Your search keyword '"Zech LA"' showing total 19 results

1. Hyperalphalipoproteinemia in human lecithin cholesterol acyltransferase transgenic rabbits. In vivo apolipoprotein A-I catabolism is delayed in a gene dose-dependent manner.

Author

Brousseau ME, Santamarina-Fojo S, Zech LA, Bérard AM, Vaisman BL, Meyn SM, Powell D, Brewer HB Jr, and Hoeg JM

Subjects

Animals, Animals, Genetically Modified, Animals, Newborn, Cholesterol Esters blood, Chromatography, High Pressure Liquid, Gene Expression, Humans, Hyperlipoproteinemias blood, Hyperlipoproteinemias metabolism, Kinetics, Phosphatidylcholine-Sterol O-Acyltransferase genetics, Phospholipids blood, Rabbits, Apolipoprotein A-I metabolism, Cholesterol, HDL blood, Hyperlipoproteinemias genetics, Phosphatidylcholine-Sterol O-Acyltransferase biosynthesis

Abstract

Lecithin cholesterol acyltransferase (LCAT) is an enzyme involved in the intravascular metabolism of high density lipoproteins (HDLs). Overexpression of human LCAT (hLCAT) in transgenic rabbits leads to gene dose-dependent increases of total and HDL cholesterol concentrations. To elucidate the mechanisms responsible for this effect, 131I-HDL apoA-I kinetics were assessed in age- and sex-matched groups of rabbits (n=3 each) with high, low, or no hLCAT expression. Mean total and HDL cholesterol concentrations (mg/dl), respectively, were 162+/-18 and 121+/-12 for high expressors (HE), 55+/-6 and 55+/-10 for low expressors (LE), and 29+/-2 and 28+/-4 for controls. Fast protein liquid chromatography analysis of plasma revealed that the HDL of both HE and LE were cholesteryl ester and phospholipid enriched, as compared with controls, with the greatest differences noted between HE and controls. These compositional changes resulted in an incremental shift in apparent HDL particle size which correlated directly with the level of hLCAT expression, such that HE had the largest HDL particles and controls the smallest. In vivo kinetic experiments demonstrated that the fractional catabolic rate(FCR, d(-1)) of apoA-I was slowest in HE (0.328+/-0.03) followed by LE (0.408+/-0.01) and, lastly, by controls (0.528+/-0.04). ApoA-I FCR was inversely associated with HDL cholesterol level (r=-0.851,P<0.01) and hLCAT activity (r=-0.816, P<0.01). These data indicate that fractional catabolic rate is the predominant mechanism by which hLCAT overexpression differentially modulates HDL concentrations in this animal model. We hypothesize that LCAT-induced changes in HDL composition and size ultimately reduce apoA-I catabolism by altering apoA-I conformation and/or HDL particle regeneration.

Published

1996

2. Increased catabolic rate of low density lipoproteins in humans with cholesteryl ester transfer protein deficiency.

Author

Ikewaki K, Nishiwaki M, Sakamoto T, Ishikawa T, Fairwell T, Zech LA, Nagano M, Nakamura H, Brewer HB Jr, and Rader DJ

Subjects

Adult, Aged, Apolipoprotein A-I blood, Apolipoproteins B blood, Cholesterol Ester Transfer Proteins, Cholesterol, HDL blood, Female, Homozygote, Humans, Kinetics, Lipoproteins blood, Lipoproteins, IDL, Lipoproteins, VLDL blood, Male, Reference Values, Triglycerides blood, Carrier Proteins genetics, Carrier Proteins metabolism, Cholesterol blood, Glycoproteins, Lipoproteins, LDL blood, Models, Biological

Abstract

The cholesteryl ester transfer protein (CETP) transfers lipids among lipoprotein particles and plays a central role in lipoprotein metabolism. Humans with genetic deficiency of CETP have both elevated HDL cholesterol and apolipoprotein A-I concentrations as well as decreased LDL cholesterol and apolipoprotein B levels. The present study was undertaken to elucidate the metabolic basis for the decreased LDL cholesterol and apo B levels in CETP deficiency. We conducted a series of in vivo apo B kinetic studies in tow unrelated homozygotes with CETP deficiency and in control subjects. A primed constant infusion of stable isotopically labeled phenylalanine was administered to the two CETP deficient subjects and control subjects and apo B kinetic parameters in VLDL, intermediate density lipoproteins, and LDL were obtained by using a multicompartmental model. The fractional catabolic rates (FCR) of LDL apo B were significantly increased in the CETP-deficient subjects (0.56 and 0.75/d) compared with the controls (mean FCR of 0.39/d). Furthermore, the production rates of apo B in VLDL and intermediate density lipoprotein were decreased by 55% and 81%, respectively, in CETP deficiency compared with the controls. In conclusion, CETP-deficient subjects were demonstrated to have substantially increased catabolic rates of LDL apo B as the primary metabolic basis for the low plasma levels of LDL apo B. This result indicates that the LDL receptor pathway may be up-regulated in CETP deficiency.

Published

1995

3. Dominant expression of type III hyperlipoproteinemia. Pathophysiological insights derived from the structural and kinetic characteristics of ApoE-1 (Lys146-->Glu).

