PACT/PRKRA and p53 regulate transcriptional activity of DMRT1

Fujitani, Kazuko; Otomo, Asako; Nagayama, Yuto; Tachibana, Taro; Kato, Rika; Kawashima, Yusuke; Kodera, Yoshio; Kato, Tomoko; Takada, Shuji; Tamura, Kei; Takamatsu, Nobuhiko; Ito, Michihiko

doi:10.1590/1678-4685-GMB-2019-0017

Abstract

The transcription factor DMRT1 (doublesex and mab-3 related transcription factor) has two distinct functions, somatic-cell masculinization and germ-cell development in some vertebrate species, including mouse and the African clawed frog Xenopus laevis. However, its transcriptional regulation remains unclear. We tried to identify DMRT1-interacting proteins from X. laevis testes by immunoprecipitation with an anti-DMRT1 antibody and MS/MS analysis, and selected three proteins, including PACT/PRKRA (Interferon-inducible double-stranded RNA dependent protein kinase activator A) derived from testes. Next, we examined the effects of PACT/PRKRA and/or p53 on the transcriptional activity of DMRT1. In transfected 293T cells, PACT/PRKRA and p53 significantly enhanced and repressed DMRT1-driven luciferase activity, respectively. We also observed that the enhanced activity by PACT/PRKRA was strongly attenuated by p53. Moreover, in situ hybridization analysis of Pact/Prkra mRNA in tadpole gonads indicated high expression in female and male germline stem cells. Taken together, these findings suggest that PACT/PRKRA and p53 might positively and negatively regulate the activity of DMRT1, respectively, for germline stem cell fate.

Keywords:
p53; DMRT1; germline stem cell; testis; Xenopus

Introduction

DMRT1 (doublesex and mab-3-related transcription factor) belongs to a family of transcription factors characterized by the presence of a DNA-binding domain called DM domain. The Dmrt1 gene is required for somatic-cell masculinization, which leads to testis formation in various vertebrate species (Yoshimoto et al., 2010Yoshimoto S, Ikeda N, Izutsu Y, Shiba T, Takamatsu N and Ito M (2010) Opposite roles of DMRT1 and its W-linked paralogue, DM-W, in sexual dimorphism of Xenopus laevis: implications of a ZZ/ZW-type sex-determining system. Development 137:2519-2526.; Masuyama et al., 2012Masuyama H, Yamada M, Kamei Y, Fujiwara-Ishikawa T, Todo T, Nagahama Y and Matsuda M (2012) Dmrt1 mutation causes a male-to-female sex reversal after the sex determination by Dmy in the medaka. Chromosome Res 20:163-176.; Zhao et al., 2015Zhao L, Svingen T, Ng ET and Koopman P (2015) Female-to-male sex reversal in mice caused by transgenic overexpression of Dmrt1. Development 142:1083-1088.). The Z-linked Dmrt1 gene in chicken is involved in male sex determination (Smith et al., 2009Smith CA, Roeszler KN, Ohnesorg T, Cummins DM, Farlie PG, Doran TJ and Sinclair AH (2009) The avian Z-linked gene DMRT1 is required for male sex determination in the chicken. Nature 461:267-271.). In mice, the loss of Dmrt1 in adult Sertoli cells reprograms these cells into granulosa cells. Thus, DMRT1 plays an important role in the regulatory networks that maintain masculinization of somatic cells long after the sex determination (Matson et al., 2011Matson CK, Murphy MW, Sarver AL, Griswold MD, Bardwell VJ and Zarkower D (2011) DMRT1 prevents female reprogramming in the postnatal mammalian testis. Nature 476:101-105.). Interestingly, the W-linked Dm-W gene in the frog Xenopus laevis that we discovered, or the Y-linked Dmy/Dmrt1by gene in the teleost fish Oryzias latipes evolved through whole or partial duplication of Dmrt1 during diversification of each species for male or female sex determination, respectively (Matsuda et al., 2002Matsuda M, Nagahama Y, Shinomiya A, Sato T, Matsuda C, Kobayashi T, Morrey CE, Shibata N, Asakawa S, Shimizu N et al. (2002) DMY is a Y-specific DM-domain gene required for male development in the medaka fish. Nature 417:559-563.; Nanda et al., 2002Nanda I, Kondo M, Hornung U, Asakawa S, Winkler C, Shimizu A, Shan Z, Haaf T, Shimizu N, Shima A et al. (2002) A duplicated copy of DMRT1 in the sex-determining region of the Y chromosome of the medaka, Oryzias latipes. Proc Natl Acad Sci U S A 99:11778-11783.; Yoshimoto et al., 2008Yoshimoto S, Okada E, Umemoto H, Tamura K, Uno Y, Nishida-Umehara C, Matsuda Y, Takamatsu N, Shiba T and Ito M (2008) A W-linked DM-domain gene, DM-W, participates in primary ovary development in Xenopus laevis. Proc Natl Acad Sci U S A 105:2469-2474.) .

DMRT1 participates not only in somatic cell masculinization, but also germ cell development in some vertebrate species. In mice, DMRT1 negatively controls meiosis in male germ cells, but promotes meiosis in female germ cells (Matson et al., 2010Matson CK, Murphy MW, Griswold MD, Yoshida S, Bardwell VJ and Zarkower D (2010) The mammalian doublesex homolog DMRT1 is a transcriptional gatekeeper that controls the mitosis versus meiosis decision in male germ cells. Dev Cell 19:612-24.; Krentz et al., 2011Krentz AD, Murphy MW, Sarver AL, Griswold MD, Bardwell VJ and Zarkower D (2011) DMRT1 promotes oogenesis by transcriptional activation of Stra8 in the mammalian fetal ovary. Dev Biol 356:63-70.). We recently reported that germ cell-specific knockdown of Dmrt1 caused deficiency of female and male germ stem cells (oogonia and spermatogonia) in X. laevis, whereby some genetically female ZW transgenics displayed testicular gonads because of germ cell deficiency (Mawaribuchi et al., 2017aMawaribuchi S, Musashijima M, Wada M, Izutsu Y, Kurakata E, Park MK, Takamatsu N and Ito M (2017a) Molecular evolution of two distinct Dmrt1 promoters for germ and somatic cells in vertebrate gonads. Mol Biol Evol 34:724-733.). In addition, our observation of DMRT1 expression in germ cells during X. laevis gonadal development suggested that DMRT1 contributes to the maintenance of germline stem cell identity by controlling gene expression (Fujitani et al., 2016Fujitani K, Otomo A, Wada M, Takamatsu N and Ito M (2016) Sexually dimorphic expression of Dmrt1 and γH2AX in germ stem cells during gonadal development in Xenopus laevis. FEBS Open Bio 6:276-284.).

