Abstract
Although the negative regulator of nuclear import (NRNI) BRCA1 binding protein 2 (BRAP2) is highly expressed in testis, its role is largely unknown. Here we address this question by documenting the BRAP2 interactome from human testis, using the yeast 2-hybrid system to identify BRAP2-interacting proteins with roles in diverse cellular processes, including regulation of the actin cytoskeleton, ubiquitinylation, cell cycle/apoptosis and transcription. Interaction with BRAP2 in adult mouse testis with three of these, PH domain and leucine rich repeat protein phosphatase 1 (PHLPP1), A-Kinase anchor protein (AKAP3) and DNA methyl transferase 1 (DNMT1), was confirmed by coimmunoprecipitation assays. BRAP2's ability to inhibit PHLPP1 and DNMT1 nuclear localisation was also confirmed by quantitative confocal microscopy. Importantly, the physiological relevance thereof was implied by the cytoplasmic localisation of PHLPP1, AKAP3 and DNMT1 in pachytene spermatocytes/round spermatids where BRAP2 is present at high levels and nuclear localisation of PHLPP1 and DNMT1 in spermatogonia concomitant with lower levels of BRAP2. Interestingly, BRAP2 was also present in murine spermatozoa, in part colocalised with AKAP3. Together the results indicate for the first time that BRAP2 may play an important NRNI role in germ cells of the testis, with an additional, scaffold/structural role in mature spermatozoa.
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Introduction
Regulated nucleocytoplasmic trafficking of macromolecules is critical to a range of eukaryotic cellular processes, including oncogenesis, differentiation and development1,2,3,4. An example is mammalian spermatogenesis, by which an ordered, sequential series of germ cell type changes lead to a mature spermatozoan able to fertilise a mature ovum, where the regulation of nuclear transport in response to cellular signals is a key driver5. One mechanism by which nucleocytoplasmic transport can be regulated is through negative regulators of nuclear import (NRNIs), of which the BRCA1 binding protein 2 (BRAP2) is an example that acts by binding to the nuclear localisation signal (NLS) of cargo proteins such as BRCA1, cyclin-dependent kinase inhibitor 1 (p21) and viral proteins including the SV40 large tumour antigen (T-ag) and human papilloma virus proteins2,6,7 and retaining them in the cytoplasm. Dysregulation of BRAP2 is also linked to cancers8,9,10,11 and inflammatory dysfunction of cardiovascular system in humans12, underlining its importance as a cell regulator.
Although, highly expressed in testis13, the specific role of BRAP2 and the target proteins it may bind is largely unknown. To address this directly, we performed a yeast-2-hybrid (Y2H) screen using an adult human testis cDNA library, to determine the BRAP2 testicular interactome (see Ref. 14). The interactome includes proteins involved in regulation of the actin cytoskeleton, ubiquitinylation, cell cycle/apoptosis and transcription. We validate interaction with three of these; the PH domain and leucine rich repeat protein phosphatase 1 (PHLPP1), DNA methyl transferase 1 (DNMT1) and a testis specific A-Kinase anchor protein 3 (AKAP3), as targets of BRAP2 action for the first time, underlining BRAP2's role not only as an NRNI, but as a component within mature spermatozoa that may fulfil a structural or scaffold role.
Results
The BRAP2 interactome in testis
Although BRAP2 is highly expressed in the mammalian testis (Fig. 1a; see Ref. 13), very little is known about its specific role. To address this question, we performed a large scale yeast-2-hybrid (Y2H) screen to identify binding partners of BRAP2 from a human testis cDNA library (see also Ref. 14). We identified a total of 27 proteins (see Table 1), which constitute the first definitive insight into BRAP2 interactome. The interactors could be categorised as playing roles in actin binding/cytoskeletal organisation, DNA/RNA binding/transcriptional regulation, cell cycle/proliferation, ubiquitin signalling pathways and cell apoptosis (see Fig. 1b). The identification of UBB and UBC as BRAP2 interactors, in agreement with previous studies15,16,17 is consistent with BRAP2's E3 Ubiquitin ligase activity. Of the novel protein binding partners identified, tumour suppressor protein PH domain and leucine rich repeat protein phosphatase 1 (PHLPP1), a testis specific A-Kinase anchor protein 3 (AKAP3) and DNA methyl transferase 1 (DNMT1)18,19,20 were selected for validation.
