Effect of weight loss with reduction of intra-abdominal fat on lipid metabolism in older men.

How weight loss improves lipid levels is poorly understood. Cross-sectional studies have suggested that accumulation of fat in intra-abdominal stores (IAF) may lead to abnormal lipid levels, increased hepatic lipase (HL) activity, and smaller low density lipoprotein (LDL) particle size. To determine what effect loss of IAF would have on lipid parameters, 21 healthy older men underwent diet-induced weight loss. During a period of weight stability before and after weight loss, subjects underwent studies of body composition, lipids, measurement of postheparin lipoprotein and HL lipase activities, cholesteryl ester transfer protein activity, and insulin sensitivity (Si). After an average weight loss of 10%, reductions in fat mass, IAF, and abdominal s.c. fat were seen, accompanied by reductions in levels of triglyceride, very low density lipoprotein cholesterol, apolipoprotein B, and HL activity. High density lipoprotein-2 cholesterol and Si increased. In those subjects with pattern B LDL at baseline, LDL particle size increased. Cholesteryl ester transfer protein activity did not change. Changes in IAF and Si correlated with a decrease in HL activity (although not independently of each other). In summary, in men undergoing diet-induced weight loss, only loss of IAF was found to be associated with a reduction in HL, which is associated with beneficial effects on lipid levels.

Increased dietary micronutrients decrease serum homocysteine concentrations in patients at high risk of cardiovascular disease.

BACKGROUND: Elevated blood homocysteine is a risk factor for cardiovascular disease. A 5-micromol/L increase is associated with an approximately 70% increase in relative risk of cardiovascular disease in adults. For patients with established risk factors, this risk is likely even greater. OBJECTIVE: Effects of increased dietary folate and recommended intakes of vitamins B-12 and B-6 on serum total homocysteine (tHcy) were assessed in individuals at high risk of cardiovascular disease. DESIGN: This trial was conducted at 10 medical research centers in the United States and Canada and included 491 adults with hypertension, dyslipidemia, type 2 diabetes, or a combination thereof. Participants were randomly assigned to follow a prepared meal plan (PMP; n = 244) or a self-selected diet (SSD; n = 247) for 10 wk, which were matched for macronutrient content. The PMP was fortified to provide >/=100% of the recommended dietary allowances for 23 micronutrients, including folate. RESULTS: Mean folate intakes at 10 wk were 601 +/- 143 microgram/d with the PMP and 270 +/- 107 microgram/d with the SSD. With the PMP, serum tHcy concentrations fell from 10.8 +/- 5.8 to 9.3 +/- 4.9 micromol/L (P < 0.0001) between weeks 0 and 10 and the change was associated with increased intakes of folate, vitamin B-12, and vitamin B-6 and with increased serum and red blood cell folate and serum vitamin B-12 concentrations. tHcy concentrations did not change significantly with the SSD. CONCLUSIONS: The PMP resulted in increased intakes and serum concentrations of folate and vitamin B-12. These changes were associated with reduced serum tHcy concentrations in persons at high risk of cardiovascular disease.

Regulatory mutations in the human lipoprotein lipase gene in patients with familial combined hyperlipidemia and coronary artery disease.

We previously reported a compound heterozygote [T(-39)C/T(-93)G] in the human lipoprotein lipase (LPL) gene promoter in one out of 19 patients with familial combined hyperlipidemia (FCHL) and reduced post-heparin plasma LPL levels. The T(-39)C substitution resulted in 85% decrease in LPL promoter activity. Further screening of Caucasian patients with FCHL, coronary artery disease (CAD), and of unselected Caucasian subjects revealed four additional LPL promoter variants. Among the same 19 FCHL patients with reduced LPL levels, we found one heterozygote for a G(-53)C substitution. Among 115 CAD patients, we found five heterozygotes and one homozygote for the T(-93)G substitution and one heterozygote for a CC insertion between +13 and +19 of the 5' untranslated region. In a group of 183 unselected subjects, three heterozygotes with the T(-93)G substitution were found. The G(-53)C substitution led to approximately 70-75% decrease in promoter activity as assayed by transient transfections of THP-1 (macrophage-like) and C2C12 (myotube-like) cells. The T(-93)G substitution resulted in reduction of promoter activity by approximately 40-50%. The CC insertion between +13 and +19 caused a decrease in promoter activity by 20% in THP-1 and 50% in C2C12. Substitutions at -79 and -95, which had no effect on promoter function, were also discovered in the population samples studied. The finding of two promoter mutations (-39 and -53) among 19 FCHL patients with diminished LPL, but not among the other groups of subjects, suggests a potential role of regulatory mutations of the LPL gene in the development of dyslipidemia in FCHL.

