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:C0020473 (hyperlipidemia)
15,891 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

CAD results from atherosclerosis, a chronic disease process that has its origin in childhood. Children and adolescents can be at higher risk for CAD by virtue of being from families with premature CAD or familial dyslipoproteinemias. The plasma lipid and lipoprotein levels result from a number of complex metabolic processes that are under the control of genetic and environmental (e.g., diet) influences. The normal ranges of plasma lipids and lipoproteins in children are known, and children and adolescents with dyslipoproteinemia are ordinarily defined as those having levels of plasma total, LDL, or triglyceride above the 95th percentile or with a low HDL cholesterol below the 5th percentile. Children of a parent with documented dyslipoproteinemia or with family history of premature CAD may be screened in the fasting state any time after 2 years of age. Following the exclusion of secondary causes of dyslipoproteinemia, the diagnosis of primary dyslipoproteinemia can be made. Lipoprotein patterns are not diagnostic for a given genotype. Efforts to determine further the biochemical defects responsible for a given phenotype have led to the investigation of gene coding for the apolipoproteins, the key enzymes in the lipoproteins pathways (LPL, HDL, and LCAT) and the receptors that process lipoproteins, such as the LDL receptor and the chylomicron remnant receptor. From a practical standpoint, the diagnosis of the kind of dyslipoproteinemia in a child will depend upon the nature and severity of the dyslipoproteinemia, both in the child (or adolescent) and in parents and siblings. Marked increases in plasma total and LDL cholesterol in the child and in at least one of the parents often reflect the presence of familial hypercholesterolemia, an inherited dominant condition due to a defect in the LDL receptor gene. The triglyceride levels are often normal. If the child has a different dyslipoproteinemia pattern from siblings and parents, then the diagnosis of familial combined hyperlipidemia or hyperapobetalipoproteinemia should be considered. Most children with mild or borderline elevations in total and LDL cholesterol will have polygenic hypercholesterolemia. Triglyceride problems in children and adolescents are relatively uncommon, particularly the more severe hypertriglyceridemia such as that found in lipoprotein lipase and apoC-II deficiency, dysbetalipoproteinemia, and type V hyperlipoproteinemia. High levels of Lp(a) lipoprotein, in isolation or in combination with other dyslipoproteinemia, accelerate risk for CAD. Low levels of HDL cholesterol in the absence of other abnormalities suggest the diagnosis of hypoalphalipoproteinemia.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Diagnosis and management of familial dyslipoproteinemia in children and adolescents. 225 50

Hyperlipidemia is common in chronic renal failure (CRF), but the underlying mechanisms are not clearly defined. Certain data points toward a potential role for the state of secondary hyperparathyroidism of CRF in its pathogenesis. We examined the effects of parathyroid hormone (PTH) on lipid metabolism utilizing intravenous fat tolerance test (IVFTT) and post-heparin lipolytic activity in five normal dogs, in six animals with CRF and secondary hyperparathyroidism (NPX) and in six normocalcemic-thyroparathyroidectomized dogs (NPX-PTX) with comparable degree and duration of CRF. NPX dogs had fasting hypertriglyceridemia (82 + 6.0 mg/dl vs. 49 +/- 2.7 mg/dl in normal dogs, P less than 0.01), abnormal IVFTT, and reduced post-heparin plasma LPL activity (151 +/- 10 vs. 275 +/- 15 mumol fatty acids/ml/min in normal dogs, P less than 0.01). The NPX-PTX dogs had normal fasting levels of serum triglycerides (42 +/- 0.6 mg/dl), normal IVFTT, and normal post-heparin plasma LPL (317 +/- 19 mumol fatty acids/ml/min) despite CRF. Post-heparin HL activity in plasma was not different between NPX and NPX-TPX dogs. The results show that excess blood levels of PTH and not other consequences of CRF are mainly responsible for the abnormalities in lipid metabolism. The data are consistent with the notion that excess PTH reduces post-heparin LPL activity in plasma, which in turn results in impaired lipid removal from the circulation and consequently hyperlipidemia.
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PMID:Excess parathyroid hormone adversely affects lipid metabolism in chronic renal failure. 231 75

