Investigation of factors influencing the immunogenicity of hCG as a potential cancer vaccine.

Human chorionic gonadotrophin (hCG) and its ß-subunit (hCGß) are tumour autocrine growth factors whose presence in the serum of cancer patients has been linked to poorer prognosis. Previous studies have shown that vaccines which target these molecules and/or the 37 amino acid C-terminal hCGß peptide (hCGßCTP) induce antibody responses in a majority of human recipients. Here we explored whether the immunogenicity of vaccines containing an hCGß mutant (hCGßR68E, designed to eliminate cross-reactivity with luteinizing hormone) or hCGßCTP could be enhanced by coupling the immunogen to different carriers [keyhole limpet haemocyanin (KLH) or heat shock protein 70 (Hsp70)] using different cross-linkers [1-ethyl-3(3-dimethylaminopropyl)carboiimide (EDC) or glutaraldehyde (GAD)] and formulated with different adjuvants (RIBI or Montanide ISA720). While there was little to choose between KLH and Hsp70 as carriers, their influence on the effectiveness of a vaccine containing the BAChCGßR68E mutant was less marked, presumably because, being a foreign species, this mutant protein itself might provide T helper epitopes. The mutant provided a significantly better vaccine than the hCGßCTP peptide irrespective of the carrier used, how it was cross-linked to the carrier or which adjuvant was used when hCG was the target. Nonetheless, for use in humans where hCG is a tolerated self-protein, the need for a carrier is of fundamental importance. Highest antibody titres were obtained by linking the BAChCGßR68E to Hsp70 as a carrier by GAD and using RIBI as the adjuvant, which also resulted in antibodies with significantly higher affinity than those elicited by hCGßCTP peptide vaccine. This makes this mutant vaccine a promising candidate for therapeutic studies in hCGß-positive cancer patients.

Lipoxin A4 selectively programs the profile of M2 tumor-associated macrophages which favour control of tumor progression.

In tumor microenvironments, the macrophage population is heterogeneous, but some macrophages can acquire tumor-promoting characteristics. These tumor-associated macrophages (TAM) exhibit an M2-like profile, with deficient production of NO and ROS, characteristics of pro-inflammatory M1 cytotoxic macrophages. Lipoxins (LX) and 15-epi-lipoxins are lipid mediators which can induce certain features of M2 macrophages in mononuclear cells, but their effects on TAM remain to be elucidated. This study tested the hypothesis that ATL-1, a synthetic analogue of 15-epi-lipoxin A4 , could modulate TAM activity profile. We show that human macrophages (MΦ) differentiated into TAM-like cells after incubation with conditioned medium from MV3, a human melanoma lineage cell. Contrasting with the effects observed in other M2 subsets and M1 profile macrophages, ATL-1 selectively decreased M2 surface markers in TAM, suggesting unique behavior of this particular M2 subset. Importantly, these results were replicated by the natural lipoxins LXA4 and the aspirin induced 15-epi-LXA4 (ATL). In parallel, ATL-1 stimulated TAM to produce NO by increasing the iNOS/arginase ratio and activated NADPH oxidase, triggering ROS production. These alterations in TAM profile induced by ATL-1 led to loss of the anti-apoptotic effects of TAM on melanoma cells and increased their cytotoxic properties. Finally, ATL-1 was found to inhibit tumor progression in a murine model in vivo, which was accompanied by alterations in TAM profile and diminished angiogenesis. Together, the results show an unexpected effect of lipoxin, which induces in TAM a change from an M2- to an M1-like profile, thereby triggering tumor cell apoptosis and down-modulating the tumor progression.

Designing a new generation of anti-hCG vaccines for cancer therapy.

The heterodimeric 'pregnancy-specific' hormone human chorionic gonadotropin (hCG) has been used as the basis for a contraceptive vaccine. More recently, the observation that hCG, particularly in the form of the beta-chain expressed in the absence of alpha-chain, is aberrantly expressed in a number of different tumors has opened up a second potential application for such vaccines. Drawbacks of the currently available vaccines are that they are either relatively weakly immunogenic or that they induce antibodies that cross-react with human leuteinizing hormone (hLH). We have explored the possibility of creating mutated versions of the hCG beta-chain with improved immunologic properties.

