Rat McA-RH7777 cells efficiently assemble rat apolipoprotein B-48 or larger fragments into VLDL but not human apolipoprotein B of any size.

Studies of truncated apoB peptides in human subjects with familial hypobetalipoproteinemia, as well as of puromycin-generated spectra of nascent apoB peptides in rat and hamster liver, suggest that a minimum size is required for N-terminal fragments of apoB to be efficiently assembled into full-sized VLDL. We report here results of experiments undertaken to examine this phenomenon in greater detail by expressing individual carboxyl-truncated human apoB constructs in McArdle cells. Thus, apoB-29, -32, -37, -42, -47, -53, -70 and full length apoB-100 were transiently expressed in rat McA-RH7777 hepatoma cells, or human apoB-31 and apoB-53 were stably expressed in the same cells, and the secreted VLDL particles were characterized by kinetic gradient ultracentrifugal flotation. Calibration with rat plasma VLDL subfractions showed that about 90 and 50%, respectively, of lipoprotein particles containing endogenous rat B-100 and B-48 floated between fractions 2;-8 of the 11-fraction gradient. This corresponds to the normal VLDL diameter range of about 47 to 28 nm, with the remaining half of rat B-48 recovered as HDL particles in the 1.1 g/ml range. In contrast, regardless of their size, only 2;-5% of any of the truncated human apoB peptides expressed in these cells was recovered in the VLDL region of the gradient. The remaining 95+% of the lipoproteins were found as high density particles; as previously found in other systems the densities of the latter were inversely related to their peptide chain-length. Furthermore, transiently expressed full-length human apoB-100 was inefficiently secreted as VLDL by these cells, with the remainder appearing as LDL-sized particles. Thus, although we showed that McA-RH7777 cells secreted endogenous rat apoB as normal-sized VLDL, we found them unsuitable for our original purpose of using human apoB fragments to further define effects of apoB size on VLDL assembly. These cells appeared unable to efficiently use any size of human apoB for that process. Pulse-labeled untransfected McA-RH7777 cells chased in the presence of puromycin did, however, show a sharp decline in VLDL assembly efficiency for endogenous nascent rat apoB peptides shorter than B-48, similar to that originally found in normal rat liver.

Studying low-density lipoprotein-monoclonal antibody complexes using dynamic laser light scattering and analytical ultracentrifugation.

Monoclonal antibody complexes have proven very useful in the study of low-density lipoproteins (LDLs). Thus, complexes composed of two different monoclonal antibodies, selected from a panel of 11 different antibodies, and LDL have been employed to map apolipoprotein B (apoB) on the surface of the LDL. In this way, apoB was found to surround the LDL as a ribbon with a bow [Chatterton, J. E., et al. (1995) J. Lipid Res. 36, 2027-2037]. Moreover, monoclonal MB19, which recognizes a polymorphic site, has been employed to quantitate the two different allelic forms of apoB found on LDL in human sera, and in this way, we assessed the effect of most of the known common polymorphisms of this protein as well as detected the depletion of the normal allele product in two forms of familial defective apoB-100 [Chatterton, J. E., et al. (1995) Biochemistry 34, 9571-9580; Pullinger, C. R., et al. (1995) J. Clin. Invest. 95, 1225-1234]. In this paper, these studies have been extended by examining by dynamic light scattering and sedimentation velocity techniques the complexes formed with only one antibody, and complexes formed using two antibodies. Our data show that the largest complex formed with a single monoclonal antibody was that of an LDL dimer; no larger, nonspecific complexes were present. With two antibodies, a variety of complexes were seen. Thus, monoclonal antibodies MB47 and 4G3, which bound about 55 degrees apart, formed a very stable dimer. Monoclonal antibodies MB47 and 2D8, which bound 136 degrees apart, formed a very stable tetramer, with four LDLs held together in probably a circular structure with four monoclonal antibodies. Finally, monoclonal antibodies 2D8 and 1D1, which bound 86 degrees apart, probably formed a less stable LDL tetramer, held together by three to four monoclonal antibodies. A rationale for these structures is discussed, as well as the biological relevance of these complexes.

