Human apolipoprotein A-I. Post-translational modification by fatty acid acylation

The human apolipoproteins are secretory proteins some of which have been shown to undergo proteolytic processing and post-translational addition of carbohydrate. Apolipoprotein A-I (apo-A-I), the predominant protein associated with high density lipoproteins, undergoes co-translational proteolytic processing as well as post-translational conversion of proapo-A-I to mature apo-A-I following cellular secretion. Utilizing the human hepatoma cell line HEP-G2, we have established that, in addition to proteolytic processing, secreted nascent apo-A-I is acylated with palmitate. Uniformly labeled [14C]palmitate and [1-14C]palmitate were each incorporated into apo-A-I when analyzed by sodium dodecyl sulfate gel electrophoresis and autoradiography. The acylation of apo-A-I with palmitate was confirmed by immunoprecipitation and gas chromatography/mass spectrometry. Hydroxylamine treatment resulted in the deacylation of apo-A-I. Although three of the apo-A-I isoforms analyzed by two-dimensional gel electrophoresis were shown to contain radio-labeled palmitate, 80% of acylated apo-A-I was in the proapolipoprotein A-I isoform. [14C]Oleate was not incorporated in secreted apo-A-I, indicating the specificity of the acylation of apo-A-I. Incubation of [14C] palmitate-acylated apo-A-I in serum and plasma under conditions in which proapo-A-I is proteolytically cleaved to mature apo-A-I did not result in deacylation. These data establish that fatty acid acylation occurs in human secretory proteins in addition to the previously reported acylation of cellular membrane proteins. These results suggest that the covalent linkage of lipids to apolipoproteins may play a critical role in apolipoprotein and lipoprotein metabolism.     

In vitro conversion of proapoprotein A-I to apoprotein A-I. Partial characterization of an extracellular enzyme activity

Previous studies have established that human hepatocellular carcinoma cells (Hep G2) secrete into serum-free medium the pro form of apolipoprotein A-I (proapo-A-I) suggesting that its conversion to mature apo-A-I occurs after secretion. In order to assess the mode and site of proapo-A-I to apo-A-I conversion, we incubated the medium from [3H]proline-labeled Hep G2 cells with either human plasma, serum, lymph, or fractions thereof obtained by density gradient ultracentrifugation. The conversion was monitored by two-dimensional gel electrophoresis and by Edman degradation. Human plasma, serum, or mesenteric lymph all induced proapo-A-I to apo-A-I conversion; this was time dependent, unaffected by the serine protease inhibitor phenylmethylsulfonyl fluoride and inhibited by EDTA. Purified radiolabeled proapo-A-I bound to lymph chylomicrons and plasma high density lipoproteins. The converting enzyme was associated with both of these particles. Activity was also found in the d greater than 1.21-g/ml fraction and may have been derived from high density lipoprotein after displacement by high salts and/or ultracentrifugal force. We conclude that the conversion of proapo-A-I to apo-A-I occurs extracellularly and is probably effected by a metallo-enzyme which may act at the amphiphilic surface of either chylomicrons or high density lipoproteins.     

Apolipoprotein A-I isoprotein synthesis by the perfused rat liver

The hepatic pattern of synthesis of the apolipoprotein A-I isoforms has been analyzed in the rat. After isolated livers were perfused with defibrinated rat blood and [³H]leucine, the radioactivity associated with apolipoprotein A-I and other apolipoproteins was determined following two-dimensional gel electrophoresis of the perfusate d < 1.21 g/ml lipoprotein fraction. In rat serum, apolipoprotein A-I is a polymorphic system consisting of two major isoproteins and a series of minor species. Following liver perfusion, 72% of the radioactivity associated with apolipoprotein A-I isoproteins was recovered in the more acidic and quantitatively less abundant of the two major isoforms. Only 8% was associated with the major apolipoprotein A-I isoform, and similar or lower amounts were found in the other minor isoproteins. These results are consistent with the concept that, in the rat, the major apolipoprotein A-I isoforms differ in their pattern of biosynthesis and/or metabolism.     