Author

Mann WA, Lohse P, Gregg RE, Ronan R, Hoeg JM, Zech LA, and Brewer HB Jr

Subjects

Adult, Alleles, Cells, Cultured, DNA Mutational Analysis, Female, Fibroblasts metabolism, Heparin metabolism, Humans, Hyperlipoproteinemia Type III physiopathology, Kinetics, Male, Point Mutation, Protein Binding, Receptors, LDL metabolism, Structure-Activity Relationship, Apolipoproteins E genetics, Genes, Dominant, Hyperlipoproteinemia Type III genetics

Abstract

Type III hyperlipoproteinemia is characterized by delayed chylomicron and VLDL remnant catabolism and is associated with homozygosity for the apoE-2 allele. We have identified a kindred in which heterozygosity for an apoE mutant, apoE-1 (Lys146-->Glu), is dominantly associated with the expression of type III hyperlipoproteinemia. DNA sequence analysis of the mutant apoE gene revealed a single-point mutation that resulted in the substitution of glutamic acid (GAG) for lysine (AAG) at residue 146 in the proposed receptor-binding domain of apoE. The pathophysiological effect of this mutation was investigated in vivo by kinetic studies in the patient and six normal subjects, and in vitro by binding studies of apoE-1 (Lys146-->Glu) to LDL receptors on human fibroblasts and to heparin. The kinetic studies revealed that apoE-1 (Lys146-->Glu) was catabolized significantly slower than apoE-3 in normals (P < 0.005). In the proband, the plasma residence times of both apoEs were substantially longer and the production rate of total apoE was about two times higher than in the control subjects. ApoE-1 (Lys146-->Glu) was defective in interacting with LDL receptors, and its ability to displace LDL in an in vitro assay was reduced to 7.7% compared with apoE-3. The affinity of apoE-1 (Lys146-->Glu) to heparin was also markedly reduced compared with both apoE-2 (Arg158-->Cys) and apoE-3. These abnormal in vitro binding characteristics and the altered in vivo metabolism of apoE-1 (Lys146-->Glu) are proposed to result in the functional dominance of this mutation in the affected kindred.

Published

1995

4. The low density lipoprotein receptor is not required for normal catabolism of Lp(a) in humans.

Author

Rader DJ, Mann WA, Cain W, Kraft HG, Usher D, Zech LA, Hoeg JM, Davignon J, Lupien P, and Grossman M

Subjects

Adult, Child, Female, Heterozygote, Homozygote, Humans, Hyperlipoproteinemia Type II genetics, Male, Hyperlipoproteinemia Type II metabolism, Lipoprotein(a) metabolism, Lipoproteins, LDL metabolism, Receptors, LDL deficiency

Abstract

Lipoprotein(a) [Lp(a)] is an atherogenic lipoprotein which is similar in structure to low density lipoproteins (LDL). The role of the LDL receptor in the catabolism of Lp(a) has been controversial. We therefore investigated the in vivo catabolism of Lp(a) and LDL in five unrelated patients with homozygous familial hypercholesterolemia (FH) who have little or no LDL receptor activity. Purified 125I-Lp(a) and 131I-LDL were simultaneously injected into the homozygous FH patients, their heterozygous FH parents when available, and control subjects. The disappearance of plasma radioactivity was followed over time. As expected, the fractional catabolic rates (FCR) of 131I-LDL were markedly decreased in the homozygous FH patients (mean LDL FCR 0.190 d-1) and somewhat decreased in the heterozygous FH parents (mean LDL FCR 0.294 d-1) compared with controls (mean LDL FCR 0.401 d-1). In contrast, the catabolism of 125I-Lp(a) was not significantly different in the homozygous FH patients (mean FCR 0.251 d-1), heterozygous FH parents (mean FCR 0.254 d-1), and control subjects (mean FCR 0.287 d-1). In summary, absence of a functional LDL receptor does not result in delayed catabolism of Lp(a), indicating that the LDL receptor is not a physiologically important route of Lp(a) catabolism in humans.

Published

1995

5. The inverse association of plasma lipoprotein(a) concentrations with apolipoprotein(a) isoform size is not due to differences in Lp(a) catabolism but to differences in production rate.

Author

Rader DJ, Cain W, Ikewaki K, Talley G, Zech LA, Usher D, and Brewer HB Jr

Subjects

Adult, Aged, Apolipoproteins genetics, Apoprotein(a), Female, Humans, Lipoprotein(a) blood, Male, RNA, Messenger analysis, Apolipoproteins analysis, Lipoprotein(a) metabolism