One active C1r subunit is sufficient for the activity of the complement C1 complex: stabilization of C1r in the zymogen form by point mutations.

The binding of C1 (the first component of complement) to immune complexes leads to the autoactivation of C1r through the cleavage of the Arg463-Ile464 bond in the catalytic domain. Spontaneous activation of C1r (and C1) also occurs in the fluid phase, preventing the characterization of the zymogen form of C1r. To overcome this difficulty, the zymogen form of human C1r was stabilized by mutating the Arg in the Arg463-Ile464 bond to Gln. This mutant was designated as mutant QI. Recombinant C1r (wild type (wt) or mutant) was expressed in insect cells using serum-free medium in functionally pure form; therefore, the cell culture supernatant was suitable to reconstruct C1 for the hemolytic assay. Mutant QI was a stable, nonactivable zymogen and showed no hemolytic activity in reconstituted C1. However, this stable zymogen C1r mutant could form an active mixed dimer with the wt C1r, indicating that one active C1r subunit in the C1 complex is sufficient for the full activity of the entire complex. Our experiments also showed that the exchange of C1r monomers between the C1r dimers is completed in less than 16 h even at pH 7 and 4 degrees C. Two other mutants were also constructed by changing Arg463 to Lys, or Ile464 to Phe, and were designated as mutants KI and RF, respectively. Although these substitutions did increase the stability of the proenzyme in the cell culture supernatant, the mutant proteins retained their ability to autoactivate, and both had a wt-like hemolytic activity.

The apolipoprotein B R3531C mutation. Characteristics of 24 subjects from 9 kindreds.

Familial ligand-defective apolipoprotein B (apoB) is a group of disorders caused by mutations in the apoB gene. In this report the R3531C mutation is characterized further using a monoclonal antibody MB19/dynamic laser light scattering technique to measure ratios of Cys(3531) to normal low density lipoprotein (LDL) particles. All six subjects studied showed a preferential accumulation of particles carrying the defective apoB allotype. We determined binding properties of LDL from R3531C heterozygotes by measurement of high-affinity binding to LDL receptors on fibroblasts and its ability promote growth of U937 cells. LDL from R3531C heterozygotes, compared to normal LDL, had 49.3% of the binding affinity and was 74% as effective in a U937 cell proliferation assay. To identify new probands, we screened 2570 subjects for the R3531C mutation. Nine probands were found with 15 affected relatives. Of the seven haplotypes we uncovered, two were novel, while five were identical to one initially reported as associated with Cys3531. Three silent mutations were detected also: T3540T, N3542N and T3552T. Analysis of lipid profiles of R3531C families showed, as with the R3500Q mutation, variable expression of the phenotype, modulated by environmental and other genetic factors. Both mutations tend to produce lower plasma levels of LDL in affected subjects than do defects of the LDL receptor (familial hypercholesterolemia, FH). This study shows that the Cys(3531) LDL particles are not only defective at binding to the LDL receptor, as determined by two separate methods, but that in all cases they accumulate preferentially compared to the normal allotype.-Pullinger, C. R., D. Gaffney, M. M. Gutierrez, M. J. Malloy, V. N. Schumaker, C. J. Packard, and J. P. Kane. Apolipoprotein B R3531C mutation: characteristics of 24 subjects from 9 kindreds. .

A single copy of apolipoprotein B-48 is present on the human chylomicron remnant.

Individuals homozygous for the e2 allele encoding apolipoprotein E exhibit a remnant removal defect and accumulate substantial levels of intestinally derived particles containing apolipoprotein B-48 (apoB-48). Such lipoproteins were isolated from the plasma of E2/E2 individuals, and further purified by affinity chromatography using a polyclonal antibody specific for selective binding and removal of apoB-100-containing lipoproteins. The unbound lipoproteins, termed chylomicron remnants, were particles with average hydrated diameters of 31.2 nm as determined by dynamic light scattering. They contained apoB-48 and ApoE as their only protein components. The number of apoB-48 molecules on each lipoprotein was assessed by counting the number of antibody molecules bound to the surface of the chylomicron remnants, using either a monoclonal antibody specific for a single epitope on apoB-48 or a mixture of two such monoclonal antibodies specific for widely separated epitopes. The results of this analysis seem unambiguous: no more than one apoB-48 resides on the chylomicron remnant. Because apoB appears to be unable to transfer among lipoprotein particles, it may be inferred that nascent chylomicrons also contain a single copy of apoB-48.

