Potent CRISPR-Cas9 inhibitors from Staphylococcus genomes.

Anti-CRISPRs (Acrs) are small proteins that inhibit the RNA-guided DNA targeting activity of CRISPR-Cas enzymes. Encoded by bacteriophage and phage-derived bacterial genes, Acrs prevent CRISPR-mediated inhibition of phage infection and can also block CRISPR-Cas-mediated genome editing in eukaryotic cells. To identify Acrs capable of inhibiting Staphylococcus aureus Cas9 (SauCas9), an alternative to the most commonly used genome editing protein Streptococcus pyogenes Cas9 (SpyCas9), we used both self-targeting CRISPR screening and guilt-by-association genomic search strategies. Here we describe three potent inhibitors of SauCas9 that we name AcrIIA13, AcrIIA14, and AcrIIA15. These inhibitors share a conserved N-terminal sequence that is dispensable for DNA cleavage inhibition and have divergent C termini that are required in each case for inhibition of SauCas9-catalyzed DNA cleavage. In human cells, we observe robust inhibition of SauCas9-induced genome editing by AcrIIA13 and moderate inhibition by AcrIIA14 and AcrIIA15. We also find that the conserved N-terminal domain of AcrIIA13-AcrIIA15 binds to an inverted repeat sequence in the promoter of these Acr genes, consistent with its predicted helix-turn-helix DNA binding structure. These data demonstrate an effective strategy for Acr discovery and establish AcrIIA13-AcrIIA15 as unique bifunctional inhibitors of SauCas9

Extension of the crRNA enhances Cpf1 gene editing in vitro and in vivo.

Engineering of the Cpf1 crRNA has the potential to enhance its gene editing efficiency and non-viral delivery to cells. Here, we demonstrate that extending the length of its crRNA at the 5 end can enhance the gene editing efficiency of Cpf1 both in cells and in vivo. Extending the 5 end of the crRNA enhances the gene editing efficiency of the Cpf1 RNP to induce non-homologous end-joining and homology-directed repair using electroporation in cells. Additionally, chemical modifications on the extended 5 end of the crRNA result in enhanced serum stability. Also, extending the 5 end of the crRNA by 59 nucleotides increases the delivery efficiency of Cpf1 RNP in cells and in vivo cationic delivery vehicles including polymer nanoparticle. Thus, 5 extension and chemical modification of the Cpf1 crRNA is an effective method for enhancing the gene editing efficiency of Cpf1 and its delivery in vivo

Postural stability and handicap of dizziness after preoperative vestibular ablation and vestibular prehabilitation in patients undergoing vestibular schwannoma resection

BACKGROUND: Surgical treatment of vestibular schwannoma (VS) leads to acute ipsilateral vestibular loss if there is residual vestibular function before surgery. To overcome the sequelae of acute ipsilateral vestibular loss and to decrease postoperative recovery time, the concept of preemptive vestibular ablation with gentamicin and vestibular prehabilitation before surgery has been developed (“vestibular prehab”). OBJECTIVE: Studying postural stability during walking and handicap of dizziness over a 1-year follow-up period in VS patients undergoing vestibular prehab before surgical treatment of VS. METHODS: A retrospective review of consecutive patients with a diagnosis of a VS undergoing surgical therapy from June 2012 to March 2018 was performed. All patients were included with documentation of the length of hospital duration and the Dizziness Handicap Inventory (DHI) and the Functional Gait Assessment (FGA) assessed preoperatively as well as 6 weeks and 1 year postoperatively. RESULTS: A total 68 VS patients were included, of which 29 patients received preoperative vestibular ablation by intratympanic injection of gentamicin. Mean VS diameter was 20.2 mm (SD 9.4 mm) and mean age at surgery was 49.6 years (SD 11.5 years). Vestibular prehab had no effect on DHI and FGA at any time point studied. CONCLUSIONS: We found no effect of vestibular prehab on postural stability during walking and on the handicap of dizziness. These findings add to the body of knowledge consisting of conflicting results of vestibular prehab. Therefore, vestibular prehab should be applied only in selected cases in an experimental setting

