©1995 by The American Society for Biochemistry and Molecular Biology, Inc.
Site-specific Mutagenesis Demonstrates That Cysteine 4326 of Apolipoprotein B Is Required for Covalent Linkage with Apolipoprotein(a) in Vivo(*)

(Received for publication, July 20, 1995)

Matthew J. Callow (§) Edward M. Rubin (¶)

From the Human Genome Center, Lawrence Berkeley Laboratory, University of California, Berkeley, California 94720

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES

ABSTRACT

In the formation of the lipoprotein(a) (Lp(a)) particle, apolipoprotein(a) (apo(a)) and apolipoprotein B (apoB) are covalently linked via a disulfide bond in both humans and human-apo(a)/apoB transgenic mice. Studies based upon fluorescent labeling of free cysteine residues have suggested that cysteine 3734 of the 4 carboxyl-terminal cysteines of apoB (Cys-3734, Cys-3890, Cys-4190, and Cys-4326) is the most likely candidate to form a disulfide bond with apo(a). However, other recent studies using truncated apoB molecules suggest that Cys-4326, the terminal cysteine of apoB, may be implicated in the binding to apo(a). In order to definitively show which of apoB's carboxyl-terminal cysteines is essential in interacting with apo(a) we have used RecA-assisted restriction enzyme digestion coupled with site-specific mutagenesis to convert Cys-3734 and Cys-4326 to serine within separate 90-kilobase pair apoB P1 phagemid clones. Transgenic mice containing the normal or mutated apoB transgenes were created, and the covalent association of mutated apoB with apo(a) was assessed in mice transgenic for both apoB and apo(a). Analysis by ultracentrifugation and immunoblotting revealed that Cys-4326, but not Cys-3734, was essential in the formation of the covalent bond between apo(a) and apoB in vivo.


INTRODUCTION

Lipoprotein(a) (Lp(a)) (^1)is formed by the association of apolipoprotein(a) (apo(a)) with apolipoprotein B (apoB) of low density lipoprotein (LDL). Although weaker non-covalent interactions may occur between apoB and apo(a), it is the presence of a disulfide bond that binds them covalently(1, 2, 3, 4) . A single cysteine of apo(a) (Cys-4057) has been identified in forming the in vitro covalent association of apo(a) with human LDL (5, 6) . The introduction of a point mutation into the apo(a) molecule to remove Cys-4057 and replace it with either a serine or glycine was sufficient to prevent the formation of a tight association between LDL and apo(a). However, the cysteine of apoB involved in this association has not been unambiguously identified.

Several studies (7, 8, 9) have suggested that Cys-3734 or possibly Cys-4190 of apoB could potentially form a disulfide bridge with apo(a). Many of these studies were based upon the use of fluorescent probes that bind to free cysteine residues of proteins. Fluorescently labeled tryptic peptides of apoB that contain Cys-3734 were absent in the apoB of Lp(a), suggesting that this cysteine was unavailable for binding to the fluorescent probe because of an association with apo(a)(8) . Computer modeling also demonstrated that the peptide region around Cys-3734 was the most energetically favorable to associate with the amino acids surrounding Cys-4057 of apo(a)(8) . Both of these approaches, however, lacked direct experimental evidence for the involvement of Cys-3734 in the binding of apoB to apo(a).

Studies utilizing a truncated form of apoB (apoB-90) expressed in transgenic mice suggested that one of the two cysteines in the deleted terminal 10% of the molecule, Cys-4190 or -4326, could be involved in binding to apo(a)(10) . Another study, using a truncated apoB-94 peptide produced in cell culture, presented evidence not indicated by the fluorescent labeling studies and suggested that Cys-4326, the terminal cysteine of apoB, is involved in disulfide linkage with apo(a) (11) . In both of these studies, deletion of the terminal 6 or 10% of the apoB peptide could not be excluded from inhibiting an association with an alternative cysteine such as Cys-3734. This is important because it has been demonstrated that the conformation of apoB may influence the binding characteristics of apo(a) to apoB on LDL. Individuals with lecithin:cholesterol acyltransferase deficiency have been demonstrated to lack plasma Lp(a)(12) . The LDL of these individuals was found to be deficient in cholesterol, which suggested that interactions between apo(a) and apoB may be impacted upon by the composition and size of LDL mediating conformational changes in apoB. The low binding characteristics of very low density lipoprotein with apo(a) (13) may also be due to conformational changes. Truncated forms of apoB could adopt conformations inhibiting an association with apo(a) in a similar manner.