Abstract

Lipoprotein(a) (Lp[a]) is an atherogenic lipoprotein which is similar in structure to low density lipoproteins (LDL) but contains an additional protein called apolipoprotein(a) (apo[a]). Apo(a) is highly polymorphic in size, and there is a strong inverse association between the size of the apo(a) isoform and the plasma concentration of Lp(a). We directly compared the in vivo catabolism of Lp(a) particles containing different size apo(a) isoforms to establish whether there is an effect of apo(a) isoform size on the catabolic rate of Lp(a). In the first series of studies, four normal subjects were injected with radio-labeled S1-Lp(a) and S2-Lp(a) and another four subjects were injected with radiolabeled S2-Lp(a) and S4-Lp(a). No significant differences in fractional catabolic rate were found between Lp(a) particles containing different apo(a) isoforms. To confirm that apo(a) isoform size does not influence the rate of Lp(a) catabolism, three subjects heterozygous for apo(a) were selected for preparative isolation of both Lp(a) particles. The first was a B/S3-apo(a) subject, the second a S4/S6-apo(a) subject, and the third an F/S3-apo(a) subject. From each subject, both Lp(a) particles were preparatively isolated, radiolabeled, and injected into donor subjects and normal volunteers. In all cases, the catabolic rates of the two forms of Lp(a) were not significantly different. In contrast, the allele-specific apo(a) production rates were more than twice as great for the smaller apo(a) isoforms than for the larger apo(a) isoforms. In a total of 17 studies directly comparing Lp(a) particles of different apo(a) isoform size, the mean fractional catabolic rate of the Lp(a) with smaller size apo(a) was 0.329 +/- 0.090 day-1 and of the Lp(a) with the larger size apo(a) 0.306 +/- 0.079 day-1, not significantly different. In summary, the inverse association of plasma Lp(a) concentrations with apo(a) isoform size is not due to differences in the catabolic rates of Lp(a) but rather to differences in Lp(a) production rates.

Published

1994

6. Delayed catabolism of high density lipoprotein apolipoproteins A-I and A-II in human cholesteryl ester transfer protein deficiency.

Author

Ikewaki K, Rader DJ, Sakamoto T, Nishiwaki M, Wakimoto N, Schaefer JR, Ishikawa T, Fairwell T, Zech LA, and Nakamura H

Subjects

Adult, Aged, Apolipoproteins B metabolism, Cholesterol Ester Transfer Proteins, Female, Genetic Carrier Screening, Homozygote, Humans, Iodine Radioisotopes, Kinetics, Lipoproteins, HDL blood, Male, Radioisotope Dilution Technique, Reference Values, Time Factors, Apolipoprotein A-I metabolism, Apolipoprotein A-II metabolism, Carrier Proteins genetics, Glycoproteins

Abstract

Deficiency of the cholesteryl ester transfer protein (CETP) in humans is characterized by markedly elevated plasma concentrations of HDL cholesterol and apoA-I. To assess the metabolism of HDL apolipoproteins in CETP deficiency, in vivo apolipoprotein kinetic studies were performed using endogenous and exogenous labeling techniques in two unrelated homozygotes with CETP deficiency, one heterozygote, and four control subjects. All study subjects were administered 13C6-labeled phenylalanine by primed constant infusion for up to 16 h. The fractional synthetic rates (FSRs) of apoA-I in two homozygotes with CETP deficiency (0.135, 0.134/d) were found to be significantly lower than those in controls (0.196 +/- 0.041/d, P < 0.01). Delayed apoA-I catabolism was confirmed by an exogenous radiotracer study in one CETP-deficient homozygote, in whom the fractional catabolic rate of 125I-apoA-I was 0.139/d (normal 0.216 +/- 0.018/d). The FSRs of apoA-II were also significantly lower in the homozygous CETP-deficient subjects (0.104, 0.112/d) than in the controls (0.170 +/- 0.023/d, P < 0.01). The production rates of apoA-I and apoA-II were normal in both homozygous CETP-deficient subjects. The turnover of apoA-I and apoA-II was substantially slower in both HDL2 and HDL3 in the CETP-deficient homozygotes than in controls. The kinetics of apoA-I and apoA-II in the CETP-deficient heterozygote were not different from those in controls. These data establish that homozygous CETP deficiency causes markedly delayed catabolism of apoA-I and apoA-II without affecting the production rates of these apolipoproteins.

Published

1993

7. Rapid in vivo transport and catabolism of human apolipoprotein A-IV-1 and slower catabolism of the apoA-IV-2 isoprotein.

Author

Rader DJ, Schäfer J, Lohse P, Verges B, Kindt M, Zech LA, Steinmetz A, and Brewer HB Jr

Subjects

Adult, Apolipoprotein A-I isolation & purification, Apolipoprotein A-I metabolism, Apolipoproteins A isolation & purification, Chromatography, Affinity, Chromatography, Gel, Female, Heterozygote, Homozygote, Humans, Iodine Radioisotopes, Kinetics, Lipoproteins, HDL blood, Lipoproteins, VLDL blood, Male, Phenotype, Radioisotope Dilution Technique, Time Factors, Apolipoproteins A genetics, Apolipoproteins A metabolism, Genetic Variation

