Intracellular assembly of very low density lipoproteins containing apolipoprotein B100 in rat hepatoma McA-RH7777 cells

Previous studies with McA-RH7777 cells showed a 15-20-min temporal delay in the oleate treatment-induced assembly of very low density lipoproteins (VLDL) after apolipoprotein (apo) B100 translation, suggesting a post-translational process. Here, we determined whether the post-translational assembly of apoB100-VLDL occurred within the endoplasmic reticulum (ER) or in post-ER compartments using biochemical and microscopic techniques. At steady state, apoB100 distributed throughout ER and Golgi, which were fractionated by Nycodenz gradient centrifugation. Pulse-chase experiments showed that it took about 20 min for newly synthesized apoB100 to exit the ER and to accumulate in the cis/medial Golgi. At the end of a subsequent 20-min chase, a small fraction of apoB100 accumulated in the distal Golgi, and a large amount of apoB100 was secreted into the medium as VLDL. VLDL was not detected either in the lumen of ER or in that of cis/medial Golgi where apoB100 was membrane-associated and sensitive to endoglycosidase H treatment. In contrast, VLDL particles were found in the lumen of the distal Golgi where apoB100 was resistant to endoglycosidase H. Formation of lumenal VLDL almost coincided with the appearance of VLDL in the medium, suggesting that the site of VLDL assembly is proximal to the site of secretion. When microsomal triglyceride transfer protein activity was inactivated after apoB had exited the ER, VLDL formation in the distal Golgi and its subsequent secretion was unaffected. Lipid analysis by tandem mass spectrometry showed that oleate treatment increased the masses of membrane phosphatidylcholine (by 68%) and phosphatidylethanolamine (by 27%) and altered the membrane phospholipid profiles of ER and Golgi. Taken together, these results suggest that VLDL assembly in McA-RH7777 cells takes place in compartments at the distal end of the secretory pathway.     

The low density lipoprotein receptor prevents secretion of dense apoB100-containing lipoproteins from the liver

The assembly and secretion of very low density lipoproteins (VLDL) require microsomal triglyceride transfer protein (MTP). Recent evidence also suggests a role for the low density lipoprotein (LDL) receptor in this process. However, the relative importance of MTP in the two steps of VLDL assembly and the specific role of the LDL receptor still remain unclear. To further investigate the role of MTP and the LDL receptor in VLDL assembly, we bred mice harboring "floxed" Mttp alleles (Mttpflox/flox) and a Cre transgene on a low-density lipoprotein receptor-deficient background to generate mice with double deficiency in the liver (Ldlr-/- MttpDelta/Delta). In contrast to the plasma of Ldlr+/+ MttpDelta/Delta mice, the plasma of Ldlr-/- MttpDelta/Delta mice contained apoB100. Accordingly, Ldlr-/- MttpDelta/Delta but not Ldlr+/+ MttpDelta/Delta hepatocytes secreted apoB100-containing lipoprotein particles. The secreted lipoproteins were of LDL and HDL sizes but no VLDL-sized lipoproteins could be detected. These findings indicate that hepatic LDL receptors function as "gatekeepers" targeting dense apoB100-containing lipoproteins for degradation. In addition, these results suggest that very low levels of MTP are insufficient to mediate the second step but sufficient for the first step of VLDL assembly.     

Different fatty acids inhibit apoB100 secretion by different pathways: unique roles for ER stress, ceramide, and autophagy

Although short-term incubation of hepatocytes with oleic acid (OA) stimulates secretion of apolipoprotein B100 (apoB100), exposure to higher doses of OA for longer periods inhibits secretion in association with induction of endoplasmic reticulum (ER) stress. Palmitic acid (PA) induces ER stress, but its effects on apoB100 secretion are unclear. Docosahexaenoic acid (DHA) inhibits apoB100 secretion, but its effects on ER stress have not been studied. We compared the effects of each of these fatty acids on ER stress and apoB100 secretion in McArdle RH7777 (McA) cells: OA and PA induced ER stress and inhibited apoB100 secretion at higher doses; PA was more potent because it also increased the synthesis of ceramide. DHA did not induce ER stress but was the most potent inhibitor of apoB100 secretion, acting via stimulation of autophagy. These unique effects of each fatty acid were confirmed when they were infused into C57BL6J mice. Our results suggest that when both increased hepatic secretion of VLDL apoB100 and hepatic steatosis coexist, reducing ER stress might alleviate hepatic steatosis but at the expense of increased VLDL secretion. In contrast, increasing autophagy might reduce VLDL secretion without causing steatosis.     

