Project description:Targeted epigenetic engineering of gene expression in cell therapies would allow programming of desirable phenotypes without many of the challenges and safety risks associated with double strand break-based genetic editing approaches. Here, we develop an all-RNA platform for efficient, durable, and multiplexed epigenetic programming in primary human T cells, stably turning endogenous genes off or on using CRISPRoff and CRISPRon epigenetic editors. We achieve epigenetic programming of diverse targeted genomic elements without the need for sustained expression of CRISPR systems. CRISPRoff-mediated gene silencing is maintained through numerous cell divisions, T cell stimulations, and in vivo adoptive transfer, avoiding cytotoxicity or chromosomal abnormalities inherent to multiplexed Cas9-mediated genome editing. Finally, we successfully combined genetic and epigenetic-engineering using orthogonal CRISPR Cas12a/dCas9 systems for targeted CAR knockin and CRISPRoff silencing of therapeutically relevant genes to improve preclinical CAR T cell-mediated in vivo tumor control and survival.

Project description:Multiplexed epigenetic memory editing using CRISPRoff sensitizes glioblastoma to chemotherapy.

Project description:Engineered T cells equipped with a chimeric antigen receptor (CAR) have shown tremendous clinical success but tumor-mediated stimulation of T cell inhibitory receptors leads to exhaustion, hampering durable remission in patients. Mitigation of this effect via checkpoint inhibition or genome editing to knockout the genes encoding for these receptors has shown promise. Yet, the side effects of these procedures require alternatives. Targeted epigenome editing is a potent strategy to alter gene expression in the absence of DNA modifications. The hit-and-run feature enables durable multiplexed modulation of gene expression with greater safety. Here we describe multiplexed epigenome editing inactivation of two critical exhaustion-related genes, PDCD1 and LAG3, both in primary human T cells and in prostate cancer specific CAR T cells. Epigenetically modified CAR T cells are fully functional and nearly indistinguishable from parental cells in a variety of functional assays. Target gene silencing is durable over multiple cell divisions and repeated CAR-mediated stimulations. Furthermore, transcriptomic analysis revealed minimal off-target effects not directly attributable to the effectors used. We demonstrate that targeted epigenome editing is an effective and safe procedure for multiplexed gene inhibition and that this strategy can be used to engineer CAR T cells with novel desirable features.

Project description:General approaches for heritably altering gene expression would enable many discovery and therapeutic efforts. Here, we present CRISPRoff— a programmable epigenetic memory writer consisting of a single dead Cas9 fusion protein that establishes DNA methylation and repressive histone modifications. Transient CRISPRoff expression initiates highly specific DNA methylation and gene repression that is maintained through cell division and differentiation of stem cells to neurons. Pairing CRISPRoff with genome-wide screens and analysis of chromatin marks enabled us to explore the rules for heritable silencing. We identify sgRNAs capable of silencing the large majority of genes including those lacking canonical CpG islands (CGIs) and reveal a wide targeting window extending beyond annotated CGIs. Our finding that targeted DNA methylation outside of CGIs leads to memorized gene silencing expands the canonical model of methylation-based silencing and broadly enables diverse applications including genome-wide screens, multiplexed cell engineering, enhancer silencing, and mechanistic exploration of epigenetic inheritance.

Project description:Aging is reflected by genome-wide DNA methylation changes, but it is largely unclear how these epigenetic modifications are regulated. In this study, we explored the possibility to interfere with epigenetic clocks by epigenetic editing at individual CpG sites. CRISPR-guided approaches (dCas9-DNMT3A and CRISPRoff) facilitated targeted methylation at an age-associated genomic region in PDE4C that remained stable for more than three months. Furthermore, epigenetic editing evoked many genome-wide off-target effects, which were highly reproducible and enriched at other age-associated CpGs - thus, they are not random off-target effects, but seem to resemble coregulated epigenetic bystander modifications. 4C chromatin conformation analysis at age-associated sites revealed increased interactions with bystander modifications and other age-associated CpG sites. Subsequently, we multiplexed epigenetic modifications in HEK293T and primary T cells at five genomic regions that become either hypermethylated or hypomethylated upon aging. While epigenetic editing at age-hypomethylated CpGs appeared less stable, it also resulted in a clear enrichment of bystander modifications at other age-associated CpGs. Conversely, epigenetic clocks tend to be accelerated up to ten years after targeted DNA methylation, particularly at hypermethylated CpGs. These results demonstrate that targeted epigenome editing can modulate the epigenetic aging network in its entirety and thereby interfere with epigenetic clocks.

Project description:Aging is reflected by genome-wide DNA methylation changes, but it is largely unclear how these epigenetic modifications are regulated. In this study, we explored the possibility to interfere with epigenetic clocks by epigenetic editing at individual CpG sites. CRISPR-guided approaches (dCas9-DNMT3A and CRISPRoff) facilitated targeted methylation at an age-associated genomic region in PDE4C that remained stable for more than three months. Furthermore, epigenetic editing evoked many genome-wide off-target effects, which were highly reproducible and enriched at other age-associated CpGs - thus, they are not random off-target effects, but seem to resemble coregulated epigenetic bystander modifications. 4C chromatin conformation analysis at age-associated sites revealed increased interactions with bystander modifications and other age-associated CpG sites. Subsequently, we multiplexed epigenetic modifications in HEK293T and primary T cells at five genomic regions that become either hypermethylated or hypomethylated upon aging. While epigenetic editing at age-hypomethylated CpGs appeared less stable, it also resulted in a clear enrichment of bystander modifications at other age-associated CpGs. Conversely, epigenetic clocks tend to be accelerated up to ten years after targeted DNA methylation, particularly at hypermethylated CpGs. These results demonstrate that targeted epigenome editing can modulate the epigenetic aging network in its entirety and thereby interfere with epigenetic clocks.

