Retinoic Acid Receptors Control Spermatogonia Cell-Fate and Induce Expression of the SALL4A Transcription Factor
Differentiation of spermatozoa from immature germ cells, called spermatogonia, critically depends on retinoic acid (ATRA), the active metabolite of vitamin A that acts though binding to nuclear receptors called RXR and RAR. To understand the mechanism by which ATRA control germ cell differentiation, we generated mice simultaneously lacking all RXR or all RAR specifically in spermatogonia. From their phenotypic analysis, we demonstrate that meiosis does not require a RAR/RXR-dependent pathway in germ cells and propose that this process is either ATRA-independent or requires an ATRA signal originating from somatic cells. We also show that RXR, in the form of dimers with RAR, can drive spermatogonia differentiation through binding to a regulatory region located in the Sall4 gene. This finding is significant, as the transcription factor encoded by Sall4 is known to regulate the expression of KIT, a key tyrosine kinase receptor which is frequently deregulated in testicular cancer.
Published in the journal:
. PLoS Genet 11(10): e32767. doi:10.1371/journal.pgen.1005501
Category:
Research Article
doi:
https://doi.org/10.1371/journal.pgen.1005501
Summary
Differentiation of spermatozoa from immature germ cells, called spermatogonia, critically depends on retinoic acid (ATRA), the active metabolite of vitamin A that acts though binding to nuclear receptors called RXR and RAR. To understand the mechanism by which ATRA control germ cell differentiation, we generated mice simultaneously lacking all RXR or all RAR specifically in spermatogonia. From their phenotypic analysis, we demonstrate that meiosis does not require a RAR/RXR-dependent pathway in germ cells and propose that this process is either ATRA-independent or requires an ATRA signal originating from somatic cells. We also show that RXR, in the form of dimers with RAR, can drive spermatogonia differentiation through binding to a regulatory region located in the Sall4 gene. This finding is significant, as the transcription factor encoded by Sall4 is known to regulate the expression of KIT, a key tyrosine kinase receptor which is frequently deregulated in testicular cancer.
Introduction
Spermatogenesis is a tightly regulated, cyclical, cell differentiation process, taking place in the seminiferous epithelium of the testis and yielding mature spermatozoa from stem cells. Spermatogonia in the single cell state, known as A single (As) spermatogonia, have traditionally be considered as the main spermatogonia stem cells in the mouse. Upon division, As spermatogonia give rise either to two new single cells or to a pair of daughter cells called A paired (Apr) spermatogonia that do not complete cytokinesis and remain connected through an intercellular bridge. The Apr spermatogonia divide further to form syncytial chains of 4 to 16 A aligned (Aal) spermatogonia [1]. Collectively, As, Apr and Aal (referred to as “undifferentiated spermatogonia”) are present throughout the seminiferous epithelial cycle and retain stem cell properties. Subsequently, Aal cells differentiate without mitotic division into A1 spermatogonia. Five cell divisions follow A1 formation, forming successively A2, A3 A4, In (intermediate) and B spermatogonia. Collectively, A1 to B spermatogonia (referred to as “differentiating spermatogonia”) express the prototypic marker KIT [2,3] and differentiate at given stages of the seminiferous epithelium cycle, each step of differentiation being associated with a mitotic division [4].
In rodent, all-trans retinoic acid (ATRA), the biologically active form of vitamin A (retinol) is instrumental to spermatogonia differentiation as assessed from vitamin A deficiency studies. In mice fed a vitamin A-deficient (VAD) diet from weaning onwards, all spermatogonia progressively arrest at the Aal-A1 transition, yielding seminiferous tubules that contain only Aal spermatogonia and Sertoli cells. Systemic administration of ATRA to VAD mice reinitiates spermatogenesis from mitotically-arrested Aal spermatogonia, resulting in their massive differentiation into spermatogonia expressing KIT, the marker of the Aal-A1 transition [2], and resuming their proliferation/differentiation [5,6]. The molecular mechanism through which ATRA controls Kit expression is however not yet fully elucidated. Characterizing this mechanism is important not only in the field of reproduction, but also for a better understanding of the biology of testicular germ cell tumors as KIT is also frequently deregulated in seminomas [7].
In cells, ATRA binds to and activates nuclear receptors (RARA, RARB and RARG), which are ligand-dependent transcriptional regulators. They usually function in the form of heterodimers with rexinoid receptors (RXRA, RXRB and RXRG) to control expression of ATRA-target genes through binding to specific sites located in genomic regulatory regions and called retinoic acid response elements (RARE) [8]. In the adult mouse testis, RARG cell-autonomously transduces an ATRA signal required for spermatogonia differentiation. Accordingly, the testes abnormalities observed upon deletion of Rarg either in the whole organism or specifically in spermatogonia in sexually mature males are similar to those present in VAD males [9]. As to RXR isotypes, the situation is contrasted. Our in situ hybridization (ISH) analyses failed to detect any of them in spermatogonia in the normal mouse testis [10], while another study evidenced RXRA in spermatogonia by immunohistochemistry (IHC) [11]. Thus, either RXR is absent and therefore dispensable for RAR functioning in spermatogonia, as it is the case in Sertoli cells [12], or RXRA is required but its expression level in spermatogonia too low to be detected by ISH.
To discriminate between these two possibilities, we have generated mice lacking all RXR isotypes specifically in spermatogonia from PN5 onwards and analyzed their phenotype. We demonstrate that ablation of all Rxr genes arrests differentiation of some spermatogonia at the Aal-A1 transition and recapitulates the full set of defects characteristic of the vitamin A deficiency-induced testis degeneration. We further show that efficient ablation of the 3 Rar genes in spermatogonia using the same genetic approach resembles ablation of the 3 Rxr genes. Importantly, some A1 spermatogonia still differentiate in these mutants, indicating the existence of a mechanism allowing the Aal to A1 transition independently of RAR/RXR in germ cells. Along these lines, both meiotic and post-meiotic cells devoid of RAR or RXR are also produced, in contrast to the situation when ATRA synthesis is impaired [13]. We propose that paracrine signals emanating from and transduced in Sertoli cells by ATRA-activated RARA stimulate some Aal spermatogonia to become A1 and trigger entry into meiosis. We finally provide evidence that RXR and RAR bind to the same Sall4 regulatory region to control ATRA-dependent expression of SALL4A in the RAR/RXR-dependent spermatogonia. As SALL4A is known to impair ZBTB16-mediated Kit repression [14], our study provides novel insights into the molecular mechanism by which ATRA could control KIT expression, and thereby the differentiation of Aal into A1 spermatogonia in vivo.
