ALBERT

Beschreibung: The emergence of electronic cigarettes (e-cigs) has given cannabis smokers a new method of inhaling cannabinoids. E-cigs differ from traditional marijuana cigarettes in several respects. First, it is assumed that vaporizing cannabinoids at lower temperatures is safer because it produces smaller amounts of toxic substances than the hot combustion of a marijuana cigarette. Recreational cannabis users can discretely “vape” deodorized cannabis extracts with minimal annoyance to the people around them and less chance of detection. There are nevertheless several drawbacks worth mentioning: although manufacturing commercial (or homemade) cannabinoid-enriched electronic liquids (e-liquids) requires lengthy, complex processing, some are readily on the Internet despite their lack of quality control, expiry date, and conditions of preservation and, above all, any toxicological and clinical assessment. Besides these safety problems, the regulatory situation surrounding e-liquids is often unclear. More simply ground cannabis flowering heads or concentrated, oily THC extracts (such as butane honey oil or BHO) can be vaped in specially designed, pen-sized marijuana vaporizers. Analysis of a commercial e-liquid rich in cannabidiol showed that it contained a smaller dose of active ingredient than advertised; testing our laboratory-made, purified BHO, however, confirmed that it could be vaped in an e-cig to deliver a psychoactive dose of THC. The health consequences specific to vaping these cannabis preparations remain largely unknown and speculative due to the absence of comprehensive, robust scientific studies. The most significant health concerns involve the vaping of cannabinoids by children and teenagers. E-cigs could provide an alternative gateway to cannabis use for young people. Furthermore, vaping cannabinoids could lead to environmental and passive contamination.

Beschreibung: Peripheral T-cell lymphomas (PTCLs) are a heterogeneous group of aggressive non Hodgkin lymphomas with poor prognosis. Molecular and cytogenetic studies have shown a prominent role for kinase fusion oncogenes, mostly NPM-ALK, in ALK+ anaplastic large cell lymphomas (ALCLs) and ITK-SYK kinase in unspecified PTCLs. To gain further insight on the genetics and pathogenic mechanisms of aggressive PTCLs we performed an integrated mutation analysis using whole exome sequencing (n=12) and RNAseq (n=35) data. This analysis identified 288 candidate coding somatic mutations in 268 genes including known recurrent mutations in the TET2, DNMT3A and IDH2 epigenetic factor genes and pointed to the FYN kinase gene as a new recurrently mutated oncogene in T-cell transformation. The FYN tyrosine kinase is, with LCK, the predominant SRC family kinase found in T lymphocytes and plays an important role in T-cell activation upon T-cell receptor (TCR) stimulation. FYN mutations in PTCL included a FYN L174R mutation detected in one AITL patient sample, a FYN R176C allele recurrently found in two PTCL NOS cases and a FYN Y531H mutation present in a PTCL NOS sample. Notably, each of these alleles are predicted to specifically disrupt the inhibition of FYN kinase activity by the C terminal SRC kinase (CSK). Thus, structure analysis of FYN and FYN mutant proteins predicted that FYN L174R and, most prominently, FYN R176C and FYN Y531H can disrupt the inhibitory interaction of the FYN SH2 domain with the CSK-phosphorylated Y531. Consistently, pull down assays using GST-FYN-SH2 recombinant proteins and biotinylated C-terminal FYN peptides encompassing Y531 showed abrogation of the interaction between FYN-SH2 and P-Y531 in each of these mutants. In agreement with these results, expression of FYN L174R, FYN R176C and FYN Y531H resulted in increased levels of FYN activation. Moreover, CSK expression effectively inhibited wild type FYN, but failed to abrogate FYN L174R, FYN R176C or FYN Y531H activation. In contrast, pharmacologic kinase inhibition with dasatinib, a multikinase inhibitor which blocks ABL1 and SRC kinases, effectively abrogated the activity of FYN L174R, FYN R176C and FYN Y531H mutant proteins and suppressed the growth of cells transformed via expression of activated FYN mutant alleles. Overall these results support an oncogenic role for FYN activating mutations in the pathogenesis of PTCL and support a role for SRC kinase inhibitors for the treatment of this disease. Disclosures: No relevant conflicts of interest to declare.

Beschreibung: Peripheral T-cell lymphomas (PTCLs) are a heterogeneous and poorly understood group of aggressive non Hodgkin lymphomas with poor prognosis. To gain further insight on the genetics and pathogenic mechanisms of aggressive PTCLs we performed whole exome sequencing of matched tumor and normal DNA samples from 12 PTCL patients including 6 PTCL not otherwise specified (PTCL-NOS) tumors, 3 angioimunoablastic (AITL) T-cell lymphomas, 2 nasal type NK-/T-cell lymphomas and one enteropathy-associated T-cell lymphoma (EATL). This analysis identified 288 candidate coding somatic mutations in 268 genes and a mean mutation load of 24 non synonymous mutations per sample (range 4 – 57). Among these we noted the presence of a recurrent heterozygous mutation in the RHOA small GTPase gene (RHOA G17V) present in two independent AITL samples and one PTCL NOS biopsy. Analysis of a broad and diverse panel of 126 PTCL samples identified the presence of the RHOA G17V allele in 32 samples with a high prevalence in AITL (24/36, 67%, P 〈 0.001) and PTCL NOS cases (8/44, 18%, P 〈 0.002). The RHOA protein belongs to the Rho family of small GTPases, a group of Ras-like proteins responsible for linking a variety of cell-surface receptors to different intracellular signaling proteins. As is the case for RAS and most other small GTPases, RHOA activation is mediated by guanine exchange factors (GEFs), which catalyze the switch of RHOA from an inactive GDP-bound to an active GTP-bound state. Thus, and to test the functional significance of the RHOA G17V mutation we analyzed the capacity of this mutant to load GTP. This analysis revealed that RHOA G17V fails to incorporate GTP in response to an activated GEF in vitro. Moreover, and consistent with its inability to bind GTP, RHOA G17V failed to interact with rhotekin, a RHOA effector protein that selectively interacts with the GTP-bound active form of RHOA. However and most notably, the lack of RHOA G17V activation is not the result of a defect in RHOA-GEF interaction as RHOA G17V pull down assays demonstrated effective binding of this mutant protein to activated GEF proteins in T-cells. Based on these results we proposed an inhibitory role for RHOA G17V via sequestration of active GEF proteins. Consistently, while forced activation of RHOA signaling by GFP-RHOA overexpression induced loss of adhesion and round cell morphology in HEK293T cells, transfection of GFP-RHOA-G17V induced increased elongation and cellular protrusions as result of RHOA inactivation. In addition, immunoflourescence analysis of actin stress fiber formation by RHOA demonstrated effective abrogation of RHOA mediated cytoskeleton remodeling in cells expressing RHOA G17V. Overall these results show novel insight on the genetic basis of PTCLs and demonstrate a prominent role for RHOA G17V in the pathogenesis of AITL via disruption of RHOA signaling. Disclosures: No relevant conflicts of interest to declare.