BRAP2 interacts with PHLPP1, DNMT1 and AKAP3 in mouse testis
As a first step, coimmunoprecipitation was performed from adult mouse testis lysate using antibodies specific to PHLPP1, AKAP3 or DNMT1 (Fig. 2a, left) or anti-GST antibody as a negative control. Western analysis indicated that endogenous BRAP2 co-immunoprecipitated with specific antibodies to PHLPP1, AKAP3 or DNMT1, but not with the control antibody, indicating that BRAP2 interacts with these proteins in adult mouse testis. As confirmation, the coimmunoprecipitation was performed using antibody specific to BRAP2, Western analysis indicating that endogenous PHLPP1 (largely the alternatively spliced β-isoform) and AKAP3 could be coimmunoprecipitated with antibodies to BRAP2, but not with control antibody (Fig. 2a, right). Interestingly, BRAP2 interacts with both the α- and the alternatively spliced β-isoform of PHLPP1 (see also Fig. 2b), which selectively dephosphorylate specific AKT isoforms, promoting apoptosis and reducing cell proliferation21. Binding of BRAP2 to both PHLPP1 isoforms may modulate the synergistic action of the PHLPP1 isoforms, providing a strong regulatory mechanism to balance cell proliferation with apoptosis.
In the case of DNMT1, bands lower than that of full length DNMT1 were obtained (not shown) implying degradation; accordingly pull downs were also performed using Hek293T cells co-transfected to transiently express GFP-BRAP2 (343-592) or GFP alone along with Myc-tagged DNMT1, as well as HA-tagged PHLPP1 α- or β-isoforms and GST-tagged AKAP3. All four ectopically expressed proteins were pulled down with GFP-BRAP2 (343-592), but not with GFP alone (Fig. 2b), supporting the results obtained for testis lysates for DNMT1, AKAP3 and both isoforms of PHLPP1.
BRAP2 can acts as an NRNI for PHLPP1 and DNMT1
Whether interaction between BRAP2 and the putative binding partners is functional in terms of altering subcellular localization was assessed in the presence of ectopically expressed DsRed2 fused to BRAP2 residues 343–592 (previously shown to be functional for BRAP2-NRNI activity7) in cells of either the COS-7, which endogenously express the T-ag, or HeLa cell lines. Effects were compared to those for DsRed2 expression alone, with the shorter BRAP2 construct, DsRed2-BRAP2 (442–592)7 also used. Cells were immunostained 20 h post transfection, using specific antibodies for endogenous PHLPP1 or DNMT1, or T-ag as a positive control in COS-7 cells and Alexa 568-labeled secondary antibody, followed by imaging using CLSM. Like the positive control, PHLPP1 and DNMT1 showed reduced nuclear accumulation/increased cytoplasmic staining in presence of DsRed2-BRAP2 compared to in the presence of DsRed2 alone (Fig. 3b–d). Quantitative analysis confirmed these results, whereby determination of the nuclear to cytoplasmic fluorescence ratio (Fn/c) revealed that nuclear accumulation of PHLPP1 and DNMT1 was significantly reduced (p < 0.001; Fig. 3b, ci) in the presence of either DsRed2-BRAP2 construct, in comparable fashion to T-ag (p < 0.0001; Fig. 3d); DsRed2-BRAP2 (442-592) appeared to exert more extensive inhibition (50-70%), implying that BRAP2 residues 442-592 are sufficient for NRNI activity.
