Optogenetic approaches for controlling Ca2+ channels provide powerful means for modulating diverse Ca2+-specific biological events in space and time. However, blue light-responsive photoreceptors ...are, in principle, considered inadequate for deep tissue stimulation unless accompanied by optic fiber insertion. Here, we present an ultra-light-sensitive optogenetic Ca2+ modulator, named monSTIM1 encompassing engineered cryptochrome2 for manipulating Ca2+ signaling in the brain of awake mice through non-invasive light delivery. Activation of monSTIM1 in either excitatory neurons or astrocytes of mice brain is able to induce Ca2+-dependent gene expression without any mechanical damage in the brain. Furthermore, we demonstrate that non-invasive Ca2+ modulation in neurons can be sufficiently and effectively translated into changes in behavioral phenotypes of awake mice.Optogenetic applications in the brain of live animals often require the use of optic fibers due to poor tissue-penetration of blue light. Here the authors present monSTIM1, an improved high sensitivity optogenetic tool able to modulate Ca2+ signaling in the brain of awake mice using non-invasive light stimulation.
Cell-based therapies are emerging as effective agents against cancer and other diseases. As autonomous "living drugs," these therapies lack precise control. Chimeric antigen receptor (CAR) T cells ...effectively target hematologic malignancies but can proliferate rapidly and cause toxicity. We developed ON and OFF switches for CAR T cells using the clinically approved drug lenalidomide, which mediates the proteasomal degradation of several target proteins by inducing interactions between the CRL4
E3 ubiquitin ligase and a C2H2 zinc finger degron motif. We performed a systematic screen to identify "super-degron" tags with enhanced sensitivity to lenalidomide-induced degradation and used these degradable tags to generate OFF-switch degradable CARs. To create an ON switch, we engineered a lenalidomide-inducible dimerization system and developed split CARs that required both lenalidomide and target antigen for activation. Subtherapeutic lenalidomide concentrations controlled the effector functions of ON- and OFF-switch CAR T cells. In vivo, ON-switch split CARs demonstrated lenalidomide-dependent antitumor activity, and OFF-switch degradable CARs were depleted by drug treatment to limit inflammatory cytokine production while retaining antitumor efficacy. Together, the data showed that these lenalidomide-gated switches are rapid, reversible, and clinically suitable systems to control transgene function in diverse gene- and cell-based therapies.
Calcium (Ca2+) signals that are precisely modulated in space and time mediate a myriad of cellular processes, including contraction, excitation, growth, differentiation and apoptosis1. However, study ...of Ca2+ responses has been hamperedby technological limitations of existing Ca2+-modulatingtools. Here we present OptoSTIM1, an optogenetic tool for manipulating intracellular Ca2+ levels through activation of Ca2+-selective endogenous Ca2+ releaseactivated Ca2+ (CRAC) channels. Using OptoSTIM1, which combines a plant photoreceptor2,3 and the CRAC channel regulator STIM1 (ref. 4), we quantitatively and qualitatively controlled intracellular Ca2+ levels in various biological systems, including zebrafish embryos and human embryonic stem cells. We demonstrate that activating OptoSTIM1 in the CA1 hippocampal region of mice selectively reinforced contextual memory formation. The broad utility of OptoSTIM1 will expand our mechanistic understanding of numerous Ca2+-associated processes and facilitate screening for drug candidates that antagonize Ca2+ signals.
CAR-T therapy is a promising, novel treatment modality for B-cell malignancies and yet many patients relapse through a variety of means, including loss of CAR-T cells and antigen escape. To ...investigate leukemia-intrinsic CAR-T resistance mechanisms, we performed genome-wide CRISPR-Cas9 loss-of-function screens in an immunocompetent murine model of B-cell acute lymphoblastic leukemia (B-ALL) utilizing a modular guide RNA library. We identified IFNγR/JAK/STAT signaling and components of antigen processing and presentation pathway as key mediators of resistance to CAR-T therapy in vivo; intriguingly, loss of this pathway yielded the opposite effect in vitro (sensitized leukemia to CAR-T cells). Transcriptional characterization of this model demonstrated upregulation of these pathways in tumors relapsed after CAR-T treatment, and functional studies showed a surprising role for natural killer (NK) cells in engaging this resistance program. Finally, examination of data from B-ALL patients treated with CAR-T revealed an association between poor outcomes and increased expression of JAK/STAT and MHC-I in leukemia cells. Overall, our data identify an unexpected mechanism of resistance to CAR-T therapy in which tumor cell interaction with the in vivo tumor microenvironment, including NK cells, induces expression of an adaptive, therapy-induced, T-cell resistance program in tumor cells.