Rat liver and small intestine produce proapolipoprotein A-I which is slowly processed to apolipoprotein A-I in the circulation

Two-dimensional electrophoretic analysis of plasma lipoproteins from male Osborne-Mendel rats consistently reveals three isoforms of apolipoprotein A-I (apo-A-I) with the following apparent pI values and quantitative distribution: isoform 3, pI = 5.68, 69%; isoform 4, pI = 5.55, 29%; isoform 5, pI = 5.44, 2%. The two major isoforms were obtained by preparative isoelectric focusing and subjected to NH2-terminal amino acid sequence analysis with the following results: isoform 3, (Asp)-Glu-Pro-Gln-Ser-Gln-Trp-Asp-Arg-Val; isoform 4, X-Glu-Phe-X-Gln-Gln-Asp-Glu-Pro-Gln-Ser. By comparison with the amino acid sequence previously reported for the primary translation product of rat intestinal apo-A-I mRNA (Gordon et al. (1982) J. Biol. Chem. 257, 971-978), isoform 3, the more basic isoform, is identified as mature apo-A-I and isoform 4 as its proform ( proapo -A-I). The proform differs from mature apo-A-I by a 6-amino acid extension at the NH2 terminus. Isoform 5 was not identified further. The plasma steady state distribution of the apo-A-I forms indicates that proapo -A-I is relatively stable in the circulation. Virtually all plasma proapo -A-I is lipoprotein-associated. No significant differences in the steady state proportions of plasma apo-A-I forms were observed between male and female rats, or among various subfractions of plasma high density lipoproteins obtained by heparin-Sepharose affinity chromatography or by density gradient ultracentrifugation. Rats fed a high fat, high cholesterol diet, however, showed an increase in the proportion of circulating proapo -A-I. The relative increase in proform was even more pronounced in rats fed a fat-free diet containing orotic acid. The biosynthesis, secretion, and metabolism of the various apo-A-I forms were also studied. In liver and intestine, the only known sites of apo-A-I synthesis in the rat, approximately 85% of the newly synthesized intracellular apo-A-I, was the proform . Proapo -A-I was also the predominant form (approximately 80%) released into the circulation by isolated, perfused livers and by autoperfused intestinal segments in vivo. Gradual processing of circulating proapo -A-I to mature apo-A-I was observed in vivo following pulse-labeling of apo-A-I with [3H]leucine. Processing in vivo was approximately 80% complete in 10 h.(ABSTRACT TRUNCATED AT 400 WORDS)     

Human apolipoprotein A-I isoprotein metabolism: proapoA-I conversion to mature apoA-I

ProapoA-I (apoA-i+2 isoform) is the major apoA-I isoprotein secreted by the liver and intestine; however, it is a minor isoprotein in plasma and lymph where the major A-I apo-lipoprotein is mature apoA-I (apoA-I0, apoA-I-1, and apoA-I-2 isoforms). In the present report we provide evidence that apoA-I is rapidly and quantitatively converted to mature apoA-I, and the mature apoA-I isoforms are catabolized at equal rates. In these studies, human proapoA-I was isolated from thoracic duct chylomicrons collected during active fat absorption and mature apoA-I was isolated from plasma high density lipoproteins. The isolated lipoproteins were delipidated, fractionated by gel permeation chromatography, and the individual apoA-I isoforms were separated by preparative isoelectrofocusing. The metabolism of apoA-I isoproteins was studied in normal volunteers (N = 6) in a metabolic ward. In the first study proapoA-I and mature apoA-I (apoA-I0 isoform) were injected simultaneously into two normal subjects and the conversion of proapoA-I to mature apoA-I and the decay of radioactivity were followed in plasma and HDL over a 14-day period. ProapoA-I was rapidly and completely converted to mature apoA-I with a fractional rate of conversion of 4.0 pools/day. The average residence times of proapoA-I and mature apoA-I were 0.23 and 6.5 days, respectively. The mature apoA-I derived from proapoA-I had a residence time which was the same as the injected mature apoA-I.(ABSTRACT TRUNCATED AT 250 WORDS)     

Tangier disease. In vitro conversion of proapo-A-ITangier to mature APO-A-ITangier