The relation of plasma levels of prostaglandins to the occurrence of flushing induced by niceritrol was investigated. Niceritrol increased plasma levels of PGE2 (p less than 0.01) and 6 keto-PGF1 alpha (p less than 0.05) in 10 male subjects and aspirin reduced the level of PGE2 (p less than 0.01). Five of 10 subjects had flushing, and aspirin reduced flushing in 4 subjects. On the basis of the above study, we treated 35 hyperlipidemic patients with niceritrol in combination with aspirin, investigating the effect of the treatment of serum lipids and postheparin lipolytic activity. None of the 12 cases given aspirin from the start of the treatment experienced flushing, whereas 9 of the 23 cases not given aspirin experienced flushing, which was suppressed by adding aspirin in prescription in all cases except one. Niceritrol decreased serum cholesterol, triglyceride and atherogenic index. It also increased HDL2 cholesterol and decreased HDL3 cholesterol. The LPL activity in postheparin plasma increased in all cases after niceritrol treatment. In conclusion, aspirin increased compliance of niceritrol by reducing the occurrence of flushing probably due to the decreased levels of prostaglandins, yielding favorable results for the long-term treatment of hyperlipidemia with a sufficient doses of niceritrol.
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PMID:Increased compliance of niceritrol treatment by addition of aspirin: relationship between changes in prostaglandins and skin flushing. 348 59

The glomerulus is a complex structure containing a remarkable capillary bed which is freely permeable to water and solutes up to the size of inulin. Many small proteins are filtered, reabsorbed, and catabolized by the kidney; but most large proteins, such as albumin or immunoglobulins, are almost entirely excluded from the glomerular ultrafiltrate due to the charge-size permselectivity of the glomerular capillary basement membrane. These large proteins appear in the urine when diseases reduce the charge selectivity or result in the development of large pores in this membrane. The reabsorptive capacity of the renal tubules for these proteins is overwhelmed. Hypoalbuminemia results when increased synthetic and decreased catabolic rates of albumin fail to compensate for the urinary loss of the protein. The resulting decrease in serum oncotic pressure increases the flux of fluid out of systemic capillaries into the interstitial space, a process that increases lymphatic flow and returns the relatively protein-poor ultrafiltrate to the plasma compartment. Interstitial proteins are swept into the plasma by the increased lymphatic flow, leading to a depletion of the extravascular pool of albumin even more severe than the depletion of albumin in the plasma compartment. The rate of albumin synthesis is increased but not sufficiently to replace losses and restore the serum concentration to normal. The rate of albumin catabolism is decreased. This decrease from the normal catabolic rate is as important as the increased rate of albumin synthesis in maintenance of albumin homeostasis in nephrosis. Whereas the reduced serum oncotic pressure certainly contributes to edema formation, sodium retention may result from processes intrinsic to the kidney itself; and plasma volume may actually be expanded despite hypoalbuminemia. The hyperlipemia that occurs in nephrosis is due to a combined defect in lipoprotein metabolism: increased hepatic synthesis of VLDL and decreased removal of TG and highly atherogenic remnants of incompletely metabolized CMs. The defects in lipoprotein metabolism may in part be the end result of the urinary loss of highly negative-charged macromolecules of the mucopolysaccharide called orosomucoid, which carries with it heparan sulfate, and important cofactor for LPL.
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PMID:Mechanisms and consequences of proteinuria. 351 85

