Chicken developmental antigens in 15I5-B-congenic lines

Six partially developed 15I5-B-congenic lines of chickens were used to assess the genetic influence on the developmental expression of selected epitopes of two avian developmental antigen systems: chicken fetal antigen (CFA) and chicken adult antigen (CAA). Both CFA and CAA are serologically and molecularly complex hematopoietic antigen systems, yet little is known about genetic influences on their expression. Using polyclonal rabbit anti-CFA, only slight variations in overall CFA expression on peripheral erythrocytes were observed during neonatal development; no consistent trend was evident. In contrast, analysis with monoclonal antibody 10C6 revealed that the incidence of CFA determinant 8 (CFA8) on erythrocytes of the early neonate was significantly reduced in line 15I5 compared with lines .6-2, .7-2 and .15I-5; line .C-12 also exhibited a reduced CFA8 incidence at hatching. Likewise, the CAA epitope detected by monoclonal antibody 3F12 was found to appear at a slower rate on erythrocytes from lines 15I5 and .C-12 than on those of other lines. Similar results were obtained using the anti-CAA monoclonal 4C2 where reduced expression was found in lines 15I5, .C-12, and .P-13. Results of complement-mediated cytolysis using the positive control 9F9 monoclonal antibody suggested that observed genetic differences were not due to inherent differences in erythroid cytolytic sensitivity. Neither could the results be explained by the incidence of circulating reticulocytes vs. mature erythrocytes within the lines. Rather, the results suggest that different genetic lines of chickens vary in the developmental kinetics of definitive erythrocyte subpopulations bearing specific phenotypes defined by monoclonal antibodies. These findings are discussed in light of previous observations using these B-congenic lines.     

Avian developmental antigens: Expression on erythrocytes of chickens,Japanese quail,and quail-chicken hybrids

Monoclonal and polyclonal antibodies were used to examine the expression of three erythroid developmental antigen systems in the chicken, Japanese quail, and quail-chicken hybrid. Chicken fetal antigen (CFA), quail fetal antigen (QFA), and chicken adult antigen (CAA) each represent a series of cell-surface glycorproteins associated with the development of avian hematopoietic cells. Monoclonal anti-CFA antibodies from clones 190-4 and 288-1.1.1.2 supernatants were shown to react against epitopes associated with CFA determinants 8 and 2, respectively. Using complement-mediated microcytotoxicity, these reagents permitted the identification of different erythroid subpopulations in the neonatal chicken and hybrid; therefore, heterogeneity in cell surface CFA determinants among mature peripheral erythrocytes should serve as a useful tool for analyzing erythroid development. In the case of CAA, erythrocytes from adult hybrids were found to express the same complement of CAA determinants identified in the chicken, and CAA appeared much earlier in the hybrid than in either of the parental species. Similarly, two species-restricted fetal antigens associated with similar glycoproteins, CFA8 and QFA, had similar developmental profiles in their respective species, the chicken and quail. In contrast, these antigens were dominantly expressed but exhibited different developmental profiles on erythrocytes from the hybrids. While quail-chicken hybrids exhibited apparent genomic interactions in the expression of these developmental antigens, no evidence for the existence of hybrid-specific fetal antigens was obtained.     

Hematopoietic differentiation cell surface antigen switching in the bone marrow of different aged chickens

Abstract. Immune cytolysis and immunofluorescence were used to examine chicken fetal antigen CFA) and chicken adult antigen (CAA) expression on the differentiation/maturation series of definitive erythroid cells obtained from the bone marrow of different aged chickens. We found that erythroid cells undergo changes in CFA/CAA antigenic expression dependent on their differentiation/maturation stage as well as the developmental age of the chicken. All differentiation/maturation stages of erythroid cells in the bone marrow of 12 and 18-day-old embryos express CFA only. Erythroblasts obtained from 7-day post-hatched chickens express either CFA or CAA. All three CFA/CAA phenotypes (i.e., CFA, CAA, and CFA + CAA) are observed in subsequent maturation stages, but only the CFA + CAA phenotype is observed in mature erythroid cells in the bone marrow of 7day post-hatched chickens. Erythroblasts from 62 day post-hatched chickens exhibit all three CFA/CAA phenotypes. Cells in the subsequent maturation stages express various CFA, CAA, or CFA + CAA phenotypes resulting in a majority of the mature erythrocytes expressing both CFA and CAA, and a small population of mature erythrocytes expressing CAA only. Erythroblasts from adult chickens express both CFA and CAA; however, CFA is lost during erythroid maturation resulting in mature erythrocytes which express CAA only. These studies indicate that both the erythroid differentiation/maturation stage and the developmental age of the chicken influence CFA and CAA antigenic expression on erythroid cells undergoing cellular differentiation/maturation in the bone marrow.     