Tangier disease is a disorder characterized by low levels of apo-A-I and high density lipoproteins. The defect in Tangier disease is an abnormal A-I apolipo protein, designated apo-A- ITangier . In normal subjects, apo-A-I is secreted as proapo -A-I with subsequent extracellular conversion to mature apo-A-I. The major form in normal plasma is mature apo-A-I with small amounts of proapo -A-I. In Tangier disease, proapo -A- ITangier is present in roughly equivalent concentrations compared to mature apo-A- ITangier . It has been proposed that the defect in Tangier disease is in the conversion of pro- to mature apo-A- ITangier . To test this, proapo -A-I was isolated from normal and Tangier subjects, and the conversion to the mature form by plasma from normal and Tangier subjects was analyzed. Incubation of radiolabeled normal proapo -A-I in normal plasma anticoagulated with heparin was associated with progressive conversion to mature apo-A-I over 24 h (initially 85% of the radioactivity was in the proapo -A-I isoform; at 24 h 33% radioactivity remained in the pro-isoform). Proapo -A- ITangier was also converted to the mature isoform during 24 h of incubation in normal plasma. Initially, 84% of radioactivity was in proapo -A- ITangier , and by 24 h the radioactivity in this isoprotein had decreased to 36%. A similar pattern of conversion was also observed when proapo -A- ITangier was incubated in Tangier plasma. The proteolytic conversion of both normal proapo -A-I and proapo -A- ITangier was unaffected by the serine protease inhibitors phenylmethylsulfonyl fluoride (1 mM) or aprotinin (200 Kallikrein-inactivating units/ml), but was inhibited by EDTA (0.1%). These results indicate that proapo -A- ITangier can be converted to mature apo-A- ITangier by the converting enzyme in normal plasma. In addition, plasma from a Tangier subject can convert both normal and Tangier proapo -A-I to the mature form. These results establish that proapo -A- ITangier can be rapidly converted to mature apo-A- ITangier , and there is no deficiency of the converting enzyme activity in Tangier disease.     

Proteolytic processing of human preproapolipoprotein A-I. A proposed defect in the conversion of pro A-I to A-I in Tangier's disease

The primary translation product of human intestinal apolipoprotein A-I mRNA was isolated from wheat germ and ascites cell-free translation systems. Comparison of its NH2-terminal sequence with that of plasma high density lipoprotein-associated A-I showed that it is initially synthesized as a preproprotein. Like rat preproapolipoprotein A-I, it contains an 18-amino acid prepeptide and a 6-amino acid propeptide. The highly unusual COOH-terminal Gln-Gln dipeptide present in the rat pro-segment is also represented at the same position in the human sequence. The functional division of the 24-amino acid NH2-terminal extention into pro- and presegments was verified by finding that the stable intracellular form of A-I in a human hepatoma cell line was the proprotein. Edman degradation of radiolabeled intracellular and extracellular A-I indicated that this apolipoprotein was secreted without proteolytic cleavage of its hexapeptide prosegment. Therefore, it appears that apolipoprotein A-I undergoes an additional proteolytic processing step before it is fully integrated into plasma high density lipoprotein. Two-dimensional gel electrophoresis of purified proapolipoprotein A-I isolated from the hepatocyte cell culture media indicated that it corresponds to isoforms 2 and 3, the basic A-I isoproteins which are the precursors of plasma A-I and the predominant plasma A-I isoforms found in patients with Tangier's disease (Zannis, V. I., Lees, A. M., Lees, R. S., and Breslow, J. L. (1982) J. Biol. Chem., 257, 4978-4986). Therefore this pathologic state probably arises from a defect in the conversion of proapolipoprotein A-I to apolipoprotein A-I.     

