MALT1 forms part of a central signaling node downstream of immunoreceptor tyrosine-based activation motif (ITAM)-containing receptors, across a broad range of immune cell subsets, and regulates NF-κB driven transcriptional responses via dual scaffolding-protease activity. Allosteric inhibition of MALT1 activity has demonstrated benefit in animal models of inflammation. However, development of MALT1 inhibitors to treat autoimmune and inflammatory diseases (A&ID) has been hindered by reports linking MALT1 inhibition and genetic loss-of-function to reductions in regulatory T-cell (Treg) numbers and development of auto-inflammatory syndromes. Using an allosteric MALT1 inhibitor, we investigated the consequence of pharmacological inhibition of MALT1 on proinflammatory cells compared to regulatory T-cells. Consistent with its known role in ITAM-driven responses, MALT1 inhibition suppressed proinflammatory cytokine production from activated human T-cells and monocyte-derived macrophages, and attenuated B-cell proliferation. Oral administration of a MALT1 inhibitor reduced disease severity and synovial cytokine production in a rat collagen-induced arthritis model. Interestingly, reduction in splenic Treg numbers was less pronounced in the context of inflammation compared with naïve animals. Additionally, in the context of the disease model, we observed an uncoupling of anti-inflammatory effects of MALT1 inhibition from Treg reduction, with lower systemic concentrations of inhibitor needed to reduce disease severity compared to that required to reduce Treg numbers. MALT1 inhibition did not affect suppressive function of human Tregs in vitro. These data indicate that anti-inflammatory efficacy can be achieved with MALT1 inhibition without impacting the number or function of Tregs, further supporting the potential of MALT1 inhibition in the treatment of autoimmune disease.
Beta hemoglobinopathies resulting from dysfunctional or deficient adult beta-globin expression are some of the most prevalent inherited blood disorders in the world. Upregulation of developmentally-silenced fetal gamma-globin would replace adult beta-globin to ameliorate disease symptoms. One of the approaches to reactivate fetal globin expression in erythroid cells is through gene editing by zinc finger or CRISPR-Cas9 nucleases to disrupt the expression of a transcription factor BCL11A, which mediates fetal globin silencing. As BCL11A-deficiency leads to hematopoietic stem cells (HSCs) defects, the current editing approaches target the BCL11A erythroid-enhancer region located in intron 2 of the BCL11A gene to selectively reduce BCL11A expression in erythroid cells. Instead of targeting BCL11A, we sought to identify novel cis-regulatory elements at the beta-globin locus for targeted gene editing to achieve fetal globin reactivation. From a lenti-CRISPR mediated saturated mutagenesis screen covering the beta-globin locus using Human Umbilical Cord Blood-Derived Erythroid Progenitor (HUDEP)-2 cells, multiple fetal hemoglobin (HbF)-inducing genomic domains were identified. Most of the hits were concentrated at the gamma-globin (HBG1/2) promoters, clustered at known hereditary persistence of fetal hemoglobin (HPFH) mutation hotspots. In-depth genotype to phenotype analysis further defined the indels responsible for HbF induction in these subdomains. We interrogated multiple families of nucleases and guide RNA (gRNA) combinations with or without single-stranded oligodeoxynucleotides (ssODN) to guide editing outcome. gRNAs were selected based on their HbF induction potential (up to 40%) when introduced into mobilized peripheral blood (mPB) CD34+ hematopoietic stem and progenitor cells (HSPCs) as ribonucleoprotein (RNP) complexes. HSPCs transfected with RNPs targeting either the BCL11A erythroid-enhancer or the HBG1/2 proximal regions were then injected into NBSGW mice to study the editing in SCID-repopulating cells (SRC) and their multilineage reconstitution potential. All groups achieved high levels of human chimerism (>70% hCD45+/hCD45+mCD45) and comparable monocytes, granulocytes, B