Vaccines for the control of reproduction--status in mammals, and aspects of comparative interest.

The objective of producing vaccines which target elements of the reproductive system to control fertility has been pursued for many years. Of the many targets for such vaccines, several sperm-associated antigens have been proposed for antibody-mediated intervention before fertilization but the very abundance of antigen to be neutralized has been a barrier. Zona pellucida antigens associated with the surface of the oocyte have also been targeted and used successfully for control of 'wild' elephant populations but worries concerning immunopathologically-mediated tissue damage have been mooted. Vaccines using human chorionic gonadotropin (hCG) which is required for the implantation and maintenance of the fertilized egg, although of interest for the development of fertility control in human populations, has no relevance in the context of the present conference because external fertilization of fish eggs is independent. The pathways by which gonadotropin-releasing hormone (GnRH) secreted by the hypothalamus promote release of luteinizing (LH) and follicle-stimulating hormone (FSH) which govern the physiological maturation and maintenance of the reproductive organs, provide many targets for immunological intervention. Most consistent success has been reported using GnRH-based vaccines which are immunosterilizing in a variety of mammalian species such as pigs, rodents and white-tailed deer. The fact that the structure of the decapeptide, GnRH, has been maintained over so many years of evolution and been conserved across so many animal species, encourages the view that a strategy for control of sexual maturation in fish based upon stimulation of GnRH antibodies may well prove to be a practical proposition, provided the formulation of an appropriate highly immunogenic vaccine can be achieved.

Changes in the reproductive system of male mice immunized with a GnRH-analogue conjugated to mycobacterial hsp70.

Immunosterilization is an attractive alternative to surgical castration. Gonadotropin-releasing hormone (GnRH) controls the production of the gonadotropins thereby having an orchestrating effect on the reproductive hormone cascade and spermatogenesis. Induction of neutralizing antibody can abrogate the effect of the hormone. Current GnRH-based vaccines often require strong adjuvants and/or multiple injections of the vaccines to overcome variability in the response. Heat shock proteins (hsp) have been used as carrier molecules because of their powerful intrinsic ability to enhance an immune response to associated antigens. A GnRH-analogue, GnRH-d6-Lys, was conjugated to recombinant Mycobacterium tuberculosis hsp70. Male BALB/c mice were immunized i.p. with GnRH-hsp70 in the mild adjuvant Ribi or in incomplete Freund's adjuvant (IFA). The initial immunizations were done on pre-pubertal 3-week-old mice, with boosts at 5 and 8 weeks of age. The mice were killed at 10 weeks of age and GnRH-specific antibodies and serum testosterone levels measured. All the immunized mice mounted GnRH-specific antibody responses, with no difference in the mice immunized with GnRH-hsp70/Ribi or with GnRH-hsp70/IFA. There was substantial atrophy of the urogenital complex and significantly (P < 0.0005) reduced levels of testosterone-dependent testicular relaxin-like factor mRNA expression. Mice immunized with GnRH-hsp70/Ribi showed substantially reduced (P < 0.001) serum testosterone levels. These results indicate that hsp70 may serve as a particularly advantageous carrier for GnRH-based vaccines.

The major hormone-specific discontinuous epitopes on human chorionic gonadotrophin.

The hormone human chorionic gonadotrophin (hCG) shows extensive sequence homology with LH. Thus, many of the antigenic epitopes on hCG are shared with LH, leading to immunological cross-reaction between these two hormones. Anti-fertility and anti-cancer vaccines based upon hCG should ideally target only the hCG-specific epitopes. The hCG-unique linear epitopes located in the C-terminal peptide of the hCG beta-chain are well characterised. In contrast, the hCG-specific discontinuous epitopes, termed beta1, beta6 and beta7, have remained poorly defined. By generating hCG beta-chain molecules containing single amino acid substitutions we have identified R10, N13, R60 and Q89 as being important in the formation of the beta1 epitope, with R60 providing a particularly dominant residue. We also show that the amino acid residue Q89 contributes to the beta7 epitope, whilst D61 plays a role in both the beta6 and beta7 epitopes.