Probing the structure of C1 with an anti-C1s monoclonal antibody: the possible existence of two forms of C1 in solution.

Anti-human C1s monoclonal antibody H1532, a mouse gamma-1-immunoglobulin elicited by a C1r2C1s2 immunogen, appeared to bind to the beta-domain of C1s by electron microscopy. In agreement with this observation, Western blotting demonstrated good binding to unreduced C1s, but no binding to the alpha or gamma-B domains. When added to solutions of the C1r2C1s2 tetramer, HI532 converted the 8.7 S tetramer into an 18 S complex, which was seen by electron microscopy to be a dimer of parallel C1s x C1r x C1r x C1s molecules cross-linked by two bivalent monoclonal antibodies. If increasing amounts of HI532 were added to C1r2C1s2 followed by addition of equivalent C1q, there was a progressive loss of hemolytic activity, which became zero when two equivalents of antibody HI532 were added. When two equivalents of HI532 were added to serum or C1 reconstituted overnight from purified subcomponents, there was an immediate loss of approximately 50% of the hemolytic activity; thereafter, activity decayed slowly and even after 24 hr, 10-30% of the activity remained. The rapid loss of only 50% of the activity would be readily explained by the existence of two conformations of C1, one of which was rapidly disassembled by antibody, and the other was resistant to disassembly. These two conformations may correspond to two previously proposed structures for the C1 complex.

The human complement C1 complex has a picomolar dissociation constant at room temperature.

Periodic sampling of serum or reconstituted C1 initially diluted 1/2000 and 1/4000 (that is, to 0.1 and 0.05 nM) into a recombinant C1s-containing solution showed a gradual decline of hemolytic activity until equilibrium was approached, consistent with a simple dissociation, reassociation equilibrium, presumably C1 <--> C1q + C1r2C1s2. The presence of excess (5 nM) recombinant C1s minimized further dissociation of the C1r2C1s2, allowing the first step to be studied independently of the dissociation of C1r2C1s2 <--> C1r2 + 2 C1s. Reassociation experiments were also performed, starting with the dissociated C1 diluted to the same concentrations and following the regain of hemolytic activity to approximately the same values, showing that the same equilibrium had been achieved from both directions. Analysis of the kinetic data yielded forward and reverse rate constants and the equilibrium constant, for which values of approximately 72 and 3 pM were estimated at 0 and 23 degrees C, respectively. The effects of temperature, ionic strength, Ca2+ ion concentration, and activation of the zymogen on the equilibrium constants were explored; extreme sensitivity to temperature, ionic strength, and activation were found. At 23 and 30 degrees C, slow activation of C1 was also evident. Highly purified, reconstituted C1 yielded approximately the same values for the kinetic and equilibrium parameters as serum C1, suggesting that the structure of the reconstituted complex was similar to or identical with that of the serum C1 complex.

Expression and characterization of a 159 amino acid, N-terminal fragment of human complement component C1s.

A 159 residue, N-terminal fragment of the human C1s complement component, C1s alpha(159), was expressed in the baculovirus, insect cell system. The protein was abundantly produced 3 days after infection, reaching levels as high as 40 microg/ml in cell culture media. It had a molecular weight of 18,100 (+/-4.9) Da by laser desorption mass spectrometry, close to the theoretical value of 18,111 Da, confirmed by sequencing. Sedimentation equilibrium and gel filtration column chromatography showed that C1s alpha(159) was a monomer in the presence of EDTA, and a dimer in the presence of Ca2+. The C1s alpha(159)2 dimer had a sedimentation coefficient of 3.1 S. When the C1s alpha(159)2 was mixed with Clq, there was little or no interaction. Likewise, unactivated C1r2 dimer had a sedimentation coefficient of 6.8 S, and when mixed with C1q little or no interaction was observed. When C1s alpha(159)2 was mixed with the 6.8 S C1r2 in Ca2+, a 7.5 S complex was formed, presumably the C1s alpha(159) x C1r x C1r x C1s alpha(159) tetramer. When C1q, which migrated at 10.1 S was mixed with C1s alpha(159)2 and C1r2 in the presence of Ca2+, a C1-like complex, but containing C1s alpha(159) instead of C1s, was formed which migrated at 14.0 S. This C1-like molecule remained unactivated unless challenged with an ovalbumin-antiovalbumin immune complex. In the presence of immune complex, the C1r became activated. This suggested that the presence of the 159 amino acid C1s alpha domain, which held the C1r to the C1q, was sufficient to permit activation by an immune complex, even though the catalytic domains of C1s were not present.