A method to screen apolipoprotein polymorphisms in whole plasma: description of apolipoprotein A-IV variants in dyslipidemias and a reassessment of apolipoprotein A-I in Tangier disease

A sensitive and rapid immunological detection method was used to screen for apolipoprotein A-IV variants. Antibodies to human lymph chylomicron or plasma apolipoprotein A-IV, and plasma apolipoprotein A-I were raised in rabbits. Antibodies to apolipoprotein A-I or apolipoprotein A-IV were shown to be monospecific to their respective antigens by reactivity against human chylomicron apolipoproteins by immunoblot analysis. Plasma samples were obtained from dyslipidemic subjects from the Lipid Research Clinic of Columbia University. The plasma samples were isoelectrically focused (pH 4-6) on slab gels. Plasma proteins were then transferred to nitrocellulose paper for immunoblotting. Apolipoprotein A-IV polymorphism was determined by specific immunological detection of apolipoprotein A-IV. Identical apolipoprotein A-IV isoprotein patterns were observed when either antibodies to lymph or plasma apolipoprotein A-IV were used for immunoblotting. All the dyslipidemic plasma samples screened contained the two major and one or two minor isoproteins of normal plasma. In two instances, new apolipoprotein A-IV variants having an additional isoform were detected. One subject was hypertriglyceridemic (triacylglycerols = 342 mg/dl, cholesterol = 251 mg/dl) and had an additional major acidic apolipoprotein A-IV isoform. Another subject with mild hypocholesterolemia (triacylglycerols = 209 mg/dl, cholesterol = 120 mg/dl) was found to have additional major and minor basic apolipoprotein A-IV isoforms. The specificity of this technique allows detection of polymorphism of apolipoproteins of similar isoelectric points by use of a single dimension isoelectric focusing gel. This technique also demonstrated the presence of altered apolipoprotein A-I isoforms in the plasma of a patient with Tangier disease. These isoforms were previously identified as isoforms 2 and 4 of normal plasma by use of two-dimensional gel electrophoresis. However, by use of this new technique and careful evaluation of previously published two-dimensional gels, we now identify these apolipoprotein A-I isoforms as being more acidic than those of normal plasma.     

Human proapolipoprotein A-I: development of an antibody to the propeptide as a probe of apolipoprotein A-I biosynthesis and processing

In human plasma, apolipoprotein A-I is present as pro and mature isoproteins. The development of a highly specific antibody to the pro isoprotein of apoA-I has been difficult due to the close structural similarity between the pro and mature isoforms of apoA-I. To sermount this difficulty, a peptide was synthesized by the solid phase method which corresponded to the amino acid sequence present in the pro region of apoA-I. The synthetic peptide was coupled to serum albumin and the conjugate utilized to immunize rabbits for antibody production. Immunoblot analysis of purified proapoA-I and mature apoA-I revealed that the antibody was specific for the propeptide of apoA-I. Analysis of apoA-I in the plasma from a Tangier disease patient and newly secreted apoA-I from HepG2 cells clearly demonstrated the isoforms which contained the proisoprotein. The proapoA-I specific antibody should prove to be a useful tool in developing a radioimmunoassay for quantitation of the proisoprotein in plasma, isolation of proapoA-I from normal and dyslipoproteinemic subjects by immunoaffinity chromatography and in studies related to the synthesis and processing of apoA-I.     

Human apolipoprotein A-I polymorphism. Identification of amino acid substitutions in three electrophoretic variants of the Münster-3 type

Variant forms of apolipoprotein A-I (apo-A-I) have been shown to exist in the human population. One mutant form, referred to as apo-A-I-Münster-3, is one charge unit more basic than normal apo-A-I on isoelectric focusing gels. This variant has the same immunologic characteristics and molecular weight as normal apo-A-I. The apo-A-I-Münster-3 from subjects in three unrelated families (in two of which the trait has been shown to be transmitted as an autosomal co-dominant) has been analyzed by partial amino acid sequencing to define the cause of the electrophoretic abnormality. In the apo-A-I of family A, the abnormality was shown to occur in the smallest cyanogen bromide fragment, CB-2 (residues 87-112), and amino acid sequencing revealed asparagine instead of the usual aspartic acid at residue 103. Subjects with this mutant form have shown no signs of dyslipoproteinemia. The NH2-terminal cyanogen bromide fragment (CB-1, residues 1-86) from the apo-A-I of family B was shown to differ electrophoretically from normal CB-1, and amino acid sequencing revealed that a substitution of arginine for proline at residue 4 was responsible for this variant form. Analysis of the plasma lipids of one affected family B member demonstrated that the percentage of the total cholesterol that was esterified was somewhat lower than that normally observed. In a third family, family C, a variant having the same electrophoretic abnormality as the other two was determined to have an amino acid substitution at yet a different position. In this variant, histidine was found at residue 3 in the apo-A-I sequence, rather than the usual proline. In all three cases, the substitution could account for the electrophoretic abnormality. It is proposed that these three apo-A-I-Münster-3 variants be designated apo-A-I(Asp103----Asn), apo-A-I(Pro4----Arg), and apo-A-I(Pro3----His), respectively, to indicate the substitution that accounts for the abnormality in isoelectric focusing gels.     