Placentally derived prostaglandin E2 acts via the EP4 receptor to inhibit IL-2-dependent proliferation of CTLL-2 T cells.

A number of immunomodulatory molecules are present in the placenta, including cytokines, prostaglandins, progesterone and indoleamine 2,3-dioxygenase. An undefined factor capable of down-regulating T-cell activity has recently been reported [1] as being produced by short-term cultures of placental fragments. By careful repetition of these studies we have confirmed that chorionic villi isolated from term placenta produce a low molecular weight, heat stable factor capable of inhibiting the IL-2-dependent proliferation of mouse CTLL-2 cells. This activity was not due, however, to a previously unknown immunosuppressive molecule, but rather to prostaglandin E2 (PGE2). Expression of cyclooxygenase (COX)-2 was detected in the syncytiotrophoblast of chorionic villi explants using immunohistochemistry. Culture of the explants in the presence of the COX-1/COX--2 inhibitors indomethacin and diclofenac, or with the COX-2-selective inhibitor DFP, blocked the production of the immunosuppressive factor. The immunosuppressive activity was restored by adding PGE2 to the supernatants obtained from diclofenac-inhibited explants. A number of different receptors are involved in mediating the biological effects of prostaglandins. By utilizing selective antagonists of individual receptors, we have established that the immunosuppressive effect of PGE2 on CTLL-2 cells is exerted via the EP4 receptor. Thus, addition of an EP4-selective antagonist, but not of EP1 or EP3 antagonists, abolished the immunosuppressive effect of PGE2 on CTLL-2 cells. This may have implications for attempts to selectively manipulate T-cell responses.

Refocusing of B-cell responses following a single amino acid substitution in an antigen.

Intranasal immunization of BALB/c strain mice was carried out using baculovirus-derived human chorionic gonadotrophin (hCG) beta-chain, together with Escherichia coli heat-labile enterotoxin. Gonadotrophin-reactive immunoglobulin A (IgA) was induced in a remote mucosal site, the lung, in addition to a systemic IgG response. The extensive sequence homology with luteinizing hormone (LH) results in the production of LH cross-reactive antibodies when holo-hCG is used as an immunogen. In contrast to wild-type hCGbeta, a mutated hCGbeta-chain containing an arginine to glutamic acid substitution at position 68 did not induce the production of antibodies which cross-react with LH. Furthermore, the epitopes utilized in the B-cell response to the mutated hCGbeta shifted away from the immunodominant region of the parent wild-type molecule towards epitopes within the normally weakly immunogenic C terminus. This shift in epitope usage was also seen following intramuscular immunization of rabbits. Thus, a single amino acid change, which does not disrupt the overall structure of the molecule, refocuses the immune response away from a disadvantageous cross-reactive epitope region and towards a normally weakly immunogenic but antigen-unique area. Similar mutational strategies for epitope-refocusing may be applicable to other vaccine candidate molecules.

Increased N-linked glycosylation leading to oversialylation of monomeric immunoglobulin A1 from patients with Sjögren's syndrome.

Increased serum immunoglobulin A (IgA) level is a common finding in primary Sjögren's syndrome (pSS). IgA might not be properly eliminated because of an abnormal glycosylation. We reported previously that IgA1 from patients with pSS was oversialylated. We extend this finding by showing that monomeric IgA1 contains more sialic acid (SA) in patients than in controls, as determined by enzyme-linked immunosorbent assay (ELISA) and Western blot with Sambucus nigra agglutinin (SNA), a lectin specific for SA. To localize this excess of SA on the N- and/or O-linked oligosaccharides, we analysed them separately, using N- and O-linked oligosaccharide profiling kits based on fluorophore-assisted carbohydrate electrophoresis. N-linked, but not O-linked, oligosaccharides of patients' IgA1 were oversialylated, and this seemed to be linked to an excess of SA on the same number of polysaccharides as normal IgA1. To localize the abnormality to the Fab and/or Fc fragments, monomeric IgA1 was digested with protease, separated and transferred to nitrocellulose, where SA was identified by SNA. Both Fab and Fc fragments appeared to be oversialylated. Oversialylation of N-linked oligosaccharides of IgA1 from patients with pSS might prevent the recognition of IgA by receptors that are responsible for their clearance, resulting in an excess of serum IgA and related immune complexes.

