Project description:The CRISPR-Cas9 system is a powerful and revolutionary genome-editing tool for eukaryotic genomes, but its use in bacterial genomes is very limited. Here, we investigated the use of the Streptococcus pyogenes CRISPR-Cas9 system in editing the genome of Clostridium cellulolyticum, a model microorganism for bioenergy research. Wild-type Cas9-induced double-strand breaks were lethal to C. cellulolyticum due to the minimal expression of nonhomologous end joining (NHEJ) components in this strain. To circumvent this lethality, Cas9 nickase was applied to develop a single-nick-triggered homologous recombination strategy, which allows precise one-step editing at intended genomic loci by transforming a single vector. This strategy has a high editing efficiency (>95%) even using short homologous arms (0.2 kb), is able to deliver foreign genes into the genome in a single step without a marker, enables precise editing even at two very similar target sites differing by two bases preceding the seed region, and has a very high target site density (median interval distance of 9 bp and 95.7% gene coverage in C. cellulolyticum). Together, these results establish a simple and robust methodology for genome editing in NHEJ-ineffective prokaryotes.

Project description:The RNA-guided Cas9 nuclease is being widely employed to engineer the genomes of various cells and organisms. Despite the efficient mutagenesis induced by Cas9, off-target effects have raised concerns over the system's specificity. Recently a "double-nicking" strategy using catalytic mutant Cas9(D10A) nickase has been developed to minimise off-target effects. Here, we describe a Cas9(D10A)-based screening approach that combines an All-in-One Cas9(D10A) nickase vector with fluorescence-activated cell sorting enrichment followed by high-throughput genotypic and phenotypic clonal screening strategies to generate isogenic knockouts and knock-ins highly efficiently, with minimal off-target effects. We validated this approach by targeting genes for the DNA-damage response (DDR) proteins MDC1, 53BP1, RIF1 and P53, plus the nuclear architecture proteins Lamin A/C, in three different human cell lines. We also efficiently obtained biallelic knock-in clones, using single-stranded oligodeoxynucleotides as homologous templates, for insertion of an EcoRI recognition site at the RIF1 locus and introduction of a point mutation at the histone H2AFX locus to abolish assembly of DDR factors at sites of DNA double-strand breaks. This versatile screening approach should facilitate research aimed at defining gene functions, modelling of cancers and other diseases underpinned by genetic factors, and exploring new therapeutic opportunities.

Project description:Mutations in the metabolic enzyme fumarylacetoacetate hydrolase (FAH) cause hereditary tyrosinemia type I (HT1) in human. HT1 patients present acute and irreversible liver and kidney damage during infancy. CRISPR/Cas9-medated precise correction of disease-causing mutations in the liver of infant may provide a promising approach for the treatment of monogenetic liver metabolic disorders. However, to date, all previous precise gene therapy studies were conducted in adult HT1 rodent models (mice and rats), which are not able to recover irreversible pathological changes and result in less treatment effectiveness. In addition, rodent animals have very tiny livers comparing with that of humans, and HT1 rodent models do not authentically recapitulate some symptoms of human patients such as kidney damage. Therefore, to achieve the data which could be more translationable to medical practice of HT1 disease treatment by correcting gene mutation of hepatocytes, here, we chose a HT1 rabbit model, owning relatively large livers, and displaying liver and kidney damage as human patients, as the subject to test the gene therapy effectiveness starting from newborn stage. By delivery CRISPR/Cas9 system and donor templates to the livers by ear vein injection of adeno-associated virus (AAV), HT1 rabbits could be rescued the lethal phenotypes and were able to grow up to adult normally without NTBC treatment and give birth to offspring. In the livers of AAV-treated HT1 rabbits, both HDR-mediated and NHEJ-mediated gene corrections were occurred with the efficiencies ranged from 3.30% to 8.58%. Gene corrected HT1 rabbits showed normal structure and function of both livers and kidneys. This study in rabbits provides useful large-animal preclinical data to treat genetic metabolic disorders affecting the liver with gene therapy.