Isoproteins of human apolipoprotein A-II: isolation and characterization

In human serum, polymorphism of apoA-II predominantly in HDL3 could be demonstrated. HDL3-apoA-II was composed of four isoproteins, each with a molecular weight of 8600 (reduced form) and identical immunological properties. The isoproteins are designated apoA-II-1 (pI 5.16), apoA-II-2 (pI 4.89) corresponding to the already known apoA-II monomer band, apoA-II-3 (pI 4.58), and apoA-II-4 (pI 4.31). The amino acid compositions of the A-II isoproteins were virtually identical with the published data for apoA-II. Treatment with acid phosphatase, alkaline phosphatase, or neuraminidase before electrophoresis did not alter the apoA-II pattern. The apoA-II isoprotein pattern was studied in ten male and ten female normolipidemic volunteers, in two patients with Tangier disease, and in three patients with abetalipoproteinemia. The isoelectric focusing patterns of apoA-II appeared virtually identical in all subjects. However, in Tangier disease, due to the low apo-A-II concentration, only apoA-II-1 and apoA-II-2 were detectable, and in abetalipoproteinemia a different relative distribution pattern of the individual isoforms was found as compared to normal HDL3. Our studies indicate that apoA-II, similar to apoA-I, exists in several isoforms. The relationship of these isoforms to each other is at present unclear. They may originate from relatively basic isoproteins that are modified in charge by post-translational processes such as proteolytic cleavage, sequential deamidation, or other mechanisms.     

The charge polymorphism of rat apoprotein E

Rat apolipoprotein E (apo-E) exists in plasma as four unique isoelectric forms (designated E-1, E-2, E-3, or E-4 from acidic to basic, respectively). We have examined the processes accounting for this polymorphism using intact rats or cultured rat hepatocytes. Intrahepatic precursors of rat apo-E were isolated and analyzed on isoelectric focusing gels. The primary translation product of rat liver apo-E mRNA focused as two isoproteins with more basic pI values than the isoproteins of plasma apo-E. The microsome-processed translation product also focused as two isoproteins having pI values corresponding to apo-E-4 and apo-E-3 isoproteins of plasma apo-E. Following a bolus injection of [3H]leucine into the portal vein, intrahepatic isoproteins corresponding to plasma apo-E-2 and apo-E-1 isoproteins were first detected in the rough endoplasmic reticulum (RER) and Golgi fractions, respectively. The apparent molecular weight of intrahepatic apo-E increased as it passed from the RER to the Golgi. Only the most acidic isoform, apo-E-1, of plasma apo-E was sensitive to neuraminidase treatment indicating that sialic acid residues are responsible, in part, for the polymorphism of rat apo-E. Using cultured hepatocytes, tunicamycin (1 microgram/ml) inhibited the incorporation of [3H]glucosamine into both molecular weight forms of apolipoprotein B but did not influence the synthesis, glycosylation (as measured by [3H]glucosamine incorporation), or secretion of apo-E. Tunicamycin-inhibited hepatocytes secreted the normal complement of apo-E isoforms including apo-E-1, thus confirming that apo-E-1 is not an N-linked glycoprotein. These results suggest that post-translational modifications involving both RER and Golgi-specific reactions contribute to the polymorphism of rat apo-E.     

