NR4A orphan nuclear receptor family members, NR4A2 and NR4A3, regulate neutrophil number and survival.

The lifespan of neutrophils is plastic and highly responsive to factors that regulate cellular survival. Defects in neutrophil number and survival are common to both hematologic disorders and chronic inflammatory diseases. At sites of inflammation, neutrophils respond to multiple signals that activate protein kinase A (PKA) signaling, which positively regulates neutrophil survival. The aim of this study was to define transcriptional responses to PKA activation and to delineate the roles of these factors in neutrophil function and survival. In human neutrophil gene array studies, we show that PKA activation upregulates a significant number of apoptosis-related genes, the most highly regulated of these being NR4A2 and NR4A3 Direct PKA activation by the site-selective PKA agonist pair N6/8-AHA (8-AHA-cAMP and N6-MB-cAMP) and treatment with endogenous activators of PKA, including adenosine and prostaglandin E2, results in a profound delay of neutrophil apoptosis and concomitant upregulation of NR4A2/3 in a PKA-dependent manner. NR4A3 expression is also increased at sites of neutrophilic inflammation in a human model of intradermal inflammation. PKA activation also promotes survival of murine neutrophil progenitor cells, and small interfering RNA to NR4A2 decreases neutrophil production in this model. Antisense knockdown of NR4A2 and NR4A3 homologs in zebrafish larvae significantly reduces the absolute neutrophil number without affecting cellular migration. In summary, we show that NR4A2 and NR4A3 are components of a downstream transcriptional response to PKA activation in the neutrophil, and that they positively regulate neutrophil survival and homeostasis.

Conjugation of lymphoma idiotype to CD40 antibody enhances lymphoma vaccine immunogenicity and antitumor effects in mice.

Personalized immunotherapy of lymphoma based on tumor idiotype (Id) has shown anti-idiotype humoral immune responses in 40%-50% and cellular immune responses in 50%-75% of follicular lymphoma patients, indicating that this therapy can be clinically successful. We have developed a novel vaccine against lymphoma consisting of an anti-CD40 Ab (ADX40) chemically conjugated to the tumor idiotype A20 and tested it in a murine lymphoma model. BALB/c mice were immunized with 2 doses of immunogen alone or in conjunction with additional adjuvants before tumor challenge. ADX40-Id vaccination resulted in significantly retarded tumor growth and reduced mouse morbidity. Moreover, similar mouse survival was obtained with 2 injections of ADX40-Id as with 8 injections using the standard therapy of keyhole limpet hemocyanin Id + GM-CSF. Co-administration of ADX40-Id with 3-O-deacyl-4'-monophosphoryl lipid A further significantly enhanced vaccine efficacy, resulting in an increased overall survival. Anti-Id-specific Abs were detected at elevated levels after ADX40-Id immunization; however, in vivo depletion of CD4 and/or CD8 T cells before challenge showed that CD8 effector T cells were the major mediators of tumor protection. The results of the present study show that the ADX40-Id conjugate vaccine is a potential candidate as a stand-alone vaccine or in combination with currently licensed adjuvants for lymphoma immunotherapy.

CD154-CD40 interactions in the control of murine B cell hematopoiesis.

Interactions between CD40 and CD154 play a very important role in control of immune responses, including the delivery of T cell help to B cells and other APCs. Thus far, there has been no role postulated for CD40-CD154 interactions in hematopoiesis. We show here that CD40 is expressed on murine pro-B cells and that its ligation enhances pro-B cell proliferation in vitro and in vivo. In addition, CD154 mRNA is present in the BM. Moreover, we show that a deficiency in CD154 expression has effects on B cell hematopoiesis. Aged, CD154-deficient mice have significantly lower levels of B hematopoietic subsets downstream of pro-B cells in the BM. In addition, B lineage cells reconstitute more slowly following BMT into CD154-deficient recipients. We hypothesize that CD154 is expressed by radio-resistant cells in the BM and plays a role in fine-tuning B cell hematopoiesis.

Antibodies against cell surface antigens as very potent immunological adjuvants.

We describe here two very potent adjuvant systems which are thought to work directly on antigen specific lymphocytes, thus by-passing the normal route for adjuvants, which is to activate antigen presenting cells (APCs) inducing release of inflammatory cytokines with resultant side effects of local and systemic reactogenicity. CD40 and CD28 based adjuvants are extremely potent and should avoid the inflammatory side effects induced by most adjuvants.

Co-stimulatory agonists as immunological adjuvants.

The considerable advances made in the fields of molecular biology, genomics, proteomics and protein engineering have led to the identification of a vast range of potential vaccine antigens for a host of man's most serious diseases. However, experience informs us that vaccines based on recombinant proteins and synthetic peptides lack the immunogenicity of the whole, killed pathogens used in traditional vaccines and, as such, clinical use of these immunogens remains negligible. In order to fully realize the potential benefits of recombinant antigen-based vaccines there is a pressing need to identify powerful adjuvants which can safely enhance these weak responses with a minimum of undesirable side effects. Adjuvant research represents a vibrant and fast moving field and recent developments suggest the goal of generating effective, safe and affordable ways of enhancing immune responses appears to be almost within our grasp. The purpose of this article is to review recent advances in adjuvant development using approaches that directly exploit the immune system's own co-stimulatory pathways to exert their function; with a particular emphasis on CD40 and CD28 based therapies.

