Mercaptan-induced fragmentation of a subunit-like proteolytic fragment of immunoglobulin M

Limited papain hydrolysis of immunoglobulin M (IgM) produces a subunit-like proteolytic fragment designated IgM(p) (Inman & Hazen, 1968). In the presence of mercaptans, IgM(p) partially dissociated into Fc(mu)-like and Fab(mu) fragments. Treatment of residual IgM (that remaining after a papain digestion) with 2mm-mercaptoethylamine resulted in fragmentation of the same type that occurs in a routine limited digestion of IgM with papain, although exogenous enzyme was not added to the mixture. When IgM was hydrolysed with (14)C-labelled papain, a small quantity of the enzyme was found to be associated with the residual IgM and IgM(p) fractions. IgM and IgM 7S subunit (IgM(s)) that had been exposed to papain in the absence of activating mercaptan and separated from the enzyme by gel filtration also fragmented when subsequently treated with 2mm-mercaptoethylamine. The fragments resembled those produced during a typical limited papain digestion of IgM. It was concluded that mercaptoethylamine induced fragmentation of IgM(p) by activating adsorbed papain.     

Structural and immunochemical studies of carp (Cyprinus carpio L.) immunoglobulin. V. Tryptic fragments of carp (Cyprinus carpio L.) immunoglobulin M]

Carp IgM, isolated from normal serum is more sensitive to trypsinization compared to a human myeloma protein IgMGo. Under the same conditions (treatment with trypsin at 56 degrees C for 30 min) carp IgM was degraded to small, mostly dialysable peptides to a larger extent than IgMGo. In both cases the fragmentation resulted in immunoelectrophoretically pure Fab mu and Fc mu fragments. The Fab mu fragments of human IgM (yield: 20% of used IgM material) had a molecular weight of 54,000, the Fc mu fragments (yield: 30%) were a heterogenous mixture as far as molecular sizes concerned with values of about 300,000. For the corresponding fragments of carp IgM we could analyze a molecular weight of about 43,000 for Fab mu (yield: 8%) and for Fc mu (yield 10%) three fractions of 160,000, 130,000 and 90,000. The reductive subunits of Fc mu fragments showed different molecular weights: 39,000 for IgMGo and 45,000 for carp IgM. The anti-fragment antisera prepared in rabbits were monospecific as demonstrated by immunodiffusion.     

Solution structure of human and mouse immunoglobulin M by synchrotron X-ray scattering and molecular graphics modelling. A possible mechanism for complement activation

The pentameric 71-domain structure of human and mouse immunoglobulin M (IgM) was investigated by synchrotron X-ray solution scattering and molecular graphics modelling. The radii of gyration RG of human IgM Quaife and its Fc5, IgM-S, Fab'2 and Fab fragments were determined as 12.2 nm, 6.1 nm, 6.1 nm, 4.9 nm and 2.9 nm in that order. The RG values were similar for mouse IgM P8 and its Fab'2 and Fab fragments, despite the presence of an additional carbohydrate site. The IgM scattering curves, to a nominal resolution of 5 nm, were compared with molecular graphics models based on published crystallographic alpha-carbon co-ordinates for the Fab and Fc structures of IgG. Good curve fits for Fab were obtained based on the crystal structure of Fab from IgG. A good curve fit was obtained for Fab'2, if the two Fab arms were positioned close together at their contact with the C mu 2 domains. The addition of the Fc fragment close to the C mu 2 domains of this Fab'2 model, to give a planar structure, accounted for the scattering curve of IgM-S. The Fc5 fragment was best modelled by a ring of five Fc monomers, constrained by packing considerations and disulphide bridge formation. A position for the J chain between two C mu 4 domains rather than at the centre of Fc5 was preferred. The intact IgM structure was best modelled using a planar arrangement of these Fab'2 and Fc5 models, with the side-to-side displacement of the Fab'2 arms in the plane of the IgM structure. All these models were consistent with hydrodynamic simulations of sedimentation data. The solution structure of IgM can therefore be reproduced quantitatively in terms of crystallographic structures for the fragments of IgG. Putative Clq binding sites have been identified on the C mu 3 domain. These would become accessible for interaction with Clq when the Fab'2 arms move out of the plane of the Fc5 disc in IgM, that is, a steric mechanism exposing pre-existing Clq sites. Comparison with a solution structure for Clq by neutron scattering shows that two or more of the six globular Clq heads in the hexameric head-and-stalk structure are readily able to make contacts with the putative Clq sites in the C mu 3 domains of free IgM if if the Clq arm-axis angle in solution is reduced from 40 degrees-45 degrees to 28 degrees. This could be the trigger for Cl activation.     