Oligomerization of a 45 kilodalton fragment of diphtheria toxin at pH 5.0 to a molecule of 20-24 subunits.

Diphtheria toxin (DT) is a 58 kDa protein, secreted by lysogenic strains of Corynebacterium diphtheriae, that causes the disease diphtheria in humans. The catalytic (C) domain of DT kills host cells by gaining entry into the cytoplasm and inhibiting protein synthesis. The translocation of the C domain across the endosomal membrane and into the cytoplasm of a host cell is mediated by the translocation (T) domain of DT. This process is triggered by acidification from pH approximately 7 to pH approximately 5 within the endosome. Here we show that crm45 (cross-reacting material of 45 kDa), a 45 kDa deletion mutant of DT which contains the C and T domains but lacks the C-terminal receptor-binding (R) domain, undergoes a transition from a monomer to a large oligomer upon acidification from pH 7.0 to pH 5.0. Dynamic light scattering analysis of crm45 at pH 5.0 results in a polydispersity value of only 8-17%, suggesting that the oligomer is uniformly sized. Using analytical ultracentrifugation, measurements of the sedimentation rate and diffusion coefficient of crm45 at pH 5.0 result in a molecular mass determination of 890 +/- 40 kDa (20 +/- 1 subunits) for the oligomer. Equilibrium sedimentation data on crm45 at pH 5.0 are best fit by a single species with a mass of 1000 +/- 50 kDa (24 +/- 1 subunits). These results reveal the pH-dependent formation of a uniformly sized, 20-24 subunit oligomer of the C and T domains of DT, in solution. Because the oligomer of crm45 forms at the pH of the acidified endosome, it could be relevant to the translocation of the C domain of DT across the endosomal membrane and into the cytoplasm of host cells. The possible relevance of this oligomer of crm45 to the membrane translocation of the C domain of DT correlates with earlier kinetic studies of DT intoxication of Vero cells, which inferred the transfer of approximately 20 C domains of DT to the cytoplasm of host cells, in a single event.

Secretion from cell culture of HDL and VLDL bearing apoB-33 with a large internal deletion.

Rat hepatoma McA-RH7777 cells synthesize and secrete two populations of apoB-containing lipoproteins: a larger, VLDL-sized population floating in the Sf 40-150 range and a smaller, LDL and HDL-sized population. Three permanently transfected cell lines of McA-RH7777 cells secreted (in addition to the endogenous lipoproteins) lipoproteins containing 1) a carboxyl-terminally truncated human apoB-53 (2377 amino acids in length); 2) a carboxyl-terminally truncated human apoB-31 (1420 amino acids in length); or 3) an internally deleted human apoB protein, apoB-18/95, containing a total of 1490 amino acid residues, equivalent in length to an apoB33. The apoB-18/95 protein contained amino acid residues 1-782 joined to 708 residues near the C-terminus of apoB (residues 36364343). All three of the apoB peptides, apoB53, apoB-31, and apoB-18/95, were present on smaller LDL-HDL-class lipoproteins, with buoyant densities in the HDL density range. The sizes of the HDL class lipoproteins agreed with prior observations that lipoprotein core circumference is directly proportional to apoB size. As HDL containing apoB-18/95 conformed to this rule, contiguous apoB amino acid sequence is not required for the rule to be obeyed. In addition, apoB-18/95, but not apoB-31, was also present on the VLDL-sized lipoproteins even in the absence of serum or oleate supplementation. As the latter two constructs encode equally sized apoB peptides, their particular amino acid sequences rather than just overall length must determine whether they can assemble into a VLDL particle.

