From the Department of Molecular Genetics, University
and Biocenter Vienna, A-1030 Vienna, Austria, the
¶ Department of Molecular Biotechnology, University of
Washington, Seattle, Washington 98195, and the ** Department of Internal
Medicine, The Bowman Gray School of Medicine, Winston-Salem,
North Carolina 27157
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ABSTRACT |
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In birds, intestinally derived
lipoproteins are thought to be secreted directly into the portal vein
rather than to enter the circulation via the lymphatic system as in
mammals. Hepatic clearance of these so-called portomicrons must be
rapid, but the protein(s) mediating their catabolism, presumably
analogues of the 36-kDa mammalian apolipoprotein E, have not been
identified. In searching for such a mediator(s), we have isolated a
hitherto unknown 38-kDa protein from chicken serum, which we identified by microsequencing and molecular cloning as a counterpart to mammalian apolipoprotein AIV (apoAIV). Mature chicken apoAIV consists of 347 amino acids, lacks cysteine residues, and displays 57% sequence identity with human apoAIV and, to a significantly lesser extent, with
apoAIVs of rodents. This first nonmammalian apoAIV characterized is the
smallest homologue reported so far, because of the lack of repeated
motifs at the carboxyl terminus with the consensus sequence
Glu-Gln-Glu/Ala-Gln, a hallmark of mammalian apoAIVs. Chicken apoAIV
(isoelectric point, 4.65) is also considerably more acidic than its
human counterpart. Agarose gel electrophoresis revealed that unlike
human apoAIV, which migrates to a pre--position, chicken apoAIV
shows fast
migration. Functional characterization demonstrated that
the avian protein is able to activate the enzyme lecithin:cholesterol
acyltransferase. Roosters and hens express apoAIV predominantly in the
gut, one-fifth as much in the liver, and no other sites of expression
are identifiable by Northern blot analysis. Although pronounced
intestinal synthesis is common to apoAIVs, the features of the avian
protein support the notion that it represents a prototype of an
apoprotein that evolved to acquire possibly distinct functions in
mammals and birds.
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INTRODUCTION |
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Key molecules of lipoprotein metabolism in birds and mammals display many common features but also differ in several aspects. For instance, apolipoprotein (apo)1 B of very low-density lipoproteins (VLDL) and low-density lipoproteins (LDL) are well conserved among mammals and in the chicken (1-3). However, whereas mammalian plasma apoB exists in two forms, apoB-48 and apoB-100 (4, 5), the chicken produces only apoB-100. Mammalian apoB-48 production arises from apoB mRNA editing (6-8) that generates, via deamination of the C in position 6538 to a U, an in-frame translational stop codon (UAA) corresponding to residue 2153 (glutamine) of the human 512-kDa apoB-100 (9). This process is not observed in the chicken (10). ApoB-100 but not apoB-48 contains the binding domain recognized by the LDL receptor (11) and related receptors, including those of the chicken (12-15).
A further difference concerns the metabolism of intestinally derived lipoproteins in birds; they are not delivered to the lymphatic system but rather are thought to be secreted into the portal vein as so-called, yet to be isolated, portomicrons (16), which are subject to subsequent rapid uptake by the liver. Separation of chicken plasma lipoproteins has been performed by sequential ultracentrifugation (2), by conventional density gradient ultracentrifugation (1), or by a faster vertical spin technique (17); however, a separate portomicron entity has not been identified during the characterization of isolated lipoprotein fractions. This could be due to a lack of circulating portomicrons in peripheral blood or from difficulties in separating portomicrons from hepatically derived VLDL, as both particles are likely to carry apoB-100 in view of the absence of apoB editing in the chicken (10). Likewise, the mediator(s) of hepatic clearance of portomicrons has not been identified, but candidates for receptor binding are apoB-100, lipoprotein lipase, and/or as yet unknown proteins (18). In addition to apoB-100, mammalian apoE was found to be an in vitro ligand for the chicken homologues of the mammalian LDL receptor gene family (13, 19). Importantly, however, synthesis of apoE in chicken has not been demonstrated to date (1, 2, 20), prompting us to investigate further the possibility of expression of an avian apoE or surrogate protein(s).
