Eliminating malignant contamination from therapeutic human spermatogonial stem cells

Dovey, Serena; Valli, Hanna; Hermann, Brian P.; Sukhwani, Meena; Donohue, Joseph; Castro, Carlos; Chu, Tianjiao; Sanfilippo, Joseph S.; Orwig, Kyle E.

doi:10.1172/jci65822

Cited by 122 publications

(102 citation statements)

References 64 publications

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“…Human and monkey SSCs do not regenerate complete spermatogenesis when transplanted into mouse testes. However, they do migrate to the seminiferous tubule basement membrane and produce chains or networks of spermatogonia that persist for many months after transplantation (Hermann et al, 2009; Valli et al, 2014; Izadyar et al, 2011; Zohni et al, 2012; Nagano et al, 2001; Nagano et al, 2002; Hermann et al, 2007; Wu et al, 2009; Sadri-Ardekani et al, 2009; Sadri-Ardekani et al, 2011; Dovey et al, 2013; Clark et al, 2017; Durruthy Durruthy et al, 2014; Ramathal et al, 2014). It is not currently possible to recapitulate complete spermatogenesis from monkey or human cells using the xenotransplantation assays.…”

Section: Ssc Transplantation Bioassay In Higher Primatesmentioning

confidence: 99%

Spermatogonial stem cells and spermatogenesis in mice, monkeys and men

2018

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Continuous spermatogenesis in post-pubertal mammals is dependent on spermatogonial stem cells (SSCs), which balance self-renewing divisions that maintain stem cell pool with differentiating divisions that sustain continuous sperm production. Rodent stem and progenitor spermatogonia are described by their clonal arrangement in the seminiferous epithelium (e.g., Asingle, Apaired or Aaligned spermatogonia), molecular markers (e.g., ID4, GFRA1, PLZF, SALL4 and others) and most importantly by their biological potential to produce and maintain spermatogenesis when transplanted into recipient testes. In contrast, stem cells in the testes of higher primates (nonhuman and human) are defined by description of their nuclear morphology and staining with hematoxylin as Adark and Apale spermatogonia. There is limited information about how dark and pale descriptions of nuclear morphology in higher primates correspond with clone size, molecular markers or transplant potential. Do the apparent differences in stem cells and spermatogenic lineage development between rodents and primates represent true biological differences or simply differences in the volume of research and the vocabulary that has developed over the past half century? This review will provide an overview of stem, progenitor and differentiating spermatogonia that support spermatogenesis; identifying parallels between rodents and primates where they exist as well as features unique to higher primates.

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Section: Ssc Transplantation Bioassay In Higher Primatesmentioning

confidence: 99%

Spermatogonial stem cells and spermatogenesis in mice, monkeys and men

2018

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“…Human and mouse spermatogonia also use the same extrinsic factor—GDNF—for their growth in vitro [130]. To screen for other factors important for SSC self-renewal and differentiation, investigators can take advantage of the recent development of in vitro SSC culturing methods and the xenotransplantation assay for human SSC activity [118,121,130,132]. By utilizing the new tools that are available to the field, the transcription networks functioning in spermatogonia that promote their self-renewal and differentiation can be rapidly mapped in the near future.…”

Section: Perspectivementioning

confidence: 99%

Transcriptional control of spermatogonial maintenance and differentiation

Song

Wilkinson

2014

Seminars in Cell & Developmental Biology

110

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Spermatogenesis is a multistep process that generates millions of spermatozoa per day in mammals. A key to this process is the spermatogonial stem cell (SSC), which has the dual property of continually renewing and undergoing differentiation into a spermatogonial progenitor that expands and further differentiates. In this review, we will focus on how these proliferative and early differentiation steps in mammalian male germ cells are controlled by transcription factors. Most of the transcription factors that have so far been identified as promoting SSC self-renewal (BCL6B, BRACHYURY, ETV5, ID4, LHX1, and POU3F1) are upregulated by glial cell line-derived neurotrophic factor (GDNF). Since GDNF is crucial for promoting SSC self-renewal, this suggests that these transcription factors are responsible for coordinating the action of GDNF in SSCs. Other transcription factors that promote SSC self-renewal are expressed independently of GDNF (FOXO1, PLZF, POU5F1, and TAF4B) and thus may act in non-GDNF pathways to promote SSC cell growth or survival. Several transcription factors have been identified that promote spermatogonial differentiation (DMRT1, NGN3, SOHLH1, SOHLH2, SOX3, and STAT3); some of these may influence the decision of an SSC to commit to differentiate while others may promote later spermatogonial differentiation steps. Many of these transcription factors regulate each other and act on common targets, suggesting they integrate to form complex transcriptional networks in self-renewing and differentiating spermatogonia.

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“…in boys with leukaemia. As it was demonstrated in a rat model that transmission of leukaemia by transplanting testicular cells is possible [35], elimination of malignant cells both by cell sorting [36] and by in vitro cultures [37] may lower or even circumvent the risk for reintroducing cancer via transplantation.…”

Section: Testicular Tissue Cryopreservation In Boysmentioning

confidence: 99%

Testicular Tissue Cryopreservation

Tournaye

Verheyen

Goossens

2016

Gonadal Tissue Cryopreservation in Fertility Preservation

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Loss of spermatogonial stem cells can be associated to ageing or can be part of genetic disorders such as 47,XXY Klinefelter syndrome. However, cytotoxic therapies and/or irradiation is the main cause of germ cell loss and can disrupt spermatogenesis temporarily or permanently. These therapies are not only used to treat malignant disorders but may also be used for benign haematological conditions that need bone-marrow transplantation.Since survival rates after cancer treatment are increasing, preservation of the reproductive potential has become an important quality of life issue for both adults but also for childhood cancer survivors. Adult men who cannot bank ejaculate spermatozoa can opt to cryopreserve surgically retrieved spermatozoa, i.e. testicular sperm. Prepubertal boys cannot benefit from sperm banking, but testicular stem cell banking is being introduced into more and more clinics. This strategy should still be regarded as experimental given the lack of any report on successful transplantation and the limited safety data of this method.

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Eliminating malignant contamination from therapeutic human spermatogonial stem cells

Cited by 122 publications

References 64 publications

Spermatogonial stem cells and spermatogenesis in mice, monkeys and men

Spermatogonial stem cells and spermatogenesis in mice, monkeys and men

Transcriptional control of spermatogonial maintenance and differentiation

Testicular Tissue Cryopreservation

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