The effect of BRAP2 on localisation of DNMT1 was also confirmed in live cell experiments; where HeLa cells were cotransfected to express GFP fused full length human DNMT1 and DsRed2-BRAP2 (343-592) or DsRed2. GFP-DNMT1 showed almost 70% reduction in nuclear accumulation in the presence of Ds-Red2 BRAP2 (343-592 and 442-570), than in its absence (Fig. 3cii, p<0.0001). Overall, the results demonstrate that BRAP2 can function as an NRNI for PHLPP1 and DNMT1.
PHLPP1, AKAP3 and DNMT1 are co-localised to the cytoplasm in germ cells expressing BRAP2 in mouse testis
To put the above results into a physiological context, expression and localisation of BRAP2, together with PHLPP1, AKAP3 and DNMT1 was examined using immunohistochemistry on adult mouse testis sections. Consistent with previous observations14, BRAP2 was detected in the cytoplasm of pachytene spermatocytes, round and elongated spermatids (Fig. 4). PHLPP1, in contrast, was nuclear in spermatogonia, but cytoplasmic in pachytene spermatocytes and round spermatids, the cell types coexpressing BRAP2, consistent with an NRNI role of BRAP2. DNMT1 was also nuclear in spermatogonia, but showed both cytoplasmic and nuclear expression in pachytene spermatocytes and was exclusively cytoplasmic in round spermatids, similarly consistent with cytoplasmic retention by BRAP2 in the cell types coexpressing it. Finally, AKAP3 was absent from earlier germ cell types and present in the cytoplasm of round and elongated spermatids (Fig. 4), indicating that it is present in the same cell types as BRAP2. The results indicate clearly that in the meiotic and the post-meiotic germ cell types where BRAP2 is more highly expressed, all of its binding partners are strongly cytoplasmic, whereas in the premeiotic cell types with lower BRAP2 expression, PHLPP1 and DNMT1 are predominantly nuclear, implying that the NRNI activity of BRAP2 may play an important role during spermatogenesis.
BRAP2 is present in sperm and colocalises with AKAP3
Immunofluorescence was also used to assess the localisation of BRAP2 in relation to that of AKAP3 in spermatozoa. Murine epididymal sperm were fixed and stained with anti-BRAP2, or -AKAP3 antibodies and Alexa 568-labeled secondary antibody and examined by CLSM (Fig. 5). Results demonstrated that BRAP2 was expressed throughout the spermatozoa including the head, mid- and principle piece. AKAP3 was localised to the post acrosomal region and the principal piece demonstrating that BRAP2 and its newly identified binding partner are localised to the some of the same substructures of mature spermatozoa, consistent with the possibility of interaction of the two in vivo.
Discussion
This is the first study to document the interactome of an NRNI from a tissue of physiological context, providing new information regarding BRAP2's role not only as an NRNI, but also in a more structural or scaffold role, including, potentially in mature spermatozoa. A number of novel putative binding partners for BRAP2 were identified, with roles in diverse cell processes, including cytoskeletal organisation, cell cycle/proliferation, gene regulation and ubiquitinylation (see Table 1; Fig. 1b), implying a potentially important role of BRAP2 in these processes. We previously validated the high mobility group chromatin component HMG20A, the nuclear mitotic apparatus protein NUMA1 and nuclear envelope component SYNE214 as binding partners of BRAP2; here we present validation of PHLPP1, DNMT1 and AKAP3 as novel BRAP2 interacting proteins in testis for the first time. In particular, immunoprecipitation from adult mouse testis lysates confirmed the ability of BRAP2 to bind the selected binding partners in the testis, while ectopic expression experiments demonstrated the ability of BRAP2 to act as an NRNI for PHLPP1 and DNMT1. Finally and most importantly, immunohistochemical staining in testis sections demonstrated that in the specific meiotic and post-meiotic germ cell types that express BRAP2, its binding partners PHLPP1, DNMT1 and AKAP3 are strongly cytoplasmic, consistent with an NRNI role for BRAP2 during spermatogenesis. Exactly how this relates to the specific function of the Akt regulator PHLPP1 or DNMT1, which maintains DNA methylation patterns in replicating cells, remains to be established, but since both modulate gene expression in different ways, it does not seem unreasonable to postulate that specific retention of these proteins in the cytoplasm by BRAP2 may be central to transcriptional control in the key cell types of pachytene spermatocytes and round spermatids.