Recently, a sea lion apolipoprotein with a molecular mass of 36,053 Da has been identified as apoE (21). This protein is 12 residues longer than its human counterpart and thus represents the largest apoE molecule identified so far. In our search for hitherto unidentified chicken apolipoproteins, we discovered and purified an apoprotein with an apparent molecular mass of ~38,000 Da, reminiscent of apoE in the sea lion. However, as reported here, N-terminal sequencing of the protein revealed high homology to mammalian apoAIV (22-26), an apolipoprotein that shares several characteristics with apoE (27). Molecular cloning of the corresponding cDNA and characterization of the protein indeed demonstrates for the first time that apoAIV expression is not limited to mammals.
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EXPERIMENTAL PROCEDURES |
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Animals-- White leghorn laying hens and roosters were obtained from Heindl (Vienna, Austria) and maintained as described previously (28). Adult female New Zealand White rabbits were used for raising antibodies.
Lipoprotein and Apolipoprotein Isolation and Antibody
Production--
Blood (10 ml) was drawn from the wing veins of laying
hens and mature roosters into tubes containing 1 mg/ml EDTA, placed on
ice, and plasma was separated by low speed centrifugation (3000 × g) for 20 min at 4 °C. Plasma was adjusted to a density
of 1.063 g/ml by adding solid KBr, and the lipoproteins were floated by centrifugation in a TLA 120.2 rotor at 120,000 rpm for 1 h 40 min
(29) using a Beckman Optima TLX ultracentrifuge (Beckman Instruments).
The d < 1.063 lipoproteins were recovered with a syringe,
dialyzed against 10 mM Tris-HCl, 140 mM NaCl, 1 mM EDTA, pH 7.4, and delipidated in ether/ethanol (1:3,
v/v) at 20 °C. The 38-kDa apoprotein was purified from the d < 1.063 lipoprotein fraction by preparation by SDS-polyacrylamide gel
electrophoresis. Although the isolation from this fraction was highly
reproducible, subsequent Western blotting analysis (see below) revealed
that more than 80% of the 38-kDa apoprotein resided in the d > 1.063 lipoprotein fraction. Rabbit antibodies were obtained by intracutaneous injection of 200 µg of the protein mixed with complete Freund's adjuvant followed by injections of 200 µg of protein each mixed with
Freund's incomplete adjuvant 3, 6, and 8 weeks later. Antisera were
tested by Western blotting using preimmune serum as control. Human
apoAI and apoAIV were isolated as described (30).
Microsequencing-- The 38-kDa apolipoprotein was subjected to SDS-polyacrylamide gel electrophoresis and blotted onto a polyvinylidene difluoride membrane (Immobilon P, 0.45 µm, Millipore Corp., Bedford, MA). Microsequencing of the protein was carried out essentially as described (31).
Lipoprotein and Apoprotein Analysis-- To analyze the apoprotein content of plasma lipoprotein fractions, 200 µl of plasma were separated on a Superose-12 column (1 × 30 cm; Amersham Pharmacia Biotech) operated at a flow rate of 0.3 ml/min in 20 mM Tris-HCl, 140 mM NaCl, 1 mg/ml EDTA, pH 7.4. The positions of lipoproteins in the eluted fractions were determined by cholesterol measurement (Boehringer Mannheim). Aliquots of the fractions were separated by electrophoresis on 4-20% SDS gradient polyacrylamide gels, and apoproteins AI, B, and the 38 kDa-apoprotein were identified by Western blotting with specific antibodies.
