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Target Concepts:
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Query: UMLS:C0001430 (
adenoma
)
21,222
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Apoptosis seems to be the predominant type of active cell death in the liver (type I), while in other tissues cells may die via biochemically and morphologically different pathways (type II, type III). Active cell death is under the control of growth factors and death signals. In the liver, endogenous factors, such as transforming growth factor beta 1 (TGF-beta 1), activin A,
CD95 ligand
, and tumor necrosis factor (TNF) may be involved in induction of apoptosis. Release and action of these death factors seems to be triggered by exogenous signals such as withdrawal of hepato-mitogens, food restriction, etc. During stages of hepatocarcinogenesis, not only DNA synthesis but also apoptosis gradually increase from normal to preneoplastic to
adenoma
and carcinoma tissue. Also, in human carcinomas, birth and death rates of cells are several times higher than in surrounding liver. (Pre)neoplastic liver cells are more susceptible than normal hepatocytes to stimulation of cell replication and of cell death. Consequently, tumor promoters may act as survival factors, i.e., inhibit apoptosis preferentially in preneoplastic and even in malignant liver cells, thereby stimulating selective growth of (pre)neoplastic lesions. On the other hand, regimens favoring apoptosis and lowering cell replication may result in selective elimination of (pre)neoplastic cell clones from the liver. Finally, we have studied the first stage of carcinogenesis, namely the appearance of putatively initiated cells after a single dose of the genotoxic carcinogen N-nitrosomorpholine (NNM). Most of these cells were found to be eliminated by apoptosis, suggesting that initiation, at the organ level, can be reversed at least partially by preferential elimination of initiated cells. These events may be regulated by autocrine or paracrine actions of survival factors.
...
PMID:Apoptosis in the liver and its role in hepatocarcinogenesis. 929 54
The aim of this study was to investigate the changes in expression pattern of the most important genes connected with apoptosis in proliferative apoptotic lesions (hyperplasia,
adenoma
), applying cDNA microarray technique, in order to promote the possible diagnostic or therapeutic utilisation of any difference in gene expression compared to the healthy (normal) parathyroid gland. Samples were taken from surgically removed 2 hyperplasias, 2 adenomas and 2 normal parathyroid glands. The Apoptosis Gene Array (Superarray) was used. This contains 112 genes, in tetraspot arrangement. The probes measured 250-600 base pairs. Streptavidin was bound to the array. CDP Star TM chemiluminescent substrate was used for detection. The samples deriving from hyperplasia or
adenoma
were compared to samples from normal parathyroid glands. The following genes were overexpressed in both hyperplasia and
adenoma
: CHEK1, ATM, BCL-XL, FAS, TNF, cIAP1, TRAIL, FADD, CASP 4,5,6,8, CD120b, CD137, LTA, TANK, TARF2, CAD, LIGHTR, DR3LG. CASP1,10, BFAR, BOD, BCL2L2, TRANCE were underexpressed in both hyperplasia and
adenoma
. Genes overexpressed only in hyperplasia were: MDM2, MCL1, BCL2A1, BLK, RIPK2, CD40LG, TRAF5, HUS1, BNIP3. Underexpressed only in hyperplasia: BOK, CIDEA, TRAF1, TRIP. Overexpressed only in
adenoma
: APOLLON, RIPK1, LTB, LTBR, CASP2,13, cIAP2, CIDEB. Underexpressed only in
adenoma
: TRAF4 and
FASLG
. Overexpresion or underexpression meant 1.5-fold difference from normal average values. As a result of this study, both pro-apoptotic and antiapoptotic genes were identified in hyperplasia and
adenoma
of the parathyroid gland. It seems that increased proliferation is connected also with increased apoptotic activity, but tumor cell candidates are able to survive, by activation of signal pathways resulting in overexpresion of anti-apoptotic genes.
...
PMID:[Changes in gene expression in the course of proliferative processes in the parathyroid gland]. 1688 77
Combined phenotypes of cells with membrane and intracellular expression of apoptosis and proliferation regulation markers (p53, bcl-2, CD95,
CD95L
, Ki-67) were studied by flow cytometry of cell suspension from thyroid tissue specimens from patients with autoimmune diseases,
adenoma
, and thyroid cancer. The incidence of cell groups with phenotypes p53/Ki-67, p53/CD95, bcl-2/Ki-67, bcl-2/CD95, CD95/Ki-67, p53/
CD95L
, CD95/
CD95L
, and bcl-2/
CD95L
was evaluated and the density of receptor distribution on/in each cell group are presented. Patients with autoimmune diseases had high incidence of cells with phenotypes p53/Ki-67, p53/CD95, bcl-2/Ki-67, bcl-2/CD95, CD95/Ki-67, p53/
CD95L
, CD95/
CD95L
, and bcl-2/
CD95L
; cells with the bcl-2/CD95 phenotype were the most incident. Patients with thyroid adenoma had high levels of cells with p53/
CD95L
phenotype, while patients with thyroid cancer had significantly lower levels of p53 expression in the p53/
CD95L
cell group. The density of
CD95L
receptors on CD95/
CD95L
-positive cells was 4-7-fold higher in patients with thyroid tumors; the density of
CD95L
receptors on CD95/
CD95L
cells was maximum in thyroid adenoma and minimum in thyroid cancer. These data indicate differences in the expression of apoptosis and proliferation markers in thyroid adenoma, cancer, and autoimmune diseases. Analysis of the expression of these markers in the above diseases can be useful for differential diagnosis.
...
PMID:Comparative analysis of cells with combined apoptosis and proliferation markers in thyroid tissue specimens from patients with cancer, adenoma, and autoimmune diseases. 2226 42
