Val-boroPro accelerates T cell priming via modulation of dendritic cell trafficking resulting in complete regression of established murine tumors.

Although tumors naturally prime adaptive immune responses, tolerance may limit the capacity to control progression and can compromise effectiveness of immune-based therapies for cancer. Post-proline cleaving enzymes (PPCE) modulate protein function through N-terminal dipeptide cleavage and inhibition of these enzymes has been shown to have anti-tumor activity. We investigated the mechanism by which Val-boroPro, a boronic dipeptide that inhibits post-proline cleaving enzymes, mediates tumor regression and tested whether this agent could serve as a novel immune adjuvant to dendritic cell vaccines in two different murine syngeneic murine tumors. In mice challenged with MB49, which expresses the HY antigen complex, T cell responses primed by the tumor with and without Val-boroPro were measured using interferon gamma ELISPOT. Antibody depletion and gene-deficient mice were used to establish the immune cell subsets required for tumor regression. We demonstrate that Val-boroPro mediates tumor eradication by accelerating the expansion of tumor-specific T cells. Interestingly, T cells primed by tumor during Val-boroPro treatment demonstrate increased capacity to reject tumors following adoptive transfer without further treatment of the recipient. Val-boroPro -mediated tumor regression requires dendritic cells and is associated with enhanced trafficking of dendritic cells to tumor draining lymph nodes. Finally, dendritic cell vaccination combined with Val-boroPro treatment results in complete regression of established tumors. Our findings demonstrate that Val-boroPro has antitumor activity and a novel mechanism of action that involves more robust DC trafficking with earlier priming of T cells. Finally, we show that Val-boroPro has potent adjuvant properties resulting in an effective therapeutic vaccine.

Proteasome inhibitors as immunosuppressants: biological rationale and clinical experience.

Accumulating evidence supports the potential of proteasome inhibitors as immunosuppressants. Proteasome inhibitors interfere with antigen processing and presentation, as well as with the signaling cascades involved in immune cell function and survival. Both myeloma and healthy plasma cells appear to be highly susceptible to proteasome inhibitors due to impaired proteasomal activity in both cell types. As a consequence, these agents can be used to reduce antibody production and thus prevent antibody-induced tissue damage. Several clinical studies have explored the potential of bortezomib, a peptide boronate proteasome inhibitor, for treating immune disorders, such as antibody-mediated organ rejection and graft-versus-host disease (GVHD), with encouraging results. Here, we discuss the biological rationale for the use of proteasome inhibitors as immunosuppressive agents and review the clinical experience with bortezomib in immune-mediated diseases.

Lung transplantation across donor-specific anti-human leukocyte antigen antibodies: utility of bortezomib therapy in early graft dysfunction.

OBJECTIVE: To report the usefulness of bortezomib therapy in a sensitized lung transplant recipient experiencing antibody-mediated rejection. CASE SUMMARY: During a pretransplant evaluation, a 62-year-old woman with usual interstitial pneumonitis developed a diverticular bleed requiring transfusions, which elevated her panel reactive antibody to 98% for human leukocyte antigen (HLA) class I and 71% for class II. She underwent desensitization to decrease her panel reactive antibody levels. She received a double lung transplant across a weak HLA class II incompatibility but developed respiratory failure due to early graft dysfunction. On postoperative day (POD) 14 she was found to have donor-specific antibodies (DSA) to HLA class I and class II antigens. She received intravenous immunoglobulin (IVIG), plasmapheresis, and bortezomib to reduce the DSA. Repeat DSA testing on POD 80 demonstrated a 50% reduction in DSA, which became undetectable at POD 255. DISCUSSION: Antibody-mediated rejection (AMR) is difficult to diagnose and treat in lung transplantation. Since primary treatment options such as plasmapheresis and IVIG alone may not adequately eradicate DSA, the proteasome inhibitor bortezomib can be of additional value for the treatment of AMR. Bortezomib causes apoptosis of plasma cells, thus eliminating the production of allograft-specific DSA. CONCLUSIONS: This is the first report describing the utility of bortezomib for early graft dysfunction in a highly sensitized lung transplant recipient. Although this patient had preformed donor-specific anti-HLA antibodies, AMR was successfully treated with a combination of plasmapheresis, IVIG, and bortezomib. At time of writing, the patient continued to have excellent graft function 2 years posttransplant. Bortezomib is a potent inhibitor of plasma cell production and it appears to be useful for the treatment of antibody-mediated graft dysfunction.