The controlling effect of carbohydrate in human, rabbit and bovine immunoglobulin G on proteolysis by papain

About two-thirds of the hexose of human and rabbit immunoglobulin G (IgG) was located in the Fc fragment and one-third in the `hinge' region of the γ (heavy) polypeptide chain at the junction of the Fab and Fc fragments. In contrast, bovine IgG contained more hexose in the `hinge' region than in the Fc fragment. The initial cleavage of susceptible IgG molecules into Fab and Fc fragments by papain under the conditions given by Porter (1959) had reached completion after digestion for 2hr., though bovine IgG was digested somewhat more slowly than human or rabbit IgG. The release of `hinge' peptides from human and rabbit IgG had also reached completion by 2hr., but was slower from bovine IgG and continued for several hours longer. Since bovine IgG molecules contained on the average a greater amount of hexose in the `hinge' region, carbohydrate on this part of the γ-chain may influence not only the initial rate of enzymic hydrolysis into Fab and Fc fragments, but also, and to a greater extent, the rate of further limited hydrolysis of the N-terminal regions of the Fc fragment. The presence of carbohydrate in the `hinge' region does not appear to account for the resistance of some IgG molecules to papain digestion and of some Fc fragments to N-terminal degradation.     

Stepwise cleavage of rabbit immunoglobin G by papain and isolation of four types of biologically active Fc fragments

Four types of Fc fragments of different sizes were isolated by papain treatment of rabbit immunoglobulin G under various conditions and by subsequent chromatographic procedures. 1. Brief digestion at neutral pH without reduction produced a molecule in which the Fab and Fc fragments were still linked by a pair of labile disulphide bridges, and the Fc fragment released by cleaving these bonds, called 1Fc fragment, contained a portion of the ;hinge' region including an interchain disulphide bridge. Both complement-binding and guinea-pig skin-binding activities were retained by this fragment, which had mol. wt. 48000. 2. Prolonged digestion at neutral pH of immunoglobulin G whose labile inter-heavy-chain disulphide bridges had been reduced removed the ;hinge' region, giving mFc fragments (mol. wt. 46000), which lacked the capacity to bind guinea-pig skin but retained the antigenic as well as the complement-binding activities of 1Fc fragment completely. 3. Digestion at pH5.0 yielded a smaller fragment, sFc (mol. wt. 40000), which was no longer able to bind complement. Though the antigenic structure was intact, sFc fragment was curiously unable to precipitate with antibodies to the N-terminal determinants. 4. Fragment stFc (mol. wt. 25000), representing the C-terminal portion of Fc fragment, was formed from all the larger fragments by digestion at pH4.5. Only the C-terminal antigenic determinants were retained by stFc fragment.     

Some peculiarities of the dynamics of the immunoglobulin M structure

The isotropic mobility of separate regions of the intact molecule of immunoglobulin M (IgM) and its Fab and (Fc)5 fragments was studied using spin-labeling of carbohydrate (2,2,6,6-tetramethyl-4-aminopiperidine-1-oxyl) and peptide (2,2,5,5-tetramethyl-3-dichlorotriazinylaminopyrrolidine-1-oxyl) moieties. The spin-labeled oligosaccharide groups (OGs) in the Fab region are shown to have much more amplitude of anisotropic motion than those in the (Fc)5 region. The spin label in the latter is evidently attached in the C mu 3 domain to one of its OGs which is probably stabilized by ionic contacts between terminal N-acetylneuraminic acid residue and the peptide moiety of the IgM molecule. When the amount of the glycosidase-cleaved carbohydrate does not exceed 10-15%, most OGs affected are of the Fab region. Upon profound splitting (greater than or equal to 50%) the OGs of the (Fc)5 region are also affected; that results evidently in loosening the ionic contacts between the shortened OGs and the peptide moiety of IgM, and consequently in increasing mobility of the former. The structure of the (Fc)5 region of IgM is labile; after detaching this moiety from the intact IgM molecule, its structure is stabilized, but one of its domains (C mu 3) becomes more mobile than it is in the intact IgM molecule; at the same time the amplitude of anisotropic motion of OG bound here is decreased. In the latter case, this decrease depends on the sequence of spin-labeling and fragmentation. The most probable cause of stabilization of the (Fc)5 fragment is the heating of IgM solution to 56 degree C during fragmentation with trypsin. At this temperature the tau value for the (Fc)5 fragment is unusually low, equaling 23 ns. The spin-labeling in the peptide part of IgM occurs mostly in the Fab region which is a rather rigid moiety as expected.     

