Catabolism and biologic properties of two species of rat IgG2a Fc fragments.

Prolonged papain digestion of rat IgG2a has recently been shown to yield two species of Fc fragments, termed Fc(I) AND Fc(II). The results of structural studies indicated that Fc(II) fragment was 15 to 20% smaller than Fc(I), probably secondary to loss of a carboxy-terminal peptide. The effects of these structural laterations on the catabolism and biologic properties of the Fc fragments were determined. The results of catabolic experiments indicated that after injection into normal rats Fc(I) fragments were retained in the circulation and slowly catabolized whereas Fc(II) fragments rapidly underwent filtration in the kidneys. In nephrectomized rats, however, both Fc(I) and Fc(II) fragments possessed identical slow rates of catabolism, as determined by serum disappearance and whole body catabolic experiments. Fragment pFc, corresponding to Cgamma3 domain, was different from either of the Fc fragments in exhibiting rapid rates of catabolism in both normal and nephrectomized rats. Fc(I) was more active in complement fixation and in adherence to the Fc receptor on monocytes in comparison with Fc(II). These results support the conclusion that catabolism of Fc and maintenance in circulation are separate processes influenced by different structures in the Fc fragment. The catabolism of Fc is controlled by structures in the Cgamma2 domain. This process probably is not related either to complement fixation or to adherence to the Fc receptor on monocytes. Some correlations between the structure and biologic properties of these Fc fragments are discussed.     

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.     

Physiochemical characterization of proteolytic cleavage fragments of bovine colostral immunoglobulin G1 (IgG1).

Normal bovine colostral immunoglobulin G1 was subjected to enzymic digestion (pepsin, papain and trypsin) and the resulting fragments separated by a combination of molecularsieve and phosphocellulose chromatography.Fragments F(ab')2 derived from peptic digestion, fragment Fab from papain digestion and fragment Fab(t) from tryptic digestion showed complete antigenic identity with each other. Although fragment F(ab')2 (peptic digestion) had a sedimentation coefficient (S2o,w) of 5.3S, those for fragments Fab' (peptic digestion), Fab (papain digestion) and Fab(t) (tryptic digestion) were found to be 3.9S, 3.7S and 3.7S respectively. The mol.wts. calculated for the various fragments from the sedimentation equilibrium data were: F(ab')2, 104000 +/-200; Fab', 51900+/-340; Fab, 50900+/-230; Fab(t) 50900+/-300. Fragment Fc' (peptic digestion) had an S20,w of 3.2S and a mol. wt. of 42900+/-650; fragment Fc (papain digestion) had an SI0,w of 3.7S and a mol.wt. of 50800+/-300; fragment Fc(t) had an S20,w of 3.7S and a mol.wt. of 50800+/-300; fragment Fc(t) had an S20,w of 3.7S and a mol.wt. of 50800+/-450.     

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.     

Production of humanized Fab fragment against human high affinity IgE receptor in Pichia pastoris

Binding of allergen-IgE complexes to the high affinity IgE receptor (Fc epsilonRI) on mast cells and basophils leads to the release of various mediaters such as histamine. Fab fragments prepared by the papain digestion of humanized antibody against human Fc epsilonRI inhibited the release of histamine from human basophils. Here we established an expression system to directly produce Fab fragments of the humanized anti-human Fc epsilonRI antibody in methylotropic yeast, P. pastoris. Fab fragments were efficiently secreted into the medium at a concentration of 10-40 mg/L using a signal sequence from the P. pastoris phosphatase gene. They were consisted of disulfide-linked light and heavy chains correctly starting from the first amino acid residues by proper cleavage of the signal peptides. The obtained Fab fragments inhibited the binding between IgE and Fc epsilonRI as efficiently as the counterpart prepared by papain digestion of the whole antibody.     

Production of Humanized Fab Fragment against Human High Affinity IgE Receptor in Pichia pastoris

Binding of allergen-IgE complexes to the high affinity IgE receptor (FcεRI) on mast cells and basophils leads to the release of various mediaters such as histamine. Fab fragments prepared by the papain digestion of humanized antibody against human FcεRI inhibited the release of histamine from human basophils. Here we established an expression system to directly produce Fab fragments of the humanized anti-human FcεRI antibody in methylotropic yeast, P. pastoris. Fab fragments were efficiently secreted into the medium at a concentration of 10-40 mg/L using a signal sequence from the P. pastoris phosphatase gene. They were consisted of disulfide-linked light and heavy chains correctly starting from the first amino acid residues by proper cleavage of the signal peptides. The obtained Fab fragments inhibited the binding between IgE and FcεRI as efficiently as the counterpart prepared by papain digestion of the whole antibody.     

