Your search keyword '"Lu, Zongyang"' showing total 22 results

1. Probing dirac neutrino properties with dilepton signature

Author

Xu, Wan-Lun, Han, Zhi-Long, Jin, Yi, Li, Honglei, Lu, Zongyang, and Meng, Zhao-Xia

Published

2024

2. Phenomenology of heavy neutral gauge boson at muon collider

Author

Lu, Zongyang, Li, Honglei, Han, Zhi-Long, Si, Zong-Guo, and Zhao, Liuxin

Published

2024

3. CATI: an efficient gene integration method for rodent and primate embryos by MMEJ suppression

Author

Chen, Hongyu, Liu, Xingchen, Li, Lanxin, Tan, Qingtong, Li, Shiyan, Li, Li, Li, Chunyang, Fu, Jiqiang, Lu, Yong, Wang, Yan, Sun, Yidi, Luo, Zhen-Ge, Lu, Zongyang, Sun, Qiang, and Liu, Zhen

Published

2023

4. Comparison of chromatin accessibility landscapes during early development of prefrontal cortex between rhesus macaque and human

Author

Yao, Xuelong, Lu, Zongyang, Feng, Zhanying, Gao, Lei, Zhou, Xin, Li, Min, Zhong, Suijuan, Wu, Qian, Liu, Zhenbo, Zhang, Haofeng, Liu, Zeyuan, Yi, Lizhi, Zhou, Tao, Zhao, Xudong, Zhang, Jun, Wang, Yong, Huang, Xingxu, Wang, Xiaoqun, and Liu, Jiang

Published

2022

5. Epigenomic landscapes during prefrontal cortex development and aging in rhesus.

Author

Ning, Chao, Wu, Xi, Zhao, Xudong, Lu, Zongyang, Yao, Xuelong, Zhou, Tao, Yi, Lizhi, Sun, Yaoyu, Wu, Shuaishuai, Liu, Zhenbo, Huang, Xingxu, Gao, Lei, and Liu, Jiang

Subjects

SUPER enhancers, SINGLE nucleotide polymorphisms, NEURONAL differentiation, SIZE of brain, PREFRONTAL cortex

Abstract

The prefrontal cortex (PFC) is essential for higher-level cognitive functions. How epigenetic dynamics participates in PFC development and aging is largely unknown. Here, we profiled epigenomic landscapes of rhesus monkey PFCs from prenatal to aging stages. The dynamics of chromatin states, including higher-order chromatin structure, chromatin interaction and histone modifications are coordinated to regulate stage-specific gene transcription, participating in distinct processes of neurodevelopment. Dramatic changes of epigenetic signals occur around the birth stage. Notably, genes involved in neuronal cell differentiation and layer specification are pre -configured by bivalent promoters. We identified a cis -regulatory module and the transcription factors (TFs) associated with basal radial glia development, which was associated with large brain size in primates. These TFs include GLI3, CREB5 and SOX9. Interestingly, the genes associated with the basal radial glia (bRG)-associated cis -element module, such as SRY and SOX9, are enriched in sex differentiation. Schizophrenia-associated single nucleotide polymorphisms are more enriched in super enhancers (SEs) than typical enhancers, suggesting that SEs play an important role in neural network wiring. A cis -regulatory element of DBN1 is identified, which is critical for neuronal cell proliferation and synaptic neuron differentiation. Notably, the loss of distal chromatin interaction and H3K27me3 signal are hallmarks of PFC aging, which are associated with abnormal expression of aging-related genes and transposon activation, respectively. Collectively, our findings shed light on epigenetic mechanisms underlying primate brain development and aging. [ABSTRACT FROM AUTHOR]

Published

2024

6. Allele-specific genome editing of imprinting genes by preferentially targeting non-methylated loci using Staphylococcus aureus Cas9 (SaCas9)

Author

Liu, Yajing, Li, Jianan, Zhou, Changyang, Meng, Bin, Wei, Yu, Yang, Guang, Lu, Zongyang, Shen, Qingmei, Zhang, Yu, Yang, Hui, and Qiao, Yunbo

