Abstract
We established rat embryonic stem (ES) cell lines from a double transgenic rat line which harbours CAG-GFP for ubiquitous expression of GFP in somatic cells and Acr3-EGFP for expression in sperm (green body and green sperm: GBGS rat). By injecting the GBGS rat ES cells into mouse blastocysts and transplanting them into pseudopregnant mice, rat spermatozoa were produced in mouse←rat ES chimeras. Rat spermatozoa from the chimeric testis were able to fertilize eggs by testicular sperm extraction combined with intracytoplasmic sperm injection (TESE-ICSI). In the present paper, we disrupted rat hypoxanthine-guanine phosphoribosyl transferase (Hprt) gene in ES cells and produced a Hprt-disrupted rat line using the mouse←rat ES chimera system. The mouse←rat ES chimera system demonstrated the dual advantages of space conservation and a clear indication of germ line transmission in knockout rat production.
Similar content being viewed by others
Introduction
The investigation of gene functions has intensified following completion of genome projects in many species. A significant number of gene disrupted mouse lines have been produced using ES cells and the homologous recombination technique, for example, helping clarify the basic biology while serving as animal models for human diseases1. As a result, mice have replaced rats as the most popularly used experimental animal.
However, rats retain advantages over mice as experimental animals2,3. Their bigger body size facilitates experimental operations and repeated collection of blood samples. Moreover, rats are better suited to behavioural studies as they learn tricks, such as pressing a lever to get alcohol, more easily than mice. Despite the potential demand for gene disruption in rats, the isolation of rat ES cells was unsuccessful for many years. In 2008, Buehr and Li independently used MEK and GSK3 inhibitors as key factors in establishing the first rat ES cells4,5. Even today, however, there are few reports on gene disrupted rats involving ES cells6,7,8,9,10. The reason is unclear, but we presume it is more challenging to produce knockout (KO) rat lines than mice lines. Firstly, rat embryos are difficult to handle in vitro11. Secondly, it seemed that rat ES cell karyotypes became unstable during passages in vitro5. Thirdly, rats require greater space in animal facilities. If the efficiency of germline transmission (GLT) for KO rat production is low, the need for more animals and further space may hinder continued experiments.
Previously, we reported a successful production of a mouse←rat ES chimera (here, the ‘←’ indicates the rat ES cells were injected into mouse blastocysts to make chimera using mice as recipient mothers) and a contribution of rat ES cells to germ line cells12. In this system, preparation of rat embryos for production of rat spermatozoa is unnecessary. Therefore, animal and space requirements were identical to those for the gene disruption experiment in the mice. This enabled an enhanced experimental scale, in case the efficiency of GLT of rat ES cells was low. Both mouse and rat spermatozoa were produced in the chimeric testes. However, the shape of the sperm heads differ in rats and mice, and the utilization of GFP facilitated selection of rat spermatozoa and subsequent microinsemination13,14.
With these strategies in mind, we chose hypoxanthine-guanine phosphoribosyl transferase (Hprt) as a target gene and sought to demonstrate the new method to produce a gene-disrupted rat line using the mouse←rat ES chimera system. Hprt was chosen because the Lesch-Nyhan syndrome (LNS) was known to be caused by HPRT gene mutation in human. However, when the Hprt-deficient mice were made, they failed to show characteristic nervous disorders exhibited in LNS. One purpose of this study was to examine whether Hprt gene disruption in rats evokes self-injurious behaviour (SIB), as rats are better suited to behavioural studies and some drugs induce SIB in rats but not in mice15.
Results
Establishment of GFP-tagged rat ES cell lines
We used CAG-EGFP16 and the Acr3-EGFP17 to produce double transgenic F344 rat lines. All six established transgenic rat lines F344-Tg (CAG/Acr3-EGFP) which we abbreviated as GBGS (green body, green sperm) had ubiquitous fluorescence signal from somatic cells and testicular spermatozoa (Fig. 1 and Supplementary Fig. S1). We chose the rGBGS#6 rat line showing the strongest GFP signals for the establishment of the ES cell line.