Induction of IL-1 secretion from human monocytes by Fc region subfragments of human IgG1

Peripheral blood-derived human monocytes and the murine P388D1-monocytes-like cell line are induced to secrete IL-1 when stimulated with Fc region but not F(ab) region subfragments obtained from the cleavage of human IgG1 with papain or pepsin. The portion of the Fc region of IgG1 responsible for stimulation of IL-1 secretion appears to be located within the C gamma 3 domain of the molecule. This hypothesis is supported by the observation that the biologically active pepsin-derived pFc' subfragment is located within the C gamma 3 domain and the long-term papain digests containing predominately Fc' are also active. In contrast, short term papain digests containing mostly intact Fc fragments were found to be unable to induce IL-1 secretion.     

Cleavage of human C5 by trypsin: characterization of the digestion products by gel electrophoresis.

Human C5 is composed of two nonidentical polypeptide chains, alpha and beta (m.w. 130,000 and 80,000, respectively) linked together by disulfide bonds and noncovalent forces. Cleavage of C5 by trypsin fragments with increased anodic mobilities. Limited digestion of C5 by trypsin (substrate to enzyme ratio 10:1 w/w at 37 degrees C for 1 min) resulted in the release of a small terminal alpha-chain peptide (alpha1, m.w. 15,000) probably analogous to C5a, from a large fragment, C5b (m.w. 195,000) composed of an intact beta-chain disulfide linked to an alpha-chain that has a lower m.w. (alpha' 115,000). Further digestion (37 degrees C, 5 min) resulted in cleavage of the alpha-chain at multiple sites with the production of three peptides from the alpha'-chain (alpha2I, 23,500; alpha2II 15,700 and alpha2III 10,200) and a residual fragment, C5c (m.w. 144,000). The alpha1 and alpha2 peptides are not covalently linked to the beta-chain nor to one another. The C5c fragment on the other hand is composed of small peptides of the alpha'c chain (alpha3 14,000; alpha4I 9,000; ALPHA 4II 11,000; alpha 5 23,000 to 30,000) which are linked to the beta-chain and also probably to one another by covalent bonds. Secondary cleavage occurred upon prolonged digestion with trypsin (37 degrees C, 20 min), and this resulted in the progressive erosion of the alpha'c peptides and the conversion of C5c to smaller C5c-like species.     

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.     

抗人IgG Fc片段及Fab段单抗的鉴定及应用

本实验采用木瓜酶水解,SPA柱亲合层析等手段得到人IgGFc段及Fab段,以Sigma抗人IgGfFc段和抗人IgG Fab段单抗为标准品,鉴定了细胞库中抗人IgG系列的部分细胞株,得到特异性分泌抗人IgG Fc段和抗人IgG Fab段单抗的细胞各一株。 在上述实验基础上,用抗人IgG Fc及抗人IgG Fab单抗分别制备了Sepharose4B亲合层析柱,提纯了酶解人IgG Fc、Fab片段,经ELISA法鉴定,相互之间无交叉反应。同时用此方法制备了人抗HBe Fab片段,并将该片段进行了过氧化物酶标记,用来配制HBe ELISA诊断盒,证明其生物活性未受影响,而且消除了类风湿因子引起的HBe Ag假阳性现象。因抗HBe单抗来源困难,如采用HBe多抗制备ELISA试剂,本法将是提高质量的一个好方法。     

Purification and some properties of streptococcal protein G, a novel IgG-binding reagent

Protein G, a bacterial cell wall protein with affinity for immunoglobulin G (IgG), has been isolated from a human group G streptococcal strain (G148). Bacterial surface proteins were solubilized by enzymatic digestion with papain. Protein G was isolated by sequential use of ion-exchange chromatography on DEAE-cellulose, gel filtration on Sephadex G-100, and affinity chromatography on Sepharose 4B-coupled IgG. The presence of protein G in various pools and fractions during the isolation was followed by their ability to inhibit the binding of radio-labeled IgG to G148 bacteria. A highly purified protein G was obtained. On polyacrylamide gel electrophoresis in sodium dodecyl sulfate, the apparent m.w. was 30,000, and on agarose gel electrophoresis the purified protein gave rise to a single band in the alpha 1-region. Protein G was found to bind all human IgG subclasses and also rabbit, mouse, and goat IgG. On the IgG molecule, the Fc part appears mainly responsible for the interaction with protein G, although a low degree interaction was also recorded for Fab fragments. IgM, IgA, and IgD, however, showed no binding to protein G. This novel IgG-binding reagent promises to be of theoretical and practical interest in immunologic research.     

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.     

Disulfide bonding of secretory component to a single monomer subunit in human secretory IgA.