Paraoxonase genotypes, lipoprotein lipase activity, and HDL.

Paraxonase, an enzyme associated with the high density lipoprotein (HDL) particle, hydrolyzes paraoxon, the active metabolite of the insecticide parathion. Several studies have shown that paraxonase levels in humans have a distribution characteristic of two alleles, one with low activity and the other with high activity. Paraoxonase also has arylesterase activity, which does not exhibit activity polymorphism and can therefore serve as an estimate of enzyme protein. Although the ability of paraoxon to irreversibly inhibit lipoprotein lipase (LPL) has been exploited experimentally for many years, the role of plasma paraoxonase in lipoprotein metabolism is unknown. Seventy-two normal individuals were examined for paraoxonase genotypes, plasma paraoxonase and arylesterase activities, postheparin LPL and hepatic lipase (HL) activities, and lipoprotein levels to determine whether (1) paraoxonase activity or genotype determines lipoprotein levels via an effect on LPL or HL activity or (2) variation in LPL and HL activities determines HDL levels and indirectly affects paraoxonase activity and protein levels in plasma. In the entire group, paraoxonase activity was related to arylesterase activity and genotype. Whereas arylesterase activity was correlated with HDL cholesterol (HDL-C) and apolipoproteinA-I (apoA-I) levels, neither arylesterase nor paraoxonase was correlated with LPL or HL activity. Furthermore, LPL activity was positively correlated and HL inversely correlated with HDL cholesterol and apoA-I levels, whereas LPL was inversely correlated with triglyceride levels. The paraoxonase genotypes of the study group were 30 individuals homozygous for the low-activity allele, 38 heterozygotes, and 4 individuals homozygous for the high-activity allele. Paraoxonase genotype accounted for approximately .75 of the variation in paraoxonase activity. Paraoxonase activity was linearly related to arylesterase activity within each subgroup. No difference in either LPL or HL activity was seen as a function of paraoxonase genotype, nor were differences seen in plasma triglyceride or HDL-C by genotype by ANOVA. The relation between LPL and HL and components of HDL in the paraoxonase genotypic subgroups in general reflected the associations seen in the group as a whole. Multivariate analysis showed that LPL, HL, and arylesterase, a measure of paraoxonase mass, were independent predictors of HDL cholesterol, while paraoxonase genotype or activity was not. Thus, variation in LPL and HL appears to be significantly related to HDL cholesterol and apoA-I levels. The levels of HDL are a major correlate of paraoxonase protein levels, while paraoxonase genotype is the major predictor of plasma paraoxonase activity.

A novel A-->G mutation in intron I of the hepatic lipase gene leads to alternative splicing resulting in enzyme deficiency.

We have identified the underlying molecular defect in a patient with hepatic lipase (HL) deficiency presenting with hypertriglyceridemia and premature cardiovascular disease. DNA sequencing of polymerase chain reaction (PCR) amplified DNA and digestion with BsrI established homozygosity for an A-->G mutation in intron I of the patient's hepatic lipase gene. This mutation introduces an additional AG motif within a potential branch lariat signal located 13 bp upstream of the native 3' splice site. Two minigene constructs (normal and mutant) consisting of exons 1 and 2 as well as 192 bp of intron I of HL were generated by the overlap PCR extension method and transfected in human 293 cells. Sequence analysis of reverse transcribed, amplified cDNA generated from total RNA isolated from transfected cells demonstrated the presence of abnormally spliced products containing 13 and 78 additional bases as well as the accumulation of unspliced mRNA. No normally spliced mRNA was identified. Thus, the A-->G mutation disrupts normal splicing of intron I and generates a new AG site that is utilized as an alternative 3' splice signal leading to the most prominent RT-PCR product in vitro. Translation of these alternatively spliced products leads to premature termination resulting in the synthesis of a truncated, non-functional enzyme. The absence of normal HL protein in post heparin plasma of this patient was confirmed by Western blotting. DNA restriction analysis demonstrated that all four of the proband's children, who exhibit HL activity levels between those of the HL-deficient father and the mother with normal HL activity, are heterozygotes for the splice site mutation. Thus, our studies establish the functional significance of a novel mutation in the HL gene of a patient presenting with HL deficiency.