ES cell lines with a normal karyotype in over 65% of the cells were established from F344-GBGS inbred (three XY-type ES cell lines) and Wistar/F344-GBGS hybrid (three XY-type ES cell lines) (Supplementary Table S1) rats. The stemness was examined by the expression of Oct-4, Nanog and SSEA1 (Fig. 2a). Teratoma formations were observed after injecting the ES cell lines into the SCID mice testes. All of these established cell lines were shown to have the potential to differentiate into all three germ layers (Fig. 2b).
Production of rat spermatozoa in the mouse←rat ES chimera
To evaluate the competency for GLT in chimeric testes, we injected six lines of rat ES cells into E3.5 mouse blastocysts and nine chimeric males were obtained from each ES cell line (Fig. 3a,b and Supplementary Table S1). None of the ES cell lines derived from F344-GBGS contributed to germ cells (Supplementary Table S1). However, two out of the three ES cell lines from Wistar/F344-GBGS contributed in testicular germ cells and rat spermatozoa were formed in chimeric testes (Fig. 3c–e, Supplementary Table S1).
We chose one of the Wistar/F344-GBGS ES cell lines (rGBGS-ES-104) for the following experiments, as this cell line showed the highest normal karyotype rate and the most efficient GLT potency which was retained even at 16 passages (Supplementary Table S1). In the next experiment, we examined if such rat spermatozoa from the chimeric testis could fertilize eggs by TESE-ICSI13,14. As a result, two offspring were obtained from 93 TESE-ICSI fertilized eggs (Fig. 3f and Supplementary Table S2).
Production of Hprt-disrupted rat using the mouse←rat ES chimera
Since the rat spermatozoa from the chimeric testes were shown to have an ability to produce normal pups, we applied this method to establish a gene-disrupted rat line (Supplementary Fig. S2). We disrupted X-chromosome linked Hprt from ES cell lines in the conventional manner (Fig. 4a). After G418 and GANC selection, the cells were further treated with 6-thioguanine to eliminate the wild type cells with HPRT activity. We obtained three Hprt-targeted clones with normal karyotypes in more than 70% of the cells (Supplementary Table S3).
Mouse←rat ES chimeras were produced using three ES cell lines (Fig. 4b) and we found rat spermatozoa in chimeric testes from one Hprt-targeted clone (Fig. 4c, and Supplementary Table S4). The offspring were generated by TESE-ICSI from these spermatozoa (Fig. 4d) and the disruption of Hprt gene in the pups was confirmed by PCR genotyping (Fig. 4e and Supplementary Table S2). As expected, all of the female pups had the Hprt-KO allele, whereas none of the males had it.
Phenotype analysis of Hprt-disrupted rats
The Hprt-heterozygous mutant female rats were mated with F344 male rats and offspring were genotyped by PCR (Fig. 5a). As a result, we obtained 26 (22%) Hprt+/Y and 21 (18%) Hprt−/Y males, as well as 37 (32%) Hprt+/+ and 32 (28%) Hprt+/− females, indicating targeted Hprt allele was inherited at a normal Mendelian frequency.
The disappearance of HPRT protein in liver and brain, and the demise of HPRT activity (Hprt+/Y 55.9 ± 3.0, vs. Hprt−/Y, 2.7 ± 0.6 nmol/ml/h; P < 0.01) in the extract of brain homogenate were shown in Hprt−/Y rats (Fig. 5b,c). The Hprt−/Y rats were maintained for more than a year, but they showed healthy, with no signs of abnormality in their behaviour, e.g. SIB-like behaviours (Fig. 5d).
Discussion
Lesch-Nyhan syndrome (LNS) is known to be caused by a mutation of the HPRT gene leading to a deficiency or complete absence of HPRT enzyme activity. LNS patients suffer from an overproduction of uric acid which may lead to the development of uric acid crystals or stones in the kidneys, ureters, or bladder. Disorders of the nervous system and behavioural problems such as self-injury behaviour (SIB) are also common symptoms. Hprt-deficient mice have been produced to establish an animal model for this syndrome, but these animals exhibit none of the neurobehavioral abnormalities including SIB18. One could argue that the presence of uricase in rodents could be the cause of this difference, but the occurrence of SIB has not been affected in LNS patients when the uric acid level is lowered by xanthine oxidase inhibitors19.
