An Update on the Tools for Creating Transgenic Animal Models of Human Diseases – Focus on Atherosclerosis

An Update on the Tools for Creating Transgenic Animal Models of Human Diseases – Focus on Atherosclerosis

Brazilian Journal of Medical and Biological Research (2019) 52(5): e8108, http://dx.doi.org/10.1590/1414-431X20198108 ISSN 1414-431X Review 1/7 An update on the tools for creating transgenic animal models of human diseases – focus on atherosclerosis A.S. Volobueva2, A.N. Orekhov 1,3,4, and A.V. Deykin 1 1Institute of Gene Biology, Russian Academy of Sciences, Moscow, Russia 2Laboratory of Gene Therapy, Biocad Biotechnology Company, Strelnya, Russia 3Laboratory of Angiopathology, Institute of General Pathology and Pathophysiology, Moscow, Russia 4Institute for Atherosclerosis Research, Skolkovo Innovative Center, Moscow, Russia Abstract Animal models of diseases are invaluable tools of modern medicine. More than forty years have passed since the first successful experiments and the spectrum of available models, as well as the list of methods for creating them, have expanded dramatically. The major step forward in creating specific disease models was the development of gene editing techniques, which allowed for targeted modification of the animal’s genome. In this review, we discuss the available tools for creating transgenic animal models, such as transgenesis methods, recombinases, and nucleases, including zinc finger nuclease (ZFN), transcription activator-like effector nuclease (TALEN), and CRISPR/Cas9 systems. We then focus specifically on the models of atherosclerosis, especially mouse models that greatly contributed to improving our understanding of the disease pathogenesis and we outline their characteristics and limitations. Key words: Animal models; Gene editing; Atherosclerosis Introduction Model organisms are widely used in biomedicine reliability of resulting models. Moreover, uncontrolled gene for studying the pathophysiology of human diseases and expression could affect multiple pathways in the animal developing novel therapeutic and diagnostic methods. model organism making it difficult to replicate specific Naturally occurring animal models of human genetic disease conditions. Therefore, the development of site- diseases, like Watanabe rabbits with heritable hypercho- specific gene integration was a crucial step forward in lesterolemia, are rare, probably, because of poor survival creating genetically modified animals with accurate and of such animals. The era of transgenic animals began in identical genotypes. Novel genetic tools allowing for tar- 1974 when Rudolf Jaenisch managed to insert DNA into geted changes via homologous recombination with higher mice embryos and obtained the first genetically modified frequency have been designed, including zinc finger animal (1). Since then, plenty of methods have been nucleases (ZFN), transcription activator-like effector applied to establish somatic and germline animal models nucleases (TALEN), and clustered regularly interspaced of different human diseases, mostly using mouse models short palindromic repeats (CRISPR)/Cas9. In this review, (2). Among the most used methods are oocyte pronuclear we will summarize the existing approaches to genetically DNA microinjection, intracytoplasmic sperm injection, modified animal development with special focus on trans- stem cells modifications, and somatic cell nuclear transfer. genic animal models of atherosclerosis. The basic strategies for creating disease models are arti- ficial addition of a gene into the animal cells (knock-in), Techniques of transgenesis switching off a certain gene (knock-out), and conditional gene modification in response to certain stimuli or in a Generating transgenic mice using oocyte pronuclear specific tissue environment. These approaches are based DNA microinjection includes five basic steps: purification on homologous recombination, which rarely happens in of transgenic construct, harvesting donor zygotes, micro- nature. Viral vectors were very helpful for gene transfer, injection of transgenic construct, implantation of micro- but in most cases caused uncontrolled and often random injected zygotes into pseudo-pregnant recipient mice, and transgene integration, which affected reproducibility and genotyping of transgene expression in founder mice (3). Correspondence: A.N. Orekhov: <[email protected]> Received December 3, 2018 | Accepted February 25, 2019 Braz J Med Biol Res | doi: 10.1590/1414-431X20198108 Atherosclerosis models in transgenic animals 2/7 Different vectors for DNA delivery have been explored: engineering. We will briefly describe the most commonly episomal and viral vectors, as well as artificial chromo- used gene editing tools below (Table 1). somes allowing for insertion of large fragments. Intracytoplasmic sperm injection (ICSI) has higher Recombinases efficiency of transfer of foreign DNA in the host genome