Assembly, secretion, and vacuolar delivery of a hybrid immunoglobulin in plants

Secretory immunoglobulin (Ig) A is a decameric Ig composed of four alpha-heavy chains, four light chains, a joining (J) chain, and a secretory component (SC). The heavy and light chains form two tetrameric Ig molecules that are joined by the J chain and associate with the SC. Expression of a secretory monoclonal antibody in tobacco (Nicotiana tabacum) has been described: this molecule (secretory IgA/G [SIgA/G]) was modified by having a hybrid heavy chain sequence consisting of IgG gamma-chain domains linked to constant region domains of an IgA alpha-chain. In tobacco, about 70% of the protein assembles to its final, decameric structure. We show here that SIgA/G assembly and secretion are slow, with only approximately 10% of the newly synthesized molecules being secreted after 24 h and the bulk probably remaining in the endoplasmic reticulum. In addition, a proportion of SIgA/G is delivered to the vacuole as at least partially assembled molecules by a process that is blocked by the membrane traffic inhibitor brefeldin A. Neither the SC nor the J chain are responsible for vacuolar delivery, because IgA/G tetramers have the same fate. The parent IgG tetrameric molecule, containing wild-type gamma-heavy chains, is instead secreted rapidly and efficiently. This strongly suggests that intracellular retention and vacuolar delivery of IgA/G is due to the alpha-domains present in the hybrid alpha/gamma-heavy chains and indicates that the plant secretory system may partially deliver to the vacuole recombinant proteins expected to be secreted.     

Protein LG: a hybrid molecule with unique immunoglobulin binding properties.

Immunoglobulin (Ig)-binding bacterial proteins have attracted theoretical interest for their role in molecular host-parasite interactions, and they are widely used as tools in immunology, biochemistry, medicine, and biotechnology. Protein L of the anaerobic bacterial species Peptostreptococcus magnus binds Ig light chains, whereas streptococcal protein G has affinity for the constant (Fc) region of IgG. In this report, Ig binding parts of protein L and protein G were combined to form a hybrid molecule, protein LG, which was found to bind a large majority of intact human Igs as well as Fc and Fab fragments, and Ig light chains. Binding to Ig was specific, and the affinity constants of the reactions between protein LG and human IgG, IgGFc fragments, and kappa light chains, determined by Scatchard plots, were 5.9 x 10(9), 2.2 x 10(9), and 2.0 x 10(9) M-1, respectively. The binding properties of protein LG were more complete as compared with previously described Ig-binding proteins when also tested against mouse and rat Igs. This hybrid protein thus represents a powerful tool for the binding, detection, and purification of antibodies and antibody fragments.     

Differences in immunoglobulin light chain species found in urinary exosomes in light chain amyloidosis (Al)

Renal involvement is a frequent consequence of plasma cell dyscrasias. The most common entities are light chain amyloidosis, monoclonal immunoglobulin deposition disease and myeloma cast nephropathy. Despite a common origin, each condition has its own unique histologic and pathophysiologic characteristic which requires a renal biopsy to distinguish. Recent studies have shown urinary exosomes containing kidney-derived membrane and cytosolic proteins that can be used to probe the proteomics of the entire urinary system from the glomerulus to the bladder. In this study, we analyzed urine exosomes to determine the differences between exosomes from patients with light chain amyloidosis, multiple myeloma, monoclonal gammopathy of undetermined significance, and non-paraproteinemia related kidney disease controls. In patients with light chain amyloidosis, multiple myeloma and monoclonal gammopathy of undetermined significance, immunoreactive proteins corresponding to monomeric light chains were found in exosomes by western blot. In all of the amyloidosis samples with active disease, high molecular weight immunoreactive species corresponding to a decamer were found which were not found in exosomes from the other diseases or in amyloidosis exosomes from patients in remission. Few or no light chains monomeric bands were found in non-paraproteinemia related kidney disease controls. Our results showed that urinary exosomes may have tremendous potential in furthering our understanding of the pathophysiology and diagnosis of plasma cell dyscrasia related kidney diseases.     

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.     

