CRISPRa-mediated FOXP3 gene upregulation in mammalian cells

Forstnerič, Vida; Oven, Irena; Ogorevc, Jernej; Praznik, Arne; Lebar, Tina; Jerala, Roman; Horvat, Simon

doi:10.1186/s13578-019-0357-0

Cited by 21 publications

(18 citation statements)

References 46 publications

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“…CNS3 located at FOXP3 intron 1 (i.e., between exon 1 and 2) acts as a genetic switch that initiates gene expression through interactions with c-rel (15,16) and atypical NF-κB inhibitor (17). Accordingly, targeting CNS3 chromatin accessibility with a specific ribonucleoprotein (dCas9-catalytically inactive variant of clustered regularly interspaced short palindromic repeats-associated protein 9) has been shown to promote FOXP3 expression in Jurkat cells (18), whereas endogenous long non-coding RNA (FLICR-Foxp3 long intergenic non-coding RNA) induces a FOXP3 low T-cell subset (19). Although high FOXP3 expression levels are commonly attributed to CD4 + CD25 high Treg cells, FOXP3 is also induced by TCR stimulation in naive CD4 + CD25 − T cells and persists for several days in activated CD4 + T cells (20).…”

Section: Ipex Mutations Target Foxp3-the Indispensable Immune Regulatormentioning

confidence: 99%

IPEX as a Consequence of Alternatively Spliced FOXP3

Mailer

2020

Front. Pediatr.

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The transcription factor FOXP3 controls the immunosuppressive program in CD4 + T cells that is crucial for systemic immune regulation. Mutations of the single X-chromosomal FOXP3 gene in male individuals cause the inherited autoimmune disease immune dysregulation, polyendocrinopathy, enteropathy, and X-linked (IPEX) syndrome. Insufficient gene expression and impaired function of mutant FOXP3 protein prevent the generation of anti-inflammatory regulatory T (Treg) cells and fail to inhibit autoreactive T cell responses. Diversification of FOXP3 functional properties is achieved through alternative splicing that leads to isoforms lacking exon 2 (FOXP3 2), exon 7 (FOXP3 7), or both (FOXP3 2 7) specifically in human CD4 + T cells. Several IPEX mutations targeting these exons or promoting their alternative splicing revealed that those truncated isoforms cannot compensate for the loss of the full-length isoform (FOXP3fl). In this review, IPEX mutations that change the FOXP3 isoform profile and the resulting consequences for the CD4 + T-cell phenotype are discussed.

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Section: Ipex Mutations Target Foxp3-the Indispensable Immune Regulatormentioning

confidence: 99%

IPEX as a Consequence of Alternatively Spliced FOXP3

Mailer

2020

Front. Pediatr.

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“…Overexpression of the transcription factor HELIOS cooperates with FOXP3 to generate both CD4 + and CD8 + Treg from human Tconv, but particularly CD8 + T cells ( 20 ). Similarly, delivery of dCas9 fused to a transcriptional activator and guides recognizing FOXP3 promoter sequences increases FOXP3 expression ( 104 ).…”

Section: Genetic Engineering Strategies For Enhanced Stability and Fumentioning

confidence: 99%

Super-Treg: Toward a New Era of Adoptive Treg Therapy Enabled by Genetic Modifications

et al. 2021

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Regulatory Tcells (Treg) are essential components of peripheral immune homeostasis. Adoptive Treg cell therapy has shown efficacy in a variety of immune-mediated diseases in preclinical studies and is now moving from phase I/IIa to larger phase II studies aiming to demonstrate efficacy. However, hurdles such as in vivo stability and efficacy remain to be addressed. Nevertheless, preclinical models have shown that Treg function and specificity can be increased by pharmacological substances or gene modifications, and even that conventional T cells can be converted to Treg potentially providing new sources of Treg and facilitating Treg cell therapy. The exponential growth in genetic engineering techniques and their application to T cells coupled to a large body of knowledge on Treg open numerous opportunities to generate Treg with “superpowers”. This review summarizes the genetic engineering techniques available and their applications for the next-generation of Super-Treg with increased function, stability, redirected specificity and survival.

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“…Although not applied in pre-clinical studies, a number of early works also suggest that dCas9-based methods can help circumvent other major tumor immunoevasion mechanisms. For instance, impairment of Treg immunosuppressive function by dCas9-KRAB-mediated forkhead box P3 (FoxP3) transcriptional repression, 139 , 140 dCas9-SAM-mediated enhancement of neoplastic transformation markers, such as MICA, 141 , 142 and dCas9-KRAB-directed repression of immunosuppressive cytokine receptors 143 have demonstrated that dCas9-mediated epigenetic engineering has potential in multiple facets of cancer immunotherapy. Ultimately, dCas9-mediated epigenetic editing to improve tumor immunogenicity and/or boost the host’s anti-tumor immune response opens new therapeutic avenues, particularly in combination with ICI or ACT therapies ( Figure 2 ).…”

Section: Epigenetic Editing By Crispr-dcas9 Can Improve Anti-tumor Host Immunitymentioning

confidence: 99%

Reprogramming the anti-tumor immune response via CRISPR genetic and epigenetic editing

Alves

Taifour

Dolcetti

et al. 2021

Molecular Therapy - Methods & Clinical Development

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Precise clustered regularly interspaced short palindromic repeats (CRISPR)-mediated genetic and epigenetic manipulation of the immune response has become a promising immunotherapeutic approach toward combating tumorigenesis and tumor progression. CRISPR-based immunologic reprograming in cancer therapy comprises the locus-specific enhancement of host immunity, the improvement of tumor immunogenicity, and the suppression of tumor immunoevasion. To date, the ex vivo re-engineering of immune cells directed to inhibit the expression of immune checkpoints or to express synthetic immune receptors (chimeric antigen receptor therapy) has shown success in some settings, such as in the treatment of melanoma, lymphoma, liver, and lung cancer. However, advancements in nuclease-deactivated CRISPR-associated nuclease-9 (dCas9)-mediated transcriptional activation or repression and Cas13-directed gene suppression present novel avenues for the development of tumor immunotherapies. In this review, the basis for development, mechanism of action, and outcomes from recently published Cas9-based clinical trial (genetic editing) and dCas9/Cas13-based pre-clinical (epigenetic editing) data are discussed. Lastly, we review cancer immunotherapy-specific considerations and barriers surrounding use of these approaches in the clinic.

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CRISPRa-mediated FOXP3 gene upregulation in mammalian cells

Cited by 21 publications

References 46 publications

IPEX as a Consequence of Alternatively Spliced FOXP3

IPEX as a Consequence of Alternatively Spliced FOXP3

Super-Treg: Toward a New Era of Adoptive Treg Therapy Enabled by Genetic Modifications

Reprogramming the anti-tumor immune response via CRISPR genetic and epigenetic editing

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