Functional effects of domain deletions in a multidomain serine protease, C1r.

The C1r subcomponent of the first component of complement is a complex, multidomain glycoprotein containing five regulatory or binding modules in addition to the serine protease domain. To reveal the functional role of the N-terminal regulatory domains, two deletion mutants of C1r were constructed. One mutant comprises the N-terminal half of domain I joined to the second half of the highly homologous domain III, resulting in one chimeric domain in the N-terminal region, instead of domains I-III. In the second mutant most of the N-terminal portion of domain I was deleted. Both deletion mutants were expressed in the baculovirus-insect cell expression system with yields typical of wild type C1r. Both mutants maintained the ability of the wild type C1r to dimerize. The folding and secretion of the recombinant proteins was not affected by these deletions, and C1-inhibitor binding was not impaired. The stability of the zymogen was significantly decreased however, indicating that the N-terminal region of the C1r molecule contains essential elements involved in the control of activation of the serine protease module. Tetramer formation with C1s in the presence of Ca2+ was abolished by both deletions. We suggest that the first domain of C1r is essential for tetramer formation, since the deletion of domain I from C1r impairs this interaction.

Immunoelectron microscopy of low density lipoproteins yields a ribbon and bow model for the conformation of apolipoprotein B on the lipoprotein surface.

In the present study, the relative positions of 11 anti-apolipoprotein B monoclonal antibodies have been mapped onto the surface of human low density lipoproteins by electron microscopy. As the epitopes recognized by these antibodies have been previously located on the primary sequence of apoB, these data provide a map of the configuration of the protein on the surface of the LDL. The first 89% of apoB-100 may be modeled as a thick ribbon that wraps once around the LDL, completing the encirclement by about amino acid residue 4050. The thickness of the ribbon is sufficient to penetrate the monolayer, so that it makes contact with the core. There is a kink in the ribbon beginning almost halfway along its length at approximately apoB-48. The C-terminal 11% of apoB constitutes the "bow," an elongated structure of about 480 residues, beginning at 4050 and stretching back into one hemisphere and then crossing the ribbon into the other hemisphere between residues 3000 to 3500, thus bringing sequences in the C-terminal portion of apoB-100 near to the suggested binding site for the LDL receptor. The C-terminal sequences may act as a negative regulator of LDL receptor binding, in agreement with Parhofer et al, 1992. J. Clin. Invest. 89: 1931-1937, who reported the enhanced clearance from plasma of apoB-89-containing lipoproteins. It is proposed that in VLDL the bow could function to inhibit binding to the receptor; during lipolysis to form LDL, it is suggested that these C-terminal inhibitory sequences forming the bow would move sufficiently to allow interaction with the LDL-receptor.

Identification of apolipoprotein B100 polymorphisms that affect low-density lipoprotein metabolism: description of a new approach involving monoclonal antibodies and dynamic light scattering.

Rare mutations in apolipoprotein B (apoB) can cause defective binding of low-density lipoproteins (LDLs) to the LDL receptor, leading to elevated plasma cholesterol levels and premature atherosclerosis. This communication describes a novel approach to study the effects of apoB mutations on LDL metabolism. Monoclonal antibody MB19 identifies a common polymorphism in apoB, an Ile/Thr substitution at residue 71, by binding with a 60-fold higher affinity to apoB(Ile71)-containing LDL. Because each LDL contains a single apoB, a maximum of two LDLs may be bound by the bivalent monoclonal antibody. Thus, at the appropriate concentration, an equivalent amount of MB19 will promote substantial dimer formation of LDL containing the strongly binding apoB(Ile71), but little dimer formation of LDL containing the weakly binding apoB(Thr71). For LDL isolated from heterozygous individuals, the amount of dimer formed, determined by dynamic light scattering, yields an estimate of the allelic ratio of the two forms of LDL. For such individuals, not only the effect of the polymorphism recognized by MB19 but also the effects of other polymorphisms on the LDL allelic ratio can be determined. Examination of six normolipemic MB19 heterozygotes gave percent allelic ratios between 48:52 and 51:49 tight:weak-binding LDL, not significantly different from a 50:50 ratio. These individuals were also heterozygous for six common apoB polymorphisms, allowing calculation of the odds that each of these polymorphisms caused significant alterations in lipid levels. In contrast, the rare mutation at residue 3500 causing defective binding to the LDL receptor and familial defective apoB100 (FDB) resulted in substantial changes (26:74 and 13:87) in LDL allelic ratio in both of two FDB individuals examined.