lymphocytes, and hCD34+ HSPCs reconstitution. However, BCL11A-edited cells showed selective reduction in erythroid lineage (CD235a+) output, up to 4-fold lower than untreated or HBG1/2 promoter-edited HSPCs. Sequencing analysis from lineage-specific sorted cells further revealed reduced editing levels at BCL11A erythroid-specific enhancer in the erythroid compartment compared to unfractionated bone marrow (BM) or other human lineages (70% in erythroid vs. 90% in all other lineages). Furthermore, the nonproductive fraction of indels that did not disrupt the BCL11A GATAA motif was significantly enriched in erythroid cells (22% in erythroid vs. 8% in other lineages). Ex vivo erythroid cultures suggests BCL11A erythroid-enhancer editing may lead to slightly increased apoptosis during erythroid differentiation. In contrast, HBG1/2 promoter-edited cells had similar editing levels and indel patterns across all lineages with no significant lineage skewing. When chimeric BM from HBG1/2 promoter-edited groups were cultured in erythroid conditions, ex vivo-derived erythroid cells had significantly elevated levels of HbF compared to controls. When CD235a+ cells were sorted without further culture from chimeric BM of mice engrafted with HBG1/2 promoter-edited cells, significantly increased levels of HbF were detected by UPLC (up to 30%) compared to controls (~6%). Thus, long-term HSCs have been edited productively at the HBG1/2 promoters. These cells were able to generate erythroid progenitors that harbor HbF-inducing indels, which in turn, gave rise to erythroid cells in vivo with a clinically-relevant levels of HbF in a xenotransplantation model. Together, our data suggest that BCL11A-edited cells have an erythroid differentiation defect or survival disadvantage in NBSGW mouse model that warrants further investigation. In contrast, editing of the HBG1/2 promoters in mPB CD34+ cells achieved sustained HbF expression in erythroid lineage while maintaining multilineage differentiation potential. Targeting of the HBG1/2 promoters in HSPCs may be an attractive strategy for the development of potential gene editing medicines for beta hemoglobinopathies. Disclosures Chang: Editas Medicine Inc.: Employment, Equity Ownership. Sanchez:Editas Medicine Inc.: Employment, Equity Ownership. Heath:Editas Medicine Inc.: Employment, Equity Ownership. deDreuzy:Editas Medicine Inc.: Employment, Equity Ownership. Haskett:Editas Medicine Inc.: Employment, Equity Ownership. Vogelaar:Editas Medicine Inc.: Employment. Gogi:Editas Medicine Inc.: Employment, Equity Ownership. Da Silva:Editas Medicine Inc.: Employment, Equity Ownership. Wang:Editas Medicine Inc.: Employment, Equity Ownership. Sadowski:Editas Medicine Inc.: Employment, Equity Ownership. Gotta:Editas Medicine Inc.: Employment, Equity Ownership. Siwak:Editas Medicine Inc.: Employment, Equity Ownership. Viswanathan:Editas Medicine Inc.: Employment, Equity Ownership. Loveluck:Editas Medicine Inc.: Employment, Equity Ownership. Chao:Editas Medicine Inc.: Employment, Equity Ownership. Tillotson:Editas Medicine Inc.: Employment, Equity Ownership. Chalishazar:Editas Medicine Inc.: Employment, Equity Ownership. Dass:Editas Medicine Inc.: Employment, Equity Ownership. Ta:Editas Medicine Inc.: Employment, Equity Ownership. Brennan:Editas Medicine Inc.: Employment, Equity Ownership. Tabbaa:Editas Medicine Inc.: Employment, Equity Ownership. Marco:Editas Medicine Inc.: Employment, Equity Ownership. Zuris:Editas Medicine Inc.: Employment, Equity Ownership. Reyon:Editas Medicine Inc.: Employment, Equity Ownership. Isik:Editas Medicine Inc.: Employment, Equity Ownership. Friedland:Editas Medicine Inc.: Employment, Equity Ownership. Ta:Editas Medicine Inc.: Employment, Equity Ownership. Harbinski:Editas Medicine Inc.: Employment, Equity Ownership. Giannoukos:Editas Medicine Inc.: Employment, Equity Ownership. Teixeira:Editas Medicine Inc.: Employment, Equity Ownership. Wilson:Editas Medicine Inc.: Employment, Equity Ownership. Albright:Editas Medicine Inc.: Employment, Equity Ownership. Jiang:Editas Medicine Inc.: Employment, Equity Ownership.