Results and Discussion
The ATRA signal is generally transduced by RAR/RXR heterodimers, notably during mouse embryonic development [15]. However, it can also be relayed by RAR independently of RXR, as it is the case in Sertoli cells [12]. Analysis by reverse transcription (RT) coupled to quantitative PCR (qPCR) of mRNA extracted from fluorescent-activated cell sorting (FACS) purified spermatogonia [13] showed that Rxra and Rxrb mRNA were present in these cells. Thus, contrary to our previous thoughts [10] but in agreement with IHC analyses [11], RXR are actually present in spermatogonia and could well be necessary for their ATRA-induced differentiation. To test for this possibility, we generated mutant mice lacking all three RXR isotypes in undifferentiated spermatogonia and their descendants (hereafter called Rxra;b;gSpg–/– mutants) using Tg(Stra8-cre)1Reb transgene [16]. In this transgenic line, Cre-mediated ablation occurs as early as post-natal day 3 (PN3), as assessed using a reporter assay (S1 Fig) and in agreement with previous reports [14,16]. The crosses also generated control males devoid of the Cre transgene and carrying loxP-flanked alleles of Rxra, Rxrb and Rxrg. They did not display testis defects and were hereafter referred to as control mice.
Loss of RXR in undifferentiated spermatogonia yields age-related testis degeneration
The different generations of germ cells form cellular associations of fixed composition called epithelial stages. In control testes only the twelve normal epithelial stages (I–XII) [17] were identified (Fig 1A). In contrast, analysis of 12-week-old Rxra;b;gSpg–/– mutant testes (n = 5), revealed that, aside from normal epithelial stages (Fig 1C), 36.3 ± 9.6% of the tubule sections exhibited a degenerated seminiferous epithelium (Fig 1B) either lacking a large proportion of germ cells (T3) or containing only spermatogonia and Sertoli cells (T4). In addition, 17.8 ± 3.4% of the tubule sections lacked, around their entire circumference, either one or two generations of germ cells, yielding abnormal variants of the epithelial stages (T2). The missing germ cell layers included: preleptotene spermatocytes (Fig 1E and 1G), pachytene spermatocytes (Fig 1D and 1H), and/or round spermatids (Fig 1F and 1H). Thus, germ cell differentiation appeared altered in Rxra;b;gSpg–/– mutants. Analysis of other combinations of compound mutants at the age of 12 weeks revealed that the pathological phenotype was generated solely upon the simultaneous ablation of Rxra and Rxrb (Fig 2). This indicates that both RXRA and RXRB exert redundant functions in spermatogonia, while RXRG is dispensable. One year-old controls (n = 4) displayed only normal germ cell associations, whereas mutants (n = 4) displayed tubule sections containing only Sertoli cells and spermatogonia (Fig 1I and 1J). The latter expressed molecular markers of undifferentiated spermatogonia such as Gfra1 and Zbtb16 [3,18], but not of differentiating spermatogonia such as Kit and Stra8 [2,19] (Fig 3A–3H).
Ablation of all Rar in spermatogonia yields age-related testis degeneration resembling that induced by loss of RXR
The histological defects displayed by Rxra;b;gSpg–/– mutants appeared to be much more severe than those observed when Rarg and Rara genes are deleted using the Tg(Neurog3-cre)24Syos transgene [9]. This raised the possibility that RXR isotypes could be instrumental to some aspects of spermatogonia differentiation, independently of RARG and RARA. To test for this hypothesis, we analyzed the outcome of deleting Rar genes in spermatogonia by means of the same Tg(Stra8-cre)1Reb transgene. Accordingly, mice carrying loxP-flanked alleles of Rara, Rarb and Rarg were crossed with Tg(Stra8-cre)1Reb mice to generate Rara;b;gSpg–/– mutants and their controls.
In 12 week-old Rara;b;gSpg–/– mutants (n = 5), 24.5 ± 10.1% of the seminiferous tubule sections were abnormal, amongst which 11.5 ± 5%, identified as variants of the normal epithelial stages, lacked one or two generations of germ cells and 12.9 ± 7.3% exhibited a seminiferous epithelium either with a complete disorganization of the germ cell layers or with spermatogonia and Sertoli cells only (S2 Fig). In one-year-old mutants (n = 3), the seminiferous epithelium consisted only in Sertoli cells and spermatogonia, which expressed genes that are typical of undifferentiated spermatogonia (i.e., Gfra1 and Zbtb16), but not of differentiating spermatogonia (i.e., Kit and Stra8) (Fig 3I–3L). Altogether, these data indicate that age-matched Rara;b;gSpg–/– and Rxra;b;gSpg–/– mutants display similar, if not identical, phenotypes, including a slow and progressive loss of differentiating germ cells and the presence of spermatogonia blocked at an undifferentiated, Aal, stage (i.e., ZBTB16-positive, KIT-negative [2,3]) in aged mutants, both of which are features of the VAD testis [20].
To further document the similarities between the phenotypes induced by Rxr and Rar loss-of-functions, we examined the effect of Rxr ablation on germ cell apoptosis. Terminal deoxynucleotidyl-transferase dUTP nick end-labeling (TUNEL) assays indicated that apoptosis of preleptotene spermatocytes was not increased in testes of 8 week-old Rxra;b;gSpg–/– mutants, relative to age-matched controls (Fig 4A and 4B). Actually, we did not detect a single TUNEL-positive preleptotene spermatocyte in controls and in Rxra;b;gSpg–/– mutants (n = 3 males for each genotype; n > 200 preleptotene spermatocytes per testis). Therefore, similarly to the situation in mice lacking Rara and Rarg in spermatogonia [9], cell-death cannot account for the missing germ cell layers observed in Rxra;b;gSpg–/– mutant testes.
We next examined the effect of Rxr ablation on the pace of preleptotene spermatocyte differentiation, because any delay or an arrest of this process may lead: (i) to the disappearance of pachytene spermatocytes through their normal differentiation into round, step 7, spermatids after one cycle of the seminiferous epithelium (i.e., 8.6 days), then (ii) to the disappearance of step 7 spermatids through their normal transformation into mature, step 16, spermatids after completion of a second cycle. Thus, we evaluated the duration of meiotic phase of spermatogenesis after 5-bromo-2'-deoxyuridine (BrdU) incorporation into S-phase nuclei. In adult testis, BrdU is mainly incorporated into B spermatogonia and preleptotene spermatocytes [20]. We fate-mapped the BrdU-labeled descendants of these cells 9 and 17 days after injection of the tracer. At the latter time-point, the most advanced, BrdU-positive, cell-type was step 7 spermatids in both control and Rxra;b;gSpg–/– testes (n = 3 for each genotype; 8 week-old) and there was no retained labeling in any spermatocyte (Fig 4C and 4D). Thus, similarly to the situation in mice lacking Rara and Rarg in spermatogonia [9], the duration of meiosis is not altered in Rxra;b;gSpg–/– mutant testes. In this context, it seems logical to assume that ablation of Rxr genes induces germ cell depletion solely through altering the spermatogonia proliferation/differentiation process. Accordingly, BrdU was detected in Rxra;b;gSpg–/– testes, 9 days after its incorporation, in cells displaying histological features of spermatogonia (Fig 4E and 4F). BrdU was never detected in spermatogonia of control testes at this time-point after injection because its amount becomes diminished by half in each daughter cell upon cell-division, yielding a progressive decrease of the signal over time and its absence 9 days after BrdU incorporation. This observation indicates that some of the spermatogonia that had incorporated BrdU in the Rxra;b;gSpg–/– testes did not divide further or divided more slowly than in control testes, as it is the case for spermatogonia lacking Rar [9] and in VAD testis [20]. Our study shows therefore that the outcomes of ablating RAR or RXR in spermatogonia are identical at the histological level.
