Refolding of the immunoglobulin light chain.

The kinetics of the refolding reactions of type lambda Bence Jones proteins from 4 M GuHCl were studied by CD, ultraviolet absorption, and fluorescence spectrophotometry. The kinetics were complex and consisted of at least three phases, an undetectable fast phase, a detectable fast phase, and a slow phase. The slow phase followed first-order kinetics and the three experimental methods used gave similar rate constants for all the Bence Jones proteins (about 3 X 10(-3) s-1). The refolding reaction of VL fragment was too fast to be measured in the present experiments. The refolding process of CL fragment was very similar to those of Bence Jones proteins except that the detectable fast phase was less significant. The rate constant of the slow phase observed for the CL fragment was similar to those of the slow phase observed for Bence Jones proteins. The activation energy of the slow phase was the same for a Bence Jones protein and its CL fragment. These results indicate that the refolding kinetics of the CL domain are very similar to those of isolated CL fragment and that refolding of the VL domain precedes refolding of the CL domain, even though both domains have similar immunoglobulin folds. However, the results of refolding experiments on Bence Jones proteins, and VL and CL fragments in the presence of ANS, as well as the other lines of evidence, indicate that the refolding kinetics of the Bence Jones protein molecule cannot be expressed as simple sum of the refolding reactions of isolated VL and CL fragments.     

Novel human light chain V kappa segment: serologic and structural analyses of the kappa III-like Bence Jones protein and IgG kappa light chain REE

Immunochemical and sequence analyses of kappa light chain REE (Bence Jones protein REE and the light chain isolated from IgG kappa myeloma protein REE) revealed antigenic and structural features not previously described for human kappa-chains. Although closely related to proteins of the V kappa III subgroup, light chain REE is readily distinguished from light chains classified serologically as members of the kappa IIIa or kappa IIIb sub-subgroups. Light chains REE (Bence Jones protein REE and light chain REE) are identical in sequence and differ from kappa III proteins by at least 10 uncommon amino acid substitutions in the first three framework regions. Further, kappa-chain REE is unique by virtue of a four-residue deletion in the third complementarity-determining region. The deletion encompasses the three carboxyl-terminal residues in the V kappa-encoded segment and the first residue at the site of V-J recombination. Urine specimens from patient REE also contained a light chain fragment that lacked the first (amino-terminal) 85 residues of the native light chain but otherwise was identical in sequence to the light chain REE. The extensive amino acid differences and unique length of the V kappa segment in light chain REE indicate that this kappa-chain is the product of an unusual V kappa III gene or, alternatively, represents a rarely expressed and novel human V kappa gene.     

Monomer-dimer equilibria of a Bence Jones protein and its variable fragment.

The circular dichroic (CD) spectra of a type lambda Bence Jones protein (Tod), its variable (VL) fragment, and the constant (CL) fragment of a type lambda protein (Nag) were measured under various conditions. In the pH region from 5.5 to 7.5, the CD spectra of Tod protein with intact interchain disulfide bond (L(SS)) and and CL did not change with pH, while the spectra of Tod protein in which the interchain disulfide bond had been reduced and alkylated (L(RA)) and VL did not change with pH. The dimerization reactions of L(RA) and VL were studied by following the CD change with protein concentration. The CD spectrum of CL did not change with the protein concentration. The dimerization constant for L(RA) was 4 X 10(4) M-1 at at pH 7.5 and 25 degrees C, which was smaller than that for VL (1 X 10(5) M-1). The ellipticity at 278 nm for the L(RA) dimer was different from that for the L(SS) dimer and changed with pH. These findings indicate that the L(RA) dimer and L(SS) dimer have different conformations. The differences in the conformation and L-L interaction between the L(RA) dimer and L(SS) dimer are discussed on the basis of the conformations of VL and CL and the interactions between the paired domains.     

Idiotypical identity of IgG myeloma protein with monoclonal IgM, Bence Jones protein, and Fv derived from one patient.

Serum from a patient (KK) with IgG2-lambda myeloma was shown to contain multiple paraproteins corresponding to an IgM-lambda monoclonal protein (MMP), a lambda-type Bence Jones protein (BJP), and a 30 kDa component in addition to the IgG2 myeloma protein (GMP). These proteins possessed common idiotypic determinants, as judged by their monoclonal reactivity with rabbit anti-GMP idiotype antibody (aId) in the immunofixation electrophoresis. Analysis with aId absorbed with either H or L chain of GMP revealed that the 30 kDa component shared both VH and VL with GMP and MMP, while BJP carried only the VL idiotype. The 30 kDa component, however, failed to react with antibody to either the mu, gamma, alpha, kappa, or lambda isotype, indicating that it had an Fv-like molecular composition. These results suggest that myeloma cells of KK had diverged from the same precursor B cell clone to produce MPs of different isotypes and altered molecular constructions.     

