151 research outputs found
In Vitro Studies on the Trafficking of Dendritic Cells Through Endothelial Cells and Extra-Cellular Matrix
Dendritic cells (DC) are antigen presenting cells (APC) with the unique ability to initiate an
immune response. Immature DC are localized in peripheral tissues where they exert a sentinel
function for incoming antigens (Ag). After Ag capture and exposure to inflammatory stimuli
DC undergo maturation and migrate to regional lymph nodes where the presentation of antigenic
peptides to T lymphocytes takes place. Thus their correct functioning as APC involves
localization in tissues and trafficking via the lymph or blood to lymphoid organs. In the
present study we have investigated the ability of DC to interact in vitro with human vascular
endothelial cells (EC) and extracellular matrix (ECM). DC are differentiated from monocytes
by in vitro exposure to GM-CSF and IL-13 for 7 days. In adhesion assays a considerable proportion
of DC binds to resting EC monolayers and this adhesion is inhibited by anti-CD11a
and CD11b, but not anti-CD11c mAbs. Binding to a natural ECM, derived from cultured EC
involves VLA-4 and VLA-5 integrins. In a transmigration assay, 10 % of input cells are able
to cross the EC monolayer in the absence of exogenous stimuli. The amount of DC transmigrated
through a monolayer of EC was increased of 2-3 fold by C-C chemokines RANTES,
MIP1α, and MIP-1β. Most importantly, in view of the trafficking pattern of these cells, a significant
proportion of DC can migrate in a reverse transmigration assay, i.e. across the
endothelial basement membrane and subsequently, across endothelial cells. Upon exposure to
immune or inflammatory signals peripheral DC undergo maturation and migration to lymphoid
organs. Functional maturation is associated with loss of responsiveness to chemokines
present at sites of inflammation (e.g. MIP1α, MIP1β and RANTES) and acquisition of a
receptor repertoire which renders these cells responsive to signals which guide their localization
in lymphoid organs (e.g. MIP3β). A better understanding of the molecular basis of DC
trafficking may provide molecular and conceptual tools to direct and modulate DC localization
as a strategy to upregulate and orient specific immunity
Enhanced recruitment of genetically modified CX3CR1-positive human T cells into Fractalkine/CX3CL1 expressing tumors: Importance of the chemokine gradient
Background: Adoptive T-cell based immunotherapies constitute a promising approach to treat cancer, however, a major problem is to obtain effective and long-lasting anti-tumor responses. Lack of response may be due to insufficient trafficking of specific T cells to tumors. A key requirement for efficient migration of cytotoxic T cells is that they express chemokine receptors that match the chemokines produced by tumor or tumor-associated cells. Methods: In this study, we investigated whether the in vivo tumor trafficking of activated T cells could be enhanced by the expression of the chemokine receptor CX3CR1. Two human colorectal cancer cell lines were used to set up a xenograft tumor model in immunodeficient mice; the NCI-H630, constitutively expressing the chemokine ligand CX3CL1 (Fractalkine), and the RKO cell line, transduced to express CX3CL1. Results: Human primary T cells were transduced with the receptor CX3CR1-eGFP. Upon in vivo adoptive transfer of genetically modified CX3CR1-T cells in mice bearing NCI-H630 tumors, enhanced lymphocyte migration and tumor trafficking were observed, compared to mice receiving Mock-T cells, indicating improved homing ability towards ligand-expressing tumor cells. Furthermore, significant inhibition of tumor growth was found in mice receiving modified CX3CR1-T cells. In contrast, tumors formed by RKO cells transduced with the ligand (RKO-CX3CL1) were not affected, nor more infiltrated upon transfer of CX3CR1-T lymphocytes, likely because high levels of the chemokine were shed by tumor cells in the systemic circulation, thus nullifying the blood-tissue chemokine gradient. Conclusions: This study demonstrates that ectopic express
CD40 activation of BCP-ALL cells generates IL-10-producing, IL-12-defective APCs that induce allogeneic T-cell anergy