Abstract

Apolipoprotein (apo) A-IV is a polymorphic, intestinally derived apolipoprotein that is genetically linked to and similar in structure to apoA-I, the major apolipoprotein in high density lipoproteins (HDL). ApoA-IV plays a potentially important role in lipoprotein metabolism and reverse cholesterol transport, but its in vivo metabolism is poorly understood. In order to gain insight into factors modulating apoA-IV metabolism in humans, the in vivo kinetics of the two major human apoA-IV isoproteins apoA-IV-1 and apoA-IV-2 were investigated in normolipidemic human subjects. 131I-apoA-IV-1 and 125I-apoA-IV-2 were reassociated with autologous plasma and injected into study subjects. Analysis of the kinetic data revealed a rapid mean fractional catabolic rate (FCR) for apoA-IV-1 of 2.42 +/- 0.11 d-1. The mean production, or transport, rate of apoA-IV-1 was 16.3 +/- 1.4 mg/kg per d. Plasma apoA-IV concentrations were highly correlated with apoA-IV production rate (r = 0.84, P < 0.001) and not correlated with apoA-IV fractional catabolic rate (r = 0.25, P = NS). The mean FCR of apoA-IV-2 was 2.21 +/- 0.10 d-1. In the ten subjects in whom 131I-apoA-IV-1 and 125I-apoA-IV-2 were simultaneously injected, the FCR of apoA-IV-2 was significantly slower by paired t test (P = 0.003). The FCR of apoA-IV-2 in an apoA-IV-2/2 homozygote was only 1.49 d-1, substantially slower than in all other subjects. We conclude that: (a) apoA-IV is a rapidly catabolized apolipoprotein in humans, with a fractional catabolic rate more than 10 times greater than that of apoA-I; (b) apoA-IV has a high absolute transport rate similar to that of apoA-I; (c) plasma levels of apoA-IV are primarily determined by apoA-IV production rate in normolipidemic subjects; and (d) the fractional catabolic rate of the common variant apoA-IV-2 is slower than that of the wild-type apoA-IV-1.

Published

1993

8. In vivo metabolism of a mutant form of apolipoprotein A-I, apo A-IMilano, associated with familial hypoalphalipoproteinemia.

Author

Roma P, Gregg RE, Meng MS, Ronan R, Zech LA, Franceschini G, Sirtori CR, and Brewer HB Jr

Subjects

Adult, Cholesterol blood, Female, Heterozygote, Humans, Kinetics, Male, Mutation, Tangier Disease metabolism, Triglycerides blood, Apolipoprotein A-I genetics, Apolipoprotein A-I metabolism, Hypolipoproteinemias metabolism, Lipoproteins, HDL blood

Abstract

Apo A-IMilano is a mutant form of apo A-I in which cysteine is substituted for arginine at amino acid 173. Subjects with apo A-IMilano are characterized by having low levels of plasma HDL cholesterol and apo A-I. To determine the kinetic etiology of the decreased plasma levels of the apo A-I in these individuals, normal and mutant apo A-I were isolated, radiolabeled with either 125I or 131I, and both types of apo A-I were simultaneously injected into two normal control subjects and two subjects heterozygous for apo A-IMilano. In the normal subjects, apo A-IMilano was catabolized more rapidly than the normal apo A-I (mean residence times of 5.11 d for normal apo A-I vs. 3.91 d for apo A-IMilano), clearly establishing that apo A-IMilano is kinetically abnormal and that it has a shortened residence time in plasma. In the two apo A-IMilano subjects, both types of apo A-I were catabolized more rapidly than normal (residence times ranging from 2.63 to 3.70 d) with normal total apo A-I production rates (mean of 10.3 vs. 10.4 mg/kg per d in the normal subjects). Therefore, in the subjects with apo A-IMilano, the decreased apo A-I levels are caused by rapid catabolism of apo A-I and not to a decreased production rate, and the abnormal apo A-IMilano leads to the rapid catabolism of both the normal and mutant forms of apo A-I in the affected subjects.

Published

1993

9. Cholesterol kinetics in subjects with bile fistula. Positive relationship between size of the bile acid precursor pool and bile acid synthetic rate.

Author

Schwartz CC, Zech LA, VandenBroek JM, and Cooper PS

Subjects

Bile metabolism, Biliary Fistula blood, Biliary Fistula surgery, Carbon Radioisotopes, Cholecystectomy, Cholesterol blood, Humans, Lipoproteins blood, Mevalonic Acid metabolism, Models, Biological, Radioisotope Dilution Technique, Tritium, Bile Acids and Salts metabolism, Biliary Fistula metabolism, Cholesterol metabolism, Liver metabolism

Abstract

Our aim was to identify and quantitate cholesterol pools and transport pathways in blood and liver. By studying bile fistula subjects, using several types of isotopic preparations, simultaneous labeling of separate cholesterol pools and sampling all components of blood and bile at frequent intervals, we developed a comprehensive multicompartmental model for cholesterol within the rapidly miscible pool. Data in six components (bile acids, esterified cholesterol in whole plasma, and free cholesterol in blood cells, bile, alpha lipoproteins, and beta lipoproteins) were modeled simultaneously with the SAAM program. The analysis revealed extensive exchange of free cholesterol between HDL and liver, blood cells, and other tissues. There was net free cholesterol transport from HDL to the liver in most subjects. The major organ that removed esterified cholesterol from blood was the liver. A large portion (4,211 mumol) of total hepatic cholesterol comprised a pool that turned over rapidly (t1/2 of 72 min) by exchanging mainly with plasma HDL and was the major source of bile acids and biliary cholesterol. Only 6% of hepatic newly synthesized cholesterol was used directly for bile acid synthesis: the analysis showed that 94% of newly synthesized cholesterol was partitioned into the large hepatic pool (putative plasma membrane free cholesterol) which exchanged rapidly with plasma lipoproteins. Bile acid synthetic rate correlated directly with the size of the large hepatic pool. In conclusion, hepatic and blood cholesterol pools and transports have been quantitated. HDL plays a central role in free cholesterol exchange/transport between all tissues and plasma. In humans, the metabolically active pool comprises a large portion of total hepatic cholesterol that, in part, regulates bile acid synthesis.