Expression, distribution and specificity of Fc receptors for IgM on murine B cells

Subpopulations of normal adult murine splenic B cells and a panel of murine B cell tumors were examined for their ability to bind murine IgM specifically. By using two-color flow cytometric analyses, we have demonstrated that 90 to 95% of surface (s)IgD+ B cells express surface membrane receptors for IgM (Fc mu R). The binding of pentameric murine IgM to splenocyte Fc mu R was IgM-specific since it was totally inhibited by other polymeric IgM proteins, but not by Ig of other H chain classes or by mAb specific for the murine IgG or IgE FcR. Binding of IgM to splenic cells was saturable. Fc mu R were co-expressed with the Fc gamma R as well as the Fc epsilon R on the majority of splenic B cells. Minor populations of splenic mononuclear cells expressed only an Fc mu R, Fc gamma R or Fc epsilon R. In a survey of B tumor cell lines representing different stages of B cell development, we observed that the Fc mu R was expressed on pre-B cell lines and that Fc mu R detection was maximal on immature B cell lines that expressed sIgM and low amounts of sIgD and Ia. Fc mu R were not detected on cell lines that had switched from sIgM to the expression of another sIg, or on plasmacytomas and hybridomas. The studies with normal splenocytes establish that the majority of sIgD+ B lymphocytes in adult BALB/c mice express surface membrane receptors that specifically bind IgM. The studies with B lineage tumor cells suggest that the expression of Fc mu R on B cells is developmentally regulated and that the pattern of expression exhibited by Fc mu R during B cell ontogeny differs from the patterns that have been previously found for IgG and IgE FcR. These observations raise the possibility that Fc mu R might have a functional significance in some aspect of B cell maturation and activation. By using a family of IgM H chain constant region domain deletional mutants, we have further demonstrated that, like the T cell Fc mu R, the B cell Fc mu R also requires a C mu 3 domain for binding to occur, raising the possibility that the T and B cell Fc mu R in mice may be structurally related molecules.     

Characterization of two species of Fc fragments obtained from rat IgG2a by prolonged papain digestion.

Prolonged papain digestion of rat IgG2a produced two molecular species of Fc fragments, termed Fc(I) and Fc(II). Studies by gel filtration chromatography and polyacrylamide gel electrophoresis in SDS/urea indicated that the two subunit polypeptide chains in each Fc preparation were associated by non-covalent bonds only. By analytical ultracentrifugation Fc(I) was found to have a m.w. of 47,100 and a sedimentation coefficient of 4.08S. Fc(II) had a m.w. of 39,800 and a sedimentation coefficient of 3.83S. The m.w. for the subunit chains of Fc(I) and Fc(II) were 25,300 and 20,300, respectively, as determined by analytical ultracentrifugation under dissociating conditions. Calculation of the frictional coefficient ratios indicated that both Fc fragments possessed compact globular structures. The difference in size between these two Fc fragments probably was due to a loss of some carboxy-terminal residues in Fc(II). Both Fc fragments possessed nearly identical amino-terminal amino acid sequences. Papain cleavage occurred primarily between residues 233/234 and 234/235. The carbohydrate compositions of the two species of Fc fragments were similar. It was concluded that under acid and reducing conditions papain cleavage of rat IgG2a occurred to the carboxy-terminal side of the hinge region. Prolonged papain digestion led to secondary attack in the carboxy-terminal end of the CGAMMA3 domain at an unidentified site, or sites, producing a stable second species of Fc fragments.     

Glycosylation in the Fc domain of IgG increases resistance to proteolytic cleavage by papain