Apo(a) is not normally expressed in mice, and in human-apo(a) transgenic mice, apo(a) is not covalently linked to murine apoB(14, 15) . However, in mice that contain both transgenes for human apo(a) and apoB, Lp(a) particles, similar to that observed in humans, are present in the plasma of the double transgenic animals(16, 17) . In this study we have used transgenic mice to study the in vivo interactions of apo(a) and apoB. To determine which free cysteine of human apoB is involved in disulfide linkage to apo(a), we have employed site-directed mutagenesis to convert Cys-3734 and Cys-4326 to serines within separate apoB P1-phagemid genomic clones. The P1 clone of the human apoB gene was then used to prepare transgenic mice expressing the mutated protein. In combination with an apo(a)-expressing yeast artificial chromosome transgene(18) , the formation of Lp(a) by the mutant apoB molecules in an in vivo setting was examined.


EXPERIMENTAL PROCEDURES

Mutagenesis

ApoB P1-phagemid (DMPC-HFF #1-0261G) DNA was prepared by alkaline lysis of the bacterial cells followed by phenol extraction and ethanol precipitation of the DNA. A 1.55-kilobase pair (kbp) EcoRI fragment from apoB-P1 DNA, containing codon 3734 (19, 20) , was subcloned into an M13 vector (M13BM20, Boehringer Mannheim) and mutagenized by standard procedures (21, 22) with primer A. Primer B was used for sequencing of both the parental phage and the mutagenized phage using the Sequenase version 2.0 sequencing kit (U. S. Biochemical Corp.). For mutation of codon 4326, PCR with Pfu DNA polymerase (Stratagene) was used to amplify a 123-bp product from the P1 DNA with primers C and D. Primer C contained the mutation site and was extended to beyond a nearby HindIII site. The mega-primer produced from this PCR reaction was then used for a second round of PCR(23, 24) , extending beyond a PvuII site using primer E to generate a 331-bp product. The PCR product was digested with PvuII and HindIII to generate a 160-bp fragment, which was cloned into the HindIII and one of the two PvuII sites of pBluescript II SK+ to form the plasmid pHP. Sequencing of pHP was carried out using the SK primer (Stratagene). A 4.16-kbp ScaI-PvuII fragment of the apoB gene, contiguous with the 160-bp PvuII-HindIII fragment and containing a single HindIII site, was subcloned to a separate PvuII-digested pBluescript plasmid to form pSP. The 448-bp PvuII fragment from pHP was then subcloned into the single PvuII site of pSP to recreate a 4.1-kbp HindIII fragment suitable for replacement of the native 4.1-kbp HindIII fragment.

RARE Digestion of Plasmid DNA

RARE digestion of P1 DNA (25, 26) and the creation of the apoB-P1 containing the mutated codon 3734 was performed as described previously(27) . However, for the replacement of codon 4326, a 4.1-kbp HindIII fragment of the apoB-P1 was selected for removal by RARE digestion. AluI methylase was used to methylate HindIII sites left unprotected by two oligonucleotides targeted to the HindIII sites surrounding codon 4326. The DNA was then digested with HindIII to specifically cut those sites protected from methylation and used directly for ligation of the mutated 4.1-kbp fragment along with the chloramphenicol resistance/sacB selectable markers(27) . Plasmids containing the mutated fragment and the chloramphenicol resistance/sacB genes were selected on chloramphenicol-containing plates. A P1 plasmid was then isolated and characterized by restriction enzyme digestion. The chloramphenicol resistance/sacB genes were removed with selection on 5% sucrose(28) , leaving the mutated 4.1-kbp fragment within the apoB gene.