Published

1993

10. Variation in lipoprotein(a) concentrations among individuals with the same apolipoprotein (a) isoform is determined by the rate of lipoprotein(a) production.

Author

Rader DJ, Cain W, Zech LA, Usher D, and Brewer HB Jr

Subjects

Adult, Apolipoproteins chemistry, Apoprotein(a), Female, Humans, Male, Phenotype, Apolipoproteins blood, Lipoprotein(a) biosynthesis, Lipoprotein(a) blood

Abstract

Lipoprotein(a) [Lp(a)] is an atherogenic lipoprotein which is similar in structure to, but metabolically distinct from, LDL. Factors regulating plasma concentrations of Lp(a) are poorly understood. Apo(a), the protein that distinguishes Lp(a) from LDL, is highly polymorphic, and apo(a) size is inversely correlated with plasma Lp(a) level. Even within the same apo(a) isoform class, however, plasma Lp(a) concentrations vary widely. A series of in vivo kinetic studies were performed using purified radiolabeled Lp(a) in individuals with the same apo(a) isoform but different Lp(a) levels. In a group of seven subjects with a single S4-apo(a) isoform and Lp(a) levels ranging from 1 to 13.2 mg/dl, the fractional catabolic rate (FCR) of 131I-labeled S2-Lp(a) (mean 0.328 day-1) was not correlated with the plasma Lp(a) level (r = -0.346, P = 0.45). In two S4-apo(a) subjects with a 10-fold difference in Lp(a) level, the FCR's of 125I-labeled S4-Lp(a) were very similar in both subjects and not substantially different from the FCRs of 131I-S2-Lp(a) in the same subjects. In four subjects with a single S2-apo(a) isoform and Lp(a) levels ranging from 9.4 to 91 mg/dl, Lp(a) concentration was highly correlated with Lp(a) production rate (r = 0.993, P = 0.007), but poorly correlated with Lp(a) FCR (mean 0.304 day-1). Analysis of Lp(a) kinetic parameters in all 11 subjects revealed no significant correlation of Lp(a) level with Lp(a) FCR (r = -0.53, P = 0.09) and a strong correlation with Lp(a) production rate (r = 0.99, P < 0.0001). We conclude that the substantial variation in Lp(a) levels among individuals with the same apo(a) phenotype is caused primarily by differences in Lp(a) production rate.

Published

1993

11. In vivo metabolism of proapolipoprotein A-I in Tangier disease.

Author

Bojanovski D, Gregg RE, Zech LA, Meng MS, Bishop C, Ronan R, and Brewer HB Jr

Subjects

Adult, Apolipoprotein A-I, Female, Humans, Kinetics, Male, Middle Aged, Apolipoproteins A metabolism, Hypolipoproteinemias metabolism, Protein Precursors metabolism, Tangier Disease metabolism

Abstract

Tangier disease is a rare familial disorder characterized by extremely low levels of apolipoprotein A-I (apoA-I) and high density lipoproteins (HDL). In normal subjects, proapoA-I is secreted into plasma and converted to mature apoA-I by the cleavage of the amino-terminal six amino acids with the major isoprotein in plasma being mature apoA-I. In contrast, in Tangier disease there is a marked relative increase of proapoA-I as compared with mature apoA-I. ProapoA-I and mature apoA-I were isolated from normal and Tangier disease subjects, radio-labeled, and autologous apoA-I isoproteins injected into normal and Tangier subjects. The in vivo catabolism and conversion of proapoA-I and mature apoA-I in normal and Tangier disease subjects were quantitated. A comparison of the rate of catabolism of apoA-I isoproteins from plasma revealed a significantly faster rate of catabolism of both isoproteins of apoA-I in Tangier subjects when compared with normal subjects. The fractional conversion rate of proapoA-I to mature apoA-I was 3.9 d-1 in normal subjects and 3.6 d-1 in Tangier subjects. The results indicate that (a) apoA-I enters plasma as the pro isoprotein in both normal and Tangier subjects, (b) Tangier disease subjects have a normal fractional rate of conversion of proapoA-I to mature apoA-I, (c) proapoA-I is catabolized at the same rate as mature apoA-I in Tangier subjects, and (d) Tangier subjects catabolize both pro and mature apoA-I at a much greater rate than do normal subjects. Therefore, the relative increase in proapoA-I in Tangier disease is due to a marked decrease in mature apoA-I resulting from rapid catabolism of both pro- and mature apoA-I and not to defective conversion of proapoA-I to mature apoA-I.

Published

1987

12. Kinetic model for production and metabolism of very low density lipoprotein triglycerides. Evidence for a slow production pathway and results for normolipidemic subjects.