Complete amino acid sequence determinations demonstrate identity of the urinary Bence Jones protein (BJP-DIA) and the amyloid fibril protein (AL-DIA) in a case of AL-amyloidosis.

The complete primary structures of both the main amyloid fibril protein component (AL-DIA) and the soluble Bence Jones protein (BJP-DIA) obtained from the same patient with AL-amyloidosis are reported for the first time. The amino acid sequences were determined by automated Edman degradation following proteolytic digestion of the isolated proteins and HPLC separation of the resulting fragments and by amino-terminal sequencing after treatment with pyroglutamate aminopeptidase. Sequencing data were confirmed by amino acid analysis and plasma desorption mass spectrometry (PDMS). Molecular weights of the complete proteins were determined by laser desorption mass spectrometry. The amyloid fibril preparation contained a complete monoclonal lambda immunoglobulin light chain (subgroup 1.2) as well as different-sized fragments thereof which were identified by immunoblotting and amino-terminal sequencing following immobilization of electrophoretically-separated proteins on poly(vinylidene difluoride) (PVDF) membranes. The soluble urinary Bence Jones protein (BJP-DIA) was a dimer of monoclonal L-chains with a primary structure identical to that of the amyloid L-chain (AL-DIA) and thus represented the amyloid precursor protein.     

Preliminary crystallographic data on the human lambda III Bence Jones protein dimer Cle

A complete human λ Bence Jones protein dimer (Cle) has been isolated and crystallized. Protein Cle was characterized immunochemically and chemically as having a variable region amino acid sequence associated with light chains of the λ chain subgroup, λIII, and a constant region sequence characteristic of “non-Mcg” type λ chains. Bence Jones protein Cle contains two covalently bound intact monomers, each having a molecular weight of ~23,000. Crystals of Bence Jones protein Cle, obtained from ammonium sulfate solutions, diffract to 2.6 Å resolution and have the orthorhombic space group P2₁2₁2₁ with cell dimensions $\text{a = 113.0}\text{A}\text{?}\text{, b = 72.3}\text{A}\text{?}\text{,}\text{and}\text{c = 48.9}\text{A}\text{?}$. The asymmetric unit consists of a dimer with a molecular weight of ~ 46,000.     

Amino acid sequence of an amyloidogenic Bence Jones protein in myeloma-associated systemic amyloidosis

The complete amino acid sequence of an amyloidogenic Bence Jones protein (NIG-84) from an individual with myeloma-associated systemic amyloidosis has been determined. The protein, with a blocked N-terminus, represents a complete light chain consisting of 217 residues and it has a structural feature characteristic of the V lambda II subgroup. In addition to a two-residue insertion at positions 28 and 29, it has an additional rare insertion of alanine at position 100. NIG-84 is an example of the first complete sequence presented for the amyloidogenic Bence Jones protein of the V lambda II subgroup.     

Primary structure of the variable region of an amyloidogenic Bence Jones protein NIG-77

The complete amino acid sequence of the variable region of a Bence Jones protein NIG-77 from an individual with myeloma-associated systemic amyloidosis has been determined. This protein represents a complete light chain consisting of 216 residues and it has a sequence characteristic of V lambda I subgroup, which is closely homologous to that of another amyloidogenic V lambda I Bence Jones protein NIG-51, differing by 20 of 111 residues (82% homology). In contrast, it differs by 29 residues (74% homology) to that of non-amyloidogenic V lambda I light chain NIG-64. This finding shows that, in accordance with our previous report(1), the V lambda I-related light chains can further be divided into two distinct subsubgroups, V lambda I-1 and V lambda I-2, and the latter property seems to be more prone in association with the amyloid process.     