Project description:Bacillus strains are important industrial bacteria that can produce various biochemical products. However, low transformation efficiencies and a lack of effective genome editing tools have hindered its widespread application. Recently, clustered regularly interspaced short palindromic repeat (CRISPR)-Cas9 techniques have been utilized in many organisms as genome editing tools because of their high efficiency and easy manipulation. In this study, an efficient genome editing method was developed for Bacillus licheniformis using a CRISPR-Cas9 nickase integrated into the genome of B. licheniformis DW2 with overexpression driven by the P43 promoter. The yvmC gene was deleted using the CRISPR-Cas9n technique with homology arms of 1.0 kb as a representative example, and an efficiency of 100% was achieved. In addition, two genes were simultaneously disrupted with an efficiency of 11.6%, and the large DNA fragment bacABC (42.7 kb) was deleted with an efficiency of 79.0%. Furthermore, the heterologous reporter gene aprN, which codes for nattokinase in Bacillus subtilis, was inserted into the chromosome of B. licheniformis with an efficiency of 76.5%. The activity of nattokinase in the DWc9n?7/pP43SNT-SsacC strain reached 59.7 fibrinolytic units (FU)/ml, which was 25.7% higher than that of DWc9n/pP43SNT-SsacC Finally, the engineered strain DWc9n?7 (?epr ?wprA ?mpr ?aprE ?vpr ?bprA ?bacABC), with multiple disrupted genes, was constructed using the CRISPR-Cas9n technique. Taken together, we have developed an efficient genome editing tool based on CRISPR-Cas9n in B. licheniformis This tool could be applied to strain improvement for future research.IMPORTANCE As important industrial bacteria, Bacillus strains have attracted significant attention due to their production of biological products. However, genetic manipulation of these bacteria is difficult. The CRISPR-Cas9 system has been applied to genome editing in some bacteria, and CRISPR-Cas9n was proven to be an efficient and precise tool in previous reports. The significance of our research is the development of an efficient, more precise, and systematic genome editing method for single-gene deletion, multiple-gene disruption, large DNA fragment deletion, and single-gene integration in Bacillus licheniformis via Cas9 nickase. We also applied this method to the genetic engineering of the host strain for protein expression.

Project description:Germline manipulation using CRISPR/Cas9 genome editing has dramatically accelerated the generation of new mouse models. Nonetheless, many metabolic disease models still depend upon laborious germline targeting, and are further complicated by the need to avoid developmental phenotypes. We sought to address these experimental limitations by generating somatic mutations in the adult liver using CRISPR/Cas9, as a new strategy to model metabolic disorders. As proof-of-principle, we targeted the low-density lipoprotein receptor (Ldlr), which when deleted, leads to severe hypercholesterolemia and atherosclerosis. Here we show that hepatic disruption of Ldlr with AAV-CRISPR results in severe hypercholesterolemia and atherosclerosis. We further demonstrate that co-disruption of Apob, whose germline loss is embryonically lethal, completely prevented disease through compensatory inhibition of hepatic LDL production. This new concept of metabolic disease modeling by somatic genome editing could be applied to many other systemic as well as liver-restricted disorders which are difficult to study by germline manipulation.

Project description:PRKAG2 cardiac syndrome is an autosomal dominant inherited disease resulted from mutations in the PRKAG2 gene that encodes ?2 regulatory subunit of AMP-activated protein kinase. Affected patients usually develop ventricular tachyarrhythmia and experience progressive heart failure that is refractory to medical treatment and requires cardiac transplantation. In this study, we identify a H530R mutation in PRKAG2 from patients with familial Wolff-Parkinson-White syndrome. By generating H530R PRKAG2 transgenic and knock-in mice, we show that both models recapitulate human symptoms including cardiac hypertrophy and glycogen storage, confirming that the H530R mutation is causally related to PRKAG2 cardiac syndrome. We further combine adeno-associated virus-9 (AAV9) and the CRISPR/Cas9 gene-editing system to disrupt the mutant PRKAG2 allele encoding H530R while leaving the wild-type allele intact. A single systemic injection of AAV9-Cas9/sgRNA at postnatal day 4 or day 42 substantially restores the morphology and function of the heart in H530R PRKAG2 transgenic and knock-in mice. Together, our work suggests that in vivo CRISPR/Cas9 genome editing is an effective tool in the treatment of PRKAG2 cardiac syndrome and other dominant inherited cardiac diseases by selectively disrupting disease-causing mutations.

