Separation of three class II antigens from a homozygous human B cell line

Three class II molecules were isolated from a homozygous DRw6 human B lymphoblastoid cell line using the monoclonal antibodies L243 (L203), L227, LKT 111, and Genox 3.53. Two of the antigens appeared to employ the same heavy chain but expressed different light chains. The two light chains were separated after denaturation using L227 and LKT 111. One or both of these two molecules carried the DRw6 and MT2 determinants. The third class II antigen expressed the DC1 determinant. It was composed of a heavy and light chain different from the DR-like antigen subunits. The antibodies L243, L227, and LKT 111 did not preclear the cell lysate of the DC1 antigen recognized by Genox 3.53. However, a xenoanti-DR serum immunoprecipitated both the DR-like and the DC1 antigens. Thus, in total, one cell line can express at least two class II heavy chains and three class II light chains. This observation was not unique to this cell line.     

Paired indirect immunoenzyme staining with primary antibodies from the same species. Application of horseradish peroxidase and alkaline phosphatase as sequential labels

Summary Paired indirect immunoenzyme staining based on primary antisera from the same species was performed sequentially without intermediate antibody elution. The first antigen was labelled brown by an immunoperoxidase procedure (either the two-stage indirect method, the unlabelled antibody peroxidase-antiperoxidase method, or the avidin-biotin bridge method using diaminobenzidine (DAB) and hydrogen peroxide as the substrates. The second antigen was labelled blue by applying a two-stage indirect immuno-alkaline phosphatase procedure using naphthol AS phosphate and Fast Blue BB salt as the substrate. In this way, polyclonal mucosal immunocytes were revealed in distinctly contrasting colours when stained for and light chains. Glucagon and somatostatin (D) cells in human pancreatic islets, and gastrin and D cells in human gastric antral glands, were likewise clearly differentiated. Conversely, a mixed colour appeared in some immunocytes after staining for and chains. However, unbalanced colour mixing was sometimes difficult to interpret, and additional experiments demonstrated that unwanted interactions could take place between the two sequences of reagents if the density of the DAB deposits was insufficient. These pitfalls were incompatible with unequivocal double staining in the same cell. Nevertheless, paired staining could be conveniently applied with the described procedures when prior knowledge had established that the antigens in question were located in separate cells.     

Separation of four class II molecules from DR2 and DRw6 homozygous B lymphoid cell lines

Four human class 11 molecules, one FA, one DC1, and two DR-like molecules, were isolated from DR2 and DRw6 homozygous cell lines by means of a variety of monoclonal antibodies and were compared with each other by two-dimensional (2-D) gel electrophoresis. Anti-DR2 or anti-DR3 + 5 + w6 sera immunoprecipitated two distinct light chains (L1 and L2) and one heavy chain (H1) from a DR2 or DRw6 homozygous cell line, respectively. One or both of these two class II molecules were also immunoprecipitated by DR-specific monoclonal antibodies and were considered to constitute a DR family of molecules. Three DC1-specific monoclonal antibodies, SDR4.1, Tu22, and PLM5, immunoprecipitated a set of heavy (H2) and light (L3) chains distinct from those of two DR-like molecules. The heavy chains of the DC1 antigens from DR2 and DRw6 cell lines were indistinguishable, whereas the light chains were structurally distinct from each other. A fourth molecule, FA, was identified by a novel monoclonal antibody and was also detected by two additional antibodies, Tu39 and SG171, that blocked the SB-specific T-cell proliferative response. The FA light chain (L4) was distinct from those of the former three antigens on both cell lines, whereas the FA heavy chain was indistinguishable from the DC1 heavy chain (H2) in this 2-D gel analysis. Thus, four light chains and two heavy chains were isolated from both DR2 and DRw6 homozygous cell lines. A possible gene-antigen organization of the DC-like antigens was also discussed.     

