Your search keyword '"ABE8e"' showing total 11 results

1. Directed-evolution mutations enhance DNA-binding affinity and protein stability of the adenine base editor ABE8e.

Author

Zhu, Haixia, Wang, Lei, Wang, Ying, Jiang, Xinyi, Qin, Qin, Song, Menghua, and Huang, Qiang

Subjects

*PROTEIN stability, *DNA-binding proteins, *ADENINE, *CRISPRS, *GENOME editing, *BASE pairs

Abstract

Adenine base editors (ABEs), consisting of CRISPR Cas nickase and deaminase, can chemically convert the A:T base pair to G:C. ABE8e, an evolved variant of the base editor ABE7.10, contains eight directed evolution mutations in its deaminase TadA8e that significantly increase its base editing activity. However, the functional implications of these mutations remain unclear. Here, we combined molecular dynamics (MD) simulations and experimental measurements to investigate the role of the directed-evolution mutations in the base editing catalysis. MD simulations showed that the DNA-binding affinity of TadA8e is higher than that of the original deaminase TadA7.10 in ABE7.10 and is mainly driven by electrostatic interactions. The directed-evolution mutations increase the positive charge density in the DNA-binding region, thereby enhancing the electrostatic attraction of TadA8e to DNA. We identified R111, N119 and N167 as the key mutations for the enhanced DNA binding and confirmed them by microscale thermophoresis (MST) and in vivo reversion mutation experiments. Unexpectedly, we also found that the directed mutations improved the thermal stability of TadA8e by ~ 12 °C (Tm, melting temperature) and that of ABE8e by ~ 9 °C, respectively. Our results demonstrate that the directed-evolution mutations improve the substrate-binding ability and protein stability of ABE8e, thus providing a rational basis for further editing optimisation of the system. [ABSTRACT FROM AUTHOR]

Published

2024

2. A new compact adenine base editor generated through deletion of HNH and REC2 domain of SpCas9

Author

Yuqiang Qian, Di Wang, Wenchao Niu, Ding Zhao, Jinze Li, Zhiquan Liu, Xun Gao, Yang Han, Liangxue Lai, and Zhanjun Li

Subjects

CRISPR/Cas9, Base editor, ABE8e, Reduce size, AAV, Biology (General), QH301-705.5

Abstract

Abstract Background Adenine base editors (ABEs) are promising therapeutic gene editing tools that can efficiently convert targeted A•T to G•C base pairs in the genome. However, the large size of commonly used ABEs based on SpCas9 hinders its delivery in vivo using certain vectors such as adeno-associated virus (AAV) during preclinical applications. Despite a number of approaches having previously been attempted to overcome that challenge, including split Cas9-derived and numerous domain-deleted versions of editors, whether base editor (BE) and prime editor (PE) systems can also allow deletion of those domains remains to be proven. In this study, we present a new small ABE (sABE) with significantly reduced size. Results We discovered that ABE8e can tolerate large single deletions in the REC2 (Δ174-296) and HNH (Δ786-855) domains of SpCas9, and these deletions can be stacked together to create a new sABE. The sABE showed higher precision than the original ABE8e, with proximally shifted protospacer adjacent motif (PAM) editing windows (A3- A15), and comparable editing efficiencies to 8e-SaCas9-KKH. The sABE system efficiently generated A-G mutations at disease-relevant loci (T1214C in GAA and A494G in MFN2) in HEK293T cells and several canonical Pcsk9 splice sites in N2a cells. Moreover, the sABE enabled in vivo delivery in a single adeno-associated virus (AAV) vector with slight efficiency. Furthermore, we also successfully edited the genome of mouse embryos by microinjecting mRNA and sgRNA of sABE system into zygotes. Conclusions We have developed a substantially smaller sABE system that expands the targeting scope and offers higher precision of genome editing. Our findings suggest that the sABE system holds great therapeutic potential in preclinical applications.