Production of Transgenic Mice

To prepare the DNA for microinjection, P1 phagemid DNA that had been prepared as above was gently treated with Geneclean (Bio101) and microdialyzed on 0.025-µm type VS filters (Millipore, Bedford, MA) against TE. Microinjection of FVB embryos was performed as described previously(29, 30) . Transgenic founder animals were screened for expression of the transgene by immuno-dot blot using a biotinylated human apoB specific monoclonal antibody (provided by E. Krul, Washington University, St. Louis, MO). Human apoB was assayed using enzyme-linked immunosorbent assay(16) . The Ser-3734 apoB and Ser-4326 apoB transgenic founder animals were bred with apo(a) yeast artificial chromosome hemizygous transgenic mice (18) to obtain mice expressing both apo(a) and apoB proteins.

Centrifugation and Immunoblotting

EDTA plasma was collected from the tail vein of non-fasted mice. The total lipoprotein fraction was prepared by adjusting 25 µl of plasma to a volume of 230 µl and a density of 1.21 g/ml with NaBr before centrifugation at 40,000 rpm for 18 h and at 10 °C in the type 42.2 rotor. A volume of 25 µl was removed from the tops of the tubes (d < 1.21 g/ml) and also from the bottoms (d > 1.21 g/ml). Plasma fractions of 5 µl were combined with 50 µl of 15% SDS, 6 M urea, 5% 2-mercaptoethanol, 0.2 M Tris, pH 6.8, sample buffer, boiled for 5 min, and electrophoresed on precast SDS-polyacrylamide gels (4-12% acrylamide, Novex, San Diego, CA). The proteins were transferred to nitrocellulose and immunodetected with a goat polyclonal anti-Lp(a) antibody (Biodesign, Kennebunkport, ME) for the detection of apo(a) (18) or a biotinylated human apoB specific monoclonal antibody for apoB (16) .

Oligonucleotides

The oligonucleotides (5`-3`) used were: A, GTCAAGTTTGCTCGATGGAACC; B, CAAATGATGAAGTTCTCAGC; C, AAAGAAAACCTAAGCCTTAATCTTCAT; D, CAAAATATTCTTCACGAAGGGC; E, AGCCCAAGAGGTATTTAAAGCC; F, GGCTGATAAATTCATTATTCCTGG; G, CTTCAGGGAATTTTACCTCGG.


RESULTS AND DISCUSSION

Vector Construction and Creation of Transgenic Mice

The P1 phagemid genomic clone described here has previously been used in the production of apoB transgenic mice and contained 75 kbp of human genomic sequence including the 43-kbp apoB gene with extensive 5` and 3` sequences(16) . Manipulation of the intact phagemid to allow mutagenesis was not feasible due to the lack of conveniently located, infrequent, restriction enzyme sites. To achieve selective removal and reinsertion of small fragments of DNA from the phagemid we utilized RARE digestion. We have previously reported the use of this technique to remove a 1.55-kbp DNA fragment from the apoB-P1 and reinsertion of the mutated fragment(27) . This technique involves protecting specific restriction enzyme sites by forming a triplex DNA complex over the region with a complementary oligonucleotide. Unprotected sites are methylated, followed by dissociation of the complex and inactivation of the methylase. The protected sites can then be specifically cut with the restriction enzyme. We have expanded the use of this technique to include the chloramphenicol resistance/sacB genes as positive and negative selection markers for replacement of the wild-type sequence with the mutated sequence.

Mutagenesis of the 1.55-kbp EcoRI fragment containing codon 3734 was carried out in M13, whereas PCR mutagenesis was used for alteration of codon 4326 followed by subcloning of the product to a plasmid for sequencing. The DNA sequences surrounding the mutated sites were determined and compared with that of the published sequence. For both codon 3734 and codon 4326, a single base change was introduced into the apoB sequence converting a thymidine to an adenosine and thus effectively converting a cysteine to a serine in the translated product. No other changes to the apoB gene sequence were detected.

