CSB-PGBD3 Mutations Cause Premature Ovarian Failure
Through whole exome sequencing in a non-consanguineous family having four affected members with POF and Sanger sequencing in 432 sporadic cases, we identified three novel mutations in CSB-PGBD3. Our functional studies implicate CSB-PGBD3, a gene which has previously shown association with DNA repair and Cockayne syndrome has a potential role in maintenance of ovarian function. This study also provides evidence for a pivotal role of DNA repair in POF.
Published in the journal:
CSB-PGBD3 Mutations Cause Premature Ovarian Failure. PLoS Genet 11(7): e32767. doi:10.1371/journal.pgen.1005419
Category:
Research Article
doi:
https://doi.org/10.1371/journal.pgen.1005419
Summary
Through whole exome sequencing in a non-consanguineous family having four affected members with POF and Sanger sequencing in 432 sporadic cases, we identified three novel mutations in CSB-PGBD3. Our functional studies implicate CSB-PGBD3, a gene which has previously shown association with DNA repair and Cockayne syndrome has a potential role in maintenance of ovarian function. This study also provides evidence for a pivotal role of DNA repair in POF.
Introduction
Premature ovarian failure (POF), also known as premature ovarian insufficiency (POI), typically is defined by elevated serum FSH levels prior to the age of 40 years [1]. Approximately 1% of women are affected. The disorder is heterogeneous, causation including chromosomal abnormalities and single gene mutations, as well as autoimmune, metabolic, infectious and iatrogenic factors [1]. Evidence for genetic factors has been provided by population and candidate gene studies. Approximately 10 − 15% of cases have an affected first or second degree relative [2], although proven genes with functional confirmation exist only for FMR1, NR5A1, BMP15, NOBOX, FIGLA, PGRMC1 and GDF9 [3–10]. Genome wide association studies (GWAS) have revealed multiple loci potentially associated with POF in Chinese, Korean, and Dutch [11–13]. However, in each it was difficult to implicate specific novel genes, and the positive findings were not always replicated. Recently, some causative perturbation has been found in POF associated with somatic anomalies, such as Perrault syndrome and blepharophimosis-epicanthus syndrome type 1 (BPES1), using whole genome or exome sequencing [14–16]. However, low prevalence and impaired fecundity result in limited pedigrees of POF without associated somatic anomalies (non-syndromic), and whole exome sequencing has not yet been conducted in non-syndromic POF kindreds having more than one affected member until the recent report by Wang, in which compound heterozygous mutation in the HFM1 gene were identified [17].
Here, we reported our results of whole exome sequencing in a Chinese non-consanguineous POF kindred and Sanger sequencing in 432 sporadic POF patients. We identified one heterozygous PGBD3 mutation in the kindred, and two CSB-PGBD3 fusion gene mutations among the 432 sporadic patients. All three mutants of CSB-PGBD3 were impaired in DNA damage repair, as indicated by delayed or absent recruitment to sites of cellular damaged. This could be caused by dysfunctional interaction with RNA polymerase II (RNAPol II). However, other mechanisms could exist.
Results
Patients with POF in the non-consanguineous family
The index case (Fig 1A, Ⅲ5) in the family was a 28-year-old woman of Han Chinese descent who presented with secondary amenorrhea at 23 years of age, with serum follicle stimulating hormone (FSH) concentrations exceeding 40 IU/L on two occasions. In her family there were 3 other females with POF. Ⅱ3 andⅡ11, currently in their 60s or 50s, were childless and presented with secondary amenorrhea at the age of 18 years and 27 years, respectively. Ⅲ2 experienced oligomenorrhea from the age of menarche at age 14 years, gave birth at age 30 years to a normal infant after attempting, unsuccessfully, for the previous 6 years. She developed amenorrhea at the age of 37 years. Chromosomal abnormalities, FMR1 premutation, previous ovarian surgery, or exposure to chemotherapy or radiotherapy were not present in any family member.
