Orphan G protein-coupled receptor GPR56 plays a role in cell transformation and tumorigenesis involving the cell adhesion pathway.

GPR56 is an orphan G protein - coupled receptor, mutations of which have recently been associated with bilateral frontoparietal polymicrogyria, a rare neurologic disease that has implications in brain development. However, no phenotype beyond central nervous system has yet been described for the GPR56-null mutations despite abundant GPR56 expression in many non - central nervous system adult tissues. In the present study, we show that higher GPR56 expression is correlated with the cellular transformation phenotypes of several cancer tissues compared with their normal counterparts, implying a potential oncogenic function. RNA interference-mediated GPR56 silencing results in apoptosis induction and reduced anchorage-independent growth of cancer cells via increased anoikis, whereas cDNA overexpression resulted in increased foci formation in mouse fibroblast NIH3T3 cell line. When GPR56 silencing was induced in vivo in several xenograft tumor models, significant tumor responses (including regression) were observed, suggesting the potential of targeting GPR56 in the development of tumor therapies. The expression profiling of GPR56-silenced A2058 melanoma cell line revealed several genes whose expression was affected by GPR56 silencing, particularly those in the integrin-mediated signaling and cell adhesion pathways. The potential role of GPR56 in cancer cell adhesion was further confirmed by the observation that GPR56 silencing also reduced cell adhesion to the extracellular matrix, which is consistent with the observed increase in anoikis and reduction in anchorage-independent growth phenotypes. The oncogenic potential and apparent absence of physiologic defects in adult human tissues lacking GPR56, as well as the targetable nature of G protein - coupled receptor by small molecule or antibody, make GPR56 an attractive drug target for the development of cancer therapies.

A 96-well surrogate survival assay coupled with a special short interfering RNA vector for assessing cancer gene targets with enhanced signal/noise ratio and its utility in HTS for cancer therapeutic targets.

Transient transfection of short interfering RNAs to inactivate cancer therapeutic genes in cancer cells is an important method to induce therapeutic phenotypes (cell apoptosis, growth arrest, etc.) for cancer target validation. These phenotypes can be initially assessed by cell survival via colorimetric/fluorescence readings, e.g., alamarBlue (Trek Diagnostic Systems, Cleveland, OH) and WST-1. However, intrinsic problems exist for transient transfection-varying toxicity, inconsistent transfection efficiency, as well as other cell-specific determinants-which contribute to a low signal:noise ratio of the assays, rendering of the assay ineffective particularly when applied in high-throughput screening (HTS) multiplexed for different cells. This report describes a method using reporter as a "normalized surrogate" for the conventional survival readout in a 96-well format. In this approach, only the transfected surviving cells produce reporter activities, and many variables associated with transient transfection are excluded. A constitutively expressed reporter gene (luciferase or LacZ) expression cassette is co-transfected into cells along with a specially designed RNA interference (RNAi) vector (or a transgene for that matter). The reporter activity in either liquid cultures or in soft agar cultures in 96-well formats is then quantitated in situ. The RNAi vector construction is simplified so that it can be adapted to a 96-well format. Our data demonstrated that the relative reporter readings for survival are independent of both transfection efficiency and cellular toxicity. The signal:noise ratio is markedly increased, particularly for cells with low transfection efficiency. The assay is versatile and robust and can be applied in multiplexed HTS for cancer target identification and validation.

Synthetic peptides as cancer vaccines.

Effective cancer therapy or prevention has been the dream of physicians and scientists for many years. Although we are still very far from our ultimate goal of cancer prevention, significant milestones have been realized in terms of our knowledge base and understanding of the pathogenesis of cancerous cells and the involvement of the immune system against both self- and virus-associated tumor antigens. Immunotherapeutic strategies are now accepted to being superior in terms of the exquisite specificity that they offer in targeting only tumor cells as opposed to the existent chemotherapy or radiation therapy that is more general and invasive with many associated side effects. There are several immunotherapeutic strategies that are currently under investigation. This review primarily focuses on the significant advances made in the use of synthetic peptides in the development of subunit cancer vaccines. We have attempted to highlight some of the fundamental issues regarding antigen processing and presentation, Major Histocompatibility Complex (MHC) restriction, T-cell help, structural determinants in antibody recognition, and the use of these concepts in the rational design and delivery of peptide vaccines to elicit protective humoral and cell mediated immune responses. The recent use of costimulatory molecules and cytokines to augment immune responses also has been discussed along with the contributions of our laboratory to the field of synthetic peptide vaccine development.

A novel multivalent human CTL peptide construct elicits robust cellular immune responses in HLA-A*0201 transgenic mice: implications for HTLV-1 vaccine design.