Recombinases are enzymes allowing for site-specific compared to pronuclear injection. In this method, animal mutagenesis. They recognize their target sites and induce spermatozoa are demembranated either by freeze-thaw- recombination between them, thereby excising DNA ing or by treatment with a detergent and incubated with fragments located between them. Depending on the linear, double stranded transgenic DNA. This sperm-DNA orientation of the binding sites, recombinases can cause complex is injected into mature metaphase II oocytes by deletions, insertions, translocations, and inversions. One of ICSI, allowing the transgene to be incorporated into the the major advantages of recombinases is that they allow for embryonic genome via the DNA repair mechanism (4,5). conditional gene modification, which is of special impor- Embryonic stem (ES) cells can also be used for trans- tance when mutations in a target gene are lethal during genesis. The exogenous DNA is introduced into stem cells, embryogenesis. Using tissue-specific or inducible promo- following cell propagation and selection steps. After that, tors, researchers can choose the preferential time-point the genetically modified ES cells are introduced into the and organ for genetic modification to occur. However, find- embryo, for instance, by injecting them into a blasto- ing a highly specific promotor is challenging and not always cyst using micromanipulators or by aggregating them with possible, and much effort is needed to create an optimal eight-cell-stage embryos. These methods have been used disease model using this method. Among the most known for creating mouse models (6). recombinase systems are Cre-LoxP, which was intro- Somatic cell nuclear transfer (SCNT) remains by far the duced in 1980, and Flp-FRT. Cre-LoxP has been applied most popular method for production of large transgenic for generation of various mouse models of human cancers animals. SCNT involves generation of modified somatic (8). Recently, novel recombinase systems were discov- cells (typically fibroblasts), which are then fused with the ered, such as Nigri/nox and Panto/pox (9). Among the enucleated oocyte to restart the embryo development. The limitations of this method is the fact that it remains rather genetically modified embryos are then transferred into costly and time consuming. the oviducts of recipient animals (7). Nucleases Molecular tools for gene editing Endonucleases induce double-stranded breaks (DSB) in the DNA molecule that can later be repaired by the Recombinases, nucleases, and accessory proteins cellular DNA repair systems, via either blunt-end, non- are natural or artificially created tools for gene editing that homologous end-joining (NHEJ) or by homology-directed are used for developing powerful methods of genetic repair (HDR). In the case of NHEJ, a proportion of DSBs Table 1. Brief characteristics of available molecular gene editing tools. Tool Mechanism Advantages Limitations Recombinases Cre-LoxP, Flp-FRT, Induce recombination between target Conditional gene modification Difficult to find highly specific Nigri/nox, Panto/pox sites possible promoters, costly, and time and others consuming Nucleases ZFN Recognize a specific site on DNA Gene targeting with good efficacy Off-target activity, technical through zinc finger domains and difficulty to create ZFN modules, introduce a double-stranded break difficulty to replace large fragments of DNA, high cost TALENs Cleave DNA between TALEN A simpler and faster design Off-target activity, relatively large binding sites compared to ZFN facilitated by the size complicates the delivery creation of ‘‘TALEN library’’ CRISPR/Cas9 Cas9 is guided by RNA and cleaves Ease of use: can be adapted to Relatively large size of the protein DNA at designed sites target any DNA site by changing complex, off-target cleavage the guide RNA ZFN: zinc finger nucleases; TALENs: transcriptional activator-like effector nucleases; CRISPR/Cas9: clustered regularly interspaced short palindromic repeat/CRISPR-associated protein 9. Braz J Med Biol Res | doi: 10.1590/1414-431X20198108 Atherosclerosis models in transgenic animals 3/7 within the cellular population will be misrepaired leading to mutation p.Asn1768Asp in Scn8a gene (sodium channel heterogeneous genetic insertions or deletions at the target Nav1.6). This mutation exhibits a dominant gain of func- site. By contrast, HDR enables precise insertion of a trans- tion due to impaired channel inactivation. Researchers gene into the targeted region if the donor DNA template generated several TALEN constructs and targeting tem- contains the desired transgene flanked by sequences that plate of 4 kb genomic DNA to maximize the yield of are homologous to the regions either side of the cleavage targeted alleles. Then, two rounds of injection of both site and is co-delivered into the cell along

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