CD40 antibody as a potent immunological adjuvant: CD40 antibody provides the CD40 signal to B cells, but does not substitute for T cell help in responses to TD antigens.

Agonistic antibodies against CD40 have great potential as immunological adjuvants. We have shown that CD40mAbs induce strong antibody responses against conjugated antigen, and that this enhancement of responses extends to any sequence physically associated to the CD40 binding moiety, including the antibody's own Fc region. Thus, the CD40mAb acts as a model immunogen, containing both antigenic (i.e. Fc portion) and CD40 binding motifs (i.e. CD40 binding moiety). Using this system we examine here whether CD40mAb is able to directly mimic T cell help to B cells. CD40mAbs have no adjuvant effect in CD4 depleted mice, and thus, do not mimic T cell help. Simultaneous administration of recombinant IL-4 was unable to restore the adjuvant action of anti-CD40 in T cell depleted mice. However, CD40mAbs are effective adjuvants in CD154-/- mice, indicating that the antibodies are able to provide the CD40 stimulus to B cells which is naturally lacking in these mice. Identification of the additional stimuli required to fully mimic T cell help may be advantageous in vaccination of immunosuppressed patients.

CD40 antibody as an adjuvant induces enhanced T cell responses.

Monoclonal antibodies against CD40, conjugated to antigen, act as potent immunological adjuvants for primary antibody responses. We show here that CD40mAbs can also act as strong adjuvants for memory antibody responses, and for T cell responses as measured by ex vivo T cell proliferation to antigen, and delayed type hypersensitivity. Interferon gamma secretion in response to antigen is also enhanced. Finally, the adjuvant effect of CD40mAbs for secondary antibody responses is transferred with T cells rather than B cells. CD40mAb apparently have potent adjuvant effects on both Th1-like cells, and on T cells able to promote B cell antibody production. It is possible that the adjuvant effects of CD40 are mediated at least in part, indirectly, through enhanced antigen presentation by specific B cells, to T cells.

Apoptotic cell death in conjunction with CD80 costimulation confers uveal melanoma cells with the ability to induce immune responses.

Uveal melanoma is a rare malignancy with a poor prognosis despite current therapeutic intervention. The current investigation focuses on the immunogenicity of uveal melanoma cells genetically modified with recombinant adenovirus encoding CD80 (AdCD80) in contrast to their parental counterpart. We demonstrate that costimulation provided by uveal melanoma cells improved immune responses in vitro as determined by mixed lymphocyte tumour cell cultures and cytotoxic T-cell assays using lymphocytes from healthy donors and uveal melanoma patients. Flow cytometry revealed T-cell stimulation by activated CD4+ and CD8+ T cells. Additionally, autologous lymphocytes proliferated in response to CD80-expressing primary uveal melanomas, indicating that this patient group is suitable for immunotherapy. Moreover, this study utilized AdCD80 modified and parental apoptotic tumour cells, loaded onto immature dendritic cells, as a source of tumour antigen. The ability of live or apoptotic tumour cells to stimulate lymphocyte proliferation and activation was determined. Apoptotic uveal melanoma cells expressing CD80 were efficient at inducing an immune response and served as a potent immunogen. The use of apoptotic uveal melanoma cells in combination with expression of costimulatory molecules could prove a novel adjuvant therapy for the treatment of this disease.

A potent adjuvant effect of CD40 antibody attached to antigen.

There is great potential for novel vaccines based on recombinant proteins and synthetic peptides. Unfortunately these antigens often lack the immunogenicity of whole, killed pathogens used in traditional vaccines. Thus there is strong interest in the identification of immunological adjuvants with low reactogenicity, but high potency, to enhance immune responses and realize the potential of these new vaccine strategies. CD40 antibodies have been shown to have adjuvant effects when administered at very high doses. These large doses are impractical and induce a cascade of cytokine release giving rise to septic shock-like symptoms, as well as splenomegaly and polyclonal antibody production. We show here that a very small amount of CD40 antibody can exhibit potent adjuvant effects when attached to soluble antigen. The lack of detectable systemic effects indicates that this method may be a powerful and practical means of enhancing the efficacy of recombinant vaccines.

Anti-CD28 has a potent adjuvant effect on the antibody response to soluble antigens mediated through CTLA-4 by-pass.

With the surge in potential new vaccines produced as recombinant proteins or synthetic peptides has come a pressing need to identify safe, potent immunological adjuvants to enhance immunogenicity of these antigens. CD28 is an important costimulatory molecule for T cells, and it has been shown that cell surface expression of its ligands, CD80 and CD86, can enhance cellular immune responses against tumor cells, however, these tumor cells do not normally express the ligands. Many new vaccines will be based upon soluble recombinant antigens, and in vaccination with these antigens CD80 and CD86 would normally be expressed on activated antigen-presenting cells and additional stimulation through CD28 would not be predicted to enhance responses further. However, we show here that, surprisingly, CD28 antibody can very strongly enhance immune responses against soluble proteins, but only when directly attached to the antigen. The mode of action of CD28 antibodies appears to be linked to their ability to signal through CD28, but not to bind the negative feedback regulatory antigen, CTLA-4. CD28 stimulants may represent novel, highly effective and safe immunological adjuvants for use with a wide range of prophylactic and therapeutic vaccines.