Project description:The CRISPR-Cas universe continues to expand. The type II CRISPR-Cas system from Streptococcus pyogenes (SpyCas9) is most widely used for genome editing due to its high efficiency in cells and organisms. However, concentrating on a single CRISPR-Cas system imposes limits on target selection and multiplexed genome engineering. We hypothesized that CRISPR-Cas systems originating from different bacterial species could operate simultaneously and independently due to their distinct single-guide RNAs (sgRNAs) or CRISPR-RNAs (crRNAs), and protospacer adjacent motifs (PAMs). Additionally, we hypothesized that CRISPR-Cas activity in zebrafish could be regulated through the expression of inhibitory anti-CRISPR (Acr) proteins. Here, we use a simple mutagenesis approach to demonstrate that CRISPR-Cas systems from Streptococcus pyogenes (SpyCas9), Streptococcus aureus (SauCas9), Lachnospiraceae bacterium (LbaCas12a, previously known as LbCpf1), Acidaminococcus sp. (AspCas12a, previously known as AsCpf1) and Neisseria meningitidis (Nme2Cas9) are orthogonal systems capable of operating simultaneously in zebrafish. We implemented multichannel CRISPR recording using up to three CRISPR systems, and show that LbaCas12a may provide superior information density compared to previous methods. We also demonstrate that type II Acrs (anti-CRISPRs) are effective inhibitors of SpyCas9 in zebrafish. These results indicate that at least five CRISPR-Cas systems and two anti-CRISPR proteins are functional in zebrafish embryos. These orthogonal CRISPR-Cas systems and Acr proteins will enable combinatorial and intersectional strategies for spatiotemporal control of genome editing and genetic recording in animals.

Project description:Compact and versatile CRISPR-Cas systems will enable genome engineering applications through high-efficiency delivery in a wide variety of contexts. Here we create an efficient miniature Cas system (CasMINI) engineered from the type V-F Cas12f (Cas14) system by guide RNA and protein engineering, which is less than half the size of currently used CRISPR systems (Cas9 or Cas12a). We demonstrate that CasMINI can drive high levels of gene activation (up to thousands-fold increases), while the natural Cas12f system fails to function in mammalian cells. We show that the CasMINI system has comparable activities to Cas12a for gene activation, is highly specific, and allows for robust base editing and gene editing. We expect that CasMINI can be broadly useful for cell engineering and gene therapy applications ex vivo and in vivo.

Project description:Simple and efficient delivery of CRISPR genome editing systems in primary cells remains a major challenge. Here, we describe an engineered Peptide-Assisted Genome Editing (PAGE) CRISPR-Cas system for rapid and robust editing of primary cells. PAGE couples a cell-penetrating Cas protein with a cell-penetrating endosomal escape peptide in a 30-minute incubation that yields up to ~98% editing efficiency in primary human and mouse T cells. PAGE provides a broadly generalizable platform for next generation genome engineering in primary cells. CITATION INFORMATION: Zhang Zhen, Baxter Amy E, Ren Diqiu, Qin Kunhua, Chen Zeyu, Collins Sierra M., Huang Hua, Komar Chad A., Bailer Peter F., Parker Jared B., Blobel Gerd A., Kohli Rahul M., Wherry E. John*, Berger Shelley,*, and Shi Junwei*. Peptide-assisted genome editing permits efficient CRISPR engineering of primary T cells.

Project description:The type V-I CRISPR-Cas system is becoming increasingly attractive for its potential utility in gene editing. However, natural nucleases often exhibit low efficiency, limiting their application. Here, we utilized structure-guided rational design and combinatorial protein engineering to optimize an uncharacterized Cas12i nuclease, Cas12i3. Accordingly, we developed Cas-SF01, a Cas12i3 variant that exhibits significantly improved gene-editing activity in mammalian cells and plants. Cas-SF01 displays comparable or superior editing performance compared to SpCas9 or recently engineered Cas12 nucleases. Further analysis of PAM recognition showed that Cas-SF01 has an expanded PAM range and effectively recognizes NTTN and noncanonical NATN and TTVN PAMs. Additionally, we identified an amino acid substitution, D876R, that markedly reduced the off-target effect while maintaining high on-target activity, leading to the development of Cas-SF01HiFi (high-fidelity Cas-SF01). Finally, we demonstrated that Cas-SF01 has robust gene-editing activity in both the monocot plant rice and dicot plant pepper. Our results suggest that Cas-SF01 can serve as a robust gene-editing platform with high efficiency and specificity for future genome editing applications across different organisms.

Project description:Transient elimination of RNAs by CRISPR-Cas13 systems has been widely used in basic and applied sciences over the last years. However, the efficiency of the system can be enhanced in vivo, and its application has generated controversy due to the recently described collateral activity in mammalian cells and mouse models. Here, we have optimized the CRISPR-RfxCas13d (CasRx) system for an optimized RNA targeting in vivo in zebrafish embryos, by different and compatible approaches. These strategies include the use of chemically modified guide RNAs to increase and sustain mRNA knockdown, an improved nuclear targeting, and the evaluation of ex vivo computational models for predicting gRNA efficiency in vivo. Furthermore, our study demonstrated that transient CRISPR-RfxCas13d approaches can effectively deplete endogenous mRNAs in zebrafish embryos without inducing collateral effects, except for targeting extremely abundant RNAs. For that, we have implemented alternative RNA-targeting CRISPR-Cas systems with reduced or absent collateral activity in zebrafish embryos. Altogether, these findings contribute to optimize CRISPR-Cas technology for RNA targeting in zebrafish through transient approaches and assist the progress of potential implications for knockdown therapies in vivo.