Project description:Aging is reflected by genome-wide DNA methylation changes, but it is largely unclear how these epigenetic modifications are regulated. In this study, we explored the possibility to interfere with epigenetic clocks by epigenetic editing at individual CpG sites. CRISPR-guided approaches (dCas9-DNMT3A and CRISPRoff) facilitated targeted methylation at an age-associated genomic region in PDE4C that remained stable for more than three months. Furthermore, epigenetic editing evoked many genome-wide off-target effects, which were highly reproducible and enriched at other age-associated CpGs - thus, they are not random off-target effects, but seem to resemble coregulated epigenetic bystander modifications. 4C chromatin conformation analysis at age-associated sites revealed increased interactions with bystander modifications and other age-associated CpG sites. Subsequently, we multiplexed epigenetic modifications in HEK293T and primary T cells at five genomic regions that become either hypermethylated or hypomethylated upon aging. While epigenetic editing at age-hypomethylated CpGs appeared less stable, it also resulted in a clear enrichment of bystander modifications at other age-associated CpGs. Conversely, epigenetic clocks tend to be accelerated up to ten years after targeted DNA methylation, particularly at hypermethylated CpGs. These results demonstrate that targeted epigenome editing can modulate the epigenetic aging network in its entirety and thereby interfere with epigenetic clocks.

Project description:Aging is reflected by genome-wide DNA methylation changes, but it is largely unclear how these epigenetic modifications are regulated. In this study, we explored the possibility to interfere with epigenetic clocks by epigenetic editing at individual CpG sites. CRISPR-guided approaches (dCas9-DNMT3A and CRISPRoff) facilitated targeted methylation at an age-associated genomic region in PDE4C that remained stable for more than three months. Furthermore, epigenetic editing evoked many genome-wide off-target effects, which were highly reproducible and enriched at other age-associated CpGs - thus, they are not random off-target effects, but seem to resemble coregulated epigenetic bystander modifications. 4C chromatin conformation analysis at age-associated sites revealed increased interactions with bystander modifications and other age-associated CpG sites. Subsequently, we multiplexed epigenetic modifications in HEK293T and primary T cells at five genomic regions that become either hypermethylated or hypomethylated upon aging. While epigenetic editing at age-hypomethylated CpGs appeared less stable, it also resulted in a clear enrichment of bystander modifications at other age-associated CpGs. Conversely, epigenetic clocks tend to be accelerated up to ten years after targeted DNA methylation, particularly at hypermethylated CpGs. These results demonstrate that targeted epigenome editing can modulate the epigenetic aging network in its entirety and thereby interfere with epigenetic clocks.

Project description:Aging is reflected by genome-wide DNA methylation changes, but it is largely unclear how these epigenetic modifications are regulated. In this study, we explored the possibility to interfere with epigenetic clocks by epigenetic editing at individual CpG sites. CRISPR-guided approaches (dCas9-DNMT3A and CRISPRoff) facilitated targeted methylation at an age-associated genomic region in PDE4C that remained stable for more than three months. Furthermore, epigenetic editing evoked many genome-wide off-target effects, which were highly reproducible and enriched at other age-associated CpGs - thus, they are not random off-target effects, but seem to resemble coregulated epigenetic bystander modifications. 4C chromatin conformation analysis at age-associated sites revealed increased interactions with bystander modifications and other age-associated CpG sites. Subsequently, we multiplexed epigenetic modifications in HEK293T and primary T cells at five genomic regions that become either hypermethylated or hypomethylated upon aging. While epigenetic editing at age-hypomethylated CpGs appeared less stable, it also resulted in a clear enrichment of bystander modifications at other age-associated CpGs. Conversely, epigenetic clocks tend to be accelerated up to ten years after targeted DNA methylation, particularly at hypermethylated CpGs. These results demonstrate that targeted epigenome editing can modulate the epigenetic aging network in its entirety and thereby interfere with epigenetic clocks.

Project description:Aging is reflected by genome-wide DNA methylation changes, but it is largely unclear how these epigenetic modifications are regulated. In this study, we explored the possibility to interfere with epigenetic clocks by epigenetic editing at individual CpG sites. CRISPR-guided approaches (dCas9-DNMT3A and CRISPRoff) facilitated targeted methylation at an age-associated genomic region in PDE4C that remained stable for more than three months. Furthermore, epigenetic editing evoked many genome-wide off-target effects, which were highly reproducible and enriched at other age-associated CpGs - thus, they are not random off-target effects, but seem to resemble coregulated epigenetic bystander modifications. 4C chromatin conformation analysis at age-associated sites revealed increased interactions with bystander modifications and other age-associated CpG sites. Subsequently, we multiplexed epigenetic modifications in HEK293T and primary T cells at five genomic regions that become either hypermethylated or hypomethylated upon aging. While epigenetic editing at age-hypomethylated CpGs appeared less stable, it also resulted in a clear enrichment of bystander modifications at other age-associated CpGs. Conversely, epigenetic clocks tend to be accelerated up to ten years after targeted DNA methylation, particularly at hypermethylated CpGs. These results demonstrate that targeted epigenome editing can modulate the epigenetic aging network in its entirety and thereby interfere with epigenetic clocks.