Differentiation of A1 spermatogonia and meiosis still can occur when RAR and RXR are absent in germ cells
Given the central role assigned to ATRA in spermatogonia differentiation and in male meiosis [13,21], it was surprising that differentiation of only some spermatogonia was impaired, and that meiosis always proceeded normally in the absence of either Rar or Rxr. To exclude the possibility that Cre-mediated excision was mosaic, thereby resulting in the absence of RAR or RXR in some, but not all, differentiating germ cells, we analyzed their expression in Rara;b;gSpg–/– and Rxra;b;gSpg–/– testes. RT-qPCR analysis of whole testis RNA showed that the amount of Rarg transcripts was markedly reduced (4-fold) in Rara;b;gSpg–/– mutants, as early as PN5 (S3 Fig). Consistent with this finding, IHC analyses indicated a total absence of RARG in germ cells of Rara;b;gSpg–/– mutants, at PN5 and at PN60 (S3 Fig). In fact 100% of spermatogonia and of preleptotene spermatocytes were devoid of RARG in Rara;b;gSpg–/– mutants. Efficient loss of RARA and RARB in these mutants can be assessed neither by RT-qPCR because they are not, or only weakly, expressed in spermatogonia nor by IHC analyses because reliable antibodies are not available [9,10]. However, efficient ablation of loxP-flanked Rara and Rarb alleles was assessed at the genomic level, using FACS-purified germ cell populations [22]. PCR analysis demonstrated that excised (null, L–), but not conditional (L2) alleles, were detected in genomic DNA isolated from spermatogonia, spermatocytes and spermatids of PN60 mice bearing the Tg(Stra8-cre)1Reb transgene (S3 Fig). Together, these data indicate that ablation of all 3 Rar genes was efficient in all germ cells, as early as PN5. As the outcome of ablating all RAR in spermatogonia appears very close to that induced upon Rarg knockout (Rarg–/– mutants) [9], our data suggest that RARG is the major functional RAR isotype in spermatogonia. Similar results were obtained in Rxra;b;gSpg–/– mutants, with Rxra transcript amounts markedly reduced (4- to 5-fold) as early as PN5 (S3 Fig).
Assuming that the excision of Rar and Rxr genes was complete from PN5 onwards, the impact of RAR or RXR loss-of-functions during the pubertal development of the testis was evaluated at PN20, i.e., when the first post-meiotic cells appear. At this developmental stage, control, Rxra;b;gSpg–/– and Rara;b;gSpg–/– mutant testes (n = 4 for each genotype) were indistinguishable: in both situations, late pachytene and diplotene spermatocytes represented the most advanced germ cell in the vast majority of tubule sections (Fig 5A). These results indicate that the spermatocytes present at PN20 in the mutants testes, appeared in due time, likely because the spermatogonia from which they derived started to differentiate before PN3, at a time when Rar or Rxr genes were not yet knocked out. More importantly, they also indicate that all preleptotene spermatocytes initiated meiosis normally (around PN8), at a time when they were devoid of RAR or RXR since ablation was obvious from PN5 in their precursors (see above). Analyzing the seminiferous epithelium later during pubertal development revealed the occurrence of abnormal cellular associations at PN25: few tubule sections in mutant testes displayed spermatogonia associated with round spermatids but without the intervening layers of preleptotene and pachytene spermatocytes (Fig 5B and 5C). This observation confirms the initial wave of A1 spermatogonia differentiation was not affected (yielding step 7 spermatids at PN25), and suggests the second wave was arrested (or delayed) in few tubules at some point before meiosis, leading to the absence of spermatocytes at PN25. However, the presence of normal cellular associations in the majority of tubule sections indicates that both A1 spermatogonia differentiation and meiosis occurred, despite absence of RAR or RXR in germ cells (see above). In keeping with this, KIT-positive A1 spermatogonia were found at stages VII-VIII of the seminiferous epithelium cycle in Rara;b;gSpg–/– mutants at PN60, similarly to the situation in control mice (Fig 5E and 5F).
The reason why ablation of RAR or RXR in germ cells affects only a fraction of A1 spermatogonia is unclear. In some cases the A1 transition appears to take place in due time, yielding normal cell associations, while in other instances no A1 are formed and Aal spermatogonia have to wait one (or several) epithelial cycles to become A1, yielding seminiferous tubule segments with missing generations of spermatocytes and spermatids. Moreover, spermatogonia do not transition at random because, as a result of stage-dependent cell divisions [4], extensive rows of differentiating, KIT-positive, RARG-negative, spermatogonia were observed at stages I-VI of the seminiferous epithelium cycle in Rara;b;gSpg–/– mutants, as it is the case in control males (Fig 5G–5I). An unknown signal, distinct from ATRA, may operate as a backup only in the context of Rara;b;gSpg–/– and Rxra;b;gSpg–/– mutants to promote spermatogonia differentiation. Alternatively, two populations of Aal spermatogonia may normally exist in the seminiferous epithelium at stages VII-VIII, one requiring RAR/RXR to transition, the other one being committed to become A1, independently of RAR/RXR heterodimers. As A1 spermatogonia were less and less often generated with aging and no longer observed in old Rara;b;gSpg–/– and Rxra;b;gSpg–/– mutants, the second population may become depleted with time resulting in a complete arrest of spermatogenesis. Given the pivotal role of ATRA and the precise timing in spermatogonia differentiation at stage VII-VIII of the seminiferous epithelium cycle [4], instructing the transition in this second population may also require ATRA. We propose that an ATRA signal transduced by RARA in Sertoli cells stimulates some Aal spermatogonia to become A1 even though no RAR/RXR pathway is functional within these latter cells. In keeping with this proposal, it worth noting that the seminiferous epithelium of mice lacking both RARA in Sertoli cells and RARG in spermatogonia (RaraSer–/–;Rarg–/– mutants) was found to consist only in Sertoli cells and undifferentiated spermatogonia (Fig 5D), as it is the case when ATRA synthesis is specifically abolished in Sertoli cells [13].