Studies of human brains have suggested that the neurological symptoms of LNS could be related to dysfunction of the dopaminergic neurotransmitter system20,21. Although, the Hprt-disrupted mice showed lowered dopamine levels in the brain, SIB-like behaviour was not observed22. On the other hand, a forced reduction of dopamine with 6-hydroxydopamine in rats during their development is used as a model of the dopamine deficiency in LNS23.
Combining these facts together, we produced Hprt-disrupted rat, exploring possible production of an animal model for LNS. However, the Hprt-disrupted rats did not show any SIB-like behaviour or detrimental effect on health in the environment of our animal facilities. The role of Hprt gene in rodents (at least in mice and rats) seemed to be less essential than in human.
It is known that rat spermatogonia injected into mouse testes are supported by mouse Sertoli cells and undergo spermatogenesis to produce rat spermatozoa24. The fertilizing ability of these spermatozoa was proven by producing pups by microinsemination25. A new gene disruption method using rat germline stem (GS) cells has been explored using this xenogeneic transplantation system. Homologous recombination was successfully demonstrated in rat GS cells, but no offspring were obtained using rat spermatozoa from mouse testis even though the original rat GS cells produced fertile spermatozoa26. As the researchers also speculated, the karyotype of rat cells in culture, especially when exposed to a low serum concentration, is prone to develop abnormalities. In case of the rat spermatozoa derived from mouse←rat chimeric testes, it was reported that rat iPS cell-derived spermatozoa yielded offspring27. However, fertilizing ability of spermatozoa after homologous recombination was not examined. This is the first report that homologous recombined rat spermatozoa could be generated in the mouse←rat ES chimeric testis.
We previously reported that using a Acr3-EGFP transgene enabled observation of accumulated EGFP in sperm acrosome17. However, Tsukiyama et al. reported that EGFP was not detectable in rat spermatozoa derived from the mouse←rat iPSC chimeric testis using CAG/Acr3-EGFP27. In our experiment, we established ES cell lines from CAG/Acr3-EGFP double transgenic rats confirmed to have green fluorescent in acrosome. This enabled us to identify and retrieve rat spermatozoa despite their small number among countless mouse spermatozoa in the chimeric testis.
The phenotypes of human disease can sometimes be reproduced in KO rat more resembled manner than in KO mouse28,29. Therefore, if establishing a human disease animal model in mouse is difficult, it merits a try in rat. Nevertheless, reports of KO rat using ES cells through homologous recombination remain few6,7,8,9,10.
The reason for this has not been analysed sufficiently, but our experience and previous reports5,6,26 suggest that it could be attributable to low GLT ratio derived from fragile characteristics of rat ES cells in vitro cultivation. The lower the GLT ratio, the more mating pairs are required. It may also require longer breeding periods, labour, and cost. Altogether these challenge production of gene-disrupted rat. One advantage of our mouse←rat ES chimera system is simple, early-stage identification of GLT by direct observation of rat spermatozoa in whole testis occurring as early as 10 weeks of age. Another advantage is that required animal room space almost equals that of mouse KO experiments.
Recent, genome editing technologies such as ZFNs, TALENs, and the CRISPR/Cas system function as powerful tools in production of gene modified animals30,31. However, for complicated gene modifications such as knock-in, conditional knockout, gene trap and chromosome engineering, ES cells may retain advantages in large-scale experiments to detect rather rare events.
Our chimeric testis method described here provides a new practical method to produce a gene-manipulated rat.
Methods
Animals
All animal experiments were conducted in accordance with the guidelines of “Animal experiment rules” established by the Research Institute for Microbial Diseases, Osaka University, and were approved by the Animal Care and Use Committee of the Research Institute for Microbial Diseases, Osaka University. F344, and SD rats, ICR and BDF1 mice were purchased from Japan SLC, Inc. Severe combined immunodeficiency (SCID) mice (BALB/c JHan Hsd-Prkdc scid.) were purchased from Clea Japan, Inc. Wistar rats were purchased from CHARLES RIVER LABORATORIES JAPAN, INC.
