Induction of anti-tumor immunity with epidermal cells pulsed with tumor-derived RNA or intradermal administration of RNA.
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The skin is well-suited to serve as a substrate for vaccination strategies. In this regard, epidermal cells exposed to granulocyte-macrophage colony-stimulating factor can, upon subcutaneous injection into naive mice, present a soluble extract of tumor as a source of tumor-associated antigens for the induction of in vivo anti-tumor immunity. Use of RNA for immunization has a potential advantage over this technique. Because RNA can be amplified, only a small amount of tumor is needed for antigen preparation and, as with a soluble extract, it is not necessary to know the molecular nature of the antigen(s) relevant to immunity. To test the hypothesis that RNA-pulsed epidermal cells can induce anti-tumor immunity, total cellular RNA was isolated from the S1509a spindle cell tumor and used to pulse CAF1 epidermal cells enriched for Langerhans cell content and pre-exposed to granulocyte-macrophage colony-stimulating factor. These cells were then injected subcutaneously into naive CAF1 mice three times at weekly intervals followed by challenge with living S1509a cells. Tumor growth was significantly less than in control animals immunized in an identical fashion but with irrelevant RNA. Digestion of S1509a RNA with RNase prior to pulsing of epidermal cells prevented the development of immunity. In separate experiments, intradermal injection of S1509a RNA into naive mice three times at weekly intervals also induced immunity to challenge with the tumor. Digestion of S1509a RNA with RNase also prevented development of immunity in this system. Effective anti-tumor immunity can be induced in mice utilizing RNA-pulsed epidermal cells for in vivo immunization or by injecting RNA intradermally into naive mice. (+info)
Sensitization of tumour cells to lysis by virus-specific CTL using antibody-targeted MHC class I/peptide complexes.
(50/1721)
A number of cell surface molecules with specificity to tumour cells have been identified and monoclonal antibodies (mAb) to some of these antigens have been used for targeting tumour cells in vivo. We have sought to link the powerful effector mechanisms of cytotoxic T-cells with the specificity of mAb, by targeting recombinant HLA class I molecules to tumour cells using an antibody delivery system. Soluble recombinant MHC class I/peptide complexes including HLA-A2.1 refolded around an immunodominant peptide from the HIV gag protein (HLA-A2/gag) were synthesized, and the stability of these complexes at 37 degrees C was confirmed by enzyme-linked immunosorbent assay using a conformation-specific antibody. MHC class I-negative lymphoma cells (Daudi) were labelled with a biotinylated mAb specific for a cell surface protein (anti-CD20) then linked to soluble biotinylated HLA-A2/gag complexes using an avidin bridge. Flow cytometry revealed strong labelling of lymphoma cells with HLA-A2/gag complexes (80-fold increase in mean channel fluorescence). CTL specific for HLA-A2/gag efficiently lysed complex-targeted cells, while control CTL (specific for an HLA-A2.1-restricted epitope of melan-A) did not. Similarly, SK-mel-29 melanoma cells were also efficiently lysed by HLA-A2/gag-specific CTL when HLA-A2/gag complexes were linked to their surface via the HMW-MAA specific anti-melanoma antibody 225.28s. With further consideration to the in vivo stability of the MHC class I/peptide complexes, this system could prove a new strategy for the immunological therapy of cancer. (+info)
The CD45 tyrosine phosphatase regulates Campath-1H (CD52)-induced TCR-dependent signal transduction in human T cells.
(51/1721)
Campath-1H, a humanized mAb undergoing clinical trials for treatment of leukemia, transplantation and autoimmune diseases, produces substantial lymphocyte depletion in vivo. The antibody binds to CD52, a highly glycosylated molecule attached to the membrane by a glycosylphosphatidylinositol anchor. Cross-linked Campath-1H is known to activate T cells in vitro. We have investigated the molecular basis for these effects by comparing the protein tyrosine phosphorylation signals induced by Campath-1H and the CD3 mAb OKT3 in primary T cells, and in CD45(+)TCR(+), CD45(-)TCR(+) and CD45(+)TCR(-) Jurkat subclones transfected with CD52. Our results show that Campath-1H triggers similar tyrosine phosphorylation events as OKT3 in both primary T cells and in the CD45(+)TCR(+) Jurkat sub-clone, albeit at quantitatively lower levels. However, no phospholipase C gamma 1 activation nor calcium signals were detected in response to CD52 ligation. The CD52-mediated induction of protein tyrosine phosphorylation was absolutely dependent upon the expression of both the TCR and the CD45 phosphotyrosine phosphatase at the cell surface. Cross-linking of Campath-1H was essential for signal transduction in all cells investigated. Fluorescence resonance energy transfer was used to demonstrate CD52 homo-association at the cell surface in Jurkat T cells in a TCR- and CD45-independent manner, and CD52-TCR association in CD45(+)TCR(+) cells. We propose a model to explain the activating effects of Campath-1H in which CD52 mAb cross-linking causes the trapping of TCR polypeptides within molecular complexes at the cell surface, thereby inducing signals via the TCR by a process which depends on the CD45-mediated regulation of the p56(lck) and p59(fyn) tyrosine kinases. (+info)
Detection of circulating anti-p53 antibodies in esophageal cancer patients.