While immune checkpoint blockade results in durable responses for some patients, many others have not experienced such benefits. These treatments rely upon reinvigorating specific T cell-antigen ...interactions. However, it is often unknown what antigens are being recognized by T cells or how to potently induce antigen-specific responses in a broadly applicable manner. Here, we characterized the CD8
+
T cell response to a murine model of melanoma following combination immunotherapy to determine the basis of tumor recognition. Sequencing of tumor-infiltrating T cells revealed a repertoire of highly homologous TCR sequences that were particularly expanded in treated mice and which recognized an antigen from an endogenous retrovirus. While vaccination against this peptide failed to raise a protective T cell response
in vivo
, engineered antigen mimotopes induced a significant expansion of CD8
+
T cells cross-reactive to the original antigen. Vaccination with mimotopes resulted in killing of antigen-loaded cells
in vivo
yet showed modest survival benefit in a prophylactic vaccine paradigm. Together, this work demonstrates the identification of a dominant tumor-associated antigen and generation of mimotopes which can induce robust functional T cell responses that are cross-reactive to the endogenous antigen across multiple individuals.
We present a versatile platform to inactivate proteins in living cells using light, light-activated reversible inhibition by assembled trap (LARIAT), which sequesters target proteins into complexes ...formed by multimeric proteins and a blue light-mediated heterodimerization module. Using LARIAT, we inhibited diverse proteins that modulate cytoskeleton, lipid signaling and cell cycle with high spatiotemporal resolution. Use of single-domain antibodies extends the method to target proteins containing specific epitopes, including GFP.
This study introduces a T cell enrichment process, capitalizing on the size differences between activated and unactivated T cells to facilitate the isolation of activated, transducible T cells. By ...employing multidimensional double spiral (MDDS) inertial sorting, our approach aims to remove unactivated or not fully activated T cells post-activation, consequently enhancing the efficiency of chimeric antigen receptor (CAR) T cell manufacturing. Our findings reveal that incorporating a simple, label-free, and continuous MDDS sorting step yields a purer T cell population, exhibiting significantly enhanced viability and CAR-transducibility (with up to 85% removal of unactivated T cells and approximately 80% recovery of activated T cells); we found approximately 2-fold increase in CAR transduction efficiency for a specific sample, escalating from ∼10% to ∼20%, but this efficiency highly depends on the original T cell sample as MDDS sorting would be more effective for samples possessing a higher proportion of unactivated T cells. This new cell separation process could augment the efficiency, yield, and cost-effectiveness of CAR T cell manufacturing, potentially broadening the accessibility of this transformative therapy and contributing to improved patient outcomes.
Receptor tyrosine kinases (RTKs) are a family of cell-surface receptors that have a key role in regulating critical cellular processes. Here, to understand and precisely control RTK signalling, we ...report the development of a genetically encoded, photoactivatable Trk (tropomyosin-related kinase) family of RTKs using a light-responsive module based on Arabidopsis thaliana cryptochrome 2. Blue-light stimulation (488 nm) of mammalian cells harbouring these receptors robustly upregulates canonical Trk signalling. A single light stimulus triggers transient signalling activation, which is reversibly tuned by repetitive delivery of blue-light pulses. In addition, the light-provoked process is induced in a spatially restricted and cell-specific manner. A prolonged patterned illumination causes sustained activation of extracellular signal-regulated kinase and promotes neurite outgrowth in a neuronal cell line, and induces filopodia formation in rat hippocampal neurons. These light-controllable receptors are expected to create experimental opportunities to spatiotemporally manipulate many biological processes both in vitro and in vivo.