Apolipoprotein B100 exit from the endoplasmic reticulum (ER) is COPII-dependent,and its lipidation to very low density lipoprotein occurs post-ER

Hepatic apolipoprotein B100 (apoB100) associates with lipids to form dense lipoprotein particles in the endoplasmic reticulum (ER) and is further lipidated to very low density lipoproteins (VLDL). Because the VLDL diameter can exceed 200 nm, classical ER-derived vesicles may be unable to accommodate VLDLs. Using hepatic membranes and cytosol to reconstitute ER budding, apoB100-containing vesicles sedimented distinct from those harboring more typical cargo but contained Sec23. Moreover, ER exit of apoB was inhibited by dominant-negative Sar1. Budding required Sar1 regardless of whether oleic acid (OA) was added to stimulate apoB lipidation; therefore, either large apoB100-lipoproteins reside in secretory vesicles, or full lipidation occurs post-ER. Using membranes from cells incubated in the presence or absence of OA, we determined that apoB100-lipoproteins in ER vesicles had not become lipidated to VLDLs. VLDL particles resided in the Golgi, but not the ER, after fractionation of OA-treated cells. We conclude that apoB100-lipoproteins exit the ER in COPII vesicles, but under conditions favorable for VLDL formation final lipid loading occurs post-ER.     

Lovastatin therapy reduces low density lipoprotein apoB levels in subjects with combined hyperlipidemia by reducing the production of apoB-containing lipoproteins: implications for the pathophysiology of apoB production

We investigated the metabolism of very low density lipoprotein (VLDL), intermediate density lipoprotein (IDL), and low density lipoprotein (LDL) apolipoprotein B (apoB) in seven patients with combined hyperlipidemia (CHL), using 125I-labeled VLDL and 131I-labeled LDL and compartmental modeling, before and during lovastatin treatment. Lovastatin therapy significantly reduced plasma levels of LDL cholesterol (142 vs 93 mg/dl, P less than 0.0005) and apoB (1328 vs 797 micrograms/ml, P less than 0.001). Before treatment, CHL patients had high production rates (PR) of LDL apoB. Three-fourths of this LDL apoB flux was derived from sources other than circulating VLDL and was, therefore, defined as "cold" LDL apoB flux. Compared to baseline, treatment with lovastatin was associated with a significant reduction in the total rate of entry of apoB-containing lipoproteins into plasma in all seven CHL subjects (40.7 vs. 25.7 mg/kg.day, P less than 0.003). This reduction was associated with a fall in total LDL apoB PR and in "cold" LDL apoB PR in six out of seven CHL subjects. VLDL apoB PR fell in five out of seven CHL subjects. Treatment with lovastatin did not significantly alter VLDL apoB conversion to LDL apoB or LDL apoB fractional catabolic rate (FCR) in CHL patients. In three patients with familial hypercholesterolemia who were studied for comparison, lovastatin treatment increased LDL apoB FCR but did not consistently alter LDL apoB PR. We conclude that lovastatin lowers LDL cholesterol and apoB concentrations in CHL patients by reducing the rate of entry of apoB-containing lipoproteins into plasma, either as VLDL or as directly secreted LDL.     

The assembly and secretion of ApoB 100-containing lipoproteins in Hep G2 cells. ApoB 100 is cotranslationally integrated into lipoproteins.

The possibility that apoB 100 is cotranslationally translocated to the endoplasmic reticulum lumen and integrated into lipoproteins has been investigated. ApoB 100 nascent polypeptides were shown to be secreted from pulse-labeled Hep G2 cells after treatment with puromycin and chase for 1 or 2 h in the presence of puromycin and cycloheximide. These nascent polypeptides banded during sucrose gradient ultracentrifugation between the position of the high (HDL) and the low (LDL) density lipoproteins, revealing an inverse relationship between the length of the polypeptide and the density of the fraction. ApoB 100 occurred in the position of LDL and very low density lipoproteins (VLDL). Electronmicroscopy studies of the apoB-containing particles from the gradient indicated an increase in size with increasing length of the polypeptide. Furthermore, labeling studies indicated that the triglyceride load increased with the length of the polypeptide. An inverse relationship between the size of C-terminally truncated apoB polypeptides and the density of the assembled lipoproteins was also observed in experiments with transfected minigenes coding for apoB 41, apoB 29, and apoB 23. These proteins appeared on HDL particles. Pulse-chase experiments indicated that 80-200-kDa apoB nascent polypeptides on particles with HDL density, with time, were converted into larger polypeptides on lighter particles, to be fully replaced by apoB 100 on LDL-VLDL particles. The formation of these LDL-VLDL particles could be blocked by cycloheximide. Sixty-five percent of pulse-labeled apoB nascent polypeptides present in the microsomal fraction was released by sodium carbonate treatment, and 77% of these polypeptides could be recovered on the immature particles (banding between HDL and LDL) after sucrose gradient ultracentrifugation. Pulse-chase experiments indicated that these nascent polypeptides, on the immature lipoproteins, had the capacity to be precursors for all the apoB 100-containing LDL and VLDL particles formed in the cell. The obtained results indicate that a major portion of the apoB nascent polypeptides in the cell form lipoproteins cotranslationally during the translocation to the lumen of the endoplasmic reticulum.     