IgG antibodies (Abs) and fragments of IgG Abs are becoming major biotherapeutics to treat an assortment of human diseases. Commonly prepared fragments of IgGs include Fc, Fab, and F(ab')2 fragments, all of which can be made using the sulfhydryl protease papain, although prolonged digestion times and/or excessive amounts of papain typically result in further cleavage of the Fc domain into smaller fragments. During our attempts to use papain to isolate Fc fragments from different IgG monoclonal Abs, it was observed that prior removal of Fc glycans resulted in a faster rate of papain-mediated degradation of the Fc domain. Subsequent time-course experiments comparing glycosylated and deglycosylated versions of IgG antibodies showed that the majority of molecules in a deglycosylated IgG sample were converted into Fab, Fc, and smaller Fc fragments in less than one hour, whereas the original glycosylated IgG required more than two hours to convert into a comparable amount of Fab and Fc fragments. Furthermore, whereas papain digestion converted almost all of a deglycosylated Fc fragment into smaller fragments of approximately 10 and approximately 12 kDa within 4 h, more than 40% of a glycosylated Fc fragment remained intact even after 24 h of digestion. These results indicate that the presence of CH(2) domain glycans in either IgGs or purified Fc fragments increases resistance to papain digestion. Increased sensitivity of non-glycosylated Fc domains to papain is consistent with the Fc domains lacking a defined structure, as exemplified by their inability to bind Fcgamma receptors, since misfolded proteins are often degraded by proteases because of increased accessibility of their proteolytic cleavage sites. Based on these observations it is possible to use papain sensitivity as a means of assessing proper Fc structure of IgG molecules.     

Comparison of the C-mediating killing activity and C-activating properties of mouse monoclonal and polyclonal antibodies against Trypanosoma cruzi

A Mouse polyclonal antiserum against Trypanosoma cruzi or its IgG and IgM fractions and five monoclonal antibodies (two IgM, two IgG(1) and one IgG(2a)) recognize and combine with membrane components of trypomastigote forms of the parasite as revealed by immunofluorescence. Although all these antibodies sensitize trypomastigotes and prepare them to activate the complement (C) system, as measured by consumption of total C, C4, B and C3, only the polyclonal antiserum or its IgG, IgM and Fabmu fragments were able to induce trypanosome lysis by the alternative C pathway.     

利用FPLC提纯抗苯丙氨酸羟化酶抗体的Fab及其轻链和重链的分离

 IgGPH_7经木瓜蛋白酶消解产生Fab和Fc,在FPLC仪上,分别用MonoQ,Superose_(12),MonoS柱提纯Fab。提纯的Fab经还原和烷基化后,再用琥珀酸酐修饰,然后用Mono Q柱分离得到轻链和重链。最后通过SDS凝胶电泳和N端顺序测定,以鉴定它的纯度和轻、重链。     

Fc and Fab Fragments from IgG<Subscript>2</Subscript> Human Immunoglobulins Characterized

Papain digestion of 7S immunoglobulin G (IgG) produces two 3.5S Fab fragments and one 3.5S Fc fragment^1–8. The Fab fragment contains one light chain and one Fd fragment and is still able to combine specifically univalently with antigen. The Fc fragment is a dimer of the carboxyl terminal half of the heavy chain. Pepsin splits 7S IgG into some small peptides derived from Fc and one 5S F(ab′)₂ fragment, which contains both antigen-binding sites. Based on this information, some investigators^6,7 have postulated that pepsin splits the γ chains at the C-terminal side of the inter-heavy chain disulphide bridges, whereas papain splits at the N-terminal side of the inter-heavy chain disulphide bridges. We report here evidence that this model does not apply to all IgG subclasses. In the case of human IgG₂ subclass myeloma proteins, papain splits initially at the C-terminal side of inter-heavy chain disulphide bridges. We also show that the amino-acid sequence of the Fc fragment of human IgG₂ subclass so far determined has approximately 95% homology with that of human IgG₁ and IgG₄ subclasses reported by others^9–15.     

Cell-adhesive immunoglobulin M in human plasma

Human plasma contains a cell-adhesive protein that has a structure related to immunoglobulins. This protein was purified by affinity chromatography on an elastin-Sepharose column and by Mono Q anion-exchange chromatography. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis under non-reducing and reducing conditions revealed that this protein is a kind of immunoglobulin M (IgM). Antibodies against the mu chain and against the Fc region of IgM inhibited the adhesion of cells to this protein. Addition of the peptide GRGDS into media inhibited the adhesion, too. These results suggest that this protein is a special subset of IgM having a cell-binding sequence in the Fc region. We propose the name "cell-adhesive immunoglobulin M (CA-IgM)" for this protein. CA-IgM binds to alpha-elastin and laminin suggesting that it may play a role in the interaction between cells and the extracellular matrix.     

Immunoglobulin secretion by human splenic lymphocytes in vitro: the effects of antibodies to IgM and IgD.

