Endocytosis and recycling of MHC-encoded class II molecules by mouse B lymphocytes

The movements of mouse MHC-encoded class II (H-2E) and class I (H-2K), transferrin receptor and surface Ig molecules of B lymphocytes were studied using radiolabeled mAb and electron microscopy. A total of 10 to 20% of antibodies specific for H-2E molecules were gradually internalized with a t 1/2 of 15 min, reaching a plateau after 30 min at 37 degrees C. Equivalent results were obtained either with the whole antibody or Fab' fragments, suggesting that the internalization of class II molecules was spontaneous. Similar results were obtained with antibodies specific for the transferrin receptor, of which 50% were internalized with t 1/2 of 5 min, reaching a plateau after 30 min. In contrast to antibodies specific for H-2E molecules and the transferrin receptor, antibodies specific for H-2K were not internalized. Reappearance of internalized H-2E-specific antibodies at the cell surface was observed at 37 degrees C. When compared to antibodies specific for surface Ig, degradation of antibodies specific for H-2E molecules was limited even after 5 h incubation. Neither ammonium chloride nor cycloheximide inhibited internalization and recycling. Electron microscopy showed that internalization of H-2E molecules occurred via coated pits/coated vesicles. These results indicate that class II molecules are spontaneously internalized and recycled by B lymphocytes.     

Two distinct mechanisms for redistribution of lymphocyte surface macromolecules. I. Relationship to cytoplasmic myosin

A detailed kinetic analysis of the distribution of cytoplasmic myosin during the capping of various lymphocytic surface molecules revealed two distinct capping mechanisms. (a) Some cell surface molecules, including immunoglobulin, Fc receptor, and thymus leukemia antigen, all cap spontaneously in a small fraction of lymphocytes during locomotion. Cytoplasmic myosin becomes concentrated in the cytoplasm underlying these spontaneous caps. Exposure to specific antibodies causes all three of these surface molecules to cap rapidly with a concomitant redistribution of cytoplasmic myosin to the area of the cap. These antibodies also stimulate cell locomotion. (b) Other lymphocyte surface molecules, including H2 and Thy.1, do not cap spontaneously. Moreover, exposure to antibodies to these molecules causes them to cap slowly without a redistribution of cytoplasmic myosin or stimulation of cell locomotion. Exposure to concanavalin A gives a response intermediate between these two extremes. We believe that the first type of capping is active and may involve a direct link between the surface molecules and the cytoplasmic contractile apparatus. The second type of capping appears to result simply from aggregation of cross-linked molecules in the plane of the membrane.     

Effects of monoclonal antibodies against lymphocyte surface antigens on interleukin 2 excretion by Epstein-Barr virus-specific human T-cell hybridomas

Monoclonal antibodies were used as probes to study the role of cell surface antigens in the response of Epstein-Barr virus (EBV)-specific human T-T hybridomas to autologous EBV-infected B lymphoblasts. Somatic cell hybrids were generated by fusing EBV-primed peripheral blood T lymphocytes with a mutant clone of the JM human T-lymphoblastoid-cell line. When exposed to autologous EBV-infected B lymphoblasts, the resulting hybrid clones released Interleukin 2 into the culture medium. Incubation of the EBV-infected B cells with two monoclonal antibodies against human Ia-like molecules blocked their ability to trigger the hybridomas. Under the same conditions, monoclonal antibodies against beta 2-microglobulin, and a 45,000 MW surface antigen common to EBV-infected B lymphoblasts, did not alter the capacity of the B cells to stimulate the hybridomas. None of four monoclonal antibodies against surface antigens on the T-cell hybridomas impaired their responsiveness to EBV-infected B lymphoblasts. These results suggest the possibility that naturally occurring or exogenously administered antibodies against Ia molecules might interfere with T-cell regulation of EBV-induced B-cell activation.     