Modulation of apolipoprotein B-100 mRNA editing: effects on hepatic very low density lipoprotein assembly and intracellular apoB distribution in the rat

We have studied the consequences of alterations to hepatic apoB mRNA editing on the biosynthesis and intracellular distribution of newly synthesized apoB variants together with their mass distribution in nascent Golgi very low density lipoproteins (VLDL). Radiolabeled liver membrane fractions were prepared from control or hypothyroid animals and separated by discontinuous sucrose gradient centrifugation. Hepatic apoB-100 synthesis in these groups accounted for 93-100% of total newly synthesized apoB species of Golgi fractions recovered from the sucrose gradients (G1 and G2). The analogous fractions isolated from the livers of hyperthyroid (treated with 3,3',5-triiodo-L-thyronine, T3) animals revealed that newly synthesized apoB-100 accounted for only 46 +/- 10% (G1) and 24 +/- 11% (G2), respectively, of total newly synthesized apoB. ApoB-100 mass in nascent Golgi VLDL from control and hypothyroid G1 fractions represented 70-78% total apoB as determined by Western blot analysis. By contrast, Golgi VLDL from hyperthyroid animals contained predominantly (greater than 78%) apoB-48 as the apoB species. Electron microscopy revealed that the morphology and size distribution of hyperthyroid G1 VLDL were similar to particles isolated from control animals. Thus, despite a profound reduction in the proportion of apoB-100 mRNA species containing an unmodified codon (CAA, B-GLN) at position 2153 in hyperthyroid animals (6 +/- 1% vs 50-61% in control and hypothyroid animals) apoB-100 biosynthesis was detectable in a defined membrane fraction isolated by discontinuous sucrose gradient centrifugation. However, no apoB-100 synthesis was detectable in liver samples prepared by Polytron disruption in Triton-containing buffers. These data suggest that effective hepatic VLDL assembly and secretion in the T3-treated rat continues despite a profound reduction in apoB-100 biosynthesis and implies that apoB-48 contains the requisite domains to direct this process, a situation analogous to that in the intestine.     

Assembly of very low density lipoprotein in the hepatocyte. Differential transport of apoproteins through the secretory pathway

The transport of the apolipoprotein (apo) constituents of hepatic very low density lipoprotein (VLDL) through the secretory pathway was investigated with estrogen-induced chick hepatocytes in primary culture. Cell monolayers were pulse-labeled with [3H]leucine and, after differing periods of chase with unlabeled leucine, were subjected to subcellular fractionation for 3H-apoprotein analysis. The first-order rate constants for transit of apoB, apoA-I, and apoII through the endoplasmic reticulum (ER) and Golgi were estimated using a three-compartment (ER, Golgi, and extracellular medium) kinetic analysis. The results indicate that apoB resides in the ER (t1/2 = 26 min) for a shorter period of time than in the Golgi (t1/2 = 43 min). For apoII, the t1/2 for transport through the ER and Golgi are 43 and 49 min, respectively. ApoA-I transits the ER at a rate (t1/2 = 6 min) much faster than apoB, apoII, and virtually all other secretory proteins. Upon reaching the Golgi, the rate of movement of apoA-I is markedly reduced (t1/2 = 28 min). Thus, in contrast to current models of protein secretion, the rate-limiting step in the secretion of VLDL apoproteins from the cell is transport through the Golgi, not the ER. Examination of the steady-state distribution of the apoproteins in the ER and Golgi support this conclusion. To characterize the intracellular transport process further, the distribution of apoproteins between the lumenal contents of the ER and Golgi and the membranes which delineate these compartments was determined after steady-state labeling with [3H]leucine. Approximately 50% of the apoB in the ER and in a dense, early Golgi fraction was membrane-associated, whereas in a less dense or late Golgi compartment, only 20% was bound to membranes. ApoII was also associated with the membranes of the ER and Golgi to a significant extent. In contrast, apoA-I was primarily localized lumenally throughout the secretory pathway. The occurrence of membrane-associated apoproteins in the Golgi, coupled with their slow rate of transit through this compartment suggests a major role for the Golgi in the assembly of the constituents of VLDL, and suggests that interaction of apoproteins (apoB) with the membranes of the Golgi is required for the maturation of VLDL.     