Published

2023

3. A new compact adenine base editor generated through deletion of HNH and REC2 domain of SpCas9.

Author

Qian, Yuqiang, Wang, Di, Niu, Wenchao, Zhao, Ding, Li, Jinze, Liu, Zhiquan, Gao, Xun, Han, Yang, Lai, Liangxue, and Li, Zhanjun

Subjects

*ADENINE, *BASE pairs, *ADENO-associated virus, *GENOME editing, *CRISPRS, *ZYGOTES, *GENETIC vectors

Abstract

Background: Adenine base editors (ABEs) are promising therapeutic gene editing tools that can efficiently convert targeted A•T to G•C base pairs in the genome. However, the large size of commonly used ABEs based on SpCas9 hinders its delivery in vivo using certain vectors such as adeno-associated virus (AAV) during preclinical applications. Despite a number of approaches having previously been attempted to overcome that challenge, including split Cas9-derived and numerous domain-deleted versions of editors, whether base editor (BE) and prime editor (PE) systems can also allow deletion of those domains remains to be proven. In this study, we present a new small ABE (sABE) with significantly reduced size. Results: We discovered that ABE8e can tolerate large single deletions in the REC2 (Δ174-296) and HNH (Δ786-855) domains of SpCas9, and these deletions can be stacked together to create a new sABE. The sABE showed higher precision than the original ABE8e, with proximally shifted protospacer adjacent motif (PAM) editing windows (A3- A15), and comparable editing efficiencies to 8e-SaCas9-KKH. The sABE system efficiently generated A-G mutations at disease-relevant loci (T1214C in GAA and A494G in MFN2) in HEK293T cells and several canonical Pcsk9 splice sites in N2a cells. Moreover, the sABE enabled in vivo delivery in a single adeno-associated virus (AAV) vector with slight efficiency. Furthermore, we also successfully edited the genome of mouse embryos by microinjecting mRNA and sgRNA of sABE system into zygotes. Conclusions: We have developed a substantially smaller sABE system that expands the targeting scope and offers higher precision of genome editing. Our findings suggest that the sABE system holds great therapeutic potential in preclinical applications. [ABSTRACT FROM AUTHOR]

Published

2023

4. Chitosan Hydrogel-Delivered ABE8e Corrects PAX9 Mutant in Dental Pulp Stem Cells.

Author

Liu, Bowen, Zhang, Chenjiao, Zhao, Han, Gao, Jian, and Hu, Jingchao

Subjects

HYPODONTIA, HYDROGELS in medicine, DENTAL pulp, CHITOSAN, WESTERN immunoblotting

Abstract

Hypodontia (dental agenesis) is a genetic disorder, and it has been identified that the mutation C175T in PAX9 could lead to hypodontia. Cas9 nickase (nCas9)-mediated homology-directed repair (HDR) and base editing were used for the correction of this mutated point. This study aimed to investigate the effect of HDR and the base editor ABE8e in editing PAX9 mutant. It was found that the chitosan hydrogel was efficient in delivering naked DNA into dental pulp stem cells (DPSCs). To explore the influence of the C175T mutation in PAX9 on the proliferation of DPSCs, hydrogel was employed to deliver PAX9 mutant vector into DPSCs, finding that the PAX9-containing C175T mutation failed to promote the proliferation of DPSCs. Firstly, DPSCs stably carrying PAX9 mutant were constructed. Either an HDR or ABE8e system was delivered into the above-mentioned stable DPSCs, and then the correction efficiency using Sanger sequencing and Western blotting was determined. Meanwhile, the ABE8e presented significantly higher efficiency in correcting C175T compared with HDR. Furthermore, the corrected PAX9 presented enhanced viability and differentiation capacity for osteogenic and neurogenic lineages; the corrected PAX9 even possessed extremely enhanced transcriptional activation ability. In summary, this study has powerful implications for studies into base editors, chitosan hydrogel, and DPSCs in treating hypodontia. [ABSTRACT FROM AUTHOR]

