Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0022116 (ischemia)
 91,303 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We evaluated the proliferative activity of human atherosclerotic lesions associated with active symptoms of ischemia, by assessing the expression of the proliferating cell nuclear antigen (PCNA). We confirmed in vitro that PCNA, an essential component of the DNA synthesis machinery, is selectively expressed in proliferating human vascular smooth muscle cells. 37 atherosclerotic lesions (18 primary and 19 restenotic) retrieved by directional atherectomy from either coronary or peripheral arteries were then studied for the expression of PCNA, using in situ hybridization or immunohistochemistry. Among plaques studied by in situ hybridization, 7 out of 11 primary and 11 out of 11 restenotic lesions contained PCNA-positive cells. The mean rate of proliferation (percent of PCNA-positive cells) was 7.2 +/- 10.8% in primary lesions and 20.6 +/- 18.2% in restenotic lesions (P < 0.05). Among specimens studied by immunohistochemistry, five out of seven primary and eight out of eight restenotic lesions contained proliferating cells. The mean rate of proliferation was again higher in the restenotic (15.2 +/- 13.6%) than primary (3.6 +/- 3.5%) lesions (P < 0.05). Proliferating cells were detected as late as 1 yr after angioplasty. We conclude that cellular proliferation is a feature of atherosclerotic lesions which are associated with symptoms of ischemia, but that it is more prominent in restenosis compared to primary lesions. These findings have implications for therapies aimed at limiting lesion growth, particularly after percutaneous revascularization.
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PMID:Proliferative activity in peripheral and coronary atherosclerotic plaque among patients undergoing percutaneous revascularization. 809 7

The presence of delayed graft function (DGF) following cadaver donor renal transplantation is associated with inferior graft survival as well as decreased patient survival. Delay in onset of function eliminates a valuable indicator of allograft viability, which is not easily replaced by standard diagnostic procedures. The purpose of this study was to demonstrate that a new clearance technique could be used to measure renal function minute to minute and under conditions similar to those observed in humans in the immediate posttransplantation period. A monkey model was used to provide controlled conditions. Increasing levels of ischemic injury were produced in 12 Rhesus monkeys by renal hilum cross-clamping. Real-time measurements of glomerular filtration rate (GFR) were obtained from the rate of clearance of the extracellular fluid of the GFR agent 99mTc-DTPA, as measured with a specially designed external radioactivity counting device called the ambulatory renal monitor, or ARM. GRF was measured every 2-5 min as the slope (k) of the log of activity measured minute to minute versus time. GFR measurements were correlated with blood urea nitrogen (BUN), plasma creatinine (Cr), routine light microscopy, and measurement of proliferating cell nuclear antigen (PCNA), a marker of cell proliferation. Large changes in renal function due to ischemia or ureteral obstruction were observed within minutes. In addition, the rate constant on Day 1 was predictive of peak serum Cr(R =--0.86, R2=.74, p = .0001). Acute tubular necrosis (ATN) resolution was reflected more quickly when using the rate constant (Day 1) than when using either BUN or plasma Cr (Day 3-4). Because of renal functional reserve, BUN and plasma Cr were relatively insensitive indicators of mild to moderate reductions in GFR as compared with the rate constant. We conclude that ARM is a simple method which provide an accurate, near real-time GFR readout with potential applications not only for the clinical management of patients with DGF, but also as a research tool in acute renal failure (ARF).
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PMID:Real-time monitoring of renal function during ischemic injury in the rhesus monkey. 857 Aug 62