The arrangement of disulfide bonds joining secretory component (SC) to the alpha chains in secretory IgA was studied by determining the molecular size of the principal fragments resulting from CNBr digestion of secretory dimeric Fc fragments from IgA (Fc)2alpha fragments). In vitro complexes formed by incubating 125I-free SC and myeloma 131I-(Fc)2alpha fragments were isolated by gel filtration and subsequently digested with cyanogen bromide. The CNBr digests of SC-(Fc)2alpha fragments were analyzed by gel filtration in 5 M guanidine. Two principal fragments were obtained, one containing a monomeric Fc fragment from IgA (Fcalpha) associated with SC (m.w. congruent to 110,000) and a second containing the second Fcalpha monomer (m.w. congruent to 50,000) from the dimeric SC-(Fc)2alpha. Similar results were obtained when secretory (Fc)2alpha fragments isolated from native secretory IgA dimer were subjected to CNBr digestion. The data indicate that SC is disulfide bonded to a single monomer subunit in secretory IgA dimer.     

Extended flexible linker structures in the complement chimaeric conjugate CR2-Ig by scattering, analytical ultracentrifugation and constrained modelling: implications for function and therapy

Complement receptor 2 (CR2; CD21) is a membrane-bound regulator of complement activation, being comprised of 15 or 16 short complement repeat (SCR) domains. A recombinant glycosylated human CR2 SCR 1-2 domain pair was engineered with the Fc fragment of a mouse IgG1 antibody to create a chimaera CR2-Ig containing the major ligand binding domains. Such a chimaera has therapeutic potential as a complement inhibitor or immune modulator. X-ray and neutron scattering and analytical ultracentrifugation identified its domain structure in solution, and provided a comparison with controversial folded-back crystal structures for deglycosylated CR2 SCR 1-2. The radius of gyration R(G) of CR2-Ig was determined to be 5.39(+/-0.14) nm and 5.29(+/-0.01) nm by X-ray and neutron scattering, respectively. The maximum dimension of CR2-Ig was determined to be 17 nm. The molecular mass of CR2-Ig ranged between 101,000 Da and 107,000 Da as determined by neutron scattering and sedimentation equilibrium, in good agreement with the sequence-derived value of 106,600 Da. Sedimentation velocity gave a sedimentation coefficient of 4.49(+/-0.11) S. Stereochemically complete models for CR2-Ig were constructed from crystal structures for the CR2 SCR 1-2 and mouse IgG1 Fc fragments. The two SCR domains and the Fc fragment were joined by randomised conformational peptides. The analysis of 35,000 possible CR2-Ig models showed that only those models in which the two SCR domains were arranged in an open V-shape in random orientations about the Fc fragment accounted for the scattering and sedimentation data. It was not possible to define one single conformational family of Fab-like fragment relative to the Fc fragment. This flexibility is attributed to the relatively long linker sequence and the absence of the antibody light chain from CR2-Ig. The modelling also confirmed that the structure of CR2 SCR 1-2 is more extended in solution than in its crystal structure.     

Interaction of rabbit IgG with anti-IgG: localization of epitopes and absence of immunoreactivity of the pFc'-fragment]

To localize essential epitopes of rabbit IgG, a series of proteolytic IgG fragments obtained by papain (Fab, Fc) or pepsin (pFc', F(ab')2) proteolysis have been prepared and their interaction with sheep antibodies against rabbit IgG has been studied. The data obtained suggest that essential immunoreactive epitopes of rabbit IgG are located in the CH2 domain and hinge region. This finding is in line with the results obtained by computing the antigenic sites of immunoglobulins. However, the deviation from the computed antigenic structure was deduced from the complete lack of immunoreactivity of the pFc fragment, it being a dimer of the terminal CH3 domain of the Fc fragment. The hinge region comparable in size with the dimensions of the epitope reveals high affinity binding to anti-IgG, thus testifying to the localization of the expressed epitope or its essential part in the hinge region. Proteolytic cleavage of this region leads to a significant decrease in the binding of the IgG fragment to anti-IgG. In addition to the CH2 domain and hinge region, a relatively low interaction of the antigen-binding antibody fragments with anti-IgG was found.     

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.     

Fragments produced by digestion of human immunoglobulin G subclasses with pepsin in urea.

It was previously shown that digestion of human IgG1/kappa myeloma proteins with pepsin in the presence of 8 M-urea produces fragments which differ from other proteolytic fragments of IgG, including those produced by peptic digestion in aqueous buffers. The two large urea/pepsin fragments each consist of three peptides, and together account for all of the constant region of the light chains and most of the constant region of the heavy chains. Myeloma proteins of subclasses IgG2, IgG3 and IgG4 with kappa light chains were digested with pepsin in 8 M-urea, and the resulting fragments compared with those produced from IgG1/kappa proteins. Gel filtration, starch- and polyacrylamide-gel electrophoresis and sequence analysis have shown that the peptides from each subclass are analogous with those from IgG1. A brief investigation of the products of urea/pepsin digestion of myeloma proteins with lambda light chains has shown that in these proteins light-chain cleavage occurs at residue leucine-182, instead of or as well as at residue 117, where cleavage takes place in kappa chains. Comparison of sequences around sites of urea/pepsin cleavage has shown that pepsin has quite restricted specificity under these conditions.     