Published

2019

7. Efficient Generation of Pathogenic A-to-G Mutations in Human Tripronuclear Embryos via ABE-Mediated Base Editing

Author

Li, Guanglei, Liu, Xinyi, Huang, Shisheng, Zeng, Yanting, Yang, Guang, Lu, Zongyang, Zhang, Yu, Ma, Xu, Wang, Lisheng, Huang, Xingxu, and Liu, Jianqiao

Published

2019

8. Developing ABEmax-NG with Precise Targeting and Expanded Editing Scope to Model Pathogenic Splice Site Mutations In Vivo

Author

Huang, Shisheng, Liao, Zhaodi, Li, Xiangyang, Liu, Zhen, Li, Guanglei, Li, Jianan, Lu, Zongyang, Zhang, Yu, Li, Xiajun, Ma, Xu, Sun, Qiang, and Huang, Xingxu

Published

2019

9. Generation of isogenic single and multiplex gene knockout mice by base editing-induced STOP

Author

Yang, Guang, Zhu, Tianyu, Lu, Zongyang, Li, Guanglei, Zhang, Hao, Feng, Songjie, Liu, Yajing, Li, Jianan, Zhang, Yu, Chen, Jia, Guo, Xuejiang, and Huang, Xingxu

Published

2018

10. Multiple sgRNAs facilitate base editing-mediated i-stop to induce complete and precise gene disruption

Author

Jia, Kun, Lu, Zongyang, Zhou, Fei, Xiong, Zhiqi, Zhang, Rui, Liu, Zhiwei, Ma, Yu’e, He, Lei, Li, Cong, Zhu, Zhen, Pan, Dejing, and Lian, Zhengxing

Published

2019

11. Locus-specific DNA methylation of Mecp2 promoter leads to autism-like phenotypes in mice

Author

Lu, Zongyang, Liu, Zhen, Mao, Wei, Wang, Xinying, Zheng, Xiaoguo, Chen, Shanshan, Cao, Beibei, Huang, Shisheng, Zhang, Xuliang, Zhou, Tao, Zhang, Yu, Huang, Xingxu, Sun, Qiang, and Li, Jia-Da

Published

2020

12. m6A facilitates hippocampus-dependent learning and memory through YTHDF1

Author

Shi, Hailing, Zhang, Xuliang, Weng, Yi-Lan, Lu, Zongyang, Liu, Yajing, Lu, Zhike, Li, Jianan, Hao, Piliang, Zhang, Yu, Zhang, Feng, Wu, You, Delgado, Jary Y., Su, Yijing, Patel, Meera J., Cao, Xiaohua, Shen, Bin, Huang, Xingxu, Ming, Guo-li, Zhuang, Xiaoxi, Song, Hongjun, He, Chuan, and Zhou, Tao

Published

2018

13. Cynomolgus-rhesus hybrid macaques serve as a platform for imprinting studies

Author

Lu, Zongyang, Li, Jie, Lu, Yong, Li, Ling, Wang, Wei, Zhang, Chenchen, Xu, Libing, Nie, Yanhong, Gao, Changshan, Bian, Xinyan, Liu, Zhen, Wang, Guang-Zhong, and Sun, Qiang

Published

2023

14. Base-edited cynomolgus monkeys mimic core symptoms of STXBP1 encephalopathy

Author

Lu, Zongyang, He, Siting, Jiang, Jian, Zhuang, Ling, Wang, Yan, Yang, Guang, Jiang, Xiaoyu, Nie, Yanhong, Fu, Jiqiang, Zhang, Xiaotong, Lu, Yong, Bian, Xinyan, Chang, Hung-Chun, Xiong, Zhiqi, Huang, Xingxu, Liu, Zhen, and Sun, Qiang

Published

2022

15. Investigating the Z' gauge boson at future lepton colliders * Supported by the National Natural Science Foundation of China (11635009, 11805081), Natural Science Foundation of Shandong Province (ZR2019QA021), and the Open Project of Guangxi Key Laboratory of Nuclear Physics and Nuclear Technology (NLK2021-07)

Author

Yin, Xinyue, ć®·, é'«ć‚¦, Li, Honglei, 李, ć´Şč•ľ, Jin, Yi, é‡', ćŻ..., Han, Zhilong, éź©, ĺż—éľ™, Lu, Zongyang, and 芦, ĺ®—ć´‹

Published

2022

16. m6A facilitates hippocampus-dependent learning and memory through YTHDF1.

