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.     

ApoB-100-containing lipoproteins are major carriers of 3-iodothyronamine in circulation

3-Iodothyronamine (T(1)AM) is a biogenic amine derivative of thyroid hormone present in tissue and blood of vertebrates. Approximately 99% of the circulating thyroid hormones are bound to plasma proteins, including three major thyroid hormone-binding proteins, and the question arises as to whether circulating T(1)AM is also bound to serum factors. We report here that T(1)AM is largely bound to a single protein component of human serum. Using T(1)AM-affinity chromatography, we isolated this protein, and sequence analysis identified it as apolipoprotein B-100 (apoB-100), the protein component of several low density lipoprotein particles. Consistent with this finding, we demonstrate that >90% of specifically bound T(1)AM in human serum resides in the apoB-100-containing low density lipoprotein fraction. T(1)AM reversibly binds to apoB-100-containing lipoprotein particles with an equilibrium dissociation constant (K(D)) of 17 nm and a T(1)AM/apoB-100 stoichiometry of 1:1. Competition binding assays demonstrate that this binding site is highly selective for T(1)AM. Intracellular T(1)AM uptake is significantly enhanced by apoB-100-containing lipoprotein particles. Modest enhancements to apoB-100 cellular uptake and secretion by T(1)AM were observed; however, multidose T(1)AM treatment did not affect lipid or lipoprotein inventory in vivo. Thus, it appears that apoB-100 serves as a carrier of circulating T(1)AM and affords a novel mechanism by which T(1)AM gains entry to cells.     

Studies on the assembly of apo B-100-containing lipoproteins in HepG2 cells

The relationship between apoB-100 and the membrane of the endoplasmic reticulum (ER) has been studied by a combination of pulse-chase methodology and subcellular fractionation. HepG2 cells were pulse-labeled with [35S]methionine for 3 min and chased with cold methionine for periods between 0 and 20 min. ApoB-100 and albumin, present in the membrane as well as in the luminal content of the ER vesicles, were isolated after each chase period. The results indicated that apoB-100 was cotranslationally bound to the membrane of the ER, and from this membrane-bound form, was transferred to the lumen after a delay of 10-15 min. Albumin was, as could be expected for a typical secretory protein, cotranslationally sequestered in the lumen of the ER. Apo-B-100-containing lipoproteins present in the microsomal lumen were analyzed by ultracentrifugation in a sucrose gradient. ApoB-100 occurred on rounded particles in three density regions: (i) d 1.1065-1.170 g/ml (Fraction I), (ii) d 1.011-1.045 g/ml (Fraction II), and (iii) d less than 1.011 g/ml (Fraction III). Fraction I, isolated from cells cultured in the absence of oleic acid, contained a homogenous population of particles with a mean diameter of approximately 200 A. Fraction I isolated from cells cultured in the presence of oleic acid was slightly more heterogeneous and had a mean diameter of approximately 250 A. Fractions II and III had mean diameters of 300 and 500 A, respectively. Cholesterol esters and triacylglycerol were the quantitatively dominating lipid constituents of all three fractions. Pulse-chase experiments indicated that Fraction I contained the newly assembled lipoproteins. With increasing chase time, the apoB-100 radioactivity was redistributed from Fraction I to Fractions II and III, indicating that Fraction I is converted into Fractions II and III during the intracellular transfer. Particles corresponding to Fractions II and III were by far the most abundant lipoproteins found in the medium. The results presented support the possibility of a sequential assembly of apoB-100-containing lipoproteins.     

The assembly and secretion of apolipoprotein B-containing lipoproteins.

