Binding characteristics of monoclonal antibodies raised against bovine growth hormone

A novel monoclonal antibody-based enzyme-linked immunosorbent assay to determine luteinizing hormone in bovine plasma

The development of a novel enzyme-linked immunosorbent assay (ELISA) for determining luteinizing hormone (LH) in bovine plasma is described. Anti-bovine LH (bLH) monoclonal antibodies (mAbs) were produced and characterized. One mAb recognizing the bLH β subunit was used for immunoaffinity purification of substantial amounts of biologically active bLH from pituitary glands. The purified bLH in combination with 2 anti-bLH β subunit mAbs was used to develop a sandwich ELISA, which satisfied all the criteria required to investigate LH secretory patterns in the bovine species. The ELISA standard curve was linear over the range 0.05 to 2.5 ng/mL, and the assay proved suitable for measuring bLH in plasma without any prior treatment of samples. Cross-reactivity and recovery tests confirmed the specificity of the method. The intra- and inter-assay coefficients of variation ranged between 3.41% and 9.40%, and 9.29% and 15.84%, respectively. The analytical specificity of the method was validated in vivo by provocative tests for LH in heifers, using the LH releasing peptide gonadotropin-releasing hormone. In conclusion, the adoption of mAbs for this ELISA for coating the wells and labeling, combined with the easy one-step production of reference bLH, ensures long-term continuity in large-scale measurements of LH in the bovine species.

Characterization of biologically active bovine pituitary FSH purified by immunoaffinity chromatography using a monoclonal antibody

A substantial amount of highly purified, biologically active bovine FSH was isolated from pituitary extracts by immunoaffinity chromatography based on a novel anti-bovine FSH beta-subunit monoclonal antibody. The biological activity was assessed in vitro using a steroidogenic granulosa cell line constitutively expressing the FSH receptor. Amino acid analysis, N-terminal amino acid sequencing, and peptide mass mapping demonstrated that primary structure modifications do not contribute to the heterogeneity of bovine FSH. The monosaccharide composition of the N-linked oligosaccharides was quantified and remarkably two distinct forms of sialic acids, N-acetyl- and N-glycolyl-neuraminic acids were found. In conclusion, we showed that isoform differences in bovine FSH is likely due only to sugar chain heterogeneity, and we give the first evidence that two substituted sialic acids contribute to the diversity of mammalian glycoprotein hormone isoforms.

Monoclonal antibodies as a probe for the unfolding of porcine growth hormone

Monoclonal antibodies (mAbs) were generated against pituitary porcine growth hormone (pGH). Ten mAbs were selected for their specificity and affinity for pGH. These mAbs were of the immunoglobulin G (IgG)(1) kappa subclass, with dissociation constants (K(d)) between 7.42 and 0.26 nM, and recognised seven non-overlapping epitopes. We measured whether the mAbs detected alterations of the pGH three-dimensional structure by comparing the antibody reactivity to native pGH and to pGH experimentally unfolded by heating at 50 degrees C, 75 degrees C and 100 degrees C or by reduction and S-carboxymethylation. The antibody-antigen interactions were studied with two enzyme-linked immunosorbent assays (ELISA), based either on a direct binding or inhibition format. The results show that: 1) one mAb, mAb D12, is a conformation-sensitive antibody that recognises an epitope present only in the native pGH. Because the intact three-dimensional structure is essential for the expression of biological activity, mAb D12 could be used to detect altered pGH molecules in biological samples (blood, pituitary extracts or material produced with recombinant technology), and for the one-step purification of biologically active pGH by immunoaffinity chromatography; 2) one mAb, mAb I4, binds to a linear epitope that is not significantly modified in the denatured hormone. This mAb was able to detect the hormone in assays where protein conformation is usually strongly altered, i.e. immunoblotting and immunohistochemistry; 3) the performances of the other eight mAbs differed significantly in the competitive and non-competitive ELISA.

Monoclonal antibody against human growth hormone receptor

GHR shows a high degree of homology with the prolactin receptor and with the other receptors that belong to the hemopoietic receptor superfamily. This paper describes a monoclonal antibody (MAb) (2B4B6) specific for both the extracellular domain of human GHR and human growth hormone (GH) binding protein. Mice were immunized against a seven-aminoacid peptide sequence screened by FASTA (sequence similarity search served by Genome-Net) from the European Bioinformatics Institute to exclude the existence of human membrane proteins with significant sequence homology. MAbs were screened against the peptide sequence and 2B4B6 was selected for its capability to recognize the full-length hGHBP. As evaluated by both enzyme-linked immunoadsorbent assay (ELISA) and FACS analysis, this MAb seems to recognize and bind to a hGHR positive cell line, IM-9, as well as a murine cell line, BaF3 (8/6), transfected with a chimeric construct, hGHR/hG-CSFR and expressing hGHR on the cell membrane. Studies investigating the biological effects of this MAb showed that anti-hGHR mediated inhibition of cell proliferation was not due to competition with GH binding but rather to prevention of receptor dimerization. Because of its specificity, this MAb may be usefully applied in situations in which GHR and receptors with a high degree of homology, such as PRLR (prolactin receptor), are expressed simultaneously, as occurs in the immune system.