Direct involvement of surface IA/E molecules during B cell maturation using an antigen-specific B cell clone

TP67.14 is a subclone of a resulting B cell hybridoma established by somatic hybridization between splenic B cells of A/J mice immunized with TNP-LPS and 2.52 M, a HAT medium-sensitive mutant of a B cell line; it expresses IgM, B220, IAk, and IEk on the cell membrane and also possesses a receptor molecule for TNP on its surface derived from TNP-reactive B cells of A/J mice used for cell fusion. As shown previously, TP67.14 could be induced to generate a significant amount of anti-TNP antibodies when treated with TNP-conjugated protein such as TNP-BSA and TNP-keyhole limpet hemocyanin without T cell help as well as LPS. Our study was undertaken to investigate direct involvement of surface MHC class II molecules on B cells during B cell maturation by analysis with this Ag-specific B cell clone. The data demonstrate that mAb against IAk and IEk molecules, but not IAd and H-2k, markedly inhibited the differentiative effects of LPS on TP67.14. In contrast, both antibodies specifically augmented the secretion of anti-TNP antibodies by TP67.14 treated with TNP-BSA, although these antibodies alone failed to induce the generation of anti-TNP antibodies. Interestingly, TP67.14 significantly differentiated into anti-TNP antibody secreting cells when incubated with TNP-conjugated monoclonal anti-IAk or anti-IEk antibodies alone; this differentiative effect was much greater than that of TNP-conjugated anti-IAd mAb or purified mouse IgG under the same conditions. Our result suggests that surface IA/E molecules on B cells may be directly involved in a transductional signal for B cell maturation mediated by the cross-linkage of receptor molecules on B cells with Ag.     

Evidence for an IgD homologue on chicken lymphocytes

Chicken lymphocyte membrane immunoglobulins (Ig), were precipitated with mouse monoclonal antibodies specific for heavy and light chain isotypes and analyzed by polyacrylamide gel electrophoresis. Very little or no membrane-bound IgG and IgA was detected. After sequential precipitation and removal of IgM reactive with any of three monoclonal anti-mu antibodies, anti-light chain antibody precipitated residual Ig with a relative electrophoretic mobility similar to that of IgM. Under reducing conditions, these surface Ig molecules had a heavy chain that appeared slightly larger (approximately 81,000 daltons) than mu-chain (approximately 79,000 daltons), and light chains of approximately 25,000 daltons. Complete clearance of membrane-bound IgM reactive with an anti-mu allotype antiserum left similar molecules precipitate by monoclonal anti-light chain antibody. These non-IgM molecules could be detected on the surface of lymphocytes from blood, spleen, bursa and the B cell line RAV-1, but not from thymus or blood from an agammaglobulinemic chicken. After capping of B cell surface IgM with anti-mu, immunofluorescent staining with anti-light chain antibody revealed residual Ig molecules disturbed across the surface of more than 90% of the IgM-bearing cells. The data suggest the existence of an avian homologue of mammalian IgD. Affinity-purified goat anti-mu antibodies and a fourth monoclonal anti-mu antibody reacted with both IgM and the putative IgD molecules, which suggests that the IgD homologue shares at least one common determinant with chicken IgM.     

Characterization of lipopolysaccharide from Myxococcus xanthus by use of monoclonal antibodies.

Lipopolysaccharide is a major constituent of the cell surface of the gram-negative procaryote Myxococcus xanthus. We have purified lipopolysaccharide from M. xanthus and have shown by silver staining that the lipopolysaccharide contains a heterogeneous population of molecules which migrate as a broad low-molecular-mass band (approximately 5 kilodaltons) and as a stepladder of about 30 higher-molecular-mass bands (15- to 70-kilodalton range). The broad band consists of lipopolysaccharide molecules with just lipid A and core regions. The stepladder bands contain lipopolysaccharide molecules with lipid A, core regions, and various numbers of O-antigen units. Monoclonal antibodies generated against the cell surface of developing M. xanthus cells (J. S. Gill and M. Dworkin, Proc. Natl. Acad. Sci. USA 84:4505-4508, 1987) were used to help characterize the lipopolysaccharide molecules. Five monoclonal antibodies bound to carbohydrate epitopes on the stepladder but not to the broad band, indicating that these monoclonal antibodies recognize carbohydrates on the O antigen of the lipopolysaccharide molecules. Four of these five monoclonal antibodies bound to doublet bands in the stepladder, while the other monoclonal antibody bound to singlet bands in the stepladder. One monoclonal antibody bound to a carbohydrate epitope on both the broad band and the stepladder, indicating that it bound to the core of the lipopolysaccharide.     