A low budget luminometer for sensitive chemiluminescent immunoassays.

We have designed a simple luminometer based on a reasonably priced Peltier-cooled charge-coupled device (CCD) camera, housed in a light-tight box, with straightforward lens imaging and a simple platform for a microtitre or other assay format. The quantitative readout of the CCD image is recorded on a PC using customised software. The instrument can be assembled in a standard university workshop for under pound3000, compared with the cheapest commercial instruments retailing at pound10,000 and above. Consistent with the general view on chemiluminescent assays, the sensitivity is 10-100 times greater than that obtained with parallel ELISA's using a chromogenic substrate. A unique feature of the CCD format is that it enables assays to be carried out on arrays of minidots and even nanodots of antigen on the floor of each microtitre well. This permits direct comparison and standardisation of reactivity of a single sample against several antigens and economy in the use of reagents, test sample and technician time; finger-prick samples of blood can be analysed. The instrument should have widespread applicability in developing countries and, indeed, in any laboratories with hard-pressed budgets.

Dual specificity antibodies using a double-stranded oligonucleotide bridge.

The covalent conjugation of oligonucleotides to antibody Fab' fragments was optimized by using oligonucleotides modified with a hexaethylene linker arm bearing three amino groups. One oligonucleotide was coupled to antibody of one specificity and a complementary oligonucleotide to antibody of a second specificity. The antibodies were then allowed to hybridize by base pairing of the complementary nucleotide sequences and the generation of bispecific antibody was analyzed on SDS-PAGE and confirmed using BIAcore analysis. The strategy of complementary oligonucleotide-linked bispecific molecules is not limited to antibodies but is applicable to linking any two molecules of different characteristics.

The effect of low-profile serine substitutions in the V3 loop of HIV-1 gp120 IIIB/LAI on the immunogenicity of the envelope protein.

Many microbial antigens contain powerful hypervariable epitopes that fail to induce broadly protective immunity because they dominate the immune response at the expense of more conserved but weaker epitopes. If the undesired B cell epitopes are eliminated, the immune system could be focused on the conserved epitopes and produce a stronger antibody response to conserved parts of the protein and thus become a more efficacious immunogen for a vaccine. We examined this possibility using the human immunodeficiency virus envelope glycoprotein (gp)120 IIIB/LAI and selectively replaced the amino acids from the V3 region and analyzed the overall immunogenicity of the mutant proteins after nucleic acid immunization in mice. The most variable residues of the human immunodeficiency virus type 1 gp120 V3 loop sequence were replaced with serine, which has a small uncharged hydrophilic side chain and therefore is likely to be less immunogenic than amino acids found in wildtype V3 sequences. The serine substitutions did not affect the ability of soluble CD4 to bind the mutant molecules compared with wildtype gp120 and monoclonal antibodies against both linear and discontinuous epitopes located in the V1/V2, C1, and C4 regions of the molecule. These data suggest that the V3 loop substitutions did not grossly affect the overall conformation of the envelope molecule. Immunization of CBA x BALB/c F1 mice with DNA expression plasmids for the wild-type gp120 sequence induced a predominantly IgGI antibody response with end point titers of 10(4)-5 x 10(4). The antibodies reacted only with conformationally intact gp120. Serine replacements targeted to both sides of the V3 loop had a major impact on gp120 immunogenicity, with a markedly reduced response in the majority of animals tested. Analysis of the epitope specificity of the responses suggests that N-terminal amino acids in the V3 loop contribute to the major immunodominant epitope and provides no evidence that their removal enhances immunogenicity of the conserved regions.

Epitopes of human chorionic gonadotropin and their relationship to immunogenicity and cross-reactivity of beta-chain mutants.