Author

Shi, Hailing, Zhang, Xuliang, Weng, Yi-Lan, Lu, Zongyang, Liu, Yajing, Lu, Zhike, Li, Jianan, Hao, Piliang, Zhang, Yu, Zhang, Feng, Wu, You, Delgado, Jary Y., Su, Yijing, Patel, Meera J., Cao, Xiaohua, Shen, Bin, Huang, Xingxu, Ming, Guo-li, Zhuang, Xiaoxi, and Song, Hongjun

Abstract

N6-methyladenosine (m6A), the most prevalent internal RNA modification on mammalian messenger RNAs, regulates the fates and functions of modified transcripts through m6A-specific binding proteins1-5. In the nervous system, m6A is abundant and modulates various neural functions6-11. Whereas m6A marks groups of mRNAs for coordinated degradation in various physiological processes12-15, the relevance of m6A for mRNA translation in vivo remains largely unknown. Here we show that, through its binding protein YTHDF1, m6A promotes protein translation of target transcripts in response to neuronal stimuli in the adult mouse hippocampus, thereby facilitating learning and memory. Mice with genetic deletion of Ythdf1 show learning and memory defects as well as impaired hippocampal synaptic transmission and long-term potentiation. Re-expression of YTHDF1 in the hippocampus of adult Ythdf1-knockout mice rescues the behavioural and synaptic defects, whereas hippocampus-specific acute knockdown of Ythdf1 or Mettl3, which encodes the catalytic component of the m6A methyltransferase complex, recapitulates the hippocampal deficiency. Transcriptome-wide mapping of YTHDF1-binding sites and m6A sites on hippocampal mRNAs identified key neuronal genes. Nascent protein labelling and tether reporter assays in hippocampal neurons showed that YTHDF1 enhances protein synthesis in a neuronal-stimulus-dependent manner. In summary, YTHDF1 facilitates translation of m6A-methylated neuronal mRNAs in response to neuronal stimulation, and this process contributes to learning and memory. Neuronal stimulation induces protein translation of m6A-methylated neuronal mRNAs facilitated by YTHDF1, and this process contributes to learning and memory. [ABSTRACT FROM AUTHOR]

Published

2018

17. Base editing with a Cpf1-cytidine deaminase fusion.

Author

Li, Xiaosa, Wang, Ying, Liu, Yajing, Yang, Bei, Wang, Xiao, Wei, Jia, Lu, Zongyang, Zhang, Yuxi, Wu, Jing, Huang, Xingxu, Yang, Li, and Chen, Jia

Abstract

The targeting range of CRISPR-Cas9 base editors (BEs) is limited by their G/C-rich protospacer-adjacent motif (PAM) sequences. To overcome this limitation, we developed a CRISPR-Cpf1-based BE by fusing the rat cytosine deaminase APOBEC1 to a catalytically inactive version of Lachnospiraceae bacterium Cpf1. The base editor recognizes a T-rich PAM sequence and catalyzes C-to-T conversion in human cells, while inducing low levels of indels, non-C-to-T substitutions and off-target editing. [ABSTRACT FROM AUTHOR]

Published

2018

18. Base-Editing-Mediated R17H Substitution in Histone H3 Reveals Methylation-Dependent Regulation of Yap Signaling and Early Mouse Embryo Development.