Hematopoietic differentiation cell surface antigen switching in the bone marrow of different aged chickens

Immune cytolysis and immunofluorescence were used to examine chicken fetal antigen CFA) and chicken adult antigen (CAA) expression on the differentiation/maturation series of definitive erythroid cells obtained from the bone marrow of different aged chickens. We found that erythroid cells undergo changes in CFA/CAA antigenic expression dependent on their differentiation/maturation stages as well as the developmental age of the chicken. All differentiation/maturation stages of erythroid cells in the bone marrow of 12 and 18-day-old embryos express CFA only. Erythroblasts obtained from 7-day post-hatched chickens express either CFA or CAA. All three CFA/CAA phenotypes (i.e., CFA, CAA, and CFA + CAA) are observed in subsequent maturation stages, but only the CFA + CAA phenotype is observed in mature erythroid cells in the bone marrow of 7-day post-hatched chickens. Erythroblasts from 62 day post-hatched chickens exhibit all three CFA/CAA phenotypes. Cells in the subsequent maturation stages express various CFA, CAA, or CFA + CAA phenotypes resulting in a majority of the mature erythrocytes expressing both CFA and CAA, and a small population of mature erythrocytes expressing CAA only. Erythroblasts from adult chickens express both CFA and CAA; however, CFA is lost during erythroid maturation resulting in mature erythrocytes which express CAA only. These studies indicate that both the erythroid differentiation/ maturation stage and the developmental age of the chicken influence CFA and CAA antigenic expression on erythroid cells undergoing cellular differentiation/maturation in the bone marrow.     

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.     

Screening of phage-displayed peptide libraries with a monoclonal antibody raised against the F protein of the bovine respiratory syncytial virus

Summary Most of the monoclonal antibodies (MAbs) raised against the fusion (F) protein of the bovine respiratory syncytial virus recognize discontinuous epitopes on the protein. In order to find mimotopes of these epitopes, phage-displayed peptide libraries were screened with MAbs. The results obtained with MAb AL11C2 are described here. After four or five pannings, colony immunoscreening with AL11C2 allowed the isolation of positive clones that are specific for this monoclonal antibody. Four different sequences were determined on isolated phages, three of which are cysteine-constrained peptides in fusion with PVIII and one is a hexapeptide in fusion with PIII. In the case of the peptides containing two cysteines, the binding to AL11C2 was shown to be dependent on the presence of a disulfide bridge. The recombinant phages were also shown to inhibit the binding of AL11C2 to its natural antigen in a competitive ELISA assay.     

Monoclonal antibodies to bovine UDP-galactosyltransferase. Characterization, cross-reactivity, and utilization as structural probes

A series of mouse monoclonal antibodies has been developed against a soluble form of bovine UDP-galactose:N-acetylglucosamine galactosyltransferase purified to apparent chemical homogeneity by a combination of affinity and immunoadsorption chromatography. The purified enzyme consists of two molecular mass variants of 42 and 48 kDa. Individual monoclonal antibodies were selected for by their ability to recognize immobilized affinity-purified galactosyltransferase and were not reactive against bovine alpha-lactalbumin and bovine immunoglobulins. Based on competitive binding assays and Western blot analysis with either galactosyltransferase or lactose synthetase (covalently cross-linked alpha-lactalbumin galactosyltransferase), these monoclonal antibodies can be subdivided into four groups. Group A (3 clones) recognize an epitope at or near the alpha-lactalbumin binding site. In addition, this group is cross-reactive with soluble galactosyltransferase from human milk and pleural effusion. Group B (6 clones) and D (1 clone) appear to recognize two different epitopes on the 6-kDa fragment which is released when the 48-kDa galactosyltransferase polypeptide is converted to the 42-kDa form, apparently by proteolysis. Groups A and C (1 clone) recognize epitopes found on both the 48- and 42-kDa polypeptide. Interestingly, immunofluorescence studies indicate that only two monoclonal antibody groups (C and D) are able to decorate membrane-bound galactosyltransferase (Golgi-associated) in formalin-fixed, methanol-, or detergent-permeabilized cells. Thus, these groups of monoclonal antibodies appear to identify four separate structural/functional domains on soluble galactosyltransferase, two of which are not readily accessible for binding in situ.     

