整合组学与CRISPR技术用于鉴定和验证鸡基因组中的基因组安全港位点

Integrating Omics and CRISPR Technology for Identification and Verification of Genomic Safe Harbor Loci in the Chicken Genome.

作者信息

Dehdilani Nima, Goshayeshi Lena, Yousefi Taemeh Sara, Bahrami Ahmad Reza, Rival Gervier Sylvie, Pain Bertrand, Dehghani Hesam

机构信息

Stem Cell Biology and Regenerative Medicine Research Group, Research Institute of Biotechnology, Ferdowsi University of Mashhad, Azadi Square, Mashhad, Iran.

Division of Biotechnology, Faculty of Veterinary Medicine, Ferdowsi University of Mashhad, Mashhad, Iran.

出版信息

Biol Proced Online. 2023 Jun 24;25(1):18. doi: 10.1186/s12575-023-00210-5.

DOI:10.1186/s12575-023-00210-5

PMID:37355580

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10290409/

Abstract

BACKGROUND

One of the most prominent questions in the field of transgenesis is 'Where in the genome to integrate a transgene?'. Escape from epigenetic silencing and promoter shutdown of the transgene needs reliable genomic safe harbor (GSH) loci. Advances in genome engineering technologies combined with multi-omics bioinformatics data have enabled rational evaluation of GSH loci in the host genome. Currently, no validated GSH loci have been evaluated in the chicken genome.

RESULTS

Here, we analyzed and experimentally examined two GSH loci in the genome of chicken cells. To this end, putative GSH loci including chicken HIPP-like (cHIPP; between DRG1 and EIF4ENIF1 genes) and chicken ROSA-like (cROSA; upstream of the THUMPD3 gene) were predicted using multi-omics bioinformatics data. Then, the durable expression of the transgene was validated by experimental characterization of continuously-cultured isogenous cell clones harboring DsRed2-ΔCMV-EGFP cassette in the predicted loci. The weakened form of the CMV promoter (ΔCMV) allowed the precise evaluation of GSH loci in a locus-dependent manner compared to the full-length CMV promoter.

CONCLUSIONS

cHIPP and cROSA loci introduced in this study can be reliably exploited for consistent bio-manufacturing of recombinant proteins in the genetically-engineered chickens. Also, results showed that the genomic context dictates the expression of transgene controlled by ΔCMV in GSH loci.

摘要

背景

转基因领域最突出的问题之一是“转基因整合到基因组的何处？”。转基因逃避表观遗传沉默和启动子关闭需要可靠的基因组安全港（GSH）位点。基因组工程技术的进步与多组学生物信息学数据相结合，使得对宿主基因组中的GSH位点进行合理评估成为可能。目前，尚未在鸡基因组中评估经过验证的GSH位点。

结果

在此，我们分析并通过实验检测了鸡细胞基因组中的两个GSH位点。为此，利用多组学生物信息学数据预测了推定的GSH位点，包括鸡类HIPP（cHIPP；在DRG1和EIF4ENIF1基因之间）和鸡类ROSA（cROSA；在THUMPD3基因上游）。然后，通过对在预测位点携带DsRed2-ΔCMV-EGFP盒的连续培养同基因细胞克隆进行实验表征，验证了转基因的持久表达。与全长CMV启动子相比，CMV启动子的弱化形式（ΔCMV）允许以位点依赖的方式精确评估GSH位点。

结论

本研究中引入的cHIPP和cROSA位点可可靠地用于基因工程鸡中重组蛋白的一致性生物制造。此外，结果表明基因组背景决定了GSH位点中由ΔCMV控制的转基因的表达。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/96d6/10290409/d6fac0f3895d/12575_2023_210_Fig1_HTML.jpg

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整合组学与CRISPR技术用于鉴定和验证鸡基因组中的基因组安全港位点

Integrating Omics and CRISPR Technology for Identification and Verification of Genomic Safe Harbor Loci in the Chicken Genome.

作者信息

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSIONS

背景

结果

结论

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