The double transgenic rat lines were produced by injecting a mixture of two transgenes (CAG-EGFP and Acr3-EGFP)16,17 into the pronucleus of F344 fertilised eggs.
Construction of the targeting vector
The rat Hprt gene consists of nine exons and the targeting vector was designed to remove a part of the third exon of Hprt (Fig. 4a). A targeting vector was constructed using pNT1.1 [ http://www.ncbi.nlm.nih.gov/nuccore/JN935771]32. For Hprt gene disruption, a 2.7 kb NotI-XhoI fragment as a short arm and a 5.7 kb KpnI-XbaI fragment as a long arm were obtained by PCR amplification using genomic DNA derived from F344 as a template. The PCR primers used were (5′-3′): AAGCGGCCGCATTAGTGATGATGAACCAGGTTATGACC and TTCATGACATCTCGAGCAAGTCTTTCAGTC for the short arm (SA) and AAGGTACCTGTAGATTTTATCAGACTGAAGAGCTACTG and CTTTCCAGTTAAAGTTGAGAGATCATCTCC for the long arm (LA). DNA fragments were amplified using KOD FX (TOYOBO) for 40 cycles under the following conditions: 94 °C for 30 sec, 68 °C for 3 min (SA) or 8 min (LA). These two fragments were inserted into a pNT1.1 vector and the targeting construct was linearized with NotI.
Generation of Hprt-disrupted ES cells and genotyping
Rat ES cells were established and maintained in 2i containing medium as described12. For homologous recombination, 1.6 × 107 rat ES cells were electroporated with 50 μg of linearized DNA in a total volume of 800 μl using a Bio-Rad Gene Pulser (250 V and 500 lF; Bio-Rad, Foster City, CA, USA). They were then plated onto 1% matrigel coated 100-mm tissue culture dishes plated with SNL cells in N2B27-2i medium. The rat ES cells were treated with 75 μg/ml of G418 at two days and 4 μM of GANC at four days after electroporation for positive/negative selection. Ten days after electroporation, 284 survival colonies were retrieved and cultured with 10 μM 6-thioguanine for obtaining of Hprt-disrupted clone (17 clones). The correct targeting was confirmed by PCR analysis for homologous recombination on both the 3′ and 5′ ends of the targeting vector.
Screening primers for ES cell clones were (5′-3′): GTATGCTGGGCTCTGGACATAC and GCCTTCTATCGCCTTCTTGACGAGTTCTTC for the short arm and CCGGTGGATGTGGAATGTGTGCGAGGCC and CTTTCCAGTTAAAGTTGAGAGATCATCTCC for the long arms. DNA fragments were amplified using Ex Taq (Takara) and Ampdirect (SHIMADZU) for 40 cycles under the following conditions: 94 °C for 30 sec, 68 °C for 3 min (SA) or 8 min (LA).
Genotyping primers for the detection of Hprt-disrupted rat were (5′-3′): TAGTCCAGGCTGTCTTTCAACTC (rHPRT-F1 for typing), GCTTTAATGTAATCCAGCAGGTCA (rHPRT-R1 for typing) and ATCTGGACGAAGAGCATCAG (Neo-Pr114 for typing). DNA fragments were amplified using KOD FX (TOYOBO) for 40 cycles under the following conditions: 94 °C for 30 sec, 65 °C for 30 sec and 72 °C for 1 min.
Production of the mouse←rat ES chimera
The mouse←rat ES chimeras were produced as described12. Briefly, Two- or four-cell stage embryos were collected from E1.5 pregnant mice which were BDF1 females crossbred with ICR males. After incubation for 48 hours, four to six established rat ES cells were injected into each mouse blastocyst. Subsequently, mouse←rat ES chimeric blastocysts were transferred into the uterine horn of E2.5 pseudopregnant ICR mice. Mouse←rat ES chimeras were recovered by natural delivery on E19.5 or by Caesarean section on E19.5, and were identified by GFP fluorescence and coat colour.