Structure and function of several anti-dansyl chimeric antibodies formed by domain interchanges between human IgM and mouse IgG2b.

Two pairs of chimeric, domain-switched immunoglobulins with identical murine, anti-dansyl (5-dimethylaminonaphthalene-1-sulfonyl) variable domains have been generated, employing as parent antibodies a human IgM and a mouse IgG2b. The first pair of chimeric antibodies mu mu gamma mu and gamma gamma mu gamma was generated by switching the C mu 3 and C gamma 2 domains between IgM and IgG2b. The second pair of chimeras mu mu gamma gamma and gamma gamma mu mu were formed by switching both C mu 3 and C mu 4 with C gamma 2 and C gamma 3. SDS-polyacrylamide gel electrophoresis and analytical ultracentrifugation showed that over half (57 and 71%) of the two chimeric antibodies possessing the C mu 4 domain and tail piece formed disulfide-linked IgM-like polymers. In contrast, the two chimeric antibodies lacking the C mu 4 domain were almost entirely monomeric. Both monomeric chimeras had reduced ability to activate complement. The chimera gamma gamma mu gamma had no activity under any of the assay conditions, whereas mu mu gamma gamma caused only a small amount of cell lysis but was fully active in consuming complement at 4 degrees C. The polymeric chimera gamma gamma mu mu was much less active than IgM, bound C1 weakly and caused some cell lysis but consumed little complement with soluble antigen. The polymeric chimera mu mu gamma mu bound C1 strongly and was the most active antibody in all assays, even more active than the parental IgG2b and IgM antibodies; it was the only antibody that exhibited antigen-independent activity. The results suggest that C mu 3 alone does not constitute the complement binding site in IgM but requires both C mu 1-2 and C mu 4 for full activity.

Familial ligand-defective apolipoprotein B. Identification of a new mutation that decreases LDL receptor binding affinity.

Detection of new ligand-defective mutations of apolipoprotein B (apoB) will enable identification of sequences involved in binding to the LDL receptor. Genomic DNA from patients attending a lipid clinic was screened by single-strand conformation polymorphism analysis for novel mutations in the putative LDL receptor-binding domain of apoB-100. A 46-yr-old woman of Celtic and Native American ancestry with primary hypercholesterolemia (total cholesterol [TC] 343 mg/dl; LDL cholesterol [LDL-C] 241 mg/dl) and pronounced peripheral vascular disease was found to be heterozygous for a novel Arg3531-->Cys mutation, caused by a C-->T transition at nucleotide 10800. One unrelated 59-yr-old man of Italian ancestry was found with the same mutation after screening 1,560 individuals. He had coronary heart disease, a TC of 310 mg/dl, and an LDL-C of 212 mg/dl. A total of eight individuals were found with the defect in the families of the two patients. They had an age- and sex-adjusted TC of 240 +/- 14 mg/dl and LDL-C of 169 +/- 10 mg/dl. This compares with eight unaffected family members with age- and sex-adjusted TC of 185 +/- 12 mg/dl and LDL-C of 124 +/- 12 mg/dl. In a dual-label fibroblast binding assay, LDL from the eight subjects with the mutation had an affinity for the LDL receptor that was 63% that of control LDL. LDL from eight unaffected family members had an affinity of 91%. By way of comparison, LDL from six patients heterozygous for the Arg3500-->Gln mutation had an affinity of 36%. The percentage mass ratio of the defective Cys3531 LDL to normal LDL was 59:41, as determined using the mAb MB19 and dynamic laser light scattering. Thus, the defective LDL had accumulated in the plasma of these patients. Using this mass ratio, it was calculated that the defective Cys3531 LDL particles bound with 27% of normal affinity. Deduced haplotypes using 10 apoB gene markers showed the Arg3531-->Cys alleles to be different in the two kindreds and indicates that the mutations arose independently. The Arg3531-->Cys mutation is the second reported cause of familial ligand-defective apoB.