Types of growth include embryonic, fetal, neonatal, juvenile and mature. Until full differentiation is achieved, cells grow through proliferation from progenitor cells. At maturity, the cellular genome is fixed with committed patterns of cell cycle duration and adaptation, ranging from static to renewing type 3. The static cell type cannot proliferate and adapts through hypertrophy. The renewing type continuously proliferates even without stimulus. In all cell types the processes of differentiation and proliferation are mutually exclusive. Cellular kinetics involve (a) the duration of the cell cycle, (b) the birth rate of cells, and (c) the growth rate fractions. The duration of the cell cycle is 2-4 days. All growth factors (GF) exert their influence during G1 phase. Release a GF by one cell type can influence the proliferation of another (= paracrine stimulation). At the end of G1 is the point of highest sensitivity to toxicity. Tumor suppressor genes act here through tyrosine phosphorylation. During S, the cell replicates its chromosomes. During G2 the immune surveillance and DNA damage repair mechanisms operate. Injured cells stay here longer enabling repair of their damaged DNA. Cell division involves both nuclear (mitosis) and cytoplasmic (cytokinesis) phases giving rise to 2 new cells. The cell cycle has 2 checkpoints. The first involves the G1-S transition and the second the G2-M transition. The types of cell cycle inhibition include (a) cycle- and phase-specific inhibition; (b) cycle-and nonphase-specific inhibition; (c) noncycle-and nonphase-specific inhibition, and finally (d) noncycle, nonphase-, and nonorgan-specific inhibition. Proliferation is a circadian process and it is stimulated by a variety of stimuli which include (1) interference with hormonal feedback pathways; (2) inhibition of the tissue trophic activity; (3) sustained presence of antigenic substances; (4) tissue ischemia; (5) changes of conditions luminally or on surfaces of tissues; (6) sustained cytotoxicity; (7) cell death; and (8) surgical resection. Proliferation can be arrested through senescence, apoptosis, injury or even during the development of immune cells. In the past, tissue/cell kinetics have been studied by tritiated thymidine histoautoradiography. Recently, monoclonal antibodies to proliferation-associated antigens, have been successfully employed. These antigens are cycle-associated proteins and include (1) PCNA; (2) p53; (3) Ki67; (4) AGNOR; (5) Statin; and (6) BrdU. Practical examples are given comparing PCNA and BrdU markers from 3 tissues, i.e. liver, glandular stomach, and uterus, across 2 or 3 strains of rats. Mean values of labeling indices are cited. Within the PCNA marker, 2 different clones are compared from the glandular stomach of SD rats of 2 different ages. Gender and across species comparisons are also made. All these comparisons denote that in every study where markers are used (a) there is a need for a concurrent study control group of the same age; (b) there is a need for in-house control data for this particular organ by species, strain, gender and age; (c) there is ancillary assessment of the trophic status of the target tissue; (d) there is a need for at least 2 different time points during assessment; (e) there is a need for such proliferation data prior to commencing the 2 year rodent bioassay; and (f) that PCNA is the most reliable and versatile of all markers used, capable of rendering good results even from archival specimens.
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PMID:Proliferation markers. 867 72

The expression of the immediate early genes (IEGs) c-fos and e-jun have been hypothesized to potentially play key roles in mediating cellular responses following injury to the liver. In this study, we sought to evaluate the potential involvement of c-jun and c-fos as determinants either of cellular regeneration or programmed cell death following ischemia/reperfusion (I/R) in mouse liver. To this end, we have analyzed the in situ messenger RNA (mRNA) expression patterns of c-jun and c-fos following lobar I/R in mouse liver. The expression patterns of c-jun and c-fos were correlated with four criteria for tissue repair and injury, including: 1) morphological determinations of regeneration using immunocytochemical detection of proliferating cell nuclear antigen (PCNA), 2) programmed cell death (apoptosis) using the in situ terminal deoxynucleotidyl transferase-mediated dUTP-biotin nick end-labeling (TUNEL) method, 3) histopathologic assessment of hepatocellular necrosis, and 4) serum glutamic pyruvic transaminase (GPT) levels. Increasing lengths of lobar ischemia for 3, 60, and 90 minutes followed by reperfusion directly correlated with the extent of liver injury as determined by serum transaminases and hepatocellular necrosis. PCNA expression in the liver was elevated at 1 to 6 hours following liver reperfusion and returned to baseline levels by 20 hours in both ischemic and nonischemic lobes. In contrast, apoptotic responses peaked only in ischemic lobes at 6 hours' postreperfusion and remained elevated out to 20 hours. Two distinct patterns of c-jun and c-fos expression were observed during the acute (1-3 hours) and subacute (6-20 hours) phases of liver responses to I/R including: 1) coexpression of c-jun and c-fos mRNA within damaged regions of the liver at 1 to 3 hours' postreperfusion, and 2) a decline in c-fos expression with sustained high levels of c-jun expression within a subset of cells bordering necrotic/apoptotic regions of the liver at 6 to 20 hours' postreperfusion. These findings suggest that coexpression of both c-jun and c-fos may be involved in mediating early tissue repair processes in liver remodeling following I/R. In contrast, the onset of hepatocellular apoptosis correlated with sustained c-jun expression, in the absence of c-fos, and suggests that these changes in the molecular profile of immediate early gene expression may regulate cellular responses that signal hepatocytes for programmed cell death.
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PMID:Expression of c-fos and c-jun during hepatocellular remodeling following ischemia/reperfusion in mouse liver. 867 76

