Sterile Testis Complementation with Spermatogonial Lines Restores Fertility to DAZL-Deficient Rats and Maximizes Donor Germline Transmission

Despite remarkable advances in assisted reproductive capabilities ∼4% of all couples remain involuntarily infertile. In almost half of these cases, a lack of conception can in some measure be attributed to the male partner, wherein de novo Y-chromosomal deletions of sperm-specific Deleted-in-Azoospermia (DAZ) genes are particularly prevalent. In the current study, long-term cultures of rat spermatogonial stem cells were evaluated after cryo-storage for their potential to restore fertility to rats deficient in the DAZ-like (DAZL) gene. Detailed histological analysis of DAZL-deficient rat testes revealed an apparently intact spermatogonial stem cell compartment, but clear failure to produce mature haploid gametes resulting in infertility. After proliferating >1 million-fold in cell number during culture post-thaw, as few as 50,000 donor spermatogonia transplanted into only a single testis/recipient effectively restored fecundity to DAZL-deficient rats, yielding 100% germline transmission to progeny by natural mating. Based on these results, the potency and efficacy of this donor stem cell line for restoring fertility to azoospermic rodents is currently unprecedented. Prospectively, similar successes in humans could be directly linked to the feasibility of obtaining enough fully functional spermatogonial stem cells from minimal testis biopsies to be therapeutically effective. Thus, regeneration of sperm production in this sterile recipient provides an advanced pre-clinical model for optimizing the efficacy of stem cell therapies to cure a paradoxically increasing number of azoospermic men. This includes males that are rendered infertile by cancer therapies, specific types of endocrine or developmental defects, and germline-specific de novo mutations; all of whom may harbor healthy sources of their own spermatogonial stem cells for treatment

Dominant lethal pathologies in male mice engineered to contain an X-linked DUX4 transgene

Facioscapulohumeral muscular dystrophy (FSHD) is an enigmatic disease associated with epigenetic alterations in the subtelomeric heterochromatin of the D4Z4 macrosatellite repeat. Each repeat unit encodes DUX4, a gene that is normally silent in most tissues. Besides muscular loss, most patients suffer retinal vascular telangiectasias. To generate an animal model, we introduced a doxycycline-inducible transgene encoding DUX4 and 3' genomic DNA into a euchromatic region of the mouse X chromosome. Without induction, DUX4 RNA was expressed at low levels in many tissues and animals displayed a variety of unexpected dominant leaky phenotypes, including male-specific lethality. Remarkably, rare live-born males expressed DUX4 RNA in the retina and presented a retinal vascular telangiectasia. By using doxycycline to induce DUX4 expression in satellite cells, we observed impaired myogenesis in vitro and in vivo. This mouse model, which shows pathologies due to FSHD-related D4Z4 sequences, is likely to be useful for testing anti-DUX4 therapies in FSHD

Genetic association and characterization of FSTL5 in isolated clubfoot

ACKNOWLEDGEMENTS: The Atherosclerosis Risk in Communities Study is carried out as a collaborative study supported by National Heart, Lung, and Blood Institute contracts (HHSN268201100005C, HHSN268201100006C, HHSN268201100007C, HHSN268201100008C, HHSN268201100009C, HHSN268201100010C, HHSN268201100011C, and HHSN268201100012C). The authors thank the staff and participants of the ARIC study for their important contributions. Funding for GENEVA was provided by National Human Genome Research Institute grant U01HG004402 (E.Boerwinkle). We thank H. Hobbs and J. Cohen for contributing control samples for replication genotyping, Nadav Ahituv for sharing RNA-seq data for both bat and mouse embryonic limb buds, Tommy Hyatt for designing the custom genotyping assay, and members of the UT Southwestern Transgenic Core facility, including John Ritter, Mylinh Nguyen, and Robert Hammer. Publicly available mouse embryonic expression analysis results were provided online at https://oncoscape.v3.sttrcancer.org/atlas.gs.washington.edu.mouse.rna/landing (24). The authors acknowledge the contributions and support of the Center for Excellence in Clubfoot Research at Scottish Rite for Children, including Shawne Faulks and Kristhen Atala. Fstl5 mutant rats were produced by the NIH Mutant Rat Resource at UT Southwestern Medical Center (R24RR03232601, R24OD011108, R01HD036022, and (5R01HD053889). This study was supported by funding from the Scottish Rite for Children Research Fund (J.J.R.), Shriners Hospital for Children (J.T.H), and the National Institutes of Health award R01HD043342 (J.T.H.).Peer reviewedPostprin

Dominant lethal pathologies in male mice engineered to contain an X-linked DUX4 transgene

Facioscapulohumeral muscular dystrophy (FSHD) is an enigmatic disease associated with epigenetic alterations in the subtelomeric heterochromatin of the D4Z4 macrosatellite repeat. Each repeat unit encodes DUX4, a gene that is normally silent in most tissues. Besides muscular loss, most patients suffer retinal vascular telangiectasias. To generate an animal model, we introduced a doxycycline-inducible transgene encoding DUX4 and 3' genomic DNA into a euchromatic region of the mouse X chromosome. Without induction, DUX4 RNA was expressed at low levels in many tissues and animals displayed a variety of unexpected dominant leaky phenotypes, including male-specific lethality. Remarkably, rare live-born males expressed DUX4 RNA in the retina and presented a retinal vascular telangiectasia. By using doxycycline to induce DUX4 expression in satellite cells, we observed impaired myogenesis in vitro and in vivo. This mouse model, which shows pathologies due to FSHD-related D4Z4 sequences, is likely to be useful for testing anti-DUX4 therapies in FSHD

A new mouse model for FSHD

To understand the effect of DUX4 in vivo, and to generate a model in which to test anti-DUX4 therapeutics, we have introduced a doxycycline (dox)-inducible transgene encoding DUX4 and 3′ genomic DNA into a euchromatic region of the mouse X chromosome. Although this mouse was intended to provide doxycycline-inducible phenotypes, through expression of DUX4, we found that the transgene alone, without dox, was lethal in males. Females were runted and presented a skin pathology in the absence of dox. This is due to low level leaky expression of the DUX4 gene, as transcript can be detected by PCR in most tissues with the most consistent detection in neural tissues including retina, and in testis. We could not detect the protein in the absence of dox. Although males are not usually born live, occasional males survive to term. These animals are much more severely affected than their female counterparts, and remarkably, display a retinal vascular pathology similar to that seen in FSHD. In addition, they show a defect in spermatogenesis. Muscles from these animals were composed of smaller fibers and were weaker, but proportionally so, and no dystrophy was present prior to death, invariably before 6 weeks of age. We performed ex vivo culture experiments with myoblasts and muscle fibroadipogenic progenitors (FAPs) isolated from the iDUX4 males, and found that high levels of dox caused cell death of myoblasts and was growth inhibitory to fibroblasts. Low non-toxic levels of dox impaired differentiation of myoblasts in vitro, but had no effect on adipogenic differentiation of muscle FAPs. To evaluate the effect of DUX4 expression during regenerative repair in vivo, we crossed the Pax7-ZsGreen satellite cell marker into this strain and performed transplants of satellite cells from live-born males into female NSG-mdx4Cv mice,and treated recipients with varying doses of dox. By using dystrophin staining to quantify engraftment, we observed a consistent and easily quantifiable dose-dependent reduction in regeneration by transplanted satellite cells. These data show that DUX4 expression, even at low levels, is inhibitory to regenerative myogenesis. We further propose that the quantification of donor-derived myofibers generated by transplanted iDUX4 satellite cells can serve as a useful in vivo test system for therapeutics directed against the DUX4 protein or transcript