Lipoprotein fractions containing apoAI or the 38-kDa apoprotein were immunoprecipitated. To aliquots of the fractions were added equal volumes of immunoprecipitation buffer (50 mM Tris-HCl, 150 mM NaCl, 5 mM EDTA, 0.5% Triton X-100, 0.1% SDS, pH 7.4), and incubation with the respective antisera at a dilution of 1:60 and protein A-Sepharose beads was carried out for 16 h at 4 °C. The protein A-Sepharose beads were washed three times with phosphate-buffered saline. The beads were resuspended in Laemmli sample buffer containing 2% 2-mercaptoethanol, and the precipitated proteins were eluted by heating to 95 °C for 5 min and subjected to electrophoresis on 4-20% SDS gradient polyacrylamide gels. Chicken and human lipoproteins were separated by agarose gel electrophoresis and crossed immunoelectrophoresis was performed using antibodies to human apoAIV (32) and to the chicken 38-kDa protein, respectively.Isoelectric Focusing and Determination of Isoelectric Point-- Apolipoproteins were analyzed by isoelectric focusing in 6 M urea-containing gels with the PhastSystem essentially as described (33). Plasma was diluted 50-fold and 1 µl was applied close to the cathode. Isoelectric focusing was performed with a gel containing only one sample lane at one side to determine the position of the protein. Immediately after isoelectric focusing, the lane containing the sample was cut off and subjected to Western blotting. The remaining gel was cut into 2-mm strips of approximately 25 µl volume. Strips were incubated overnight at 20 °C in plastic tubes containing 1.4 ml of distilled water and the resulting pH was measured (34). The position of the protein was then localized within the established pH gradient and assigned an isoelectric point.
Western Blotting-- Delipidated apolipoproteins or aliquots of column fractions were separated on 4-20% SDS gradient polyacrylamide gels (35) and transferred electrophoretically to nitrocellulose (36). The nitrocellulose membranes were blocked with 5% powdered milk in phosphate-buffered saline containing 0.1% Tween 20, incubated with antiserum (diluted 1:1000), developed with goat anti-rabbit IgG conjugated to horseradish peroxidase, and detected with the enhanced chemiluminescence method (37).
Isolation of Human and Chicken Lecithin:Cholesterol Acyltransferase-- LCAT was isolated from human plasma by a combination of ultracentrifugation, affinity chromatography on blue Sepharose, ion exchange chromatography, and hydroxyapatite chromatography as described (38). Chicken LCAT was isolated from 200 ml of pooled plasma essentially as described (39) with the following modifications. After ultracentrifugation at a buoyant density of 1.21 g/ml, the clear middle fractions were recovered from the tubes, dialyzed against 0.5 M NaCl, applied to a phenyl-Sepharose column (2.6 × 12 cm) equilibrated with the same buffer, and eluted with deionized water. LCAT activity was determined by incubating aliquots of the eluted fractions with artificial substrate complexes containing human apoAI-egg yolk lecithin-14C-cholesterol. Fractions containing LCAT activity were pooled, and purification of the enzyme was continued by DEAE-Sephacel and hydroxyapatite chromatography as described for human LCAT (38).
Apolipoprotein Cofactor Function for Human and Chicken
LCAT--
Apolipoprotein-phospholipid (egg yolk lecithin or
L--phosphatidylcholine-
-palmitoyl-
-oleoyl)-14C-cholesterol
complexes as substrates for LCAT were prepared by the cholate dialysis
procedure (40) at a molar ratio of phospholipid/apoprotein of 150:1.
The assays were performed by incubating the substrate complexes with
purified enzyme as described (38). At various time points the amount of
cholesteryl ester formed was determined in aliquots of the incubation
mixture, and the formation of cholesteryl esters was found to be linear
for at least 2 h. As human apolipoprotein AI serves as a cofactor
for chicken LCAT as well (39), this apoprotein, complexed to egg yolk
lecithin, was used as an internal standard. The reactivity of each set
of substrates with a given LCAT preparation was expressed relative to
the reactivity with human apoAI-egg yolk lecithin complexes (100%).