Project description:Mutations in the metabolic enzyme fumarylacetoacetate hydrolase (FAH) cause hereditary tyrosinemia type I (HT1) in human. HT1 patients present acute and irreversible liver and kidney damage during infancy. CRISPR/Cas9-medated precise correction of disease-causing mutations in the liver of infant may provide a promising approach for the treatment of monogenetic liver metabolic disorders. However, to date, all previous precise gene therapy studies were conducted in adult HT1 rodent models (mice and rats), which are not able to recover irreversible pathological changes and result in less treatment effectiveness. In addition, rodent animals have very tiny livers comparing with that of humans, and HT1 rodent models do not authentically recapitulate some symptoms of human patients such as kidney damage. Therefore, to achieve the data which could be more translationable to medical practice of HT1 disease treatment by correcting gene mutation of hepatocytes, here, we chose a HT1 rabbit model, owning relatively large livers, and displaying liver and kidney damage as human patients, as the subject to test the gene therapy effectiveness starting from newborn stage. By delivery CRISPR/Cas9 system and donor templates to the livers by ear vein injection of adeno-associated virus (AAV), HT1 rabbits could be rescued the lethal phenotypes and were able to grow up to adult normally without NTBC treatment and give birth to offspring. In the livers of AAV-treated HT1 rabbits, both HDR-mediated and NHEJ-mediated gene corrections were occurred with the efficiencies ranged from 3.30% to 8.58%. Gene corrected HT1 rabbits showed normal structure and function of both livers and kidneys. This study in rabbits provides useful large-animal preclinical data to treat genetic metabolic disorders affecting the liver with gene therapy.

Project description:Mutations in the metabolic enzyme fumarylacetoacetate hydrolase (FAH) cause hereditary tyrosinemia type I (HT1) in human. HT1 patients present acute and irreversible liver and kidney damage during infancy. CRISPR/Cas9-medated precise correction of disease-causing mutations in the liver of infant may provide a promising approach for the treatment of monogenetic liver metabolic disorders. However, to date, all previous precise gene therapy studies were conducted in adult HT1 rodent models (mice and rats), which are not able to recover irreversible pathological changes and result in less treatment effectiveness. In addition, rodent animals have very tiny livers comparing with that of humans, and HT1 rodent models do not authentically recapitulate some symptoms of human patients such as kidney damage. Therefore, to achieve the data which could be more translationable to medical practice of HT1 disease treatment by correcting gene mutation of hepatocytes, here, we chose a HT1 rabbit model, owning relatively large livers, and displaying liver and kidney damage as human patients, as the subject to test the gene therapy effectiveness starting from newborn stage. By delivery CRISPR/Cas9 system and donor templates to the livers by ear vein injection of adeno-associated virus (AAV), HT1 rabbits could be rescued the lethal phenotypes and were able to grow up to adult normally without NTBC treatment and give birth to offspring. In the livers of AAV-treated HT1 rabbits, both HDR-mediated and NHEJ-mediated gene corrections were occurred with the efficiencies ranged from 3.30% to 8.58%. Gene corrected HT1 rabbits showed normal structure and function of both livers and kidneys. This study in rabbits provides useful large-animal preclinical data to treat genetic metabolic disorders affecting the liver with gene therapy.

Project description:We demonstrate CRISPR-Cas9-mediated correction of a Fah mutation in hepatocytes in a mouse model of the human disease hereditary tyrosinemia. Delivery of components of the CRISPR-Cas9 system by hydrodynamic injection resulted in initial expression of the wild-type Fah protein in ?1/250 liver cells. Expansion of Fah-positive hepatocytes rescued the body weight loss phenotype. Our study indicates that CRISPR-Cas9-mediated genome editing is possible in adult animals and has potential for correction of human genetic diseases.

Project description:Adeno-associated virus (AAV) vectors are ideal for performing gene repair due to their ability to target multiple different genomic loci, low immunogenicity, capability to achieve targeted and stable expression through integration, and low mutagenic and oncogenic potential. However, many handicaps to gene repair therapy remain. Most notable is the low frequency of correction in vivo. To date, this frequency is too low to be of therapeutic value for any disease. To address this, a point-mutation-based mouse model of the metabolic disease hereditary tyrosinemia type I was used to test whether targeted AAV integration by homologous recombination could achieve high-level stable gene repair in vivo. Both neonatal and adult mice were treated with AAV serotypes 2 and 8 carrying a wild-type genomic sequence for repairing the mutated Fah (fumarylacetoacetate hydrolase) gene. Hepatic gene repair was quantified by immunohistochemistry and supported with reverse transcription polymerase chain reaction and serology for functional correction parameters. Successful gene repair was observed with both serotypes but was more efficient with AAV8. Correction frequencies of up to 10(-3) were achieved and highly reproducible within typical dose ranges. In this model, repaired hepatocytes have a selective growth advantage and are thus able to proliferate to efficiently repopulate mutant livers and cure the underlying metabolic disease.AAV-mediated gene repair is feasible in vivo and can functionally correct an appropriate selection-based metabolic liver disease in both adults and neonates.