Effects of 1,2-cyclohexanedione modification on the metabolism of very low density lipoprotein apolipoprotein B: potential role of receptors in intermediate density lipoprotein catabolism

The conversion of very low density (VLDL) to low density lipoproteins (LDL) is a two-step process. The first step is mediated by lipoprotein lipase, but the mechanism responsible for the second is obscure. In this study we examined the possible involvement of receptors at this stage. Apolipoprotein B (apoB)-containing lipoproteins were separated into three fractions, VLDL (Sf 100-400), an intermediate fraction IDL (Sf 12-100), and LDL (Sf 0-12). Autologous 125I-labeled VLDL and 131I-labeled 1,2-cyclohexanedione-modified VLDL were injected into the plasma of four normal subjects and the rate of transfer of apoB radioactivity was followed through IDL to LDL. Modification did not affect VLDL to IDL conversion. Thereafter, however, the catabolism of modified apoB in IDL was retarded and its appearance in LDL was delayed. Hence, functional arginine residues (and by implication, receptors) are required in this process. Confirmation of this was obtained by injecting 125I-labeled IDL and 131I-labeled cyclohexanedione-treated IDL into two additional subjects. Again, IDL metabolism was delayed by approximately 50% as a result of the modification. These data are consistent with the view that receptors are involved in the metabolism of intermediate density lipoprotein.     

Microsomal membrane-associated apoB is the direct precursor of secreted VLDL in primary cultures of rat hepatocytes

Brefeldin A (BFA) added to primary cultures of rat hepatocytes, at a concentration of 0.2 microg/ml, prevented the assembly of newly synthesized apolipoprotein B (apoB) into mature, secretory VLDL but did not prevent the secretion of apoB as denser particles (HDL apoB), or of albumin. The unassembled apoB remained associated with the membranes of the cellular microsomal fraction. There was no effect of BFA on the removal of apoB from the lumen of these vesicles. VLDL apoB formed only a minor component of the total apoB in the microsomal lumen. Higher (5 microg/ml) concentrations of BFA were required to prevent the secretion of HDL apoB and albumin. Under these conditions apoB accumulated in the microsomal lumen, as well as in the membranes of these vesicles. Again, apoB VLDL formed only a minor proportion of the total lumenal apoB. ApoB-48 VLDL and apoB-100 VLDL assembly could be restored by removing BFA from the medium. This reactivation of VLDL assembly was accompanied by an increased removal of apoB from the microsomal membranes, but there was no detectable increase in the small quantity of VLDL apoB that was recovered from the microsomal lumen. In the absence of BFA, during pulse-chase experiments the pattern of change in the specific radioactivity of microsomal membrane apoB was similar to that of the secreted VLDL apoB whereas that of the lumenal apoB resembled that of the secreted HDL apoB. The results suggest that membrane-associated apoB is the main direct precursor of secreted VLDL apoB in primary cultures of rat hepatocytes and that VLDL assembly does not involve primarily microsomal lumenal apoB as an intermediate.     

Lipolytic degradation of human very low density lipoproteins by human milk lipoprotein lipase: the identification of lipoprotein B as the main lipoprotein degradation product