As for molecular functions of DMRT1 as transcription factor, in mice it represses and enhances Stra8 transcription in male and female germ cells, respectively (Matson et al., 2010Matson CK, Murphy MW, Griswold MD, Yoshida S, Bardwell VJ and Zarkower D (2010) The mammalian doublesex homolog DMRT1 is a transcriptional gatekeeper that controls the mitosis versus meiosis decision in male germ cells. Dev Cell 19:612-24.; Krentz et al., 2011Krentz AD, Murphy MW, Sarver AL, Griswold MD, Bardwell VJ and Zarkower D (2011) DMRT1 promotes oogenesis by transcriptional activation of Stra8 in the mammalian fetal ovary. Dev Biol 356:63-70.). In gonadal somatic cells of mice, DMRT1 could repress transcription of five feminizing genes, Foxl2, Esr1, Esr2, Wnt4 and Rspo1 as a repressor, but activates three masculinizing genes Ptgdr, Sox9, and Sox8 as an activator (Matson et al., 2011Matson CK, Murphy MW, Sarver AL, Griswold MD, Bardwell VJ and Zarkower D (2011) DMRT1 prevents female reprogramming in the postnatal mammalian testis. Nature 476:101-105.). To clarify the transcriptional regulation by DMRT1, we tried to isolate DMRT1-associated proteins from X. laevis testis extracts by immunoprecipitation with an anti-DMRT1 antibody and mass spectrometry analysis, resulting in the identification of several proteins. Here, we focused on PACT/PRKRA (Interferon-inducible double-stranded RNA dependent protein kinase activator A), because PACT/PRKRA could strongly enhance the transcriptional activity of DMRT1. Because PACT/PRKRA is involved in p53 sumoylation and activation (Bennett et al., 2012Bennett RL, Pan Y, Christian J, Hui T and May WS (2012) The RAX/PACT-PKR stress response pathway promotes p53 sumoylation and activation, leading to G1 arrest. Cell Cycle 11:407-417.), we examined whether the tumor suppressor p53 might be involved in the DMRT1-driven transcriptional regulation. Interestingly, p53 greatly repressed the transcriptional activity of DMRT1, as well as the enhanced activity by PACT/PRKRA in transfected 293T cells.

Materials and Methods

Animal care and use

Experimental procedures in the production of monoclonal antibodies were approved by the Institutional Animal Care and Use Committee (permission number: S0036) and performed according to Osaka City University Animal Experimentation Regulations. All of the experiments usinging X. laevis were performed under approval by the Institutional Animal Care and Use Committee of Kitasato University (permission number: 1602). X. laevis frogs at various developmental stages were purchased from Watanabe Zoushoku (Yachiomachi, Japan) and maintained at 22 °C. Tadpole developmental stages were identified according to the descriptions by Nieuwkoop and Faber (1956)Nieuwkoop PD and Faber J (1956) Normal table of Xenopus laevis (Daudin): A systematical and chronological survey of the development from the fertilized egg till the end of metamorphosis. North Holland Publ. Co, Amsterdam, 243 pp..

Immunogen preparation

A bacterial expression vector pMALc2-DMRT1 (130-336) was constructed by inserting the region encoding residues from 130 to 336 of X. laevis DMRT1.L into pMAL-c2 (New England Biolabs). The recombinant protein was produced in E. coli Rosetta (DE3) pLysS (Novagen) BL21(DE3), and purified using amylose resin (New England Biolabs), followed by elution with 10 mM maltose, according to the manufacturer’s instructions. The purified protein was dialyzed with phosphate buffered saline (PBS) and used as an immunogen.

Production of mouse anti-DMRT1 monoclonal antibodies

Mouse monoclonal anti-DMRT1 antibodies were generated based on the mouse medial iliac lymph node method (Sado et al., 2006Sado Y, Inoue S, Tomono Y and Omori H (2006) Lymphocytes from enlarged iliac lymph nodes as fusion partners for the production of monoclonal antibodies after a single tail base immunization attempt. Acta Histochem Cytochem 39:89-94.). Briefly, the purified protein was injected into the tail base with Freund’s complete adjuvant. Three weeks later, cells from the lymph nodes of the immunized mice were fused with mouse myeloma. The resulting hybridoma cells were plated onto 96-well plates and cultured in HAT (hypoxanthine aminopterin thymidine) selection medium. Monoclonal antibodies were purified from the hybridoma supernatants by ion-exchange chromatography.

Immunoblotting

Samples were run by 10% SDS-PAGE and transferred to FluoroTrans 0.2 μm membrane (PALL). The membrane was blocked with 5% skim milk in PBS, incubated with purified monoclonal antibodies (1:400) or the 1:10,000 diluted anti-DMRT1 rabbit polyclonal antibody (Fujitani et al., 2016Fujitani K, Otomo A, Wada M, Takamatsu N and Ito M (2016) Sexually dimorphic expression of Dmrt1 and γH2AX in germ stem cells during gonadal development in Xenopus laevis. FEBS Open Bio 6:276-284.) at 4 °C overnight, and then washed with PBST (0.1% Tween-20 in PBS). Next, the samples were incubated with anti-mouse or anti-rabbit IgG-HRP-conjugated secondary antibodies (1 h at RT) and then washed. Signals were detected using ImmunoStar LD substrate (Wako) and C-Digit (LI-COR). Both, the anti-mouse and anti-rabbit HRP-conjugated antibodies, were purchased from SIGMA, and were diluted 1:20,000.

Immunohistochemistry

Adult testes were dissected and immediately frozen, embedded in FSC 22 Blue compound (Leica), and sliced into 7 μm sections in a cryostat (Leica, CM1850). Sections were fixed in 4% paraformaldehyde (PFA), followed by treatment with 5% bovine serum albumin (BSA), and 0.5% Triton X-100 in PBS. The fixed sections or cells were then incubated overnight with monoclonal antibodies (1:10) or the 1:1000 diluted anti-DMRT1 rabbit polyclonal antibody (Fujitani et al., 2016Fujitani K, Otomo A, Wada M, Takamatsu N and Ito M (2016) Sexually dimorphic expression of Dmrt1 and γH2AX in germ stem cells during gonadal development in Xenopus laevis. FEBS Open Bio 6:276-284.) at 4 °C. After washing, the sections or cells were incubated with the anti-mouse IgG-Alexa 488 conjugated antibody (1:2,000) and anti-mouse IgG Alexa 592 conjugated antibody (1:2,000), respectively, followed by treatment with 10 μg/mL Hoechst 33258 (Sigma) for nuclei staining. The Alexa-conjugated antibodies were purchased from Invitrogen. Signals were examined by fluorescence microscopy BZ-8000 (Keyence).

Immunoprecipitation (IP)

Transfected 293T cells or testes dissected from 1-year-old adult X. laevis were homogenized in RIPA buffer, followed by sonication. The cell extracts from a 35 mm dish with 1 μg of each anti-DMRT1 monoclonal antibody, or the testicular extracts (10 mg) with 100 μg of the anti-DMRT1 monoclonal antibody 4F6 were mixed with 100 μL of EZveiw Red Protein G Affinity Gel (Sigma), and incubated overnight at 4 ºC. Mouse normal IgG (Santa Cruz Biotechnology; sc-2025) was used as a negative control. The gels were washed twice with RIPA buffer, and the denatured proteins were separated by SDS-PAGE (Perfect NT Gel W, 10–20% acrylamide, 28 wells; DRC Co. Ltd.). Silver staining was performed with the 2D-SILVER STSIN II kit (Cosmo Bio 423413).