GENE-43. TARGETING GABPb1L INHIBITS IN VIVO GROWTH OF TERT PROMOTER MUTANT GLIOBLASTOMA

Abstract Understanding cancer cell immortality in primary glioblastoma (GBM) is essential for the development of more informed treatments. Multiple cancer types, including >80% of GBMs, undergo immortalization by reactivating Telomerase Reverse Transcriptase (TERT) through acquired mutations in the TERT promoter. TERT, the catalytically active and rate-limiting subunit of telomerase, functions to maintain telomeres, which cap and protect the ends of chromosomes. Our past work has demonstrated that the transcription factor GABP - and specifically its tetramer-forming isoform GABPb1L - binds and activates the mutant TERT promoter. The generation of CRISPR-induced indels in GABPb1L results in a gradual loss of cell viability in TERT promoter mutant but not TERT promoter wild type tumor cells in vitro, but the extent to which GABPb1L function is compromised in this setting is unclear. Thus, the potential for use of GABPb1L as an effective therapeutic target for TERT promoter mutant GBM requires further investigation. Here, we use CRISPR-based strategies to demonstrate that full knockout of GABPb1L is rapidly lethal in TERT promoter mutant cells in vitro, in association with a decrease in both TERT mRNA and telomerase activity. Heterozygous deletion of GABPb1L in the context of TERT promoter mutations leads to slowed growth of orthotopic xenograft tumors in mice, and prolonged survival. Additionally, inducible RNAi-mediated inhibition of GABPb1L in growing tumors is also capable of decreasing tumor burden and increasing survival, further strongly suggesting that targeting GABPb1L in patient tumors could be a viable treatment strategy. Finally, reduced GABPb1L synergizes with temozolomide (TMZ) therapy such that TMZ treatment in the context of low GABPb1L and low TERT leads to a complete ablation of orthotopic GBM xenografts. These results highlight the potential to improve disease outcomes by targeting TERT through inhibition of GABPb1L, particularly in conjunction with TMZ treatment

GENE-43. TARGETING GABPb1L INHIBITS IN VIVO GROWTH OF TERT PROMOTER MUTANT GLIOBLASTOMA

Abstract Understanding cancer cell immortality in primary glioblastoma (GBM) is essential for the development of more informed treatments. Multiple cancer types, including >80% of GBMs, undergo immortalization by reactivating Telomerase Reverse Transcriptase (TERT) through acquired mutations in the TERT promoter. TERT, the catalytically active and rate-limiting subunit of telomerase, functions to maintain telomeres, which cap and protect the ends of chromosomes. Our past work has demonstrated that the transcription factor GABP - and specifically its tetramer-forming isoform GABPb1L - binds and activates the mutant TERT promoter. The generation of CRISPR-induced indels in GABPb1L results in a gradual loss of cell viability in TERT promoter mutant but not TERT promoter wild type tumor cells in vitro, but the extent to which GABPb1L function is compromised in this setting is unclear. Thus, the potential for use of GABPb1L as an effective therapeutic target for TERT promoter mutant GBM requires further investigation. Here, we use CRISPR-based strategies to demonstrate that full knockout of GABPb1L is rapidly lethal in TERT promoter mutant cells in vitro, in association with a decrease in both TERT mRNA and telomerase activity. Heterozygous deletion of GABPb1L in the context of TERT promoter mutations leads to slowed growth of orthotopic xenograft tumors in mice, and prolonged survival. Additionally, inducible RNAi-mediated inhibition of GABPb1L in growing tumors is also capable of decreasing tumor burden and increasing survival, further strongly suggesting that targeting GABPb1L in patient tumors could be a viable treatment strategy. Finally, reduced GABPb1L synergizes with temozolomide (TMZ) therapy such that TMZ treatment in the context of low GABPb1L and low TERT leads to a complete ablation of orthotopic GBM xenografts. These results highlight the potential to improve disease outcomes by targeting TERT through inhibition of GABPb1L, particularly in conjunction with TMZ treatment

Disruption of the β1L Isoform of GABP Reverses Glioblastoma Replicative Immortality in a TERT Promoter Mutation-Dependent Manner