Although the direct conversion of very low density lipoproteins (VLDL) into low density (LDL) and high density (HDL) lipoproteins only requires lipoprotein lipase (LPL) as a catalyst and albumin as the fatty acid acceptor, the in vitro-formed LDL and HDL differ chemically from their native counterparts. To investigate the reason(s) for these differences, VLDL were treated with human milk LPL in the presence of albumin, and the LPL-generated LDL1-, LDL2-, and HDL-like particles were characterized by lipid and apolipoprotein composition. Results showed that the removal of apolipoproteins B, C, and E from VLDL was proportional to the degree of triglyceride hydrolysis with LDL2 particles as the major and LDL1 and HDL + VHDL particles as the minor products of a complete in vitro lipolysis of VLDL. In comparison with native counterparts, the in vitro-formed LDL2 and HDL + VHDL were characterized by lower levels of triglyceride and cholesterol ester and higher levels of free cholesterol and lipid phosphorus. The characterization of lipoprotein particles present in the in vitro-produced LDL2 showed that, as in plasma LDL2, lipoprotein B (LP-B) was the major apolipoprotein B-containing lipoprotein accounting for over 90% of the total apolipoprotein B. Other, minor species of apolipoprotein B-containing lipoproteins included LP-B:C-I:E and LP-B:C-I:C-II:C-III. The lipid composition of in vitro-formed LP-B closely resembled that of plasma LP-B. The major parts of apolipoproteins C and E present in VLDL were released to HDL + VHDL as simple, cholesterol/phospholipid-rich lipoproteins including LP-C-I, LP-C-II, LP-C-III, and LP-E. However, some of these same simple lipoprotein particles were present after ultracentrifugation in the LDL2 density segment because of their hydrated density and/or because they formed, in the absence of naturally occurring acceptors (LP-A-I:A-II), weak associations with LP-B. Thus, the presence of varying amounts of these cholesterol/phospholipid-rich lipoproteins in the in vitro-formed LDL2 appears to be the main reason for their compositional difference from native LDL2. These results demonstrate that the formation of LP-B as the major apolipoprotein B-containing product of VLDL lipolysis only requires LPL as a catalyst and albumin as the fatty acid acceptor. However, under physiological circumstances, other modulating agents are necessary to prevent the accumulation and interaction of phospholipid/cholesterol-rich apolipoprotein C- and E-containing particles.     

Antisense inhibition of apoB synthesis with mipomersen reduces plasma apoC-III and apoC-III-containing lipoproteins

Mipomersen, an antisense oligonucleotide that reduces hepatic production of apoB, has been shown in phase 2 studies to decrease plasma apoB, LDL cholesterol (LDL-C), and triglycerides. ApoC-III inhibits VLDL and LDL clearance, and it stimulates inflammatory responses in vascular cells. Concentrations of VLDL or LDL with apoC-III independently predict cardiovascular disease. We performed an exploratory posthoc analysis on a subset of hypercholesterolemic subjects obtained from a randomized controlled dose-ranging phase 2 study of mipomersen receiving 100, 200, or 300 mg/wk, or placebo for 13 wk (n = 8 each). ApoC-III-containing lipoproteins were isolated by immuno-affinity chromatography and ultracentrifugation. Mipomersen 200 and 300 mg/wk reduced total apoC-III from baseline by 6 mg/dl (38-42%) compared with placebo group (P < 0.01), and it reduced apoC-III in both apoB lipoproteins and HDL. Mipomersen 100, 200, and 300 mg doses reduced apoB concentration of LDL with apoC-III (27%, 38%, and 46%; P < 0.05). Mipomersen reduced apoC-III concentration in HDL. The drug had no effect on apoE concentration in total plasma and in apoB lipoproteins. In summary, antisense inhibition of apoB synthesis reduced plasma concentrations of apoC-III and apoC-III-containing lipoproteins. Lower concentrations of apoC-III and LDL with apoC-III are associated with reduced risk of coronary heart disease (CHD) in epidemiologic studies independent of traditional risk factors.     

Metabolism of very low density lipoproteins in the pig. An in vivo study.

1. The metabolism of apolipoprotein B (apoB) was investigated in pigs injected with [125I]very low density lipoproteins (VLDL) to determine to which extent the two distinct low density lipoprotein subclasses (LDL1 and LDL2) derive from VLDL. 2. The lipoproteins were isolated by density gradient ultracentrifugation and the transfer of radioactivity from VLDL into LDL1 and LDL2 apoB was measured. 3. Only a minor portion of VLDL apoB was converted to LDL1 (7.7 +/- 3.2%) and LDL2 (3.6 +/- 1.5%), respectively. Thus, we conclude that the major portion of LDL, especially LDL2, is synthesized independently from VLDL catabolism.     

Metabolsim of apoB and apoC lipoproteins in man: kinetic studies in normal and hyperlipoproteininemic subjects.