Enzymatic in-gel protein digestion

Gels containing the bands of interest were cut into small pieces, destained in 50% ACN/50 mmol/L NH4HCO3, washed with deionized water, dehydrated in 100% CAN, and dried in an evaporator. The gel pieces were rehydrated in 25 mM Tris-HCl (pH 9.0)/20% ACN containing 50 ng/mL trypsin (sequencing grade; Roche) for 45 min. After unabsorbed solution was removed, the gel pieces were incubated in 50 mM Tris-HCl (pH 9.0) for 20 h at 37 °C. The solution was transferred to a new tube. In addition, the remaining fragments were extracted in 5% formic acid/50% ACN for 20 min at room temperature, and transferred to the tube.

Protein identification by LC-MS/MS analysis

The digested peptides were desalted and separated by HPLC (the EASY-nLC 1000, Thermo Fisher Scientific) and analyzed by mass spectrometry (Q-Exactive mass spectrometer, Thermo Fisher Scientific). The proteins were identified by using the obtained data and X. laevis database.

cDNA synthesis and RT-qPCR

Isolation of total RNA from X. laevis tadpoles and frogs at various stages of development, and cDNA synthesis were performed as described previously (Fujitani et al., 2016Fujitani K, Otomo A, Wada M, Takamatsu N and Ito M (2016) Sexually dimorphic expression of Dmrt1 and γH2AX in germ stem cells during gonadal development in Xenopus laevis. FEBS Open Bio 6:276-284.). RT-qPCR was carried out using the SYBR Green Realtime PCR Master Mix (ToYoBo, Osaka, Japan). Pact/Prkra cDNA was amplified using the following primer pair: 5’-CAGCTGCTGCATGAATTTG-3’ (forward) and 5’-CTCTCCTAAGCTAGTTATGTCACC-3’ (reverse).

cDNA cloning and plasmid construction

phb2, yb-1, and Pact/Prkra cDNAs were amplified from X. laevis adult testis cDNA by PCR using PrimeSTAR polymerase (TaKaRa) with the following primer sets: phb2 (5’-GCTCAGAATTTAAAGGATTTTGC-3’, 5’-TCACT TCTTTCCTTGTTTGAAAAC-3’), yb-1 (5’-AGCAGC GAGGTTGAAACAC-3’, 5’-TTACTCAGCCCCGCCCT G-3’) and PACT/PRKRAPact/Prkra (5’-TCCCAGGAG AGGTTTCCAG-3’, 5’-TCACTTTTTAATACACATG ATTTTTA-3’), respectively. PCR products were cloned into a vertebrate expression vector pcDNA3-S-Tag (Ito et al., 1999Ito M, Yoshioka K, Akechi M, Yamashita S, Takamatsu N, Sugiyama K, Hibi M, Nakabeppu Y, Shiba T and Yamamoto KI (1999) JSAP1, a novel jun N-terminal protein kinase (JNK)-binding protein that functions as a scaffold factor in the JNK signaling pathway. Mol Cell Biol 19:7539-7548.). Effector plasmids used for luciferase reporter assay pcDNA3-FLAG-p53 were cloned into the vertebrate expression vector pcDNA3-FLAG (Ito et al., 1999Ito M, Yoshioka K, Akechi M, Yamashita S, Takamatsu N, Sugiyama K, Hibi M, Nakabeppu Y, Shiba T and Yamamoto KI (1999) JSAP1, a novel jun N-terminal protein kinase (JNK)-binding protein that functions as a scaffold factor in the JNK signaling pathway. Mol Cell Biol 19:7539-7548.) by PCR using Prime STAR polymerase (TaKaRa) with the following primer pair (5’-GAACCTTCCTCTGAGAC-3’, 5’-TCATTCCGAGTCGGGCTGTTC-3’).

Luciferase reporter assay

Twenty four hours before transfection, 293T cells were plated at 510⁴ cells per well in a 48-well plate. The cells were transfected with luciferase reporter plasmid p4xDMRT1-luc (Yoshimoto et al., 2010Yoshimoto S, Ikeda N, Izutsu Y, Shiba T, Takamatsu N and Ito M (2010) Opposite roles of DMRT1 and its W-linked paralogue, DM-W, in sexual dimorphism of Xenopus laevis: implications of a ZZ/ZW-type sex-determining system. Development 137:2519-2526.), effector plasmids, and Renilla luciferase vector pRL-SV40 (Promega) by PEI MAX vector. After 24 hours, luciferase activities were measured in a Luminocounter 700 (Niti-ON). Firefly luciferase activity was normalized by Renilla luciferase activity using the dual luciferase assay system (Promega).

Whole mount in situ hybridization

Whole mount in situ hybridization for X. laevis Pact/Prkra mRNA was performed as described previously (Wada et al., 2017Wada M, Fujitani K, Tamura K, Mawaribuchi S, Kamata Y, Takamatsu N and Ito M (2017) Masculinization-related genes and cell-mass structures during early gonadal differentiation in the African Clawed Frog Xenopus laevis. Zoolog Sci 34:105-111.), using DIG-labeled sense or anti-sense probes from nucleotides 1-930 in GenBank number NM_001086031.1.

Statistical analysis

Two-group, or multiple group comparisons were performed by Student’s t-test or one-way ANOVA followed by Tukey HSD test, respectively. Significance for all tests was set at p < 0.05.

Results

Mouse monoclonal antibody 4F6 reacts specifically to X. laevis DMRT1

To identify DMRT1-associating proteins in X. laevis testes by proteome analysis, we produced mouse monoclonal antibodies against the truncated C-terminal protein of X. laevis DMRT1 from 130 to 336 aa, which contains a specific region among DM domain family proteins. We examined the specificity of 20 monoclonal antibodies to DMRT1 by immunoblotting, immunoprecipitation (IP) and immunohistochemistry (IHC), and from this screen we selected the antibody 4F6. The results using 4F6 are shown in Figure 1. 4F6 reacted specifically to overexpressed FLAG-tagged DMRT1 in 293T cells on immunoblot analysis (Figure 1A). Immunoprecipitates using 4F6 from the extract of 293T cells overexpressing FLAG-tagged DMRT1 showed a specific reaction with the anti-FLAG antibody (Figure 1B). In addition, the IHC analysis with 4F6 or the anti-DMRT1 polyclonal antibody (Fujitani et al., 2016Fujitani K, Otomo A, Wada M, Takamatsu N and Ito M (2016) Sexually dimorphic expression of Dmrt1 and γH2AX in germ stem cells during gonadal development in Xenopus laevis. FEBS Open Bio 6:276-284.) on sections of adult testis revealed that both antibodies reacted to the exact same cells, that is, spermatogonia and Sertoli cells (Figure 1C).

