Overcoming Transcription Activator-like Effector (TALE) DNA Binding Domain Sensitivity to Cytosine Methylation
Background: TALE-based technologies are poised to revolutionize the field of biotechnology; however, their sensitivity to cytosine methylation may drastically restrict their ranges of applications. Results: TALE repeat N* proficiently accommodates 5-methylated cytosine. Conclusion: Sensitivity of TALE to cytosine methylation can be overcome by using TALE repeat N*. Significance: Utilization of TALE repeat N* enables broadening the scope of TALE-based technologies.Within the past 2 years, transcription activator-like effector (TALE) DNA binding domains have emerged as the new generation of engineerable platform for production of custom DNA binding domains. However, their recently described sensitivity to cytosine methylation represents a major bottleneck for genome engineering applications. Using a combination of biochemical, structural, and cellular approaches, we were able to identify the molecular basis of such sensitivity and propose a simple, drug-free, and universal method to overcome it.Transcription activator-like effectors (TALEs), 4 a group of bacterial plant pathogen proteins, have recently emerged as new engineerable scaffolds for production of tailored DNA binding domains with chosen specificities (1). Interest in these systems comes from the apparent simple cipher governing DNA recognition by their DNA binding domain (2, 3). The TALE DNA binding domain is composed of multiple TALE repeats that individually recognize one DNA base pair through specific amino acid di-residues (repeat variable di-residues or RVDs). The remarkably high specificity of TALE repeats and the apparent absence of context-dependent effects among repeats in an array allow modular assembly of TALE DNA binding domains able to recognize almost any DNA sequence of interest. Within the past 2 years, engineered TALE DNA binding domains have been fused to transcription activator (dTALEs) (4), repressor (5), or nuclease domains (TALENs) (6) and used to specifically regulate or modify genes of interest (1). Although successfully used in different cellular contexts, engineered TALE DNA binding domains have recently been reported to be affected by the presence of 5-methylated cytosine (5mC) in their endogenous cognate target (7). Often considered as the fifth base, 5mC is found in about 70% of CpG dinucleotides in mammalian and plant somatic/pluripotent cells (8, 9) and has also been reported in 5-cytosine-phosphoadenine, 5-cytosine-phosphothymine, and 5-cytosine-phosphocytosine dinucleotides (10). Moreover, 5mC has been identified in CpG islands embedded in many promoters (11) and, to a higher extent, in proximal exons of several genes (12). These two critical regulatory regions are generally chosen by investigators to knock out genes of therapeutic and biotechnological interest or to modulate their expression using TALE-based technologies. The ubiquity of 5mC in different cell types and genomic kingdoms, its particular localization, and its negative impact on dTALE activity reported in Ref. 7 make this epigenetic modification a major dra...
Granulocyte–macrophage colony-stimulating factor inactivation in CAR T-cells prevents monocyte-dependent release of key cytokine release syndrome mediators
Edited by Peter Cresswell Chimeric antigen receptor T-cell (CAR T-cell) therapy has been shown to be clinically effective for managing a variety of hematological cancers. However, CAR T-cell therapy is associated with multiple adverse effects, including neurotoxicity and cytokine release syndrome (CRS). CRS arises from massive cytokine secretion and can be life-threatening, but it is typically managed with an anti-IL-6Ra mAb or glucocorticoid administration. However, these treatments add to a patient's medication burden and address only the CRS symptoms. Therefore, alternative strategies that can prevent CRS and neurotoxicity associated with CAR T-cell treatment are urgently needed. Here, we explored a therapeutic route aimed at preventing CRS rather than limiting its consequences. Using a cytokine-profiling assay, we show that granulocyte-macrophage colony-stimulating factor (GMCSF) is a key CRS-promoting protein. Through a combination of in vitro experiments and gene-editing technology, we further demonstrate that antibody-mediated neutralization or TALEN-mediated genetic inactivation of GMCSF in CAR T-cells drastically decreases available GMCSF and abolishes macrophage-dependent secretion of CRS biomarkers, including monocyte chemoattractant protein 1 (MCP-1), interleukin (IL) 6, and IL-8. Of note, we also found that the genetic inactivation of GMCSF does not impair the antitumor function or proliferative capacity of CAR T-cells in vitro. We conclude that it is possible to prevent CRS by using "all-in-one" GMCSF-knockout CAR T-cells. This approach may eliminate the need for anti-CRS treatment and may improve the overall safety of CAR T-cell therapies for cancer patients.