Cytotoxic T-lymphocytes are critical in the clearance of chronic viral infections such as HTLV-1. Peptide-based vaccines may have potential application in invoking antiviral CTL responses. In the development of vaccination strategies, it is becoming increasingly important to elicit a broad immune response against several epitopes simultaneously that may provide large population coverage. In the present study, we addressed this issue, namely the processing and presentation of multiple CTL epitopes simultaneously for the generation of multispecific CTL responses. We designed a novel multivalent peptide consisting of three HLA-A(*)0201 restricted CTL epitopes, with intervening double arginine residues in tandem. These epitopes were derived from the HTLV-1 regulatory protein Tax, which is an attractive target for vaccine development against HTLV-1. Arginine residues were included to provide cleavage sites for proteasomes, to generate the intended MHC Class I ligands. Proteasomal digestion studies and mass spectrometry analysis showed cleavage of the multivalent construct to generate the individual epitopes. Immunization of HLA-A(*)0201 transgenic mice with this construct efficiently elicited cellular responses to each intended epitope in vivo, further validating the applicability of this approach. These data may have potential in the development of immunotherapeutic strategies for the treatment of HTLV-1 disease and in the future design of multivalent subunit peptide vaccines.

De novo design of peptide immunogens that mimic the coiled coil region of human T-cell leukemia virus type-1 glycoprotein 21 transmembrane subunit for induction of native protein reactive neutralizing antibodies.

Peptide vaccines able to induce high affinity and protective neutralizing antibodies must rely in part on the design of antigenic epitopes that mimic the three-dimensional structure of the corresponding region in the native protein. We describe the design, structural characterization, immunogenicity, and neutralizing potential of antibodies elicited by conformational peptides derived from the human T-cell leukemia virus type 1 (HTLV-1) gp21 envelope glycoprotein spanning residues 347-374. We used a novel template design and a unique synthetic approach to construct two peptides (WCCR2T and CCR2T) that would each assemble into a triple helical coiled coil conformation mimicking the gp21 crystal structure. The peptide B-cell epitopes were grafted onto the epsilon side chains of three lysyl residues on a template backbone construct consisting of the sequence acetyl-XGKGKGKGCONH2 (where X represents the tetanus toxoid promiscuous T cell epitope (TT) sequence 580-599). Leucine substitutions were introduced at the a and d positions of the CCR2T sequence to maximize helical character and stability as shown by circular dichroism and guanidinium hydrochloride studies. Serum from an HTLV-1-infected patient was able to recognize the selected epitopes by enzyme-linked immunosorbent assay (ELISA). Mice immunized with the wild-type sequence (WCCR2T) and the mutant sequence (CCR2T) elicited high antibody titers that were capable of recognizing the native protein as shown by flow cytometry and whole virus ELISA. Sera and purified antibodies from immunized mice were able to reduce the formation of syncytia induced by the envelope glycoprotein of HTLV-1, suggesting that antibodies directed against the coiled coil region of gp21 are capable of disrupting cell-cell fusion. Our results indicate that these peptides represent potential candidates for use in a peptide vaccine against HTLV-1.

Protective efficacy of multiepitope human leukocyte antigen-A*0201 restricted cytotoxic T-lymphocyte peptide construct against challenge with human T-cell lymphotropic virus type 1 Tax recombinant vaccinia virus.

Human T-cell lymphotropic virus type 1 (HTLV-1) is the causative agent of adult T-cell leukemia. Multiepitope T-cell vaccines are more likely to generate a broad long-lasting immune response than those composed of single epitopes. We recently reported a novel multivalent cytotoxic T-lymphocyte peptide construct derived from the Tax protein of HTLV-1 separated by arginine spacers that elicited high cellular responses against individual epitopes simultaneously in human leukocyte antigen (HLA)-A*0201 transgenic mice. We now report the effect of epitope orientation on the processing of the multiepitope construct by 20s proteasomes and the effect of the processing rates on the immunogenicity of the intended epitopes. A positive correlation was found between processing rates and the immunogenicity of the intended epitopes. The construct with the highest immunogenicity for each epitope was tested for protective efficacy in a preclinical model of infection using HTLV-1 Tax recombinant vaccinia virus and HLA-A*0201 transgenic mice. Mice vaccinated with the multiepitope construct displayed a statistically significant reduction in viral replication that was dependent on CD8 T cells. Reduction in viral replication was also confirmed to be specific to Tax-vaccinia virus. These results demonstrate the activation of Tax-specific CD8+ T cells by vaccination and are supportive of a multivalent peptide vaccine approach against HTLV-1 infections.