MHC-like molecules in some nonmammalian vertebrates can be detected by some cross-reactive xenoantisera

Rabbit antisera raised to human and chicken MHC molecules were used to immunoprecipitate cross-reactive molecules from biosynthetically and cell surface-labeled spleen and/or blood cells of representative vertebrate species. Five major points emerged: 1) There were many nonspecific cross-reactions using these techniques, so various criteria were developed to distinguish these from true MHC-like molecules. 2) Only very small subpopulations of immunogen-specific antibodies cross-reacted with MHC-like molecules in other nonmammalian species. These subpopulations were different for each species and even within a species, sometimes being so limited as to behave like alloantisera. This led to a very scattered pattern of true cross-reactions that sometimes failed to reflect the properties of the bulk antibody population. 3) Antisera containing antibodies to class II beta- and class I alpha-chains cross-reacted better and more widely than those to B-G, class II alpha and, in general, beta 2-microglobulin. 4) Some cross-reactive antibodies were clearly directed to epitopes on the surface of the mature heterodimers, but many seemed to recognize nonlinear cryptic determinants, presumably in the contact regions between the chains. These latter antibodies recognized biosynthetic intermediates and also a variety of unusual cell surface MHC-like molecules present in reptile and amphibian, but absent in the mammal and chicken cells tested. These included E homodimers whose relationship to chicken B-G molecules is unknown. 5) MHC-like molecules were identified in a bird, three reptiles, and two amphibians, but no molecules with the expected properties were found with these reagents in any of the fish tested.     

Trypanosoma simiae and Trypanosoma congolense: surface glycoconjugates of procyclic forms-the same coats on different hangers?

Organic solvent extraction, reverse-phase high performance liquid chromatography and enzyme-linked immunosorbent assay with surface binding monoclonal antibodies were used to isolate membrane molecules of procyclic culture forms of Trypanosoma simiae and Trypanosoma congolense. Gel electrophoresis of the purified molecules revealed two predominant molecular species from each parasite that were broadly similar yet showed different apparent molecular masses and staining characteristics. The molecules were shown to be glycosylphosphatidylinositol-lipid anchored glycoconjugates, rich in carbohydrates. Each moiety displayed surface-disposed carbohydrate epitopes that were recognized on the surface of both species of trypanosomes by monoclonal antibodies specific for procyclic parasites of the subgenus Nannomonas. The epitopes were previously shown to be displayed on the glutamic acid-alanine rich protein of T. congolense yet neither this protein, nor its encoding gene is present in T. simiae. The results indicate that although T. congolense and T. simiae share common carbohydrate surface epitopes, these are displayed on biochemically different molecules. We speculate that the surface disposed carbohydrate structures are involved in parasite-tsetse interactions since these species have the same developmental cycles in the insect vector.     

The production and characteristics of liposomes bearing interferon antibodies on their surfaces

Liposomes carrying anti-interferon antibodies 5A6 on their surface were prepared from the mixture of lecithin and cholesterol. The binding of antibodies with the liposomal membrane was achieved by their modification with palmitic acid molecules in an amount of 3-4 molecules per vesicle. Antibodies on the liposomal surface were shown to retain their antigenic specificity, but the amount of the antigen bound by them was less than a half of the possible maximum amount. Double immune complexes could be formed on bound antibodies, but the number of such complexes was relatively small. The causes of a decrease in the sorption of interferon and the formation of immune complexes are discussed.     