PROBLEM: Human chrionic gonadotropin (hCG) is a placental glycoprotein hormone, a heterodimeric molecule, consisting of alpha and beta chains. It induces the synthesis of progesterone, which is essential for the maintenance of the fertilized egg. Antibodies directed against hCG can, therefore, prevent pregnancy and serve as a vaccine. hCG belongs to the glycoprotein hormone family and shares the alpha chain with the other members. The beta chain is a hormone-specific subunit that is unique to hCG, but still possesses 85% amino acid homology with the beta chain of luteinizing hormone (LH), which means that prolonged immunization with hCG produces antibodies that cross-react with LH. METHOD OF STUDY: We have taken an approach involving the mutation of beta hCG to eliminate cross-reactive epitopes without affecting the natural folding of the polypeptide chain and thus the unique beta hCG-specific epitopes. RESULTS: Several mutants have been constructed that have maintained the binding to hCG-specific monoclonal antibodies (mAbs) but have lost the ability to bind to a panel of LH cross-reactive mAbs. To investigate the immunogenicity of selected mutants, mice were immunized with expression plasmid DNA, containing the gene for wild-type beta hCG and two mutants: mutant 3, with four amino acid substitutions (68 Arg-->Glu; 74 Arg-->Ser; 75 Gly-->His; 79 Val-->His), and mutant 7, with a single amino acid substitution (68 Arg-->Glu). CONCLUSIONS: Although both mutants were able to elicit antibody responses in at least some animals, the levels were less than those seen with the wild-type beta hCG DNA, and there seems still to be a residual cross-reactivity with LH. Attempts to improve the immunogenicity of the mutants and to further modify the sequence to remove the cross-reactivity are currently underway.

Can epitope-focused vaccines select advantageous immune responses?

One of the great success stories of preventive medicine is the achievement of protection against many pathogens by the simple procedure of vaccination. The rationale behind vaccination is to generate a protective immune response and an expanded population of memory cells ready to encounter the infectious agent, which will then elicit a potent secondary immune response. However, the development of effective vaccines against many pathogens has, so far, been unsuccessful. Many vaccines in current use fail to direct the immune response towards the epitopes that will ensure optimal protection. In these circumstances, can vaccines be produced that focus the immune system in a calculated, epitope-specific manner?

Enhancement in antigen binding by a combination of synergy and antibody capture.

The effects of orientating pairs of synergistic monoclonal antibodies (mAb) on binding of human chorionic gonadotropin (hCG) was studied by radioimmunoassay (RIA), enzyme-linked immunosorbent assay (ELISA) and surface plasmon resonance (SPR). Antibody synergy towards hCG required two functionally intact antibodies located adjacent to each other and with different epitope specificities. We investigated whether immobilization procedures avoiding protein denaturation, increasing proper orientation and promoting higher molecular flexibility of the synergistic mAb resulted in significantly enhanced antigen, binding. Synergistic mAb pairs captured through their Fc-region by protein G or a polyclonal serum against the Fc-part of mouse IgG could be used at 10-fold lower coating concentrations to achieve maximal binding of the analyte as compared with the same mAb pairs coated directly onto polystyrene. The synergistic effect observed with protein A used as capture varied greatly with the subclasses of the two synergistic antibodies employed. Scatchard analysis revealed that the number of functionally synergistic antibody sites participating in the binding of hCG for one mAb pair was about 10 times higher for the protein G-captured as compared with the directly coated synergistic pair. Biotinylated synergistic mAb pairs, coated directly or captured by streptavidin, did not display any enhanced antigen binding when tested in SPR or ELISA. With SPR, synergy was only observed when the synergistic mAb had been captured through their Fc-region. Using protein G or a polyclonal rabbit anti-IgG1 serum as capture reagents in SPR, synergistic triple mAb combinations against hCG were demonstrated.

Relative location of epitopes involved in synergistic antibody binding using human chorionic gonadotropin as a model.

