Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: UMLS:C0020473 (hyperlipidemia)
 15,891 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Type II diabetic subjects, 26 with symptoms and/or signs of large vessel disease (LVD group) and 26 free from clinical vascular disease (FVD group), matched for sex, age, body weight, and duration of diabetes after diagnosis, together with 28 healthy controls participated in a preliminary study on new potential risk factors of large vessel disease. The activity of erythrocyte aldehyde dehydrogenase (ALDH) was significantly higher (P less than 0.005) in the LVD than in the FVD group and in the controls, as indicated by a shorter half-life of acetaldehyde in homogenates of erythrocytes and plasma (100 +/- 11, 203 +/- 28, and 180 +/- 21 min, respectively). The results were unaffected by antidiabetes therapy, blood glucose control, alcohol consumption, or by recognized risk factors of angiopathy, such as blood pressure, hyperlipidemia, or smoking. Whether ALDH activity is a primary factor in large vessel disease or is merely a secondary phenomenon is unknown. However, ALDH activity is a critical factor determining chlorpropamide alcohol flush (CPAF), which has been suggested to be an inherited trait in some type II diabetic subjects. In conclusion, high ALDH activity was shown to be associated with an increased risk of large vessel disease in diabetes.
 ...
PMID:Aldehyde dehydrogenase activity and large vessel disease in diabetes mellitus. A preliminary study. 394 78

Ther are several main mechanisms that allow us to understand a number of the hepatic and metabolic effects of ethanol. Ethanol is oxidized in the liver to two products (hydrogen and acetaldehyde), to which many of the effects of ethanol can be attributed. The hydrogen generated alters the redox state, and though this effect is attenuated after chronic ethanol consumption, it may still be sufficient to explain alterations in lipid metabolism, possibly increased collagen deposition, and, under special circumstances, depression of protein synthesis. Acetaldehyde impairs microtubules, decreases protein secretion, and causes protein retention and ballooning of the hepatocyte. Acetaldehyde exerts toxicity also with regard to other key cellular functions, particularly in the mitochondria, and it may promote peroxidation of the cellular membranes. It is noteworthy that after chronic consumption of ethanol, there is increased acetaldehyde, in part because of decreased disposition in the mitochondria and partly because of induction of an alternative pathway of ethanol metabolism, namely the microsomal ethanol-oxidizing system. Indeed, this MEOS increases in activity after chronic ethanol consumption, with cross induction and acceleration of the metabolism of other drugs and increased lipoprotein production with hyperlipemia. There is also increased microsomal activation of hepatotoxic compounds (including drugs and possibly vitamin A). Fibrosis and cirrhosis can develop despite an associated adequate diet and even in the absence of alcoholic hepatitis. They are preceded by myofibroblasts and fibroblast proliferation. What eventually causes the increased number of myofibroblasts and promotes fibrosis is unclear, nor do we know the relative role of hepatocytes or mesenchymal cells in the process of fibroplasis. Possibly selective roles in this process of specific nutritional factors remain to be elucidated.
 ...
PMID:Alcohol, protein nutrition, and liver injury. 634 74

The effects of ethanol, acetaldehyde, acetate and lactate on lipoprotein lipase (LPL) activity and regulation have been investigated. None of the substances had any direct effect on the enzyme or enzyme-substrate complex. Ethanol and acetate interfered with LPL regulation studied in vitro using rat adipose tissue. Acetate administration to humans did not influence the activity of LPL and hepatic lipase in post-heparin plasma, nor was the intravenous fat tolerance test affected. Ethanol administration markedly increased and prolonged the hyperlipidemia induced by oral triglyceride intake; the effect of acetate was much less pronounced. Thus, acetate does not seem to interfere with LPL regulation in man. The previously described impairment in LPL activity and regulation after ethanol intake is probably mediated by ethanol itself.
 ...
PMID:Acute effects of ethanol and its metabolites on plasma lipids and lipoprotein lipase activity. 688 18