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It has been reported that circulating anti-p53 antibodies (p53-Ab) in the serum are detected in some cancers. To investigate the usefulness of detecting p53-Ab, we measured the circulating p53-Ab in comparison with squamous cell carcinoma antigen (SCC-Ag) in patients with esophageal carcinoma. Serum specimens from 46 esophageal cancer patients (42 squamous cell carcinomas, 3 mucoepidermoid carcinomas and 1 basaloid squamous carcinoma) and 13 healthy subjects were studied. Serum p53-Ab was measured by an enzyme-linked immunosorbent assay. Surgically resected specimens from 43 patients were immunohistochemically stained for p53. Serum SCC-Ag was measured by a radioimmunoassay. The results were analyzed with the clinical data and outcome. Serum p53-Ab was detected in 13 (28%) of the 46 patients, but not in any of the healthy subjects. The positive rate was 0% (0/6) in stage I, 60% (3/5) in stage IIA, 30% (3/10) in stage IIB, 29% (7/24) in stage III and 0% (0/1) in stage IV. There was no difference in the outcome between the p53-Ab-positive and p53-Ab-negative patients. Immunohistochemically, 30 (70%) of the 43 specimens stained positively for p53. Serum p53-Ab was detected in 43% (13/30) of the patients with tumors which stained positively for p53. There was a close correlation between positivity for p53 immunostaining and positivity for p53-Ab (p<0.01). An elevated level of SCC-Ag was found in only 13%of the patients, and most patients positive for SCC-Ag already had advanced disease with lymph node metastasis and invasion to the adventitia. In conclusion, serum p53-Ab was detected in Japanese esophageal cancer patients at a frequency similar to that reported in Western countries. Serum p53-Ab may be a potentially useful molecular marker for detection and screening of esophageal cancer. Further studies of a large population may be required to elucidate the true diagnostic usefulness of measuring the serum p53-Ab. (+info)
Serological identification of embryonic neural proteins as highly immunogenic tumor antigens in small cell lung cancer.
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Serological analysis of expression cDNA libraries (SEREX) derived from two small cell lung cancer (SCLC) cell lines using pooled sera of SCLC patients led to the isolation of 14 genes, including 4 SOX group B genes (SOX1, SOX2, SOX3, and SOX21) and ZIC2. SOX group B genes and ZIC2 encode DNA-binding proteins; SOX group B proteins regulate transcription of target genes in the presence of cofactors, whereas ZIC2 is also suspected to be a transcriptional regulator. These genes are expressed at early developmental stages in the embryonic nervous system, but are down-regulated in the adult. Although SOX2 mRNA can be detected in some adult tissues, ZIC2 is expressed only in brain and testis, and SOX1, SOX3, and SOX21 transcripts are not detectable in normal adult tissues. Of SCLC cell lines tested, 80% expressed ZIC2 mRNA, and SOX1, SOX2, and SOX3 expression was detected in 40%, 50%, and 10%, respectively. SOX group B and ZIC2 antigens elicited serological responses in 30-40% of SCLC patients in this series, at titers up to 1:10(6). In sera from 23 normal adults, no antibody was detected against SOX group B or ZIC2 proteins except for one individual with low-titer anti-SOX2 antibody. Seroreactivity against SOX1 and 2 was consistently higher titered than SOX3 and 21 reactivity, suggesting SOX1 and/or SOX2 as the main antigens eliciting anti-SOX responses. Although paraneoplastic neurological syndromes have been associated with several SCLC antigens, neurological symptoms have not been observed in patients with anti-SOX or anti-ZIC2 antibodies. (+info)
SEREX analysis for tumor antigen identification in a mouse model of adenocarcinoma.