All determinations were performed in duplicate, and zero time blanks
were subtracted.
cDNA Preparation and PCR Analysis and cDNA Cloning-- Total RNA was prepared by the Trisolve method (Biotecx), and poly(A)+ RNA was prepared by passing 1 mg of total RNA twice over an oligo(dT) column. First-strand cDNA was prepared by mixing 3 µg of poly(A)+ RNA with 0.2 nmol of a random hexamer (Boehringer Mannheim) in a total volume of 10 µl and heating for 10 min at 75 °C. After quick chilling, 0.5 Mmol each of dNTPs and 200 units of SuperscriptTM II (Moloney murine leukemia virus RNase H-reverse transcriptase from Life Technologies, Inc.) were added, and DNA synthesis was allowed in 25 mm Tris-HCl, 37.5 mM KCl, 1.5 mM MgCl2, pH 8.3, in a total volume of 25 µl for 2 h at 37 °C. The reaction was stopped by heating to 95 °C for 5 min. PCR amplification was carried out in 100 µl final volume of the following reaction mixture: 2 µl of the cDNA solution, 500 pmol of each degenerated primer (see below), 200 µmol each of the dideoxynucleotides (Amersham Pharmacia Biotech), 10 mm Tris-HCl (pH 9.0), 50 mM KCl, 0.1% Triton X-100, 2.5 mM MgCl2, and 5 units of Taq polymerase (Promega). The reaction conditions were as follows: 1 min at 94 °C, 1 min at 60 °C, 1 min at 72 °C, 30 cycles in a Perkin-Elmer 480 DNA Thermal Cycler. PCR products were subjected to electrophoresis on a 1.5% agarose gel (SeaKem GTGTM, FMC Bioproducts) and purified using a Qiaex II gel extraction kit (Qiagen), subcloned into the pGEM-TTM vector (Promega) and transformed into Epurian Coli XL1-BlueTM Subcloning-Grade Competent Cells (Stratagene). Plasmid DNA samples were sequenced using [35S]dATP (NEN Life Science Products), T7, and SP6 primers and a Sequenase Version 2.0 kit (U. S. Biochemical Corp.).
For cDNA cloning, we screened a chicken liverNorthern Blot Analysis--
Total RNAs (15 µg each) from
different homogenized organs (intestinal epithelium was scraped off the
submucosal layers with a scalpel before isolation of RNA) were
denatured in 1 M deionized glyoxal, 48% dimethyl
sulfoxide, and 10 mM sodium phosphate buffer, pH 6.8, for
1 h at 50 °C and separated on a 1.2% agarose gel in 10 mM sodium phosphate buffer, pH 6.8. After transfer to
Hybond N membrane (Amersham Pharmacia Biotech), RNA was immobilized by UV cross-linking and filters were hybridized with a specific
32P-labeled 190-bp PCR fragment (see under "Results")
in 1% BSA, 7% SDS, 0.5 M sodium phosphate buffer, 1 mM EDTA, pH 6.8, for 15 h at 65 °C. After washing
at 65 °C, autoradiography was carried out at 75 °C overnight.
Before rehybridization with a labeled 1300-bp cDNA fragment of rat
glyceraldehyde-3-phosphate dehydrogenase for control, the blots were
stripped by incubating the membranes three times (10 min each) in 0.1×
SSC, 0.1% SDS at 95 °C. Autoradiograms were scanned using a laser
densitometer (ImageQuant Densitometer, Molecular Dynamics).