Atomic force spectroscopy-based study of antibody pesticide interactions for characterization of immunosensor surface

Development of immunobiosensor detector surfaces involves the immobilization of active antibodies on the capture surface without any significant loss of antigen binding activity. An atomic force microscope (AFM) was used to directly evaluate specific interactions between pesticides and antibodies on a biosensor surface. Oriented immobilization of antibodies against two herbicide molecules 2,4-dichlorophenoxyacetic acid (2,4-D) and atrazine, on gold, was carried out to create the active immunobiosensor surfaces. The adhesive forces between immobilized antibodies and their respective antigens were measured by force spectroscopy using hapten-carrier protein functionalized AFM cantilevers. Relative functional affinity (avidity) measurements of the antibodies carried out prior to immobilization, well correlated with subsequent AFM force measurement observations. Analysis showed that immobilization had not compromised the reactivity of the surface immobilized antibody molecules for antigen nor was there any change in their relative quality with respect to each other. The utility of the immunoreactive surface was further confirmed using a Surface Plasmon Resonance (SPR) based detection system. Our study indicates that AFM can be utilized as a convenient immunobiosensing tool for confirming the presence and also assessing the strength of antibody-hapten interactions on biosensor surfaces under development.     

Class I-specific antibodies inhibit proliferation in primary but not secondary mouse T cell responses.

Murine T and B splenocytes were incubated with antibodies that recognize CD3 or surface IgM. These antibodies induced proliferation of their respective target cells. Once stimulated via their receptors, the proliferation of both CD4+ and CD8+ T but not B lymphocytes was inhibited by class I-specific antibodies or their monovalent Fab' fragments. The inhibition of proliferation was dependent on the site on class I molecules recognized by the antibodies used, with the alpha 1/alpha 2 domains of H-2K molecules representing the major site for inhibition. Only soluble antibody-mediated proliferation could be inhibited by class I-directed antibodies; proliferation induced by CD3-specific antibody immobilized on plastic was not inhibited. Primary allogeneic MLR was also inhibited by class I-specific antibodies. In contrast, neither secondary allogeneic MLR, secondary Ag-specific responses, nor proliferation of CTL clones or tumor cell lines were inhibited by class I-specific antibodies. These results suggest a role for class I molecules in regulation of TCR/CD3- but not surface IgM-mediated cell signaling, which depends on the form of stimulation and the stage of differentiation of T cells.     

Medical applications of leukocyte surface molecules--the CD molecules

Leukocytes are the cells of the immune system and are centrally involved in defense against infection, in autoimmune disease, allergy, inflammation, and in organ graft rejection. Lymphomas and leukemias are malignancies of leukocytes, and the immune system is almost certainly involved in most other cancers. Each leukocyte expresses a selection of cell surface glycoproteins and glycolipids which mediate its interaction with antigen, with other components of the immune system, and with other tissues. It is therefore not surprising that the leukocyte surface molecules (CD molecules) have provided targets for diagnosis and therapy. Among the "celebrities" are CD20, a target for lymphoma therapeutic antibodies which earns $2 billion annually (and makes a significant difference to lymphoma patients), and CD4, the molecule used by the human immunodeficiency virus (HIV) as an entry portal into cells of the immune system. This short review provides a background to the CD molecules and antibodies against them, and summarizes research, diagnostic, and therapeutic applications of antibodies against these molecules.     

