Arginase-1 and Ym1 are markers for murine, but not human, alternatively activated myeloid cells.

7nonenoneRAES G; VAN DEN BERGH R; DE BAETSELIER P; GHASSABEH GH; SCOTTON C; LOCATI M; S. SOZZANIRaes, G; VAN DEN BERGH, R; DE BAETSELIER, P; Ghassabeh, Gh; Scotton, C; Locati, M; Sozzani, Silvan

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Analysis of blood-brain barrier permeability of monovalent nanobodies using microdialysis

BACKGROUND AND PURPOSE: Nanobodies are promising antigen-binding moieties for molecular imaging and therapeutic purposes due to their favorable pharmacological and pharmacokinetic properties. However, the capability of monovalent nanobodies to reach targets in the central nervous system (CNS) remains to be demonstrated. EXPERIMENTAL APROACH: We have assessed the blood-brain barrier permeability of Nb_An33, a nanobody against the Trypanosoma brucei brucei Variant-specific Surface Glycoprotein (VSG). This analysis was performed in healthy rats and in rats that were in the encephalitic stage of African trypanosomiasis using intracerebral microdialysis, Single Photon Emission Computed Tomography (SPECT), or a combination of both methodologies. This enabled the quantification of unlabeled and (99m) Tc-labeled nanobodies using respectively a sensitive VSG-based nanobody-detection ELISA, radioactivity measurement in collected microdialysates, and SPECT image analysis. KEY RESULTS: The combined read-out methodologies demonstrate that disposition of Nb_An33 can be detected in the brain of healthy rats following intravenous injection and that inflammation-induced damage to the blood-brain barrier significantly increases the nanobody perfusion efficiency. We also illustrate the advantage of complementing SPECT analyses with intracerebral microdialysis in brain disposition studies and suggest that it is of interest to evaluate the blood-brain barrier penetrating potential of monovalent nanobodies in models of CNS-inflammation. The presented data also suggest that fast blood clearance might hamper efficient targeting of specific nanobodies to the CNS. CONCLUSIONS AND IMPLICATIONS: Nanobodies can perfuse into the brain parenchyma, especially in pathological conditions where the blood-brain barrier integrity is compromised

Camelid immunoglobulins and nanobody technology

It is well established that all camelids have unique antibodies circulating in their blood. Unlike antibodies fromother species, these special antibodies are devoid of light chains and are composed of a heavy-chainhomodimer. These so-called heavy-chain antibodies (HCAbs) are expressed after a V\u2013D\u2013J rearrangement and require dedicated constant g-genes. An immune response is raised in these so-called heavy-chain antibodies following classical immunization protocols. These HCAbs are easily purified from serum, and the antigenbinding fragment interacts with parts of the target that are less antigenic to conventional antibodies. Since the antigen-binding site of the dromedary HCAb is comprised in one single domain, referred to as variable domain of heavy chain of HCAb (VHH) or nanobody (Nb), we designed a strategy to clone the Nb repertoire of an immunized dromedary and to select the Nbs with specificity for our target antigens. The monoclonal Nbs are well produced in bacteria, are very stable and highly soluble, and bind their cognate antigen with high affinity and specificity. We have successfully developed recombinant Nbs for research purposes, as probe in biosensors, to diagnose infections, and to treat diseases like cancer or trypanosomosis.Peer reviewed: YesNRC publication: Ye

Tip-DC development during parasitic infection is regulated by IL-10 and requires CCL2/CCR2, IFN-gamma and MyD88 signaling.

The development of classically activated monocytic cells (M1) is a prerequisite for effective elimination of parasites, including African trypanosomes. However, persistent activation of M1 that produce pathogenic molecules such as TNF and NO contributes to the development of trypanosome infection-associated tissue injury including liver cell necrosis in experimental mouse models. Aiming to identify mechanisms involved in regulation of M1 activity, we have recently documented that during Trypanosoma brucei infection, CD11b(+)Ly6C(+)CD11c(+) TNF and iNOS producing DCs (Tip-DCs) represent the major pathogenic M1 liver subpopulation. By using gene expression analyses, KO mice and cytokine neutralizing antibodies, we show here that the conversion of CD11b(+)Ly6C(+) monocytic cells to pathogenic Tip-DCs in the liver of T. brucei infected mice consists of a three-step process including (i) a CCR2-dependent but CCR5- and Mif-independent step crucial for emigration of CD11b(+)Ly6C(+) monocytic cells from the bone marrow but dispensable for their blood to liver migration; (ii) a differentiation step of liver CD11b(+)Ly6C(+) monocytic cells to immature inflammatory DCs (CD11c(+) but CD80/CD86/MHC-II(low)) which is IFN-gamma and MyD88 signaling independent; and (iii) a maturation step of inflammatory DCs to functional (CD80/CD86/MHC-II(high)) TNF and NO producing Tip-DCs which is IFN-gamma and MyD88 signaling dependent. Moreover, IL-10 could limit CCR2-mediated egression of CD11b(+)Ly6C(+) monocytic cells from the bone marrow by limiting Ccl2 expression by liver monocytic cells, as well as their differentiation and maturation to Tip-DCs in the liver, showing that IL-10 works at multiple levels to dampen Tip-DC mediated pathogenicity during T. brucei infection. A wide spectrum of liver diseases associates with alteration of monocyte recruitment, phenotype or function, which could be modulated by IL-10. Therefore, investigating the contribution of recruited monocytes to African trypanosome induced liver injury could potentially identify new targets to treat hepatic inflammation in general, and during parasite infection in particular.Journal ArticleResearch Support, Non-U.S. Gov'tinfo:eu-repo/semantics/publishe