Direct immunoenzyme double staining applicable for monoclonal antibodies

Summary A novel method for immunoenzymatic double staining was developed, using primary antibodies directly labeled with either horseradish peroxidase or alkaline phosphatase. The enzyme-antibody conjugates were applied simultaneously on sections of human tonsil. Intracytoplasmic antigens like immunoglobulins and light chains could easily be detected simultaneously in the same tissue section. With antibodies against cell surface antigens like IgM and T cell antigens areas containing B and T cells could be clearly distinghuished. This method opens the possibility to perform double staining with two monoclonal antibodies.     

Production of an anti-mouse MHC class II monoclonal antibody with biological activity in transgenic tobacco

To produce a monoclonal antibody specific to a mouse major histocompatibility complex (MHC) class II protein, we synthesized the complementary DNAs for the heavy and light chains of a monoclonal antibody by PCR amplification. These cDNAs were then introduced separately into tobacco plant cells. After performing Northern blot analysis to confirm the expression of each of the chain genes in the transformed plants, we constructed transgenic plants expressing both the heavy and light chains by sexual crossing. The expression of the heavy and light chain genes in the sexually crossed plant was confirmed by Northern and Western blot analyses, respectively. Fluorocytometric analysis showed that the plant-derived antibodies, which we purified using a protein G affinity column, bound specifically to target cells that expressed the cognate MHC class II molecules on their cell surfaces. The results of this study demonstrate that a monoclonal antibody against mouse MHC class II proteins can be expressed in transgenic plants. They also show the specific binding activity of plant-derived antibodies to cognate antigens.     

Turnover rates at regulatory phosphorylation sites on myosin II in endothelial cells

Assembly and motor activity of non-muscle myosin II can be regulated by phosphorylation. Because myosin II-containing structures undergo continuous assembly, disassembly, and remodeling in living cells, especially during cell migration, myosin II should undergo frequent phosphorylation and dephosphorylation. This study examines the turnover of phosphate on myosin II in stationary and migrating endothelial cells. Cultured bovine aortic endothelial cells were metabolically labeled with (32)P-phosphate, and the incorporation of phosphate into myosin II was assessed by quantitative phosphor imaging of electrophoretic gels of myosin II immunoadsorbed from cell lysates. Likewise, phosphate turnover was measured upon chasing the (32)P with unlabeled phosphate. Phosphate incorporated very slowly into heavy chains, taking >8 h to plateau, and turned over at 相似文献   

B cells

B cells are an important component of adaptive immunity. They produce and secrete millions of different antibody molecules, each of which recognizes a different (foreign) antigen. The fact that humans express a very large repertoire of antibodies is due to the complex mechanism of V(D)J recombination of immunoglobulin (Ig) genes as well as other processes including somatic hypermutation, gene conversion and class switching. The B cell receptor (BCR) is an integral membrane protein complex that is composed of two Ig heavy chains, two Ig light chains and two heterodimers of Igalpha and Igbeta. To eliminate foreign antigens, B cells cooperate with other cells of the immune system including macrophages, dendritic cells and T cells. B cell development is a tightly controlled process in which over 75% of the developing cells become apoptotic because of inappropriate immunoglobulin gene rearrangements or recognition of self antigens by Igs. Hence, the majority of B cell-associated disorders are caused by the incorrect function of genes/proteins involved in B cell development.     

Distinct subpopulations of IgG memory B cells respond to different molecular forms of the same hapten.

Spleen cells from mice primed with the thymus-dependent antigen trinitrophenyl keyhold limpet hemocyanin several months earlier can be cultured in vitro to give vigorous IgG antihapten PFC responses to thymus-dependent (TD) and thymus-independent (TI) forms of the same hapten. Here we show that the IgG memory precursors that respond to these two forms of the hapten constitute functionally distinct subpopulations. We have designated these subpopulations as B1gamma and B2gamma to represent secondary precursor cells responding to TI and TD antigens, respectively. Three types of evidence for these subpopulations are presented: 1) In vitro secondary IgG responses to TD and TI forms of the TNP hapten are additive when both forms are added to the same culture. 2) The precursor frequencies for the TD and TI antigens are additive, but addition is not observed between two TD or two TI antigens. 3) Each population can be selectively eliminated by BUdR and light treatment without affecting the other population. The ontogenetic relationships between these subpopulations are discussed in relation to all presently proposed subpopulations B1mu, B2mu, B1gamma, and B2gamma.     