More surprisingly, following the Aal to A1 transition, germ cell differentiation progressed at a normal pace despite the lack of RAR or RXR inside these cells. This indicates that initiation (and progression) of meiosis can proceed even in the absence of a functional ATRA signaling pathway in spermatocytes. If one considers that ATRA is as a mandatory meiosis-inducing substance in vertebrates [23], then our finding necessarily implies that the ATRA-dependent pathway instructing preleptotene spermatocytes is not autocrine in nature, as previously proposed [13], but instead operates in Sertoli cells. In this context, ATRA would control the synthesis by Sertoli cells of yet unknown, intermediate, secreted factor(s) acting on spermatocytes to trigger meiosis. Alternatively, the possibility exists that meiotic initiation does not require ATRA in male germ cells, as it was shown to be the case in female germ cells [24]. Discriminating between these two possibilities awaits further investigations. Regardless of the scenario, our findings indicate that expression of Stra8 does not require a RAR/RXR-dependent signaling pathway in preleptotene spermatocytes, even though this receptor heterodimer can efficiently bind to RARE in the Stra8 promoter [13,24].
RARG/RXR heterodimers bind to Sall4 and induce expression of SALL4A in spermatogonia
The similarities between Rar and Rxr gene ablations indicate that RAR and RXR exert convergent functions in spermatogonia, and support the possibility that ATRA signaling in these cells involves RAR/RXR heterodimers. They also indicate that RXR in spermatogonia are unlikely to play a role other than controlling differentiation in conjunction with RAR. To test whether RAR and RXR were actually recruited to an endogenous gene promoter in spermatogonia in vivo, we performed immunoprecipitation (IP) of these nuclear receptors using chromatin from PN5 wild-type testes, followed by qPCR analysis of the recovered DNA fragments, and assessed binding to Stra8, which is proposed as a RAR target-gene in spermatogonia [21]. Both anti-RAR and anti-RXR antibodies were able to precipitate, with similar efficiencies, the DNA sequences containing the RAR binding sites of the Stra8 promoter (S4 Fig). These data further support the notion that RAR/RXR heterodimers can be the functional units transducing the ATRA-signal in spermatogonia. However, although STRA8 promotes spermatogonia differentiation, it is not strictly required for this process [19,25,26] and its expression does not appears to be dependent upon RAR/RXR-signaling (see above). Thus, effectors acting downstream of ATRA and distinct from STRA8 likely account for the Aal to A1 spermatogonia transition.
To gain insights into the genetic cascade controlled by RAR/RXR heterodimers and aside from STRA8, we set up an experiment aimed at identifying ATRA-controlled genes in spermatogonia. To this purpose, we used Aldh1a1-3Ser−/− mutants as a model, in which all retinaldehyde dehydrogenase activity is ablated in Sertoli cells. These mutants were chosen because (i) their spermatogonia differentiation is blocked at the Aal stage, (ii) Aal spermatogonia express RARG [9] and (iii) Aal spermatogonia are poised to differentiate into A1 spermatogonia upon activation of ATRA signaling [13]. We treated organotypic cultures of Aldh1a1-3Ser−/− testes with the RARG-selective agonist BMS961 (n = 5) or with its vehicle (n = 5) for 6 hours and extracted mRNA. Microarray expression profiling identified only a few transcripts that were differentially expressed upon activation of RARG, amongst which Sall4. This gene encodes two isoforms named SALL4A and SALL4B [27]. They are zinc-finger transcription factors, which participate in regulatory networks and are critical for cell fate decisions and lineage specification [28,29]. In the mouse testis, their expression is restricted to spermatogonia [30,31] and mice deficient for Sall4 in these cell-type display testis defects that resemble those observed in Rxra;b;gSpg–/– and Rara;b;gSpg–/– mutants, namely loss of differentiating, KIT-positive, spermatogonia and of meiotic cells [14]. Thus Sall4 gene appears particularly relevant to ATRA-induced spermatogonia differentiation.
We confirmed by RT-qPCR that Sall4a mRNA steady state level was increased upon BMS961 administration in Aldh1a1-3Ser−/− testes, without the need for intermediate protein synthesis as this increase occurred in the presence of cycloheximide (Fig 6A). Western-blot analysis of protein extracts from Aldh1a1-3Ser−/− testes revealed that SALL4A protein level was increased by BMS961-activated RARG (Fig 6B, compare lane 1 to 2); this increase was prevented in mice additionally carrying a Rarg knock-out (Fig 6B, compare lane 3 to 4) and was not observed in BMS961-treated Rara;b;gSpg–/– mutants (Fig 6B, compare lane 5 to 6). In addition, Sall4a mRNA levels were significantly decreased in whole testis of Rara;b;gSpg–/– and Rxra;b;gSpg–/– mutants at PN60, while Sall4b and Zbtb16 mRNA levels were unchanged (Fig 6C). The finding that Sall4b mRNA level was not altered is in keeping with previous reports showing that SALL4B is expressed at a constant level in spermatogonia [31,32]. Altogether our results indicate that (i) Sall4a expression is decreased in testes of mice lacking RAR or RXR in spermatogonia (Rara;b;gSpg–/– and Rxra;b;gSpg–/– testes); (ii) SALL4A is detected at a low level in the seminiferous epithelium of mice deficient in ATRA (Aldh1a1-3Ser−/− testes), but at a high level when RARG is activated by BMS961 in these mice (Aldh1a1-3Ser−/− testes treated with BMS961), except when RARG is lacking (Aldh1a1-3Ser−/−;Rarg−/− testes, treated with BMS961); and (iii) SALL4A is not detected in testes of adult mice lacking RAR in spermatogonia even in the presence of the RARG agonist (Rara;b;gSpg–/– testes, treated with BMS961). Altogether, these data indicate that Sall4a expression is controlled by ATRA-activated RARG in spermatogonia.
