the same phenotype. This suggests that loss of inhibition by retinoic acid may be a critical element in the tumorigenic conversion of prostatic epithelial cells.
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PMID:Altered growth regulation and loss of response to retinoic acid accompany tumorigenic transformation of prostatic cells. 1062 24

Uncontrolled cellular proliferation is a hallmark of cancer. Thus, a relevant and important question is how cancer cells have escaped from normal growth regulatory mechanisms to become malignant and, further, what events favor progression and metastasis. Growth regulatory proteins of the transforming growth factor-beta family (TGF-beta) are one of the few classes of endogenous inhibitors of cell growth. Contrary to the first notion that these proteins may be downregulated in cancer cells to promote their growth, generally it has been otherwise found that there is a marked increase in the expression of TGF-beta mRNA and protein in human cancers (in vivo), including those of the pancreas, colon, stomach, lung, endometrium, prostate, breast, brain, and bone. Furthermore, in many of these cancers high expression correlates with more advanced stages of malignancy and decreased survival. The increased expression of TGF-beta is usually accompanied by a loss in the growth inhibitory response to TGF-beta. For example, certain tumor cells in culture (i.e., colon carcinoma and glioblastoma multiforme) demonstrate a progressive loss of the growth inhibitory response to TGF-beta that varies directly with the malignant stage of the original tumor, and the most aggressive forms actually switch to being autocrine and/or paracrine growth stimulated by TGF-beta. The study of the molecular events associated with the escape of tumor cells from growth regulation by TGF-beta has provided insight into mechanisms underlying carcinogenesis. The mechanisms for upregulation of TGF-beta are unknown. However, once malignant cells lose their growth inhibitory response to TGF-beta and produce massive amounts of these proteins, the increased expression of TGF-beta provides a selective advantage for tumor cell survival as TGF-betas are also angiogenic and have potent immunosuppressive effects, including specifically inhibiting tumoricidal natural and lymphocyte-activated killer cells. In light of the significant role for TGF-betas in regulating cell growth, it is not surprising that in more recent years studies have shown that specific genetic alterations involved in the signaling pathway for TGF-beta-mediated growth inhibition have occurred in many human cancers. Specific defects in TGF-beta receptors, TGF-beta-related-signal transduction/gene activation, and TGF-beta-regulated cell cycle proteins, have all been implicated in the oncogenesis of many human cancers. In this context, components of the TGF-beta growth response pathway are considered to be tumor suppressor genes, as absence (or malfunction) of one or more receptors or signaling proteins would have the potential to cause loss of growth regulation. More recently, the posttranslational reduction of levels of the cyclin-dependent kinase inhibitor (CKI), p27kip1, which mediates TGF-beta growth inhibition, provides an additional means for cancer cells to escape negative growth regulation by TGF-beta. This review provides background information on TGF-beta and updates the status of our knowledge of the role for TGF-beta in specific human malignancies. Understanding the molecular events involved in TGF-beta function in normal cells and its lack of function in tumor cells should identify novel therapeutic targets in human cancers.
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PMID:The role for transforming growth factor-beta (TGF-beta) in human cancer. 1065 29

It is widely recognized that growth factors play critical roles in cell proliferation and differentiation. In the early 1980s, several members of the transforming growth factor-beta (TGF-beta) superfamily were identified and subsequently shown to play important roles in many diseases, in particular cancer. Efforts to understand how TGF-beta exerts its effects led to identification of TGF-beta-receptors and several downstream signaling pathways activated by this family of growth factors. This review provides an overview of TGF-beta-receptors and its downstream signaling pathways. As part of this discussion, this review indicates that inactivation of TGF-beta-receptors or components of their signaling pathways is often a target during carcinogenesis and that mutations or altered expression at any step along this complex, growth regulatory pathway can lead to aberrant cell proliferation. Lastly, the Cancer Genome Anatomy Project is briefly discussed, in particular how it may help to identify aberrant growth factor expression during carcinogenesis and improve the diagnosis of cancer patients.
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PMID:Growth regulatory factors and carcinogenesis: the roles played by transforming growth factor beta, its receptors and signaling pathways. 1069 93