Growth inhibition of myeloma cells by anti-idiotype antibodies in the absence of membrane-bound immunoglobulin

Immunoglobulins are expressed as membrane-bound or secreted forms. Plasma cells produce little or no membrane immunoglobulin but secrete immunoglobulin molecules in large amounts. Immunoglobulin idiotypes of malignant B cells are tumor-specific antigens that may be targeted for immunotherapy. Thus, idiotype vaccination is being evaluated in clinical trials to control residual disease in multiple myeloma and non-Hodgkin's lymphoma. It is traditionally considered that anti-idiotype antibodies are not effective against plasma cell tumors, because the large amounts of immunoglobulin molecules secreted by the tumors block anti-idiotype antibodies, and because the absence of membrane immunoglobulin on the surface of these tumor cells renders them resistant to the effect of anti-idiotype antibodies. While the obstacle of abundant circulating idiotype may be obviated by reducing tumor burden to minimal residual disease, the absence of membrane immunoglobulin has been considered as a limiting factor that prevents tumor eradication by anti-idiotype antibodies. We demonstrate here that murine plasmacytoma cells can produce small amounts of membrane immunoglobulin M (IgM) heavy chains. However, the latter are precursor molecules that do not reach the cell surface. Although membrane-bound IgM is absent, the cells stain positively for surface IgM, reflecting molecules of the secreted form in the process of secretion. In spite of the relatively low levels of secreted immunoglobulin on the cell surface, anti-idiotype antibodies are effective in retardation of tumor growth in vivo. Thus, while there is no doubt that idiotype-specific cell-mediated responses are very important, myeloma patients in complete remission may additionally benefit from idiotype-specific humoral responses.     

Early regenerative responses induced by monoclonal antibodies directed against a surface glycoprotein of goldfish retinal ganglion cells.

Monoclonal antibodies directed primarily against antigenic determinants associated with the goldfish optic nerve were prepared and characterized. One selected clone 23-4-C(IgG2a), detected antigenic determinants of glycoprotein nature with an apparent mol. wt. of 140 000. Following injury the level of these molecules increased with a peak at 5-7 days after the lesion (2- to 3-fold higher than the basal level). The results strongly suggest that the increase derives, at least partially, from a real increment in the level of these molecules in the retinal ganglion cells rather than from changes in accessibility. Immunofluorescence studies indicate that the retinal ganglion cells carry the antigenicity. Intraocular injection of the monoclonal antibodies, concomitantly with crush injury, resulted in an earlier and higher regenerative response, reflected by sprouting capacity, protein synthesis and accumulation of radiolabeled material in the tectum contralateral to the side of injury. This may indicate that the antibodies directly activate retinal cells via interaction with surface molecules. Alternatively, the antibodies may be directed against surface molecules which are associated with axonal growth inhibitors, and may therefore mask these surface antigens from further interaction with their native substrate.     

The guanidine hydrochloride-induced denaturation of CP43 and CP47 studied by terahertz time-domain spectroscopy

Terahertz time-domain spectroscopy (THz-TDS) is a new technique in studying the conformational state of a molecule in recent years. In this work, we reported the first use of THz-TDS to examine the denaturation of two photosynthesis membrane proteins: CP43 and CP47. THz-TDS was proven to be useful in discriminating the different conformational states of given proteins with similar structure and in monitoring the denaturation process of proteins. Upon treatment with guanidine hydrochloride (GuHCl), a 1.8 THz peak appeared for CP47 and free chlorophyll a (Chl a). This peak was deemed to originate from the interaction between Chl a and GuHCl molecules. The Chl a molecules in CP47 interacted with GuHCl more easily than those in CP43.     

The guanidine hydrochloride-induced denaturation of CP43 and CP47 studied by terahertz time-domain spectroscopy

Terahertz time-domain spectroscopy (THz-TDS) is a new technique in studying the conformational state of a molecule in recent years. In this work, we reported the first use of THz-TDS to examine the denaturation of two photosynthesis membrane proteins: CP43 and CP47. THz-TDS was proven to be useful in discriminating the different conformational states of given proteins with similar structure and in monitoring the denaturation process of proteins. Upon treatment with guanidine hydrochloride (GuHCl), a 1.8 THz peak appeared for CP47 and free chlorophyll a (Chl a). This peak was deemed to originate from the interaction between Chl a and GuHCl molecules. The Chl a molecules in CP47 interacted with GuHCl more easily than those in CP43. Supported by the National Natural Science Foundation of China (Grant No. 39890390)     