Figure 1
Immunoreaction of an anti-DMRT1 monoclonal antibody 4F6 against X. laevis DMRT1. (A) Immunoblot analysis using the anti-FLAG (M5) or anti-DMRT1 (4F6) monoclonal antibodies. pcDNA3-FLAG or pcDNA3-FLAG-DMRT1 was transiently transfected into 293T cells. Extracts of 293T cells were examined by immunoblotting with each antibody followed by a HRP conjugated anti-mouse IgG antibody. DMRT1 was detected as a single band at the same size by both antibodies (arrowhead). (B) Immunoprecipitation (IP) analysis with the anti-FLAG (M5) or anti-DMRT1 (4F6) monoclonal antibodies. pcDNA3-FLAG-DMRT1 was transiently transfected into 293T cells. The cell lysate was mixed with each antibody and pulled down with protein A/G agarose. IP extracts were examined by immunoblotting using the anti-DMRT1 polyclonal antibody followed by a HRP conjugated anti-rabbit IgG antibody. (C) Immunohistochemical analysis using the anti-DMRT1 monoclonal antibody 4F6 (1/10) and anti-DMRT1 polyclonal antibodies (1/1000) . Frozen sections of adult testis were stained with Hoechst 33258 for nuclei and reacted with both the antibodies, followed by Alexa 594-conjugated anti-mouse (red) and Alexa 488 anti-rabbit-IgG (green) antibodies. Both signals showed the same staining patterns.

PACT/PRKRA has the potential to enhance transcriptional activity of DMRT1

Immunoprecipitates obtained by the anti-DMRT1 monoclonal antibody 4F6 and normal mouse IgG as a negative control from X. laevis adult testes were separated by SDS-PAGE, followed by silver staining. We compared the staining patterns between the two IP samples, and observed seven bands specific to 4F6 (Figure 2). Each band derived from 4F6 and its corresponding region derived from normal IgG were excised from the gels and analyzed by mass spectrometry. We identified 332 proteins from the 4F6 IP sample. From these, 124 proteins were selected as 4F6-specific proteins, because the remaining 208 proteins were also found in the sample using normal IgG. We then focused on three proteins, Prohibitin 2 (PHB2), Y-box binding protein-1 (YB-1), and PACT/PRKRA, which are all known to function in nuclei.

Figure 2
Silver staining of immunoprecipitates using the anti-DMRT1 monoclonal antibody 4F6 from X. laevis adult testes. Testis extracts were mixed with normal mouse IgG or the anti-DMRT1 antibody 4F6, and pulled down with protein A/G agarose. The immunoprecipitates were examined by silver staining (the right and middle lanes) or immunoblotted with an anti-DMRT1 polyclonal antibody (right lane). Seven 4F6-specific bands were excised, and examined by LC-MS.

To clarify how PHB2, YB-1, and PACT/PRKRA are involved in DMRT1 function, we investigated the effect of each protein on transcriptional regulation by DMRT1 using the luciferase reporter assay. Expression plasmids for each protein and DMRT1, as well as a DMRT1-driven luciferase reporter plasmid carrying four repeats of the DMRT1-binding sequence 5’-TTGATACATTGTTGC-3’ (Yoshimoto et al., 2010Yoshimoto S, Ikeda N, Izutsu Y, Shiba T, Takamatsu N and Ito M (2010) Opposite roles of DMRT1 and its W-linked paralogue, DM-W, in sexual dimorphism of Xenopus laevis: implications of a ZZ/ZW-type sex-determining system. Development 137:2519-2526.) were co-transfected into 293T cells (Figure S1). Exogenous expression of PHB2 had a small effect and YB-1 a slightly stronger effect on luciferase activities driven by DMRT1. In contrast, PACT/PRKRA greatly enhanced the DMRT1-driven activity in a dose-dependent manner (Figure 3 and Figure S1).

Figure 3
Effects of PACT/PRKRA and/or p53 on transcriptional activity by DMRT1 using luciferase reporter assay. 150 ng of DMRT1-driven firefly luciferase reporter plasmid (p4xDMRT1-luc), 3.3 ng of DMRT1 expression plasmid (pcDNA3-FLAG-DMRT1), and 10 ng Renilla luciferase vector (pRL-TK-luc) as transfection internal control in the presence or absence of PACT/PRKRA and/or p53 expression plasmids (pcDNA3-FLAG-PACT/PRKRA and/or -p53) were transiently co-transfected into 293T cells, using 1.2 μg PEI MAX. Total amount of DNA was kept at 250 ng per each transfection with pcDNA3-FLAG empty vector. 24 hours after transfection, cell lysates were used to measure luciferase activity. Relative activity is shown as the fold increase compared with the value obtained with 250 ng of pcDNA3-FLAG empty vector. The symbols -, +, and ++ indicate 0, 3.3, and 20 ng, respectively. Values are expressed as mean ± SE, n = 3. The letters above the bars indicate the results of Tukey HSD test following one-way ANOVA (p < 0.05).

We also examined whether each protein could directly interact with DMRT1 in cultured cells. After co-expression of DMRT1 and S-tagged PHB2, YB-1, and PACT/PRKRA in 293T cells, the cell extracts were mixed with S-protein agarose. Then, the pull-down samples as well as the cell extracts were examined by western blot analysis (data not shown). No signals for DMRT1 bound to PHB2, YB-1, or PACT/PRKRA could be detected, indicating the possibility of indirect interactions with DMRT1.

p53 has the potential to repress transcriptional activity of DMRT1

PACT/PRKRA was characterized as a negative regulator of p53 (Li et al., 2007Li L, Deng B, Xing G, Teng Y, Tian C, Cheng X, Yin X, Yang J, Gao X, Zhu Y et al. (2007) PACT is a negative regulator of p53 and essential for cell growth and embryonic development. Proc Natl Acad Sci U S A 104:7951-7956.). Thus, we investigated the effects of p53 on transcriptional activity of DMRT1 in the presence and absence of exogenous PACT/PRKRA using the luciferase reporter assay in co-transfected 293T cells (Figure 3). The DMRT1-driven luciferase activity enhanced by PACT/PRKRA was found strongly and dose-dependently down-regulated by p53 expression. Interestingly, even in the assay without exogenous PACT/PRKRA, the DMRT1-driven activity was also significantly repressed by p53 expression in a dose-dependent manner.

Pact/Prkra mRNA is expressed in germline stem cells of the tadpole gonads

Because Pact/Prkra can contribute to upregulation of DMRT1 function, we next investigated the expression profile of Pact/Prkra mRNA in developing gonads in X. laevis. We first performed an RT-qPCR analysis of Pact/Prkra transcripts during gonadal development (Figure 4A). The Pact/Prkra transcripts showed no or only few significant differences between ZW and ZZ gonads from stage 50, just after sex determination, to stage 65, when metamorphosis is almost completely finished. In addition, the transcripts of ZW or ZZ gonads exhibited uniform expression during tadpole development. In contrast, the amount of the Pact/Prkra mRNA gradually increased in adult testes from 6 weeks after metamorphosis to 1-2 years, which might be related to a prosperous spermatogenesis.