Detection of avian hematopoietic cell surface antigens with monoclonal antibodies to myeloid cells : Their distribution on normal and leukemic cells of various lineages

The isolation and characterization of monoclonal antibodies reacting with cell surface antigenic determinants of normal and leukemic avian hematopoietic cells is described. The antibodies were produced by immunizing mice with normal macrophages, as well as with myeloid cells transformed with the avian acute leukemia viruses MC29, AMV and E26. Eleven antibodies were characterized for their reactivity with a variety of normal and leukemic cells of the myeloid, B- and T-lymphoid and of the erythroid cell lineage. Using several methods, they could be subdivided into five distinct types: I. Four antibodies were specific for the myeloid lineage, predominantly reacting with immature myeloid cells. II. One antibody reacted with mature and immature myeloid cells as well as with T-lymphoid cells. III. Four antibodies reacted with myeloid, erythroid and T-lymphoid cells. IV. One antibody reacted with myeloid as well as with T- and B-lymphoid cells. V. One antibody reacted with all kinds of chicken hematopoietic cells except erythrocytes. The first type of antibodies detected glycoproteins with MWs of 170 and 130 kD. The pattern of antigens precipitated varied with the different monoclonal antibodies of this group. The antibody of the fourth type precipitated a 30 kD polypeptide from extracts of myeloid and lymphoid cells. None of the other antibodies precipitated any detectable proteins.     

Selection of Apoptotic Cell Specific Human Antibodies from Adult Bone Marrow

Autoreactive antibodies that recognize neo-determinants on apoptotic cells in mice have been proposed to have protective, homeostatic and immunoregulatory properties, although our knowledge about the equivalent antibodies in humans has been much more limited. In the current study, human monoclonal antibodies with binding specificity for apoptotic cells were isolated from the bone marrow of healthy adults using phage display technology. These antibodies were shown to recognize phosphorylcholine (PC)-associated neo-determinants. Interestingly, three of the four identified apoptotic cell-specific antibody clones were encoded by VH3 region rearrangements with germline or nearly germline configuration without evidence of somatic hypermutation. Importantly, the different identified antibody clones had diverse heavy chain CDR3 and deduced binding surfaces as suggested by structure modeling. This may suggest a potentially great heterogeneity in human antibodies recognizing PC-related epitopes on apoptotic cells. To re-construct the postulated structural format of the parental anti-PC antibody, the dominant clone was also expressed as a recombinant human polymeric IgM, which revealed a substantially increased binding reactivity, with dose-dependent and antigen-inhibitable binding of apoptotic cells. Our findings may have implication for improved prognostic testing and therapeutic interventions in human inflammatory disease.     

Recognition of two Dermatophagoides pteronyssinus-specific epitopes on antigen P1 by using monoclonal antibodies: binding to each epitope can be inhibited by serum from dust mite-allergic patients

Monoclonal antibodies were raised against Antigen P1, the major allergen of the house dust mite (Dermatophagoides pteronyssinus). The majority were Antigen P1 specific, isotype IgG1, and did not react with a comparable D. farinae allergen. These antibodies bound 38 to 50% of 125I Antigen P1 in antigen-binding assays (titer greater than or equal to 1/1,000,000), and the quantities of IgG antibody in ascites were 2 to 4 logs greater than those in polyclonal mouse antiserum or in serum from a mite-allergic patient. Two IgM antibodies showed weak binding to Antigen P1 but reacted strongly with D. pteronyssinus in enzyme immunoassay (titer greater than or equal to 1/100,000). Assessments of the specificity of the IgG antibodies by using two inhibition radioimmunoassays suggested that they were directed against two different epitopes. Antibodies 10B9 F6 and 5H8 C12 were purified by preparative isoelectric focusing (isoelectric points of pI 6.25 and 7.4, respectively) and radiolabeled with 125I. Cross-inhibition experiments, using ascites dilutions to inhibit binding of each radiolabeled antibody to Antigen P1, confirmed that these antibodies recognized two distinct epitopes. Analysis of antibodies from 39 clones/hybrids showed that the majority were directed against the same epitopes as either 10B9 F6 or 5H8 C12 (3 out of 39 [8%] and 29 out of 39 [74%], respectively). None of the monoclonal antibodies significantly inhibited (greater than 10%) human IgE binding to Antigen P1 in the radioallergosorbent test. However, 12 of 14 sera from mite allergic patients inhibited binding by the monoclonal antibodies. One serum from a mite-allergic patient inhibited binding of both 10B9 F6 and 5H8 C12 by greater than 85% and showed parallel inhibition curves. The results suggest that these monoclonal antibodies could be used to assay Antigen P1 in both D. pteronyssinus and house dust extracts. It should also be possible to use monoclonal antibodies in inhibition assays to define the antigenic/allergenic determinants recognized by human IgG and IgE antibodies on this mite allergen.     