We systematically screened a large panel of well-characterized monoclonal antibodies (mAb) directed towards various epitopes on human chorionic gonadotropin (hCG) for synergistic binding of 125I-hCG when they were adsorbed to a solid phase. The epitope locations involved in synergy were then related to the crystal structure of hCG and discussed in accordance with available data on the hCG epitopes. Enhanced binding of hCG was specific for certain pairs of mAb and was reflected in a 3-50-fold increased apparent functional affinity constant for hCG. Surface plasmon resonance revealed that when the mAb were captured by a polyclonal anti-IgG1 coupled to the Biacore chip, the off rates for hCG were significantly slower with synergistic mAb combinations than for the corresponding single mAb or nonsynergistic pairs of mAb, whereas the on rates did not differ appreciably. Each of the two antibodies involved in synergistic binding of hCG (more than 3-fold compared to additive binding of the two mAb) always belonged to a different epitope cluster in a separate antigenic domain on hCG. Synergistic epitope combinations on holo-hCG were located in similar structural planes. Combinations of mAb directed towards the epitope clusters alpha 2/beta 3/5, alpha 2/hCG beta CTP (C-terminal peptide) and beta 3/5/hCG beta CTP showed the strongest enhancement, with binding more than 10-fold greater than the sum of 125I-hCG bound to the individual mAb, followed by pairs of mAb directed towards the epitope groups beta 1/beta 3/5, c 1/2/beta 3/5, beta 1/alpha 2, and alpha 2/alpha 3/5 (3-9-fold). The greater frequency of synergy obtained with the linear epitopes of the hCG beta CTP can be ascribed to their greater molecular flexibility relative to the constrained discontinuous epitopes on hCG alpha and core-hCG beta (residues 1-112). In general, these studies provide a method for rapid screening of synergistic antibody pairs which also helps to identify non-overlapping epitopes that are accessible in similar structural planes. In turn, this facilitates the design of high-affinity bispecific antibodies targetted to a single antigen molecule.

Identification and selective destruction of shared epitopes in human chorionic gonadotropin beta subunit.

The feasibility of producing epitope-specific antigens by mutation of the gene is demonstrated, the aim being to eliminate unwanted surface epitopes yet allowing the natural folding of the protein to maintain the desired epitope(s). The model protein is the beta subunit of human chorionic gonadotropin (hCG beta) which previously has been used as an immunological contraceptive vaccine but has extensive cross-reaction with human luteinizing hormone. Of a series of mutants made, the mutant with substitutions of Glu for Arg 68, Ser for Arg 74, His for Gly 75 and His for Val 79, lost the ability to react with a panel of cross-reacting monoclonal antibodies while retaining the discontinuous and linear epitopes specific to the holo-hormone. In addition, allocation of amino acid residues to established epitope clusters could be made: residues 24, 25, 68 and 71 probably contribute to the cluster termed beta 3, residues 20, 21, 22, 75 and 77 to cluster beta 6 and residue 68 to clusters beta 2, beta 4 and beta 5.

Unique role of thyroxine in T cell recognition of a pathogenic peptide in experimental autoimmune thyroiditis.

We have previously demonstrated the importance of iodination and the requirement of the thyroxine residues in thyroglobulin (Tg) for the stimulation of two clonotypically distinct murine T cell hybridomas reactive against human and mouse Tg. We are now able to show that these T cell hybridomas only recognize an 11-residue peptide containing a thyroxine structure that has iodine at two positions on each ring. This iodination state is critical for recognition by these hybridomas as a peptide containing de-iodinated thyroxine is nonstimulatory. Furthermore we have demonstrated that a peptide lacking the thyroxine residue or containing de-iodinated thyroxine cannot block the recognition of the thyroxine-containing peptide. We suggest that in our system the thyroxine residue is involved in binding to major histocompatibility complex (MHC) class II molecules. We have also been able to show that the thyroxine residue is available for contact by the T cell receptor (TCR) as recognition of the peptide/H-2A(k) complex is blockable by an antibody directed against thyroxine. Using substituted peptides, we have been able partially to define the residues within the peptide that are critical for recognition of the 11-residue peptide by our hybridomas. From our data, we suggest that the thyroxine residue may bind the MHC and TCR, while the residues identified in the peptide backbone as important for the stimulation of the hybridomas may bind only the TCR.