Association of human lambda light chain V/J/C segments: serologic analysis and primary structure of the lambda VI Bence Jones protein THO

The complete amino acid sequence of the human monoclonal lambda VI light chain Bence Jones protein THO was determined. We have found it to have remarkable similarities to the previously sequenced lambda VI Bence Jones protein SUT. Immunochemical analyses demonstrated that both lambda VI chains belong to a V lambda VI sub-subgroup. The 98-residue V gene-encoded segments of proteins THO and SUT are closely homologous and are distinguished from other lambda VI chains by a one-residue deletion at the V-J recombination site. Proteins THO and SUT have identical 13-residue J segments and therefore are encoded by the same J lambda gene. Further, both proteins have identical 105-residue C regions that by sequence represent products of the C lambda 3 (Kern-, Oz+) gene. The primary structure and serologic properties of proteins THO and SUT imply at the protein level of association between certain types of V lambda, J lambda, and C lambda segments.     

Protein L from Peptostreptococcus magnus binds to the kappa light chain variable domain.

Protein L is an immunoglobulin light chain-binding protein expressed by some strains of the anaerobic bacterial species Peptostreptococcus magnus. The major variable region subgroups of human kappa and lambda light chains were tested for protein L binding; V kappa I, V kappa III, and V kappa IV bound protein L, whereas no binding occurred with proteins of the V kappa II subgroup or with any lambda light chain subgroups. Studies of the protein L binding capacity of naturally occurring VL fragments, and VL- and CL-related trypsin- and pepsin-derived peptides prepared from a kappa I light chain, localized the site of interaction to the VL domain. The affinity constant for the binding to an isolated V kappa I fragment was comparable to that for the native protein (Ka 0.9 x 10(9) M-1 and Ka 1.5 x 10(9) M-1, respectively). No binding occurred with CL-related fragments. Extensive reduction and alkylation of the V kappa fragment or the native kappa chain resulted in complete loss of protein L binding. Although it is possible, from comparative amino acid sequence data, to identify certain VL-framework region residues that account for the selective binding of protein L by kappa I, kappa III, and kappa IV proteins, our studies indicate that this interaction is essentially dependent upon the tertiary structural integrity of the kappa chain VL domain.     

Unfolding and refolding of a type kappa immunoglobulin light chain and its variable and constant fragments

By limited proteolysis of a type kappa immunoglobulin light chain (Oku) with clostripain, both the VL and CL fragments were obtained with a high yield. The unfolding and refolding by guanidine hydrochloride of light chain Oku and its VL and CL fragments were studied at pH 7.5 and 25 degrees C with circular dichroism and tryptophyl fluorescence. The concentration of guanidine hydrochloride at the midpoint of the unfolding curve was 1.2 M for the VL fragment and 0.9 M for the CL fragment. As in the case of the CL fragment of light chain Nag (type lambda) [Goto, Y., & Hamaguchi, K. (1982) J. Mol. Biol. 156, 891-910], the unfolding and refolding kinetics of the CL fragment could be explained in principle on the basis of the three-species mechanism U1 in equilibrium U2 in equilibrium N, where N is native protein and U1 and U2 are the slow-folding and fast-folding species, respectively, of unfolded protein. The unfolding and refolding kinetics of the VL(Oku) fragment were described by a single exponential term. Double-jump experiments, however, showed that two forms of the unfolding molecule exist. The equilibrium and kinetics of unfolding of light chain Oku were explained by the sum of those of the VL and CL fragments. On the other hand, the refolding kinetics of light chain Oku were greatly different from the sum of those of the VL and CL fragments.(ABSTRACT TRUNCATED AT 250 WORDS)     

Thermally induced structural transitions of the variable and constant halves of Bence Jones proteins: fluorimetric studies

Fluorimetric method has been used to study the thermally induced structural transitions of the variable and constant halves of Bence Jones proteins. Like the intact protein, both the variable and constant halves exhibit significant increase in their fluorescence intensity at 50–56° due to conformational unfolding. The intact protein and its variable half, thus unfolded, exhibit considerable ANS dye (8-Anilinonapthalene-I-sulfonate) binding capacity, as measured by the increase in ANS fluorescence. However, this is not true for the unfolded constant half. The thermosolubility properties, which are shown by intact Bence Jones proteins and their variable halves but not by their constant halves, appear to correlate with the exposure of hydrophobic binding sites at elevated temperature.     