Experiments on rabbits have shown hyperlipidemia to develop within the first 48 h after a single intravenous injection of bovine serum albumin (BSA, fraction V). The mean concentration of blood plasma triglycerides (TG) was considerably higher than normal (by 262% after 24 and by 625% after 48 h). The cholesterol content was also elevated (by 80 and 270%, respectively). Following 7 and 14 days the lipid concentration returned to normal. The plasma post-heparin lipoprotein lipase activity (PHP-LPL) was lower 24 h and 7 days after BSA injection and the hypotriglyceridemic effect of heparin was less pronounced. The data obtained support the hypothesis that hyperlipidemia provoked by a single intravenous injection of BSA to rabbits results from low PHP-LPL activity and possible changes in TG-rich lipoprotein substrate affinity for the enzyme.
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PMID:[Role of lipolytic enzymes in the development of hyperlipidemia induced by administration of heterologous albumin in rabbits]. 669 22

In this review we have endeavored to emphasize the central role of the liver in normal lipoprotein metabolism and to demonstrate how derangements in these metabolic processes can lead to abnormalities characteristic of liver disease. Since changes in the concentration and composition of plasma lipids and lipoproteins occur frequently in liver disease, these findings may be useful in following the clinical course of patients with liver disease of various causes. It should be emphasized that elevated plasma triglycerides and cholesterol are due to underlying defects in lipoprotein metabolism and should not be confused with primary hyperlipidemia. Impaired cholesterol esterification, abnormal lipoprotein electrophoretic patterns and lipoprotein compositional changes, all reflect abnormalities of lipoprotein metabolism that are secondary to hepatocellular injury or cholestasis. These abnormalities are very sensitive indicators of fundamental metabolic defects that are related in part to LCAT and apoprotein activator deficiencies, impaired H-TGL and LPL activity and, perhaps, defective remnant lipoprotein clearance by the liver. Since these abnormalities tend to improve with clinical recovery they have proved to be reliable and sensitive indicators of hepatic function and thus, are useful in the assessment of liver disease.
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PMID:Lipoprotein metabolism in liver disease. 698 38

Serum lipids were analyzed in 16 patients with active acromegaly. Of these 62.5% had hyperlipidaemia defined as exceeding and 90% fiducial limits of normal controls. The mean serum cholesterol (5.50 mmol/l) and triglyceride (4.09 mmol/l) levels of the patients were significantly higher than those of age-matched normal controls. Type V hyperlipoproteinaemia was observed in two cases and type III hyperlipoproteinaemia in one. There was no difference in the incidence of diabetes between the normolipidaemic (n = 6) and hyperlipidaemic (n = 10) groups. Serum levels of growth hormone in hypercholestelaemic patients (n = 3) were significantly higher than those of normolipidaemic patients and combined hyperlipidaemic patients (n = 5 tended to have higher levels of growth hormone than normolipidaemic patients. In cases developing type III or type V hyperlipoproteinaemia, the activity of hepatic triglyceride lipase of lipoprotien lipase was decreased, but in increased when serum GH levels fell after therapy for acromegaly. It is suggested that 1) growth hormone may play some role on the pathogenesis of hyperlipidaemia associated with acromegaly, and 2) growth hormone has an inhibitory effect on H-TGL and LPL, and so hyperlipoproteinaemia in some cases of acromegaly might be caused by low H-TGL or LPL activity resulting from high growth hormone levels.
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PMID:The incidence and pathogenesis of hyperlipidaemia in 16 consecutive acromegalic patients. 711 4