Project description:Transient elimination of RNAs by CRISPR-Cas13 systems has been widely used in basic and applied sciences over the last years. However, the efficiency of the system can be enhanced in vivo, and its application has generated controversy due to the recently described collateral activity in mammalian cells and mouse models. Here, we have optimized the CRISPR-RfxCas13d (CasRx) system for an optimized RNA targeting in vivo in zebrafish embryos, by different and compatible approaches. These strategies include the use of chemically modified guide RNAs to increase and sustain mRNA knockdown, an improved nuclear targeting, and the evaluation of ex vivo computational models for predicting gRNA efficiency in vivo. Furthermore, our study demonstrated that transient CRISPR-RfxCas13d approaches can effectively deplete endogenous mRNAs in zebrafish embryos without inducing collateral effects, except for targeting extremely abundant RNAs. For that, we have implemented alternative RNA-targeting CRISPR-Cas systems with reduced or absent collateral activity in zebrafish embryos. Altogether, these findings contribute to optimize CRISPR-Cas technology for RNA targeting in zebrafish through transient approaches and assist the progress of potential implications for knockdown therapies in vivo.

Project description:Transient elimination of RNAs by CRISPR-Cas13 systems has been widely used in basic and applied sciences over the last years. However, the efficiency of the system can be enhanced in vivo, and its application has generated controversy due to the recently described collateral activity in mammalian cells and mouse models. Here, we have optimized the CRISPR-RfxCas13d (CasRx) system for an optimized RNA targeting in vivo in zebrafish embryos, by different and compatible approaches. These strategies include the use of chemically modified guide RNAs to increase and sustain mRNA knockdown, an improved nuclear targeting, and the evaluation of ex vivo computational models for predicting gRNA efficiency in vivo. Furthermore, our study demonstrated that transient CRISPR-RfxCas13d approaches can effectively deplete endogenous mRNAs in zebrafish embryos without inducing collateral effects, except for targeting extremely abundant RNAs. For that, we have implemented alternative RNA-targeting CRISPR-Cas systems with reduced or absent collateral activity in zebrafish embryos. Altogether, these findings contribute to optimize CRISPR-Cas technology for RNA targeting in zebrafish through transient approaches and assist the progress of potential implications for knockdown therapies in vivo.

Project description:Transient elimination of RNAs by CRISPR-Cas13 systems has been widely used in basic and applied sciences over the last years. However, the efficiency of the system can be enhanced in vivo, and its application has generated controversy due to the recently described collateral activity in mammalian cells and mouse models. Here, we have optimized the CRISPR-RfxCas13d (CasRx) system for an optimized RNA targeting in vivo in zebrafish embryos, by different and compatible approaches. These strategies include the use of chemically modified guide RNAs to increase and sustain mRNA knockdown, an improved nuclear targeting, and the evaluation of ex vivo computational models for predicting gRNA efficiency in vivo. Furthermore, our study demonstrated that transient CRISPR-RfxCas13d approaches can effectively deplete endogenous mRNAs in zebrafish embryos without inducing collateral effects, except for targeting extremely abundant RNAs. For that, we have implemented alternative RNA-targeting CRISPR-Cas systems with reduced or absent collateral activity in zebrafish embryos. Altogether, these findings contribute to optimize CRISPR-Cas technology for RNA targeting in zebrafish through transient approaches and assist the progress of potential implications for knockdown therapies in vivo.

Project description:Transient elimination of RNAs by CRISPR-Cas13 systems has been widely used in basic and applied sciences over the last years. However, the efficiency of the system can be enhanced in vivo, and its application has generated controversy due to the recently described collateral activity in mammalian cells and mouse models. Here, we have optimized the CRISPR-RfxCas13d (CasRx) system for an optimized RNA targeting in vivo in zebrafish embryos, by different and compatible approaches. These strategies include the use of chemically modified guide RNAs to increase and sustain mRNA knockdown, an improved nuclear targeting, and the evaluation of ex vivo computational models for predicting gRNA efficiency in vivo. Furthermore, our study demonstrated that transient CRISPR-RfxCas13d approaches can effectively deplete endogenous mRNAs in zebrafish embryos without inducing collateral effects, except for targeting extremely abundant RNAs. For that, we have implemented alternative RNA-targeting CRISPR-Cas systems with reduced or absent collateral activity in zebrafish embryos. Altogether, these findings contribute to optimize CRISPR-Cas technology for RNA targeting in zebrafish through transient approaches and assist the progress of potential implications for knockdown therapies in vivo.

Project description:The CRISPR/Cas genome editing approach in non-model organisms poses challenges that remain to be resolved.Here, we demonstrated a generalized roadmap for a de-novo genome-annotation approach applied to the non-model organism Macrobrachium rosenbergii. We also addressed typical genome editing challenges arising from genetic variations, such as a high frequency of single nucleotide polymorphisms, differences in sex chromosomes, and repetitive sequences that can lead to off-target events. For genome editing of M. rosenbergii, our laboratory recently adapted the CRISPR/Cas genome-editing approach to embryos and embryonic primary cell culture. In this continuation study, an annotation pipeline was trained to predict gene models by leveraging available genomic, transcriptomic, and proteomic data, enabling accurate gene prediction and guide design for knock-outs. Next-generation sequencing analysis demonstrated a high frequency of genetic variations in genes on both autosomal and sex chromosomes, which have been shown to affect the accuracy of editing analyses. To enable future applications based on the CRISPR/Cas tool in non-model organisms, we also verified the reliability of editing efficiency and tracked off-target frequencies. Despite the lack of comprehensive information on non-model organisms, this study provides an example of the feasibility of selecting and editing specific genes with a high degree of certainty.