The assembly of lipoproteins containing apolipoprotein B is a complex process that occurs in the lumen of the secretory pathway. The process consists of two relatively well-identified steps. In the first step, two VLDL precursors are formed simultaneously and independently: an apolipoprotein B-containing VLDL precursor (a partially lipidated apolipoprotein B) and a VLDL-sized lipid droplet that lacks apolipoprotein B. In the second step, these two precursors fuse to form a mature VLDL particle. The apolipoprotein B-containing VLDL precursor is formed during the translation and concomitant translocation of the protein to the lumen of the endoplasmic reticulum. The VLDL precursor is completed shortly after the protein is fully synthesized. The process is dependent on the microsomal triglyceride transfer protein (MTP). Although the mechanism by which the lipid droplets are formed is unknown, recent observations indicate that the process is dependent on MTP. The fusion of the two precursors is not dependent on MTP, but the mechanism remains to be elucidated. The conversion of the apolipoprotein B-containing precursor to VLDL seems to be dependent on the ADP ribosylation factor 1 (ARF 1) and its activation of phospholipase D. During their assembly, nascent apolipoprotein B chains undergo quality control and are sorted to degradation. Such sorting, which occurs cotranslationally during the formation of the apolipoprotein B-containing precursor, involves cytosolic chaperons and ubiquitination that targets apolipoprotein B to proteasomal degradation. Other levels of sorting occur in the secretory pathway. Thus, lysosomal enzymes are involved as well as the LDL 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.     

The assembly and secretion of apoB 100 containing lipoproteins in Hep G2 cells. Evidence for different sites for protein synthesis and lipoprotein assembly

Pulse-chase studies combined with subcellular fractionation indicated that LpB 100 (i.e. the apoprotein B (apoB) 100 containing lipoproteins) was released to the lumen of the secretory pathway in a subcellular fraction enriched in smooth vesicles, and referred to as SMF (the smooth membrane fraction). The migration of SMF during gradient ultracentrifugation as well as kinetic studies indicated that the fraction was derived from a pre-Golgi compartment, probably the smooth endoplasmic reticulum (ER). Only small amounts of LpB 100 could be detected during these pulse-chase experiments in the subcellular fractions derived from the rough endoplasmatic reticulum (RER). SMF contained the major amount of the diacylglycerol acyltransferase activity present in the ER, while the major amount of membrane bound apoB 100 was present in the RER. Pulse-chase studies of the intracellular transfer of apoB 100 demonstrated the formation of a large membrane-bound preassembly pool in the ER, while no significant amount of apoB 100 radioactivity was present in the membrane of the Golgi apparatus. The maximal radioactivity of LpB 100, recovered from the ER or the Golgi lumen, was small compared with the radioactivity recovered from the ER membrane, indicating that the assembled LpB 100 rapidly leaves the cells. This in turn indicates that the rate-limiting step in the secretion of apoB 100 was the transfer of the protein from the ER membrane to the LpB 100 in the lumen. A portion of the intracellular pool of apoB 100 was not secreted but underwent posttranslational degradation.     

Direct evidence for a two-step assembly of ApoB48-containing lipoproteins in the lumen of the smooth endoplasmic reticulum of rabbit enterocytes.

The aim of this study was to investigate the types and characteristics of chylomicron precursors in the lumen of the secretory compartment of rabbit enterocytes. Luminal contents were separated into density subfractions in two continuous self-generating gradients of different density profiles. In enterocytes from rabbits fed a low fat diet, newly synthesized and immunodetectable apoB48 was only in the subfraction of density similar to high density lipoprotein (dense particles); the luminal triacylglycerol (TAG) content was low and only in the subfraction of density similar to that of chylomicrons/very low density lipoproteins (light particles). After feeding fat, newly synthesized, and immunodetectable apoB48 was in both dense (phospholipid-rich) and light (TAG-rich) particles. Luminal TAG mass and synthesis increased after fat feeding and was only in light particles. Pulse-chase experiments showed that the luminal-radiolabeled apoB48 lost from the dense particles was recovered in the light particles and the secreted chylomicrons. All of the light particle lipids (mass and newly synthesized) co-immunoprecipitated with apoB48. However, in the dense particles, there was a preferential co-precipitation of the preexisting rather than newly synthesized phospholipid. Assembly of apoB48-containing TAG-enriched lipoproteins is therefore a two-step process. The first step produces dense apoB48 phospholipid-rich particles, which accumulate in the smooth endoplasmic reticulum lumen. In the second step, these dense particles rapidly acquire the bulk of the TAG and additional phospholipid in a single and rapid step.     