Immunoglobulin G biosynthesis in a human lymphoblastoid cell line. Differences between membrane-bound and secretory forms of gamma chains

The cultured human B lymphoblastoid cell line Maja synthesises two forms of the gamma heavy chain of immunoglobulin G (IgG) that differ in apparent molecular weight. The lower-molecular-weight form is secreted into the culture medium as a water-soluble product in association with light chains and comigrates on dodecyl sulphate polyacrylamide gels with serum IgG gamma chains. The higher-molecular-weight form is not detected in culture supernatants. In distinction to the secreted form, the higher-molecular-weight form is labelled by a lipophilic, photoactivatable nitrene and is inserted asymmetrically in a transmembrane orientation into rough microsomes. It is concluded that Maja cells synthesise secretory (gamma s) and membrane-associated (gamma m) forms of IgG heavy chains. Both forms of the gamma heavy chain are glycosylated, and can contain one or two asparagine-linked glycan units. The gamma m and gamma s heavy chains differ by about 10 000 in apparent molecular weight. This difference resides exclusively in the polypeptide moiety. Although part of the difference comprises a transmembrane peptide and a cytoplasmic tail of apparent molecular weight about 2000 for gamma m chains, a substantial segment of unique peptide is most probably present on the non-cytoplasmic side of the bilayer. The ionophore monensin inhibits the intracellular transport of gamma s and gamma m chains at a stage when they are sensitive to the enzyme endo-beta-N-acetylglucosaminidase H. In contrast, HLA-A and HLA-B antigens reach a stage at which they are insensitive to this enzyme in the presence of monensin, although their surface expression is inhibited by the ionophore. The implications of these results for the intracellular transport of membrane-associated glycoproteins are discussed.     

The MT3 specificity resides on a novel human class II antigen distinct from the HLA-DR antigen and DC-like antigen

The MT3 specificity is closely associated with the HLA-DR4, DR7, and DRw9, and is a supertypic specificity. To determine whether the MT3 specificity resides on a novel class II antigen, the MT3 antigen, DR antigen and the DC-like antigen from the DR4-, DR7- and DRw9-homozygous B lymphoid cell lines were identified and compared with one another by two-dimensional gel electrophoresis using alloantisera. The analysis revealed that each of the three antigens exists as a structurally distinct class II antigen in each cell line. The light chains of the MT3, DR and DC-like antigens are different in charge from one another. The molecular weight of the heavy chains of the MT3 and DR antigens is higher than that of the DC-like antigen. On the other hand, no electrophoretic differences are observed between the heavy chains of the MT3 and DR antigens. These results strongly suggest that the MT3 specificity resides on a light chain of a novel class II antigen distinct from the DR antigen and the DC-like antigen. These observations also support our previous proposition that the MT3 antigen belongs to the fourth group of the human class II antigens.     

The gamma and epsilon subunits of the CD3 complex inhibit pre-Golgi degradation of newly synthesized T cell antigen receptors