The effects of F(ab')2 fragments of affinity-purified rabbit anti-human mu chain antibody (RaHmu) and rabbit anti-human delta chain antibody (RaHdelta) on spontaneous and mitogen-stimulated immunoglobulin (Ig) secretion by normal human spleen cells were studied. IgM and IgG secretion by human spleen cells cultured in vitro was measured by incubating the cells with 3H-amino acids precipitating the secreted labeled Ig with anti-Ig, and analyzing the precipitates by sodium dodecyl sulfate polyacrylamide gel electrophoresis. Both RaHmu and RaHdelta suppressed spontaneous and LPS-induced IgM and IgG secretion as well as PWM-stimulated IgG secretion. In different experiments, RaHmu and RaHdelta either suppressed or augmented PWM-induced IgM secretion. The anti-Ig induced augmentation of PWM-triggered IgM secretion was most apparent when spleen cells were cultured at lower cell densities or when lower concentrations of anti-Ig were employed. These date indicate that perturbation of B cell surface immunoglobulin receptors with specific anti-Ig antibody can alter markedly the ability of these cells to differentiate into antibody-secreting cells.     

The contribution of constant region domains to the binding of murine IgM to Fc mu receptors on T cells

IgM hybridoma constant region domain deletional mutants were used to investigate the domain requirements for binding of murine IgM to Fc mu receptors (Fc mu R) on normal murine T lymphocytes. Parental Sp 6:18 (mu, kappa; anti-trinitrophenyl) and its mutant proteins or their trinitrophenyl-antigen immune complexes were tested for their ability to inhibit the binding of pentameric IgM to Fc mu R on T lymphocytes. Inhibition was observed with ligands containing multiple copies of the third constant region domain. Inhibition did not occur with ligands missing the third constant region domain. In addition, a battery of rat monoclonal antibodies specific for individual murine IgM constant region domains was tested for the ability to inhibit the binding of pentameric murine IgM to Fc mu R on normal murine T lymphocytes. Total inhibition was observed with the antibodies directed to different epitopes located in C mu 3, but significant inhibition was not observed with antibodies directed to C mu 1, C mu 2, or C mu 4. Studies with domain deletional mutants and anti-domain antibodies have independently provided strong evidence that the C mu 3 domain plays a major role in the binding of IgM to Fc mu R on T lymphocytes and that C mu 1, C mu 2, and C mu 4 are not essential for binding. These studies have also provided evidence that valency and avidity influence the binding of IgM to T lymphocytes that express Fc mu R.     

IgM complex receptors on subpopulations of murine lymphocytes.

Murine lymphocytes from spleen, lymph node, and thymus were examined for IgM complex receptors. Lymphocytes from all three organs were found to bind SRBC sensitized with IgM from various sources including: primary anti-SRBC serum, murine and rabbit anti-Escherichia coli LPS sera, and a murine IgM myeloma (MOPC 104E). Rosette formation by lymphocytes with IgM-sensitized SRBC was inhibited by soluble antigen-IgM complexes but not by IgM or antigen alone. Rosette formation was also inhibited by human IgM (Fc)5mu but not by Fab mu. Antiserum and complement treatment of the cells and subsequent recovery of the viable cells by trypsinization, filtration, and washing revealed the IgM rosette-forming cell (RFC) in the thymus to be a T cell. Spleen on the other hand was found to contain both B and T cells capable of binding IgM sensitized SRBC. Removal of both B and T cells from spleen cell suspensions eliminated all IgM RFC. The IgM complex receptor was found to be trypsin insensitive. Anti-Ig column fractionation enriched IgM RFC in spleen and lymph node suspensions passed through the columns, whereas cells bearing surface Ig, IgG complex receptors, and C3 receptors were retained in the columns.     

Intracellular distribution and degradation of immunoglobulin G and immunoglobulin G fragments injected into HeLa cells

Intact rabbit immunoglobulin G molecules (IgGs) and their papain or pepsin fragments were radio-iodinated and injected into HeLa cells. Whole IgGs, Fab2, and Fc fragments were degraded with half-lives of 60- 90 h, whereas half-lives of Fab fragments were 110 h. These results indicate that proteolytic cleavage in the hinge region of the IgG molecule is not the rate-limiting step in its intracellular degradation. The hingeless human myeloma protein, Mcg, was degraded at the same rate as bulk human IgG, providing further evidence that the proteolytically susceptible hinge region is not important for intracellular degradation of IgG molecules. SDS acrylamide gel analysis of injected rabbit IgG molecules revealed that heavy and light chains were degraded at the same rate. Injected rabbit IgGs and rabbit IgG fragments were also examined on isoelectric focusing gels. Fab, Fab2, and Fc fragments were degraded without any correlation with respect to isoelectric point. Positively charged rabbit IgGs disappeared more rapidly than their negative counterparts, contrary to the trend reported for normal intracellular proteins. The isoelectric points of two mouse monoclonal antibodies were essentially unchanged after injection into HeLa cells, suggesting that the altered isoelectric profile observed for intact rabbit IgG resulted from degradation and not protein modification. The intracellular distributions of IgG fragments and intact rabbit IgG molecules were determined by autoradiography of thin sections through injected cells. Intact IgG molecules were excluded from HeLa nuclei whereas both Fab and Fc fragments readily entered them. Thus, for some proteins, entry into the nuclear compartment is determined primarily by size.     