Two novel apolipoprotein A-IV variants in individuals with familial combined hyperlipidemia and diminished levels of lipoprotein lipase activity.

It has been suggested that apo A-IV may play a role in modulating the activation of lipoprotein lipase (LPL) by apo C-II (Goldberg et al., 1990). Therefore, the role of genetic variation at the apolipoprotein A-IV locus in familial combined hyperlipidemia (FCHL) was investigated. A subset of FCHL patients with half the level of plasma LPL activity was screened by single-strand conformation polymorphism (SSCP) for variants in the apolipoprotein A-IV gene. Two of 20 such individuals were found to be heterozygous carriers of previously undescribed amino acid substitutions: S158L and R 244Q substitutions, designated A-IV-Seattle-1 and A-IV-Seattle-2, respectively. These substitutions were not detected among 20 other FCHL patients with normal LPL levels and among 97 unselected medical students. The finding of these two alleles among only the 20 patients with FCHL with reduced levels of LPL suggests an association with this phenotype. It is hypothesized that these two alleles may contribute, along with alleles of other genes or environmental factors, to the development of FCHL. A third previously undescribed variant (A141S) was observed in four (two homozygotes and two heterozygotes) of the 97 medical students.

A mutation in the promoter of the lipoprotein lipase (LPL) gene in a patient with familial combined hyperlipidemia and low LPL activity.

We have identified a naturally occurring mutation in the promoter of the lipoprotein lipase (LPL) gene. One of 20 patients with familial combined hyperlipidemia (FCHL) and reduced levels of postheparin plasma LPL activity was found to be a heterozygote carrier of this mutation. The mutation, a T-->C substitution at nt -39, occurred in the binding site of the transcription factor Oct-1. As a result, the transcriptional activity of the mutant promoter was < 15% of wild type, as determined by transfection studies in the human macrophage-like cell line THP-1. This decrease in promoter activity was observed in undifferentiated as well as in phorbol ester-differentiated THP-1 cells. Furthermore, the inductive effect of elevating the levels of intracellular cAMP was equally reduced. This mutation was not present among 20 FCHL patients with normal plasma LPL levels nor has it been reported among individuals with familial LPL deficiency. Thus, heterozygosity for LPL promoter mutations may be one of several factors that contribute to the etiology of FCHL.

The LPL gene in individuals with familial combined hyperlipidemia and decreased LPL activity.

Familial combined hyperlipidemia (FCHL) is an oligogenic disorder, with family members having elevated apolipoprotein B-100 levels and either elevated plasma cholesterol or triglyceride levels or both. Obligate heterozygous parents of children with lipoprotein lipase (LPL) deficiency express a mild FCHL phenotype. Of patients with FCHL, 36% have diminished postheparin LPL activity and mass values that are comparable with those of obligate heterozygotes for LPL deficiency. It is hypothesized that heterozygosity for mutations in the LPL gene could contribute to FCHL in this subset of patients. Single-strand conformation polymorphism (SSCP) analysis, direct DNA sequencing, and Southern blot analysis were used to examine exons 1 through 9 and exon-intron junctions of the LPL gene in 20 patients with FCHL and low LPL activity and mass. One subject had a substitution (GAC-->AAC) in exon 2, changing Asp9 to Asn. Two subjects had a previously undescribed "silent" substitution (GTG-->GTA) in exon 3 at Val108. Three patients had a premature termination at codon 447 in exon 9 resulting in truncation of the mature protein by two amino acids. In addition to SSCP analysis, exons 4, 5, and 6, where almost all mutations in LPL-deficient patients have been found, were sequenced and no additional mutations were found. Southern blot analysis of the LPL gene revealed one subject with heterozygous loss of an EcoRI site but without an abnormality in Stu I restriction fragments; this mutation is therefore unlikely to be functionally significant. The substitutions identified at codons 9 and 447 have previously been found not to affect lipolytic activity when expressed in vitro.(ABSTRACT TRUNCATED AT 250 WORDS)

Apolipoprotein B and a second major gene locus contribute to phenotypic variation of spontaneous hypercholesterolemia in pigs.

