. Background. Severe hereditary hypercholesterolaemia is most frequently due to familial hypercholesterolaemia (FH), caused by mutations in the LDL receptor (LDLR) gene. However, a phenotype very similar to FH may also be caused by defects in other genes like the genes for apolipoprotein (apo) B‐100 or autosomal recessive hypercholesterolaemia (ARH). Subject. An 8‐year‐old male of Lebanese origin was diagnosed with severe hypercholesterolaemia and extensive cutaneous and tendon xanthomas. Plasma LDL cholesterol before treatment was 17 mmol L−1, whilst parents and both siblings had normal levels. Diagnosis. Degradation of 125I‐labelled LDL in blood lymphocytes was reduced, but not abolished. Sequencing analysis of the LDLR and apoB‐100 genes were negative, whilst a splice acceptor mutation in intron 1 (IVS 1 –1G>C) was detected in the ARH gene. The patient was homozygous for the mutation, whilst the parents were heterozygous. These findings were in agreement with a diagnosis of ARH. Treatment and clinical course. Monthly LDL apheresis and atorvastatin 120 mg daily reduced LDL cholesterol preapheresis level to 4.8 mmol L−1. When ezetimibe was given 10 mg day−1 in combination with rosuvastatin 80 mg day−1, LDL cholesterol was further lowered to 1.6 mmol L−1, which made apheresis unnecessary. Cutaneous and tendon xanthomas disappeared completely and the intima‐media thickness of the common carotid arteries decreased. At age 23 he developed a small myocardial infarction. Conclusion. ARH should be considered in cases of severe hypercholesterolaemia with a pattern of recessive inheritance. Combination therapy with high‐dose statin and ezetimibe seems to be the treatment of choice in ARH and may reduce or eliminate the need for LDL apheresis treatment.
Reduction of plasma cholesterol by statins is fundamental to prevent coronary heart disease. Such therapy is often sub-optimal, however, particularly in patients with reduced LDL receptors (familial hypercholesterolemia), and novel or adjuvant therapies are therefore warranted. Cholesterol elimination is profoundly influenced by the rate of its conversion to bile acids (BA), regulated by the enzyme Cyp7a1. Induced fecal loss of BA by resin treatment reduces plasma cholesterol, presumably through induction of hepatic LDL receptors (LDLR). We here describe the effect of PR835, a drug belonging to a new class of lipid-lowering agents that inhibit the Slc10a2 protein, the intestinal transporter responsible for active uptake of BA. Treatment reduced plasma cholesterol by 40% in mice devoid of both the LDLR and its ligand, apoE, while triglycerides and HDL cholesterol were unchanged. Cyp7a1 enzyme activity and mRNA were induced several-fold, and hepatic HMG CoA reductase mRNA increased, mirroring an induced synthesis of BA and cholesterol. The addition of a statin potentiated the effect, leading to reductions of plasma total and LDL cholesterol by 64% and 70%, respectively. These effects could not be attributed to induction of other known hepatic lipoprotein receptors and indicate the presence of new points of targeting in lipid-lowering therapy.
SummaryPlatelet hyperactivity in vitro is found in patients with isolated hypercholesterolemia. It is, however, less well established if platelet activity in vivo is enhanced, and if there are differences between various types of hyperlipoproteinemia.Platelet function in vivo was studied at rest and during mental stress in men with isolated hypercholesterolemia (phenotype IIa; n = 21) or combined hyperlipidemia (phenotype IIb; n = 29), and age-matched normolipidemic controls (n = 41). The urinary excretion of 11-dehydrothromboxane B2 was elevated in patients compared to controls (IIa, p <0.05; IIb, p <0.001), and higher in type IIb than in IIa patients (p <0.05). Platelet secretion, assessed as plasma β-thromboglobulin levels, was higher in type IIb patients compared to controls (p <0.01) and type IIa patients (p <0.05) during mental stress. The urinary excretion of β-thromboglobulin was also elevated in type IIb patients compared to controls (p <0.05). Platelet aggregability at rest, as measured by filtragometry ex vivo was, however, reduced in both patient groups compared to controls (p <0.05). No correlations were found between plasma lipoprotein levels and markers of platelet function in vivo. Type IIb patients had higher plasma fibrinogen levels and higher leukocyte counts than controls (p <0.05 and p <0.001) and type IIa patients (p <0.05 and p = 0.06). Thromboxane excretion was positively related to fibrinogen levels and leukocyte counts (p <0.01 for both). Preliminary data regarding serum TNF-α also indicated an elevation of this inflammatory cytokine in type IIb patients (p <0.05 vs controls).In conclusion, thromboxane generation and platelet secretion in vivo are enhanced in patients with hypercholesterolemia, and particularly so among patients with concomitant elevation of plasma triglycerides. The mechanism is unknown, but inflammatory mediators may be involved. The present findings are of interest in relation to the role of triglycerides in coronary artery disease.
Platelet function was studied in 10 patients with familial hypercholesterolaemia, following lipid-lowering treatment with selective LDL-apheresis and with the HMG-CoA reductase inhibitor pravastatin. Platelet function was assessed before, and 2, 5 and 14 days after LDL-apheresis, and before and after 4 weeks of pravastatin therapy. Both treatments significantly reduced total- and LDL-cholesterol, whereas LDL-apheresis also reduced VLDL-cholesterol. Lp(a)-levels were reduced by LDL-apheresis and elevated by pravastatin treatment. Pravastatin therapy significantly enhanced platelet aggregability in vivo, as measured by ex vivo filtragometry. Plasma serotonin levels also increased. Other markers of in vivo activation of platelets, i.e. beta-thromboglobulin in plasma and urine, and 11-dehydro-thromboxane B2 in urine were unaltered. Adenosine diphosphate-induced platelet aggregation in vitro remained unchanged during pravastatin therapy, and the platelet volume distribution was not affected. LDL-apheresis reduced the mean platelet volume, as well as the percentage of large platelets, whereas the percentage of small platelets increased. Other measures of platelet function in vivo or in vitro were, however, unaltered following LDL-apheresis. Thus, pravastatin therapy enhances certain aspects of platelet aggregability in vivo, whereas a single treatment with selective LDL-apheresis does not consistently affect platelet aggregability during resting conditions. These results do not support the concept that reduction of LDL-cholesterol improves platelet function in hypercholesterolaemic patients, at least not in the short-term. However, the reduction of platelet volume after LDL-apheresis may be beneficial for patients receiving this therapy regularly.
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