The molecular mechanism for the genetic disorder familial defective apolipoprotein B100

Familial defective apolipoprotein B100 (FDB) is a genetic disorder in which low density lipoproteins (LDL) bind defectively to the LDL receptor, resulting in hypercholesterolemia and premature atherosclerosis. FDB is caused by a mutation (R3500Q) that changes the conformation of apolipoprotein (apo) B100 near the receptor-binding site. We previously showed that arginine, not simply a positive charge, at residue 3500 is essential for normal receptor binding and that the carboxyl terminus of apoB100 is necessary for mutations affecting arginine 3500 to disrupt LDL receptor binding. Thus, normal receptor binding involves an interaction between arginine 3500 and tryptophan 4369 in the carboxyl tail of apoB100. W4369Y LDL and R3500Q LDL isolated from transgenic mice had identically defective LDL binding and a higher affinity for the monoclonal antibody MB47, which has an epitope flanking residue 3500. We conclude that arginine 3500 interacts with tryptophan 4369 and facilitates the conformation of apoB100 required for normal receptor binding of LDL. From our findings, we developed a model that explains how the carboxyl terminus of apoB100 interacts with the backbone of apoB100 that enwraps the LDL particle. Our model also explains how all known ligand-defective mutations in apoB100, including a newly discovered R3480W mutation in apoB100, cause defective receptor binding.     

Trans fatty acids alter the lipid composition and size of apoB-100-containing lipoproteins secreted by HepG2 cells

This study was conducted to determine the secretion rate and composition of lipoproteins secreted by HepG2 cells as influenced by the type of fatty acid present in the incubation medium. Cells were preincubated for 24 h with palmitic, oleic, elaidic, linoleic or conjugated linoleic acid (CLA), and the lipoproteins secreted during a subsequent incubation period of 24 h were collected for analysis. The secretion rate of apolipoprotein B-100 (apoB) was significantly greater in HepG2 cells preincubated with elaidic acid compared with those preincubated with palmitic or oleic acid; apoB secretion was greater in cells preincubated with CLA compared with those preincubated with linoleic acid. The lipid composition of secreted lipoproteins was also influenced by fatty acid treatment, resulting in significantly smaller lipoprotein particles secreted by cells preincubated with elaidic acid and CLA compared with those secreted by cells treated with oleic acid and linoleic acid, respectively. Our results are relevant to human metabolism for the following reasons: (1) the size of plasma low-density lipoproteins (LDLs) is determined, at least in part, by the composition of apoB-containing lipoproteins secreted by the liver; (2) small plasma LDL particles are associated with an increased risk of coronary heart disease; and (3) specific dietary fatty acids can affect the composition and size of plasma LDLs, thereby imparting a relative atherogenicity to plasma LDLs independent of LDL cholesterol concentration. The present study therefore suggests that elaidic acid and CLA promote the hepatic secretion of small apoB-containing lipoproteins, which could lead to an increased production of small plasma LDL particles.     