To clarify the development of tubular necrosis and its healing process in ischemic renal failure observing degeneration, necrosis, cell proliferation and the involvement of apoptosis in the renal tubular epithelial cells before and after renal ischemia in rats through morphological examination. Eight week-old male rats were used for this study. The model for acute renal failure was by obstruction of bilateral renal arteries and veins for 45 minutes in several intervals (0 hr, 1 hr, 3 hr, 6 hr, 12 hr, 24hr, 48 hr, 96 hr, 1 week, 2 weeks and 4 weeks) each following reperfusion. Urinary beta 2-microglobulin (BMG) levels were measured to evaluate renal tubular function. In evaluating tubular necrosis and cell proliferation, observations of renal tubular tissue were made serially by use of light microscopy and immunological staining of proliferating cell nuclear antigen (PCNA) and bromodeoxyuridine (BrdU), respectively. The number of nuclei in the proximal tubular epithelium/circumference of the basement membrane (n/BM index) was calculated using a tissue measuring device. Transmission electron microscopy and the TdT-mediated dUTP-biotin nick end labeling (TUNEL) methods were used as indices of apoptosis. Maximal BMG values were obtained 24 hours after ischemia when injury in the proximal tubular epithelium was most prominent. The maximal number of PCNA and BrdU-positive cells were obtained 24 hours after ischemia and thereafter gradually decreased. The n/BM index in the disorder group was significantly increased 96 hours and 1 week after ischemia (p < 0.001). Electron microscopy revealed nuclear fragmentation and apoptosis in the tubular area indicating that there were significant differences. The number of positive cells for in situ nick end labelling increased 24 hours and 2 weeks after ischemia, exhibiting a two peak curve. However, the number of positive cells significantly decreased 4 weeks after ischemia. In the proximal kidney tubules damaged by reperfusion after ischemia, epithelial hyperplasia developed 3 to 6 days after the most active period of S-phase cells was noted. Thereafter, a decreasing number of epithelial cells was observed. It seemed that the decreasing number of these cells had been produced by apoptosis detected 2 weeks after ischemia.
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PMID:[A pathomorphological study on damage and repair process of tubuli after renal ischemia]. 895 3