A novel idiotopic determinant on phosphorylcholine-binding immunoglobulins restricted to isotype and allotype

A shared idiotopic (Id) determinant, designated B24-50, was detected on phosphorylcholine (PC)-binding myeloma proteins by using a monoclonal antibody. Analysis of immune sera from inbred and congenic strains of mice revealed the presence of this Id determinant on a very small proportion of the PC-binding immunoglobulins (Ig). Hybridoma and myeloma proteins of various classes were analyzed for B24-50 expression, and a clear association of B24-50 with IgA was demonstrated. The Id was found on two distinct idiotypic families, (TEPC15 and McPC603), which share a similar heavy chain but have different light chains; however, isolated heavy chains did not express B24-50. The Id did not require the absolute association of the TEPC15 light chain V kappa 22 with the TEPC15 heavy chain but appeared dependent upon the interaction of the light chain with the TEPC15 heavy chain via quaternary interactions and/or shared amino acid residues of V kappa 8 (M603) and V kappa 22. Furthermore, B24-50 was not found on IgA of strains with the Ighb allotype. Thus B24-50 is a novel isotype-restricted determinant found on two Id families and is influenced by the Igh allotype.     

Serologically defined V region subgroups of human lambda light chains

The availability of numerous antisera prepared against lambda-type Bence Jones proteins and lambda chains of known amino acid sequence has led to the differentiation and classification of human lambda light chains into one of five V lambda subgroups. The five serologically defined subgroups, V lambda I, V lambda II, V lambda III, V lambda IV, and V lambda VI, correspond to the chemical classification that is based on sequence homologies in the first framework region (FR1). Proteins designated by sequence as lambda V react with specific anti-lambda II antisera and are thus included in the V lambda II subgroup classification. The isotypic nature of the five V lambda subgroups was evidenced through analyses of lambda-type light chains that were isolated from the IgG of normal individuals. Based on analyses of 116 Bence Jones proteins, the frequency of distribution of the lambda I, lambda II/V, lambda III, lambda IV, and lambda VI proteins in the normal lambda chain population is estimated to be 27%, 37%, 23%, 3%, and 10%, respectively. This distribution of V lambda subgroups was comparable to that found among 82 monoclonal Ig lambda proteins. Considerable V lambda intragroup antigenic heterogeneity was also apparent. At least two sub-subgroups were identified among each of the five major V lambda subgroups, implying the existence of multiple genes in the human V lambda genome. The V lambda classification of 54 Ig lambda proteins obtained from patients with primary or multiple myeloma-associated amyloidosis substantiated the preferential association of lambda VI light chains with amyloidosis AL and the predominance of the normally rare V lambda VI subgroup in this disease.     

Production of a bi-specific monoclonal antibody recognizing mouse kappa light chains and horseradish peroxidase

Summary The production of a bi-specific monoclonal antibody that simultaneously recognizes mouse kappa light chains and horseradish peroxidase (HRP) for use as a general developing reagent in a wide variety of immunobased techniques is described. This antibody, named McC10, was produced by the fusion of an aminopterin-sensitive interspecies hybridoma which secretes rat monoclonal antibodies against HRP (RAP₂·Ag) and splenocytes from a rat immunized with whole mouse immunoglobulin (Ig)G. The hybrid-hybridoma generated from this fusion expresses and secretes rat Igs of the IgG₁ and IgG_2a subclasses, as determined by radial immunodiffusion. In competitive binding solid-phase enzymatic assays, McC10 was found to cross-react with all four mouse IgG subclasses as well as mouse kappa light chains. In contrast, in this type of assay, McC10 did not appear to recognize mouse IgA, IgM or lambda light chains. However, IgM-bearing kappa light chains were recognized by immunocytochemistry. Epitope specificity of this bi-specific antibody was more clearly determined on immunoblots where McC10 was found to exclusively recognize mouse kappa light chains and display no cross-reactivity with mouse Ig heavy chains nor with kappa light chains from rat or rabbit. In addition, McC10 was used successfully in two-step immunocytochemistry (ICC) for the localization of enkephalin, nerve growth factor (NGF) receptor and paired helical filament-immunoreactive sites in rat brain, rat skin and human brain, respectively, using mouse IgG's and IgM's as primary antibodies. McC10 compared favourably with peroxidase-anti-peroxidase (PAP) ICC with respect to sensitivity but was markedly superior with respect to specificity when used in fixed human brain or rat skin. This study demonstrates some of the potential advantages of using an epitope specific monoclonal bi-specific developing reagent like McC10 in an immunobased technique like ICC. Its potential use in a variety of other immunobased procedures is discussed.     