Intrahepatic assembly of very low density lipoproteins. Phosphorylation of small molecular weight apolipoprotein B

The possibility that apo-B is phosphorylated was examined using cultured rat hepatocytes. Rabbit antiserum prepared against rat apo-B was found to specifically react with both large and small molecular weight apo-B (by electroblotting assay and by immunoprecipitation of [35S]methionine-labeled proteins synthesized and secreted by hepatocytes). Following a 4-h incubation with [35P]orthophosphate, immunoprecipitation, and sodium dodecyl sulfate electrophoresis, an autoradiographic band corresponding to small molecular weight apo-B was obtained from cells and medium. Compared to the relative abundance of 32P which was associated with secreted small molecular weight apo-B, there was little (if any) detected in large molecular weight apo-B. Addition of excess unlabeled apo-B (obtained from rat serum) totally competed with the specific antiserum for this radioactive protein, indicating it was antigenically related to apo-B. Moreover, isolation of the 32P-labeled apo-B electrophoretic band, followed by acid hydrolysis and phosphoamino acid analysis, showed that at least 20% of the 32P originally associated with small molecular weight apo-B was in the form of phosphoserine. Control experiments ruled out the possible contamination of apo-B with phospholipid as well as the possibility that the phosphoserine produced by acid hydrolysis could have been derived from phosphatidylserine. To examine the relevance of these data to the in vivo state, rats were injected with [32P]orthophosphate. Immunoprecipitation of their livers followed by autoradiographic analysis showed the presence of 32P in small molecular weight apo-B. These data show for the first time that small molecular weight apo-B is synthesized as a phosphoserine containing protein.     

Arterial retention of apolipoprotein B(48)- and B(100)-containing lipoproteins in atherogenesis

PURPOSE OF REVIEW: The "response to retention" hypothesis of atherosclerosis suggests that the arterial deposition of cholesterol is directly proportional to the concentration of circulating plasma lipoproteins. However, there is increasing evidence to support the concept that specific lipoproteins may be preferentially retained within the arterial wall, possibly as a result of greater affinity for cell surface and extracellular matrices. RECENT FINDINGS: Recently, key studies have provided insight into mechanisms involved in the interaction of apolipoprotein B (apoB)-containing lipoproteins with extracellular matrices. In addition, novel methods and innovative experimental design has enabled us to differentiate between the delivery, retention and efflux of apoB(48)- and apoB(100)-containing lipoproteins. Other studies have demonstrated a relationship between extracellular matrix proteoglycan expression and the development of atherosclerosis. Discussion in the present review also extends to the mechanisms that are involved in the relative intimal retention of apoB(48)- and apoB(100)-containing lipoproteins in order to explain the atherogenicity of these macromolecules. SUMMARY: The perspective of this review is to highlight recent advances in the area of arterial lipoprotein retention and the physiological significance these processes may have in the aetiology of cardiovascular disease. Importantly, an understanding of the mechanisms responsible for the retention of apoB(48)/B(100)-containing lipoproteins will enable new strategies to be developed for the future management of cardiovascular disease.     

Influence of peroxisome proliferator-activated receptor alpha agonists on the intracellular turnover and secretion of apolipoprotein (Apo) B-100 and ApoB-48

The peroxisome proliferator-activated receptor (PPAR) alpha agonist WY 14,643 increased the secretion of apolipoprotein (apo) B-100, but not that of apoB-48, and decreased triglyceride biosynthesis and secretion from primary rat hepatocytes. These effects resulted in decreased secretion of apoB-100-very low density lipoprotein (VLDL) and an increased secretion of apoB-100 on low density lipoproteins/intermediate density lipoproteins. ApoB-48-VLDL was also replaced by more dense particles. The proteasomal inhibitor lactacystin did not influence the recovery of apoB-100 or apoB-48 in primary rat hepatocytes, indicating that co-translational (proteasomal) degradation is of less importance in these cells. Treatment with WY 14,643 made the recovery of apoB-100 sensitive to lactacystin, most likely reflecting the decreased biosynthesis of triglycerides. The PPAR alpha agonist induced a significant increase in the accumulation of pulse-labeled apoB-100 even after a short pulse (2-5 min). There was also an increase in apoB-100 nascent polypeptides, indicating that the co-translational degradation of apoB-100 was inhibited. However, a minor influence on an early posttranslation degradation cannot be excluded. This decreased co-translational degradation of apoB-100 explained the increased secretion of the protein. The levels of apoB-48 remained unchanged during these pulse-chase experiments, and albumin production was not affected, indicating a specific effect of PPAR alpha agonists on the co-translational degradation of apoB-100. These findings explain the difference in the rate of secretion of the two apoB proteins seen after PPAR alpha activation. PPAR alpha agonists increased the expression and biosynthesis of liver fatty acid-binding protein (LFABP). Increased expression of LFABP by transfection of McA-RH7777 cells increased the secretion of apoB-100, decreased triglyceride biosynthesis and secretion, and increased PPAR alpha mRNA levels. These findings suggest that PPAR alpha and LFABP could interact to amplify the effect of endogenous PPAR alpha agonists on the assembly of VLDL.     