Immunoelectron microscopic detection of band 3 protein during erythroid cell differentiation by a monoclonal antibody

We created a monoclonal antibody, designated EB1 (IgM, kappa), that reacts with erythroblasts by fusion of P3-X63-Ag8.653 with splenocytes of rats immunized with erythroblastic islands isolated from mice spleens. Western blotting revealed that EB1 reacted with the band 3 protein of the erythrocytic membrane. It stained erythrocytes and erythroblasts, forming clusters in the bone marrow, splenic red pulp, and fetal liver, but did not stain other tissues in the cryostat sections. The EB1 antigen was detected during dimethyl sulfoxide-induced differentiation of murine erythroleukemia cells. Immunoelectron microscopy revealed that the EB1 antigen was expressed from the basophilic erythroblasts during normal erythroid differentiation. Preferential segregation of the EB1 antigen on the cell membrane of the nucleating erythroblasts was not observed. These results suggest that EB1 is specific for erythrocyte band 3 protein and may be useful for studying erythroid cell differentiation.     

Monoclonal antibodies detecting different epitopes on the Forssman glycolipid hapten

Two hybridomas, derived by fusing mouse myeloma cells with spleen cells from a rat immunized with mouse mammary tumors, have been shown to produce antibodies that recognize cell surface antigens on mesenchymal cells in a variety of tissues. Evidence presented in this report suggests that these antibodies detect overlapping epitopes on the Forssman glycolipid hapten (GalNAc alpha 1-3GalNAc beta 1-3Gal alpha 1-4Gal beta 1-4Glc beta 1-1Cer). One antibody (33B12) reacts with the terminal sugar sequence GalNAc alpha 1-3GalNAc and is specific for Forssman. The other antibody (117C9) recognizes the internal sugar sequence GalNAc beta 1-3Gal. The terminal sugar sequence GalNAc beta 1-3Gal in globoside, as well as the internal sugar sequence GalNAc beta 1-4Gal in asialo-GM1, is not recognized as an antigenic determinant by 117C9. Nevertheless, the 117C9 antibody does not react exclusively with the Forssman antigen. In a lipid extract fractionated by Folch partition of mouse mammary tumors, the antibody also detects other glycolipids.     

Anti-major histocompatibility complex immunity detected prior to intentional alloimmunization. II. Monoclonal H-2-specific antibodies obtained from an unimmunized C57BL/KaLwRij (H-2b) mouse

A monoclonal 'natural' anti-H-2 IgM antibody produced by a hybridoma cell line OL-3.17 (H-2 m. 209) is described. The OL-3.17 monoclonal antibody was obtained by hybridization of spleen B cells from an unimmunized C57BL/Ka (H-2b) mouse in the serum of which simultaneously an IgM kappa paraprotein of high concentration and a natural H-2-specific antibody of high titer was detected. The monoclonal antibody OL-3.17 reacted strongly with H-2d and H-2s and weakly with H-2k,q,r lymphocytes, thereby detecting a hitherto unknown H-2 public determinant. The target molecules for OL-3.17 cocapped with class-I H-2 antigens, but immunoprecipitation of H-2 antigens was not achieved. This is the first monoclonal H-2-specific antibody obtained from a mouse without intentional immunization and, with high probability, was derived from a B-cell clone which produced natural H-2-specific antibodies detectable in the serum of the original mouse.     