The kinetics of apolipoproteins B and C were studied in 14 normal and hyperlipoproteinemic subjects after injection of exogenously (125)I-labeled very low density lipoprotein (VLDL) particles. Plasma radioactivities of apoB and apoC were determined over a period of 4 days in VLDL (d < 1.006) and total radioactivity in intermediate (IDL) (1.006 < d < 1.019), low (LDL) (1.019 < d < 1.063), and high (HDL) (1.063 < d < 1.21) density lipoproteins. The data were analyzed by the use of a model, developed mostly from these data, with the following results. The VLDL particle undergoes a series of incremental density changes, most likely due to a number of delipidation steps, during which apoB stays with the particle until the density reaches the IDL range. There is, however, a loss of apoC associated with these delipidation steps. In our normal subjects, all IDL apoB eventually becomes LDL. In our hyperlipemic subjects some of the apoB on IDL is also degraded directly. The apoC lost by VLDL and IDL recycles to HDL, and most of it is picked up again by newly synthesized VLDL. There is a slowdown of the stepwise delipidation process in all hyperlipemic individuals studied. Three additional features became apparent in the type III subjects. First, there is a significant increase (a factor of 2 compared to normal) in the apoB synthesis rate by way of VLDL; second, there is an induced direct apoB synthesis pathway by way of IDL (and/or LDL); third, a bypass of the regular stepwise VLDL delipidation pathway is induced by which VLDL particles lose apoC but none of their apoB, thereby forming a new particle with metabolic properties similar to LDL, but with a density still in the VLDL density range. Two type III patients treated with nicotinic acid and clofibrate showed a sharp decrease in their VLDL apoB synthesis rates. This was somewhat compensated by an increased IDL apoB synthesis rate. A type I patient on a medium chain triglyceride diet also showed a number of metabolic changes, including reduced VLDL apoB synthesis and the induction of considerable IDL and/or LDL apoB synthesis.     

The inhibition of microsomal triglyceride transfer protein activity in rat hepatoma cells promotes proteasomal and nonproteasomal degradation of apoprotein b100

In the human hepatic cell line, HepG2, apolipoprotein B100 (apoB100) degradation is increased by inhibiting lipid transfer mediated by the microsomal triglyceride transfer protein (MTP) and is predominantly accomplished by the ubiquitin-proteasome pathway. In the current study, we determined whether this degradative pathway was restricted to HepG2 cells or was of more general importance in hepatic apoB100 metabolism. Rat hepatoma McArdle RH7777 cells (McA), compared to HepG2 cells, secrete a large fraction of apoB100 associated with VLDL particles, as does the normal mammalian liver. In McA cells studied under basal conditions, the proteasome inhibitor lactacystin (LAC) increased apoB100 recovery, indicating that the role of the proteasome in apoB100 metabolism is not restricted to HepG2 cells. When apoB100 lipidation was blocked by an inhibitor of MTP (MTPI), recovery of cellular apoB100 was markedly reduced, but LAC was only partially ( approximately 50%) effective in reversing the induced degradation. This partial effectiveness of LAC may have represented either (1) incomplete inhibition by LAC of its preferred target, the chymotrypsin-like activity of the proteasome, (2) the presence of an apoB100 proteolytic activity of the proteasome resistant to LAC, or (3) a nonproteasomal proteolytic pathway of apoB100 degradation. By studying immunoisolated proteasomes and McA cells treated with LAC and/or MTPI and a variety of protease inhibitors, we determined that the proteasomal component of apoB100 degradation was entirely attributable to the chymotrypsin-like catalytic activity, but only accounted for part of apoB100 degradation induced by MTPI. The nonproteasomal apoB100 degradative pathway was nonlysosomal and resistant to E64d, DTT, and peptide aldehydes such as MG132 or ALLN but was partially sensitive to the serine protease inhibitor APMSF. Furthermore, when the protein trafficking inhibitor, brefeldin A, was used to block endoplasmic reticulum (ER) to Golgi transport in MTPI-treated McA cells, degradative activity resistant to LAC was increased, suggesting that the nonproteasomal pathway is associated with the ER.     

