Mass cytometry to characterize the immune lung cancer microenvironment.

The human tumor microenvironment requires use of high-dimensional single-cell tools to uncover its cellular complexity and functional variety. For decades, flow cytometry has been the technology of choice to explore immune cell diversity in different pathological contexts. Recently, a new format for flow cytometry - termed mass cytometry - has been developed. It allows for simultaneous interrogation of more than 40 different molecular markers, without the need for spectral compensation, which significantly augments the ability of cytometry to evaluate complex cellular systems and processes. Currently, different multiparametric single-cell analysis approaches are being widely adopted to interrogate the human tumor microenvironment. However, important challenges must be addressed when solid tissues are analyzed by single-cell technologies. This protocol describes the challenge and better use of single-cell mass cytometry to dissect tumor infiltrating leukocytes from surgically resected tumoral lung tissues.

Transfer of SCN1A to the brain of adolescent mouse model of Dravet syndrome improves epileptic, motor, and behavioral manifestations.

Dravet syndrome is a genetic encephalopathy characterized by severe epilepsy combined with motor, cognitive, and behavioral abnormalities. Current antiepileptic drugs achieve only partial control of seizures and provide little benefit on the patient's neurological development. In >80% of cases, the disease is caused by haploinsufficiency of the SCN1A gene, which encodes the alpha subunit of the Nav1.1 voltage-gated sodium channel. Novel therapies aim to restore SCN1A expression in order to address all disease manifestations. We provide evidence that a high-capacity adenoviral vector harboring the 6-kb SCN1A cDNA is feasible and able to express functional Nav1.1 in neurons. In vivo, the best biodistribution was observed after intracerebral injection in basal ganglia, cerebellum, and prefrontal cortex. SCN1A A1783V knockin mice received the vector at 5 weeks of age, when most neurological alterations were present. Animals were protected from sudden death, and the epileptic phenotype was attenuated. Improvement of motor performance and interaction with the environment was observed. In contrast, hyperactivity persisted, and the impact on cognitive tests was variable (success in novel object recognition and failure in Morris water maze tests). These results provide proof of concept for gene supplementation in Dravet syndrome and indicate new directions for improvement.