Optic Nerve Regeneration in Adult Fish and Apolipoprotein A-I

Fish optic nerves, unlike mammalian optic nerves, are endowed with a high capacity to regenerate. Injury to fish optic nerves causes pronounced changes in the composition of pulse-labeled substances derived from the surrounding non-neuronal cells. The most prominent of these injury-induced changes is in a 28-kilodalton (kDa) polypeptide whose level increases after injury, as revealed by one-dimensional gel electrophoresis and autoradiography. The present study identified as apolipoprotein A-I (apo-A-I) a polypeptide of 28 kDa in media conditioned by regenerating fish optic nerves. The level of this polypeptide increased after injury by approximately 35%. Apo-A-I was isolated by gel-permeation chromatography from delipidated high-density lipoproteins (HDL) that had been obtained from carp plasma by sequential ultracentrifugation. Further identification of the purified protein as apo-A-I was based on its molecular mass (28 kDa) as determined by gel electrophoresis, amino acid composition, and microheterogeneity studies. The isolated protein was further analyzed by immunoblots of two-dimensional gels and was found to contain six isoforms. Western blot analysis using antibodies directed against the isolated plasma protein showed that the 28-kDa polypeptide in the preparation of soluble substances derived from the fish optic nerves (conditioned media, CM) cross-reacted immunologically with the isolated fish plasma apo-A-I. Immunoblots of two-dimensional gels revealed the presence of three apo-A-I isoforms in the CM of regenerating fish optic nerves (pIs: 6.49, 6.64, and 6.73). At least some of the apo-A-I found in the CM is derived from the nerve, as was shown by pulse labeling with [35S]methionine, followed by immunoprecipitation. The apo-A-I immunoactive polypeptides in the CM of the fish optic nerve were found in high molecular-weight, putative HDL-like particles. Immunocytochemical staining revealed that apo-A-I immunoreactive sites were present in the fish optic nerves. Higher labeling was found in injured nerves (between the site of injury and the brain) than in non-injured nerves. The accumulation of apo-A-I in nerves that are capable of regenerating may be similar to that of apo-E in sciatic nerves of mammals (a regenerative system); in contrast, although its synthesis is increased, apo-A-I does not accumulate in avian optic nerves nor does apo-E in rat optic nerves (two nonregenerative systems).     

Comparison of the metabolic behavior of rat apolipoproteins A-I and A-IV, isolated from both lymph chylomicrons and serum high density lipoproteins

Rat apolipoprotein (apo) A-I and A-IV, isolated from both lymph chylomicrons and serum high density lipoproteins (HDL) were analyzed by isoelectric focusing. Lymph chylomicron apo A-I consisted for 81 +/- 2% of the pro form and for 19 +/- 2% of the mature form, while apo A-I isolated from serum HDL was present for 36 +/- 4% in the pro form and for 64 +/- 4% in the mature form. Apo A-IV also showed two major protein bands after analysis by isoelectric focusing. The most prominent component is the more basic protein that amounts to 80 +/- 2% in apo A-IV isolated from lymph chylomicrons and to 60 +/- 3% in apo A-IV isolated from serum HDL. Apo A-I (or apo A-IV), isolated from both sources (lymph chylomicrons or serum HDL), was iodinated and the radioactive apolipoproteins were incorporated into rat serum lipoproteins. The resulting labeled HDL was isolated from serum by molecular sieve chromatography on 6% agarose columns and injected intravenously into rats. No difference in the fractional turnover rate or the tissue uptake of the two labeled HDL preparations was observed, neither for apo A-I nor for apo A-IV. It is concluded that the physiological significance of the extracellular pro apo A-I conversion or the post-translational modification of apo A-IV is not related to the fractional turnover rate in serum or to the rate of catabolism in liver and kidneys.     