Phospholipid transfer activity of microsomal triacylglycerol transfer protein is sufficient for the assembly and secretion of apolipoprotein B lipoproteins

Human microsomal triacylglycerol transfer protein (hMTP) is essential for apolipoprotein B (apoB)-lipoprotein assembly and secretion and is known to transfer triacylglycerols, cholesterol esters, and phospholipids. To understand the relative importance of each lipid transfer activity, we compared the ability of hMTP and its Drosophila ortholog (dMTP) to assemble apoB lipoproteins and to transfer various lipids. apoB48 secretion was induced when co-expressed with either hMTP or dMTP in COS cells, and oleic acid supplementation further augmented secretion without altering particle density. C-terminal epitope-tagged dMTP (dMTP-FLAG) facilitated the secretion of apoB polypeptides in the range of apoB48 to apoB72 but was approximately 50% as efficient as hMTP-FLAG. Comparison of lipid transfer activities revealed that although phospholipid transfer was similar in both orthologs, dMTP was unable to transfer neutral lipids. We conclude that the phospholipid transfer activity of MTP is sufficient for the assembly and secretion of primordial apoB lipoproteins and may represent its earliest function evolved for the mobilization of lipid in invertebrates. Identification of MTP inhibitors, which selectively affect transfer of a specific lipid class, may have therapeutic potential.     

Glyceride-cysteine lipoproteins and secretion by Gram-positive bacteria.

The membrane penicillinases of Bacillus licheniformis and Bacillus cereus are lipoproteins with N-terminal glyceride thioether modification identical to that of the Escherichia coli outer membrane lipoprotein. They are readily labeled with [3H]palmitate present during exponential growth. At the same time, a few other proteins in each organism become labeled and can be detected by fluorography after sodium dodecyl sulfate-polyacrylamide gel electrophoresis of total membrane proteins. We distinguish these proteins from the O-acyl proteolipids by demonstrating the formation of glyceryl cysteine sulfone after performic acid oxidation and hydrolysis of the protein. By this criterion, B. licheniformis and B. cereus contain sets of lipoproteins larger in average molecular weight than that of E. coli. Members of the sets probably are under a variety of physiological controls, as indicated by widely differing relative labeling intensity in different media. The set in B. licheniformis shares with membrane penicillinase a sensitivity to release from protoplasts by mild trypsin treatment, which suggests similar orientation on the outside of the membrane. At least one protein is the membrane-bound partner of an extracellular hydrophilic protein, the pair being related as membrane and exopenicillinases are. We propose that the lipoproteins of gram-positive organisms are the functional equivalent of periplasmic proteins in E. coli and other gram-negative bacteria, prevented from release by anchorage to the membrane rather than by a selectively impermeable outer membrane.     

