Activation-inducible CAR expression enables precise control over engineered CAR T cell function.

CAR T cell therapy is a rapidly growing area of oncological treatments having a potential of becoming standard care for multiple indications. Coincidently, CRISPR/Cas gene-editing technology is entering next-generation CAR T cell product manufacturing with the promise of more precise and more controllable cell modification methodology. The intersection of these medical and molecular advancements creates an opportunity for completely new ways of designing engineered cells to help overcome current limitations of cell therapy. In this manuscript we present proof-of-concept data for an engineered feedback loop. We manufactured activation-inducible CAR T cells with the help of CRISPR-mediated targeted integration. This new type of engineered T cells expresses the CAR gene dependent on their activation status. This artifice opens new possibilities to regulate CAR T cell function both in vitro and in vivo. We believe that such a physiological control system can be a powerful addition to the currently available toolbox of next-generation CAR constructs.

Ubiquitination and the proteasome rather than caspase-3-mediated C-terminal cleavage are involved in the EAAT2 degradation by staurosporine-induced cellular stress.

Diminished glutamate (Glu) uptake via the excitatory amino acid transporter EAAT2, which normally accounts for ~90% of total forebrain EAAT activity, may contribute to neurodegeneration via Glu-mediated excitotoxicity. C-terminal cleavage by caspase-3 (C3) was reported to mediate EAAT2 inactivation and down-regulation in the context of neurodegeneration. For a detailed analysis of C3-dependent EAAT2 degradation, we employed A172 glioblastoma as well as hippocampal HT22 cells and murine astrocytes over-expressing VSV-G-tagged EAAT2 constructs. C3 activation was induced by staurosporine (STR). In HT22 cells, STR-induced C3 activation-induced rapid EAAT2 protein degradation. The mutation of asparagine 504 to aspartate (D504N), which should inactivate the putative C3 cleavage site, increased EAAT2 activity in A172 cells. In contrast, the D504N mutation did not protect EAAT2 protein against STR-induced degradation in HT22 cells, whereas inhibition of caspases, ubiquitination and the proteasome did. Similar results were obtained in astrocytes. Phylogenetic analysis showed that C-terminal ubiquitin acceptor sites-but not the putative C3 cleavage site-exhibit a high degree of conservation. Moreover, C-terminal truncation mimicking C3 cleavage increased rather than decreased EAAT2 activity and stability as well as protected EAAT2 against STR-induced ubiquitination-dependent degradation. We conclude that cellular stress associated with endogenous C3 activation degrades EAAT2 via a pathway involving ubiquitination and the proteasome but not direct C3-mediated cleavage. In addition, C3 cleavage of EAAT2, described to occur in other models, is unlikely to inactivate EAAT2. However, mutation of the highly conserved D504 within the putative C3 cleavage site increases EAAT2 activity via an unknown mechanism.

FLEXamers: A Double Tag for Universal Generation of Versatile Peptide-MHC Multimers.

Peptide-MHC (pMHC) multimers have become a valuable tool for immunological research, clinical immune monitoring, and immunotherapeutic applications. Biotinylated tetramers, reversible Streptamers, or dye-conjugated pMHC multimers are distinct pMHC reagents tailored for T cell identification, traceless T cell isolation, or TCR characterization, respectively. The specific applicability of each pMHC-based reagent is made possible either through conjugation of probes or reversible multimerization in separate production processes, which is laborious, time-consuming, and prone to variability between the different types of pMHC reagents. This prohibits broad implementation of different types of pMHC reagents as a standard toolbox in routine clinical immune monitoring and immunotherapy. In this article, we describe a novel method for fast and standardized generation of any pMHC multimer reagent from a single precursor ("FLEXamer"). FLEXamers unite reversible multimerization and versatile probe conjugation through a novel double tag (Strep-tag for reversibility and Tub-tag for versatile probe conjugation). We demonstrate that FLEXamers can substitute conventional pMHC reagents in all state-of-the-art applications, considerably accelerating and standardizing production without sacrificing functional performance. Although FLEXamers significantly aid the applicability of pMHC-based reagents in routine workflows, the double tag also provides a universal tool for the investigation of transient molecular interactions in general.