Four Ser-3734 apoB and five Ser-4326 apoB founder mice expressing human apoB as determined by immuno-dot blot assay were created, but only two founders of each mutation type were bred with apo(a) transgenic mice to generate transgenic lines. PCR was used to confirm the presence of the mutated DNA sequences in the genomes of the transgenic mice (Fig. 1). Introduction of the point mutations and conversion of thymidine to adenosine within the apoB DNA sequence introduces TaqI and DdeI restriction enzyme sites for codon 3734 and codon 4326, respectively. No product was obtained from non-transgenic mouse genomic DNA in each case, demonstrating that both primer sets were specific for human DNA. Genomic DNA from apoB transgenic mice gave a 203-bp PCR product from the codon 3734 region and a 331-bp product from the codon 4326 region. However, the product from the Ser-3734 apoB genomic DNA was able to produce the TaqI digestion pattern confirming the presence of the mutated apoB in these mice. Similarly, the PCR product for the codon 4326 region was digested with DdeI in Ser-4326 apoB mice.


Figure 1: PCR amplification of transgenic DNA. Genomic DNA and P1 DNA were amplified by PCR using Taq DNA polymerase. Primers F and G were used to amplify a 203-bp region containing codon 3734. Mutation of codon 3734 introduces a TaqI restriction site. Primers D and E were used to amplify a 331-bp region containing codon 4326. Mutation of this codon introduces a DdeI site. DNA was electrophoresed on 2% Nu-sieve-agarose (FMC) after digesting with TaqI or DdeI. Lane 1, markers; lane 2, non-Tg; lane 3, wt B Tg; lane 4, wt B Tg RE-digested; lane 5, mutated P1; lane 6, mutated P1 RE-digested; lane 7, mutated Tg; lane 8, mutated Tg RE-digested.



The size of human apoB found in plasma from the various transgenic strains was compared by immunoblot analysis (Fig. 2). The human protein found in both of the mutated apoB transgenic lines was identical in size to the human apoB from wild-type (wt) apoB transgenic mouse plasma. Both apoB-48 and apoB-100 bands were present demonstrating normal mRNA editing and synthesis of the peptide.


Figure 2: Human apoB immunoblot of the lipoprotein fraction from transgenic mice. The d < 1.21 g/ml lipoprotein fraction of plasma from mice was collected, electrophoresed, and immunoblotted under reducing conditions as described under ``Experimental Procedures.'' The equivalent of 1 µl of lipoprotein fraction was loaded into each lane, except for wt B in which case 2 µl were loaded.



Association of Human ApoB with Apo(a)

Previous studies have demonstrated that the covalent association of apo(a) with apoB can withstand centrifugation during the separation of lipoproteins from other plasma proteins. Ultracentrifugation was used in this study to demonstrate the presence or absence of apo(a) within the lipoprotein fraction of plasma. Apo(a) was found associated with lipoproteins in plasma from wt apoB/apo(a) transgenic mice and Ser-3734 apoB/apo(a) transgenic mice. However, in apo(a) and Ser-4326 apoB/apo(a) mice, apo(a) was found only within the lipoprotein-free fraction of plasma and was not associated with lipoproteins (Fig. 3). These results clearly demonstrate that the single amino acid conversion of Cys-4326 to serine, in itself, was sufficient to prevent formation of Lp(a). In contrast, conversion of Cys-3734 to serine failed to prevent an association of apo(a) with apoB.


Figure 3: Human apo(a) immunoblot of plasma fractions from transgenic mice. The d < 1.21 g/ml, lipoprotein-containing (L) or d > 1.21 g/ml, lipoprotein-free (F) fractions of transgenic mouse plasma were collected by ultracentrifugation. The equivalent of 1 µl (for wt B/(a) and Ser-3734 B/(a)) or 2 µl (for (a) and Ser-4326 B/(a)) of plasma fractions was electrophoresed under reducing conditions and immunoblotted using an anti-apo(a) antibody as described under ``Experimental Procedures.''