Whole exome sequencing detects a heterozygous missense mutation in PGBD3
Whole exome sequencing was performed in the three known affected casesⅡ3, Ⅱ11 and Ⅲ5; one genetically obligate male carrier (Ⅱ5) should a mutation be segregating in autosomal dominant fashion; and one normal family member Ⅱ9. More than 20,000 single-nucleotide variants (SNVs) were identified in each subject. After being “blasted” with public databases, verified by Sanger sequencing, and sequencing the remaining family members (Ⅱ1, Ⅱ2, Ⅱ6, Ⅱ7, Ⅱ8, Ⅱ10, Ⅲ1, Ⅲ2, Ⅲ3, Ⅲ6, Ⅲ7, Ⅲ8, Ⅲ9, Ⅲ10, Ⅲ11, Ⅲ12, Ⅲ13), only the heterozygous variant (ENST00000515869: c.2237G>A, p.G746D) in PiggyBac transposable element derived 3 (PGBD3) was exclusively carried by those affected individuals (Ⅱ3, Ⅱ11, Ⅲ2 and Ⅲ5), and the obligate carrier (Ⅱ5), and absent in normal family members. Ⅲ2 and Ⅲ5 inherited the variant from their fathersⅡ2 and Ⅱ5, respectively, supporting autosomal dominant inheritance (Table 1 and Fig 1).
Mutational screening in sporadic POF patients
To validate exome data and detect independent mutations, we further performed Sanger sequencing of PGBD3 in 432 sporadic POF patients and 400 matched control females. Clinical features of the two cohorts were shown in Table 2. The PGBD3 transposon integrated into intron 5 of the Cockayne syndrome Group B gene (CSB, also known as ERCC6, excision repair cross-complementing rodent repair deficiency, complementation group 6) about 43 Mya in marmoset. This resulted in abundant CSB-PGBD3 fusion protein arising by alternative splicing of CSB exons 1–5 to the PGBD3 transposase which was conserved in the subsequent primate radiation [18]. Given that, we sequenced exons 1–5 of CSB in the two cohorts as well. As a result, we found one additional novel heterozygous missense mutation (ENST00000515869: c.3166G>A, p.V1056I) in PGBD3 and one heterozygous nonsense mutation (ENST00000515869: c.643G>T, p.E215X) in exon 4 of CSB in POF patients; the latter resulted in a truncated protein without PGBD3. Neither perturbation was found among controls (S1 Table). The women having these two novel variants experienced normal puberty and established regular menses with menarche at 14 and 15 years old, respectively. They presented with secondary amenorrhea at the age of 24 and 25 years respectively, and neither of them had achieved pregnancy. They were of normal height and intellectually normal. Karyotype and FMR1 premutation analysis were normal. Somatic anomalies were not present in any family members. Clinical characteristics of mutation carriers were shown in Table 1.
Expression of CSB-PGBD3 in the primate oocyte
Through immunohistochemistry using anti-PGBD3 antibody (Abnova PAB21786) and through in situ hybridization using probe targeting at CSB-PGBD3 mRNA on sections of formalin-fixed and paraffin-embedded ovarian tissue of rhesus monkey (9 years old), we observed that CSB-PGBD3 was exclusively expressed in nuclei of oocytes from primordial, primary, secondary to antral follicles (Fig 2A and 2B). Western blot with anti-PGBD3 antibody (Abnova PAB21786) in human ovarian tissue, granulosa cells, heart tissues and COV434 cells had confirmed the protein’s localization (Fig 2C), indicating that the CSB-PGBD3 fusion protein might play a role in oogenesis or maintenance of genomic stability of oocytes.
