Browsing by Author "Hilton, Isaac B."
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Item Compact engineered human mechanosensitive transactivation modules enable potent and versatile synthetic transcriptional control(Springer Nature, 2023) Mahata, Barun; Cabrera, Alan; Brenner, Daniel A.; Guerra-Resendez, Rosa Selenia; Li, Jing; Goell, Jacob; Wang, Kaiyuan; Guo, Yannie; Escobar, Mario; Parthasarathy, Abinand Krishna; Szadowski, Hailey; Bedford, Guy; Reed, Daniel R.; Kim, Sunghwan; Hilton, Isaac B.Engineered transactivation domains (TADs) combined with programmable DNA binding platforms have revolutionized synthetic transcriptional control. Despite recent progress in programmable CRISPR–Cas-based transactivation (CRISPRa) technologies, the TADs used in these systems often contain poorly tolerated elements and/or are prohibitively large for many applications. Here, we defined and optimized minimal TADs built from human mechanosensitive transcription factors. We used these components to construct potent and compact multipartite transactivation modules (MSN, NMS and eN3x9) and to build the CRISPR–dCas9 recruited enhanced activation module (CRISPR-DREAM) platform. We found that CRISPR-DREAM was specific and robust across mammalian cell types, and efficiently stimulated transcription from diverse regulatory loci. We also showed that MSN and NMS were portable across Type I, II and V CRISPR systems, transcription activator-like effectors and zinc finger proteins. Further, as proofs of concept, we used dCas9-NMS to efficiently reprogram human fibroblasts into induced pluripotent stem cells and demonstrated that mechanosensitive transcription factor TADs are efficacious and well tolerated in therapeutically important primary human cell types. Finally, we leveraged the compact and potent features of these engineered TADs to build dual and all-in-one CRISPRa AAV systems. Altogether, these compact human TADs, fusion modules and delivery architectures should be valuable for synthetic transcriptional control in biomedical applications.Item Persistent tailoring of MSC activation through genetic priming(Elsevier, 2024) Beauregard, Michael A.; Bedford, Guy C.; Brenner, Daniel A.; Sanchez Solis, Leonardo D.; Nishiguchi, Tomoki; Abhimanyu; Longlax, Santiago Carrero; Mahata, Barun; Veiseh, Omid; Wenzel, Pamela L.; DiNardo, Andrew R.; Hilton, Isaac B.; Diehl, Michael R.; Chemistry; BioengineeringMesenchymal stem/stromal cells (MSCs) are an attractive platform for cell therapy due to their safety profile and unique ability to secrete broad arrays of immunomodulatory and regenerative molecules. Yet, MSCs are well known to require preconditioning or priming to boost their therapeutic efficacy. Current priming methods offer limited control over MSC activation, yield transient effects, and often induce the expression of pro-inflammatory effectors that can potentiate immunogenicity. Here, we describe a genetic priming method that can both selectively and sustainably boost MSC potency via the controlled expression of the inflammatory-stimulus-responsive transcription factor interferon response factor 1 (IRF1). MSCs engineered to hyper-express IRF1 recapitulate many core responses that are accessed by biochemical priming using the proinflammatory cytokine interferon-γ (IFN-γ). This includes the upregulation of anti-inflammatory effector molecules and the potentiation of MSC capacities to suppress T cell activation. However, we show that IRF1-mediated genetic priming is much more persistent than biochemical priming and can circumvent IFN-γ-dependent expression of immunogenic MHC class II molecules. Together, the ability to sustainably activate and selectively tailor MSC priming responses creates the possibility of programming MSC activation more comprehensively for therapeutic applications.Item Programmable human histone phosphorylation and gene activation using a CRISPR/Cas9-based chromatin kinase(Springer Nature, 2021) Li, Jing; Mahata, Barun; Escobar, Mario; Goell, Jacob; Wang, Kaiyuan; Khemka, Pranav; Hilton, Isaac B.; Bioengineering; BiosciencesHistone phosphorylation is a ubiquitous post-translational modification that allows eukaryotic cells to rapidly respond to environmental stimuli. Despite correlative evidence linking histone phosphorylation to changes in gene expression, establishing the causal role of this key epigenomic modification at diverse loci within native chromatin has been hampered by a lack of technologies enabling robust, locus-specific deposition of endogenous histone phosphorylation. To address this technological gap, here we build a programmable chromatin kinase, called dCas9-dMSK1, by directly fusing nuclease-null CRISPR/Cas9 to a hyperactive, truncated variant of the human MSK1 histone kinase. Targeting dCas9-dMSK1 to human promoters results in increased target histone phosphorylation and gene activation and demonstrates that hyperphosphorylation of histone H3 serine 28 (H3S28ph) in particular plays a causal role in the transactivation of human promoters. In addition, we uncover mediators of resistance to the BRAF V600E inhibitor PLX-4720 in human melanoma cells using genome-scale screening with dCas9-dMSK1. Collectively, our findings enable a facile way to reshape human chromatin using CRISPR/Cas9-based epigenome editing and further define the causal link between histone phosphorylation and human gene activation.Item Quantification of Genome Editing and Transcriptional Control Capabilities Reveals Hierarchies among Diverse CRISPR/Cas Systems in Human Cells(American Chemical Society, 2022) Escobar, Mario; Li, Jing; Patel, Aditi; Liu, Shizhe; Xu, Qi; Hilton, Isaac B.; Bioengineering; BiosciencesCRISPR/Cas technologies have revolutionized the ability to redesign genomic information and tailor endogenous gene expression. Nevertheless, the discovery and development of new CRISPR/Cas systems has resulted in a lack of clarity surrounding the