A significant proportion of apo(a) was found in the lipoprotein-free fraction of plasma from the wt apoB/apo(a) mice (Fig. 3). This was a consistent feature of this line and was attributed to the low concentration of human apoB in these animals compared with higher expressors. (^2)To ensure that adequate levels of apoB were available for maximum binding of apo(a), the plasma concentration of human apoB was assessed for those mice presented in Fig. 2and Fig. 3using a human apoB specific enzyme-linked immunosorbent assay. The wt apoB line contained 14 mg/dl compared with the Ser-3734 apoB and Ser-4326 apoB lines that contained 59 and 20 mg/dl, respectively. These data demonstrate that the lack of association between Ser-4326 apoB and apo(a) could not be attributed to low levels of circulating apoB in these mice.

ApoB contains 25 cysteine residues with at least 16 of these committed to intramolecular disulfide bonds. This leaves 9 potential cysteine residues available for intermolecular interactions(9) . In the present study we chose to replace Cys-3734 and Cys-4326 of human apoB with serine, based upon previous reports suggesting that at least one of these cysteines is a likely candidate for the single disulfide linkage to apo(a). Our results clearly demonstrate that only Cys-4326 is required for the covalent interaction of human apo(a) and human apoB. This is in contrast to a recent study suggesting that 2 molecules of apo(a) are associated per single apoB molecule within the Lp(a) structure(31) . The complete lack of detectable apo(a) within the lipoprotein fraction of the Ser-4326 apoB mice strongly implies that only one molecule of apo(a) is associated covalently with each apoB molecule. Furthermore, the possibility that Cys-3734 is responsible for binding one of the apo(a) molecules also seems unlikely. Non-reduced Lp(a) from Ser-3734 apoB/apo(a) mice demonstrated identical migration compared with Lp(a) from wt apoB/apo(a) mice on SDS-polyacrylamide gels (data not shown), suggesting an equal number of apo(a) molecules bound in each case. However, it is not inconceivable that Lp(a) could require the binding of an initial apo(a) molecule at Cys-4326 to expose alternative binding sites for a second apo(a) molecule.

The large size of the apoB gene has made it difficult to study structural features of this protein. However, with the advent of new technologies such as RARE digestion of DNA, site-specific mutagenesis and manipulation of large genomic clones can be achieved. Here, we have used this approach to demonstrate that Cys-4326 of human apoB, and not Cys-3734, is required for the covalent, disulfide linkage between human apoB and apo(a) in vivo. Furthermore, the transgenic mice developed in these studies may prove useful for the analysis of early events leading to the formation of the disulfide bond. Inhibition of this process could provide new approaches to reducing plasma levels of Lp(a)


FOOTNOTES

*
This work was supported in part by National Heart, Lung, and Blood Institute Grant NIH HL-18574 and by a grant funded by the National Dairy Promotion and Research Board and administered in cooperation with the National Dairy Council. Research was conducted at the Lawrence Berkeley Laboratory (Department of Energy Contract DE-AC0376SF00098), University of California, Berkeley. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore by hereby marked ``advertisement'' in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§
Supported by the American Heart Association, California Affiliate.

American Heart Association Established Investigator. To whom correspondence should be addressed: Human Genome Center, M/S 74-157, Lawrence Berkeley Laboratory, University of California, Berkeley, CA 94720. Tel.: 510-486-5072; Fax: 510-486-6746.

(^1)
The abbreviations used are: Lp(a), lipoprotein(a); apo(a), apolipoprotein(a); apoB, apolipoprotein B; LDL, low density lipoprotein; kbp, kilobase pair(s); bp, base pair(s); PCR, polymerase chain reaction; RARE, RecA-assisted restriction endonuclease; wt, wild-type; Tg, transgenic mouse; RE, restriction enzyme.

(^2)
M. J. Callow and E. M. Rubin, unpublished observation.


ACKNOWLEDGEMENTS

We thank Mary Stevens, Jun-Li Zhang, Pat Blanche, and Phil Cooper for excellent technical assistance.


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©1995 by The American Society for Biochemistry and Molecular Biology, Inc.