Figure 4
Expression of PACT/PRKRA mRNA in developing ZW and ZZ gonads. (A) Quantitative RT-PCR analysis of Pact/Prkra mRNA during gonadal development of ZW (red) and ZZ (blue) tadpoles and adults in X. laevis. cDNAs were synthesized using total RNAs from ZW and ZZ gonads at various stages of tadpoles after sex determination, and at 6 weeks, 1 year, and 2 years of frogs after metamorphosis, and then amplified by PCR using specific primer pairs as described in Table S1. W and Y show weeks and year(s), respectively. EF1α was used for normalization. RT-qPCR data represent the mean (n=3) and SD. Values are expressed as mean ± SE, n = 3. Differences among stages were evaluated by one-way ANOVA followed by the Tukey HSD test (p < 0.05). Mean values not sharing the same letters are significantly different from each other. Sexual differences between ZZ and ZW gonads at each stage were evaluated or by Student’s t-test (*p < 0.05). N.S., not significant. (B) Distribution of Pact/Prkra mRNAs on transverse sections of ZW and ZZ tadpole gonads at stage 56. Whole-mount in situ hybridization of the gonads with the attached mesonephros was performed with the Pact/Prkra sense or anti-sense RNA probe, followed by 7-μm cryostat sectioning. The sections were treated with an anti-VASA monoclonal antibody to identify germ cells (red) and Hoechst 33258 for nuclei (blue). Note that the nuclei in germ cells were faintly stained by Hoechst 33258. Arrowheads indicate Pact/Prkra-expressing germ cells. Scale bars, 20 μm.

Next, to clarify the topological distribution of the Pact/Prkra mRNA, we used DIG-labeled Pact/Prkra RNA sense and anti-sense probes to perform a whole mount in situ hybridization on stage 56 ZW and ZZ tadpole gonads, which started displaying sexual differences in morphology. To topologically identify Pact/Prkra-expressing cells, we analyzed sections that were counterstained with an anti-VASA antibody and the nuclear stain Hoechst 33258 (Figure 4B). Germline stem cells are characterized as not only expressing of VASA, but also faint staining of their nuclei. The anti-sense probe seemed to hybridize to Pact/Prkra mRNA in both somatic and germ cells of the ZW and ZZ gonads, while almost no signals were detected with the sense probe. Strong signals were observed in some germline stem cells of both sexes.

Discussion

For comprehending gonadal development, including sex determination and differentiation, in the African clawed frog X. laevis carrying a ZZ/ZW-type sex-determining system, we previously identified Dmrt1 and its W-linked paralog Dm-W, and characterized the former as a gene for testis formation and germ-cell development and the latter as a female sex-determining gene (Yoshimoto et al., 2006Yoshimoto S, Okada E, Oishi T, Numagami R, Umemoto H, Tamura K, Kanda H, Shiba T, Takamatsu N and Ito M (2006) Expression and promoter analysis of Xenopus DMRT1 and functional characterization of the transactivation property of its protein. Dev Growth Differ 48:597-603., 2008Yoshimoto S, Okada E, Umemoto H, Tamura K, Uno Y, Nishida-Umehara C, Matsuda Y, Takamatsu N, Shiba T and Ito M (2008) A W-linked DM-domain gene, DM-W, participates in primary ovary development in Xenopus laevis. Proc Natl Acad Sci U S A 105:2469-2474., 2010Yoshimoto S, Ikeda N, Izutsu Y, Shiba T, Takamatsu N and Ito M (2010) Opposite roles of DMRT1 and its W-linked paralogue, DM-W, in sexual dimorphism of Xenopus laevis: implications of a ZZ/ZW-type sex-determining system. Development 137:2519-2526.; Yoshimoto and Ito, 2011Yoshimoto S and Ito M (2011) A ZZ/ZW-type sex determination in Xenopuslaevis. FEBS J 278:1020-1026.; Fujitani et al., 2016Fujitani K, Otomo A, Wada M, Takamatsu N and Ito M (2016) Sexually dimorphic expression of Dmrt1 and γH2AX in germ stem cells during gonadal development in Xenopus laevis. FEBS Open Bio 6:276-284.; Mawaribuchi et al., 2017aMawaribuchi S, Musashijima M, Wada M, Izutsu Y, Kurakata E, Park MK, Takamatsu N and Ito M (2017a) Molecular evolution of two distinct Dmrt1 promoters for germ and somatic cells in vertebrate gonads. Mol Biol Evol 34:724-733.). We also reported on the molecular evolution of Dmrt1 family genes (Mawaribuchi et al., 2012Mawaribuchi S, Yoshimoto S, Ohashi S, Takamatsu N and Ito M (2012) Molecular evolution of vertebrate sex-determining genes. Chromosome Res 20:139-151., 2017aMawaribuchi S, Musashijima M, Wada M, Izutsu Y, Kurakata E, Park MK, Takamatsu N and Ito M (2017a) Molecular evolution of two distinct Dmrt1 promoters for germ and somatic cells in vertebrate gonads. Mol Biol Evol 34:724-733. bMawaribuchi S, Takahashi S, Wada M, Uno Y, Matsuda Y, Kondo M, Fukui A, Takamatsu N, Taira M and Ito M (2017b) Sex chromosome differentiation and the W- and Z-specific loci in Xenopus laevis. Dev Biol 426:393-400.). However, it remained unknown how DMRT1 activates or represses transcription of its target genes in gonadal somatic cells and germ cells as a transcription factor. In this study, to understand the transcriptional regulation by DMRT1, we tried to identify such functions of DMRT1 in X. laevis by analyzing immunoprecipitates with an anti-DMRT1 monoclonal antibody from extracts of adult testes. From the more than one hundred identified proteins we selected three, PHB2, YB-1, and PACT/PRKRA for further analysis.

Unexpectedly, a protein-protein binding assay in co-transfected 293T cells indicated that these proteins apparently do not directly interact with DMRT1 (data not shown). Rather, the result suggested that each protein might be indirectly associated with DMRT1 through other DMRT1-binding proteins. PHB2 is an intercellular communicator between nucleus and mitochondria, and suppresses transcription of target genes in nuclei (Bavelloni et al., 2015Bavelloni A, Piazzi M, Raffini M, Faenza I and Blalock WL (2015) Prohibitin 2: At a communications crossroads. IUBMB Life 67:239-254.). In contrast, the transcription factor YB-1 is involved in transcriptional regulation by interacting with other transcription factors, including p53 (Okamoto et al., 2000Okamoto T, Izumi H, Imamura T, Takano H, Ise T, Uchiumi T, Kuwano M and Kohno K (2000) Direct interaction of p53 with the Y-box binding protein, YB-1: A mechanism for regulation of human gene expression. Oncogene 19:6194-6202.). Strikingly, exogenous expression of PHB2 or YB-1 induced only few or no changes in our DMRT1-driven luciferase reporter assay (Figure S1), indicating that transcription driven by PHB2 or YB-1 could be by indirect interaction with DMRT1.

In the DMRT1-driven luciferase reporter assay using transfected 293T cells, only PACT/PRKRA enhanced the luciferase activity significantly (Figure 3 and Figure S1). PACT/PRKR is also known as RAX, P2P-R, and RBBP6. Importantly, p53 significantly repressed the enhanced activity by PACT/PRKRA (Figure 3), indicating a p53-PACT/PRKRA and DMRT1-PACT/PRKRA interaction. We also found that p53 could moderately attenuate the DMRT1-driven activity in the absence of exogenous expression of PACT/PRKRA. Because we could not observe a direct interaction between DMRT1 and p53 in co-transfected 293T cells (data not shown), p53 might also indirectly participate in the PACT/PRKRA-independent transcription by DMRT1.