The Lpb5 apolipoprotein B (apoB) allele occurs in pigs with spontaneous hypercholesterolemia. Low-density lipoprotein (LDL) from these pigs binds to the LDL receptor with a lower affinity and is cleared from the circulation more slowly than control pig LDL. However, the severity of hypercholesterolemia in pigs with the mutant apoB allele is highly variable. This study aimed to determine the metabolic basis for the phenotypic heterogeneity among Lpb5 pigs. Lpb5 pigs were divided into two groups: those with plasma cholesterol greater than 180 mg/dL (Lpb5.1) and those with plasma cholesterol less than 180 mg/dL (Lpb5.2). LDL from both Lpb5.1 and Lpb5.2 pigs was catabolized in vivo and in vitro at a similarly reduced rate. The difference in plasma cholesterol between the two phenotypic groups was in part due to a higher buoyant LDL production rate in Lpb5.1 pigs than in Lpb5.2 pigs. The in vivo LDL receptor status was evaluated by measuring the catabolism of LDL chemically modified to abrogate LDL receptor binding. Approximately 50% of LDL clearance in normal and Lpb5.2 pigs was via the LDL receptor; in Lpb5.1 pigs, 100% of LDL clearance was LDL receptor independent. Quantitative pedigree analysis of the segregation of the plasma cholesterol phenotype suggested that two major gene loci (the apoB locus and a second apparently unlinked locus) contribute to the determination of plasma cholesterol levels in this pig population.

Nucleotide sequence encoding the carboxyl-terminal half of apolipoprotein B from spontaneously hypercholesterolemic pigs.

Previous studies from this laboratory characterized the hypercholesterolemia of pigs with a mutant allele of apolipoprotein B (apoB), designated Lpb5. This apoB allele is associated with low density lipoprotein (LDL) particles deficient in binding to the LDL receptor. To identify potential causative mutations in Lpb5 DNA, 10.6 kb of genomic DNA, encoding the carboxyl-terminal 58% of apoB were sequenced from the Lpb5 allele and from an allele encoding phenotypically normal apoB. Comparison of the two DNA sequences revealed 33 polymorphisms, 13 of which resulted in amino acid polymorphisms. To determine whether any of the amino acids at the polymorphic positions in Lpb5-encoded apoB were unique to that isoform, those positions were sequenced in four other pig apoB alleles encoding phenotypically normal apoB. None of the amino acids were by themselves uniquely encoded by the Lpb5 allele. However, a unique haplotype consisting of Asp3164 in conjunction with Ala3447 distinguished the Lpb5-encoded apoB from all other allelic isoforms sequenced in this region. To gain insight into changes in the tertiary structure of the mutant apoB, 13C-NMR analysis of LDL reductively methylated with [13C]-formaldehyde was performed. LDL has lysine residues that titrate at pH 10.5 and others that titrate at pH 8.9. The latter residues are thought to include those involved in the interaction of LDL with the LDL receptor. LDL from Lpb5 pigs possessed a smaller proportion of lysine residues titrating at pH 8.9 than did LDL from non-Lpb5 pigs, suggesting that the Lpb5-encoded apoB is altered in a manner affecting the microenvironment of particular lysine residues.

Determination of pig apolipoprotein B genotype by gene amplification and restriction fragment length polymorphism analysis.

Sequence differences within the pig apoB gene can be used to identify rapidly four of eight known pig apoB alleles, designated LPB1-LBP8. We describe the use of gene amplification, followed by endonuclease digestion and agarose gel electrophoresis, to discern size and restriction site differences. LPB5, a common allele associated with reduced low density lipoprotein clearance and hypercholesterolaemia in pigs, is identified by a 283-bp insertion in intron 28. LPB3 and LPB7 are distinguished by a unique HindIII site; LPB8 shares a unique HincII site with LPB5. This method facilitates identification of the apoB genotype of pigs used in lipoprotein research and allows for further investigation into the association of particular apoB alleles with lipoprotein metabolism abnormalities.