Reactive astrocytes influence not only the severity of brain injury, but also the capacity of brain to reshape itself with learning. Mechanisms responsible for astrogliosis remain unknown but might be best studied in vitro, where improved access and visualization permit application of modern molecular and cellular techniques. We have begun to explore whether gliosis might be studied in hippocampal organotypic cultures (HOTCs), where potential cell-to-cell interactions are preserved and the advantages of an in vitro preparation are still realized. Following HOTC exposure to N-methyl-D-aspartate (NMDA), dose-dependent changes occurred in the optical density (OD) values for the astrocytic immunohistochemical [immunostaining (IS)] markers glial fibrillary acidic protein (GFAP) and vimentin. Exposure of HOTCs to NMDA (10 microM) caused selective death in the CA1 hippocampal region and the dentate gyrus. It also significantly increased GFAP IS and vimentin IS OD values in these regions. Increased GFAP IS and vimentin IS OD values were also seen in CA3, a hippocampal region that displayed no cell death. Light microscopic examination revealed hypertrophied GFAP and vimentin IS cells, characteristic of reactive astrocytes. Cellular proliferation, as assessed by proliferating cell nuclear antigen IS, was also significantly increased in all three of these hippocampal regions. In contrast, exposure of HOTCs to a noninjurious level of NMDA (1 microM) caused only minor changes in GFAP IS and vimentin IS OD values but a significantly reduced cellular proliferation in all HOTC regions. These results show that reactive astrocytosis from excitotoxic injury of HOTC parallels changes seen in vivo after global ischemia. Furthermore, since resting astroglia within HOTCs are also similar to their counterparts in vivo, HOTCs may be used to examine mechanisms by which these cells are transformed into reactive species within tissue that resembles intact brain.
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PMID:Reactive astrocytosis from excitotoxic injury in hippocampal organ culture parallels that seen in vivo. 897 84

In ischaemic porcine myocardium, the growth of collateral vessels by angiogenesis is observed in clusters in the vicinity of focal necroses. Because mitosis of endothelial cells is a prerequisite for angiogenesis, the purpose of this study has been to evaluate the time course of mitosis as an indicator of vascular growth in a porcine model of coronary microembolization. Ischaemia was induced by injection of 25-microm microspheres in the left circumflex artery, followed by tissue collection from non-ischaemic and ischaemic areas of the same heart after 24, 72 or 168 h microembolization. Tissue was studied by histone H3 in-situ hybridization, PCNA/cyclin immunohistochemistry and electron microscopy. The number of blood vessels in ischaemic myocardium was compared with that in normal control tissue. Capillary growth started as early as 24 h after microembolization, as indicated by increasing numbers of proliferating, histone H3- and PCNA/cyclin-positive cells in the necrotic inflammatory foci of the ischaemic area. At 72 h and 168 h, the number of blood vessels was significantly higher in ischaemic than in normal myocardium, whereas at 168 h, mitosis of cells was, as in normal myocardium, a rare event. Coronary microembolization of porcine myocardium thus leads to an increased cellular proliferation rate between 24 h and less than 7 days after the onset of microembolization, followed by enhanced capillary growth. In-situ hybridization with histone H3 and PCNA/cyclin immunohistochemistry seem to be reliable markers for proliferation and vascular growth in non-cancerogenic tissue.
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PMID:Time course of mitosis and collateral growth following coronary microembolization in the porcine heart. 902 87

Proliferation and dedifferentiation of tubular cells are the hallmark of early regeneration after renal ischemic injury. Vimentin, a class III intermediate filament expressed only in mesenchymal cells of mature mammals, was shown to be transiently expressed in post-ischemic renal tubular epithelial cells. Vimentin re-expression was interpreted as a marker of cellular dedifferentiation, but its role in tubular regeneration after renal ischemia has also been hypothesized. This role was evaluated in mice bearing a null mutation of the vimentin gene. Expression of vimentin, proliferating cell nuclear antigen (a marker of cellular proliferation), and villin (a marker of differentiated brush-border membranes) was studied in wild-type (Vim+/+), heterozygous (Vim+/-), and homozygous (Vim-/-) mice subjected to transient ischemia of the left kidney. As expected, vimentin was detected by immunohistochemistry at the basal pole of proximal tubular cells from post-ischemic kidney in Vim+/+ and Vim+/- mice from day 2 to day 28. The expression of the reporter gene beta-galactosidase in Vim+/- and Vim-/- mice confirmed the tubular origin of vimentin. No compensatory expression of keratin could be demonstrated in Vim-/- mice. The intensity of proliferating cell nuclear antigen labeling and the pattern of villin expression were comparable in Vim-/-, Vim+/- and Vim+/+ mice at any time of the study. After 60 days, the structure of post-ischemic kidneys in Vim-/- mice was indistinguishable from that of normal non-operated kidneys in Vim+/+ mice. In conclusion, 1) the pattern of post-ischemic proximal tubular cell proliferation, differentiation, and tubular organization was not impaired in mice lacking vimentin and 2) these results suggest that the transient tubular expression of vimentin is not instrumental in tubular regeneration after renal ischemic injury.
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PMID:Normal tubular regeneration and differentiation of the post-ischemic kidney in mice lacking vimentin. 909 92