Cross-linking of insulin receptors to MHC antigens in human B lymphocytes: evidence for selective molecular interactions

Molecular interactions between insulin receptors and MHC antigens were investigated in human B cells. Two B lymphoblastoid cell lines, IM-9 and 526, chosen for their high insulin binding capacity, were found to express 15,000 and 25,000 insulin receptors per cell, respectively. Insulin receptors were labeled with a 125I-photoreactive insulin analogue, and all other surface proteins by lactoperoxidase-catalyzed radioiodination. Neighbor proteins were cross-linked with a cleavable homobifunctional reagent dithio-bis-(succinimidyl propionate) (DSP) and solubilized before immunoprecipitation by anti-HLA monoclonal antibodies. Gel analysis of the precipitated proteins showed that 90% of insulin receptors precipitable by anti-insulin receptor antibodies were precipitated by anti-class I antibodies (anti-heavy chain and anti-beta 2-microglobulin) after cross-linking with 2 mM DSP. In neither IM-9- nor 526 cells could HLA antigens be precipitated by anti-insulin receptor antibodies, suggesting that the concentration of class I antigens largely exceeds the concentration of insulin receptors at the cell surface. In 526 lymphocytes, class I MHC antigens were also found to adjoin class II antigens, since both molecules could be coprecipitated with anti-HLA A, B, C and with anti-HLA-DR antibodies after chemical cross-linking. Down-regulation of insulin receptors by chronic exposure of IM-9 cells to insulin did not affect the amount of MHC molecules present on the cell surface, and conversely, class I MHC molecules were internalized in 526 cells irrespective of the presence of insulin. These results thus show that insulin receptors and MHC antigens form multimolecular complexes in the plasma membrane of cultured human B cells. These interactions, which do not appear to influence the regulation of these proteins on the cell surface, may be involved in the mechanism of hormone signaling.     

New antibody immobilization method via functional liposome layer for specific protein assays

A specific protein assay system based on functional liposome-modified gold electrodes has been demonstrated. To fabricate such assay system, a liposome layer was initially grown on top of a gold layer. The liposome layer contained two kinds of functional molecules: biotin molecules for the binding sites of streptavidin and N-(10,12-pentacosadiynoic)-acetylferrocene molecules for the facile redox probe in electrochemical detections. Then, streptavidin was attached on the functional liposme-modified layer using the interaction of streptavidin-sbiotin complex. On the streptavidin-attached surface, antibody molecules, anti-human serum albumin antibodies could be immobilized without any secondary antibodies. AFM imaging of the streptavidin-attached liposome surface revealed a uniform distribution of closely packed streptavidin molecules. In situ quartz-crystal microbalance and electrochemical measurements demonstrated that the wanted antibody-antigen reactions should occur with high specificity and selectivity. Our specific antibody assay system, based on a functional liposome modified electrode, can be developed further to yield sophisticated structures for numerous protein chips and immunoassay sensors.     

Subtractive single-chain antibody (scFv) phage-display: tailoring phage-display for high specificity against function-specific conformations of cell membrane molecules

Phage-display of antibody libraries is a powerful tool to select antibodies for specific epitopes. We describe a strategy for selecting highly specific scFv-clones that discriminate between various conformational states of cell surface receptors. This approach adapts the M13 pIII phage-display technology toward a cell suspension-based strategy, which allows panning against complex, multimeric, fully functional cell membrane epitopes without alteration of structure due to purification or immobilization. As the functional properties are preserved, phage can be specifically depleted or selected for neo-epitopes exposed after physiological alterations of the targeted molecules. This subtractive strategy allows highly specific selection for single-chain antibodies directed against functionally regulated epitopes on the cell surface molecules that can be tailored for diagnostic and therapeutic applications. Using this protocol, activation-specific single-chain antibodies can be obtained within 4-6 weeks.