Cell-based therapies are emerging as potent agents against cancer and other diseases, but are uniquely uncontrolled “living drugs”. For example, chimeric antigen receptor (CAR) T cells can ...effectively target hematologic malignancies yet pose a risk for toxic hyperactivation. Future cell-based therapies, including CAR T cells, could be improved by incorporating specific and reversible control systems. However, clinically suitable ON- and OFF-switches engineered from non-immunogenic human polypeptide sequences and regulated by non-immunosuppressive FDA-approved drugs are needed. Here we report the engineering of a robust lenalidomide-responsive degron tag, which we then used to construct a degradable CAR affording reversible OFF-switch functional control at clinically relevant lenalidomide doses.
Thalidomide, lenalidomide, and pomalidomide are effective and clinically approved therapies for multiple myeloma, subtypes of non-Hodgkin lymphoma, and myelodysplastic syndrome with chromosome 5q deletion. These drugs exert therapeutic properties by acting as molecular glue, bridging interactions between the CRL4CRBN ubiquitin ligase and disease-relevant proteins that are subsequently ubiquitinated and degraded by the proteasome. A set of Cys2-His2 (C2H2) zinc fingers have emerged as degron motifs mediating drug-dependent interactions with the CRL4CRBN ubiquitin ligase. We hypothesized that these small, modular, human polypeptide domains could be further engineered and repurposed as tags to induce drug-dependent depletion of engineered proteins. By systematically shuffling the subdomains of all known zinc finger degrons and functionally screening this hybrid zinc finger library, we engineered “super-degron” tags that are more efficiently degraded at lower drug concentrations than any C2H2 zinc finger in the human proteome.
We then incorporated one of these super-degrons (SD01) into a second-generation CAR targeting CD19 (FMC63-4-1BB-CD3z), thereby constructing a degradable CAR (Figure 1A). In a Jurkat T cell model, addition of lenalidomide induced rapid and near-complete depletion of the degradable CAR (Figure 1B/C). When co-cultured with target cells expressing CD19, therapeutically relevant lenalidomide concentrations robustly inhibited T cell activation (Figure 1D). Indeed, the IC50 for inhibition of IL2 secretion and CD69 expression were 2 and 22 nM lenalidomide, respectively, whereas in myeloma patients the plasma concentration of lenalidomide following one 25 mg oral dose decays from ~1000 to 10 nM over the course of 24 hours (Connarn et al, CPDD, 2017). In primary T cells, 100 nM lenalidomide suppressed degradable CAR effector functions including tumor cell killing and cytokine release (Figure 1E). Using pomalidomide, which has a longer in vivo half-life, we demonstrated robust and reversible depletion of the degradable CAR in T cells engrafted in NSG mice. Together, these findings demonstrate reversible OFF-switch control of degradable CARs at clinically relevant lenalidomide concentrations. Experiments are underway to determine whether, in the context of tumor clearance in NSG mice, degradable CAR T cell effector functions can be paused and subsequently released with short-term administration of lenalidomide. Whereas the current management of CAR T cell hyperactivation syndromes consists of supportive care, tocilizumab, and/or high-dose corticosteroids, we propose that cytokine release and CAR-related encephalopathy syndromes may be more easily diagnosed and managed with degradable CARs. The super-degron tags presented here are generalizable and clinically suitable tools to achieve chemical genetic control of diverse genetically engineered cell therapies.
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Jan:Broad Institute: Other: Contributor to a patent filing on this technology that is held by the Broad Institute.. Sievers:Broad Institute: Other: Contributor to a patent filing on this technology that is held by the Broad Institute.. Maus:Broad Institute: Other: Contributor to a patent filing on this technology that is held by the Broad Institute.. Ebert:Broad Institute: Other: Contributor to a patent filing on this technology that is held by the Broad Institute.; Deerfield: Research Funding; Celgene: Research Funding.