relative efficacies among these technologies in human cells. This deficit makes the optimal selection of CRISPR/Cas technologies in human cells unnecessarily challenging, which in turn hampers their adoption, and thus ultimately limits their utility. Here, we designed a series of endogenous testbed systems to methodically quantify and compare the genome editing, CRISPRi, and CRISPRa capabilities among 10 different natural and engineered Cas protein variants spanning Type II and Type V CRISPR/Cas families. We show that although all Cas protein variants are capable of genome editing and transcriptional control in human cells, hierarchies exist, particularly for genome editing and CRISPRa applications, wherein Cas9 ≥ Cas12a > Cas12e/Cas12j. Our findings also highlight the utility of our modular testbed platforms to rapidly and systematically quantify the functionality of practically any natural or engineered genomic-targeting Cas protein in human cells.Item Reversing Post-Infectious Epigenetic-Mediated Immune Suppression(Frontiers Media S.A., 2021) Abhimanyu; Ontiveros, Carlos O.; Guerra-Resendez, Rosa S.; Nishiguchi, Tomoki; Ladki, Malik; Hilton, Isaac B.; Schlesinger, Larry S.; DiNardo, Andrew R.; Bioengineering; Biosciences; Systems, Synthetic, and Physical BiologyEpigenetic changes limit the immune response from inducing exuberant collateral damage to host tissue after severe and chronic infections. However, following treatment for these infections, including sepsis, pneumonia, hepatitis B, hepatitis C, HIV, tuberculosis (TB) or schistosomiasis, detrimental epigenetic scars persist, and result in long-lasting immune suppression. This is believed to be one of the contributing factors for why survivors of infection have increased all-cause mortality and increased rates of unrelated secondary infections. Several mechanisms that induce epigenetic-mediated immune suppression have been demonstrated in-vitro and in animal models. Modulation of the AMPK-mTOR, NFAT or NR4A pathways is able to block or reverse the development of detrimental epigenetic scars. Similarly, drugs that directly modify epigenetic enzymes, such as those that inhibit histone deacetylase (HDAC) inhibitors, DNA hypomethylating agents or modifiers of the Nucleosome Remodeling and DNA methylation (NuRD) complex or Polycomb Repressive Complex (PRC) have demonstrated capacity to restore host immunity in the setting of cancer-, LCMV- or murine sepsis-induced epigenetic-mediated immune suppression. A third clinically feasible strategy for reversing detrimental epigenetic scars are bioengineering approaches to either directly reverse the detrimental epigenetic marks or to modify the epigenetic enzymes or transcription factors that induce detrimental epigenetic scars. Each of these approaches, alone or in combination, have ablated or reversed detrimental epigenetic marks in in-vitro or in animal models; translational studies are now required to evaluate clinical applicability.Item Single C-to-T substitution using engineered APOBEC3G-nCas9 base editors with minimum genome- and transcriptome-wide off-target effects(American Association for the Advancement of Science, 2020) Lee, Sangsin; Ding, Ning; Sun, Yidi; Yuan, Tanglong; Li, Jing; Yuan, Qichen; Liu, Lizhong; Yang, Jie; Wang, Qian; Kolomeisky, Anatoly B.; Hilton, Isaac B.; Zuo, Erwei; Gao, Xue; Center for Theoretical and Biological PhysicsCytosine base editors (CBEs) enable efficient cytidine-to-thymidine (C-to-T) substitutions at targeted loci without double-stranded breaks. However, current CBEs edit all Cs within their activity windows, generating undesired bystander mutations. In the most challenging circumstance, when a bystander C is adjacent to the targeted C, existing base editors fail to discriminate them and edit both Cs. To improve the precision of CBE, we identified and engineered the human APOBEC3G (A3G) deaminase; when fused to the Cas9 nickase, the resulting A3G-BEs exhibit selective editing of the second C in the 5′-CC-3′ motif in human cells. Our A3G-BEs could install a single disease-associated C-to-T substitution with high precision. The percentage of perfectly modified alleles is more than 6000-fold for disease correction and more than 600-fold for disease modeling compared with BE4max. On the basis of the two-cell embryo injection method and RNA sequencing analysis, our A3G-BEs showed minimum genome- and transcriptome-wide off-target effects, achieving high targeting fidelity.Item The sound of silence: Transgene silencing in mammalian cell engineering(Cell Press, 2022) Cabrera, Alan; Edelstein, Hailey I.; Glykofrydis, Fokion; Love, Kasey S.; Palacios, Sebastian; Tycko, Josh; Zhang, Meng; Lensch, Sarah; Shields, Cara E.; Livingston, Mark; Weiss, Ron; Zhao, Huimin; Haynes, Karmella A.; Morsut, Leonardo; Chen, Yvonne Y.; Khalil, Ahmad S.; Wong, Wilson W.; Collins, James J.; Rosser, Susan J.; Polizzi, Karen; Elowitz, Michael B.; Fussenegger, Martin; Hilton, Isaac B.; Leonard, Joshua N.; Bintu, Lacramioara; Galloway, Kate E.; Deans, Tara L.; BioengineeringTo elucidate principles operating in native biological systems and to develop novel biotechnologies, synthetic biology aims to build and integrate synthetic gene circuits within native transcriptional networks. The utility of synthetic gene circuits for cell engineering relies on the ability to control the expression of all constituent transgene components. Transgene silencing, defined as the loss of expression over time, persists as an obstacle for engineering primary cells and stem cells with transgenic cargos. In this review, we highlight the challenge that transgene silencing poses to the robust engineering of mammalian cells, outline potential molecular mechanisms of silencing, and present approaches for preventing transgene silencing. We conclude with a perspective identifying future research directions for improving the performance of synthetic gene circuits.