Mevinolin and cholestyramine inhibit the direct synthesis of low density lipoprotein apolipoprotein B in miniature pigs

Previous studies established that following simultaneous injection of 125I-labeled homologous very low density lipoproteins (VLDL) and 131I-labeled homologous low density lipoproteins (LDL) into miniature pigs, a large proportion of LDL apolipoprotein B (apoB) was synthesized directly, independent of VLDL or intermediate density lipoprotein (IDL) apoB catabolism. The possibility that cholestyramine alone (a bile acid sequestrant) or in combination with mevinolin (a cholesterol synthesis inhibitor) could regulate the direct LDL apoB synthetic pathway was investigated. 125I-labeled VLDL and 131I-labeled LDL were injected into miniature pigs (n = 8) during a control period and following 18 days of cholestyramine treatment (1.0 g kg-1d-1) or following 18 days of treatment with cholestyramine and mevinolin (1.2 mg kg-1d-1). ApoB in each lipoprotein fraction was selectively precipitated using isopropanol in order to calculate specific activity. In control experiments, LDL apoB specific activity curves reached their peak values well before crossing the VLDL or IDL apoB curves. However, cholestyramine treatment resulted in LDL apoB curves reaching maximal values much closer to the point of intersection with the VLDL or IDL curves. Kinetic analyses demonstrated that cholestyramine reduced total LDL apoB flux by 33%, which was due entirely to inhibition of the LDL apoB direct synthesis pathway since VLDL-derived apoB was unaffected. In addition, the LDL apoB pool size was reduced by 30% and the fractional catabolic rate of LDL apoB was increased by 16% with cholestyramine treatment. The combination of mevinolin and cholestyramine resulted in an even more marked inhibition of the direct LDL apoB synthesis pathway (by 90%), and in two animals this pathway was completely abolished. This inhibition was selective as VLDL-derived LDL apoB synthesis was not significantly different. LDL apoB pool size was reduced by 60% due primarily to the reduced synthesis as well as a 40% greater fractional removal rate. These results are consistent with the idea that cholestyramine and mevinolin increase LDL catabolism by inducing hepatic apoB, E receptors. We have now shown that the direct synthesis of LDL apoB is selectively inhibited by these two drugs.     

Resistance of a very low density lipoprotein subpopulation from familial dysbetalipoproteinemia to in vitro lipolytic conversion to the low density lipoprotein density fraction

In vitro lipolysis of very low density lipoprotein (VLDL) from normolipidemic and familial dysbetalipoproteinemic plasma by purified bovine milk lipoprotein lipase was studied using the combined single vertical spin and vertical autoprofile method of lipoprotein analysis. Lipolysis of normolipidemic plasma supplemented with autologous VLDL resulted in the progressive transformation of VLDL to low density lipoprotein (LDL) via intermediate density lipoprotein (IDL) with the transfer of the excess cholesterol to high density lipoprotein (HDL). At the end of 60 min lipolysis, 92-96% of VLDL triglyceride was hydrolyzed, and, with this process, greater than 95% of the VLDL cholesterol and 125-I-labeled VLDL protein was transferred from the VLDL to the LDL and HDL density region. When VLDL from the plasma of an individual with familial dysbetalipoproteinemia was substituted for VLDL from normolipidemic plasma, less than 50% of the VLDL cholesterol and 65% of 125I-labeled protein was removed from the VLDL density region, although 84-86% of VLDL triglyceride was lipolyzed. Analysis of familial dysbetalipoproteinemic VLDL fractions from pre- and post-lipolyzed plasma showed that the VLDL remaining in the postlipolyzed plasma (lipoprotein lipase-resistant VLDL) was richer in cholesteryl ester and tetramethylurea-insoluble proteins than that from prelipolysis plasma; the major apolipoproteins in the lipoprotein lipase-resistant VLDL were apoB and apoE. During lipolysis of normolipidemic VLDL containing trace amounts of 125I-labeled familial dysbetalipoproteinemic VLDL, removal of VLDL cholesterol was nearly complete from the VLDL density region, while removal of 125I-labeled protein was only partial. A competition study for lipoprotein lipase, comparing normolipidemic and familial dysbetalipoproteinemic VLDL to an artificial substrate ([3H]triolein), revealed that normolipidemic VLDL is clearly better than familial dysbetalipoproteinemic VLDL in competing for the release of 3H-labeled free fatty acids. The results of this study suggest that, in familial dysbetalipoproteinemic individuals, a subpopulation of VLDL rich in cholesteryl ester, apoB, and apoE is resistant to in vitro conversion by lipoprotein lipase to particles having LDL-like density. The presence of this lipoprotein lipase-resistant VLDL in familial dysbetalipoproteinemic subjects likely contributes to the increased level of cholesteryl ester-rich VLDL and IDL in the plasma of these subjects.     