The T cell receptor for antigen (TCR) is composed of six different transmembrane proteins. T cells carefully control the intracellular transport of the receptor and allow only complete receptors to reach the plasma membrane. In an attempt to understand how T cells regulate this process, we used c-DNA transfection and subunit-specific antibodies to follow the intracellular transport of five subunits (alpha beta gamma delta epsilon) of the receptor. In particular, we assessed the intracellular stability of each chain. Our results showed that the chains were markedly different in their susceptibility to intracellular degradation. TCR alpha and beta and CD3 delta were degraded rapidly, whereas CD3 gamma and epsilon were stable. An analysis of the N-linked oligosaccharides of the glycoprotein subunits suggested that the chains were unable to reach the medial Golgi during the metabolic chase. This was supported by immunofluorescence micrographs that showed both the stable CD3 gamma and unstable CD3 delta chain localized in the endoplasmic reticulum. To study the effects of subunit associations on intracellular transport we used cotransfection to reconstitute precise combinations of subunits. Associations between stable and unstable subunits expressed in the same cell led to the formation of stable complexes. These complexes were retained in or close to the endoplasmic reticulum. The results suggested that the intracellular transport of the T cell receptor could be regulated by two mechanisms. The TCR alpha and beta and CD3 delta subunits were degraded rapidly and as a consequence failed to reach the plasma membrane. CD3 gamma or epsilon were stable but were retained inside the cell. The results also demonstrated that there was an interplay between the two pathways such that the CD3 gamma and epsilon subunits were able to protect labile chains from rapid intracellular degradation. In this way, they could seed subunit assembly in or close to the endoplasmic reticulum and allow a stable receptor to form before its transport to the plasma membrane.     

Separation and comparison of human TL-like antigens and HLA(A,B, C) antigens expressed on Cultured T cells

Beta₂-microglobulin-bound T-cell membrane components containing both human TL-like antigens and HLA(A, B, C) antigens were partially purified from Renex 30-solubilized membrane material of cells of a human T-cell-type leukemia cell line, HPB-ALL. The radioiodinated preparation was subjected to limited papain digestion; the HLA(A, B, C) antigens split, whereas a large portion of the human TL-like antigens remained intact. The antigen molecules were recovered by lentil-lectin affinity chromatography and separated by gel filtration on the basis of the induced difference in molecular size. The human TL-like-antigen preparation thus obtained was essentially free of HLA(A, B, C) antigens. The human TL-like antigens were immunospecifically precipitated and the component polypeptide, heavy and light, chains were separated by acid dissociation followed by gel filtration. The component chains were compared with the corresponding chains of HLA(A, B, C) antigens obtained similarly from the same HPB-ALL cells with respect to their fragmentation patterns on chemical or enzymatic cleavage. The results provided convincing evidence for the identity of the light chains of human TL-like antigens and HLA(A, B, C) antigens, and also evidence suggesting the presence of substantial differences in the fundamental structure of the heavy chains of human TL-like antigens and HLA(A, B, C) antigens.A unit of the New York State Department of Health.     

The binding of haptens by the polypeptide chains of rabbit antibody molecules

1. The binding of haptens by the polypeptide chains derived from two rabbit immunoglobulin G antibodies was examined by gel chromatography and equilibrium dialysis. 2. The gamma chains were examined in a dilute sodium acetate buffer, pH5.4, in which they exist as a monodisperse solution of dimers; aggregation of the protein promoted by some haptens had to be avoided. These chains exhibited variable extents of binding, reflecting the specificities of the parent antibody molecules, usually with only small increments above the binding by gamma chains from normal immunoglobulin G. 3. The light chains existed as an interconverting mixture of monomers and dimers in all buffers of near neutral pH that were examined. They bound small amounts of hapten, again broadly reflecting the specificities of the parent antibody molecules. 4. For both the gamma and light chains the dimeric state appeared necessary for appreciable binding of hapten. Apparently in each case the partners in the dimer interact in a manner analogous to the gamma chain-light chain interaction in the parent antibody molecule, to give a site analogous to the antibody site. This implies that the binding of antigens by isolated chains has a large fortuitous element, providing no reliable indication of their contributions to the original antibody sites.     