A key to the success of chimeric antigen receptor (CAR) T-cell based therapies greatly rely on the capacity to identify and target antigens with expression restrained to tumor cells. Here we present a strategy to generate CAR T-cells that are only effective locally (tumor tissue), potentially also increasing the choice of targetable antigens. By fusing an oxygen sensitive subdomain of HIF1α to a CAR scaffold, we generated CAR T-cells that are responsive to a hypoxic environment, a hallmark of certain tumors. Along with the development of oxygen-sensitive CAR T-cells, this work also provides a basic framework to use a multi-chain CAR as a platform to create the next generation of smarter self-decision making CAR T-cells.
Preclinical Evaluation of Allogeneic CAR T Cells Targeting BCMA for the Treatment of Multiple Myeloma
Clinical success of autologous CD19-directed chimeric antigen receptor T cells (CAR Ts) in acute lymphoblastic leukemia and non-Hodgkin lymphoma suggests that CAR Ts may be a promising therapy for hematological malignancies, including multiple myeloma. However, autologous CAR T therapies have limitations that may impact clinical use, including lengthy vein-to-vein time and manufacturing constraints. Allogeneic CAR T (AlloCAR T) therapies may overcome these innate limitations of autologous CAR T therapies. Unlike autologous cell therapies, AlloCAR T therapies employ healthy donor T cells that are isolated in a manufacturing facility, engineered to express CARs with specificity for a tumor-associated antigen, and modified using gene-editing technology to limit T cell receptor (TCR)-mediated immune responses. Here, transcription activator-like effector nuclease (TALEN) gene editing of B cell maturation antigen (BCMA) CAR Ts was used to confer lymphodepletion resistance and reduced graft-versus-host disease (GvHD) potential. The safety profile of allogeneic BCMA CAR Ts was further enhanced by incorporating a CD20 mimotope-based intra-CAR off switch enabling effective CAR T elimination in the presence of rituximab. Allogeneic BCMA CAR Ts induced sustained antitumor responses in mice supplemented with human cytokines, and, most importantly, maintained their phenotype and potency after scale-up manufacturing. This novel off-the-shelf allogeneic BCMA CAR T product is a promising candidate for clinical evaluation.
The ActVA-ActVB system from Streptomyces coelicolor is a two-component flavin-dependent monooxygenase involved in the antibiotic actinorhodin biosynthesis. ActVB is a NADH:flavin oxidoreductase that provides a reduced FMN to ActVA, the monooxygenase that catalyzes the hydroxylation of dihydrokalafungin, the precursor of actinorhodin. In this work, using stopped-flow spectrophotometry, we investigated the mechanism of hydroxylation of dihydrokalafungin catalyzed by ActVA and that of the reduced FMN transfer from ActVB to ActVA. Our results show that the hydroxylation mechanism proceeds with the participation of two different reaction intermediates in ActVA active site. , 7), in the utilization of sulfur from aliphatic sulfonates in E. coli (8), and in the desulfurization of fossil fuels by Rhodococcus species (9), as well as the hydroxylation of 4-hydroxyphenylacetate in Acinetobacter baumannii (10). We have been investigating the mechanism of the FMN-dependent twocomponent enzyme system, ActVA-ActVB, which participates in the last steps of the biosynthesis of the antibiotic actinorhodin in Streptomyces coelicolor (11-13) (Scheme 1).The first enzyme of the two-component flavin-dependent oxygenases is a NAD(P)H:flavin oxidoreductase that catalyzes the reduction of free oxidized flavins (FAD and/or FMN) by the reduced pyridine nucleotides, NADPH or NADH (3,[14][15][16]. The second enzyme is an oxygenase that binds the resulting free reduced flavin and promotes its reaction with O 2 to hydroxylate the substrate (2,3,(5)(6)(7)(8)(9)(10)17). Therefore, in contrast to the single-component flavin hydroxylases, the two-component sys-* This work was supported by National Institutes of Health Grant GM64711 (to D. P. B.). The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact. 1 To whom correspondence may be addressed.
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