Published

2023

5. Optimize nearly PAM-less adenine base editor to improve editing efficiency

Author

ZHOU Xiao-yu, WANG Xiao-yue

Subjects

adenine base editor, spry, abe8e, editing efficiency, Medicine

Abstract

Objective To explore the effects of replacing different components of PAM-less adenine base editor (ABE) on its editing efficiency. Methods ABEmax was replaced with Tad-8e in SpRY-ABEmax to construct SpRY-ABE8e. Then the connecting peptide 3xGGS-XTEN-3xGGS between Cas9 protein variant SpRY and Tad-8e was shortened to PAPAPA. ABEs and sgRNA expression plasmids were co-transfected into HEK 293T cells. After 24 hours, cells were incubated with 1.5 μg/mL puromycin. After 72 hours, the cells expressing green fluorescent protein were flow sorted and the cell genome was extracted and the expected editing sites were amplified by PCR technology. Sanger sequencing was performed and Beat tool was used to estimate the editing efficiency of each site. Results Compared with control group, SpRY-ABEmax, SpRY-ABE8e has higher editing efficiency and expanded editing window(P＜0.05); editing window of SpRY-ABE8e can be limited to a certain extent while maintaining editing efficiency by using the shortened linker peptide. Conclusions The editing efficiency can be improved by replacing different components of PAM-less ABE, which will provide more candidate tools for gene therapy in the future.

Published

2022

6. Delivery of Cas9-guided ABE8e into stem cells using poly(l-lysine) polypeptides for correction of the hemophilia-associated FIX missense mutation.

Author

Rong, Lijuan, Chen, Dandan, Huang, Xiangbo, and Sun, Ling

Subjects

*STEM cells, *MISSENSE mutation, *POLYPEPTIDES, *BLOOD coagulation factor IX, *HEMOPHILIACS, *STAR-branched polymers, *BLOOD coagulation factors

Abstract

The coagulation factor 9 gene (FIX) point mutation contributes to most hemophilia B cases, providing ideal gene correction models. Here we identified the frequent mutation G20519A (R226Q) in FIX , which resulted in many severe and moderate hemophilia B patients. This study aimed to investigate the effect of HDR and base editing in correcting FIX mutant. We first constructed HEK293 and liver-derived cell lines Huh7 cells stabling carrying mutated FIX containing G20519A (HEK293-FIXmut and Huh7-FIXmut). Then, CRISPR/Cas9-based homology-directed repair (HDR) and base editing were used for the correction of this mutated point. We used Cas9 nickase (nCas9) mediated HDR and the advanced base editor ABE8e to correct G20519A and then measured the concentration and activity of FIX. Furthermore, we used the star-shaped poly(lysine) gene nanocarriers to deliver the ABE8e correction systems into HEK293-FIXmut and Huh7-FIXmut stem cells to correct mutated FIX. As a result, we found that gRNAs directed inefficient HDR in correcting G20519A. The ABE8e corrected the mutation efficiently in both HEK293-FIXmut and Huh7-FIXmut stem cells. In addition, the star-shaped poly(lysine) carriers delivered non-viral vectors into stem cells efficiently. The nanocarriers-delivered ABE8e system corrected mutated FIX in stem cells, and the stem cells secreted active FIX in high concentration. In conclusion, our study provides a potential alternative for correcting mutated FIX in hemophilia B patients. • The point mutation G20519A (R226Q) in FIX results to lower concentration and lower activity of FIX. • ABE8e corrected mutated FIX more efficiently compared with HDR. • Bioinspired star shaped PLL polypeptides could deliver gene correction systems into stem cells. • PLL-delivered ABE8e system could correct mutated FIX efficiently in stem cells. [ABSTRACT FROM AUTHOR]

Published

2022

7. Chitosan Hydrogel-Delivered ABE8e Corrects PAX9 Mutant in Dental Pulp Stem Cells

Author

Bowen Liu, Chenjiao Zhang, Han Zhao, Jian Gao, and Jingchao Hu

Subjects

hydrogel, hypodontia, dental agenesis, dental pulp stem cells, PAX9, ABE8e, Science, Chemistry, QD1-999, Inorganic chemistry, QD146-197, General. Including alchemy, QD1-65