Production of a bi-specific monoclonal antibody recognizing mouse kappa light chains and horseradish peroxidase. Applications in immunoassays

The production of a bi-specific monoclonal antibody that simultaneously recognizes mouse kappa light chains and horseradish peroxidase (HRP) for use as a general developing reagent in a wide variety of immunobased techniques is described. This antibody, named McC10, was produced by the fusion of an aminopterin-sensitive interspecies hybridoma which secretes rat monoclonal antibodies against HRP (RAP2.Ag) and splenocytes from a rat immunized with whole mouse immunoglobulin (Ig)G. The hybrid-hybridoma generated from this fusion expresses and secretes rat Igs of the IgG1 and IgG2a subclasses, as determined by radial immunodiffusion. In competitive binding solid-phase enzymatic assays, McC10 was found to cross-react with all four mouse IgG subclasses as well as mouse kappa light chains. In contrast, in this type of assay, McC10 did not appear to recognize mouse IgA, IgM or lambda light chains. However, IgM-bearing kappa light chains were recognized by immunocytochemistry. Epitope specificity of this bi-specific antibody was more clearly determined on immunoblots where McC10 was found to exclusively recognize mouse kappa light chains and display no cross-reactivity with mouse Ig heavy chains nor with kappa light chains from rat or rabbit. In addition, McC10 was used successfully in two-step immunocytochemistry (ICC) for the localization of enkephalin, nerve growth factor (NGF) receptor and paired helical filament-immunoreactive sites in rat brain, rat skin and human brain, respectively, using mouse IgG's and IgM's as primary antibodies. McC10 compared favourably with peroxidase-anti-peroxidase (PAP) ICC with respect to sensitivity but was markedly superior with respect to specificity when used in fixed human brain or rat skin.(ABSTRACT TRUNCATED AT 250 WORDS)     

Posttranslational association of immunoglobulin heavy chain binding protein with nascent heavy chains in nonsecreting and secreting hybridomas

A rat monoclonal antibody specific for immunoglobulin (Ig) heavy chain binding protein (BiP) has allowed the examination of the association of BiP with assembling Ig precursors in mouse B lymphocyte-derived cell lines. The anti-BiP monoclonal antibody immunoprecipitates BiP along with noncovalently associated Ig heavy chains. BiP is a component of the endoplasmic reticulum and binds free intracellular heavy chains in nonsecreting pre-B (mu+, L-) cell lines or incompletely assembled Ig precursors in (H+, L+) secreting hybridomas and myelomas. In the absence of light chain synthesis, heavy chains remain associated with BiP and are not secreted. The association of BiP with assembling Ig molecules in secreting hybridomas is transient and is restricted to the incompletely assembled molecules which are found in the endoplasmic reticulum. BiP loses affinity and disassociates with Ig molecules when polymerization with light chain is complete. We propose that the association of BiP with Ig heavy chain precursors is a novel posttranslational processing event occurring in the endoplasmic reticulum. The Ig heavy chains associated with BiP are not efficiently transported from the endoplasmic reticulum to the Golgi apparatus. Therefore, BiP may prevent the premature escape and eventual secretion of incompletely assembled Ig molecules.     

Determination of the subclasses of monoclonal human immunoglobulins G and of the light chain type with the aid of specific antisera]

Sera of 86 patients suffering from G-myeloma were studied for the purpose of determination of subclasses of monoclone IgG. Investigations were carried out by means of antisera to subclasses IgG by the double diffusion method in gel after Ouchterlony. The following distribution of myeloma Ig was revealed: G1--70%, G2--17%, G3--11%,and G4--2%. In typing of the light igG chains by the method of immunoelectrophoresis, using antisera to the light chains of immunoglobulins of the chi and lambda type it was found that IgG1 chi was encountered more frequently than IgG1 lambda (3:1 ratio). The amount of the sera with the IgG2, IgG3, and IgG4 was insufficient for the reliable conclusion of their distribution by the type of light chains.     