Intriguingly, we were able to show for the first time that BRAP2 is present in mature spermatozoa, in part colocalised with the testis specific protein, AKAP3 which targets protein kinase A to discrete locations within the cell and thereby modulate sperm motility, capacitation and the acrosome reaction19,22. Presumably BRAP2 may contribute to localising AKAP3 to specific areas of the mature sperm to help facilitate these functions; importantly, since AKAP3 is not implicated as having a nuclear role, it would appear that BRAP2's function in this context is not as an NRNI, but more as a scaffold or adaptor protein. That BRAP2 is localised all over the sperm may imply that its role in this context in the mature sperm may relate not only to AKAP3, but potentially to other proteins. A schematic model depicting the putative role of BRAP2 in spermatogenesis in modulating subcellular localisation is presented in Fig. 6.
In summary, this study reports the first tissue interactome for BRAP2. Importantly, it not only supports an important NRNI role for BRAP2 in meiotic and post meiotic germ cells in the testis in preventing nuclear access of proteins such as PHLPP1, DNMT1, HMG20A and NuMA119,22, but also suggests a role for BRAP2 in the mature spermatozoan, potentially as a scaffold supporting the roles of proteins such as AKAP3. Detailed analysis of BRAP2 and its interactors is a high priority for future work in this laboratory, to continue to provide insight into BRAP2's role in spermatogenesis.
Methods
Ethics statement
The procedure of mouse tissue acquisition and experiments were performed in accordance with the guidelines of the NHMRC Code of Practice for the Care and Use of Animals for Experimental Purposes and approved by the Monash University Standing Committee on Ethics in Animal Experimentation. The study was approved by the Monash University Research Committee.
Yeast two-hybrid Screen
To identify BRAP2 binding proteins from testis, a high throughput Y2H system was performed in collaboration with Hybrigenics Inc. (Paris, France) of a random-primed human testis cDNA library using the C terminal fragment (343-592 amino acids) of human BRAP2 (gi: 188497704) as a bait.
Collection of mouse tissues and epididymal sperm
Inbred C57BL/6J (B6) wild type male mice were obtained from Monash University Central Animal Services. Animals were culled by cervical dislocation prior to dissection of the organs and decapsulation (testis and kidneys). To collect sperm the epididymis was nicked and incubated in PBS + 5% FCS for 15–25 min at 37°C. Briefly, sperm released from epididymis were washed thrice using PBS for 5 min at 300 × g, resuspended in PBS and air dried onto polylysine-coated slides as described previously23,24.
Expression plasmid construction
DsRed2-tagged BRAP2 mammalian expression vectors were constructed by inserting the sequences encoding BRAP2 amino acids 343–592 and 442-592, amplified by polymerase chain reaction (all primer sequences used are listed in supplementary Table 1) and cloned into the HindIII and BamHI restriction endonuclease sites, C-terminal to the coding sequence of DsRed2, of plasmid DsRed2-C1 (Clontech, Mountain View, CA, USA). The GFP-fused BRAP2 (encoding amino acids 343–592) expression vector was constructed as described previously7, using the Gateway system (Invitrogen, Carlsbad, CA, USA); in the plasmid vector pDONR207. LR recombination reactions were subsequently performed, using the Gateway-compatible destination vector pEPI-GFP25 to generate GFP-fusion protein-encoding constructs for mammalian cell expression. The integrity of all constructs was verified by DNA sequencing. The mammalian expression plasmids encoding GFP-DNMT126 and GST-AKAP319 were generous gifts from Dr. Heinrich Leonhardt (Faculty of Biology at the LMU, Munich) and Dr. Daniel W. Carr (School of Medicine, Endocrinology; Oregon health and Science universities, Portland), respectively. Plasmids pcDNA3/Myc-DNMT127, pcDNA3-HA-PHLPP1α18 and pcDNA3 HA-PHLPP1β28 were from Addgene (numbers 36939, 22404 and 37100 respectively).