Interactions between human and carp (Cyprimus carpio) low density lipoproteins (LDL) and LDL receptors

1. We have compared the concentration and chemical composition of carp and human plasma lipoproteins and studied their interaction with human fibroblast LDL receptors. 2. The main lipoproteins in carp are of high density (HDL) in contrast to low density lipoproteins (LDL) in human. 3. Carp lipoproteins are devoid of apolipoprotein (apo) E, a major ligand for interaction with LDL receptors in mammals. 4. Carp very low density lipoproteins (VLDL) and LDL but not HDL nor apoA-I cross react with human LDL in their interaction with LDL receptors on human cultured fibroblasts. 5. Carp liver membranes possess high affinity receptors that are saturable and have calcium dependent ligand specificity (apoB and apoE) similar to human LDL receptor. Carp VLDL and LDL but not HDL nor its major apolipoprotein complexed to L-alpha-phosphatidylcholine dimyristoyl (apoA-I-DMPC) competed with the specific binding of human LDL to this receptor.     

The assembly and secretion of apolipoprotein B-48-containing very low density lipoproteins in McA-RH7777 cells

We have used an extraction procedure, which released membrane-bound apoB-100, to study the assembly of apoB-48 VLDL (very low density lipoproteins). This procedure released apoB-48, but not integral membrane proteins, from microsomes of McA-RH7777 cells. Upon gradient ultracentrifugation, the extracted apoB-48 migrated in the same position as the dense apoB-48-containing lipoprotein (apoB-48 HDL (high density lipoprotein)) secreted into the medium. Labeling studies with [(3)H]glycerol demonstrated that the HDL-like particle extracted from the microsomes contains both triglycerides and phosphatidylcholine. The estimated molar ratio between triglyceride and phosphatidylcholine was 0.70 +/- 0.09, supporting the possibility that the particle has a neutral lipid core. Pulse-chase experiments indicated that microsomal apoB-48 HDL can either be secreted as apoB-48 HDL or converted to apoB-48 VLDL. These results support the two-step model of VLDL assembly. To determine the size of apoB required to assemble HDL and VLDL, we produced apoB polypeptides of various lengths and followed their ability to assemble VLDL. Small amounts of apoB-40 were associated with VLDL, but most of the nascent chains associated with VLDL ranged from apoB-48 to apoB-100. Thus, efficient VLDL assembly requires apoB chains of at least apoB-48 size. Nascent polypeptides as small as apoB-20 were associated with particles in the HDL density range. Thus, the structural requirements of apoB to form HDL-like first-step particles differ from those to form second-step VLDL. Analysis of proteins in the d < 1.006 g/ml fraction after ultracentrifugation of the luminal content of the cells identified five chaperone proteins: binding protein, protein disulfide isomerase, calcium-binding protein 2, calreticulin, and glucose regulatory protein 94. Thus, intracellular VLDL is associated with a network of chaperones involved in protein folding. Pulse-chase and subcellular fractionation studies showed that apoB-48 VLDL did not accumulate in the rough endoplasmic reticulum. This finding indicates either that the two steps of apoB lipoprotein assembly occur in different compartment or that the assembled VLDL is transferred rapidly out of the rough endoplasmic reticulum.     

Docosahexaenoic acid impairs the maturation of very low density lipoproteins in rat hepatic cells

One mechanism of the lipid-lowering effects of the fish oil n-3 fatty acids [e.g., docosahexaenoic acid (DHA)] in cell and animal models is induced hepatic apolipoprotein B100 (apoB) presecretory degradation. This degradation occurs post-endoplasmic reticulum, but whether DHA induces it before or after intracellular VLDL formation remains unanswered. We found in McA-RH7777 rat hepatic cells that DHA and oleic acid (OA) treatments allowed formation of pre-VLDL particles and their transport to the Golgi, but, in contrast to OA, with DHA pre-VLDL particles failed to quantitatively assemble into fully lipidated (mature) VLDL. This failure required lipid peroxidation and was accompanied by the formation of apoB aggregates (known to be degraded by autophagy). Preventing the exit of proteins from the Golgi blocked the aggregation of apoB but did not restore VLDL maturation, indicating that failure to fully lipidate apoB preceded its aggregation. ApoB autophagic degradation did not appear to require an intermediate step of cytosolic aggresome formation. Taken with other examples in the literature, the results of this study suggest that pre-VLDL particles that are competent to escape endoplasmic reticulum quality control mechanisms but fail to mature in the Golgi remain subject to quality control surveillance late in the secretory pathway.