Immunoglobulin fold and tandem repeat structures in proteoglycan N-terminal domains and link protein

Detailed primary sequence and secondary structure analyses are reported for the hyaluronate binding region (G1 domain) and link protein of proteoglycan aggregates. These are based on six full or partial sequences from the chicken, pig, human, rat and bovine proteins. Determinations of a full pig and a partial human link protein sequence are reported in the Appendix. Five sequences at the N terminus in both proteins were compared with the structures of 11 variable immunoglobulin (Ig) fold domains for which crystal structures are available. Despite only modest sequence homology, a clear alignment could be proposed. Analysis of this shows that the equivalents of the first and second hypervariable segments are now significantly longer, and both proteins have N-terminal extensions that are up to 23 residues in length. Secondary structure predictions showed that these sequences could be identified with available crystal structures for the variable Ig fold. However the hydrophobic residues involved in interactions between the light and heavy chains in Igs are replaced by hydrophilic charged groups in both proteins. These results imply that both proteins are members of the Ig superfamily, but exhibit structural differences distinct from other members of this superfamily for which crystal structures are known. The proteoglycan tandem repeat (PTR) is a repeat of 99 residues that is found twice in the amino acid sequence of link protein and the proteoglycan G1 domain adjacent to the Ig fold, and also twice in the proteoglycan G2 domain. A total of 16 PTRs was available for analysis. Compositional analyses show that these are positively charged if these originate from link protein, and negatively charged if from the G1 or G2 domains. The 16 Robson secondary structure predictions for the PTRs were averaged to improve the statistics of the prediction, and checked by comparison with Chou-Fasman calculations. A strong alpha-helix prediction was found at residues 13 to 25, and several beta-strands were predicted. The overall content is 18% alpha-helix and 28% beta-sheet, with 44% of the remaining sequence being predicted as turns. These analyses show that both the proteoglycan G1 domain and link protein are constructed from two distinct globular components, which may provide the two functional roles of these proteins in proteoglycan aggregation.     

Protein G: a powerful tool for binding and detection of monoclonal and polyclonal antibodies

Protein G is an immunoglobulin (IgG)-binding bacterial cell wall protein recently isolated from group G streptococci. We have investigated the avidity of protein G for various monoclonal and polyclonal Ig of the IgG class, and compared it with the binding properties of protein A, the staphylococcal Fc-binding protein. Radiolabeled Ig were mixed with Sepharose-coupled protein G or protein A, and the amounts of radioactivity bound to the matrix-coupled bacterial proteins were determined. The avidity was found to be greater for protein G than for protein A for all examined Ig. Protein G bound all tested monoclonal IgG from mouse IgG1, IgG2a, and IgG3, and rat IgG2a, IgG2b, and IgG2c. In addition, polyclonal IgG from man, cow, rabbit, goat, rat, and mouse bound to protein G, whereas chicken IgG did not. The binding property of protein G was additionally exploited in the Western blot assay, in which iodine-labeled protein G was used successfully for the detection of a rat monoclonal antibody against ovalbumin, and for the detection of rabbit and goat polyclonal whole antisera against human urinary proteins. In these experimental situations, protein G was found to be a powerful reagent for the detection of IgG, and consequently the antigen against which these antibodies are directed.     

Immunoglobulin heavy chain and binding protein complexes are dissociated in vivo by light chain addition

Immunoglobulin heavy chain binding protein (BiP, GRP78) associates stably with the free, nonsecreted Ig heavy chains synthesized by Abelson virus transformed pre-B cell lines. In cells synthesizing both Ig heavy and light chains, the Ig subunits assemble rapidly and are secreted. Only incompletely assembled Ig molecules can be found bound to BiP in these cells. In addition to Ig heavy chains, a number of mutant and incompletely glycosylated transport-defective proteins are stably complexed with BiP. When normal proteins are examined for combination with BiP, only a small fraction of the intracellular pool of nascent, unfolded, or unassembled proteins can be found associated. It has been difficult to determine whether these BiP-associated molecules represent assembly intermediates which will be displaced from BiP and transported from the cell, or whether these are aberrant proteins that are ultimately degraded. In order for BiP to monitor and aid in normal protein transport, its association with these proteins must be reversible and the released proteins should be transport competent. In the studies described here, transient heterokaryons were formed between a myeloma line producing BiP-associated heavy chains and a myeloma line synthesizing the complementary light chain. Introduction of light chain synthesis resulted in assembly of prelabeled heavy chains with light chains, displacement of BiP from heavy chains, and secretion of Ig into the culture supernatant. These data demonstrate that BiP association can be reversible, with concordant release of transportable proteins. Thus, BiP can be considered a component of the exocytic secretory pathway, regulating the transport of both normal and abnormal proteins.     