Cell culture
African green monkey kidney COS-7, human cervical cancer HeLa and human embryonic kidney HeK 293T cell lines were cultured and maintained in DMEM/EMEM containing 10% fetal calf serum in a 5% CO2 humidified incubator at 37°C7.
Transfection/immunofluorescence
Cells seeded onto glass coverslips were transfected using Lipofectamine® 2000 (Invitrogen) according to the manufacturer's specifications. 20–24 h post transfection, cells were fixed7 and incubated in anti-SV40 T-ag (Santa Cruz, 1:800) or anti-PHLPP1 (Novus Biologicals, 1:200) or anti-DNMT1 (Abcam, 1:200) primary antibodies, followed by incubation with Alexa 568-labeled goat anti-rabbit secondary antibody or Alexa 568-labeled rabbit anti-mouse secondary antibody (Invitrogen, 1:1000). DNA was counterstained with DNA-specific dye 4,6-diamidino-2-phenylindole (DAPI) using ProLong® Gold Anti-Fade Reagent (Invitrogen).
Immunofluoresence on epididymal sperm was performed using a protocol modified from Herrero et al., 199623. Sperm were fixed with 4% PFA for 10 mins, permeabilized with Triton X-100 (0.1%) and blocked with 1% BSA. Sperm were incubated with anti-BRAP2 (1:200) or anti-AKAP3 (1:100) primary antibody at 4°C overnight, followed by Alexa 568-labeled goat anti-rabbit secondary antibody (Invitrogen, 1:1000) and mounted using ProLong® Gold Antifade with DAPI (Invitrogen Laboratories). Images were captured using a FluoView™ FV1000 confocal microscope, using 100X oil immersion objective lens.
CLSM and image analysis
Cells immunostained for endogenous proteins or transfected to express DsRed2 fusion proteins were imaged using a FluoView™ FV1000 Confocal Microscope equipped with 100x oil immersion objective lens. For assessing subcellular localization of GFP and DsRed2 fusion proteins in live cells; CLSM analysis was done similarly on a FluoViewTM FV1000 confocal microscope equipped with a FCS2 live-cell chamber and temperature controller maintained at 37°C (Bioptechs, Butler, PA, USA). The nuclear to cytoplasmic fluorescence ratio (Fn/c) was determined as previously described7 from digitized images using the ImageJ 1.43r public domain software (NIH), statistical analysis performed using a 2-tailed unpaired t-test and the Microsoft excel software.
Lysate preparation/coimmunoprecipitation/Western analysis
Adult mouse tissues were dissected from C57 black mice, as per Section 2.2. Following PBS washes, tissues were homogenized using RIPA buffer (150 mM sodium chloride, 1% NP40, 0.5% sodium deoxycholate, 0.1% SDS, 50 mM Tris, pH 8) containing a protease inhibitor cocktail (Roche), cell pellets were lysed using a lysis buffer as described previously7. Cellular debris was removed by centrifugation at 20,000 × g for 30 min at 4°C. Protein concentration of the cleared lysate was determined by Bradford assay (Biorad).
Co-immunoprecipitation was performed from 400 μg of mouse testis lysate using the Catch and Release® v2.0 Reversible Immunoprecipitation System (Upstate Cell Signalling Solutions) according to the manufacturer's instructions, using 4 μg of anti-PHLPP1 (Novus Biologicals), anti-AKAP3 (Protein tech), anti-DNMT1 (Abcam), anti-BRAP2 (Sigma), or anti-GST (Santa Cruz) antibodies. Following overnight incubation, proteins were eluted from the beads with successive 60 μl additions of 1 ×, 2 × and 4 × non-denaturing buffer and 1 × denaturing buffer and subjected to SDS-polyacrylamide gel electrophoresis (10% gel, or 8%).