Although alcohol is likely to have direct effects on the subcellular integrity of the pancreas, other factors arising outside the pancreas may modulate or potentiate alcohol-induced damage. Among these factors are the hepatic metabolism of ethanol to acetaldehyde (via isoenzymes of ADH), the hepatic production of free radicals, the release of G.I. hormones, pancreatic ischemia (and reperfusion injury), hyperlipemia, diet and smoking. This article summarises what is known about these extrapancreatic factors. It is suggested that the pathogenesis of alcoholic pancreatitis is multifactorial but that many studies in this field are difficult to interpret because of methodological problems, particularly with regard to inadequate controls.
 ...
PMID:An overview of extrapancreatic factors in the pathogenesis of alcoholic pancreatitis. 897 59

Excessive consumption of alcohol leads to severe alterations of lipid metabolism, including hyperlipemia and hypercholesterolemia. Following these epidemiological observations, we investigated the effects of ethanol at the cellular level by employing a human hepatomal cell line (HepG2) and by evaluating the biosyntheses of lipid classes from different labeled precursors. Incubation of cells with 2% ethanol resulted in a decreased labeling of phospholipids and in an increase in cholesterol synthesis and secretion. Triglyceride synthesis was increased by ethanol but their secretion in the medium was reduced, suggesting that these alterations may be related to their accumulation in the liver. The alcohol-induced alterations of lipid metabolism are not due to its metabolite acetaldehyde and data suggest that alcohol enhances cholesterol synthesis by affecting the initial steps without increasing HMGCoA expression. The observed modifications of lipid metabolism in HepG2 may partially explain the enhanced incidence of cardiovascular disorders that has been associated with alcoholism.
 ...
PMID:Ethanol enhances cholesterol synthesis and secretion in human hepatomal cells. 959 May 14

Alcoholic fatty liver and hyperlipemia result from the interaction of ethanol and its oxidation products with hepatic lipid metabolism. An early target of ethanol toxicity is mitochondrial fatty acid oxidation. Acetaldehyde and reactive oxygen species have been incriminated in the pathogenesis of the mitochondrial injury. Microsomal changes offset deleterious accumulation of fatty acids, leading to enhanced formation of triacylglycerols, which are partly secreted into the plasma and partly accumulate in the liver. However, this compensatory mechanism fades with progression of the liver injury, whereas the production of toxic metabolites increases, exacerbating the lesions and promoting fibrogenesis. The early presence of these changes confers to the fatty liver a worse prognosis than previously thought. Alcoholic hyperlipemia results primarily from increased hepatic secretion of very-low-density lipoprotein and secondarily from impairment in the removal of triacylglycerol-rich lipoproteins from the plasma. Hyperlipemia tends to disappear because of enhanced lipolytic activity and aggravation of the liver injury. With moderate alcohol consumption, the increase in high-density lipoprotein becomes the predominant feature. Its mechanism is multifactorial (increased hepatic secretion and increased extrahepatic formation as well as decreased removal) and explains part of the enhanced cholesterol transport from tissues to bile. These changes contribute to, but do not fully account for, the effects on atherosclerosis and/or coronary heart disease attributed to moderate drinking.
 ...
PMID:Alcohol and lipids. 975 44