Activation of lecithin: cholesterol acyltransferase by human apolipoprotein A-IV

Human plasma apoproteins (apo) A-I and A-IV both activate the enzyme lecithin:cholesterol acyltransferase (EC 2.3.1.43). Lecithin:cholesterol acyltransferase activity was measured by the conversion of [4-14C] cholesterol to [4-14C]cholesteryl ester using artificial phospholipid/cholesterol/[4-14C]cholesterol/apoprotein substrates. The substrate was prepared by the addition of apoprotein to a sonicated aqueous dispersion of phospholipid/cholesterol/[4-14C]cholesterol. The activation of lecithin:cholesterol acyltransferase by apo-A-I and -A-IV differed, depending upon the nature of the hydrocarbon chains of the sn-L-alpha-phosphatidylcholine acyl donor. Apo-A-I was a more potent activator than apo-A-IV with egg yolk lecithin, L-alpha-dioleoylphosphatidylcholine, and L-alpha-phosphatidylcholine substituted with one saturated and one unsaturated fatty acid regardless of the substitution position. When L-alpha-phosphatidylcholine esterified with two saturated fatty acids was used as acyl donor, apo-A-IV was more active than apo-A-I in stimulating the lecithin:cholesterol acyltransferase reaction. Complexes of phosphatidylcholines substituted with two saturated fatty acids served as substrate for lecithin:cholesterol acyltransferase even in the absence of any activator protein. Essentially the same results were obtained when substrate complexes (phospholipid-cholesterol-[4-14C]cholesterol-apoprotein) were prepared by a detergent dialysis procedure. Apo-A-IV-L-alpha-dimyristoylphosphatidylcholine complexes thus prepared were shown to be homogeneous particles by column chromatography and density gradient ultracentrifugation. It is concluded that apo-A-IV is able to facilitate the lecithin:cholesterol acyltransferase reaction in vitro.     

Biosynthesis of apolipoprotein C-III in rat liver and small intestinal mucosa

We have examined the biosynthesis of rat apolipoprotein C-III in the small intestine and liver. The primary translation product of its mRNA was recovered from wheat germ and ascites cell-free systems. Comparison of its NH2-terminal sequence with the NH2 terminus of plasma high density lipoprotein-associated apolipoprotein C-III showed that apo-C-III was initially synthesized as a preprotein with a 20 amino acid long NH2-terminal extension: Met-X-X-X-Met-Leu-Leu-X-X-Ala-Leu-X-Ala-Leu-Leu-Ala-X-Ala-X-Ala. Co-translational cleavage of the cell-free translation product by signal peptidase generated a polypeptide with the same NH2 terminus as the mature protein (X-Glu-X-Glu-Gly-Ser-Leu-Leu-Leu-Gly-Ser-Met). Therefore, this apolipoprotein does not undergo post-translational proteolytic processing like two other high density lipoprotein-affiliated proteins, proapo-A-I and proapo-A-II. The mRNA encoding apolipoprotein C-III comprises 0.4% of the translatable RNA species in adult rat liver and 0.14% of the translatable RNA species in small intestinal epithelium. Acute fat feeding with a triglyceride meal resulted in a 2-fold increase in intestinal preapo-C-III mRNA accumulation but no change in the levels of preproapo-A-I mRNA. Thus, the acute response of the apo-A-I and C-III genes to triacylglycerol absorption differs.     

Chain length-function correlation of amphiphilic peptides. Synthesis and surface properties of a tetratetracontapeptide segment of apolipoprotein A-I

The segment corresponding to residues 121 to 164 of human plasma apolipoprotein A-I (apo-A-I) has been synthesized by the Merrifield solid phase method. The peptide binds to unilamellar phospholipid vesicles and to phospholipid-cholesterol mixed vesicles. The surface affinity of the peptide measured in this way indicated that the mechanism of binding is the same as that of apo A-I (144-165) and apo A-I itself. The peptide appears to be a globular monomer in a aqueous solution, with 17% alpha helix content. The peptide bound to vesicles activates lecithin:cholesterol acyltransferase: compared to apo A-I, the peptide is about 30% as efficient in the activation of cholesterol esterification and of phospholipid hydrolysis when the surface is saturated by the activator. For a variety of amphiphilic peptides and for apo A-I, the lecithin: cholesterol acyltransferase-activating ability correlates well with their alpha helix contents in 50% trifluoroethanol.     