To pull down GFP fusion proteins, cell lysates were incubated with GFP-trap beads (Chromotek) per manufacturer's instructions, for 1 h at 4°C with gentle rotation. The beads were then washed three times with GFP-trap wash buffer and resuspended in SDS–PAGE sample buffer. For detection of GFP fusion proteins by immunoprecipitation, 30 μl of the eluate was subjected to SDS-polyacrylamide gel electrophoresis (10% gel).
After electrophoresis, proteins were transferred to Polyvinylidene Fluoride (PVDF) membranes (PALL Corporation) preactivated in isopropanol (Merck) and Western blotting carried out as previously described7. Briefly, the membrane was blocked in 5% skim milk powder in PBS and incubated overnight at 4°C with rabbit anti-BRAP2 (1:1000), anti-PHLPP1 (1:750 or 1:1000, as appropriate), or mouse anti-DNMT1 (1:1000) primary antibodies. The anti-HA antibody (Cell Signalling) was used for detection of HA-PHLPP1 proteins; anti-myc antibody (Santa Cruz) for Myc-DNMT1 and anti-GST antibody for detection of AKAP3-GST proteins. Subsequently, blots were incubated in HRP-coupled goat anti-rabbit or goat anti-mouse secondary antibody (Millipore, 1:10,000), for 1 h and detected using enhanced chemiluminescence (ECL) (Perkin Elmer) according to the manufacturer's instructions. Tissue and cell lysates (25 μg) were subjected to SDS-polyacrylamide gel electrophoresis (10% gel) and Western transfer, blocking, incubation with anti-BRAP2 primary antibody and ECL detection performed essentially as above.
Immunohistochemistry
Immunohistochemistry was performed on Bouins-fixed paraffin-embedded adult Asmu:Swiss mouse testes sections using an avidin-biotin amplified immunohistochemical method as described previously29. The testis sections were incubated with primary antibody diluted in 0.5% BSA in TBS overnight in a humid chamber at 4°C {anti-BRAP2 (1:500), anti PHLPP1 (1:100); anti-AKAP3 (1:200) or anti-DNMT1 (1:400)}. Bound primary antibody was detected using biotinylated anti-rabbit/anti-mouse antibody (Millipore) diluted 1:500 in 0.5% bovine serum albumin (BSA)/PBS. Negative controls received 0.5% BSA in TBS in place of primary antibody. The sections were incubated with Vectastain® (Vector laboratories) washed and counterstained with Harris' Hematoxylin (BioRad) and mounted onto coverslips using DPX (di-n-butyl-phthalate in xylene) mounting solution (Sigma) and imaged using a bright field microscope (Provis) with 40 or 100 × oil immersion lens.
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Acknowledgements
The support of the National Health and Medical Research Council (Australia; project grant #491055 and Senior Prinicpal Research Fellowship APP1002486) and the Australian Research Council (ARC, Grant CEO 348239), Monash Micro Imaging Facility, Monash University, Clayton and Cassandra David for cell culture. Dr. Heinrich Leonhardt (Faculty of Biology at the LMU, Munich) is thanked for the GFP-DNMT1 encoding construct and Dr. Daniel W. Carr (School of Medicine, Endocrinology; Oregon health and Science universities, Portland) for GFP-AKAP3 and GST-AKAP3 plasmid constructs. Elizabeth Richards is thanked for assistance with immunostaining of sperm and Penny Whiley for immunohistochemistry.
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D.A.J. supervised the project and helped S.F. in experimental designing. S.F. carried out all of the experiments, analysed the data and wrote the manuscript. K.M.W. provided advice on data analysis and reviewed the manuscript. K.L.L. provided reagents, key expertise in analysis of testicular germ cell types and reviewed the manuscript. D.A.J. and S.F. finalized the manuscript.
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Supplementary Table 1
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Fatima, S., Wagstaff, K., Loveland, K. et al. Interactome of the negative regulator of nuclear import BRCA1-binding protein 2. Sci Rep 5, 9459 (2015). https://doi.org/10.1038/srep09459
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DOI: https://doi.org/10.1038/srep09459
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