The overgrowth of cells of the vessel wall, especially of the smooth muscle cells (SMCs), contributes to the pathogenesis of coronary atherosclerosis and wound repair after coronary angioplasty. However, the association between cellular proliferation in coronary lesions and clinical pathophysiology remains to be clarified in humans. Thus, we investigated proliferative activity in coronary tissues obtained from patients with coronary ischemia. The proliferative activity in tissues obtained by using directional coronary atherectomy (DCA) from 87 coronary lesions was assessed by immunohistochemical staining for the proliferating cell nuclear antigen (PCNA). The lesions were divided into 34 primary lesions and 53 postangioplasty lesions. The 34 primary tissue samples were obtained from 9 patients with stable angina pectoris (SAP) and 25 patients with acute coronary syndromes (ACS). Collectively, the 53 postangioplasty tissue samples were obtained from 37 patients with SAP and 16 patients with ACS. The PCNA labeling index (LI) was quantified as the mean percentage of PCNA-positive cells in the 3 most positive high-power fields (x 200). The mean LIs were high in the primary ACS samples [8.9 +/- 2.1% (p = 0.01)] and postangioplasty samples [2.3 +/- 0.8% (p = 0.08) in SAP cases and 4.1 +/- 2.4% (p = 0.06) in ACS cases] compared with the primary SAP samples (0.2 +/- 0.2%). Intimal hyperplasia, a random proliferation of SMCs (alpha-actin positive) was marked in the primary ACS samples (76%) as well as in the postangioplasty SAP (92%) and ACS (81%) samples, as compared with the primary SAP samples (33%) (p < 0.01). PCNA expression was mainly evident in the nucleus of the SMCs and CD68-positive macrophages. Many PCNA-positive cells were localized in plaque areas, as follows: intimal hyperplasia, neovascularized lesions, lesions with macrophage clusters, and lesions near areas of disrupted internal elastic lamina. The levels of PCNA expression in coronary lesions were not associated with the subsequent development of restenosis after DCA. Our findings suggest that the excessive proliferation of vascular wall cells, especially SMCs, is involved in the pathogenesis of ACS and in the process of wound repair after angioplasty in humans.
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PMID:Comparison of proliferative activity in coronary plaques from patients with coronary ischemia. Histopathological and immunohistochemical analysis. 911 65

We used double staining histochemistry to investigate the relationship between apoptotic cell death and selective protein expression associated with DNA damage (p53, Bax, MDM2, Gadd45), DNA repair (PCNA) and cell cycle proteins (cyclin A, cyclin D, cdk2, cdk4) in rats (n = 6; control rats, n = 5) subjected to transient (2 h) middle cerebral artery occlusion (MCAo) and 46 h of reperfusion. Few apoptotic cells were detected in the non-ischemic hemisphere of control rats. In ischemic animals, scattered apoptotic cells were present in the ischemic core and clustered apoptotic cells were present and localized to the inner boundary zone of the ischemic core. Proteins were preferentially localized to the cellular cytoplasm of control rats and in the non-ischemic hemisphere of rats subjected to MCAo. However, after MCAo these proteins were expressed and were preferentially localized to nuclei within the ischemic lesion. DNA damage induced proteins (wt-p53 and p53-response proteins) were preferentially expressed within apoptotic cells after ischemia. DNA repair proteins and cell cycle proteins were preferentially expressed within morphologically intact cells and in reversibly damaged cells in the ischemic areas. The selective expression of proteins associated with DNA damage, DNA repair and cell cycle observed in morphologically intact cells, ischemic injured cells and apoptotic cells suggests a differential role for these proteins in cell survival and apoptosis after stroke.
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PMID:Apoptosis and protein expression after focal cerebral ischemia in rat. 931 3


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