Abstract

Hypodontia (dental agenesis) is a genetic disorder, and it has been identified that the mutation C175T in PAX9 could lead to hypodontia. Cas9 nickase (nCas9)-mediated homology-directed repair (HDR) and base editing were used for the correction of this mutated point. This study aimed to investigate the effect of HDR and the base editor ABE8e in editing PAX9 mutant. It was found that the chitosan hydrogel was efficient in delivering naked DNA into dental pulp stem cells (DPSCs). To explore the influence of the C175T mutation in PAX9 on the proliferation of DPSCs, hydrogel was employed to deliver PAX9 mutant vector into DPSCs, finding that the PAX9-containing C175T mutation failed to promote the proliferation of DPSCs. Firstly, DPSCs stably carrying PAX9 mutant were constructed. Either an HDR or ABE8e system was delivered into the above-mentioned stable DPSCs, and then the correction efficiency using Sanger sequencing and Western blotting was determined. Meanwhile, the ABE8e presented significantly higher efficiency in correcting C175T compared with HDR. Furthermore, the corrected PAX9 presented enhanced viability and differentiation capacity for osteogenic and neurogenic lineages; the corrected PAX9 even possessed extremely enhanced transcriptional activation ability. In summary, this study has powerful implications for studies into base editors, chitosan hydrogel, and DPSCs in treating hypodontia.

Published

2023

8. ABE8e with Polycistronic tRNA-gRNA Expression Cassette Sig-Nificantly Improves Adenine Base Editing Efficiency in Nicotiana benthamiana

Author

Zupeng Wang, Xiaoying Liu, Xiaodong Xie, Lei Deng, Hao Zheng, Hui Pan, Dawei Li, Li Li, and Caihong Zhong

Subjects

CRISPR, base editor, ABE, ABE8e, STU, PTG, Biology (General), QH301-705.5, Chemistry, QD1-999

Abstract

Adenine base editor containing TadA8e (ABE8e) has been reported in rice. However, the application of ABE8e in other plant species has not been described, and the comparison between ABE8e and ABE7.10, which is widely used in plants, has also been poorly studied. Here, we developed the ABE8e with the polycistronic tRNA-gRNA expression cassette (PTG-ABE8e) and PTG-ABE7.10 and compared their A-to-G editing efficiencies using both transient and stable transformation in the allotetraploid Nicotiana benthamiana. We found that the editing efficiency of PTG-ABE8e was significantly higher than that of PTG-ABE7.10, indicating that ABE8e was more efficient for A-to-G conversion in N. benthamiana. We further optimized the ABE8e editing efficiency by changing the sgRNA expression cassette and demonstrated that both PTG and single transcript unit (STU) enhanced ABE8e efficiency for A-to-G conversion in N. benthamiana. We also estimated the potential off-target effect of PTG-ABE8e at potential off-targeting sites predicted using an online tool in transgenic plants, and no off-target editing event was found for potential off-targeting sites selected, indicating that ABE8e could specifically facilitate A-to-G conversion. Our results showed that ABE8e with PTG structure was more suitable for A-to-G conversion in N. benthamiana and provided valuable clues for optimizing ABE tools in other plants.

Published

2021

9. ABE8e with Polycistronic tRNA-gRNA Expression Cassette Sig-Nificantly Improves Adenine Base Editing Efficiency in Nicotiana benthamiana

Author

Xiaoying Liu, Caihong Zhong, Dawei Li, Hao Zheng, Pan Hui, Deng Lei, Xiaodong Xie, Z. Wang, and Li Li

Subjects

0106 biological sciences, 0301 basic medicine, QH301-705.5, Nicotiana benthamiana, Genetically modified crops, 01 natural sciences, base editor, Catalysis, Article, STU, Inorganic Chemistry, 03 medical and health sciences, Tobacco, CRISPR, Guide RNA, Biology (General), Physical and Theoretical Chemistry, QD1-999, Molecular Biology, Spectroscopy, Subgenomic mRNA, Gene Editing, biology, Chemistry, Organic Chemistry, ABE8e, General Medicine, biology.organism_classification, Plants, Genetically Modified, Computer Science Applications, Cell biology, Tetraploidy, Transformation (genetics), 030104 developmental biology, Transfer RNA, Expression cassette, CRISPR-Cas Systems, PTG, 010606 plant biology & botany, ABE, RNA, Guide, Kinetoplastida