The next two questions we asked were: In what types of cells does PACT/PRKRA enhance transcriptional activity by DMRT1 or p53 repress its enhanced activity? And what does the regulation by PACT/PRKRA and/or p53 mean? In situ hybridization analysis showed that PACT/PRKRA was highly expressed in female and male germline stem cells (oogonia and spematogonia) in tadpole gonads of X. laevis (Figure 4B). This observation coincided with the expression pattern during gonadal development in ZW and ZZ tadpoles and adults (Figure 4A). We recently reported that, in X. laevis germline stem cells, DMRT1 and a phosphorylated form of the histone variant H2AX (γH2AX) could contribute to the maintenance of their stem cell identity and participate in genome protection against double strand breaks, respectively (Fujitani et al., 2016Fujitani K, Otomo A, Wada M, Takamatsu N and Ito M (2016) Sexually dimorphic expression of Dmrt1 and γH2AX in germ stem cells during gonadal development in Xenopus laevis. FEBS Open Bio 6:276-284.). p53 has been described as “the guardian of the genome”, because it plays important roles in cell cycle regulation, DNA repair, and apoptosis, leading to genome stability by preventing mutations or eliminating DNA-damaged, mutated cells. For the next generation, p53 functions to guarantee germ cell quality (Takashima et al., 2013Takashima S, Hirose M, Ogonuki N, Ebisuya M, Inoue K, Kanatsu-Shinohara M, Tanaka T, Nishida E, Ogura A and Shinohara T (2013) Regulation of pluripotency in male germline stem cells by Dmrt1. Genes Dev 27:1949-1958.; Gebel et al., 2017Gebel J, Tuppi M, Krauskopf K, Coutandin D, Pitzius S, Kehrloesser S, Osterburg C and Dötsch V (2017) Control mechanisms in germ cells mediated by p53 family proteins. J Cell Sci 130:2663-2671.), as in mouse spermatogonial stem cells, Dmrt1 depletion causes apoptosis, but both Dmrt1 and p53 depletion induces pluripotency, suggesting that p53 and DMRT1 might play contrary and/or related roles in spermatogonial stem cells. In other words, the balance between DMRT1 and p53 might maintain germline stem cell identity. Taken together, these findings suggest that PACT/PRKRA might enhance DMRT1 function for germline stem cell identity, but p53 negatively controls DMRT1 function, leading to apoptosis in damaged, mutated germline stem cells. In addition, YB-1, one of the three DMRT1-interacting proteins identified in this study, was found to directly bind with p53 (Okamoto et al., 2000Okamoto T, Izumi H, Imamura T, Takano H, Ise T, Uchiumi T, Kuwano M and Kohno K (2000) Direct interaction of p53 with the Y-box binding protein, YB-1: A mechanism for regulation of human gene expression. Oncogene 19:6194-6202.), as described above. It is possible that germline stem cell identity regulated by DMRT1 and p53 might be mediated not only through PACT/PRKRA, but also YB-1.

PACT/PRKRA has been characterized as a dsRNA binding protein (Redfern et al., 2013Redfern AD, Colley SM, Beveridge DJ, Ikeda N, Epis MR, Li X, Foulds CE, Stuart LM, Barker A, Russell VJ et al. (2013) RNA-induced silencing complex (RISC) proteins PACT, TRBP, and Dicer are SRA binding nuclear receptor coregulators. Proc Natl Acad Sci U S A 110:6536-6541.), a RISC (RNA-induced silencing complex) member required for subsequent siRNA-mediated post-transcriptional gene silencing (Patel and Sen, 1998Patel RC and Sen GC (1998) PACT, a protein activator of the interferon-induced protein kinase, PKR. EMBO J 17:4379-4390.), and an activator of protein kinase R (PKR), also known as interferon-induced, dsRNA-activated protein kinase (Huang et al., 2002Huang X, Hutchins B and Patel RC (2002) The C-terminal, third conserved motif of the protein activator PACT plays an essential role in the activation of double-stranded-RNA-dependent protein kinase (PKR). Biochem J 366:175-186.). We presently have no indication on whether and how dsRNA/RISC may be involved in the PACT/PRKRA-DMRT1 interaction. Interestingly, PKR is associated with p53 (Cuddihy et al., 1999Cuddihy AR, Hoi-Tao WA, Wai NTN, Li S and Koromilas AE (1999) The double-stranded RNA activated protein kinase PKR physically associates with the tumor suppressor p53 protein and phosphorylates human p53 on serine 392 in vitro. Oncogene 18:2690-2702.), and PACT/PRKRA-PKR signaling in response to stress-inhibited p53 turnover lead to G1 cell cycle arrest (Bennett et al., 2012Bennett RL, Pan Y, Christian J, Hui T and May WS (2012) The RAX/PACT-PKR stress response pathway promotes p53 sumoylation and activation, leading to G1 arrest. Cell Cycle 11:407-417.). It will be interesting to clarify whether the two signaling modules, PACT/PRKRA-PKR-p53 and DMRT1-PACT/PRKRA-p53, have mutual relation in germline stem cells.

Acknowledgments

We are grateful for funding support by Grant-in-Aid for Scientific Research from the Ministry of Education, Culture, Sports, Science, and Technology [22132003 to M.I.]. We also greatly thank Jim Goddard for careful reading and commenting on the manuscript.

