Circulating CD81-expressing extracellular vesicles as biomarkers of response for immune-checkpoint inhibitors in advanced NSCLC.

PD-L1 in tumor cells is the only used biomarker for anti PD1/PD-L1 immune-checkpoints inhibitors (ICI) in Non Small Cell Lung Cancer (NSCLC) patients. However, this parameter is inaccurate to predict response, especially in patients with low tumor PD-L1. Here, we evaluated circulating EVs as possible biomarkers for ICI in advanced NSCLC patients with low tumoral PD-L1. EVs were isolated from plasma of 64 PD-L1 low, ICI-treated NSCLC patients, classified either as responders (R; complete or partial response by RECIST 1.1) or non-responders (NR). EVs were characterized following MISEV guidelines and by flow cytometry. T cells from healthy donors were triggered in vitro using patients' EVs. Unsupervised statistical approach was applied to correlate EVs' and patients' features to clinical response. R-EVs showed higher levels of tetraspanins (CD9, CD81, CD63) than NR-EVs, significantly associated to better overall response rate (ORR). In multivariable analysis CD81-EVs correlated with ORR. Unsupervised analysis revealed a cluster of variables on EVs, including tetraspanins, significantly associated with ORR and improved survival. R-EVs expressed more costimulatory molecules than NR-EVs although both increased T cell proliferation and partially, activation. Tetraspanins levels on EVs could represent promising biomarkers for ICI response in NSCLC.

Energy metabolism and cell motility defect in NK-cells from patients with hepatocellular carcinoma.

Functional rescue of NK-cells in solid tumors represents a central aim for new immunotherapeutic strategies. We have conducted a genomic, phenotypic and functional analysis of circulating NK-cells from patients with HCV-related liver cirrhosis and hepatocellular carcinoma. NK-cells were sorted from patients with HCC or liver cirrhosis and from healthy donors. Comparative mRNA gene expression profiling by whole-human-genome microarrays of sorted NK-cells was followed by phenotypic and functional characterization. To further identify possible mediators of NK-cell dysfunction, an in vitro model using media conditioned with patients' and controls' plasma was set up. Metabolic and cell motility defects were identified at the genomic level. Dysregulated gene expression profile has been translated into reduced cytokine production and degranulation despite a prevalent phenotype of terminally differentiated NK-cells. NKG2D-downregulation, high SMAD2 phosphorylation and other phenotypic and molecular alterations suggested TGF-ß as possible mediator of this dysfunction. Blocking TGF-ß could partially restore functional defects of NK-cells from healthy donors, exposed to TGF-ß rich HCC patients' plasma, suggesting that TGF-ß among other molecules may represent a suitable target for immunotherapeutic intervention aimed at NK-cell functional restoration. By an unbiased approach, we have identified energy metabolism and cell motility defects of circulating NK-cells as main mechanisms responsible for functional NK-cell impairment in patients with hepatocellular carcinoma. This opens the way to test different approaches to restore NK-cell response in these patients.

A novel antibody combination to identify KIR2DS2high natural killer cells in KIR2DL3/L2/S2 heterozygous donors.

The killer cell immunoglobulin-like receptor (KIR) KIR2DS2 induces natural killer (NK) cell activation upon ligation and in genetic studies is associated with protection against certain cancers and viral infections. One of the difficulties in understanding KIR2DS2 has been that ligands have been hard to define. In part, this is because the high sequence homology between KIR2DS2 and KIR2DL3/KIR2DL2 has made it difficult to make antibodies that specifically detect NK cells expressing KIR2DS2. Using transfected NK cell line (NKL) cells and primary human samples, we report the identification of a novel antibody combination which allows identification of NK cells with relatively high expression of KIR2DS2. This separation is sufficient to examine primary human NK cell activation in response to KIR2DS2 specific ligands.