Abstract

Adenine base editor containing TadA8e (ABE8e) has been reported in rice. However, the application of ABE8e in other plant species has not been described, and the comparison between ABE8e and ABE7.10, which is widely used in plants, has also been poorly studied. Here, we developed the ABE8e with the polycistronic tRNA-gRNA expression cassette (PTG-ABE8e) and PTG-ABE7.10 and compared their A-to-G editing efficiencies using both transient and stable transformation in the allotetraploid Nicotiana benthamiana. We found that the editing efficiency of PTG-ABE8e was significantly higher than that of PTG-ABE7.10, indicating that ABE8e was more efficient for A-to-G conversion in N. benthamiana. We further optimized the ABE8e editing efficiency by changing the sgRNA expression cassette and demonstrated that both PTG and single transcript unit (STU) enhanced ABE8e efficiency for A-to-G conversion in N. benthamiana. We also estimated the potential off-target effect of PTG-ABE8e at potential off-targeting sites predicted using an online tool in transgenic plants, and no off-target editing event was found for potential off-targeting sites selected, indicating that ABE8e could specifically facilitate A-to-G conversion. Our results showed that ABE8e with PTG structure was more suitable for A-to-G conversion in N. benthamiana and provided valuable clues for optimizing ABE tools in other plants.

Published

2021

10. Robust genome editing via modRNA-based Cas9 or base editor in human pluripotent stem cells.

Author

Haideri T, Howells A, Jiang Y, Yang J, Bao X, and Lian XL

Subjects

Humans, CRISPR-Cas Systems genetics, RNA, Messenger genetics, Plasmids, Gene Editing methods, Pluripotent Stem Cells

Abstract

CRISPR systems have revolutionized biomedical research because they offer an unprecedented opportunity for genome editing. However, a bottleneck of applying CRISPR systems in human pluripotent stem cells (hPSCs) is how to deliver CRISPR effectors easily and efficiently. Here, we developed modified mRNA (modRNA)-based CRIPSR systems that utilized Cas9 and p53DD or a base editor (ABE8e) modRNA for the purposes of knocking out genes in hPSCs via simple lipid-based transfection. ABE8e modRNA was employed to disrupt the splice donor site, resulting in defective splicing of the target transcript and ultimately leading to gene knockout. Using our modRNA CRISPR systems, we achieved 73.3% ± 11.2% and 69.6 ± 3.8% knockout efficiency with Cas9 plus p53DD modRNA and ABE8e modRNA, respectively, which was significantly higher than the plasmid-based systems. In summary, we demonstrate that our non-integrating modRNA-based CRISPR methods hold great promise as more efficient and accessible techniques for genome editing of hPSCs., Competing Interests: X.L.L., T.H., A.H., and Y.J. are listed as inventors on a provisional patent application (no. 63/335,568), which was filed on April 27, 2022. The other authors declare no competing interests., (© 2022 The Author(s).)

Published

2022

11. ABE8e with Polycistronic tRNA-gRNA Expression Cassette Sig-Nificantly Improves Adenine Base Editing Efficiency in Nicotiana benthamiana.

Author

Wang, Zupeng, Liu, Xiaoying, Xie, Xiaodong, Deng, Lei, Zheng, Hao, Pan, Hui, Li, Dawei, Li, Li, and Zhong, Caihong

Subjects

*NICOTIANA benthamiana, *ADENINE, *TRANSGENIC plants, *PLANT species, *GENOME editing

Abstract

Adenine base editor containing TadA8e (ABE8e) has been reported in rice. However, the application of ABE8e in other plant species has not been described, and the comparison between ABE8e and ABE7.10, which is widely used in plants, has also been poorly studied. Here, we developed the ABE8e with the polycistronic tRNA-gRNA expression cassette (PTG-ABE8e) and PTG-ABE7.10 and compared their A-to-G editing efficiencies using both transient and stable transformation in the allotetraploid Nicotiana benthamiana. We found that the editing efficiency of PTG-ABE8e was significantly higher than that of PTG-ABE7.10, indicating that ABE8e was more efficient for A-to-G conversion in N. benthamiana. We further optimized the ABE8e editing efficiency by changing the sgRNA expression cassette and demonstrated that both PTG and single transcript unit (STU) enhanced ABE8e efficiency for A-to-G conversion in N. benthamiana. We also estimated the potential off-target effect of PTG-ABE8e at potential off-targeting sites predicted using an online tool in transgenic plants, and no off-target editing event was found for potential off-targeting sites selected, indicating that ABE8e could specifically facilitate A-to-G conversion. Our results showed that ABE8e with PTG structure was more suitable for A-to-G conversion in N. benthamiana and provided valuable clues for optimizing ABE tools in other plants. [ABSTRACT FROM AUTHOR]

Published

2021