Structure and function of bovine growth hormone. Bovine growth hormone as an experimental model for studies of protein-protein interactions

Growth hormone (GH) is a polipeptide that controls the differentiation, growth and metabolism of many cell types, and is secreted from the hypophysis of all vertebrate species tested so far. Despite the overlapping evolutionary, structural, immunological and biological properties, it is well-known that GHs from distinct mammalian species have significant species-specific characteristics. The main purpose of this review is to highlight bovine GH (bGH) structural features related to its species-specific properties. Novel interest in bGH is also aroused by the advent of biotechnological methods for production of recombinant proteins. In fact recombinant bGH will have a great importance in veterinary medicine research and as a 'high tech' drug that needs to be monitored in zootechnical productions.

Structural analysis of bovine somatotropin using monoclonal antibodies and the conformation-sensitive immunoassay

Bovine somatotropin was studied with respect to thermal stability, quantitative thermal denaturation kinetics, and refolding potential following thermal denaturation using a panel of 6 monoclonal antibodies and the Conformation-Sensitive Immunoassay (CSI). The antibody panel consisted of 4 conformation-dependent and 2 sequence-specific antibodies. Each of the antibodies revealed unique thermal stability profiles for their respective epitopes suggesting that they each recognize different antigenic determinants. Comparing the thermal stability profiles generated with these antibodies allowed the stability of bovine somatotropin to be "dissected" based on individual structural features. The degree to which bovine somatotropin is stabilized by disulfide bonds was examined using CSI-based quantitative thermal denaturation kinetics profiles generated under reducing and nonreducing conditions. All of the conformational epitopes unfolded faster under reducing conditions indicating that the two disulfide bonds within the somatotropin molecule impart some degree of global stabilization. The ability of bovine somatotropin to refold after reducing or nonreducing thermal denaturation was also examined using the antibody panel and the CSI. The results show that, although significant refolding was evident for some epitopes, bovine somatotropin cannot refold to the native state following thermal denaturation under either reducing or nonreducing conditions.

Monoclonal antibodies against recombinant human growth hormone as probes to study immune function

Monoclonal antibodies were raised against human recombinant growth hormone (rhGH) and those that did not cross-react with other human recombinant proteins like prolactin (PRL), interleukin 2 (IL-2), insulin, or bovine pituitary growth hormone were selected. The selected hybridoma supernatants were studied for their ability to influence T lymphocyte proliferation when induced either by a mitogen, such as phytohemagglutinin (PHA), or by alloantigen. All supernatants inhibited proliferation. Three MAbs were then purified by several passages on antimouse IgG (or IgM)-agarose columns, and characterized. These MAbs recognized three different epitopes, as revealed by competition study, although their inhibitory effect on PHA-induced T cell proliferation was quite similar. The data demonstrate that the MAbs were not cytolytic, that they did not interfere with the PHA binding to T cell membranes, and, as revealed by FACS analysis, did not bind to the membrane. Finally, these MAbs immunoprecipitated a 44-kDa molecule from PHA-activated T cell-concentrated supernatants. These data indicate that the MAbs recognized a soluble factor that plays a central role in T cell proliferation and that is probably the immune growth hormone.

Monoclonal antibodies can reveal immunoreactivity differences between pituitary and recombinant bovine growth hormone

Monoclonal antibodies (MAbs) to pituitary bovine growth hormone (bGH) were used to assay the immunoreactivity of a recombinant form of bGH. The recombinant hormone used differed from the pituitary principally in the presence of a short amino acid sequence starting with methionine added to the N-terminal end of the molecule. Monoclonal antibody 1D2 recognized the recombinant hormone with greater affinity than the pituitary hormone, whereas MAb 5G1 bound the recombinant molecule with a lower strength than the pituitary. The other MAbs showed different behavior depending on the type of immunoassay used. Results indicate that the recombinant bGH molecule has been altered in its immunological structure, and suggest a possible interaction of the added N-terminal fragment with the three-dimensional structure of the hormone.

Identification of antigenic differences of recombinant and pituitary bovine growth hormone using monoclonal antibodies

For characterization and determination of recombinant bovine GH (rbGH) eight monoclonal antibodies (MAb) were produced against rbGH from Monsanto. The various MAb showed different affinities to rbGH, pituitary bovine GH (pbGH), and pituitary ovine GH (poGH). With epitope analysis several MAb were shown to recognize different epitopes of rbGH. The MAb MUC-rbGH-3A11 and MUC-rbGH-1E5 were used to develop a Sandwich ELISA. By checking the specificity of the assay no cross reactivity was found with pituitary porcine GH, pituitary human GH, bovine or ovine prolactin and little cross reactivity with poGH could be found. The Sandwich ELISA detected various rbGH (Monsanto, Elanco, Cyanamid) with different N-terminal amino acids and discriminated between rbGH and pituitary bovine GH by an affinity factor of 2.0. The detection level was 2 ng rbGH per ml PBS buffer. The recovery was about 86% in bovine serum. It might therefore be possible to detect rbGH-treated cows using a Sandwich ELISA, but this would need a field study.

An immuno-dominant sequential epitope recognized by mouse anti-recombinant bovine growth hormone antisera

The sequential epitopes on bovine growth hormone (bGH) recognised by five polyclonal mouse antisera have been identified by scanning with multiple pin-bound peptides. Four main epitopes were identified at residues 29-40, 101-110, 139-152 and 181-191. Of these, only epitope 139-152 is recognised by all five mouse antisera indicating that, for the mouse, this may represent an immuno-dominant region of the bGH molecule.