Interaction between hepatic microsomal membrane lipids and apolipoprotein A-I

Incubation of apoprotein A-I (apo-A-I), the major protein component of human high density lipoprotein, with rat liver microsomal membranes under conditions of elevated pH and ionic strength leads to the production of a soluble protein:lipid complex (A-I/MM complex). The A-I/MM complex, as purified by density gradient centrifugation and agarose column chromatography, possesses a lipid composition similar to the hepatic microsomal membrane and a protein/lipid ratio similar to that of plasma high density lipoproteins, but markedly different from that of recombinant particles prepared with synthetic lipids. The A-I/MM complex constitutes a more physiological recombinant particle than can be formed using synthetic lipids and may be a suitable model for the newly assembled intracellular high density lipoproteins. Incubation of the erythrocyte plasma membranes with apo-A-I under the same conditions as used with microsomal membranes fails to generate any lipid:apoprotein complexes. This membrane specificity for forming soluble lipoprotein complexes suggests that the microsomal membranes possess a unique feature, possibly their lipid composition, which render them particularly suitable to serve as lipid donors to the apoproteins which are undergoing assembly within the endoplasmic reticulum/Golgi organelles.     

Intracellular modification of human apolipoprotein AII (apoAII) and sites of apoAII mRNA synthesis: comparison of apoAII with apoCII and apoCIII isoproteins

We have studied the intracellular modifications of human apoAII by pulse-chase labeling of HepG2 cell cultures with [35S]methionine or [3H]arginine followed by two-dimensional analysis and autoradiography of the radiolabeled apoAII isoproteins. A short (5.0-min) pulse showed the presence of a precursor form of apoAII (pI = 5.75) designated proapoAII or apoAII3. A 5-10-min chase resulted in a decrease in the relative concentration of the proapoAII coupled with an increase in the relative concentration of a new form (pI = 5.3) designated modified proapoAII or apoAII1. Longer chase resulted in the appearance of the plasma apoAII form and at least five other acidic apoAII isoproteins in the cell lysate and the culture medium. Labeling with [3H]arginine showed that apoAII isoproteins designated 3, 1, -1, and -3 contained the prosegment whereas isoproteins designated 1a, 0, -1a, -2a, -3a, and -4a did not. Comparison of nascent apoAII, apoCII, and apoCIII isoproteins revealed that they were distinctly different on the two-dimensional gels. Neuraminidase treatment converted the acidic apoAII isoproteins to isoproteins 1a and 0 (modified and plasma apoAII forms). The combined data are consistent with the following intra- and/or extracellular modifications of apoAII: (a) modification of the apoAII which results in the net loss of two positive charges; (b) glycosylation of the modified proapoAII with carbohydrate chains containing sialic acid; (c) proteolytic removal of the prosegment and cyclization of the N-terminal glutamine. Analysis of apoAII mRNA distribution in 13 fetal human tissues as well as in cell lines of human origin showed abundance of apoAII mRNA in liver and HepG2 cells and only traces in the intestine.     

The covalent structure of apolipoprotein A-I from canine high density lipoproteins

The complete amino acid sequence of apolipoprotein A-I (apo-A-I) from canine serum high density lipoproteins (HLD) has been determined by automated Edman degradation of the intact protein and proteolytic fragments derived therefrom. The major strategy involved analysis of overlapping sets of peptides generated by cleavage at lysyl residues with Myxobacter protease and by tryptic hydrolysis at arginines in the citraconylated protein derivative. Canine apo-A-I has 232 residues in its single polypeptide chain and its covalent structure is highly homologous to one of the two reported sequences for human apo-A-I. As in the case for the human apoprotein, predictive analysis of the canine apo-A-I sequence suggests that it comprises a series of amphiphilic alpha helices punctuated by a periodic array of prolyl residues. Human HDL contains a second major protein component, apolipoprotein A-II (apo-A-II) that is lacking in HDL from dog serum. The absence of apo-A-II in canine HDL raised the possibility that the apo-A-I from this source might contain within its primary structure sequences related to apo-A-II and thus perform the dual function of both proteins in one. Our analysis proves that canine apo-A-I has all of the structural features of human apo-A-I and that it is not an A-I: A-II hybrid molecule.