Faculty Bibliography

The genetic disease abetalipoproteinemia is characterized by a total absence of apolipoprotein B-containing lipoproteins from plasma. A presumed synthetic defect in apolipoprotein B synthesis was thought to be responsible for this disorder. The present study quantitates apoprotein B synthesis and apolipoprotein B messenger RNA levels in duodenal mucosa from normal patients and four patients with abetalipoproteinemia. After in vitro [3H]leucine incorporation, small intestinal biopsy specimens from three of four patients with abetalipoproteinemia synthesized immunoprecipitable apolipoprotein B of identical mobility (on sodium dodecyl sulfate gel electrophoresis) to normal apolipoprotein B. In abetalipoproteinemia, the apolipoprotein B content of intestinal mucosa by radioimmunoassay was 15% of normal mucosal values, whereas apolipoprotein B messenger RNA quantitation showed 3-20-fold increased levels compared with normal mucosa. In one patient, smaller-molecular-weight fragments of apolipoprotein B were immunoprecipitated from duodenal biopsy specimens. The synthesis rates and messenger RNA levels of two other chylomicron apoproteins (apolipoprotein A-I and apolipoprotein A-IV) were found to be reduced by 50%. These results show the synthesis of immunologically recognizable apolipoprotein B48 in abetalipoproteinemia. The significance of mucosal apolipoprotein B content in abetalipoproteinemia is discussed in terms of factors controlling apolipoprotein B synthesis in normal mucosa and in abetalipoproteinemia

Regulatory mechanisms of hepatic apolipoprotein synthesis were studied in groups of male Sprague-Dawley rats made severely hypolipidemic by treatment with pharmacological doses of 17 alpha-ethinyl estradiol. Treatment resulted in a marked reduction of plasma cholesterol and apolipoproteins B, A-I, and A-IV. Hepatic apoA-I mRNA and apoA-I synthesis were increased in the ethinyl estradiol-treated animals. Hepatic apoA-IV protein synthesis rates were unaltered; however, a reduction of the apoA-IV mRNA level was observed. Diet-control studies suggested the effects of 17 alpha-ethinyl estradiol on apoA-I, unlike those on apoA-IV, appeared to be related to the steroid and not to reduced caloric intake. Livers of control and ethinyl estradiol-treated rats synthesized both apoBH and apoBL. Total hepatic apoB (apoBL plus apoBH) synthesis and apoB mRNA levels in the ethinyl estradiol-treated rats were similar to ad libitum fed or diet-controls. In ad libitum fed and diet-control rats, 21% and 32%, respectively, of newly synthesized hepatic apoB was apoBH. In contrast, 47% of the newly synthesized apoB in the ethinyl estradiol-treated animal was apoBH. Nucleotide sequence analysis of hepatic apoB mRNA confirmed a marked decrease in the proportion of the apoBL mRNA in ethinyl estradiol-treated animals. After cessation of 17 alpha-ethinyl estradiol treatment, the hepatic apolipoprotein A-I synthesis rate, apolipoprotein A-I and A-IV mRNA levels, and the apoBH and apoBL synthesis rates, as well as plasma apolipoprotein and cholesterol levels, returned to normal. A major finding of the present study is that pharmacological doses of ethinyl estradiol do not affect total hepatic apoB synthesis, but increase the relative amount of apoBH synthesized

The effect of inhibiting cholesteryl ester transfer protein (CETP) on the in vitro redistribution of apolipoproteins(apo) A-IV and apoE among lipoproteins in whole plasma was studied in seven normal male subjects. Plasmas were incubated in the presence of a purified monoclonal antibody TP2 (Mab TP2) that neutralizes the activity of CETP. Mab TP2 had no effect on lecithin:cholesterol acyltransferase (LCAT) activity. Prior to and following a 6-h incubation at 37 degrees C in the presence of Mab TP2 or a control mouse myeloma immunoglobulin (IgG), plasmas were gel-filtered on Sephacryl S-300 and the distribution of apoA-IV and apoE among lipoproteins was determined by radioimmunoassay. Incubation (i.e., with active LCAT and CETP) increased the amount of apoA-IV associated with lipoproteins by 240%. When CETP activity was inhibited during incubation, the amount of apoA-IV that became lipoprotein-associated was significantly increased (315% of basal). Plasma incubation also caused a redistribution of apoE from high density lipoproteins (HDL) to larger lipoproteins (131% of basal); however, when CETP was inhibited, significantly greater amounts of apoE became associated with the larger particles (155% of basal). These effects were observed in all seven subjects. Increased movement of apoE from HDL to triglyceride-rich particles was not due to displacement by apoA-IV since loss of apoE from HDL was still observed when no movement of apoA-IV onto HDL occurred, such as during LCAT or combined LCAT and CETP inhibition. We speculate that low CETP activity (e.g., in species such as rats) may lead to an increased content of HDL apoA-IV and also to apoE enrichment of triglyceride-rich lipoproteins, augmenting their clearance

Intracellular forms of chylomicrons, very low density lipoprotein (VLDL) and high density lipoprotein (HDL) have previously been isolated from the rat intestine. These intracellular particles are likely to be nascent precursors of secreted lipoproteins. To study the distribution of intracellular apolipoprotein among nascent lipoproteins, a method to isolate intracellular lipoproteins was developed and validated. The method consists of suspending isolated enterocytes in hypotonic buffer containing a lipase inhibitor, rupturing cell membranes by nitrogen cavitation, and isolating lipoproteins by sequential ultracentrifugation. ApoB and apoA-I mass are determined by radioimmunoassay and newly synthesized apolipoprotein characterized following [3H]leucine intraduodenal infusion. Intracellular chylomicron, VLDL, low density lipoprotein (LDL), and HDL fractions were isolated and found to contain apoB, and apoA-IV, and apoA-I. In the fasted animal, less than 10% of total intracellular apoB and apoA-I was bound to lipoproteins and 7% of apoB and 35% of apoA-I was contained in the d 1.21 g/ml infranatant. The remainder of intracellular apolipoprotein was in the pellets of centrifugation. Lipid feeding doubled the percentage of intracellular apoA-I bound to lipoproteins and increased the percentage of intracellular apoB bound to lipoproteins by 65%. Following lipid feeding, the most significant increase was in the chylomicron apoB and HDL apoA-I fractions. These data suggest that in the fasting state, 90% of intracellular apoB and apoA-I is not bound to lipoproteins. Lipid feeding shifts intracellular apolipoprotein onto lipoproteins, but most intracellular apolipoprotein remains non-lipoprotein bound. The constant presence of a large non-lipoprotein-bound pool suggests that apolipoprotein synthesis is not the rate limiting step in lipoprotein assembly or secretion