Using data sets locating RAR-occupied sites genome-wide in several cell-types [33,34], we identified a 700 bp-long RAR-binding region located in the first intron of Sall4 (RARE, Fig 7A). This DNA fragment contained a RAR binding sequence called IR1, consisting of inverted repeats (two core motifs 5’-RGKTSA-3’ oriented head-to-tail) separated by 1 bp (Fig 7B), as well as two additional sites called DR1 and DR0 (direct repeats of the core motif separated by 1 and 0 bp, respectively). We performed triplicate IP experiments with anti-RAR and anti-RXR antibodies using chromatin extracted from PN5 wild-type mouse testes as substrate. At this developmental stage, Sall4a expression was dependent upon RARG (Fig 7C, left panel). We analyzed the immuno-precipitated chromatin fragments by qPCR and evidenced robust binding of both RAR and RXR in vivo, in a 106bp-long region restricted to chr2:168,591,142–168,591,247 (NCBI37/mm9) in Sall4 (RARE, Fig 7C, right panel). To further confirm interaction of IR1 with RAR/RXR heterodimers, we performed electrophoretic mobility shift assays (EMSA) (Fig 7D). They revealed that RARG isotype in combination with RXRA isotype (lane 4), but neither RARG nor RXRA alone (lanes 2 and 3, respectively), bound the radiolabelled IR1 sequence. Binding was competed by increasing amounts of unlabeled IR1 (lanes 5–7), but not by IR1m bearing point-mutations in the first core motif (lanes 8–10). They also showed that unlabeled IR1 efficiently competed binding of RARG/RXRA heterodimers to the radiolabeled, canonical, RAR binding site of Rarb gene (called DR5, Fig 7E). The data suggested therefore that RARG/RXRA heterodimers could enhance expression of SALL4A through binding to an IR1 motif located in Sall4 intron. This motif appeared moderately well-conserved in mouse, rat, human and primate genomes (Fig 7B), but single mismatches do not necessarily abrogate RAR/RXR binding, even when located at highly conserved positions [33]. The DR1 and DR0 were also able to bind RARG/RXRA heterodimers (S5 Fig). Their sequences were even well-conserved across the species than that of IR1 (Fig 7B). Thus the RAR binding region in Sall4 belongs to the category of “composite elements”, the functionality of which has already been demonstrated [34]. Interestingly, SALL4A is also expressed in human spermatogonia [35]. Moreover, Fertilysin (N,N’-1,8-octanediylbis[2,2-dichloro-acetamide], also called WIN 18,446), which acts by inhibiting ATRA synthesis [36], reversibly inhibits spermatogenesis in men by inducing an arrest of germ cell differentiation at the spermatogonia stage [37,38], which resembles the phenotype we describe here in the mouse. Thus it is possible that RAR/RXR heterodimers also drive SALL4A expression in human spermatogonia.
A model for the effects of ATRA on KIT expression
A hallmark of the transition to a differentiating state in spermatogonia is the expression of KIT receptor at the surface of A1 spermatogonia [5]. However, it is unclear what regulatory steps control the expression of this crucial cell surface receptor. Several studies have shown that undifferentiated spermatogonia are primed to turns on KIT and initiate differentiation upon activation of an ATRA signal [2]. This ATRA signal acts indirectly on Kit because its mRNA is not induced by BMS961, as assessed from our microarray expression profiling (see above) and no RAR binding site is found in Kit [39]. From our present study, we propose that ATRA enhances the level of Sall4a mRNA, allowing thereby an increase of the amount of SALL4A in spermatogonia. In agreement with this proposal, SALL4A appears at PN3-PN4 in wild-type spermatogonia [31,32], coinciding with the onset of endogenous ATRA signaling [40] and differentiation of the first KIT-positive spermatogonia [41]. SALL4A in high amount could (i) sequester ZBTB16, resulting in the release of the ZBTB16-mediated repression of Kit expression [14]; (ii) interact with DNMT3A and/or DNMT3B [42], allowing the epigenetic shift which is instrumental to A1 transition to take place properly [43]; and (iii) act on yet unknown other components of the differentiation program required in spermatogonia to transition to the A1 state.
In agreement with our proposal, Hobbs et al. [14] reported that the total amount of SALL4 protein detected in spermatogonia is higher at the A1 stage (i.e., in the ZBTB16-high, KIT-positive cell population) than at the Aal stage (i.e., in the ZBTB16-high, KIT-negative cell population). It is however not possible to show by IHC that Aal spermatogonia expressing SALL4A upon ATRA signaling activation differentiate into A1 spermatogonia and express KIT because, contrary to what has been stated in a previous report [31], antibodies to SALL4 do not distinguish between SALL4A and SALL4B. As SALL4B is expressed in spermatogonia and in their precursors from embryonic day 17.5 onwards [31,32], these antibodies are unsuitable to detect a specific increase in the expression of the sole SALL4Aisoform.
A comprehensive model summarizing the combination of transcriptional, post-transcriptional and non-genomic effects of ATRA pathways possibly controlling KIT expression and the commitment of Aal spermatogonia towards the A1 fate is proposed (Fig 8). The interest of better understanding the control of KIT expression in spermatogonia is not restricted to gametogenesis, but extends to testicular cancer. In fact, seminoma cells frequently bear somatic mutations activating KIT, or overexpress KIT or SALL4 [7,44,45]. Therefore, pharmacological modulation of mechanisms that regulate KIT expression in spermatogonia, such as antagonizing ATRA action, might have important applications for future therapeutic strategies.
Materials and Methods
Mice and treatments
Mice were on a mixed C57BL/6-129/Sv (50–50%) genetic background. They were housed in a licensed animal facility (agreement #A67-218-37). All experiments were approved by the local ethical committee (Com’Eth, accreditations #2012–080 and #2012–081), and were supervised by N.B.G. or M.M. who are qualified in compliance with the European Community guidelines for laboratory animal care and use (2010/63/UE). To inactivate Rar- or Rxr-coding genes in spermatogonia, mice carrying loxP-flanked alleles (L2) of Rara, Rarb and Rarg or of Rxra, Rxrb and Rxrg [12, and references therein] were crossed with mice bearing the Tg(Stra8-cre)1Reb transgene [16]. In F1, RxraL2/L2;RxrbL2/L2;RxrgL2/L2 females were crossed with males bearing one copy of the transgene (Stra8tg/0). The resulting males (Stra8-Cretg/0;Rxra+/L2;Rxrb+/L2;Rxrg+/L2) were backcrossed on RxraL2/L2;RxrbL2/L2;RxrgL2/L2 females to generate mutant males in F2 (Stra8-Cretg/0;RxraL2/L2;RxrbL2/L2;RargL2/L2), and their control littermates (Rxra+/L2;Rxrb+/L2;Rxrg+/L2 and RxraL2/L2;RxrbL2/L2;RxrgL2/L2 males). The same approach was used to inactivate Rara, Rarb and Rarg in spermatogonia. Aldh1a1-3ser-/- mutants were generated as described previously [13]. Mice lacking RARA in Sertoli cells in a RARG-null genetic background were obtained by crossing RaraSer–/–[12] and Rarg–/– mice [9] together. BMS961 (50 mg/kg body weight, Tocris Bioscience) dissolved in dimethylsulfoxide was administered to the mice by intra peritoneal injections. BrdU (Sigma-Aldrich) was dissolved in phosphate buffered saline and injected by intra peritoneal at 50 mg/kg body weight.