Analysis of the N-linked oligosaccharides of human C1s using electrospray ionisation mass spectrometry.

Information on the structures of the oligosaccharides linked to Asn residues 159 and 391 of the human complement protease C1s was obtained using mass spectrometric and monosaccharide analyses. Asn159 is linked to a complex-type biantennary, bisialylated oligosaccharide NeuAc2 Gal2 GlcNAc4 Man3 (molecular mass = 2206 +/- 1). Asn391 is occupied by either a biantennary, bisialylated oligosaccharide, or a triantennary, trisialylated species NeuAc3 Gal3 GlcNAc5 Man3 (molecular mass = 2861 +/- 1), or a fucosylated triatennary, trisialylated species NeuAc3 Gal3 GlcNAc5 Man3 Fuc1 (molecular mass = 3007 +/- 1), in relative proportions of approximately 1:1:1. The carbohydrate heterogeneity at Asn391 gives rise to three major types of C1s molecules of molecular masses 79,318 +/- 8 (A), 79,971 +/- 8 (B), and 80,131 +/- 8 (C), with an average mass of 79,807 +/- 8. A minor modification, yielding an extra mass of 132 +/- 2, is also detected within positions 1-153.

Human/mouse chimeric monoclonal antibodies with human IgG1, IgG2, IgG3 and IgG4 constant domains: electron microscopic and hydrodynamic characterization.

The unique structure of the human IgG3 constant region with its greatly extended hinge can clearly be seen in electron micrographs, which compare a series of recombinant proteins with the same murine anti-dansyl variable domain but constant domains from human IgG1, IgG2, IgG3 and IgG4. The hinge region of IgG3 was found to be very long, with some measurements extending to 100 A. It exhibited considerable flexibility allowing the Fc to be displaced far toward either side. Upon addition of bivalent hapten, all of the monoclonal antibodies formed complexes. IgG1, IgG3 and IgG4 formed circular dimers, composed of two antibodies forming a ring-shaped complex, presumably through the binding of two bivalent haptens. IgG2, on the other hand, showed a distribution of complexes which was noticeably different from the other subclasses. Some circular dimers, some linear dimers and a large amount of monomer were seen. This was interpreted in terms of an energy barrier to ring closure arising from the orientation of the Fab arms of IgG2 probably leading to linear dimers as the predominate complex seen with the analytical ultracentrifuge. A substantial number of these dimers probably dissociated upon dilution for examination in the electron microscope. The distribution of the angles between the Fab arms of the monoclonal antibodies forming the circular dimers has been measured for the different subclasses. Most were open at wide angles (> 100 degrees) but some formed very shallow angles, with the Fab arms being nearly parallel to each other. The free energy for this transition was calculated from the ratio of open/closed angles, and it was found to be proportional to the length of the upper hinge of the monoclonal antibody, in agreement with previous nanosecond depolarization results (Dangl et al., Eur. molec. Biol. Org. J. 7, 1989-1994, 1988).

Apolipoprotein B and low-density lipoprotein structure: implications for biosynthesis of triglyceride-rich lipoproteins.