The use of leukemia cells as antigenpresenting cells (APCs) in immunotherapy is critically dependent on their capacity to initiate and sustain an antitumor-specific immune response. Previous studies suggested that pediatric B-cell precursor acute lymphoblastic leukemia (BCP-ALL) cells could be manipulated in vitro through the CD40-CD40L pathway to increase their immunostimulatory capacity. We extended the APC characterization of CD40L-activated BCP-ALL for their potential use in immunotherapy in a series of 19 patients. Engaging CD40 induced the up-regulation of CCR7 in 7 of 11 patients and then the migration to CCL19 in 2 of 5 patients. As accessory cells, CD40Lactivated BCP-ALL induced a strong proliferation response of naive T lymphocytes. Leukemia cells, however, were unable to sustain proliferation over time, and T cells eventually became anergic. After CD40-activation, BCP-ALL cells released substantial amounts of interleukin-10 (IL-10) but were unable to produce bioactive IL-12 or to polarize TH1 effectors. Interestingly, adding exogenous IL-12 induced the generation of interferon- (IFN- )–secreting TH1 effectors and reverted the anergic profile in a secondary response. Therefore, engaging CD40 on BCP-ALL cells is insufficient for the acquisition of full functional properties of immunostimulatory APCs. These results suggest caution against the potential use of CD40L-activated BCP-ALL cells as agents for immunotherapy unless additional stimuli, such as IL-12, are provided.Fil: D'Amico, Giovanna. Università Milano Bicocca; ItaliaFil: Vulcano, Marisa. Universidad de Buenos Aires. Facultad de Medicina; Argentina. Consejo Nacional de Investigaciones Científicas y Técnicas. Oficina de Coordinación Administrativa Houssay; ArgentinaFil: Bugarin, Cristina. Università Milano Bicocca; ItaliaFil: Bianchi, Giancarlo. Università Milano Bicocca; ItaliaFil: Pirovano, Gisella. Università Milano Bicocca; ItaliaFil: Bonamino, Martin. Università Milano Bicocca; ItaliaFil: Marin, Virna. Università Milano Bicocca; ItaliaFil: Allavena, Paola. Università Milano Bicocca; ItaliaFil: Biagi, Ettore. Università Milano Bicocca; ItaliaFil: Biondi, Andrea. Università Milano Bicocca; Itali
Mannose-modified hyaluronic acid nanocapsules for the targeting of tumor-associated macrophages
Tumor-associated macrophages (TAMs), a class of immune cells that play a key role in tumor immunosuppression, are recognized as important targets to improve cancer prognosis and treatment. Consequently, the engineering of drug delivery nanocarriers that can reach TAMs has acquired special relevance. This work describes the development and biological evaluation of a panel of hyaluronic acid (HA) nanocapsules (NCs), with different compositions and prepared by different techniques, designed to target macrophages. The results showed that plain HA NCs did not significantly influence the polarization of M0 and M2-like macrophages towards an M1-like pro-inflammatory phenotype; however, the chemical functionalization of HA with mannose (HA-Man) led to a significant increase of NCs uptake by M2 macrophages in vitro and to an improved biodistribution in a MN/MNCA1 fibrosarcoma mouse model with high infiltration of TAMs. These functionalized HA-Man NCs showed a higher accumulation in the tumor compared to non-modified HA NCs. Finally, the pre-administration of the liposomal liver occupying agent Nanoprimer™ further increased the accumulation of the HA-Man NCs in the tumor. This work highlights the promise shown by the HA-Man NCs to target TAMs and thus provides new options for the development of nanomedicine and immunotherapy-based cancer treatmentsOpen Access funding provided thanks to the CRUE-CSIC agreement with Springer Nature. This work was supported by the 2^2-INTRATARGET project (A20/00028) funded by the ISCIII under the umbrella of the ERA NET EuroNanoMed GA N 723770 of the EU Horizon 2020 Research and Innovation Programme. This work was also supported by the Xunta de Galicia (ED431C 2018/30, and “Centro singular de investigación de Galicia” accreditation 2019 − 2022, ED431G2019/03), and the European Union (European Regional Development Fund-ERDF)S
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