TERT promoter mutations reactivate telomerase, allowing for indefinite telomere maintenance and enabling cellular immortalization. These mutations specifically recruit the multimeric ETS factor GABP, which can form two functionally independent transcription factor species: a dimer or a tetramer. We show that genetic disruption of GABPβ1L (β1L), a tetramer-forming isoform of GABP that is dispensable for normal development, results in TERT silencing in a TERT promoter mutation-dependent manner. Reducing TERT expression by disrupting β1L culminates in telomere loss and cell death exclusively in TERT promoter mutant cells. Orthotopic xenografting of β1L-reduced, TERT promoter mutant glioblastoma cells rendered lower tumor burden and longer overall survival in mice. These results highlight the critical role of GABPβ1L in enabling immortality in TERT promoter mutant glioblastoma.This work was supported by a generous gift from the Dabbiere family (J.F.C.), the Hana Jabsheh Research Initiative (J.F.C.), NIH grant NCI P50CA097257 (J.F.C. and J.A.D.), NCI P01CA118816-06 (J.F.C.), T32 GM008568 and T32 CA151022 (A.M.), and NCI R01CA163336 (J.S.S.), and the Sontag Foundation Distinguished Scientist Award (J.S.S.). C.F. is supported by a US NIH K99/R00 Pathway to Independence Award (K99GM118909) from the National Institute of General Medical Sciences. Additional support was provided by Fundação para a Ciência e Tecnologia SFRH/BD/88220/2012 (A.X.-M.) and IF/00601/2012 (B.M.C.). J.A.D. is an investigator of the Howard Hughes Medical Institute.info:eu-repo/semantics/publishedVersio

Cornerstones of CRISPR-Cas in drug discovery and therapy.

The recent development of CRISPR-Cas systems as easily accessible and programmable tools for genome editing and regulation is spurring a revolution in biology. Paired with the rapid expansion of reference and personalized genomic sequence information, technologies based on CRISPR-Cas are enabling nearly unlimited genetic manipulation, even in previously difficult contexts, including human cells. Although much attention has focused on the potential of CRISPR-Cas to cure Mendelian diseases, the technology also holds promise to transform the development of therapies to treat complex heritable and somatic disorders. In this Review, we discuss how CRISPR-Cas can affect the next generation of drugs by accelerating the identification and validation of high-value targets, uncovering high-confidence biomarkers and developing differentiated breakthrough therapies. We focus on the promises, pitfalls and hurdles of this revolutionary gene-editing technology, discuss key aspects of different CRISPR-Cas screening platforms and offer our perspectives on the best practices in genome engineering

Systematic discovery of natural CRISPR-Cas12a inhibitors

Cas12a (Cpf1) is a CRISPR-associated nuclease with broad utility for synthetic genome engineering, agricultural genomics, and biomedical applications. Although bacteria harboring CRISPR-Cas9 or CRISPR-Cas3 adaptive immune systems sometimes acquire mobile genetic elements encoding anti-CRISPR proteins that inhibit Cas9, Cas3, or the DNA-binding Cascade complex, no such inhibitors have been found for CRISPR-Cas12a. Here we use a comprehensive bioinformatic and experimental screening approach to identify three different inhibitors that block or diminish CRISPR-Cas12a-mediated genome editing in human cells. We also find a widespread connection between CRISPR self-targeting and inhibitor prevalence in prokaryotic genomes, suggesting a straightforward path to the discovery of many more anti-CRISPRs from the microbial world

Potent CRISPR-Cas9 inhibitors from Staphylococcus genomes.

Anti-CRISPRs (Acrs) are small proteins that inhibit the RNA-guided DNA targeting activity of CRISPR-Cas enzymes. Encoded by bacteriophage and phage-derived bacterial genes, Acrs prevent CRISPR-mediated inhibition of phage infection and can also block CRISPR-Cas-mediated genome editing in eukaryotic cells. To identify Acrs capable of inhibiting Staphylococcus aureus Cas9 (SauCas9), an alternative to the most commonly used genome editing protein Streptococcus pyogenes Cas9 (SpyCas9), we used both self-targeting CRISPR screening and guilt-by-association genomic search strategies. Here we describe three potent inhibitors of SauCas9 that we name AcrIIA13, AcrIIA14, and AcrIIA15. These inhibitors share a conserved N-terminal sequence that is dispensable for DNA cleavage inhibition and have divergent C termini that are required in each case for inhibition of SauCas9-catalyzed DNA cleavage. In human cells, we observe robust inhibition of SauCas9-induced genome editing by AcrIIA13 and moderate inhibition by AcrIIA14 and AcrIIA15. We also find that the conserved N-terminal domain of AcrIIA13-AcrIIA15 binds to an inverted repeat sequence in the promoter of these Acr genes, consistent with its predicted helix-turn-helix DNA binding structure. These data demonstrate an effective strategy for Acr discovery and establish AcrIIA13-AcrIIA15 as unique bifunctional inhibitors of SauCas9