References

Bavelloni A, Piazzi M, Raffini M, Faenza I and Blalock WL (2015) Prohibitin 2: At a communications crossroads. IUBMB Life 67:239-254.
Bennett RL, Pan Y, Christian J, Hui T and May WS (2012) The RAX/PACT-PKR stress response pathway promotes p53 sumoylation and activation, leading to G1 arrest. Cell Cycle 11:407-417.
Cuddihy AR, Hoi-Tao WA, Wai NTN, Li S and Koromilas AE (1999) The double-stranded RNA activated protein kinase PKR physically associates with the tumor suppressor p53 protein and phosphorylates human p53 on serine 392 in vitro Oncogene 18:2690-2702.
Fujitani K, Otomo A, Wada M, Takamatsu N and Ito M (2016) Sexually dimorphic expression of Dmrt1 and γH2AX in germ stem cells during gonadal development in Xenopus laevis FEBS Open Bio 6:276-284.
Gebel J, Tuppi M, Krauskopf K, Coutandin D, Pitzius S, Kehrloesser S, Osterburg C and Dötsch V (2017) Control mechanisms in germ cells mediated by p53 family proteins. J Cell Sci 130:2663-2671.
Huang X, Hutchins B and Patel RC (2002) The C-terminal, third conserved motif of the protein activator PACT plays an essential role in the activation of double-stranded-RNA-dependent protein kinase (PKR). Biochem J 366:175-186.
Ito M, Yoshioka K, Akechi M, Yamashita S, Takamatsu N, Sugiyama K, Hibi M, Nakabeppu Y, Shiba T and Yamamoto KI (1999) JSAP1, a novel jun N-terminal protein kinase (JNK)-binding protein that functions as a scaffold factor in the JNK signaling pathway. Mol Cell Biol 19:7539-7548.
Krentz AD, Murphy MW, Sarver AL, Griswold MD, Bardwell VJ and Zarkower D (2011) DMRT1 promotes oogenesis by transcriptional activation of Stra8 in the mammalian fetal ovary. Dev Biol 356:63-70.
Li L, Deng B, Xing G, Teng Y, Tian C, Cheng X, Yin X, Yang J, Gao X, Zhu Y et al. (2007) PACT is a negative regulator of p53 and essential for cell growth and embryonic development. Proc Natl Acad Sci U S A 104:7951-7956.
Masuyama H, Yamada M, Kamei Y, Fujiwara-Ishikawa T, Todo T, Nagahama Y and Matsuda M (2012) Dmrt1 mutation causes a male-to-female sex reversal after the sex determination by Dmy in the medaka. Chromosome Res 20:163-176.
Matson CK, Murphy MW, Griswold MD, Yoshida S, Bardwell VJ and Zarkower D (2010) The mammalian doublesex homolog DMRT1 is a transcriptional gatekeeper that controls the mitosis versus meiosis decision in male germ cells. Dev Cell 19:612-24.
Matson CK, Murphy MW, Sarver AL, Griswold MD, Bardwell VJ and Zarkower D (2011) DMRT1 prevents female reprogramming in the postnatal mammalian testis. Nature 476:101-105.
Matsuda M, Nagahama Y, Shinomiya A, Sato T, Matsuda C, Kobayashi T, Morrey CE, Shibata N, Asakawa S, Shimizu N et al. (2002) DMY is a Y-specific DM-domain gene required for male development in the medaka fish. Nature 417:559-563.
Mawaribuchi S, Yoshimoto S, Ohashi S, Takamatsu N and Ito M (2012) Molecular evolution of vertebrate sex-determining genes. Chromosome Res 20:139-151.
Mawaribuchi S, Musashijima M, Wada M, Izutsu Y, Kurakata E, Park MK, Takamatsu N and Ito M (2017a) Molecular evolution of two distinct Dmrt1 promoters for germ and somatic cells in vertebrate gonads. Mol Biol Evol 34:724-733.
Mawaribuchi S, Takahashi S, Wada M, Uno Y, Matsuda Y, Kondo M, Fukui A, Takamatsu N, Taira M and Ito M (2017b) Sex chromosome differentiation and the W- and Z-specific loci in Xenopus laevis Dev Biol 426:393-400.
Nanda I, Kondo M, Hornung U, Asakawa S, Winkler C, Shimizu A, Shan Z, Haaf T, Shimizu N, Shima A et al. (2002) A duplicated copy of DMRT1 in the sex-determining region of the Y chromosome of the medaka, Oryzias latipes Proc Natl Acad Sci U S A 99:11778-11783.
Nieuwkoop PD and Faber J (1956) Normal table of Xenopus laevis (Daudin): A systematical and chronological survey of the development from the fertilized egg till the end of metamorphosis. North Holland Publ. Co, Amsterdam, 243 pp.
Okamoto T, Izumi H, Imamura T, Takano H, Ise T, Uchiumi T, Kuwano M and Kohno K (2000) Direct interaction of p53 with the Y-box binding protein, YB-1: A mechanism for regulation of human gene expression. Oncogene 19:6194-6202.
Patel RC and Sen GC (1998) PACT, a protein activator of the interferon-induced protein kinase, PKR. EMBO J 17:4379-4390.
Redfern AD, Colley SM, Beveridge DJ, Ikeda N, Epis MR, Li X, Foulds CE, Stuart LM, Barker A, Russell VJ et al. (2013) RNA-induced silencing complex (RISC) proteins PACT, TRBP, and Dicer are SRA binding nuclear receptor coregulators. Proc Natl Acad Sci U S A 110:6536-6541.
Sado Y, Inoue S, Tomono Y and Omori H (2006) Lymphocytes from enlarged iliac lymph nodes as fusion partners for the production of monoclonal antibodies after a single tail base immunization attempt. Acta Histochem Cytochem 39:89-94.
Smith CA, Roeszler KN, Ohnesorg T, Cummins DM, Farlie PG, Doran TJ and Sinclair AH (2009) The avian Z-linked gene DMRT1 is required for male sex determination in the chicken. Nature 461:267-271.
Takashima S, Hirose M, Ogonuki N, Ebisuya M, Inoue K, Kanatsu-Shinohara M, Tanaka T, Nishida E, Ogura A and Shinohara T (2013) Regulation of pluripotency in male germline stem cells by Dmrt1. Genes Dev 27:1949-1958.
Wada M, Fujitani K, Tamura K, Mawaribuchi S, Kamata Y, Takamatsu N and Ito M (2017) Masculinization-related genes and cell-mass structures during early gonadal differentiation in the African Clawed Frog Xenopus laevis Zoolog Sci 34:105-111.
Yoshimoto S, Okada E, Oishi T, Numagami R, Umemoto H, Tamura K, Kanda H, Shiba T, Takamatsu N and Ito M (2006) Expression and promoter analysis of Xenopus DMRT1 and functional characterization of the transactivation property of its protein. Dev Growth Differ 48:597-603.
Yoshimoto S, Okada E, Umemoto H, Tamura K, Uno Y, Nishida-Umehara C, Matsuda Y, Takamatsu N, Shiba T and Ito M (2008) A W-linked DM-domain gene, DM-W, participates in primary ovary development in Xenopus laevis Proc Natl Acad Sci U S A 105:2469-2474.
Yoshimoto S, Ikeda N, Izutsu Y, Shiba T, Takamatsu N and Ito M (2010) Opposite roles of DMRT1 and its W-linked paralogue, DM-W, in sexual dimorphism of Xenopus laevis: implications of a ZZ/ZW-type sex-determining system. Development 137:2519-2526.
Yoshimoto S and Ito M (2011) A ZZ/ZW-type sex determination in Xenopuslaevis FEBS J 278:1020-1026.
Zhao L, Svingen T, Ng ET and Koopman P (2015) Female-to-male sex reversal in mice caused by transgenic overexpression of Dmrt1. Development 142:1083-1088.

Supplementary material

The following online material is available for this article:

Figure S1 - Effects of PHB2, YB1, and PACT/PRKRA on transcriptional activity by DMRT1 using luciferase reporter assay.

Table S1 - Sequences of oligonucleotide primers used in PCR reaction for cloning.

Associate Editor: Juan Lucas Argueso Almeida

Publication Dates

Publication in this collection
30 Mar 2020
Date of issue
2020

History

Received
23 Jan 2019
Accepted
08 May 2019

License information: This is an open-access article distributed under the terms of the Creative Commons Attribution License (type CC-BY), which permits unrestricted use, distribution and reproduction in any medium, provided the original article is properly cited.

[1] Bavelloni A, Piazzi M, Raffini M, Faenza I and Blalock WL (2015) Prohibitin 2: At a communications crossroads. IUBMB Life 67:239-254.

[2] Bennett RL, Pan Y, Christian J, Hui T and May WS (2012) The RAX/PACT-PKR stress response pathway promotes p53 sumoylation and activation, leading to G1 arrest. Cell Cycle 11:407-417.

[3] Cuddihy AR, Hoi-Tao WA, Wai NTN, Li S and Koromilas AE (1999) The double-stranded RNA activated protein kinase PKR physically associates with the tumor suppressor p53 protein and phosphorylates human p53 on serine 392 in vitro Oncogene 18:2690-2702.

[4] Fujitani K, Otomo A, Wada M, Takamatsu N and Ito M (2016) Sexually dimorphic expression of Dmrt1 and γH2AX in germ stem cells during gonadal development in Xenopus laevis FEBS Open Bio 6:276-284.