Studies on the assembly and secretion of fibrinogen.

cDNAs of fibrinogen A alpha and gamma chains were individually subcloned into a eukaryotic expression vector by using the polymerase chain reaction. Triple cotransfection into COS cells of the two plasmids together with a B beta chain expression plasmid, constructed as described previously (Danishefsky, K.J., Hartwig, R., Banerjee, D., and Redman, C. (1990) Biochim. Biophys. Acta 1048, 202-208), resulted in the secretion of complete fibrinogen into the media and the formation of four additional intracellular complexes which we also showed to be present in the hepatocyte cell line Hep 3B. The complexes, which have Mr = 232, 150, 135, and 128 (x 10(-3) conform with the Mr expected for A alpha B beta gamma 2, B beta gamma 2 and gamma 3, respectively. A A mechanism of assembly is proposed based on the assumption that all these complexes are precursors of complete fibrinogen. Each of the expressed fibrinogen chains in transfected COS cells interacts noncovalently with binding protein (BiP, GRP 78), but not to the same extent; gamma chain binds less BiP than the A alpha and B beta chains. Assembly of fibrinogen is not absolutely required for its secretion. In addition to complete fibrinogen, the conditioned media of hepatocytes and of transfected COS cells contained free A alpha, free gamma, and two of the above-mentioned complexes, A alpha gamma 2 and A alpha B beta gamma 2.     

The type II secretion system: biogenesis, molecular architecture and mechanism

Many gram-negative bacteria use the sophisticated type II secretion system (T2SS) to translocate a wide range of proteins from the periplasm across the outer membrane. The inner-membrane platform of the T2SS is the nexus of the system and orchestrates the secretion process through its interactions with the periplasmic filamentous pseudopilus, the dodecameric outer-membrane complex and a cytoplasmic secretion ATPase. Here, recent structural and biochemical information is reviewed to describe our current knowledge of the biogenesis and architecture of the T2SS and its mechanism of action.     

Intrahepatic assembly of very low density lipoproteins. Rate of transport out of the endoplasmic reticulum determines rate of secretion

To identify the rate-limiting step(s) in the hepatic production of very low density lipoproteins (VLDL), we investigated the intracellular distribution and rate of intracellular transport of de novo synthesized apolipoprotein B (apoB). For all secretory proteins examined (i.e. albumin, large molecular weight apoB, and small molecular weight apoB) the rough and smooth microsomes contained the majority of intracellular de novo synthesized protein, while the Golgi subfraction contained 10% or less. Pulse-chase analysis of the intracellular movement of apoB and albumin showed that the first order rate constant (in terms of half-life) describing the rate of movement out of the smooth and rough microsomes determined the overall rate of movement out of the cell. These data suggest that movement out of the endoplasmic reticulum, the site where VLDL is assembled, determines the overall rate of secretion. Furthermore, compared to albumin, the rate of intracellular transport of apoB was approximately two times slower suggesting that processing unique to VLDL apoB occurring in the endoplasmic reticulum was responsible. Additional studies show that essentially all of the de novo synthesized 35S-labeled albumin (produced from a pulse of [35S]methionine) lost from the cell during the chase period could be recovered in the culture medium. In contrast, much less of large molecular weight apoB (36%) and small molecular weight apoB (60%) was recovered in the culture medium. Since these cultured rat hepatocytes do not take up or degrade newly secreted apoB, these data suggest that a significant amount of apoB is degraded intracellularly.     

Human ApoB-100 gene resides in the p23----pter region of chromosome 2

Human apolipoprotein (apo) B-100 is the major apolipoprotein of low density lipoproteins (LDL) and the principal ligand for interaction with the LDL receptor. The gene for apoB-100 has been localized to the p23----pter region of chromosome 2 by filter hybridization analysis with radiolabelled apoB-100 cDNA probes and human-mouse somatic cell hybrids containing chromosome 2 translocations. Other genes at the end of the short arm of chromosome 2 include acid phosphatase, proopiomelanocortin complex, malate dehydrogenase, and N-myc, the latter gene has been previously localized to the same bands (2p23----pter) as the apoB-100 gene. The localization of the apoB-100 gene to the p23----pter region of chromosome 2 completes the genomic organizational relationship of the LDL receptor and the two apolipoprotein ligands for the LDL receptor, apoE and apoB-100; the LDL receptor and apoE having been previously localized to chromosome 19.