Oxidation of ethanol via alcohol dehydrogenase (ADH) explains various metabolic effects of ethanol but does not account for the tolerance and a number of associated disorders that develop in the alcoholic. These were elucidated by the discovery of the microsomal metabolism of ethanol. The physiologic role of this system comprises gluconeogenesis from ketones, fatty acid metabolism, and detoxification of xenobiotics, including ethanol. After chronic ethanol consumption, the activity of the microsomal ethanol-oxidizing system (MEOS) increases, with an associated rise in cytochromes P-450, especially CYP2E1. This induction is associated with proliferation of the endoplasmic reticulum, both in experimental animals and in humans. The role of MEOS in vivo and its increase after chronic ethanol consumption was shown most conclusively in alcohol dehydrogenase-negative deer mice. Enhanced ethanol oxidation is associated with cross-induction of the metabolism of other drugs, resulting in drug tolerance. Furthermore, there is increased conversion of known hepatotoxic agents (such as CCl4) to toxic metabolites, which may explain the enhanced susceptibility of alcoholics to the adverse effects of industrial solvents. CYP2E1 also has a high capacity to activate some commonly used drugs, such as acetaminophen, to their toxic metabolites, and to promote carcinogenesis (e.g., from dimethylnitrosamine). Moreover, catabolism of retinol is accelerated and there also is induction of microsomal enzymes involved in lipoprotein production, resulting in hyperlipemia. Contrasting with the chronic effects of ethanol consumption, acute ethanol intake inhibits the metabolism of other drugs through competition for the at least partially shared microsomal pathway. In addition, metabolism by CYP2E1 results in a significant free radical release and acetaldehyde production which, in turn, diminish reduced glutathione (GSH) and other defense systems against oxidative stress. Acetaldehyde also forms adducts with proteins, thereby altering the functions of mitochondria and of repair enzymes. Increases of CYP2E1 and its mRNA prevail in the perivenular zone, the area of maximal liver damage. CYP1A2 and CYP3A4, two other perivenular P-450s, can also sustain the metabolism of ethanol, thereby contributing to MEOS activity and possibly liver injury. By contrast, CYP2E1 inhibitors oppose alcohol-induced liver damage, but heretofore available compounds were too toxic for clinical use. Recently, however, polyenylphosphatidylcholine (PPC), an innocuous mixture of polyunsaturated lecithins extracted from soybeans, was discovered to decrease CYP2E1 activity. PPC (and its active component dilinoleoylphosphatidylcholine) also oppose hepatic oxidative stress and fibrosis. PPC is now being tested clinically for the prevention and treatment of liver disease in the alcoholic.
 ...
PMID:Microsomal ethanol-oxidizing system (MEOS): the first 30 years (1968-1998)--a review. 1039 83

Ethanol toxicity on liver is a function of duration of alcoholism, amount of daily intake of alcohol and patient's nutrition. The threshold of alcohol toxicity on the liver is about 40 g of ethanol daily in men and 20-30 g in women, however liver cirrhosis develops in no more than 8-20% of patients exceeding this values. Ethanol is oxidized in the liver to acetaldehyde--a compound considerably more toxic than ethanol itself. Despite small amount of alcohol dehydrogenase (ADH) found in gastric mucosa, the metabolism of ethanol in this site may have an important hepatoprotective effect. The oxidation of ethanol is associated with a change of hepatocyte redox homeostasis, which leads to a number of metabolic disorders such as lactic acidosis, hyperlipidaemia and hyperuricaemia. Chronic ethanol consumption does not influence ADH activity, but has a profound stimulatory effect on microsomal enzymes, in particular cytochrome CYP2E1. This fact is responsible for development in alcoholic liver associated with rise of oxygen consumption, excessive production of free radicals and increased metabolism of ethanol, vitamin A and testosterone. Ethanol and acetaldehyde have a deleterious effect, both the direct and indirect, on hepatocytes e.g., generating radical oxygen species and damaging intestinal mucosal barrier. Cellular oxidative stress that is caused by both an excess of free radicals and the antioxidatives' deficiency (glutathion, vitamin E, phosphatidylcholine), may be the principal factor responsible for progression of alcoholic liver disease. Among other factors accelerating alcohol-related liver lesion there are certain drugs, high fat diet, infection with HCV and genetic factors (female sex, enzymatic polymorphic forms of ADH and ALDH, hemochromatosis). Great importance in pathogenesis of necrotic and inflammatory hepatic events is being attributed to portal endotoxaemia and cytokines induced within the liver, in particular TNF-alpha and interleukin 8. These cytokines play a key role in development of alcoholic hepatitis, which clinical severity ranges from subclinical to fatal forms. Apart from abstinence, the treatment of alcohol liver disease is based on hyperalimentation, since alcoholism is generally associated with protein malnutrition. In severe forms of alcohol hepatitis corticosteroids are recommended.
 ...
PMID:[Alcoholic liver disease]. 1290 Dec 71

