Alessandra Nardin

CC Chemokine Ligand 19 Secreted by Mature Dendritic Cells Increases Naive T Cell Scanning Behavior and Their Response to Rare Cognate Antigen

For immune responses to take place, naive T cells have to encounter, adhere to, and be stimulated by dendritic cells (DCs). In murine lymph nodes, T cells move randomly and scan the surface of multiple DCs. The factors controlling this motility as well as its consequences remain unclear. We have monitored by video-imaging the earliest steps of the interaction between human DCs and autologous naive CD4+ T cells in the absence of exogenous Ags. Mature, but not immature, DCs were able to elicit small calcium responses in naive T cells along with cell polarization and random motility, resulting in an efficient scanning of DC surfaces by T cells. We identified CCL19 as a key factor enabling all these early T cell responses, including the occurrence of calcium transients. Because this chemokine did not influence the strength of naive T cell adhesion to DCs, enhanced LFA-1 affinity for ICAM-1 was not the main mechanism by which CCL19 increased Ag-independent calcium transients. However, concomitantly to T cell motility, CCL19 augmented the frequency of T cell responses to rare anti-CD3/CD28-coated beads, used as surrogate APCs. We thus propose a new role for CCL19 in humans: by conditioning T cells into a motile DC-scanning state, this chemokine promotes Ag-independent responses and increases the probability of cognate MHC-peptide encounter.

Involvement of TBK1 and IKKepsilon in lipopolysaccharide-induced activation of the interferon response in primary human macrophages

Interferon (IFN) is an important effector of the innate immune response, induced by different viral or bacterial components through Toll‐like receptor‐dependent and ‐independent mechanisms. In human macrophages and macrophage‐activated killer cells, we demonstrate that (i) the type I IFN response to lipopolysaccharide (LPS) is weak compared to the host response to virus infection; (ii) there is a temporal difference in the induction of tank‐binding kinase‐1 (TBK1) and IkappaB kinase (IKK)‐related kinase epsilon (IKKϵ) kinase activities in response to LPS, with TBK1 activated early and IKKϵ induced in the late phase of IFN induction; and (iii) interferon regulatory factor (IRF)‐7 is induced following LPS treatment, but there is no evidence that IRF‐7 becomes activated by phosphorylation in vivo. Specifically, TBK1 kinase activity is rapidly increased after LPS stimulation (15 min) whereas IKKϵ activation occurs at 8 h. RNA interference‐mediated inhibition of TBK1 and IKKϵ expression in macrophages interfere with IFNB and IRF7 gene expression following LPS activation. Macrophage priming with rIFN‐α increased IRF‐7 expression, led to a sharp up‐regulation of the IFNB gene and to a rapid induction of IFNA2 upon LPS stimulation. These data support a differential role of TBK1 and IKKϵ in the downstream response mediated by IRF‐3 and IRF‐7 to LPS in primary human macrophages.

Immature Dendritic Cells (DCs) Use Chemokines and Intercellular Adhesion Molecule (ICAM)-1, But Not DC-Specific ICAM-3-Grabbing Nonintegrin, to Stimulate CD4 + T Cells in the Absence of Exogenous Antigen

Dendritic cells (DCs) possess a number of unique features that distinguish them from other APCs. One such feature is their ability to trigger Ag-independent responses in T cells. Previous studies have focused on mature DCs, but the prevalence of this phenomenon in the resting-state immature DCs has never been considered. In this study, we show that, in the absence of Ag, human immature DCs trigger multiple responses in autologous primary CD4+ T cells, namely, increased motility, small Ca2+ transients, and up-regulation of CD69. These responses are particularly marked in CD4+ memory T cells. By using several experimental approaches, we found that DC-specific ICAM-3-grabbing nonintegrin plays no role in the induction of T cell responses, whereas ICAM-1/LFA-1 interactions are required. In addition, DC-produced chemokines contribute to the Ag-independent T cell stimulatory ability of DCs, because pertussis toxin-treated T cells exhibit diminished responses to immature DCs. More particularly, CCL17 and CCL22, which are constitutively produced by immature DCs, mediate both T cell polarization and attraction. Thus, immature DCs owe part of their outstanding Ag-independent T cell stimulatory ability to chemokines and ICAM-1, but not DC-specific ICAM-3-grabbing nonintegrin.