Isolation of germ cell populations by flow cytometry and organotypic cultures
Germ cell populations were purified from testes of Aldh1a1-3ser-/-, Rara;b;gSpg–/– and Rxra;b;gSpg–/– mice by FACS and characterized as described previously [13,22]. Organotypic cultures of testes from Aldh1a1-3ser-/- mice were also as described previously, except that the RARG-selective agonist BMS961 at 10–7M (Tocris Bioscience) was used to activate RAR signaling instead of BMS753 [13].
Histology, detection of apoptotic and proliferating cells, immunohistochemistry (IHC) and in situ hybridization (ISH)
For histology, testis samples were fixed in Bouin’s fluid for 16 hours and embedded in paraffin. Histological sections (5 μm-thick) were stained with hematoxylin and eosin or with periodic acid-Shiff (PAS). The percentage of affected seminiferous tubules was established on PAS-stained histological sections by counting cross-sections of tubules (n > 400 per testis). For all other methods, testes were fixed for 16 hours in 4% (wt/vol) buffered paraformaldehyde (PFA). For detection of apoptotic cells, TUNEL assays were performed using the In Situ Cell-Death Detection kit, Fluorescein (Roche Diagnostics). BrdU incorporation was detected by using an anti-BrdU antibody (Roche Molecular Biochemicals) and immunofluorescence labeling as described [9]. For IHC, 10 μm-thick frozen sections were incubated overnight at 4°C with rabbit anti-STRA8 (Ab49602, Abcam), rabbit anti-RARG1 (D3A4 #8965, Cell Signaling Technology), goat anti-ZBTB16 (AF2944, R&D Systems) and rabbit anti-KIT (D13A2 #3074, Cell Signaling Technology) antibodies diluted 1:200 to 1:500. Detection of bound primary antibodies was achieved by incubating the section with Cy3-conjugated goat anti-rabbit IgG (Jackson ImmunoResearch) or Alexa Fluor 488-conjugated donkey anti-goat IgG (Life Technologies). ISH using digoxigenin-labeled probes for detection of Gfra1, Kit, Stra8 and Zbtb16 expression was performed as described [9,10,20]. The sections were all counterstained with 0.001% (vol/vol) 4,6-diamidino-2-phenylindole dihydrochloride (DAPI) and mounted in Vectashield (Vector Laboratories). The pattern of Cre expression driven by Tg(Stra8-cre)1Reb [16] was assessed through testing excision in mice carrying the Gt(ROSA)26Sortm1Sor reporter transgene [46]. In these mice, E. coli beta-galactosidase is synthesized only in cells that have experienced Cre-mediated deletion of an intervening stop sequence. Analysis of beta-galactosidase activity was as described [10].
Analysis of RNA and chromatin
Total RNA was prepared using TRIzol reagent (Life Technologies). Reverse transcription of total RNA followed by PCR amplification of cDNA was performed using QuantiTect Reverse Transcription (Qiagen) and LightCycler 480 SYBR Green I Master (Roche Diagnostics) kits, respectively. Primers were as indicated in Table 1. Triplicates of at least three samples were used in each experimental condition. The transcript levels were normalized relative to that of Rplp0 or Gapdh transcripts, whose expressions are not changed by retinoid administration. Data were expressed as fold induction relative to vehicle or control conditions. To prepare chromatin, PN5 testes were fixed with 0.4% PFA (wt/vol) for 15 minutes, before being sonicated to shear DNA to an average size of 500 bp. For each reaction, 100 μg of chromatin was first incubated with 18 μg of ChIP grade anti-RAR (sc-773; Santa Cruz biotechnology), anti-RXR (sc-774; Santa Cruz biotechnology) or anti-RNA polymerase II (RNApol2; sc-9001; Santa Cruz biotechnology) antibodies and then with protein G-Sepharose. Beads were washed, and eluted DNA–protein complexes were reverse cross-linked and purified. ChIP was performed in triplicate, using distinct chromatin extracts. The recovered immuno-precipitated DNA was analyzed by triplicate qPCR and was compared with input DNA. Quantitation was determined by the enrichment of the binding site compared with a site located upstream the TSS (–11kb), and were expressed as mean fold-enrichment (n = 3). The sequences of the oligonucleotides used are indicated in Table 2. Statistical significance was assessed by Student t tests or by one-way ANOVA followed by the post hoc Newman-Keuls test for comparison by pairs.
Electrophoretic mobility shift assays
They were performed as described previously [47]. Briefly, the oligonucleotides were annealed and labeled with [γ-32P]ATP (Amersham Bioscience). For competition assays, unlabeled oligonucleotides were added in the incubation mixture in 1- to 1000-fold molar excess. The sequences of the oligonucleotides used are described in Table 2.
Western blotting
Protein extracts were prepared in 50 mM Tris-HCl (pH7.5) buffer containing 150 mM NaCl, 0.5% (wt/vol) sodium deoxycholate, 1% (vol/vol) NP40, 0.2% (vol/vol) sodium dodecyl sulfate (SDS), and protease inhibitor mixture (Roche diagnostics). They were resolved by 4–16% (wt/vol) gradient SDS polyacrylamide gel electrophoresis (Expedeon) and transferred to nitrocellulose membranes (Protran) using standard protocols. The membranes were incubated with anti-SALL4 antibodies (Ab29112; Abcam) diluted 1:500 and IgG were detected using goat anti-mouse coupled to horseradish peroxidase as secondary antibodies (diluted 1:5000) followed by chemiluminescence according to the manufacturer’s protocol (GE Healthcare). The blots were subsequently incubated 2 times for 10 minutes at room temperature in 0.2M glycine pH 2.2 containing 0.1% (wt/vol) SDS and 0.1% (wt/vol) Tween 20, and were further probed with anti-actin antibodies (sc-58673; Santa Cruz biotechnology) diluted 1:500 to verify for equivalent loading in all the lanes.