Fatty aldehyde dimethyl acetals (DMA) derived from plasma and erythrocyte membrane plasmalogen phospholipids of 109 donors, aged 25-91 years, were measured as weight percent of total phospholipid fatty acids and DMA. The age range from 70 to 90 years (n = 82) was divided into age groups of five years each. Cumulative distributions of the DMA values of these age groups, when compared with those of 17 younger persons (aged 25-41 years), revealed a tendency to higher DMA values in the youngest age group, and to lower values in the oldest one. Linear regressions were computed between age and hexadecanaldimethylacetal (16:0 DMA) or octadecanaldimethylactal (18:0 DMA) of erythrocyte membrane and plasma phospholipids. Statistically significant negative correlations with age were obtained. Because of their sensitivity to oxidation reactions, a role of plasmalogens as a natural antioxidant in oxidative defense mechanisms appears to be convincing. However, it will possibly be difficult to separate the effects of normal aging on the decline of plasmalogen phospholipid levels in some tissues from those of certain pathological conditions - including hyperlipidemia and atherosclerosis.
 ...
PMID:Plasmalogen phospholipids - facts and theses to their antioxidative qualities. 1537 2

A new liquid chromatography-tandem mass spectrometric (LC-MS/MS) approach, based on the precursor ion scanning technique using a triple-stage quadrupole, has been developed to detect free and protein-bound histidine (His) residues modified by reactive carbonyl species (RCS) generated by lipid peroxidation. This approach has been applied to urines from Zucker obese rats, a nondiabetic animal model characterized by obesity and hyperlipidemia, where RCS formation plays a key role in the development of renal and cardiac dysfunction. The immonium ion of His at m/z 110 was used as a specific product ion of His-containing peptides to generate precursor ion spectra, followed by MS2 acquisitions of each precursor ion of interest for structural characterization. By this approach, three novel adducts, which are excreted in free form only, have been identified, two of them originating from the conjugation of 4-hydroxy-trans-2-nonenal (HNE) to His, followed by reduction/oxidation of the aldehyde: His-1,4-dihydroxynonane (His-DHN), His-4-hydroxynonanoic acid (His-HNA), and carnosine-HNE, this last recognized in previous in vitro studies as a new potential biomarker of carbonyl stress. No free His-HNE was found in urines, which was detected only in protein hydrolysates. The same LC-MS/MS method, working in multiple reaction monitoring (MRM) mode, has been developed, validated, and applied to quantitatively profile in Zucker urines both conventional (1,4-dihydroxynonane mercapturic acid, DHN-MA) and the newly identified adducts, except His-HNA. The analytes were separated on a C12 reversed-phase column by gradient elution from 100% A (water containing 5 mM nonafluoropentanoic acid) to 80% B (acetonitrile) in 24 min at a flow rate of 0.2 mL/min and analyzed for quantification in MRM mode by applying the following precursor-to-product ion transitions m/z 322.2 --> 164.1 + 130.1 (DHN-MA), m/z 314.7 --> 268.2 + 110.1 (His-DHN), m/z 312.2 --> 110.1 + 156.0 (His-HNE), m/z 383.1 --> 266.2 + 110.1 (CAR-HNE), m/z 319.2 --> 301.6 + 156.5 (H-Tyr-His-OH, internal standard). Precision and accuracy data, as well as the lower limits of quantification in urine, were highly satisfactory (from 0.01 nmol/mL for CAR-HNE, His-DHN, His-HNE, to 0.075 nmol/mL for DHN-MA). The method, applied to evaluate for the first time the advanced lipoxidation end products profile in urine from obese Zucker rats, an animal model for the metabolic syndrome, has proved to be suitable and sensitive enough for testing in vivo the carbonyl quenching ability of newly developed RCS sequestering agents.
 ...
PMID:HNE Michael adducts to histidine and histidine-containing peptides as biomarkers of lipid-derived carbonyl stress in urines: LC-MS/MS profiling in Zucker obese rats. 1797 57


1 2 Next >>