Author

Yang, Guang, Zhou, Changyang, Wang, Ran, Huang, Shisheng, Wei, Yu, Yang, Xianfa, Liu, Yajing, Li, Jianan, Lu, Zongyang, Ying, Wenqin, Li, Xiajun, Jing, Naihe, Huang, Xingxu, Yang, Hui, and Qiao, Yunbo

Abstract

Summary The coactivator-associated arginine methyltransferase CARM1 catalyzes the methylation of histone H3 arginine 17/26 (H3R17/26me) and non-histone proteins at arginine residues to regulate gene transactivation through profiling or Carm1 overexpression assays. However, the direct relationship between H3R17/26me and its causal role in mouse embryo development remains largely unclear. Here, we use rAPOBEC1-XTEN-Cas9n-UGI (BE3) to efficiently introduce a point mutation (R17H) at multiple Hist1/2H3 loci and a premature-stop codon into the catalytic domain of CARM1 in mouse embryos, resulting in remarkable downregulation of H3R17me levels and developmental defects in pre-implantation and fetal embryos. Transcriptomic analysis reveals that Yap1 and cell cycle signaling pathways are dysregulated in Carm1 truncation and H3R17H substitution embryos, and Yap1 overexpression could rescue the base-editing-elicited defects. Our data establish the direct regulatory relationship between CARM1-mediated H3R17me and early mouse embryo development and demonstrate that Yap1 acts downstream of CARM1-mediated H3R17me to regulate the mouse embryo development. Graphical Abstract Highlights • Base editing introduces substitutions at multiple histone H3 loci • Both H3R17H substitution and Carm1 truncation disrupt early embryo development • H3R17H substitution and Carm1 truncation lead to similar transcriptomic alterations • H3R17me regulates embryonic development through Yap1 and cell cycle signaling pathways Yang et al. apply CRISPR-Cas9-based base editing tools to precisely introduce substitutions at multiple histone H3 loci to disrupt methylation at histone H3 arginine 17 (H3R17me), and they find that CARM1-mediated H3R17me regulates embryo development through Yap1 and cell cycle signaling pathways. [ABSTRACT FROM AUTHOR]

Published

2019

19. Modeling a cataract disorder in mice with prime editing.

Author

Lin J, Liu X, Lu Z, Huang S, Wu S, Yu W, Liu Y, Zheng X, Huang X, Sun Q, Qiao Y, and Liu Z

Abstract

Prime editing enables efficient introduction of targeted transversions, insertions, and deletions in mammalian cells and several organisms. However, genetic disease models with base deletions by prime editing have not yet been reported in mice. Here, we successfully generate a mouse model with a cataract disorder through microinjection of prime editor 3 (PE3) plasmids to efficiently induce targeted single-base deletion. Notably, a generated mouse with a high G-deletion rate (38.2%) displays a nuclear cataract phenotype; the PE3-induced deletions in mutant mice achieve high rates of germline transmission to their progenies, with phenotypic inheritance of cataract. Our data propose that modeling a genetic disease with a single nucleotide deletion in mice can be achieved with prime genome editing in vivo ., Competing Interests: The authors declare no competing interests., (© 2021 The Authors.)

Published

2021

20. Cas12a Base Editors Induce Efficient and Specific Editing with Low DNA Damage Response.

Author

Wang X, Ding C, Yu W, Wang Y, He S, Yang B, Xiong YC, Wei J, Li J, Liang J, Lu Z, Zhu W, Wu J, Zhou Z, Huang X, Liu Z, Yang L, and Chen J

Subjects

17-Hydroxysteroid Dehydrogenases genetics, Animals, Ataxia Telangiectasia Mutated Proteins metabolism, Bacterial Proteins genetics, CRISPR-Associated Proteins genetics, Cytidine metabolism, Cytidine Deaminase genetics, Cytidine Deaminase metabolism, DNA Replication, Deamination, Endodeoxyribonucleases genetics, Female, HEK293 Cells, Humans, Mice, Mice, Inbred C57BL, Mice, Inbred ICR, Phosphorylation, Proteins genetics, Proteins metabolism, Thymidine metabolism, Tumor Suppressor Protein p53 metabolism, Ubiquitins metabolism, Bacterial Proteins metabolism, CRISPR-Associated Proteins metabolism, DNA Damage, Endodeoxyribonucleases metabolism, Gene Editing methods