Tissue distribution and biochemical and functional properties of Tp55 (CD27), a novel T cell differentiation antigen

Two monoclonal antibodies (CLB-CD 27/1 and CLB-CD 27/2) were raised against a novel determinant on human T lymphocytes. One of these antibodies, CLB-CD 27/1 (clone 9F4), was grouped by the Third International Workshop and Conference on Human Leucocyte Differentiation Antigens together with three other monoclonal antibodies (VIT 14, OKT 18A, and S152) in the new cluster CD27. In this paper we show that antibodies belonging to this cluster recognize an antigen present on a large subset of peripheral T lymphocytes and most medullary thymocytes. At least two different nonoverlapping epitopes were identified with directly labeled monoclonal antibodies. Immunoprecipitation studies indicate that the target antigen of CD27 antibodies is a polypeptide of 55 kDa, which appears in the form of a disulfide-linked homodimer on the T lymphocyte membrane (Tp55). Stimulation of T cells via the T3/T cell antigen-receptor complex, with either phytohemagglutinin or CD3 monoclonal antibodies, resulted in a fivefold increase in the membrane expression of Tp55, whereas activation by phorbol myristate acetate caused a marked down-regulation. Moreover, an additional molecule of 32 kDa was precipitated from the membrane of activated but not of resting T cells. Addition of CD27 antibodies to cultures stimulated with either phytohemagglutinin or CD3 monoclonal antibody led to enhanced proliferation, whereas no effect was observed in phorbol myristate acetate or interleukin 2-stimulated cultures. The possible role of the Tp55 antigen in T cell activation is discussed.     

Selection and characterization of human antibodies neutralizing Bacillus anthracis toxin

A less than adequate therapeutic plan for the treatment of anthrax in the 2001 bioterrorism attacks has highlighted the importance of developing alternative or complementary therapeutic approaches for biothreat agents. In these regards passive immunization possesses several important advantages over active vaccination and the use of antibiotics, as it can provide immediate protection against Bacillus anthracis. Herein, we report the selection and characterization of several human monoclonal neutralizing antibodies against the toxin of B. anthracis from a phage displayed human scFv library. In total 15 clones were selected with distinct sequences and high specificity to protective antigen and thus were the subject of a series of both biophysical and cell-based cytotoxicity assays. From this panel of antibodies a set of neutralizing antibodies were identified, of which clone A8 recognizes the lethal (and/or edema) factor binding domain, and clones F1, G11, and G12 recognize the cellular receptor binding domain found within the protective antigen. It was noted that all clones distinguish a conformational epitope existing on the protective antigen; this steric relationship was uncovered using a sequential epitope mapping approach. For each neutralizing antibody, the kinetic constants were determined by surface plasmon resonance, while the potency of protection was established using a two-tier macrophage cytotoxicity assay. Among the neutralizing antibodies identified, clone F1 possessed the highest affinity to protective antigen, and provided superior protection from lethal toxin in the cell cytotoxicity assay. The data presented provide the ever-growing arsenal of immunological and functional analysis of monoclonal antibodies to the exotoxins of anthrax. In addition it grants new candidates for the prophylaxis and therapeutic treatment against this toxin.     

One I region restriction determinant can associate with multiple antigenic epitopes

Studies presented in this paper show that T cell clones recognizing different epitopes of multideterminant antigens can be restricted by the same I-A molecule. These data further support the concept that a single I-A restriction site can present more than one antigenic epitope. This concept was supported by data on the proliferation of T cell clones reactive with either poly(L-Glu60, L-Ala30, L-Tyr10)n(GAT) or poly(Tyr, Glu)-poly D,L-Ala--poly Lys [(T,G)-A--L] which recognized different epitopes on these multideterminant antigens. Two clones recognizing different epitopes on the same multideterminant antigen can be blocked by the same monoclonal anti-I-A antibody. Additionally, the mutation in the Abm12 chain utilized in [B6.C-H-2bm12(bm12) X B10.A(4R)]F1 mice can affect the restriction determinant of clones recognizing different antigenic epitopes. These results suggest that in the strictest sense, the determinant selection theory is not tenable and would support the concept that T cell specificity is controlled by the T cell repertoire.     