Author

Zech LA, Grundy SM, Steinberg D, and Berman M

Subjects

Glycerol blood, Humans, Kinetics, Mathematics, Lipoproteins, VLDL blood, Models, Biological, Triglycerides blood

Abstract

A model for the synthesis and degradation of very low density lipoprotein triglyceride (VLDL-TG) in man is proposed to explain plasma VLDL-TG radioactivity data from studies conducted over a 48-h interval after injection of glycerol labeled with 14C, 3H, or both. The curve describing the radioactivity of plasma VLDL triglycerides reaches a maximum at about 2 h, after which the decay is biphasic in all cases; the late curvature becoming evident only after 8--12 h. To fit the complex curve, it was necessary to postulate two pathways for the incorporation of plasma glycerol into VLDL-TG, one much slower than the other. A process of stepwise delipidation of VLDL in the plasma compartment, previously proposed for VLDL apoprotein models, was also necessary. Predicted VLDL-TG synthesis rates calculated with this model can differ significantly from those based on experiments of shorter duration in which the slow VLDL-TG component is not apparent. The results of these studies strongly support the interpretation that the late, slow component of the VLDL-TG activity curve is predominantly due to the slowly turning-over precursor compartment in the conversion pathway and is not due either to a slow compartment in the labeled precursor, plasma free glycerol, or to an exchange of plasma VLDL-TG with an extravascular compartment. It also cannot, in these studies, be attributed to a slowly turning-over VLDL-TG moiety in the plasma. The model was tested with data from 59 studies including normal subjects and patients with obesity and(or) various forms of hyperlipoproteinemia. Good fits were obtained in all cases, and the estimated parameter values and their uncertainties for 13 normolipemic nonobese subjects are presented. Sensitivty testing was carried out to determine how critical various parameter estimations are to the assumptions introduced in the modeling.

Published

1979

13. Familial apolipoprotein E deficiency.

Author

Schaefer EJ, Gregg RE, Ghiselli G, Forte TM, Ordovas JM, Zech LA, and Brewer HB Jr

Subjects

Adolescent, Adult, Aged, Child, Cholesterol blood, Female, Homozygote, Humans, Hyperlipoproteinemia Type III blood, Hyperlipoproteinemia Type III complications, Lipoproteins blood, Male, Middle Aged, Pedigree, Phospholipids blood, Reference Values, Skin Diseases etiology, Triglycerides blood, Xanthomatosis etiology, Apolipoproteins E deficiency, Hyperlipoproteinemia Type III genetics

Abstract

A unique kindred with premature cardiovascular disease, tubo-eruptive xanthomas, and type III hyperlipoproteinemia (HLP) associated with familial apolipoprotein (apo) E deficiency was examined. Homozygotes (n = 4) had marked increases in cholesterol-rich very low density lipoproteins (VLDL) and intermediate density lipoproteins (IDL), which could be effectively lowered with diet and medication (niacin, clofibrate). Homozygotes had only trace amounts of plasma apoE, and accumulations of apoB-48 and apoA-IV in VLDL, IDL, and low density lipoproteins. Radioiodinated VLDL apoB and apoE kinetic studies revealed that the homozygous proband had markedly retarded fractional catabolism of VLDL apoB-100, apoB-48 and plasma apoE, as well as an extremely low apoE synthesis rate as compared to normals. Obligate heterozygotes (n = 10) generally had normal plasma lipids and mean plasma apoE concentrations that were 42% of normal. The data indicate that homozygous familial apoE deficiency is a cause of type III HLP, is associated with markedly decreased apoE production, and that apoE is essential for the normal catabolism of triglyceride-rich lipoprotein constituents.

Published

1986

14. Metabolism of immunoglobulin E in patients with markedly elevated serum immunoglobulin E levels.

Author

Dreskin SC, Goldsmith PK, Strober W, Zech LA, and Gallin JI

Subjects

Body Fluid Compartments, Humans, Hypergammaglobulinemia complications, Hypergammaglobulinemia immunology, Hypersensitivity, Immediate complications, Hypersensitivity, Immediate immunology, Job Syndrome immunology, Metabolic Clearance Rate, Hypergammaglobulinemia blood, Hypersensitivity, Immediate blood, Immunoglobulin E metabolism, Job Syndrome blood, Phagocyte Bactericidal Dysfunction blood

Abstract

The metabolism of human IgE was studied in normals, severe atopics, and patients with the hyperimmunoglobulin E-recurrent infection (HIE; Job's) syndrome to determine whether IgE metabolism is altered in patients with marked elevation of serum IgE. Purified polyclonal 125I-IgE was administered intravenously and serial plasma and urine samples were obtained. After analysis, the metabolic data support previously published evidence that IgE (at concentrations found in normal individuals) is catabolized at a higher fractional rate than other immunoglobulins and is catabolized by both an intravascular and an extravascular pathway. In addition, the data show that the fractional catabolic rate for IgE is significantly less for the atopic patients (mean +/- SEM = 0.20 +/- 0.01) and for the HIE patients (0.15 +/- 0.02) than for the normal volunteers (0.52 +/- 0.06; P less than 0.01) and is inversely related (r = -0.851; P less than 0.001) to the serum IgE concentration. These findings have specific importance in showing that decreased fractional catabolic rate contributes substantially to elevation of IgE in atopic and HIE patients. In addition, the findings have general significance in that they lead to a unifying hypothesis of immunoglobulin catabolism.