Delayed recruitment of CSB-PGBD3 mutants at sites of DNA damage
U2OS and HeLa cells expressing CSB-PGBD3-RFP or CSB-PGBD3-eGFP (including wild type and three mutants) were exposed to laser micro-irradiation or oxidative damage. Similar to OGG1 (8-Oxoguanine DNA Glycosylase1, responsible for the excision of 8-oxoguanine in response to oxidative damage), which localizes to the laser damaged sites rapidly, wild type CSB-PGBD3-RFP protein was recruited to the damaged sites immediately after laser irradiation, and gradually disappearing around 5 min (Fig 3A and 3B). Similar response was observed after oxidative damage, in which CSB-PGBD3-eGFP bound onto chromatin immediately after H2O2 treatment and began to separate after 15 min (Fig 3E). Compared to the wild type, the response of mutants p.G746D and p.V1056I to DNA damage was much weaker (Fig 3C), and the percentage of cells containing CSB-PGBD3-RFP that were recruited to laser damaged sites was significantly lower (22.03% vs. 72.94%, p<0.001 for p.G746D; 30.30% vs. 72.94%, p<0.001 for p.V1056I; respectively) (Fig 3D). For the truncated protein p.E215X, no accumulation was observed at the laser damaged sites (Fig 3A, 3C and 3D). However, p.E215X bound onto chromatin immediately after H2O2 treatment but separated from it unexpectedly rapidly (Fig 3E). Protein p.E215X manifested no aggregation in 15 min after H2O2 treatment, which was the peak point for the recruitment of wild type, suggesting that p.E215X may not participate in the DNA damage repair.
It is known that CSB is among the first protein to bind stalled RNA polymerase II (RNApol II) at the sites of DNA damage, and is required to recruit other transcription-coupled DNA repair (TCR) factors [19]. CSB-PGBD3 fusion protein has been previously shown to interact with RNApol II as well. To verify previous findings and explore defects of identified three mutants, we performed immunoprecipitation (IP) between FLAG-CSB-PGBD3 (including wild type and mutants) and RNApol II. No significantly different interaction with RNApol II was observed among p.G746D, p.V1056I and wild type either after UV or H2O2 damage. However, the truncated protein p.E215X failed to associate with RNApol II either after UV or H2O2 damage (Fig 3F). Our clonogenic survival assay further showed that the clonogenic survival percent of wild-type CSB-PGBD3-expressing cells was significantly higher than that of mutants-expressing cells (Fig 3G and 3H), indicating a crucial role of functional CSB-PGBD3 played in maintaining cell survival after DNA damage. Taken together, our results suggest that CSB-PGBD3 could play a role in DNA damage repair, and that the mutations we identified impair this normal function of CSB-PGBD.
Discussion
Whole exome sequencing in a kindred having multiple family members with non-syndromic POF identified the p.G746D mutation in CSB-PGBD3, inherited in autosomal dominant fashion. Among 432 sporadic POF cases, we discovered one additional novel missense mutation (p.V1056I) and one nonsense mutation (p.E215X) in CSB-PGBD3. Thus, this gene complex needs to be intact for normal ovarian development and maintenance.
CSB is an important player in TCR pathway. If perturbed, this results in Cockayne Syndrome (CS), an autosomal recessive disorder characterized by progressive growth failure, microcephaly, and mental retardation. In CS a dysfunctional DNA repair mechanism exists, nearly 70% of CS caused by perturbation in the CSB gene [20]. PGBD3 and CSB-PGBD3 fusion protein arose in the common ancestor of humans and marmosets about 43 million years ago and has been highly conserved ever since [18]. CSB-PGBD3 has been proved to participate in TCR of DNA damage [21]. However, there is no clear mechanism elucidating the role of PGBD3 plays in CS, nor has a mutation in PGBD3 been identified in CS.
Curiously, complete absence of detectable CSB protein does not invariably cause CS: a nonsense mutation at codon 77 in CSB exon 2 causes only mild UV-sensitive syndrome (UVSS) with no syndromic or developmental components [20], whereas complete absence of CSB resulting from deletion of 5' UTR sequences including exon 1 causes classical early onset CS [22]. Indeed, it may be functionally significant that the novel nonsense mutation p.E215X in our sporadic POF patient, who had no CS, UVSS or other somatic anomalies, has never been found to cause CS [20].
Our finding- perturbations and functional alterations in POF cases- replies that CSB-PGBD3 play a role in ovarian development or maintenance. In the functional study, in response to the output of laser power that induced CSB-PGBD3-RFP to the damage site, OGG1-GFP was recruited to the damage site, indicating that CSB-PGBD3 is recruited to the UVA laser-induced oxidative damage sites, and the presence of functional CSB does not displace the fusion protein from the foci. There are several possible roles played by the proteins localized to DNA damage loci, including direct participants, indirect facilitators, or bystanders. Our study and others indicate that CSB-PGBD3 binds with RNApol II after DNA damage treatments. Combined with the fact that overexpression of CSB-PGBD3 promoted cellular resistance to UV irradiation, it is likely that CSB-PGBD3 is involved in DNA repair.