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RESULTS |
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Purification and Characterization of a Novel Chicken Serum Protein-- Preparation by SDS-polyacrylamide gel electrophoresis of the proteins present in the d < 1.063 g/ml lipoprotein fraction resulted in the isolation of a hitherto unknown apolipoprotein. The relative mobility of this protein on SDS-polyacrylamide gels, corresponding to an apparent Mr of 38,000, did not change whether or not the reducing agent dithiothreitol was added (Fig. 1). By microsequencing of the 38-kDa protein, we determined an amino-terminal sequence of Asp-Val-Ser-Pro-Asp-Gln-Val-Ala-Thr-Val-Leu-Trp-Arg-Tyr-Phe and partial sequences of two tryptic peptides, Leu-Val-Pro-Phe-Ala-Thr-Glu-Leu-Gln-Ala-Gln-Leu-Val-Gln-Asp-Ser-Gln-Arg-Leu (peptide I), and Leu-Gln-Asp-Asn-Ala-Asp-Ser-Ile-Gln-Ala-Ser-Leu-Gly-Pro-Tyr-Ala-Glu-Arg (peptide II), respectively. All three of these sequences were highly homologous to apoAIV of human (22) and monkey (25, 26) and to a lesser degree to apoAIV of mouse and rat. Based on this information, we designed a pair of degenerated primers, 5'-CCYGAYCARGTSGCHACHGT-3' (A) and 5'-YTCVGTRGCRAADGGVAC-3' (B) (IUPAC ambiguity code) for PCR amplification of cDNA. With this primer pair, a 190-bp PCR product was obtained by amplification of chicken liver cDNA. Sequencing of the PCR fragment again revealed high nucleotide sequence homology to that of mammalian apoAIVs. Furthermore, the 190-bp fragment encoded an open reading frame which included both peptide sequences used to design the primer pair and overall was highly homologous to known apoAIV sequences. Thus, the PCR fragment most likely represented a newly found avian homologue of apoAIV, prompting us to clone the corresponding full-length cDNA.
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Reactivity of Chicken apoAIV with Chicken and Human
LCAT--
Incubation of purified LCAT with substrate complexes
containing either apoAI-egg yolk lecithin (100% control; Table
I) or containing apoAIVs, with egg yolk
lecithin or
L--phosphatidylcholine-
-palmitoyl-
-oleoyl, was
used to determine the cofactor function of chicken apoAIV. As shown in
Table I, chicken apoAIV activated both chicken and human LCAT; however,
with any combination of substrate and source of LCAT, chicken apoAIV
was less potent than human apoAIV. Chicken LCAT was somewhat more
active with chicken apoAIV than with the human protein regardless of
substrate phospholipid. Finally,
L-
-phosphatidylcholine-
-palmitoyl-
-oleoyl was the
better substrate for both enzymes, but only it and not egg yolk
lecithin enhanced the activation by human apoAIV of human LCAT beyond
that of the avian enzyme.
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Sites of Chicken apoAIV Expression-- Northern blot analysis of RNA from tissues of laying hens and roosters revealed a single 1.2-kilobase transcript in liver and intestine (Fig. 5). ApoAIV mRNA could not be detected in brain, heart, lung, spleen, adrenal, kidney, ovary, or testis (data not shown). Control hybridization was performed with a rat glyceraldehyde-3-phosphate dehydrogenase probe hybridizing to a 1284-nucleotide chicken mRNA (45). The chicken apoAIV mRNA is significantly smaller than the 1.7-1.8-kilobase apoAIV transcripts reported for rats (46) and humans (22, 47).
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Plasma Chicken apoAIV Protein-- The antibody raised against the purified 38-kDa protein reacted with a single protein in unfractionated chicken plasma, allowing us to determine the isoelectric point (pI) by immunoblotting following isoelectric focusing of total plasma. The migration pattern of chicken apoAIV isoforms resembled that of human apoAIV in that there were one major band (pI, 4.65) and two minor more acidic bands (Fig. 6). The measured pI agrees well with that calculated for the mature protein predicted from the cDNA (pI, 4.54), indicating that at 6 M urea the protein exposes all critical charged residues. The results shown in Fig. 6 also confirm that chicken apoAIV is considerably more acidic than its human counterpart (pI, 4.97) (50). Because potential N-glycosylation sites are absent, the two minor bands may arise either by O-glycosylation or by carbamoylation, known to occur in human apoAI (51).