Published

1987

15. Increased prevalence of apolipoprotein E4 in type V hyperlipoproteinemia.

Author

Ghiselli G, Schaefer EJ, Zech LA, Gregg RE, and Brewer HB Jr

Subjects

Apolipoprotein E4, Apolipoproteins E, Cholesterol blood, Humans, Isoelectric Focusing, Lipoproteins, VLDL blood, Middle Aged, Phenotype, Triglycerides blood, Apolipoproteins blood, Hyperlipoproteinemia Type V blood

Abstract

Type V hyperlipoproteinemia (HLP) is characterized clinically by hepatosplenomegaly, occasional eruptive xanthomas, and an increased incidence of pancreatitis. These patients have striking hypertriglyceridemia due to increased plasma chylomicron and very low density lipoprotein concentrations in the fasting state, without a deficiency of lipoprotein lipase or its activator protein, apolipoprotein (apo) C-II. ApoE, a protein constituent of triglyceride-rich lipoproteins, has been implicated in the receptor-mediated hepatic uptake of these particles. ApoE has three major alleles: E2, E3, and E4, and the products of these alleles are apoE2, apoE3, and apoE4, respectively. ApoE phenotypes were determined in 30 type V HLP patients as well as in 37 normal volunteers. Among the type V patients, 33.3% were noted to be homozygous, and 40.0% heterozygous for E4 (normal, 2.7 and 21.6%, respectively). These data suggest that apoE4 may play a role in the etiology of the hyperlipidemia in a significant number of type V HLP patients.

Published

1982

16. Tangier disease. High density lipoprotein deficiency due to defective metabolism of an abnormal apolipoprotein A-i (ApoA-ITangier).

Author

Schaefer EJ, Kay LL, Zech LA, and Brewer HB Jr

Subjects

Adult, Apolipoprotein A-I, Female, Heterozygote, Homozygote, Humans, Iodine Radioisotopes, Lipids blood, Lipoproteins blood, Lipoproteins, HDL genetics, Male, Tangier Disease diagnosis, Tangier Disease genetics, Apolipoproteins genetics, Apolipoproteins A, Hypolipoproteinemias blood, Lipoproteins, HDL deficiency, Tangier Disease blood

Abstract

Tangier disease is a rare familial disorder characterized by enlarged orange tonsils, transient peripheral neuropathy, hepatosplenomegaly, and lymphadenopathy, as well as striking reductions in plasma high density lipoproteins (HDL) and their major protein constituents, apolipoproteins (apo)A-I and A-II. In order to test the hypothesis that Tangier patients have abnormal apoA-I or apoA-II, the in vitro lipoprotein binding and in vivo metabolic characteristics of these proteins isolated from normal and Tangier plasma, were studied in normal subjects and patients with Tangier disease. After incubation with normal plasma, significantly greater percentages of radiolabeled Tangier apoA-I were associated with the 1.063-g/ml supernate (6%) and the 1.21 g/ml infranate (19%), and a lower percentage with HDL (75%), than those observed for normal apoA-I (2, 8, and 90%, respectively). In contrast, the lipoprotein binding properties of normal and Tangier apoA-II were very similar. Following the injection of radiolabeled normal and Tangier apoA-I into normal subjects (n = 4), the mean residence times of the specific activity for apoA-I(Tangier) were significantly lower, both in plasma (1.29 d) and in HDL (1.34 d), than those observed for normal apoA-I (3.80 and 4.06 d). In Tangier homozygotes the decay rates of these tracers were very rapid and were similar. No significant differences between the kinetics of normal and Tangier apoA-II were observed in normal subjects (n = 2). Tangier homozygotes (n = 3) had mean plasma HDL cholesterol, apoA-I, and apoA-II concentrations that were 4, 2, and 11% of normal (n = 24), respectively, whereas for heterozygotes (n = 3) these values were 46, 62, and 68% of normal. In homozygotes, in contrast to normals or heterozygotes, a significant fraction of both apoA-I and apoA-II were found in the 1.063-g/ml supernate instead of in HDL. Homozygotes had apoA-I(Tangier) synthesis rates and residence times that were 41 and 5% of values observed for normal apoA-I in normal subjects, and for apoA-II in homozygotes, these parameters were 63 and 18% of normal. Heterozygotes had apoA-I synthesis rates and residence times that were 92 and 66% of normal, and for apoA-II these values were 101 and 64% of normal. These data are consistent with the concept that apoA-I(Tangier) is functionally and metabolically distinct from normal apoA-I, and is the cause of the striking hypercatabolism of apoA-I and apoA-II, and the lipoprotein abnormalities observed in Tangier disease.

Published

1982

17. Transport of apolipoproteins A-I and A-II by human thoracic duct lymph.

Author

Anderson DW, Schaefer EJ, Bronzert TJ, Lindgren FT, Forte T, Starzl TE, Niblack GD, Zech LA, and Brewer HB Jr

Subjects

Biological Transport, Cholesterol blood, Cholesterol metabolism, Humans, Lipoproteins, HDL blood, Lipoproteins, HDL metabolism, Molecular Weight, Triglycerides blood, Triglycerides metabolism, Apolipoproteins metabolism, Lymph metabolism