Microinsemination
For TESE-ICSI, male mouse←rat ES chimeric testes were obtained from animals aged ten weeks or more. After removing the tunica albuginea, seminiferous tubule fragments showing EGFP signal in the mouse←rat ES chimera were carefully dissected using fine forceps under the fluorescence microscope. GFP-positive spermatozoa extruded from the isolated tubules were suspended in Hepes-mR1ECM medium. Their unique head shapes identified rat spermatozoa. Rat spermatozoa were subsequently microinjected into oocytes as described previously14. On the same day, constructed eggs were transferred into the oviductal ampulla of E0.5 pseudopregnant SD rats. Offspring were recovered by natural delivery on E21.5 to E22.5 or by Caesarean section on E22.5.
Additional Information
How to cite this article: Isotani, A. et al. Generation of Hprt-disrupted rat through mouse←rat ES chimeras. Sci. Rep. 6, 24215; doi: 10.1038/srep24215 (2016).
References
Guan, C., Ye, C., Yang, X. & Gao, J. A review of current large-scale mouse knockout efforts. Genesis 48, 73–85 (2010).
Jacob, H. J. & Kwitek, A. E. Rat genetics: attaching physiology and pharmacology to the genome. Nat Rev Genet 3, 33–42 (2002).
Mogil, J. S. Animal models of pain: progress and challenges. Nat Rev Neurosci. 10, 283–294 (2009).
Buehr, M. et al. Capture of authentic embryonic stem cells from rat blastocysts. Cell 135, 1287–1298 (2008).
Li, P. et al. Germline competent embryonic stem cells derived from rat blastocysts. Cell 135, 1299–1310 (2008).
Tong, C., Li, P., Wu, N. L., Yan, Y. & Ying, Q. L. Production of p53 gene knockout rats by homologous recombination in embryonic stem cells. Nature 467, 211–213 (2010).
Yamamoto, S. et al. Derivation of rat embryonic stem cells and generation of protease-activated receptor-2 knockout rats. Transgenic Res. 21, 743–755 (2012).
Kawamata, M. & Ochiya, T. Two distinct knockout approaches highlight a critical role for p53 in rat development. Sci Rep. 2, 945 (2012).
Uenoyama, Y. et al. Lack of pulse and surge modes and glutamatergic stimulation of luteinising hormone release in Kiss1 knockout rats. J Neuroendocrinol. 27, 187–197 (2015).
Yamamoto, S. et al. Efficient gene-targeting in rat embryonic stem cells by CRISPR/Cas and generation of human kynurenine aminotransferase II (KAT II) knock-in rat. Transgenic Res 24, 991–1001 (2015).
Kato, M., Ishikawa, A., Hochi, S. & Hirabayashi, M. Donor and recipient rat strains affect full-term development of one-cell zygotes cultured to morulae/blastocysts. J Reprod Dev. 50, 191–195 (2004).
Isotani, A., Hatayama, H., Kaseda, K., Ikawa, M. & Okabe, M. Formation of a thymus from rat ES cells in xenogeneic nude mouse ↔ rat ES chimeras. Genes Cells 16, 397–405 (2011).
Ogura, A. & Yanagimachi, R. Spermatids as male gametes. Reprod Fertil Dev. 7, 155–158, Discussion 158–159 (1995).
Hirabayashi, M., Kato, M., Aoto, T., Ueda, M. & Hochi, S. Rescue of infertile transgenic rat lines by intracytoplasmic injection of cryopreserved round spermatids. Mol Reprod Dev. 62, 295–299 (2002).
Kasim, S. & Jinnah, H. A. Pharmacologic thresholds for self-injurious behavior in a genetic mouse model of Lesch-Nyhan disease. Pharmacol Biochem Behav. 73, 583–592 (2002).
Okabe, M., Ikawa, M., Kominami, K., Nakanishi, T. & Nishimune, Y. ‘Green mice’ as a source of ubiquitous green cells. FEBS Lett. 407, 313–319 (1997).
Nakanishi, T. et al. Real-time observation of acrosomal dispersal from mouse sperm using GFP as a marker protein. FEBS Lett. 449, 277–283 (1999).
Kuehn, M. R., Bradley, A., Robertson, E. J. & Evans, M. J. A potential animal model for Lesch-Nyhan syndrome through introduction of HPRT mutations into mice. Nature 326, 295–298 (1987).
