Anti-interleukin-2 receptor monoclonal antibodies in renal transplantation

Bart D. Maes and Yves F. Vanrenterghem

Department of Nephrology, University Hospital Gasthuisberg, Leuven, Belgium

Correspondence and offprint requests to: Yves Vanrenterghem, Department of Nephrology, University Hospital Gasthuisberg, B-3000 Leuven, Belgium.E-mail: Yves.Vanrenterghem{at}UZ.K U Leuven.ac.be.

Introduction

Although life-long administration of a multi-drug regimen of aspecific small-molecular immunosuppressants is most frequently used to prevent rejection of the transplanted organ, the administration of anti-T cell antibodies in the immediate post-transplant period (induction therapy) as prophylaxis against rejection or as anti-rejection therapy is still advocated to improve long-term allograft outcome. However, older polyclonal (ALS–ATG) and monoclonal (OKT3) anti-T cell antibodies are associated with different side-effects: (i) the development of anti-xenogeneic antibodies is associated with decreased immunosuppressive effects, serum sickness and anaphylactic reactions with repeated administration, (ii) cross-reactions with non-T cell tissue (e.g. thrombopenia, leukopenia), (iii) morbidity due to target cell activating antigen-specific reactions (cytokine release syndrome), and (iv) aspecific over-immunosuppression (e.g. CMV-infection, post-transplant lymphoproliferative disorder (PTLD)) due to interference with cells not involved in the rejection process or induction of microbial proliferation by substances released from anti-T cell antibody activated cells. Recently monoclonal antibodies (mAb) directed against the interleukin-2 receptor (IL-2R) have been tested for clinical use.

The IL-2/IL-2 receptor pathway

Because IL-2-driven T-cell proliferation is a major feature of the acute rejection process, several mAb directed to the IL-2R have been developed to suppress the immune response against an allograft. When an appropriately processed and presented antigen interacts with the T cell receptor for that specific antigen, the resting T cell is activated leading to de novo synthesis and secretion of IL-2 and to expression of high-affinity IL-2Rs [1]. The IL-2R on resting T cells is composed of two polypeptide chains—IL-2Rß (CD122) and IL-2R{gamma} (CD132), forming an IL-2Rß{gamma} complex capable of binding IL-2 with intermediate affinity. After T cell activation with antigen, the {alpha}-chain (CD25, T-activation (Tac) antigen) is rapidly expressed and associates with the ß and {gamma} chains to form an IL-2{alpha}ß{gamma} complex, which in turn binds IL-2 with high affinity (Kd=10-11 M). The interaction of IL-2 with this receptor results in a rapid proliferation of the antigen-activated T cells (clonal expansion) leading to effector T cells with helper, suppressor or cytotoxic abilities. Depending on the epitope, some anti-IL-2R{alpha} mAbs block the association of the {alpha}-chain with ß{gamma} complex and the binding of IL-2 with its high-affinity receptor. Hence, the duration and magnitude of this antigen-specific immune response is suppressed by blocking only antigen-activated T cells, while cells (resting T cells, B cells, monocytes-macrophages) not involved in the immediate rejection process are not or minimally affected; moreover, no cytokine-release is induced, possibly because the {alpha}-chain is unable to cause signal transduction or internalization. In contrast, anti-IL-2Rß mAbs are less selective and effective but they inhibit IL-2 binding as well as lymphocyte activation and proliferation [2].

Development of IL-2R{alpha} monoclonal antibodies

Several murine and rat mAbs to the IL-2R{alpha} (anti-Tac [murine IgG2a] [3], 33B3.1 [rat IgG2a] [4], LO-Tact-1 [rat IgG2b] [5], BT563 [murine IgG1] [6]) have been developed and tested with a variable degree of success in humans. However, some disadvantages hindered their widespread clinical use: they have short half-lives in the circulation (<48 h) compared to human IgG (21 days), probably due to quick removal induced by naturally occurring anti-rat or anti-mouse (anti-Gal{alpha}1–3Gal) antibodies; they do not effectively recruit immune effector functions; and, sensitization (human anti-mouse [HAMA] or human anti-rat [HARA] antibodies), occurring in the majority of treated patients, may decrease their effect with repeated administration. In order to circumvent these drawbacks and to reduce the number of xenogeneic epitopes, hybridoma technology and recombinant genetic engineering with transfer of plasmids containing IgG gene sequences into mouse myeloma cells has been applied to produce chimeric and humanized antibodies. Chimeric antibodies consist of the entire variable region of the murine mAb fused with the human heavy and light chain constant regions; humanized antibodies only contain the hypervariable regions (complementarity-determining or antigen-binding regions) of the parent murine mAb fitted in the framework of a human IgG molecule. With these techniques, chimeric and humanized antibodies were produced without loss of antigen-specificity or significant loss of receptor- affinity but with longer half-lifes and without the potential to produce neutralizing antibodies. Moreover, chimeric and humanized antibodies are not only capable of reversible blocking of the IL-2R, but—unlike murine antibodies—also of inducing antibody-dependent cellular cytotoxicity (ADCC) with human targeted cells; the magnitude of ADCC is isotype-dependent (IgG1>IgG2b>IgG2a).