Ionization and reactivities of the thiol groups which participate in the formation of interchain disulfide bonds of Bence Jones proteins and an Fab(t) fragment

The pK values and reactivities of the thiol groups which participate in the formation of interchain disulfide bonds in Bence Jones proteins and the Fab(t) fragment of a myeloma protein (Jo) (IgGl, kappa) were determined by means of the reactions with chloroacetamide and DTNB, and of spectrophotometric titration. The two thiol groups of partially reduced type kappa Bence Jones protein dimers had the same pK values (pK = 9.76 at 0.2 ionic strength and 25 degrees C) and the same true second-order rate constants (k) toward chloroacetamide (k = 18.8 x 10(-2) M-1 . S-1). The two thiol groups of partially reduced type lambda Bence Jones protein dimers had different pK values but the variation of the pK values among the specimens was small (pK1 = 8.5-8.6 and pK2 = 9.5-9.7 at 0.2 ionic strength and 25 degrees C). The spectrophotometric titration of partially reduced Nag protein (type lambda) also showed that the two thiol groups have different pK values. The pK values of two thiol groups of the partially reduced Fab(t) fragment were determined as 8.51 and 9.76 at 0.2 ionic strength and 25 degrees C. The effect of ionic strength on the pK values of the thiol groups of partially reduced Nag protein and the pK values of the thiol groups in partially reduced Ta protein (type kappa) and in a hybrid molecule formed between partially reduced Ta protein and partially reduced and alkylated H chains indicated that the difference in pK values did not arise from electrostatic interaction between the two thiol groups, but that the pK values are intrinsically different. The true rate constants, k1 and k2, of the two thiol groups of type lambda Bence Jones proteins varied with the specimen (k1 = 1.9-5.7 x 10(-2) M-1 . S-1 and k2 = 18.5-25.0 x 10(-2) M-1 . S-1). The k1 and k2 values for Jo-Fab(t) were 7.21 x 10(-2) and 23.1 x 10(-2) M-1 . S-1, respectively. On the basis of these pK values and reactivities, we discuss the reformation of the interchain disulfide bonds from partially reduced Bence Jones proteins and immunoglobulins in the presence of oxidized glutathione.     

Effects of ammonium sulfate on the unfolding and refolding of the variable and constant fragments of an immunoglobulin light chain

The equilibria and kinetics of unfolding and refolding by guanidine hydrochloride of the VL and CL fragments of a type kappa immunoglobulin light chain were studied in the presence of ammonium sulfate using circular dichroism and tryptophyl fluorescence at pH 7.5 and 25 degrees C. The unfolding equilibria of the VL and CL fragments were described in terms of the two-state transition. The midpoints of unfolding in the absence of ammonium sulfate were at 0.9 and 1.2 M guanidine hydrochloride for the CL and VL fragments respectively. The transition curves were shifted to higher concentrations of guanidine hydrochloride by 1.4 and 1.6 M for the CL and VL fragments, respectively, per mole of ammonium sulfate. Unfolding reactions of the VL and CL fragments in 3 M guanidine hydrochloride followed first-order kinetics, and the rate constants for the two proteins were both greatly decreased by the presence of ammonium sulfate. The refolding reaction of the CL fragment in 0.3 M guanidine hydrochloride consisted of two phases, and the rate constants were increased a little by the presence of ammonium sulfate. The refolding reaction of the VL fragment in 0.3 M guanidine hydrochloride followed first-order kinetics, and the rate was not affected by the presence of ammonium sulfate. These results showed that ammonium sulfate stabilizes the CL and VL fragments mainly by decreasing the unfolding rate.     

Primary structure of the variable region of a human lambda VI light chain: Bence Jones protein SUT

To ascertain if lambda VI light chains have unique structural features that account for the preferential association of these proteins with primary or multiple myeloma-related amyloidosis (amyloidosis AL) we have determined the complete amino acid sequence of the variable (V) region of the lambda VI Bence Jones protein SUT. This protein, obtained from a patient with amyloidosis AL, represents a complete light chain consisting of 216 residues and it has structural and serologic properties characteristic for lambda VI light chains. The sequence of the joining segment (J) (positions 100 to 111) of protein SUT is identical to that of the J lambda I segment of the mouse IG lambda light chain gene. V region SUT is closely homologous in sequence to that of another lambda VI amyloid fibrillar protein, AR, differing by 21 residues. The V regions of proteins SUT and AR contain a two-residue insertion at positions 68 and 69 that has also been found in two other lambda VI human light chains but not in the lambda-chains of other V region subgroups.     