(54/1721)
Evaluation of immunotherapy strategies in mouse models of carcinoma is hampered by the limited number of known murine tumor antigens (Ags). Although tumor Ags can be identified based on cytotoxic T-cell activation, this approach is not readily accomplished for many tumor types. We applied an alternative strategy based on a humoral immune response, SEREX, to the identification of tumor Ags in the murine colon adenocarcinoma cell line MC38. Immunization of syngeneic C57BL/6 mice with MC38 cells by three different methods induced a protective immune response with concomitant production of anti-MC38 antibodies. Immunoscreening of an MC38-derived expression library resulted in the identification of the endogenous ecotropic leukemia virus envelope (env) protein and the murine ATRX protein as candidate tumor Ags. Northern blot analysis demonstrated high levels of expression of the env transcript in MC38 cells and in several other murine tumor cell lines, whereas expression in normal colonic epithelium was absent. ATRX was found to be variably expressed in tumor cell lines and in normal tissue. Further analysis of the expressed env sequence indicated that it represents a nonmutated tumor Ag. Polynucleotide immunization with DNA encoding the env polypeptide resulted in strong and specific antibody responses to this self Ag in all immunized mice. Thus, SEREX offers a rapid means of identifying tumor Ags in murine cancer models. (+info)
Divalent forms of CC49 single-chain antibody constructs in Pichia pastoris: expression, purification, and characterization.
(55/1721)
Single-chain variable fragments (scFvs) are tumor-recognition units that hold enormous potential in antibody-based therapeutics. Their clinical applications, however, require the large scale production and purification of biologically active recombinant scFvs. In the present study, we engineered and expressed divalent non-covalent [(scFv)(2)-His(6)] and covalent [sc(Fv)(2)-His(6)] scFvs of a tumor-associated monoclonal antibody (MAb) CC49 in Pichia pastoris. The purity and immunoreactivity of the scFvs were analyzed by SDS-PAGE, HPLC, and competitive ELISA. The binding affinity constant (K(A)), determined by surface plasmon resonance analysis using BIAcore, was 4.28 x 10(7), 2.75 x 10(7), and 1.14 x 10(8) M(-1) for (scFv)(2)-His(6), sc(Fv)(2)-His(6), and CC49 IgG, respectively. The expression of scFvs in P. pastoris was 30 to 40-fold higher than in Escherichia coli. Biodistribution studies in athymic mice bearing LS-174T human colon carcinoma xenografts showed equivalent tumor-targeting of CC49 dimers generated in yeast (scFv)(2)-His(6) and bacteria (scFv)(2) with 12.52% injected dose/gram (%ID/g) and 11. 42%ID/g, respectively, at 6 h post-injection. Interestingly, the pharmacokinetic pattern of dimeric scFvs in xenografted mice exhibited a slower clearance of His-tagged scFvs from the blood pool than scFvs lacking the His-tag (0.1 >/= p >/= 0.05). In conclusion, improved yields of divalent scFvs were achieved using the P. pastoris expression/secretion system. The in vitro and in vivo properties of these scFvs suggest possible therapeutic applications. (+info)
Analysis and reversal of the inhibition of cytophilic antibody receptors produced by antibody.
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Administration of hyperimmune antibody to leukemia L1210 to allogeneic mice inhibited the development of macrophage-mediated immunity to L1210 in those hosts. In contrast to immunized mice, animals pretreated with antibody showed rapid activation of their peritoneal macrophages, followed by their disappearance and the inability of the residual peritoneal monocytic cells to attach L1210 cells even in the presence of proved cytophilic antibody to L1210. The inhibitory activity of the antibody, which resided entirely in its IgG2 fraction, was manifested only when the specific antigen (L1210 cells) was also injected within 2 days. Pretreatment with antibody to a different leukemia, EL4, failed to inhibit the monocytic uptake of L1210, but it did inhibit uptake of EL4 by monocytes if injected with its homologous antigen. Restoration of the functional capacity of macrophages was accomplished by injecting 1 X 10-7 bone marrow cells i.v. into "suppressed" mice, but 1.5 X 10-7 thymocytes failed to correct the defect. Significantly, thymocytes antagonized the restorative capability of bone marrow cells when they were injected concomitantly. These results indicate that specific inhibition of cytophilic antibody receptors on monocytes could be accomplished through a direct mechanism involving activation and exhaustion of macrophages and an indirect mechanism, perhaps mediated through "suppressor" thymus-derived cells. Although enhancement of the growth of leukemia cells did not occur, several parallels exist in mice with enhanced growth of different tumors. This inhibiotry phenomenon may thus represent another instance of "blocking" in tumor immunity, where the target of suppressive antibody-antigen is the macrophage as well as the lymphocyte. (+info)