Abstract
Mouse artificial chromosome (MAC) vectors have several advantages as gene delivery vectors, such as stable and independent maintenance in host cells without integration, transferability from donor cells to recipient cells via microcell-mediated chromosome transfer (MMCT), and the potential for loading a megabase-sized DNA fragment. Previously, a MAC containing a multi-integrase platform (MI-MAC) was developed to facilitate the transfer of multiple genes into desired cells. Although the MI system can theoretically hold five gene-loading vectors (GLVs), there are a limited number of drugs available for the selection of multiple-GLV integration. To overcome this issue, we attempted to knock out and reuse drug resistance genes (DRGs) using the CRISPR-Cas9 system. In this study, we developed new methods for multiple-GLV integration. As a proof of concept, we introduced five GLVs in the MI-MAC by these methods, in which each GLV contained a gene encoding a fluorescent or luminescent protein (EGFP, mCherry, BFP, Eluc, and Cluc). Genes of interest (GOI) on the MI-MAC were expressed stably and functionally without silencing in the host cells. Furthermore, the MI-MAC carrying five GLVs was transferred to other cells by MMCT, and the resultant recipient cells exhibited all five fluorescence/luminescence signals. Thus, the MI-MAC was successfully used as a multiple-GLV integration vector using the CRISPR-Cas9 system. The MI-MAC employing these methods may resolve bottlenecks in developing multiple-gene humanized models, multiple-gene monitoring models, disease models, reprogramming, and inducible gene expression systems.
Highlights
There are several concerns about conventional gene delivery vectors, namely plasmids, bacterial artificial chromosomes (BACs), and P1-derived artificial chromosomes (PACs), for the production of stable transgenic (Tg) cells and animals, such as unpredictable copy number, disruption of the host genome by random integration, transgene silencing by position effect, and limitation of gene-loading size [1]
Development of a multiple-gene-loading method modified in advance. If this system is applied to human artificial chromosome (HAC)/mouse artificial chromosome (MAC), its ability to be used as a multiple-gene-loading vectors (GLVs)-loading system can be expanded to various fields of study
We developed new GLV-loading methods that are applicable to the MI-MAC
Summary
There are several concerns about conventional gene delivery vectors, namely plasmids, bacterial artificial chromosomes (BACs), and P1-derived artificial chromosomes (PACs), for the production of stable transgenic (Tg) cells and animals, such as unpredictable copy number, disruption of the host genome by random integration, transgene silencing by position effect, and limitation of gene-loading size [1]. We developed a human artificial chromosome (HAC) vector from native human chromosomes by chromosome engineering, telomere-associated chromosomal truncation, and loxP site insertion [2, 3]. The HAC vector has different properties from those of other gene delivery vectors, for example delivery of a defined copy number of transgene, stable and independent maintenance in host cells without integration, transferability from donor cells to recipient cells via microcell-mediated chromosome transfer (MMCT), and the potential for loading a megabase (Mb)-sized DNA fragment [4]. The HAC is retained in human-derived cells at high efficiency, the retention rate varies among mouse tissues; in particular, hematopoietic cells showed a low retention rate. In addition to the advantages of the HAC, the MAC has a high retention rate in mouse tissues including hematopoietic cells [9, 10]. The HAC/MAC only has a loxP site for gene loading, so the labor-intensive process of additional GLV loading must be performed
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