Monoclonal antibodies against chicken type IV and V collagens: electron microscopic mapping of the epitopes after rotary shadowing

The location of the epitopes for monoclonal antibodies against chicken type IV and type V collagens were directly determined in the electron microscope after rotary shadowing of antibody/collagen mixtures. Three monoclonal antibodies against type IV collagen were examined, each one of which was previously demonstrated to be specific for only one of the three pepsin-resistant fragments of the molecule. The three native fragments were designated (F1)2F2, F3, and 7S, and the antibodies that specifically recognize each fragment were called, respectively, IA8 , IIB12 , and ID2 . By electron microscopy, monoclonal antibody IA8 recognized an epitope located in the center of fragment (F1)2F2 and in tetramers of type IV collagen at a distance of 288 nm from the 7S domain, the region of overlap of four type IV molecules. Monoclonal antibody IIB12 , in contrast, recognized an epitope located only 73 nm from the 7S domain. This result therefore provides direct visual evidence that the F3 fragment is located closest to the 7S domain and the order of the fragments must be 7S-F3-(F1)2F2. The epitope for antibody ID2 was located in the overlap region of the 7S domain, and often several antibody molecules were observed to binding to a single 7S domain. The high frequency with which antibody molecules were observed to bind to fragments of type IV collagen suggests that there is a single population of type IV molecules of chain organization [alpha 1(IV)]2 alpha 2(IV), and that four identical molecules must form a tetramer that is joined in an antiparallel manner at the 7S domain. The monoclonal antibodies against type V collagen, called AB12 and DH2 , were both found to recognize epitopes close to one another, the epitopes being located 45-48 nm from one end of the type V collagen molecule. The significance of this result still remains uncertain, but suggests that this site is probably highly immunoreactive. It may also be related to the specific cleavage site of type V collagen by selected metalloproteinases and by alpha-thrombin. This cleavage site is also known to be located close to one end of the type V molecule.     

Production of Monoclonal Antibodies to Guinea Pig Liver Transglutaminase

Monoclonal antibodies are now a powerful tool in biology and medicine. Transglutaminase has been implicated in diverse biological functions, and the characteristics of its catalytic action are suitable for applied enzymology. In this study, we produced hybridoma cells which synthesize monoclonal antibodies against guinea pig liver transglutaminase by fusing mouse myeloma cells with spleen cells of mouse immunized with the enzyme protein. Eight hybridoma clones (coded 2F, 4B, 7C, 8B, 8D, 8E, 9F and 11C) were selected to produce monoclonal antibodies. The subclass of IgG produced by clone 9F was IgG_2a and those from the seven other clones were all IgG₁ The 9F antibody inhibited transglutaminase activity, but the other antibodies did not. A solid-phase antibody-binding assay showed that of these antibodies, 8D antibody has the highest affinity to the antigen. Transglutaminase protein in crude liver extract was identified with Western blotting analysis using 8D antibody as the probe.     

Anti-idiotypic regulation of an insulin-reactive T cell clone

A series of MHC-restricted, bovine-insulin-(BI) reactive T cell clones were generated. The specificity of one group was shown to be for an insulin A-chain loop determinant; the other group apparently demonstrated specificity of a B-chain determinant and/or amino acid residue A4. Guinea pig anti-idiotypic antisera were prepared against two idiotypically related BI monoclonal antibodies of similar A-chain loop specificity. These reagents were able to modulate the antigen-specific proliferation of an insulin-reactive, A-chain loop-specific T cell clone. Because the monoclonal antibodies and the T cell clone recognize a similar molecular domain of the insulin molecule, these data suggest that the anti-idiotypic sera mimic an insulin-like determinant, perhaps by bearing an "internal image" of the antigen and thereby interfering with T cell antigen recognition. Further, these results suggest that such reagents may be useful in characterization of T cell antigen receptor specificity and lend further credence to the concept of idiotypic-anti-idiotypic regulation of the immune response.     

Expression of an onco-developmental antegen among avian species.

Rabbit antisera directed against an onco-developmental antigen on chicken red blood cells have been serologically dissected through specific adsorptions. It is now possible to detect 13 antigenic determinants with the fractionated antisera. The onco-developmental antigen referred to as chicken fetal-leukemic antigen (CFA) is fetal-specific in the white Leghorn chicken, being present on the embryonic but not adult peripheral red blood cells of non-being present on the embryonic but not adult peripheral red blood cells of non-leukemic birds. However, one or more of the onco-developmental antigenic determinants have been detected on adult peripheral red blood cells of non-Gallus avian species, as well as on red blood cells from two adult chicken varieties. For phylogenetic purposes, red blood cells from avian species were characterized for their combinations of CFA determinants. Comparisons among species revealed specific patterns of antigenic expression within phylogenetic groups. Several CFA determinants were restricted in their occurrence to species within a single family, and one determinant was found in all cases where CFA was expressed. The distribution of CFA determinants was used to determine immunological distances among four Galliform species. These distances agreed with the immunological relationships established using different serological markers.