Supporting Information
Zdroje
1. de Rooij DG. Proliferation and differentiation of spermatogonial stem cells. Reproduction 2001; 121:347–354. 11226060
2. Schrans-Stassen BH, van de Kant HJ, de Rooij DG, van Pelt AM. Differential expression of c-kit in mouse undifferentiated and differentiating type A spermatogonia. Endocrinology 1999; 140:5894–5900. 10579355
3. Suzuki H, Sada A, Yoshida S, Saga Y. The heterogeneity of spermatogonia is revealed by their topology and expression of marker proteins including the germ cell-specific proteins Nanos2 and Nanos3. Dev Biol. 2009; 336:222–231. doi: 10.1016/j.ydbio.2009.10.002 19818747
4. de Rooij DG. Stem cells in the testis. Int J Exp Pathol. 1998; 79:67–80. 9709376
5. van Pelt AM, de Rooij DG. Retinoic acid is able to reinitiate spermatogenesis in vitamin A-deficient rats and high replicate doses support the full development of spermatogenic cells. Endocrinology. 1991; 128:697–704. 1989855
6. de Rooij DG, Russell LD. All you wanted to know about spermatogonia but were afraid to ask. J Androl. 2000; 21:776–798. 11105904
7. Rossi P. Transcriptional control of KIT gene expression during germ cell development. Int J Dev Biol. 2013; 57:179–184. doi: 10.1387/ijdb.130014pr 23784828
8. Chambon P. The nuclear receptor superfamily: a personal retrospect on the first two decades. Mol Endocrinol. 2005; 19:1418–1428. 15914711
9. Gely-Pernot A, Raverdeau M, Célébi C, Dennefeld C, Feret B, Klopfenstein M, et al. Spermatogonia differentiation requires retinoic acid receptor γ. Endocrinology 2012; 153:438–449. doi: 10.1210/en.2011-1102 22045663
10. Vernet N, Dennefeld C, Rochette-Egly C, Oulad-Abdelghani M, Chambon P, Ghyselinck NB, et al. Retinoic acid metabolism and signaling pathways in the adult and developing mouse testis. Endocrinology 2006; 147:96–110. 16210368
11. Gaemers IC, van Pelt AM, van der Saag PT, Hoogerbrugge JW, Themmen AP, de Rooij DG. Differential expression pattern of retinoid X receptors in adult murine testicular cells implies varying roles for these receptors in spermatogenesis. Biol Reprod. 1998; 58:1351–1356. 9623592
12. Vernet N, Dennefeld C, Guillou F, Chambon P, Ghyselinck NB, Mark M. Prepubertal testis development relies on retinoic acid but not rexinoid receptors in Sertoli cells. EMBO J. 2006; 25:5816–5825. 17124491
13. Raverdeau M, Gely-Pernot A, Féret B, Dennefeld C, Benoit G, Davidson I, et al. Retinoic acid induces Sertoli cell paracrine signals for spermatogonia differentiation but cell autonomously drives spermatocyte meiosis. Proc Natl Acad Sci USA 2012; 109:16582–16587. doi: 10.1073/pnas.1214936109 23012458
14. Hobbs RM, Fagoonee S, Papa A, Webster K, Altruda F, Nishinakamura R, et al. Functional antagonism between Sall4 and Plzf defines germline progenitors. Cell Stem Cell 2012; 10:284–298. doi: 10.1016/j.stem.2012.02.004 22385656
15. Mark M, Ghyselinck NB, Chambon P. Function of retinoid nuclear receptors: lessons from genetic and pharmacological dissections of the retinoic acid signaling pathway during mouse embryogenesis. Annu Rev Pharmacol Toxicol. 2006; 46:451–480. 16402912
16. Sadate-Ngatchou PI, Payne CJ, Dearth AT, Braun RE. Cre recombinase activity specific to postnatal, premeiotic male germ cells in transgenic mice. Genesis 2008; 46:738–742. doi: 10.1002/dvg.20437 18850594
17. Russell LD, Ettlin RA, SinhaHikim AP, Clegg ED. Histological and histopathological evaluation of the testis. Clearwater, FL: Cache River Press, 1990.
18. Naughton CK, Jain S, Strickland AM, Gupta A, Milbrandt J. Glial cell-line derived neurotrophic factor-mediated RET signaling regulates spermatogonial stem cell fate. Biol Reprod. 2006; 74:314–321. 16237148
19. Mark M, Jacobs H, Oulad-Abdelghani M, Dennefeld C, Féret B, Vernet N, et al. STRA8-deficient spermatocytes initiate, but fail to complete, meiosis and undergo premature chromosome condensation. J Cell Sci. 2008; 121:3233–3242. doi: 10.1242/jcs.035071 18799790
20. Ghyselinck NB, Vernet N, Dennefeld C, Giese N, Nau H, Chambon P, et al. Retinoids and spermatogenesis: lessons from mutant mice lacking the plasma retinol binding protein. Dev Dyn. 2006; 235:1608–1622. 16586441
21. Hogarth CA, Griswold MD. The key role of vitamin A in spermatogenesis. J Clin Invest. 2010; 120:956–962. doi: 10.1172/JCI41303 20364093
22. Getun IV, Torres B, Bois PR. Flow cytometry purification of mouse meiotic cells. J Vis Exp. 2011; 50:e2602.
23. Griswold MD, Hogarth CA, Bowles J, Koopman P. Initiating meiosis: the case for retinoic acid. Biol Reprod. 2012; 86:35. doi: 10.1095/biolreprod.111.096610 22075477
24. Kumar S, Chatzi C, Brade T, Cunningham TJ, Zhao X, Duester G. Sex-specific timing of meiotic initiation is regulated by Cyp26b1 independent of retinoic acid signalling. Nat Commun. 2011; 2:151. 21224842
25. Anderson EL, Baltus AE, Roepers-Gajadien HL, Hassold TJ, de Rooij DG, van Pelt AM, Page DC. Stra8 and its inducer, retinoic acid, regulate meiotic initiation in both spermatogenesis and oogenesis in mice. Proc Natl Acad Sci USA 2008; 105:14976–14980. doi: 10.1073/pnas.0807297105 18799751
26. Endo T, Romer KA, Anderson EL, Baltus AE, de Rooij DG, Page DC. Periodic retinoic acid-STRA8 signaling intersects with periodic germ-cell competencies to regulate spermatogenesis. Proc Natl Acad Sci USA 2015; 112:E2347–E2356. doi: 10.1073/pnas.1505683112 25902548
27. Rao S, Zhen S, Roumiantsev S, McDonald LT, Yuan GC, Orkin SH. Differential roles of Sall4 isoforms in embryonic stem cell pluripotency. Mol Cell Biol. 2010; 30:5364–5380. doi: 10.1128/MCB.00419-10 20837710
28. Elling U, Klasen C, Eisenberger T, Anlag K, Treier M. Murine inner cell mass-derived lineages depend on Sall4 function. Proc Natl Acad Sci USA 2006; 103:16319–21634. 17060609
29. Sakaki-Yumoto M, Kobayashi C, Sato A, Fujimura S, Matsumoto Y, Takasato M, et al. The murine homolog of SALL4, a causative gene in Okihiro syndrome, is essential for embryonic stem cell proliferation, and cooperates with Sall1 in anorectal, heart, brain and kidney development. Development 2006; 133:3005–3013. 16790473