[5] Gebel J, Tuppi M, Krauskopf K, Coutandin D, Pitzius S, Kehrloesser S, Osterburg C and Dötsch V (2017) Control mechanisms in germ cells mediated by p53 family proteins. J Cell Sci 130:2663-2671.

[6] Huang X, Hutchins B and Patel RC (2002) The C-terminal, third conserved motif of the protein activator PACT plays an essential role in the activation of double-stranded-RNA-dependent protein kinase (PKR). Biochem J 366:175-186.

[7] Ito M, Yoshioka K, Akechi M, Yamashita S, Takamatsu N, Sugiyama K, Hibi M, Nakabeppu Y, Shiba T and Yamamoto KI (1999) JSAP1, a novel jun N-terminal protein kinase (JNK)-binding protein that functions as a scaffold factor in the JNK signaling pathway. Mol Cell Biol 19:7539-7548.

[8] Krentz AD, Murphy MW, Sarver AL, Griswold MD, Bardwell VJ and Zarkower D (2011) DMRT1 promotes oogenesis by transcriptional activation of Stra8 in the mammalian fetal ovary. Dev Biol 356:63-70.

[9] Li L, Deng B, Xing G, Teng Y, Tian C, Cheng X, Yin X, Yang J, Gao X, Zhu Y et al. (2007) PACT is a negative regulator of p53 and essential for cell growth and embryonic development. Proc Natl Acad Sci U S A 104:7951-7956.

[10] Masuyama H, Yamada M, Kamei Y, Fujiwara-Ishikawa T, Todo T, Nagahama Y and Matsuda M (2012) Dmrt1 mutation causes a male-to-female sex reversal after the sex determination by Dmy in the medaka. Chromosome Res 20:163-176.

[11] Matson CK, Murphy MW, Griswold MD, Yoshida S, Bardwell VJ and Zarkower D (2010) The mammalian doublesex homolog DMRT1 is a transcriptional gatekeeper that controls the mitosis versus meiosis decision in male germ cells. Dev Cell 19:612-24.

[12] Matson CK, Murphy MW, Sarver AL, Griswold MD, Bardwell VJ and Zarkower D (2011) DMRT1 prevents female reprogramming in the postnatal mammalian testis. Nature 476:101-105.

[13] Matsuda M, Nagahama Y, Shinomiya A, Sato T, Matsuda C, Kobayashi T, Morrey CE, Shibata N, Asakawa S, Shimizu N et al. (2002) DMY is a Y-specific DM-domain gene required for male development in the medaka fish. Nature 417:559-563.

[14] Mawaribuchi S, Yoshimoto S, Ohashi S, Takamatsu N and Ito M (2012) Molecular evolution of vertebrate sex-determining genes. Chromosome Res 20:139-151.

[15] Mawaribuchi S, Musashijima M, Wada M, Izutsu Y, Kurakata E, Park MK, Takamatsu N and Ito M (2017a) Molecular evolution of two distinct Dmrt1 promoters for germ and somatic cells in vertebrate gonads. Mol Biol Evol 34:724-733.

[16] Mawaribuchi S, Takahashi S, Wada M, Uno Y, Matsuda Y, Kondo M, Fukui A, Takamatsu N, Taira M and Ito M (2017b) Sex chromosome differentiation and the W- and Z-specific loci in Xenopus laevis Dev Biol 426:393-400.

[17] Nanda I, Kondo M, Hornung U, Asakawa S, Winkler C, Shimizu A, Shan Z, Haaf T, Shimizu N, Shima A et al. (2002) A duplicated copy of DMRT1 in the sex-determining region of the Y chromosome of the medaka, Oryzias latipes Proc Natl Acad Sci U S A 99:11778-11783.

[18] Nieuwkoop PD and Faber J (1956) Normal table of Xenopus laevis (Daudin): A systematical and chronological survey of the development from the fertilized egg till the end of metamorphosis. North Holland Publ. Co, Amsterdam, 243 pp.

[19] Okamoto T, Izumi H, Imamura T, Takano H, Ise T, Uchiumi T, Kuwano M and Kohno K (2000) Direct interaction of p53 with the Y-box binding protein, YB-1: A mechanism for regulation of human gene expression. Oncogene 19:6194-6202.

[20] Patel RC and Sen GC (1998) PACT, a protein activator of the interferon-induced protein kinase, PKR. EMBO J 17:4379-4390.

[21] Redfern AD, Colley SM, Beveridge DJ, Ikeda N, Epis MR, Li X, Foulds CE, Stuart LM, Barker A, Russell VJ et al. (2013) RNA-induced silencing complex (RISC) proteins PACT, TRBP, and Dicer are SRA binding nuclear receptor coregulators. Proc Natl Acad Sci U S A 110:6536-6541.

[22] Sado Y, Inoue S, Tomono Y and Omori H (2006) Lymphocytes from enlarged iliac lymph nodes as fusion partners for the production of monoclonal antibodies after a single tail base immunization attempt. Acta Histochem Cytochem 39:89-94.

[23] Smith CA, Roeszler KN, Ohnesorg T, Cummins DM, Farlie PG, Doran TJ and Sinclair AH (2009) The avian Z-linked gene DMRT1 is required for male sex determination in the chicken. Nature 461:267-271.

[24] Takashima S, Hirose M, Ogonuki N, Ebisuya M, Inoue K, Kanatsu-Shinohara M, Tanaka T, Nishida E, Ogura A and Shinohara T (2013) Regulation of pluripotency in male germline stem cells by Dmrt1. Genes Dev 27:1949-1958.

[25] Wada M, Fujitani K, Tamura K, Mawaribuchi S, Kamata Y, Takamatsu N and Ito M (2017) Masculinization-related genes and cell-mass structures during early gonadal differentiation in the African Clawed Frog Xenopus laevis Zoolog Sci 34:105-111.

[26] Yoshimoto S, Okada E, Oishi T, Numagami R, Umemoto H, Tamura K, Kanda H, Shiba T, Takamatsu N and Ito M (2006) Expression and promoter analysis of Xenopus DMRT1 and functional characterization of the transactivation property of its protein. Dev Growth Differ 48:597-603.

[27] Yoshimoto S, Okada E, Umemoto H, Tamura K, Uno Y, Nishida-Umehara C, Matsuda Y, Takamatsu N, Shiba T and Ito M (2008) A W-linked DM-domain gene, DM-W, participates in primary ovary development in Xenopus laevis Proc Natl Acad Sci U S A 105:2469-2474.

[28] Yoshimoto S, Ikeda N, Izutsu Y, Shiba T, Takamatsu N and Ito M (2010) Opposite roles of DMRT1 and its W-linked paralogue, DM-W, in sexual dimorphism of Xenopus laevis: implications of a ZZ/ZW-type sex-determining system. Development 137:2519-2526.

[29] Yoshimoto S and Ito M (2011) A ZZ/ZW-type sex determination in Xenopuslaevis FEBS J 278:1020-1026.

[30] Zhao L, Svingen T, Ng ET and Koopman P (2015) Female-to-male sex reversal in mice caused by transgenic overexpression of Dmrt1. Development 142:1083-1088.

Brasil