DNA methylation and deprived of RNAP II. Importantly, silencing was sharply confined to the targeted gene and resistant to INF-γ, a potent natural activator of B2M. We further extended these studies by showing that our silencing approach is portable to the CRISPR/ dCas9 DNA binding technology. In this setting, comparable levels of B2M silencing (up to 80%) were achieved using either pools or even individual sgRNAs coupled to dCas9-based ATRs. Yet, adoption of this technology allowed performing simultaneous, highly efficient multiplex gene silencing within the same cell, as shown for B2M, IFNAR1 and VEGFA. Finally, we assessed resistance of the silenced gene to activity of potent artificial transcription activators and chromatin remodelers, and found that only targeted DNA demethylation was able to reawaken the silent gene. This allowed performing iterative cycles of silencing and reactivation of the same gene in the same cell population. Overall, these data provide the first demonstration of efficient and stable epigenetic silencing of endogenous genes upon transient delivery of ATRs. This was accomplished by repurposing the ERVs silencing machinery, which instructs self-sustaining repressive epigenetic states to the target gene. While silencing of B2M might be used to generate universally transplantable allogeneic cells, our hit-and-run strategy provides a powerful new alternative to conventional gene silencing for both basic and translational research.
Transplantation of gene-modified autologous hematopoietic stem/progenitor cells (HSPCs) is an effective treatment for several hematologic diseases. However, a number of blood disorders may not be amenable to gene augmentation-based therapeutics. Targeted genome editing in human HSPCs could provide a therapeutic approach for these otherwise untreatable diseases. Here we demonstrate that CRISPR/Cas9 ribonucleoprotein (RNP) edits target genes in human HSPCs with high efficiency and precision. Human adult and umbilical cord blood (CB) CD34+ cells from 20 donors were electroporated with S. pyogenes or S. aureus Cas9 RNP targeting HBB, AAVS1, or CXCR4. Sequence analysis demonstrated up to 80% editing in CB CD34+ cells (mean±s.d: 61%±9%) and up to 57% in adult CD34+ cells (39%±13%). Delivery of Cas9 RNP and a single-stranded oligodeoxynucleotide donor (ssODN) led to up to 12% ssODN-mediated homology directed repair (HDR) and also led to a 20% increase in total gene editing (HDR+NHEJ)(RNP: 48%±15%; RNP+ssODN: 69%±8%). Both Cas9 RNP gene-edited CD34+ cells and donor-matched untreated control CD34+ cells reconstituted human hematopoiesis in primary and secondary recipient immunodeficient mice, with ~85% human CD45+ cell peripheral blood reconstitution 4 months after primary transplantation. Human T and B lymphoid, erythroid, and myeloid cells were detected in the spleen, thymus, and bone marrow with 20% CD34+ cell engraftment in the marrow of mice transplanted with RNP gene-edited or control CD34+ cells. The level of targeted gene editing in human erythroid, myeloid, and CD34+ cells that were recovered and enriched from the hematopoietic organs of primary recipients (~50%) was similar to the level of gene editing detected in the pre-infusion product (~60%). In summary, these results indicate that Cas9 gene-edited human HSPCs retain long-term engraftment potential and support multilineage blood reconstitution in vivo, thus supporting further investigation of CRISPR/Cas9 mediated gene-edited hematopoietic stem/progenitor cell therapies. Disclosures Heath: Editas Medicine: Employment. Chalishazar:Editas Medicine: Employment. Lee:Editas Medicine: Employment. Selleck:Editas Medicine: Employment. Cotta-Ramusino:Editas Medicine: Employment. Bumcrot:Editas Medicine: Employment. Gori:Editas Medicine: Employment.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.