J. Slack

from all causes have been estimated among the first degree relatives of male and female index patients with ischaemic heart disease. These on July 23,

Abstract. Plasma lipoproteins and apolipoproteins have been studied in a kindred with familial apolipoprotein CII (apo CII) deficiency. As in two other recently documented pedigrees, apo CII deficiency appeared to be transmitted as an autosomal recessive trait. The homozygous state was characterized by gross fasting hypertriglyceridaemia, complete absence of apo CII from plasma and failure of plasma to activate lipoprotein lipase. Post‐heparin plasma hepatic triglyceride lipase activity was normal. Hypertriglyceridaemia reflected chylomicronaemia and elevated Sf 100–400 and Sf 20–100 lipoprotein concentrations; lipoproteins of Sf 12–20 (LDL 1 ), Sf 0–12 (LDL 2 ), F 1.2 3.5–9 (HDL 2 ) and F 1.2 0–3.5 (HDL 3 ) were greatly reduced in concentration. Low density lipoproteins (1.006–1.063 g/ml), isolated by preparative ultracentrifugation, and high density lipoproteins, isolated by heparin/Mn ++ , were triglyceride‐enriched. Electroimmunoassays revealed additionally low plasma concentrations of apolipoproteins AI, AII and B and very high concentrations of apolipoproteins CIII and E in the homozygote. The parents of the proband (heterozygotes) were normotriglyceridaemic, and had normal lipoprotein lipid concentrations and normal apolipoprotein AI, AII, B, CIII and E concentrations, in spite of having low apo CII concentrations. Activation of lipoprotein lipase in the homozygote by intravenous infusion of 200 ml fresh‐frozen plasma rapidly reduced the plasma concentrations of chylomicrons and very low density lipoproteins (VLDL). Within VLDL, the decrease in concentration occurred sequentially in the Sf 100–400 and Sf 20–100 subclasses. These changes were associated during a 4‐day study period with reciprocal increases in LDL 1 , LDL 2 , HDL 2 and HDL 3 . The plasma concentrations of apo AI and apo B also increased, associated with a less marked fall in that of apo CIII; the apo AII and apo E concentrations were unchanged. These observations support other evidence that apo CII is a cofactor for the catabolism of chylomicrons and both major subfractions of VLDL by lipoprotein lipase in man, and that human LDL 1 and LDL 2 are derived, at least in part, from triglyceride‐rich lipoprotein catabolism. They also suggest that both major subfractions of HDL acquire additional components during triglyceride‐rich lipoprotein catabolism. In normal subjects the plasma apo CII concentration appears to be greatly in excess of that required for adequate activation of lipoprotein lipase.

The serum cholesterol concentrations of 134 children aged 1-16 years who had at least one first-degree relative with presumed familial hypercholesterolaemia showed a bimodal distribution, and, using the maximum likelihood technique, two overlapping curves could be fitted. The mean value of the affected children (heterozygotes) was 8-9 mmol/l and that of the unaffected 4-9 mmol/l. The two curves intersected at 6-77 mmol/l, and at this point 5% of the unaffected children had values over 6-77 mmol/l and 3-5% of the heterozygotes had values under 6-77 mmol/l. If this cholesterol concentration is used as a cut-off point 4-25% of cases would be misdiagnosed.