Torres, R. J., Prior, C. & Puig, J. G. Efficacy and safety of allopurinol in patients with hypoxanthine-guanine phosphoribosyltransferase deficiency. Metabolism 56, 1179–1186 (2007).
Wong, D. F. et al. Dopamine transporters are markedly reduced in Lesch-Nyhan disease in vivo . Proc Natl Acad Sci USA 93, 5539–5543 (1996).
Ernst, M. et al. Presynaptic dopaminergic deficits in Lesch-Nyhan disease. N Engl J Med. 334, 1568–1572 (1996).
Egami, K. et al. Basal ganglia dopamine loss due to defect in purine recycling. Neurobiol Dis. 26, 396–407 (2007).
Breese, G. R., Criswell, H. E., Duncan, G. E. & Mueller, R. A. A dopamine deficiency model of Lesch-Nyhan disease–the neonatal-6-OHDA-lesioned rat. Brain Res Bull 25, 477–484 (1990).
Clouthier, D. E., Avarbock, M. R., Maika, S. D., Hammer, R. E. & Brinster, R. L. Rat spermatogenesis in mouse testis. Nature 381, 418–421 (1996).
Shinohara, T. et al. Rats produced by interspecies spermatogonial transplantation in mice and in vitro microinsemination. Proc Natl Acad Sci USA 103, 13624–13628 (2006).
Kanatsu-Shinohara, M. et al. Homologous recombination in rat germline stem cells. Biol Reprod 85, 208–217 (2011).
Tsukiyama, T., Kato-Itoh, M., Nakauchi, H. & Ohinata, Y. A comprehensive system for generation and evaluation of induced pluripotent stem cells using piggyBac transposition. Plos One 9, e92973 (2014).
Mashimo, T. et al. Generation of knockout rats with X-linked severe combined immunodeficiency (X-SCID) using zinc-finger nucleases. Plos One 5, e8870 (2010).
Nakamura, K. et al. Generation of muscular dystrophy model rats with a CRISPR/Cas system. Sci Rep. 4, 5635 (2014).
Tesson, L. et al. Knockout rats generated by embryo microinjection of TALENs. Nat Biotechnol. 29, 695–696 (2011).
Yoshimi, K., Kaneko, T., Voigt, B. & Mashimo, T. Allele-specific genome editing and correction of disease-associated phenotypes in rats using the CRISPR-Cas platform. Nat Commun 5, 4240 (2014).
Tokuhiro, K., Ikawa, M., Benham, A. M. & Okabe, M. Protein disulfide isomerase homolog PDILT is required for quality control of sperm membrane protein ADAM3 and male fertility [corrected]. Proc Natl Acad Sci USA 109, 3850–3855 (2012).
Acknowledgements
We thank NPO Biotechnology Research and Development for technical assistance. This work was supported by JSPS KAKENHI Grant Number 24500490 and 24240066.
Author information
Authors and Affiliations
Contributions
A.I. and M.O. performed most experiments, assisted by M.I., who constructed the targeting vector, and K.Y., who performed microinsemination. A.I., M.I., and M.O. analysed the data. A.I. and M.O. wrote the manuscript and all authors discussed the results and commented on the manuscript.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing financial interests.
Supplementary information
Rights and permissions
This work is licensed under a Creative Commons Attribution 4.0 International License. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in the credit line; if the material is not included under the Creative Commons license, users will need to obtain permission from the license holder to reproduce the material. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/
About this article
Cite this article
Isotani, A., Yamagata, K., Okabe, M. et al. Generation of Hprt-disrupted rat through mouse←rat ES chimeras. Sci Rep 6, 24215 (2016). https://doi.org/10.1038/srep24215
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/srep24215
This article is cited by
-
Blastocyst complementation using Prdm14-deficient rats enables efficient germline transmission and generation of functional mouse spermatids in rats
Nature Communications (2021)
-
Retrovirus-Mediated Transfection of the Tissue-type Plasminogen Activator Gene Results in Increased Thrombolysis of Blood Clots
Biochemical Genetics (2019)