Project description:Efficient genome editing in erythroid cells unveils novel MYB target genes and regulatory functions

Project description:CRISPR-Cas9 has tremendous potential as a therapeutic tool for treating human diseases. However, prolonged expression of the nuclease and gRNA from viral vectors in an in vivo context may cause off-target activity and immunogenicity. While extracellular vesicles have been recently demonstrated to be a promising option to transiently deliver the CRISPR-system, sufficient packaging of both Cas9 protein and gRNA is critical to achieve efficient genome editing in hard-to-transfect cells and tissues, such as skeletal muscle. Here, we developed a novel ribonucleoprotein delivery system utilizing two distinct homing mechanisms. The first is by chemical induced dimerization to recruit Cas9 protein into extracellular nanovesicles. The second utilizes a viral RNA packaging signal and two self-cleaving riboswitches to tether and release sgRNA into nanovesicles. We term our fully engineered delivery system NanoMEDIC (nanomembrane-derived extracellular vesicles for the delivery of macromolecular cargo) and demonstrate efficient genome editing in various hard-to-transfect cell types, including human iPS cells and myoblasts. Furthermore, NanoMEDIC production is scalable for industrial production as a xeno-free suspension culture system. As a disease model, therapeutic exon skipping in the dystrophin gene locus was targeted and resulted in over 90% exon skipping efficiencies in skeletal muscle cells derived from Duchenne muscular dystrophy patient iPS cells. Finally, we generated novel luciferase-based reporter mice to demonstrate that NanoMEDIC could induce exon skipping and sustain skipping activity for over 160 days, even though NanoMEDIC itself was rapidly degraded within 3 days, indicating its utility for transient in vivo genome editing therapy of DMD and beyond.

Project description:β-thalassemia cell lines were generated via CRISPR-Cas9 genome editing of Bristol Erythroid Line Adult (BEL-A) and differentiated to the basophilic and polychromatic erythroid cell stage. TMT comparative proteomics was then performed on stage matched WT and β-thalassemia cells isolated by FACS.

Project description:Genetic studies have identified common variants within the HBS1L-MYB intergenic region on chromosome 6q associated with elevated fetal hemoglobin (HbF) levels and other clinically important human erythroid traits. The mechanism by which the non-coding sequence variants affect these traits is still not clear. Here we report that several of the variants affect regulatory elements that are occupied by key erythroid transcription factors within this region. These elements interact with MYB, a critical regulator of erythroid development and HbF levels. We show that several of the variants reduce transcription factor binding, affecting long-range interactions with MYB, and MYB expression levels. We provide here a functional explanation for the genetic association of HBS1L-MYB intergenic polymorphisms with human erythroid traits and HbF levels. Our results further designate MYB as a bona fide target for therapeutic induction of HbF to ameliorate sickle cell and β-thalassemia disease severity.

Project description:Purpose: RNA editing by ADAR1 is essential for hematopoietic development. The goals of this study were firstly, to identify ADAR1-specific RNA-editing sites by indentifying A-to-I (G) RNA editing sites in wild type mice that were not edited or reduced in editing frequency in ADAR1 deficient murine erythroid cells. Secondly, to determine the transcription consequence of an absence of ADAR1-mediated A-to-I editing. Methods: Total RNA from E14.5 fetal liver of embryos with an erythroid restricted deletion of ADAR1 (KO) and littermate controls (WT), in duplicate. cDNA libraries were prepared and RNA sequenced using Illumina HiSeq2000. The sequence reads that passed quality filters were analyzed at the transcript level with TopHat followed by Cufflinks. qRT–PCR validation was performed using SYBR Green assays. A-to-I (G) RNA editing sites were identified as previously described by Ramaswami G. et al., Nature Methods, 2012 using Burrows–Wheeler Aligner (BWA) followed by ANOVA (ANOVA). RNA editing sites were confirmed by Sanger sequencing. Results: Using an optimized data analysis workflow, we mapped about 30 million sequence reads per sample to the mouse genome (build mm9) and identified 14,484 transcripts in the fetal livers of WT and ADAR1E861A mice with BWA. RNA-seq data had a goodness of fit (R2) of >0.7, p<0.0001 between biological duplicates per genotype. Clusters of hyper-editing were onserved in long, unannotated 3'UTRs of erythroid specific transcripts. A profound upregulation of interferon stimulated genes were found to be massively upregulated (up to 5 log2FC) in KO fetal liver compared to WT. 11.332 (6,894 novel) A-to-I RNA editing sites were identified when assessing mismatches in RNA-seq data. Conclusions: Our study represents the first detailed analysis of erythroid transcriptomes and A-to-I RNA editing sites, with biologic replicates, generated by RNA-seq technology. A-to-I RNA editing is the essential function of ADAR1 and is required to prevent sensing of endogenous transcripts, likely via a RIG-I like receptor mediated axis. Fetal liver mRNA profiles of E14.5 wild type (WT) and ADAR Epor-Cre knock out mice were generated by deep sequencing, in duplicate using Illumina HiSeq 2000.