HLA-DR antigens induce proliferation and cytotoxicity of T cells against haptenated (TNP and FITC) self structures

Antisera directed against the heavy, the light, or reactive against the complex of both chains of HLA-DR antigens strongly inhibited proliferation of T cells induced by TNP- or FITC-labeled autologous cells when added at initiation of the cultures, but not 72 h later. T cells from cultures treated with the anti-DR sera were unresponsive to interleukin-2 (IL-2). Nonetheless, the anti-DR sera did not inhibit proliferation of T cells that had already acquired sensitivity to IL-2. The DR antibodies abrogated the synthesis of IL-2 induced by both TNP- and FITC-conjugated autologous cells. Treatment of TNP- and FITC-labeled autologous cell cultures with the four different types of anti-DR sera significantly inhibited the induction of cytotoxic T cells. However, DR antibodies added at the effector phase of cytotoxicity assays did not inhibit the cytotoxic activity. Effector T cells from cultures treated with the anti-DR sera were unresponsive to IL-2 and addition of IL-2 to these cultures did not restore the cytotoxic activity. In contrast, effector T cells from cultures performed in the absence of the anti-DR sera proliferated to IL-2 stimulation and addition of IL-2 to these cultures significantly increased the generation of killer cells specific for hapten-labeled self structures. From these results we concluded the following: (1) Both the heavy and the light chains of DR antigens participate actively in the activation of T cells by rendering resting T cells sensitive to IL-2 and by inducing production of the growth factor in TNP- and FITC-conjugated autologous cell cultures. (2) The heavy and light chains of the DR antigens play an essential role in the induction of cytotoxic T cells specific for hapten-labeled self structures, most likely by enabling cytotoxic T cells to respond to IL-2 and by inducing the IL-2 producer T cells to synthesize the growth factor.     

Hypergastrinaemia, abomasal bacterial population densities and pH in sheep infected with Ostertagia circumcincta.

Serum gastrin and pepsinogen concentrations, food intake, abomasal pH and abomasal aerotolerant and anaerobic bacterial populations were measured in sheep infected with Ostertagia circumcincta to search for links between hypergastrinaemia, food intake and changes in the abomasal environment. Abomasal pH and serum gastrin and pepsinogen concentrations were elevated in each of five sheep infected via abomasal cannulae with 150000 exsheathed larval stage three, followed 11 days later by 100000 sheathed larvae given intraruminally. Unparasitised abomasa contained aerotolerant bacterial population densities of between 10(3) and 10(6) cells ml(-1) and these did not change significantly following parasitism. In contrast, anaerobic bacterial population densities increased markedly by about 10(4)-fold following parasitism. Anaerobic numbers changed rapidly when abomasal pH increased from 2.5 to 3.5. At pH 4 and above, anaerobic bacterial numbers approached levels expected in rumen contents but parameters other than pH did not relate to bacterial numbers. Brief periods when serum gastrin was lower than expected, coinciding with raised abomasal pH, were not explicable by increased bacterial numbers. Food intake, which decreased for a variable period from around Day 5 p.i., correlated poorly with serum gastrin concentration, suggesting hypergastrinaemia is not the sole cause of anorexia in parasitised animals. The survival of substantial numbers of rumen bacteria in the abomasum at only slightly raised pH may significantly lower the bacterial protein available to the sheep.     

Xenopus MHC class II molecules. I. Identification and structural characterization

Class II antigens from the Xenopus laevis MHC (f haplotype) were identified by using a rabbit antihuman class II beta-chain serum (anti-p29boost). This xenoantiserum inhibits bidirectional Xenopus MLR (but not PHA-stimulation), recognizes the same molecules as certain MHC-linked Xenopus alloantisera, and immunoprecipitates class II molecules from Xenopus cells consistent with the tissue distribution of mammalian class II molecules. The Xenopus class II molecules are composed of two different chains, both of which are 30 to 35kD transmembrane glycoproteins. The alpha-chains have some N-terminal sequence homology with mammalian class II alpha-chains (both I-E/DR and I-A/DC); the beta-chains are directly recognized by anti-p29boost and have a markedly increased SDS gel mobility under nonreducing conditions. During biosynthesis, they are noncovalently associated with a number of other chains, including ones at 25kD, 33kD, and 40 to 45kD. The alpha-chains bear three N-linked glycans (two Endo H insensitive in mature material) and the beta-chains bear two (one Endo H insensitive). Unlike most mammalian class II molecules, the deglycosylated beta-chains are significantly larger and more acidic than the alpha-chains.     