Production of a monoclonal antibody directed against rat liver glutathione-insulin transhydrogenase

A hybridoma cell line secreting monoclonal antibody specific for glutathione-insulin transhydrogenase has been produced by fusing mouse myeloma cells with spleen cells from mice immunized to purified rat liver glutathione-insulin transhydrogenase. The secreted antibody isotypes were found to be: Ig gamma 1 heavy chains and kappa light chains. This monoclonal antibody has been used to screen glutathione-insulin transhydrogenase in various rat tissue extracts (liver, fat, heart, testis, spleen, lung and kidney) following separation on NaDodSO4/urea polyacrylamide disc-gel electrophoresis and electrophoretic transfer to nitrocellulose. Screening with the monoclonal antibody showed the presence of one immunoreactive protein band equal in molecular weight to that of purified rat liver GIT (Mr 53,000) in extracts of all tissues studied and a second immunoreactive protein band of lower molecular weight (Mr 49,000) in spleen and lung tissue extracts. Separation of these two proteins by HPLC using a TSK-DEAE column demonstrated that both proteins exhibit insulin degrading activity. These data indicate that GIT may occur in multiple forms in some tissues.     

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.     

M components-a review of 1242 cases.

Among 1242 patients referred for immunologic investigation 1255 M components were detected in the serum. Of these patients 50.9% had multiple myeloma, 18.1% had nonmyelomatous malignant diseases such as macroglobulinemia, lymphoma, leukemia or cancer, 4.3% had connective tissue diseases, 2.5% had primary generalized amyloidosis (PGA) and the rest had various "benign" conditions. Whereas IgG was the commonest M component in multiple myeloma, connective tissue diseases and the other benign conditions, IgM was the commonest M component in lymphoma and leukemia; Bence Jones proteinemia was most frequently observed in PGA. The ratio of kappa to lambda light chains varied from 1.7:1 in IgG myeloma to 1:9 in IgD myeloma, and was 1:2.1 in PGA. Bence Jones protein was detected in 422 (66%) of 640 urine samples tested, the prevalence ranging from more than 70% in multiple myeloma and PGA to as low as 36% in various benign conditions. It is evident that the class and type of M components and the presence of Bence Jones proteinuria have no definite significance with regard to the diagnosis. Therefore, thorough investigation and follow-up at regular intervals are required when M components are detected.     

Immunological evaluation of urinary trypsin inhibitors in blood and urine: Role of N- & O-linked glycoproteins

Urinary trypsin inhibitors (uTi) suppress serine proteases during inflammation. After liberation from proinhibitors (P-alpha-I and I-alpha-I) by the white blood cell (WBC) response, uTi readily pass through the kidneys into urine. A key uTi, bikunin, is attached to O-linked and N-linked glycoconjugates. Recently, uTi inhibitors, called uristatins, were found to lack the O-linked glycoconjugates. Monoclonal antibodies were produced using purified uristatin and screened for binding differences to uristatin, bikunin, P-α-I, and I-α-I. Antibody-binding patterns were characterized using immunoaffinity binding onto protein-chip surfaces and analysis by Surface Enhanced Laser Desorption/Ionization mass spectrometry (SELDI), using specimens from patients and from purified uTi standards. Antibodies were developed and used in an enzyme-linked immunosorbent assay (ELISA) method for uTi measurement in urine and plasma specimens. ELISA was performed on specimens from normal, presumed healthy, controls and from patients who had been screened for inflammation using a high sensitivity C-reactive protein (CRP) test and a complete blood count (CBC). Polyclonal antibody against uTi showed cross-reactivity with the Tamm–Horsfall protein (THP) and with proinhibitors. Screening of anti-uTi monoclonal antibodies (Mab) revealed antibodies that did not cross-react with either of the above, thus providing a tool to measure both uristatin and bikunin in urine with Mab 3G5 and in plasma with Mab 5D11. The monoclonal antibody 5D11 cross-reacts with specific N-linked glycoconjugates of uristatin present in plasma. In ca 96% of healthy adults, uTi were present at <12 mg/l in urine and <4 mg/l in plasma. We also found that patients with an inflammation and a CRP of >2.0 mg/l had higher urinary concentrations of uTi than the control population in every subject. Free uristatin and bikunin pass readily into urine and are primarily bound to heavy chains that constitute the proinhibitor form in plasma.     