Targeting of Pseudomonas aeruginosa in the Bloodstream with Bispecific Monoclonal Antibodies

We examined the ability of a bispecific mAb reagent, consisting of a mAb specific for the primate erythrocyte complement receptor cross-linked with an anti-bacterial mAb, to target bacteria in the bloodstream in an acute infusion model in monkeys. In vitro studies demonstrated a variable level of complement-mediated binding (immune adherence) of Pseudomonas aeruginosa (strain PAO1) to primate E in serum. In vivo experiments in animals depleted of complement revealed that binding of bacteria to E was <1% before administration of the bispecific reagent, but within 5 min of its infusion, >99% of the bacteria bound to E. In complement-replete monkeys, a variable fraction of infused bacteria bound to E. This finding may have significant implications in the interpretation of animal models and in the understanding of bacteremias in humans. Treatment of these complement-replete monkeys with the bispecific reagent led to >99% binding of bacteria to E. Twenty-four-hour survival studies were conducted; several clinical parameters, including the degree of lung damage, cytokine levels, and liver enzymes in the circulation, indicate that the bispecific mAb reagent provides a degree of protection against the bacterial challenge.

Targeting of cancer cells with monoclonal antibodies specific for C3b(i).

Purpose: The goal of this research is to determine the feasibility of an immunotherapeutic approach based on the use of monoclonal antibodies (mAb) to target complement activation fragments on opsonized cancer cells. Methods: We investigated whether treatment of LNCaP and C4-2 human prostate cancer cell lines with normal human serum would allow for deposition of sufficient amounts of the complement-activation protein C3b and its fragments [collectively referred to as C3b(i)] such that these proteins could serve as cancer-cell-associated antigens for targeting by mAb. Radioimmunoassays, flow cytometry, and magnetic purging with specific immunomagnetic beads were used for the analyses. Results: In vitro opsonization of human prostate cancer cells with normal human serum resulted in deposition of C3b(i) in sufficient quantity (approx. 100,000 molecules/cell) for the cells to be targeted in a variety of protocols. We found that 51Cr-labeled and C3b(i)-opsonized cancer cells could be specifically purged at high efficiency (95%–99%) using anti-C3b(i) mAb covalently coupled to magnetic beads. Flow-cytometry experiments indicated that most normal white cells were not removed under similar conditions. Opsonization of cancer cells with sera from men with prostate cancer led to lower levels of cell-associated IgM and, subsequently, lower amounts of C3b(i) deposited than in normal subjects. Prototype experiments suggested that this deficiency could be corrected by addition of IgM from normal donor plasma. Conclusion: mAb directed against complement-activation products may provide new opportunities to deliver diagnostic and therapeutic agents selectively to cancer cells and tumor deposits. These opportunities may include ex vivo purging of C3b(i)-opsonized cancer cells prior to autologous bone marrow or stem cell transplantation.

Quantitative studies of heteropolymer-mediated binding of inactivated Marburg virus to the complement receptor on primate erythrocytes.

Previous in vitro and in vivo experiments in our laboratory have demonstrated that cross-linked bispecific monoclonal antibody (mAb) complexes (Heteropolymers, HP) facilitate binding of prototype pathogens to primate erythrocytes (E) via the E complement receptor, CR1. These E-bound immune complexes are safely and rapidly cleared from the bloodstream. In order to generate a robust bispecific system for HP-mediated clearance of real pathogens such as Filoviruses, we have developed the necessary methodologies and reagents using both inactivated Marburg virus (iMV) and a recombinant form of its surface envelope glycoprotein (rGP). We identified mAbs which bind rGP in solution phase immunoprecipitation experiments. HP were prepared by chemically cross-linking an anti-CR1 mAb with several of these anti-Marburg virus mAbs and used to facilitate binding of iMV and rGP to monkey and human E. These HP mediate specific and quantitative binding (> or = 90%) of both antigens to monkey and human E. Binding was also demonstrable in an indirect RIA. E with bound Marburg virus were probed with 125I labeled mAbs to the Marburg surface glycoprotein and more than 100 mAbs are bound per E. It should be possible to adapt this general approach to other pathogens, and experiments underway should lead to an in vivo test of HP-mediated clearance of Marburg virus.

Clearance of blood-borne pathogens mediated through bispecific monoclonal antibodies bound to the primate erythrocyte complement receptor

Abstract The primate erythrocyte complement receptor facilitates both the immune adherence reaction and the immune complex clearance properties of primate erythrocytes. These phenomena have been studied for more than 40 years. However, it has only recently become apparent that these characteristics of primate erythrocytes may be useful in the generation of a therapy based on bispecific monoclonal antibodies. Our approach uses bispecific monoclonal antibody constructs (heteropolymers) that promote binding of specific target pathogens to primate erythrocytes via the complement receptor. Once bound to the erythrocytes, the pathogen-heteropolymer complex should be cleared from the circulation, phagocytosed and destroyed in the liver. Results with several prototype target pathogens in monkey models indicate it may be possible to use this technology to develop a robust and general therapy for the treatment of diseases associated with blood-borne pathogens.