retinol-palmitate and Hyperlipoproteinemia-Type-I

Our primary aim was to determine the extent to which intraplasmic retinyl palmitate (RP) transfers to other lipoprotein particles when chylomicron remnants are not produced and/or the plasma RP residence time is increased. The study was conducted on three familial type I hyperlipoproteinemic patients, four lipoprotein lipase (LpL)-deficient heterozygotes, and three controls on a metabolic research unit. To each subject, a fat load was administered containing 16% of total daily calories in type I patients, 40% in heterozygotes and controls, plus 60,000 U/m2 vitamin A. Triglyceride (TG) and RP levels were evaluated in chylomicron and nonchylomicron fractions. Delay in the clearance of chylomicron fraction RP and the marked deficiency in nonchylomicron-RP (presumed lack of remnant production) in all three type I patients suggests that RP does not demonstrate significant intraplasmic transfer from chylomicrons to existent apolipoprotein B100 particles. In contrast to noncoincident TG and RP peaking in the normal subject, heterozygotes were found to demonstrate coincident plasma TG and RP curves, which is consistent with a common catabolic pathway for both TG and RP and inconsistent with intraplasmic RP transfer. This corroborates reports on compromised chylomicron clearance in heterozygotes. We conclude that RP is an appropriate representative marker for intestinally derived particles in LpL-deficient or partially deficient individuals.

Topics: Adolescent; Adult; Child; Child, Preschool; Chylomicrons; Diterpenes; Humans; Hyperlipoproteinemia Type I; Lipoproteins, LDL; Male; Metabolic Clearance Rate; Middle Aged; Retinyl Esters; Triglycerides; Vitamin A

We have studied the large nonconsanguineous pedigree of a proband with Type I hyperlipoproteinemia (HL) and lipoprotein lipase (LPL) deficiency. Within the nuclear family, the mother and two of the proband's five siblings had fasting hypertriglyceridemia or low-normal tissue adipose LPL activities or both. Retention of lipoprotein retinyl esters after vitamin A feeding was present only in the propositus. The maternal side of the extended pedigree contained individuals with Types IIA, IV, and V hyperlipoproteinemia, findings most consistent with autosomal dominant multiple lipoprotein-type hyperlipidemia (familial combined hyperlipidemia). This family and previously reported pedigrees of Type I HL probands have demonstrated phenotypic heterogeneity. Without specific genetic markers, homozygous LPL deficiency and complex multiple-gene mechanisms cannot be distinguished unambiguously. Parental hyperlipidemia in nuclear pedigrees of Type I HL probands should not be equated with heterozygous LPL deficiency in the absence of extended pedigree data or more informative markers. The possibility that the complex inheritance of two different genetic defects in lipoprotein transport can produce the Type I HL phenotype must be considered.

Topics: Adipose Tissue; Adolescent; Adult; Aged; Child; Diterpenes; Female; Humans; Hyperlipoproteinemia Type I; Hyperlipoproteinemias; Lipids; Lipoprotein Lipase; Male; Middle Aged; Pedigree; Phenotype; Retinyl Esters; Triglycerides; Vitamin A