Clinical studies with IL-2R{alpha} monoclonal antibodies

Recently, two anti-IL-2R{alpha} mAbs have completed phase III trials [710]: (i) basiliximab (Simulect® : t1/2 : 6.5 days), a chimeric antibody and (ii) daclizumab (Zenapax® : t1/2 : 20 days), a humanized anti-Tac antibody. At a dose of 20 mg given prior to transplantation and at day 4, basiliximab maintains CD25 receptor saturation for 30 days. In two placebo-controlled phase III trials, basiliximab in combination with steroids and cyclosporin, significantly decreased the incidence of acute rejection at 6 months (–26 to -31%) and 12 months (–23 to -29%). Overall graft and patient survival rates at 12 months however, were similar with basiliximab and placebo. Daclizumab at a dose of 1 mg/kg given prior to transplantation and every 2 weeks thereafter for a total of five doses, provided effective CD25 saturation for a period of 90 days. A significant reduction in incidence of acute rejection episodes at 6 months was demonstrated in two placebo-controlled phase III studies, either in combination with steroids and cyclosporin (28 vs 47%) or with steroids, cyclosporin and azathioprine (22 vs 35%). Moreover, in combination with triple therapy, 6-month graft survival was significantly better in the daclizumab group. In the double therapy trial, 6-month patient survival was significantly better in the daclizumab group. Whether daclizumab is superior to basiliximab in terms of incidence of acute rejection, graft and patient survival needs to be determined; one might speculate that the slightly better results obtained with daclizumab in these trials is related to the more prolonged CD25 receptor saturation due to a longer half-life and the longer dosing schedule in the daclizumab studies. Basiliximab has the advantage that only two doses in the early postoperative days were given.

Both preparations are safe and well tolerated (no cytokine release syndrome) with comparable incidence and pattern of infections and so far no increase in malignancies compared with the placebo groups. Anaphylactic or allergic reactions and clinically significant antibody production has not been described until now. No significant changes in total T-cells, activated T-cells or T-cell subsets are noticed, apart from a significant decrease in circulating CD25+ lymphocytes and lymph node lymphocytes [9,11]; this suggests that besides competitive binding and saturating the CD25 receptor, down-regulation of IL-2R expression, shedding of antibody-bound IL-2R or destruction of activated T-cells by ADCC may play a role in the mechanism of action. Both agents are easy to administer via peripheral IV infusion during 15 min in an easy dosing schedule. Because of their pharmacokinetic properties, no adjustments in adults have to be made for weight, age, gender, race or presence of proteinuria [1214].

IL-2R{alpha} monoclonal antibodies: future prospects

Despite the promising results obtained with IL-2R{alpha} monoclonal antibodies, some questions have not been answered at present.

Conclusion

Monoclonal antibody therapy (no cross-reactivity with non-T cell tissue) against a carefully selected target antigen of a limited T cell population involved in the allograft immune response (IL-2R{alpha}) allows selective immunosuppression without morbidity due to antigen-specific target reactions (no cytokine-mediated first dose reaction) or over-immunosuppression (infection/malignancy). Chimerization or humanization of the antibody resulted in a prolonged circulatory half-life and the absence of clinically significant antibody response producing a more prolonged exposure to the infused immunosuppressant and the possibility of re-administration. Initial reports about their efficacy and safety and the ease of administration makes the use of anti-IL-2 receptor monoclonal antibodies very attractive for induction after renal transplantation. They probably will allow sparing of more toxic and less specific small-molecular immunosuppressive agents causing substantial long-term morbidities. However, controlled studies comparing IL-2R{alpha} mAbs with newer immunosuppressive agents, studies in high-risk renal allograft recipients, and long-term efficacy studies are warranted to determine their definitive place in the field of immunosuppressive therapy.

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