Absence of sympathetic innervation hampers the generation of tertiary lymphoid structures upon acute lung inflammation.

Tertiary lymphoid structures (TLS) are lymphoid organs present in inflammatory non-lymphoid tissues. Studies have linked TLS to favorable outcomes for patients with cancers or infectious diseases, but the mechanisms underlying their formation are not fully understood. In particular, secondary lymphoid organs innervation raises the question of sympathetic nerve fibers involvement in TLS organogenesis. We established a model of pulmonary inflammation based on 5 daily intranasal instillations of lipopolysaccharide (LPS) in immunocompetent mice. In this setting, lung lymphoid aggregates formed transiently, evolving toward mature TLS and disappearing when inflammation resolved. Sympathetic nerve fibers were then depleted using 6-hydroxydopamine. TLS quantification by immunohistochemistry showed a decrease in LPS-induced TLS number and surface in denervated mouse lungs. Although a reduction in alveolar space was observed, it did not impair overall pulmonary content of transcripts encoding TNF-α, IL-1ß and IFN-γ inflammation molecules whose expression was induced by LPS instillations. Immunofluorescence analysis of immune infiltrates in lungs of LPS-treated mice showed a drop in the proportion of CD23+ naive cells among CD19+ B220+ B cells in denervated mice whereas the proportion of other cell subsets remained unchanged. These data support the existence of neuroimmune crosstalk impacting lung TLS neogenesis and local naive B cell pool.

[Bispecific antibodies: An old story with a bright future with CAR-T cells!] / Les anticorps bispécifiques : une vieille histoire pleine d'avenir avec les CAR-T !

CAR-T cells originate from two different approaches, cellular immunotherapy based on tumor immunosurveillance by T lymphocytes, combined with molecular engineering of bispecific antibodies and antibody fragments. The latter makes it possible to retarget immune effector cytotoxic cells (such as NK cells and T lymphocytes) to tumor cells through the binding to tumor-associated antigens. We present herein the history of bispecific antibodies, highlighting how such antibodies played a major role in CAR-T cell development. We will first evoke how antibody engineering led to the construction of various bispecific formats, in particular using the single chain Fv fragment (scFv) which has been used as the initial building block to generate chimeric bi-, tri- or multifunctional molecules. We will also describe how bispecific antibodies, either full IgG or as scFv or F(ab')2 format, directed against Fcγ receptors or CD3ɛ and against tumor-associated antigens, induce a potent anti-tumor cytotoxicity following the recruitment and activation of immune effector cells, including CD3+ T lymphocytes. These anti-tumor effects have been translated into the clinics, especially to treat malignant hemopathies. At last, recently generated bispecific CAR-T cells suggest that the embrace between cell therapy and bispecific antibodies is not over and that we are yet to witness further discoveries enabling these cells to be even more efficient.

Tumor-Associated Tertiary Lymphoid Structures: From Basic and Clinical Knowledge to Therapeutic Manipulation.

The tumor microenvironment is a complex ecosystem almost unique to each patient. Most of available therapies target tumor cells according to their molecular characteristics, angiogenesis or immune cells involved in tumor immune-surveillance. Unfortunately, only a limited number of patients benefit in the long-term of these treatments that are often associated with relapses, in spite of the remarkable progress obtained with the advent of immune checkpoint inhibitors (ICP). The presence of "hot" tumors is a determining parameter for selecting therapies targeting the patient immunity, even though some of them still do not respond to treatment. In human studies, an in-depth analysis of the organization and interactions of tumor-infiltrating immune cells has revealed the presence of an ectopic lymphoid organization termed tertiary lymphoid structures (TLS) in a large number of tumors. Their marked similarity to secondary lymphoid organs has suggested that TLS are an "anti-tumor school" and an "antibody factory" to fight malignant cells. They are effectively associated with long-term survival in most solid tumors, and their presence has been recently shown to predict response to ICP inhibitors. This review discusses the relationship between TLS and the molecular characteristics of tumors and the presence of oncogenic viruses, as well as their role when targeted therapies are used. Also, we present some aspects of TLS biology in non-tumor inflammatory diseases and discuss the putative common characteristics that they share with tumor-associated TLS. A detailed overview of the different pre-clinical models available to investigate TLS function and neogenesis is also presented. Finally, new approaches aimed at a better understanding of the role and function of TLS such as the use of spheroids and organoids and of artificial intelligence algorithms, are also discussed. In conclusion, increasing our knowledge on TLS will undoubtedly improve prognostic prediction and treatment selection in cancer patients with key consequences for the next generation immunotherapy.

[MAbs: the history of a basic research or the curiosity as a source of wealth]. / Les anticorps monoclonaux - L'histoire d'une recherche fondamentale ou la curiosité comme source de richesse1.

In 2019, monoclonal antibodies are a worldwide annual business worth of more than 100 billions USD (i.e., about 90 billions €). In addition to their use in the clinics, monoclonal antibodies are also used for diagnosis and remain highly valuable tools for academic basic and translational research. Forty-four years after the seminal publication of Georges Köhler and César Milstein, dozens of meetings and seminars focusing on various aspects of mAbs are held annually all around the world. But forty-four years later, the scientific works and efforts that have made possible this scientific breakthrough are gradually forgotten and, for many, monoclonal antibodies are no more than a multi-million USD business alike any other big business, guided by financial markets and the results of on-going clinical trials… Time has now come for acknowledging and paying tribute to all these scientists involved in basic research, to these researchers passionate about science, some famous, some forgotten, scattered all over the world. They explored during the 20th century the frontiers of unknown and generated a knowledge that allowed the emergence of a technique that translated finally into what is one of the greatest therapeutic revolution of the modern era.

TITLE: Les anticorps monoclonaux - L'histoire d'une recherche fondamentale ou la curiosité comme source de richesse1. ABSTRACT: En 2019, les anticorps monoclonaux (Acm) vont représenter un marché mondial annuel de plus de cent milliards de dollars, soit près de 90 milliards d'euros. Outre leur utilisation en clinique, les anticorps monoclonaux sont utilisés également dans de nombreux tests diagnostiques et sont toujours des outils précieux pour la recherche fondamentale et appliquée. Quarante-quatre ans après la publication de Georges Köhler et César Milstein [1], des dizaines de congrès et séminaires de toute nature sur les anticorps monoclonaux se tiennent annuellement à travers le monde. Mais 44 ans plus tard, les travaux scientifiques qui ont amené à cette publication sont peu à peu oubliés et, dans bien des esprits, les anticorps monoclonaux ne sont qu'un business d'un multi-milliard euros/dollars comme un autre, déterminé par les marchés financiers et les résultats des derniers essais cliniques… Il est grand temps de rendre hommage à toute une génération de chercheurs fondamentalistes, à ces fous de science du xx e siècle, à ces chercheurs connus et souvent désormais méconnus, disséminés aux quatre coins du monde, qui ont exploré les frontières de l'inconnu d'alors et qui ont modelé et ciselé un savoir qui a débouché sur une technique d'obtention de molécules qui ont permis l'une des plus grandes révolutions thérapeutiques de ces vingt-cinq dernières années.