Global fluctuations of the immunoglobulin domains under physiological conditions

Hydrogen-exchange rates of the indole NH proton of a tryptophan residue, buried fully in the interior of each of the constant (CL) and variable (VL) fragments of a type-kappa-immunoglobulin light chain, were studied at various pH values and at 25 degrees C under 1H-nuclear magnetic resonance. The activation energies for the exchange reactions were determined also and compared with those for the unfolding reactions of these fragments induced by guanidine hydrochloride. The pH profiles of the exchange rates of the CL(kappa) and VL(kappa) fragments were very similar to that for a CL (lambda) fragment reported previously. It was found that the CL (kappa) and VL (kappa) fragments as well as the CL (lambda) fragment undergo a global unfolding transition with a conformation very similar to that of the fully unfolded state induced by guanidine hydrochloride even under physiological conditions.     

Immunogenicity and antigenicity of immunoglobulins: detection of human immunoglobulin light-chain carbohydrate, using concanavalin A

Concanavalin A binding to glycoprotein bands on nitrocellulose blots was used to detect mannose, sorbose, N-acetylgalactosamine and/or glucose residues on 100% (31/31) of human Bence Jones protein light chains, following sodium dodecyl sulphate-polyacrylamide gel electrophoresis. All (20/20) light chains form IgG myeloma proteins and light chains from a preparation of normal polyclonal human IgG were also bound by concanavalin A. The specificity of concanavalin A for glycoproteins was demonstrated by its binding to human Fc fragments and a human monoclonal anti-Rhesus D antibody (REG-A), but not to human albumin pFc' fragments and aglycosylated REG-A derived from cells grown in the presence of the glycosylation inhibitor tunicamycin. These results suggest that all Bence Jones proteins and light chains from myeloma IgG proteins contain mono- or oligosaccharides linked O-glycosidically to serine or threonine residues.     

Anomalous Urinary Proteins in Patients with Serum M-Components

Abnormal urinary proteins were investigated in 365 patients with serum M-components; 250 urines were available for study. All specimens were concentrated and processed by electrophoresis and immunoelectrophoresis. An overall frequency of Bence Jones proteinuria was found in 63%, whereas other M-components were detected in 18%. In patients with multiple myeloma, Bence Jones proteinuria occurred in 71%, while M-components in the form of whole molecules of immunoglobulins or as Fc and F''c fragments were observed in 20%. Bence Jones globulin was found in 60% of patients with IgG myeloma, 69% of those with IgA myeloma and 100% of patients with IgD myeloma and light chain disease. In regard to other diseases, Bence Jones proteinuria was found in 44% of patients with macroglobulinemia, in 60% of patients with nonplasmacytic neoplastic diseases and in 28% of patients with non-malignant conditions. Other M-components were detected in the urine of 13%, 14% and 6% respectively.The detection of abnormal urinary proteins in patients with M-components in the serum is an important diagnostic tool and may have prognostic significance.     

Characterization of a variable fragment of a human immunoglobulin lambda chain obtained by peptic cleavage in urea

The digestion of a human dimeric lambda Bence Jones protein with pepsin in 8 M urea without prior reduction and alkylation produced a fragment of molecular weight 11,000, designated as upV lambda, corresponding to almost the entire variable region of an immunoglobulin light chain. The C-terminal amino acid residue of fragment upV lambda was shown to correspond to leucine at position 104 of the immunoglobulin lambda light chain. Fragment upV lambda was isolated in the yield of 30% by ion exchange chromatography after gel filtration. When another lambda Bence Jones protein was treated in the same way, similar results were obtained.     

Conformational transitions of non-helical proteins effected by dodecyl sulfate. Circular dichroism of alpha1-acid glycoprotein, Bence Jones protein, carbonic anhydrase B, deoxyribonuclease, pepsinogen, and plasminogen.

Circular dichroism (CD) of serum alpha1-acid glycoprotein, urinary Bence Jones protein, human carbonic anhydrase B, deoxyribonuclease from bovine pancreas, porcine pepsinogen, and plasminogen from human serum was tested in the absence and presence of 0.005-0.05 M sodium dodecyl sulfate. It was found that in all cases the CD spectra of these proteins were modified by the dodecyl sulfate into spectra indicating the presence of a moderate content of alpha-helix. The transitions were enhanced by addition of acid (pH 2.1-4.4) in all cases tested. Comparison of the various proteins with respect to the amount of reconstruction of the main chain conformation showed that the amount of helix formed depended on the amino acid composition of the protein. Rigidity due to cross-linking by disulfide bridges is the strongest deterrant to the conformational change of the main chain. The CD bands of the native proteins in the 250-350 nm spectral zone were extinguished by sodium dodecyl sulfate, and new weak bands were observed the positions of which corresponded approximately to those of the native proteins. In all cases, except the carbonic anhydrase B, the bands of thus denatured proteins were negative.