Intestinal surface peptide hydrolases: identification and characterization of three enzymes from rat brush border.

Peptide hydrolases were solubilized from rat small intestinal brush border by papain and separated by Sephadex G-200 chromatography, velocity gradient ultracentrifugation and polyacrylamide disc electrophoresis and designated according to approximate molecular size from sedimentation studies. Peptidases I (apparent Mr 230 000) and II (apparent Mr 160 000) are oligopeptidases with maximum specificity for tripeptides with identical pH optima (7.5) and similar apparent Km with L-Leu-Gly (I, 0.60 MM; II, 0.76 mM). L-Leucyl-beta-naphthylamide is a competitive inhibitor of both enzymes. Concentration of peptidase II produced partial conversion to peptidase I on polyacrylamide disc electrophoresis. The third peptide hydrolase (III, Mr 120 000) is a dipeptidase with pH optimum 8.5 and apparent Km for L-Leu-Gly of 0.65 mM. These peptide hydrolases were inhibited appreciably (37-59%) by 0.2 M glycine/NaOH, Tris - HCl or Tris - glycine buffers. EDTA (5 mM) completely inhibited these enzymes but all activity was restored by dialysis against buffer without divalent ions. Subsequent addition of Mg2+, Mn2+, Co2+ or Zn2+ (1-2 mM) inhibited peptidases I and II variably (4-81%) depending upon the substrate and buffer used. In contrast peptidase III was activated slightly by metal ions (5-20%). These peptide hydrolases are strategically located at the intestinal lumen-cell interface and possess biochemical characteristics making them ideally suited to play a pivotal role in the final stage of protein digestion.     

Expression and characterization of a DNase I-Fc fusion enzyme

Recombinant human deoxyribonuclease I (DNase I) is an important clinical agent that is inhaled into the airways where it degrades DNA to lower molecular weight fragments, thus reducing the viscoelasticity of sputum and improving the lung function of cystic fibrosis patients. To investigate DNases with potentially improved properties, we constructed a molecular fusion of human DNase I with the hinge and Fc region of human IgG1 heavy chain, creating a DNase I-Fc fusion protein. Infection of Sf9 insect cells with recombinant baculovirus resulted in the expression and secretion of the DNase I-Fc fusion protein. The fusion protein was purified from the culture medium using protein A affinity chromatography followed by desalting by gel filtration and was characterized by amino-terminal sequence, amino acid composition, and a variety of enzyme-linked immunosorbent assays (ELISA) and activity assays. The purified fusion contains DNase I, as determined by a DNase I ELISA and an actin-binding ELISA, and an intact antibody Fc region, which was quantified by an Fc ELISA, in a 2:1 stoichiometric ratio, respectively. The dimeric DNase I-Fc fusion was functionally active in enzymatic DNA digestion assays, albeit about 10-fold less than monomeric DNase I. Cleavage of the DNase I-Fc fusion by papain resulted in a specific activity comparable to the monomeric enzyme. Salt was inhibitory for wild type monomeric DNase I but actually enhanced the activity of the dimeric DNase I-Fc fusion. The DNase I-Fc fusion protein was also less Ca2+-dependent than DNase I itself. These results are consistent with a higher affinity of the dimeric fusion protein to DNA than monomeric DNase I. The engineered DNase I-Fc fusion protein described herein has properties that may have clinical benefits.     

Isolation of an Fcgamma-binding protein from the cell membrane of a macrophage-like cell line (P388D1) after detergent solubilization

Lactoperoxidase-catalyzed iodination, NP-40 lysis, and subsequent affinity chromatography on IgG-Sepharose were used in an attempt to define some of the molecular properties of the Fc receptor of P388D1, a macrophage-like mouse tumor line. Radioiodinated material retained on columns of Sepharose coupled either to monomeric mouse IgG2a or monomeric human IgG1 appeared on SDS polyacrylamide gel electrophoresis to contain principally three labeled components, a major band of about 57,000 m.w. and two minor bands of 28,000 and 24,000 m.w. The mobilities of these components changed little on reduction, which suggested that they represented single polypeptide chains, An identical pattern was obtained with Sepharose-linked Fc fragments of human IgG1, but neither Fab fragments of IgG1 nor IgM appeared to bind these components. Since the specificity of binding to the immobilized proteins is the same as that observed in vivo, it is postulated that these proteins represent either all or some portion of the P388D1 Fc receptor.