Project description:<p> <ol> <li>Implement an efficient, highly reproducible and &#39;scalable&#39; system for the production of large numbers of sickle cell anemia-specific iPS cells (iPSC).</li> <li>Derive and characterize a novel, in vitro system for the production of an unlimited supply of erythroid lineage cells from the directed differentiation of &#39;clinical grade&#39; transgene-free iPS cells; use this system to recapitulate erythroid-lineage ontogeny in vitro with the sequential development of primitive and definitive erythropoiesis, accompanied by the appropriate expression of stage-specific globin genes.</li> <li>Identify developmental gene expression profile differences between erythroid precursors that produce primarily HbF and those that produce primarily HbA or HbS.</li> <li>Determine the effects of the three known HbF major quantitative trait loci (QTL) on globin gene expression in disease-specific iPS cells during in vitro erythropoiesis.</li> <li>Search for novel HbF genetic modifiers associated with markedly elevated HbF levels found in sickle cell anemia patients naturally, or in response to hydroxyurea treatment, by examining gene expression profiles and mRNA sequence of their iPSC-derived erythroid cells.</li> <li>Develop and use a CRISPR-based gene editing platform to study the effect of novel HbF genetic modifiers, explore globin switching, and correct the HbS mutation in sickle iPSC lines.</li> </ol> </p>

Project description:The use of CRISPR/Cas proteins for the creation of multiplex genome-engineering represents an important avenue for crop improvement, and further improvements for creation of knock-in plant lines via CRISPR-based technologies may enable the high-throughput creation of designer alleles. To circumvent limitations of the commonly used CRISPR/Cas9 system for multiplex genome-engineering, we explored the use of Moraxella bovoculi 3 Cas12a (Mb3Cas12a) for multiplex genome-editing in Arabidopsis thaliana. We identified optimized promoter sequences for driving expression of single transcript multiplex crRNA arrays in A. thaliana, resulting in stable germline transmission of Mb3Cas12a-edited alleles at multiple target sites. By utilizing this system, we demonstrate single-transcript multiplexed genome-engineering using of up to 13 crRNA targets. We further show high target specificity of Mb3Cas12a-based genome-editing via whole-genome sequencing. Taken together, our method provides a simplified platform for efficient multiplex-genome-engineering in plant-based systems.

Project description:CRISPRs and TALENs are efficient systems for gene editing in many organisms including plants. In many cases the CRISPR-Cas or TALEN modules are expressed in the plant cell only transiently. Theoretically, transient expression of the editing modules should limit unexpected effects compared to stable transformation. However, very few studies have measured the off-target and unpredicted effects of editing strategies on the plant genome, and none of them have compared these two major editing systems. We conducted a comprehensive genome-wide investigation of off-target mutations using either a CRISPR-Cas9 or a TALEN strategy. We observed a similar number of SNVs and InDels for the two editing strategies compared to control non-transfected plants, with an average of 8.25 SNVs and 19.5 InDels for the CRISPR-edited plants, and an average of 17.5 SNVs and 32 InDels for the TALEN-edited plants. Interestingly, a comparable number of SNVs and InDels could be detected in the PEG-treated control plants. This shows that except for the on-target modifications, the gene editing tools used in this study did not show a significant off-target activity nor unpredicted effects on the genome, and that the PEG treatment in itself was probably the main source of mutations found in the edited plants.

Project description:Prime editing is a novel genome editing technology using fusion proteins of Cas9-nickase and reverse transcriptase, that holds promise to correct a wide variety of genetic defects. We succeeded in efficient prime editing and functional recovery of disease-causing mutations in patient-derived liver and intestinal stem cell organoids. Whole genome sequencing of did not detect off-target mutations or a mutational signature induced by prime editing.

Project description:CRISPR/Cas9 has proven to be an efficient tool for gene editing both in vitro and in vivo. The aim of this study is to evaluate editing efficiency of various genes targted in Rosa26-Cas9 knock-in mice.