The three mammalian isoforms of transforming growth factor-beta (TGF-beta1, -beta2, and -beta3) are potent regulators of cell growth, differentiation, and extracellular matrix deposition. To study their role in skin carcinogenesis, normal human keratinocytes, early (31) and late (310) passage immortalized keratinocytes (HaCaT cells), and five HaCaT-ras clones exhibiting benign (A-5, I-7), malignant (II-4, A-5 RT1), and highly aggressive (A-5 RT3) tumourigenic phenotypes were examined for the expression of TGF-beta isoforms, by immunohistochemistry. This was performed under in vivo conditions, in surface transplants and subcutaneously growing tumours in nude mice. Generally, all tissues that formed keratinized epithelia demonstrated an immunostaining pattern similar to normal human skin. TGF-beta1 was localized to the upper differentiated layers, the stratum granulosum and corneum, in a perimembranous pattern, whereas TGF-beta2 and, weaker, TGF-beta3 immunostaining was present in all suprabasal layers of normal keratinizing epithelia. In contrast, non-keratinizing transplants of non-tumourigenic or highly aggressive cells showed little to no immunoreactivity for TGF-beta1. Whereas TGF-beta2 expression was moderate in the upper layers of non-tumourigenic epithelia, large tumour cells of the malignant HaCaT-ras clones, particularly at the invasion front, were strongly positive for TGF-beta2. TGF-beta3 immunostaining was most pronounced in the stroma of malignant tumours, implying its paracrine induction by the malignant tumour transplants. These results suggest differential functions for each TGF-beta isoform in epidermal carcinogenesis, such that TGF-beta1 is associated with the more differentiated state, TGF-beta2 with highly malignant and invading cells, and TGF-beta3 with tumour stroma formation and angiogenesis. Furthermore, the expression of TGF-betas by both early- and late-stage tumours implies that the isoforms may have distinct functions at different stages of malignancy, supporting their dual role in skin carcinogenesis.
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PMID:TGF-beta isoforms are differentially expressed in increasing malignant grades of HaCaT keratinocytes, suggesting separate roles in skin carcinogenesis. 1072 84

The p53 tumor suppressor gene and members of the transforming growth factor-beta (TGF-beta) superfamily play central roles in signaling cell cycle arrest and apoptosis (programmed cell death) in normal development and differentiation, as well as in carcinogenesis. Here we describe a distantly related member of the TGF-beta superfamily, designated placental TGF-beta (PTGF-beta), that is up-regulated in response to both p53-dependent and -independent apoptotic signaling events arising from DNA damage in human breast cancer cells. PTGF-beta is normally expressed in placenta and at lower levels in kidney, lung, pancreas, and muscle but could not be detected in any tumor cell line studied. The PTGF-beta promoter is activated by p53 and contains two p53 binding site motifs. Functional studies demonstrated that one of these p53 binding sites is essential for p53-mediated PTGF-beta promoter induction and specifically binds recombinant p53 in gel mobility shift assays. PTGF-beta overexpression from a recombinant adenoviral vector (AdPTGF-beta) led to an 80% reduction in MDA-MB-468 breast cancer cell viability and a 50-60% reduction in other human breast cancer cell lines studied, including MCF-7 cells, which are resistant to growth inhibition by recombinant wild-type p53. Like p53, PTGF-beta overexpression was seen to induce both G(1) cell cycle arrest and apoptosis in breast tumor cells. These results provide the first evidence for a direct functional link between p53 and the TGF-beta superfamily and implicate PTGF-beta as an important intercellular mediator of p53 function and the cytostatic effects of radiation and chemotherapeutic cancer agents.
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PMID:Placental transforming growth factor-beta is a downstream mediator of the growth arrest and apoptotic response of tumor cells to DNA damage and p53 overexpression. 1077 12

Peroxisome proliferators (PPs) are a class of non-genotoxic chemicals that cause rodent liver enlargement and hepatocarcinogenesis. In primary rat hepatocyte cultures, PPs suppress spontaneous apoptosis and that induced by a number of pro-apoptotic stimuli such as transforming growth factor-beta(1). Tumour necrosis factor alpha (TNF-alpha) and the transcription factor NFkappaB have been implicated in the mode of action of PPs. TNF-alpha signalling to NFkappaB is thought to be responsible for many of the effects elicited by this cytokine. NFkappaB regulates gene expression in immunity, stress responses and the inhibition of apoptosis. Activation of NFkappaB requires the successive action of NFkappaB-inducing kinase and the phosphorylation of NFkappaB inhibitory proteins (IkappaB) by an IkappaB kinase (IKK) complex. The IKK2 subunit of IkappaB kinase is thought to be essential for NFkappaB activation and prevention of apoptosis. To determine whether IKK2 plays a role in the suppression of apoptosis by PPs, we expressed a dominant negative form of IKK2 (IKK2dn) in primary rat hepatocyte cultures. Infection with an adenovirus construct expressing IKK2dn caused apoptosis in control primary rat hepatocytes in the absence of exogenous TNF-alpha. Moreover, IKK2dn-induced apoptosis could not be rescued by addition of TNF-alpha or the peroxisome proliferator nafenopin. These results demonstrate a requirement for intracellular signalling pathways mediated by IKK2 in the suppression of apoptosis by the PP class of hepatocarcinogens.
Carcinogenesis 2000 Sep
PMID:A dominant negative form of IKK2 prevents suppression of apoptosis by the peroxisome proliferator nafenopin. 1096 9


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