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DISCUSSION |
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Here we describe the identification and molecular cloning of a hitherto unknown chicken protein. We believe that the purified 38-kDa serum protein and the product specified by the isolated cDNA for the first avian homologue of mammalian apoAIV are identical for several reasons: (i) the amino acid sequences at the amino terminus as well as of two tryptic peptides, obtained by microsequencing of the purified 38-kDa protein, are identical to those deduced from corresponding regions of the cloned cDNA; (ii) the sequence of a PCR fragment obtained with primers designed according to the protein sequence determined by microsequencing was identical to that in the cDNA; and (iii) the calculated size of the protein predicted from the apoAIV cDNA (38,975 Da) and the apparent molecular mass determined by SDS-polyacrylamide gel electrophoresis are in excellent agreement. This further supports the notion that the protein does not seem to be significantly glycosylated. Although human apoAIV was reported to contain 6% carbohydrate by weight (52), no potential N-glycosylation sites are identifiable in the sequence. Furthermore, according to our previous results (53) the human isoform apoAIV-1 is also unlikely to be a glycoprotein. Chicken apoAIV is the smallest homologue described to date; the mature plasma form consists of 347 amino acids as compared with 371 for rats (23), 478, 375 for mice (24), 376 for humans (22), 397 for baboons (25), and 409 for cynomolgi monkeys (26). On the other hand, chicken apoAIV possesses a 19-residue signal peptide and, like mammalian apoAIV, lacks a propeptide (46). With the exception of one strain of mice (SWR/J) (24, 54), which also has a 19-residue apoAIV prepeptide, 20-residue signal peptides are found in the mammmalian proteins. The mature chicken apoAIV has the highest degree of identity with human (57%) and nonhuman primate sequences (51%), whereas the identities with apoAIV of mice and rats are only 39 and 43%, respectively. These differences in sequence identities between avian and primate apoAIV on one hand and the rodent homologue on the other hand might argue for chicken apoAIV being a partially evolved prototype of a new apoprotein, i.e. mammalian apoAIV. Further analyses of homologous genes in a wide variety of species will be necessary to strengthen this view.
Although less potent than human apoAIV, chicken apoAIV is a significant
activator of LCAT isolated from chicken and human plasma. However,
based on the more pronounced hydrophobicity and relative higher
affinity for lipids in comparison to the human protein, more potent
LCAT activation might be expected from chicken apoAIV. In this respect,
Finer-Moore plots revealed that chicken apoAIV displays much better
defined repeated -helical structure than human apoAIV (data not
shown). However, according to De Loof et al. (55),
amphiphilic lipid binding helices in apolipoproteins can be separated
into two types, helices whose hydrophobicity profile has a maximum at
100° and those whose hydrophobicity periodicity shows a second
maximum at about 160°. Chicken apoAIV has a lower mean moment at
165° than human apoAIV or apoAI (data not shown). Because these
latter helices play an important role in LCAT activation (55), less
effective LCAT activation by chicken apoAIV would be predicted, which
is in agreement with our finding (Table I).
Another interesting feature of apoAIVs relates to their highly variable extreme C-terminal regions which contain imperfect repeats specified by the consensus sequence, E-Q-A/V-Q. For instance, in nonhuman primates this region resembles a polyglutamine tail (25, 26). In the chicken, the protein terminates with a single such peptide motif, E-Q-A-E-S. In various strains of mice, insertions or deletions of 12 nucleotides coding for these repeats are responsible for polymorphic variation unrelated to their phylogenetic descent (54). Also, a human insertion/deletion polymorphism has been identified at this site (56, 57). The polymorphisms at the apoAIV locus in baboons and cynomolgi monkeys result in carboxyl-terminal extensions of up to 9 and 12 imperfect E-Q-X-Q repeats, respectively (25, 26). Similar extensions, consisting of -CAG- (Glu) repeats resembling polyglutamine domains, might have additional pathophysiological significance. For instance, expansions of CAG repeats located within the coding regions of genes have been implicated in the pathogenesis of neurological disorders such as Huntington's disease (58, 59); however, the exact mechanism underlying pathogenicity is not known.
Similarly, the physiological significance, if any, caused by the
different length of E-Q-X-Q extensions has not yet become obvious.