Diurnal fluctuations of protein contents and the pH dependence of β<Subscript>2</Subscript>-microglobulin stability in urine

Diurnal fluctuations of protein excretion into urine and the effect of urinary pH on the urinary protein concentrations were studied in patients with various kidney diseases. The diurnal kinetics of γ-immunoglobulin, transferrin, albumin, α₁-microglobulin, γ-immunoglobulin light chains, and the retinol-binding protein proved to positively correlate with the diurnal fluctuations of proteinuria and to negatively correlate with urinary pH. Diurnal changes in urinary β₂-microglobulin content did not correlate with those of any other protein. Oral bicarbonate intake alkalinized the urine, increased the urinary β₂-microglobulin content, and led to a direct correlation between β₂-microglobulin excretion and excretion of other low-molecular proteins. Thus, proteinuria, single protein excretion, and urinary pH displayed diurnal rhythmicity in the patients; β₂-microglobulin was unstable in acid urine and its urinary level depended on the urinary pH.     

Electrophoretic characteristics of monoclonal immunoglobulin G of different subclasses

Monoclonal IgG are commonly observed in various B cell disorders, of which multiple myeloma is the most clinically relevant. In a series of serum samples, we identified by immunofixation 73 monoclonal IgG, including 63 IgG(1), 4 IgG(2), 5 IgG(3), and 1 IgG(4). The light chains were of kappa type in 45 cases, and of lambda type in 28 cases. These monoclonal IgG were further characterized by high resolution two-dimensional polyacrylamide gel electrophoresis (2-DE) in various isoelectric focusing conditions, as well as by 3-DE (2-DE of the proteins extracted from agarose after serum protein agarose electrophoresis). After 2-DE, 38 out of 73 monoclonal gamma chains (52%) were visualized using immobilized pH 3-10 gradients for isoelectric focusing. In 6 cases (8%), gamma chains were only detected using alkaline immobilized pH 6-11 gradients. In 3 cases (4%), 3-DE revealed monoclonal gamma chains hidden by polyclonal gamma chains. Finally, in 26 cases (36%), no monoclonal gamma chains were clearly visualized. Sixty-one monoclonal light chains (84%) were detected using immobilized pH 3-10 gradients, whereas 12 (16%) were not. Monoclonal gamma chains and light chains were highly heterogeneous in terms of pI and M(r). However, a statistically significant correlation (P<0.05) was observed between the position of the monoclonal IgG in agarose gel and the pI of their heavy and light chains (R=0.733, multiple linear regression). Because of the extreme diversity of their heavy and light chains, it appears that a classification of monoclonal IgG based only on their electrophoretic properties is not possible.     

Noncovalent association of heavy and light chains in Rana catesbeiana immunoglobulins

The unreduced immunoglobulins (Ig) in the bullfrog, Rana catesbeiana, dissociate into two components when subjected to electrophoresis or molecular sieving in dissociating solvents. One of these components is monomeric light chain and the other is a disulfide-bonded complex of heavy chains. This unusual behavior has been observed with all classes of bullfrog Ig that have been isolated and characterized previously: a high m.w. Ig that resembles mammalian IgM and two antigenically distinct varieties of low m.w. Ig. Light chains, isolated from the high m.w. Ig by gel filtration in 8 M urea, 1 M acidic acid, were found to contain, on average, 5.7 residues of half-cystine. None of these residues were in the free sulfhydryl form nor were they blocked by half-cystine. Moreover, none was alkylated after mild reduction of the high m.w. Ig. These findings indicate that none of the light chain half-cystine residues participate in an interchain disulfide bridge, and that most of the light chains contain three intrachain bridges. This unusual pattern of disulfide bonding appears to be responsible for the noncovalent association of heavy and light chains in this species.