Approximately 1% to 2% of persons in the general population are homozygous for a lipoprotein receptor-binding defective form of apoE (apoE2/2). However, only a small percentage (2% to 5%) of all apoE2/2 homozygotes develop type III hyperlipoproteinemia. Interaction with other genetic and environmental factors are required for the expression of this lipid abnormality. We sought to investigate the possible role of LPL gene mutations in the development of hyperlipoproteinemia in apoE2/2 homozygotes and in apoE2 heterozygotes. As a first step, we performed DNA sequence analysis of all 10 LPL coding exons in 2 patients with the apoE2/2 genotype who had type III hyperlipoproteinemia and identified a single missense mutation (Asn 291-->Ser) in exon 6 of the LPL gene. The mutation was then found in 5 of 18 patients with type III hyperlipoproteinemia who had the apoE2/2 genotype (allele frequency = 13.9%; P < or = 7.4 x 10(-5)) and 6 of 22 hyperlipidemic E2 heterozygous patients with the apoE3/2 and E4/2 genotype (allele frequency = 13.6%; P = 2.2 x 10(-5)). In contrast, this mutation was found in only 3 of 230 normolipidemic controls (allele frequency = 0.7%). In vitro mutagenesis studies revealed that the Asn 291-->Ser mutant LPL had approximately 60% of LPL catalytic activity and approximately 70% of specific activity compared with wild-type LPL. The heparin-binding affinity of the mutant LPL was not impaired. Our data suggest that the Asn 291-->Ser substitution is likely to be a significant predisposing factor contributing to the expression of different forms of hyperlipidemia when associated with other genetic factors such as the presence of apoE2.
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PMID:Patients with apoE3 deficiency (E2/2, E3/2, and E4/2) who manifest with hyperlipidemia have increased frequency of an Asn 291-->Ser mutation in the human LPL gene. 758 46

We analyzed the molecular defects in the lipoprotein lipase gene of a patient with type I hyperlipidemia suffering from recurrent pancreatitis, indicative for lipoprotein lipase deficiency. Postheparin lipoprotein lipase activity in the patient was decreased by 70%. Direct genomic sequencing revealed compound heterozygosity for two mutation: the well-known Gly188-->Glu and a new Val69-->Leu substitution. Val69 is situated in a conserved hydrophobic region of the lipoprotein lipase protein, and the substitution with leucine gives rise to a 80% decrease in specific catalytic activity, as supported by site-directed mutagenesis experiments, followed by expression in COS-cells. The combination of both defects in the lipoprotein lipase gene was incidentally associated with severe clinical expression of disease, and triglyceride levels of more than 30 mmol/l were measured. In our patient, triglyceride levels wer usually below 10 mmol/l. We, therefore, postulate that the residual LPL activity in our patient is usually sufficient to keep the triglyceride level within bounds and expression of disease occurred only when conditions such as alcohol abuse or poor compliance to diet were present.
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PMID:A compound heterozygote for lipoprotein lipase deficiency, Val69-->Leu and Gly188-->Glu: correlation between in vitro LPL activity and clinical expression. 791 54

The relationship between lipoprotein(a) [Lp(a)] and metabolism of triglyceride-rich lipoproteins (TRL) was studied in 58 untreated patients with familial combined hyperlipidemia (FCH) from eight different kindreds, 17 spouse controls, and 17 unrelated controls. Lp(a) plasma concentrations were not significantly different between FCH subjects (343 +/- 61 mg/L, mean +/- SEM) and controls (249 +/- 52 mg/L). In FCH, log-transformed Lp(a) levels correlated positively with postheparin lipoprotein lipase ([LPL] r = .61, P = .0002) and hepatic lipase ([HL] r = .46, P = .008) activities and total plasma cholesterol level (r = .30, P = .03). In controls, Lp(a) correlated with LPL (r = .50, P = .04) and total plasma cholesterol level (r = .51, P = .003). In eight FCH patients, treatment with the 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase inhibitor simvastatin resulted in significantly increased mean LPL activities and plasma Lp(a) concentrations. In three of these FCH patients, repeated measurements during 1 year demonstrated that changes in Lp(a) concentrations were paralleled by similar changes in LPL activity, but not HL activity. The observed correlation between postheparin plasma lipolytic activities and Lp(a) plasma concentrations suggests a connection between the metabolism of TRL and Lp(a).
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PMID:Lipoprotein(a) plasma concentrations associated with lipolytic activities in eight kindreds with familial combined hyperlipidemia and normolipidemic subjects. 851 May 21


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