Modeling of truncated versions of mammalian apoAIVs lacking the
C-terminal repeated sequences does not reveal significantly altered
overall hydrophobic properties. The pronounced hydrophobicity of
chicken apoAIV, resulting from more hydrophobic and smaller hydrophilic
domains along the entire protein, predicts that chicken apoAIV should
have a higher lipid affinity. This may be the reason for the presence
of apoAIV-containing particles floating in the d < 1.063 g/ml
density fraction after ultracentrifugation (Fig. 1); however, in the
chicken, apoAIV does not seem to be associated with classical VLDL or
LDL particles, as crossed immunoelectrophoresis revealed all detectable
apoAIV in fractions other than those corresponding to LDL or VLDL (Fig.
7). Furthermore, upon gel filtration of chicken plasma, apoAIV elutes
prior to and in the descending part of the HDL fraction, respectively.
When fractions containing both apoAI and apoAIV (Fig. 8) were
precipitated with antibodies to apoAI or to apoAIV, only trace amounts
of apoAIV or apoAI, respectively, were recovered. Taken together, these
data indicate that the majority of lipid-associated chicken apoAIV,
unlike the human counterpart, is not associated with apoAI-containing
lipoproteins. Finally, the electrophoretic migration of chicken
apoAIV-containing lipoprotein particles suggests that they are
distinct from pre--migrating apoAIV-containing particles observed in
humans (60). This difference may in part be due to variation in surface
charge arising from the presence of acidic lipids in the surface of the
particle and from the conformational status of the apoprotein (61).
Further experiments to biochemically characterize those lipoprotein
fraction(s) in the plasma of roosters and hens which contain apoAIV are
now underway.
The expression pattern of chicken apoAIV closely resembles that in rodents which also produce significant amounts of apoAIV in liver (48, 49). Wu and Windmueller (62), using differential labeling of liver and intestinal proteins with [3H]leucine and [13C]leucine, calculated a 41% contribution of the liver to the overall production of apoAIV in rats. The finding of pronounced expression in the gut of the chicken strengthens the notion that intestinal synthesis is a common feature of apoAIV. In this context it is of interest that unlike mammals, birds are thought to secrete intestinally derived lipoproteins directly into the portal vein (16). With the development of apoB editing in mammals, the structure and function of apoAIV might have undergone distinct evolutionary change. A hypothesis that can be tested is that chicken apoAIV could be involved in the formation and secretion of as yet unidentified triglyceride-rich lipoproteins by enterocytes.
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ACKNOWLEDGEMENTS |
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We thank Drs. H. Bujo, Ken A. Lindstedt, and S. Mörwald for helpful suggestions and Dr. R. Hackler for support in pI determinations. The skillful technical assistance of Martin Blaschke, Sabine Motzny, Michael Wittmann, and Romana Kukina is gratefully acknowledged.
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FOOTNOTES |
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* This work was supported by Grants FWF P-11692 (to J. N.) and P-11694 (to W. J. S.) from the Austrian Science Foundation, Grant H-00095/95 from the Vienna "Hochschuljubiläumsstiftung," Grants DFG Ste 381/4-2 and 5-2 from the German Research Council, and Grant NIHLB-HL30897 from the National Institutes of Health (to R. B. W.).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
The nucleotide sequence(s) reported in this paper has been submitted to the GenBankTM/EMBL Data Bank with accession number(s) Y16534.
§ Recipient of a Heisenberg-Stipendium from the German Research Council (Deutsche Forschungsgemeinschaft). Current address: Zentrum Innere Medizin, University of Marburg, Baldingerstrasse D-35043 Marburg, Germany.
Current address: Merck-Frosst Canada, Inc., Pointe Claire,
Quebec H3B 4P8, Canada.
To whom correspondence should be addressed: Dept. of Molecular
Genetics, University and Biocenter Vienna, Dr. Bohr Gasse 9/2, A-1030
Vienna, Austria. Tel.: 43-1-79515-2113; Fax: 43-1-79515-2013; E-mail:
wjs{at}mol.univie.ac.at.
1 The abbreviations used are: apo, apolipoprotein; VLDL, very low density lipoprotein; LDL, low density lipoprotein; HDL, high density lipoprotein; LCAT, lecithin:cholesterol acyltransferase (EC 2.3.1.43); PCR, polymerase chain reaction; bp, base pair(s).
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REFERENCES |
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