Cross-linking of B lymphocyte Fc gamma receptors and membrane immunoglobulin inhibits anti-immunoglobulin-induced blastogenesis

The Fc portion of rabbit anti-mouse immunoglobulin (Ig) antibodies interferes with anti-Ig-induced B lymphocyte activation as measured by DNA synthesis on day 3 of culture or maturation to Ig-secreting cells in the presence of soluble helper factors on day 4 or 5. To investigate this Fc-dependent effect at an earlier stage in B cell activation, rabbit IgG anti-mouse mu-chain- or delta-chain-specific antibodies were compared with their F(ab')2 fragments for the ability to induce mouse B cells to undergo blast transformation, as defined by an increase in cell volume during the first 24 hr of culture. Both F(ab')2 anti-Ig reagents induce blast transformation, although F(ab')2 anti-mu antibodies induce a greater size change than F(ab')2 anti-delta antibodies. Whole anti-mu or anti-delta antibodies do not induce blast transformation; however, in the presence of a monoclonal anti-mouse Fc gamma receptor antibody that blocks IgG binding to Fc gamma receptors (Fc gamma R), whole anti-mu or anti-delta antibodies induce blast transformation as well as their F(ab')2 fragments. Because the anti-Fc gamma R antibody alone has no effect on blast transformation, it appears that the simultaneous binding of membrane IgM (or IgD) and Fc gamma R by whole anti-Ig antibodies prevents this early event in membrane Ig-induced B cell activation.     

Enzymic degradation of the Fc fragment of rabbit immunoglobulin IgG

The digestion of the Fc fragment of rabbit immunoglobulin IgG by several proteolytic enzymes was investigated by using gel filtration and starch-gel electrophoresis in 8m-urea-formate as criteria of the extent of degradation. Though fragment Fc and mildly reduced fragment Fc proved resistant to tryptic hydrolysis, papain and pepsin cleaved the fragment at acidic pH values and appeared to give rise to a similar spectrum of products. A (limit) peptide comprising the C-terminal 113 residues of the heavy chain was isolated and identified from the pepsin-digest products of fragment Fc. The products of proteolytic digestion of fragment Fc were no longer able to inhibit passive cutaneous anaphylaxis by rabbit anti-(bovine serum albumin) or demonstrate reversed passive cutaneous anaphylaxis in the guinea pig. Nor were they able to inhibit the intestinal absorption of heterologous immunoglobulin IgG in the young mouse. These studies imply that the site or sites responsible for these biological properties of intact fragment Fc reside in the N-terminal 30-40% of the fragment.     

Immunoglobulin synthesis and gene rearrangements in lymphoid cells transformed by replication-competent Rauscher murine leukemia virus: transformation of B cells at various stages of differentiation

Lymphoid cells transformed by Rauscher murine leukemia virus (R-MuLV) belonged to the B cell lineages. One group of cells exhibited Fc receptors but completely lacked immunoglobulin mu heavy and kappa light chains. The majority of the cells resemble pre-B type. They displayed mu chains but kappa chains were completely absent. Very rarely certain cells synthesized both mu and kappa chains. Based on the presence of Fc receptors and IgM synthesis the cells transformed by R-MuLV belonged to three B cell developmental stages. These cells were tested for immunoglobulin gene rearrangements using JH and CK probes. DNA from cell lines without any detectable levels of IgM mu exhibited embryonic as well as rearranged JH genes, whereas cells expressing IgM possess, in addition, productive and non-productive light chain gene rearrangements. The most terminally differentiated cell possesses JH and CK rearrangement associated with the synthesis of mu and kappa chains. Presumably the cells with rearranged JH and CK genes without immunoglobulin synthesis represent a developmental transition. We conclude that cells transformed by R-MuLV belonged to five step-wise compartments of B cell development. Our findings implicate definite sequential events of immunoglobulin gene rearrangement and expression during B cell development.