ApoB100 is a very large glycoprotein essential for triglyceride transport in vertebrates. It plays functional roles in lipoprotein biosynthesis in liver and intestine, and is the ligand recognized by the LDL receptor during receptor-mediated endocytosis. ApoB100 is encoded by a single gene on chromosome 2, and the message undergoes a unique processing event to form apoB48 message in the human intestine, and, in some species, in liver as well. The primary sequence is relatively unique and appears unrelated to the sequences of other serum apolipoproteins, except for some possible homology with the receptor recognition sequence of apolipoprotein E. From its sequence, structure prediction shows the presence of both sheet and helix scattered along its length, but no transmembrane domains apart from the signal sequence. The multiple carbohydrate attachment sites have been identified, as well as the locations of most of its disulfides. ApoB is the single protein found on LDL. These lipoproteins are emulsion particles, containing a core of nonpolar cholesteryl ester and triglyceride oil, surrounded by an emulsifying agent, a monolayer of phospholipid, cholesterol, and a single molecule of apoB100. An emulsion particle model is developed to predict accurately the physical and compositional properties of an LDL of any given size. A variety of techniques have been employed to map apoB100 on the surface of the LDL, and all yield a model in which apoB surrounds the LDL like a belt. Moreover, it is concluded that apoB100 folds into a long, flexible structure with a cross-section of about 20 x 54 A2 and a length of about 585 A. This structure is embedded in the surface coat of the LDL and makes contact with the core. During lipoprotein biosynthesis in tissue culture, truncated fragments of apoB100 are secreted on lipoproteins. Here, it was found that the lipoprotein core circumference was directly proportional to the apoB fragment size. A cotranslational model has been porposed for the lipoprotein assembly, which includes these structural features, and it is concluded that in permanent hepatocyte cell lines, apoB size determines lipoprotein core circumference.

The structure and function of the first component of complement: genetic engineering approach (a review).

The availability of cDNA and genomic clones for the subcomponents of C1, as well as the recognition of the modular organization of serine-proteases have opened up exciting new possibilities for approaching structural problems. In this review the latest achievements of combined protein engineering, functional and structural studies are summarized. The concept of this research is to construct deletion, point and hybrid mutants of the highly homologous C1r and C1s subcomponents, to reveal the functional role of individual modules, map the interaction sites between subcomponents of the C1 complex and refine the structural model of C1. The first prerequisite of such an approach was the expression of the subcomponents in a eukaryotic system, in biologically active form. This was followed by expression of various mutants. Autographa californica nuclear polyhedrosis virus was used as vector to express human C1r and C1s in Spodoptera frugiperda cell culture and in lepidopteran larvae. The yield of expression was high enough to isolate recombinant subcomponents for structural and functional studies. Recombinant viruses containing the A-, B-, and C-chains of C1q were also constructed. The insect cells are able to beta-hydroxylate the Asn residue of the EGF domain in the C1r but with a low efficiency. It is clear now, that this post-translational modification does not play a role in the Ca2+ dependent C1r-C1s interaction. The results with deletion mutants of C1r show that both, domain I, and II are absolutely necessary for the tetramer formation and both have regulatory role in the autoactivation. The C1s alpha R hybrid does not dimerize in presence of Ca2+, however it can form a tetramer with C11(2) that can bind to C1q. This observation indicates that the function of the C1s alpha part in the hybrid is modulated by the C1r part (gamma B) of the molecule. The C1Rs hybrid behaves like C1r, providing haemolytically active C1 with C1q and C1s. This observations shows that the regulatory domains determine the high functional specificity of the serine-protease subcomponents of C1. In order to control the autoactivation process point mutant cDNAs were constructed by altering the Arg-Ile bond in the catalytic domain of the C1r. The Gln-Ile construction is a stable zymogen while the Arg-Phe mutant has a lower rate of autoactivation.

Electron-microscopic and hydrodynamic characterization of recombinant apolipoprotein (a) and its association with LDL.

A recombinant apo(a) containing 17 kringle 4 domains as well as the kringle 5 and protease domains of apo(a) was characterized by hydrodynamic studies and electron microscopy. Recombinant apo(a) is a monomer in solution with a molecular weight of 325,000 by sedimentation equilibrium and 320,000 by sedimentation and diffusion, and it is a highly asymmetric molecule with a frictional ratio of 2.2. In the electron microscope recombinant apo(a) is visualized as a flexible chain of domains approximately 800 A long. Sedimentation velocity studies also demonstrate that when it is mixed with LDL, recombinant apo(a) reversibly forms an Lp(a)-like complex with a 1:1 stoichiometry; moreover, complex formation is inhibited by 6-amino hexanoic acid. Hydrodynamic modeling and electron microscopy suggest that only a small portion of the r-apo(a) molecule interacts with the LDL and the rest of the chain extends into solution. Preliminary studies indicate that recombinant apo(a) also binds mouse LDL.