Abrogation of anti-HLA antibodies via proteasome inhibition.

BACKGROUND: Current treatments for autoantibody-mediated diseases (i.e., systemic lupus erythematosus) and alloantibodies (in transplant) are minimally effective. Although they deplete naïve B cells, plasmablasts, and transiently reduce antibody concentrations, they are minimally effective against long-lived, antibody-producing plasma cells. In transplantation, plasma cells produce antibodies directed against human leukocyte antigen (HLA) antigens causing poor allograft survival. We report the first clinical experience with a plasma cell depleting therapy, bortezomib, to abrogate anti-HLA antibodies in transplantation (outside of rejection) in an attempt to improve long-term allograft survival. METHODS: Eleven patients with anti-HLA alloantibodies were treated with bortezomib. All patients underwent plasmapheresis to aid in removal of antibodies and to determine the effect of bortezomib. Serial measurements of anti-HLA antibody levels were conducted weekly by single antigen bead on Luminex platform. RESULTS: Bortezomib treatment elicited substantial reduction in both donor-specific antibody (DSA) and non-DSA levels. Antibodies were directed against DSA in 8 of 11 cases. Mean time to antibody appearance was 2 months posttransplant. Within 22 days (median) from treatment initiation, 9 of 11 patients' antibody levels dropped to less than 1000 mean fluorescence intensity. Of two patients without successful depletion, all had peak mean fluorescence intensity more than 10,000. At a mean follow-up of approximately 4 months posttreatment, all patients have stable graft function. Minimal transient side effects were noticed with bortezomib in the form of gastrointestinal toxicity, thrombocytopenia, and paresthesias. CONCLUSIONS: Bortezomib therapy effectively abrogates anti-HLA antibodies. Hence, removal of antibodies, by proteasome inhibition, represents a new treatment strategy for transplantation and may have benefit in autoimmune-related disease.

Immunosensing system for alpha-fetoprotein through boronate immunoaffinity column in combination with flow injection chemiluminescence.

A novel immunosensing system for determination of human alpha-fetoprotein (AFP) was proposed by using a boronate immunoaffinity column as the glycated antigen collector in combination with flow injection chemiluminescence. The column was fabricated by filling boronic acid-modified sepharose gel into a glass tube. With a sugar-boronic acid interaction, the AFP antigen could be effectively immobilized on the sepharose gel matrix. After an off-line incubation, the mixture of the analyte AFP and horseradish peroxidase-labeled AFP antibody (HRP-anti-AFP) was injected into the column. The free HRP-anti-AFP was trapped by the immobilized antigen in the column and detected via chemiluminescence due to its sensitive effect on the reaction of luminol and hydrogen peroxide. A calibration curve with two linear ranges of 5-120 and 300-1000 ng mL(-1) was obtained under the optimized conditions. The whole assay process including regeneration of the reactor can be completed in 36 min. The presented immunoassay exhibited a high sensitivity, a wide linear range, a low interference with other antigens and a good reproducibility. It is potentially used to detect the serum AFP level in clinical diagnosis.

The proteasome and its inhibitors in immune regulation and immune disorders.

The ubiquitin-proteasome pathway is a well-characterized mechanism deputed to the degradation of intracellular proteins. Proteasomal degradation intervenes in the regulation of numerous cellular functions including signal transduction, apoptosis, cell cycle, and antigen presentation. In vitro and in vivo studies have shown that both normal and malignant cells of the immune system are exquisitely affected by inhibition of proteasome activity. This property is currently exploited in the treatment of multiple myeloma and mantle cell lymphoma, two B-cell malignancies that respond to treatment with the proteasome inhibitor bortezomib. Pharmacological inhibitors of the proteasome also affect function and survival of B and T lymphocytes and of dendritic cells and were shown to reduce autoimmune and inflammatory manifestations in several models of immune-mediated disorders. The present review offers an overview of the mechanisms implicated in the immunomodulatory effects of proteasome inhibitors and discusses prospective future applications for these small molecules in immune and inflammatory diseases.