Possible involvement of the T4 molecule in T cell recognition of class II HLA antigens: evidence from studies of proliferative responses to SB antigens

The T4 molecule has been identified as a marker of human T cell differentiation, but the function of this molecule remains to be defined. We have investigated its possible functional involvement in T cell proliferative responses to class II HLA antigens encoded by the recently described SB locus. The responses of SB-primed cells (specific for each of four different SB antigens) were studied with the use of two proliferation-inducing stimuli, SB antigen or TCGF. The proliferative responses to both stimuli were found to be mediated by T4+, T8- cells. Monoclonal antibodies against some epitopes on the T4 molecule (OKT4A and OKT4B) substantially blocked antigen-stimulated proliferative responses; antibodies against other epitopes of the T4 molecule (OKT4, T4C, T4D) blocked less well. Inhibition of SB-specific proliferation by antibodies to the T4 molecule was maximal only when the antibodies were incubated with the responder cells before the addition of stimulator cells. Proliferative responses of SB-primed cells stimulated with TCGF alone were not inhibited by any of the OKT4-related antibodies, but were completely inhibited by the anti-Tac monoclonal antibody, which reacts with the TCGF receptor. These results lend further support for the hypothesis that the T4 molecule is involved in T cell recognition of and/or activation by class II HLA antigens. We suggest that 1) the T4 molecule binds a nonpolymorphic epitope on class II HLA molecules, and 2) this interaction may facilitate, but not be an obligate requirement for, T cell activation by class II antigens.     

Does a monospecific hybridoma always secrete homogeneous immunoglobulins?

The fusion of splenocytes (from mice immunized with the beta 2 subunit of E. coli tryptophan synthase) with myeloma cells which do not produce immunoglobulins gave rise to a clone secreting immunoglobulins with two distinct isotypes : gamma 1 and gamma 2b (Djavadi-Ohaniance et al. (1984) Biochemistry, 23, 97-104). Analysis of the immunoglobulins secreted by this clone indicates that these two isotypes are carried by two distinct heavy chains which are able to randomly associate to form hybrid molecules. In addition, two classes of light chains are able to randomly and to form heterologous associations with both the gamma 1 and gamma 2b heavy chains. Only the association between the gamma 2b heavy chains with one of the two classes of light chains leads to a combining site specific for the binding of the antigen beta 2.     

A double monoclonal IgG1 kappa and IgG2 kappa in a single myeloma patient. Variation in clonal products and therapeutic responses

Two electrophoretically homogeneous immunoglobulins were detected in the serum of a patient with multiple myeloma. The heavy chains were of different classes (gamma 1 and gamma 2). The light chains of both were kappa, but had different electrophoretic mobilities on polyacrylamide gels. Amino acid sequence analysis, carbohydrate determinations, and biosynthetic experiments indicated that the difference seen in their electrophoretic mobility was due to the glycosylation of one but not the other kappa-chain. The primary structure of both chains demonstrated that they both used a V kappa 1 and a J kappa 2 gene segment and the same C kappa allele, Km(1,2), and that both contained the same junctional three amino acid deletion. However, they varied by 19 amino acids in the first 94 amino terminal residues encoded for by the V kappa gene, with some of the substitutions requiring two base changes in the appropriate codons. Moreover, the malignant "clones" producing the two proteins differed in their responses to chemotherapy. These data indicate that, although the two clones producing the serum proteins were different at the time of study, they may have arisen from the same precursor clone.