Abstract

The daily transport of human plasma apolipoproteins A-I and A-II, triglyceride, and total cholesterol from the thoracic duct lymph into plasma was measured in two subjects before and three subjects after renal transplantation. Lymph triglyceride transport was approximately 83% of the daily ingested fat loads, whereas lymph cholesterol transport was consistently greater than the amount of daily ingested cholesterol. Lymph apolipoprotein transport significantly (P < 0.05) exceeded the predicted apolipoprotein synthesis rate by an average of 659+/-578 mg/d for apolipoprotein A-I and 109+/-59 mg/d for apolipoprotein A-II among the five subjects. It is estimated that 22-77% (apolipoprotein A-I) and 28-82% (apolipoprotein A-II) of daily total body apolipoprotein synthesis takes place in the intestine. Lymph high density lipoprotein particles are mostly high density lipoprotein(2b) and high density lipoprotein(2a) and have a greater overall relative triglyceride content and a smaller relative cholesteryl ester content when compared with homologous plasma high density lipoproteins. The major quantity of both lymph apolipoprotein A-I (81+/-8%) and apolipoprotein A-II (90+/-11%) was found within high density lipoproteins with almost all of the remainder found in chylomicrons and very low density lipoproteins. The combined results are consistent with a major contribution of the intestine to total body synthesis of apolipoprotein A-I and apolipoprotein A-II. An important role of lymph in returning filtered apolipoprotein to plasma in association with high density lipoproteins is proposed. Accompanying the return of filtered apolipoprotein to the plasma is a probable transformation, both in size and composition, of at least some of the lymph high density lipoprotein(2b) and high density lipoprotein(2a) particles into high density lipoprotein(3).

Published

1981

18. Norepinephrine metabolism in humans. Kinetic analysis and model.

Author

Linares OA, Jacquez JA, Zech LA, Smith MJ, Sanfield JA, Morrow LA, Rosen SG, and Halter JB

Subjects

Adult, Biological Transport, Female, Humans, Kinetics, Male, Metabolic Clearance Rate, Norepinephrine pharmacokinetics, Posture, Radioisotope Dilution Technique, Tritium, Norepinephrine metabolism

Abstract

The present study was undertaken to quantify more precisely and to begin to address the problem of heterogeneity of the kinetics of distribution and metabolism of norepinephrine (NE) in humans, by using compartmental analysis. Steady-state NE specific activity in arterialized plasma during [3H]NE infusion and postinfusion plasma disappearance of [3H]NE were measured in eight healthy subjects in the supine and upright positions. Two exponentials were clearly identified in the plasma [3H]NE disappearance curves of each subject studied in the supine (r = 0.94-1.00, all P less than 0.01) and upright (r = 0.90-0.98, all P less than 0.01) positions. A two-compartment model was the minimal model necessary to simultaneously describe the kinetics of NE in the supine and upright positions. The NE input rate into the extravascular compartment 2, estimated with the minimal model, increased with upright posture (1.87 +/- 0.08 vs. 3.25 +/- 0.2 micrograms/min per m2, P less than 0.001). Upright posture was associated with a fall in the volume of distribution of NE in compartment 1 (7.5 +/- 0.6 vs. 4.7 +/- 0.3 liters, P less than 0.001), and as a result of that, there was a fall in the metabolic clearance rate of NE from compartment 1 (1.80 +/- 0.11 vs. 1.21 +/- 0.08 liters/min per m2, P less than 0.001). We conclude that a two-compartment model is the minimal model that can accurately describe the kinetics of distribution and metabolism of NE in humans.

Published

1987

19. Abnormal in vivo metabolism of apolipoprotein E4 in humans.

Author

Gregg RE, Zech LA, Schaefer EJ, Stark D, Wilson D, and Brewer HB Jr

Subjects

Adolescent, Adult, Apolipoprotein E3, Apolipoprotein E4, Apolipoproteins E genetics, Female, Homozygote, Humans, Hypercholesterolemia genetics, Hyperlipoproteinemia Type V genetics, Iodine Radioisotopes, Kinetics, Lipoproteins blood, Lipoproteins, HDL blood, Lipoproteins, IDL, Lipoproteins, LDL blood, Lipoproteins, VLDL blood, Male, Phenotype, Apolipoproteins E blood

Abstract

Apolipoprotein E (apoE) is important in modulating the catabolism of remnants of triglyceride-rich lipoprotein particles. It is a polymorphic protein with the three common alleles coding for apoE2, apoE3, and apoE4. ApoE3 is considered the normal isoform, while apoE4 is associated both with hypercholesterolemia and type V hyperlipoproteinemia. We quantitated the kinetics of metabolism of apoE4 in 19 normolipidemic apoE3 homozygotes and 1 normolipidemic apoE4 homozygote, and compared this with the metabolism of apoE3 in 12 normolipidemic apoE3 homozygotes. In the apoE3 homozygous subjects, apoE4 was catabolized twice as fast as apoE3, with a mean plasma residence time of 0.37 +/- 0.01 d (+/- SEM) and 0.73 +/- 0.05 (P less than 0.001), respectively. When plasma was fractionated into the lipoprotein subclasses, the greatest amount of labeled apoE4 was present on very low density lipoproteins, while the largest fraction of labeled apoE3 was associated with high density lipoproteins. The plasma apoE concentration was decreased in an apoE4 homozygote compared with the apoE3 homozygotes (3.11 mg/dl vs. 4.83 +/- 0.35 mg/dl). The reduced apoE4 concentration was entirely due to a decreased apoE4 residence time in the apoE4 homozygote (0.36 d vs. 0.73 +/- 0.05 d for apoE3 in apoE3 homozygotes). These results indicate that apoE4 is kinetically different than apoE3, and suggest that the presence of apoE4 in hypercholesterolemic and type V hyperlipoproteinemic individuals may play an important pathophysiological role in the development of these dyslipoproteinemias.

Published

1986