Abstract

The advent of base editors (BEs) holds great potential for correcting pathogenic-related point mutations to treat relevant diseases. However, Cas9 nickase (nCas9)-derived BEs lead to DNA double-strand breaks, which can trigger unwanted DNA damage response (DDR). Here, we show that the original version of catalytically dead Cas12a (dCas12a)-conjugated BEs induce a basal level of DNA breaks and minimally activate DDR proteins, including H2AX, ATM, ATR, and p53. By fusing dCas12a with engineered human apolipoprotein B mRNA editing enzyme, catalytic polypeptide-like 3A (APOBEC3A), we further develop the BEACON (base editing induced by human APOBEC3A and Cas12a without DNA break) system to achieve enhanced deamination efficiency and editing specificity. Efficient C-to-T editing is achieved by BEACON in mammalian cells at levels comparable to AncBE4max, with only low levels of DDR and minimal RNA off-target mutations. Importantly, BEACON induces in vivo base editing in mouse embryos, and targeted C-to-T conversions are detected in F0 mice., Competing Interests: Declaration of Interests J.C., L.Y., X.H., B.Y., X.W., C.D., and W.Y. have filed patent applications on aspects on this work. The authors declare no competing non-financial interests., (Copyright © 2020 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2020

21. Base editors: a powerful tool for generating animal models of human diseases.

Author

Lu Z and Huang X

Abstract

Myriads of genetic mutations, including base substitutions, deletions, and insertions as well as chromosome structural variations, have been detected in many human diseases. Although current combination of genomics and bioinformatics has contributed greatly to understanding the genetics of these disorders, it remains challenging to ensure the causal functions of each mutation, and then to further investigate the underlying mechanism and to develop therapeutic strategies. Animal models generated by genome engineering are the key to address these issues. In this review, we will first revisit the limitation of conventional gene editing tools and mouse models generated in the past. We will then introduce a novel tool, base editors (BEs), which present a new promising approach to establish pathogenically relevant animal models. Finally, we will discuss the application of BEs in non-human primates and share our perspectives on future development of base-editing techniques., Competing Interests: Conflict of interest: The authors declare no conflict of interest.

Published

2018

22. Efficient generation of mouse models of human diseases via ABE- and BE-mediated base editing.

Author

Liu Z, Lu Z, Yang G, Huang S, Li G, Feng S, Liu Y, Li J, Yu W, Zhang Y, Chen J, Sun Q, and Huang X

Subjects

Adenine chemistry, Animals, Animals, Newborn, Cell Line, Tumor, Female, Genome, Human, Genotype, Green Fluorescent Proteins chemistry, High-Throughput Nucleotide Sequencing, Humans, Male, Mice, Mutation, Protein Domains, RNA, Messenger metabolism, Sensitivity and Specificity, Sequence Analysis, DNA, RNA, Guide, CRISPR-Cas Systems, Disease Models, Animal, Homeodomain Proteins genetics, Receptors, Androgen genetics, Transcription Factors genetics

Abstract

A recently developed adenine base editor (ABE) efficiently converts A to G and is potentially useful for clinical applications. However, its precision and efficiency in vivo remains to be addressed. Here we achieve A-to-G conversion in vivo at frequencies up to 100% by microinjection of ABE mRNA together with sgRNAs. We then generate mouse models harboring clinically relevant mutations at Ar and Hoxd13, which recapitulates respective clinical defects. Furthermore, we achieve both C-to-T and A-to-G base editing by using a combination of ABE and SaBE3, thus creating mouse model harboring multiple mutations. We also demonstrate the specificity of ABE by deep sequencing and whole-genome sequencing (WGS). Taken together, ABE is highly efficient and precise in vivo, making it feasible to model and potentially cure relevant genetic diseases.

Published

2018