30. Shima JE, McLean DJ, McCarrey JR, Griswold MD. The murine testicular transcriptome: characterizing gene expression in the testis during the progression of spermatogenesis. Biol Reprod. 2004; 71:319–330. 15028632
31. Gassei K, Orwig KE. SALL4 expression in gonocytes and spermatogonial clones of postnatal mouse testes. PLoS One 2013; 8:e53976. doi: 10.1371/journal.pone.0053976 23326552
32. Liao HF, Chen WS, Chen YH, Kao TH, Tseng YT, Lee CY, et al. DNMT3L promotes quiescence in postnatal spermatogonial progenitor cells. Development 2014; 141:2402–2413. doi: 10.1242/dev.105130 24850856
33. Delacroix L, Moutier E, Altobelli G, Legras S, Poch O, Choukrallah MA, et al. Cell-specific interaction of retinoic acid receptors with target genes in mouse embryonic fibroblasts and embryonic stem cells. Mol Cell Biol. 2010; 30:231–244. doi: 10.1128/MCB.00756-09 19884340
34. Moutier E, Ye T, Choukrallah MA, Urban S, Osz J, Chatagnon A, et al. Retinoic acid receptors recognize the mouse genome through binding elements with diverse spacing and topology. J Biol Chem. 2012; 287:26328–265341. doi: 10.1074/jbc.M112.361790 22661711
35. Eildermann K, Aeckerle N, Debowski K, Godmann M, Christiansen H, Heistermann M, et al. Developmental expression of the pluripotency factor sal-like protein 4 in the monkey, human and mouse testis: restriction to premeiotic germ cells. Cells Tissues Organs 2012; 196:206–220. doi: 10.1159/000335031 22572102
36. Paik J, Haenisch M, Muller CH, Goldstein AS, Arnold S, Isoherranen N, et al. Inhibition of retinoic acid biosynthesis by the bisdichloroacetyldiamine WIN 18,446 markedly suppresses spermatogenesis and alters retinoid metabolism in mice. J Biol Chem 2014; 289:15104–15117. doi: 10.1074/jbc.M113.540211 24711451
37. Heller CG, Moore DJ, Paulsen CA. Suppression of spermatogenesis and chronic toxicity in men by a new series of bis(dichloroacetyl) diamines. Toxicol Appl Pharmacol. 1961; 3:1–11. 13713106
38. Heller CG, Flageolle BY, Matson LJ. Histopathology of the human testes as affected by bis(dichloroacetyl)diamines. Exp Mol Pathol Suppl. 1963; 2:107–114. 14089658
39. Hayashi S, Kunisada T, Ogawa M, Nishikawa S. Identification of the control regions for mouse c-kit gene transcription induced by retinoic acid. DNA Res. 1995; 2:211–218. 8770562
40. Snyder EM, Small C, Griswold MD. Retinoic acid availability drives the asynchronous initiation of spermatogonial differentiation in the mouse. Biol Reprod. 2010; 83:783–790. doi: 10.1095/biolreprod.110.085811 20650878
41. Busada JT, Chappell VA, Niedenberger BA, Kaye EP, Keiper BD, Hogarth CA, et al. Retinoic acid regulates Kit translation during spermatogonial differentiation in the mouse. Dev Biol. 2015; 397:140–149. doi: 10.1016/j.ydbio.2014.10.020 25446031
42. Yang J, Corsello TR, Ma Y. Stem cell gene SALL4 suppresses transcription through recruitment of DNA methyltransferases. J Biol Chem. 2012; 287:1996–2005. doi: 10.1074/jbc.M111.308734 22128185
43. Shirakawa T, Yaman-Deveci R, Tomizawa S, Kamizato Y, Nakajima K, Sone H, et al. An epigenetic switch is crucial for spermatogonia to exit the undifferentiated state toward a Kit-positive identity. Development 2013; 140:3565–3576. doi: 10.1242/dev.094045 23903187
44. Coffey J, Linger R, Pugh J, Dudakia D, Sokal M, Easton DF, et al. Somatic KIT mutations occur predominantly in seminoma germ cell tumors and are not predictive of bilateral disease: report of 220 tumors and review of literature. Genes Chromosomes Cancer 2008; 47:34–42. 17943970
45. Cao D, Li J, Guo CC, Allan RW, Humphrey PA. SALL4 is a novel diagnostic marker for testicular germ cell tumors. Am J Surg Pathol. 2009; 33:1065–1077. doi: 10.1097/PAS.0b013e3181a13eef 19390421
46. Soriano P. Generalized lacZ expression with the ROSA26 Cre reporter strain. Nat Genet. 1999; 21:70–71. 9916792
47. Hwang JJ, Chambon P, Davidson I. Characterization of the transcription activation function and the DNA binding domain of transcriptional enhancer factor-1. EMBO J. 1993; 12:2337–2348. 8389695
48. Filipponi D, Hobbs RM, Ottolenghi S, Rossi P, Jannini EA, Pandolfi PP, et al. Repression of kit expression by Plzf in germ cells. Mol Cell. Biol. 2007; 27:6770–6781. 17664282
49. Prabhu SM, Meistrich ML, McLaughlin EA, Roman SD, Warne S, Mendis S, Itman C, Loveland KL. Expression of c-Kit receptor mRNA and protein in the developing, adult and irradiated rodent testis. Reproduction. 2006; 131:489–499. 16514192
50. Yang QE, Racicot KE, Kaucher AV, Oatley MJ, Oatley JM. MicroRNAs 221 and 222 regulate the undifferentiated state in mammalian male germ cells. Development 2013; 140:280–290. doi: 10.1242/dev.087403 23221369
51. Tong MH, Mitchell DA, McGowan SD, Evanoff R, Griswold MD. Two miRNA clusters, Mir-17-92 (Mirc1) and Mir-106b-25 (Mirc3), are involved in the regulation of spermatogonial differentiation in mice. Biol Reprod. 2012; 86:72. doi: 10.1095/biolreprod.111.096313 22116806
52. Barrios F, Filipponi D, Campolo F, Gori M, Bramucci F, Pellegrini M, et al. SOHLH1 and SOHLH2 control Kit expression during postnatal male germ cell development. J Cell Sci. 2012; 125:1455–1464. doi: 10.1242/jcs.092593 22328502
53. Pellegrini M, Filipponi D, Gori M, Barrios F, Lolicato F, Grimaldi P, et al. ATRA and KL promote differentiation toward the meiotic program of male germ cells. Cell Cycle 2008; 7:3878–3888. 19098446
Štítky
Genetika Reprodukční medicínaČlánek vyšel v časopise
PLOS Genetics
2015 Číslo 10
Nejčtenější v tomto čísle
- Single Strand Annealing Plays a Major Role in RecA-Independent Recombination between Repeated Sequences in the Radioresistant Bacterium
- The Rise and Fall of an Evolutionary Innovation: Contrasting Strategies of Venom Evolution in Ancient and Young Animals
- Genome Wide Identification of SARS-CoV Susceptibility Loci Using the Collaborative Cross
- DCA1 Acts as a Transcriptional Co-activator of DST and Contributes to Drought and Salt Tolerance in Rice