CSB-PGBD3 is known to interact with RNApol II through the N-terminal CSB domain [23]. In our study, the truncated protein E215X (nonsense mutation in CSB exon 4) manifested no binding with RNApol II and no accumulation in the laser damaged site, indicating that CSB-PGBD3 also requires exon 5 to interact with RNApol II. Mutant p.G746D, p.V1056I, and p.E215X did not change the nuclear localization as did wild type, but their response to DNA damage caused by laser/UV/H2O2 was delayed or absent. These results, in aggregate, suggest that CSB-PGBD3 fusion protein may be involved in DNA damage repair and three mutants could be loss of function partly or totally during the process. Therefore, haploinsufficiency of functional CSB-PGBD3 fusion protein might explain POF. However, at least 18 distinct homozygous or compound heterozygous mutations in CSB exons 1–5 are responsible for CS, and there is no observation of POF in any of the families of affected CS individuals, in which one would expect heterozygous women [20, 24]. More likely, the two novel sporadic mutations we observed (E215X and V1056I) acted in a dominant negative fashion.
In the present study, we demonstrated that CSB-PGBD3 fusion protein was expressed in oocyte, but not in granulosa cells or theca-interstitial cells. Of relevance, DNA damage is one of the most common insults that challenge oocytes [25]. Ability to repair DNA damage is essential to maintain the supply of oocytes necessary for reproduction. Many DNA repair genes are found to be expressed in oogenesis, such as BRCA1 [26], HELQ [27] and EXO1 [28]. If defects occur along the pathway of DNA repair, DNA damage could accumulate; oocytes may also be particularly vulnerable to ubiquitous external damage. Subsequently, the number of damaged follicles may increase with aging, leading to a greater rate of follicle loss through atresia, finally causing POF. Our results suggest that oocytes carrying mutant p.G746D, p.V1056I, and p.E215X either alone or together are unable to repair DNA damage efficiently. This provides direct genetic evidence that perturbation of genes involved in DNA damage repair could lead to non-syndromic POF. Our finding is consistent with recent reports that perturbations of MCM8 and MCM9 are responsible for POF, acting through compromised DNA repair [29,30].
In summary, we found perturbations of CSB-PGBD3 in familial and sporadic patients with POF. Functional studies involving CSB-PGBD3 can provide explanations relevant to ovarian maintenance.
Materials and Methods
Subjects and clinical data
A non-syndromic, non-consanguineous Chinese family having four POF members (Fig 1A). In addition, 432 independent Chinese sporadic POF patients and 400 matched Chinese control females were recruited between Jan 1, 2009 and Sep 1, 2012 from the Center for Reproductive Medicine, Provincial Hospital Affiliated to Shandong University. Inclusion criteria for all POF cases consisted of cessation of menstrual cycles before age of 40 years, with serum follicle stimulating hormone (FSH) concentrations on two occasions exceeding 40 IU/L. Women with known chromosomal abnormalities, FMR1 premutation, previous ovarian surgery, or exposed to chemotherapy or radiotherapy were excluded. Written informed consent was obtained from all participants. This study was approved by the Institutional Review Board of Reproductive Medicine of Shandong University ([2012] IRB No.16). Clinical characteristics of sporadic patients with POF and controls are shown in Table 2.
Tissues and cells
The human fetal heart tissue was obtained from a fetus undergoing pregnancy termination at 28 weeks; adult ovary tissue was obtained from a woman (39 years old) undergoing oophorectomy because of ovarian serous cystadenocarcinoma; human granulosa cells were obtained from follicular fluid of a patient with tubal factor necessitating in vitro fertilization. All the human tissues and cells were obtained from Department of Gynaecology and Obstetrics and Center for Reproductive Medicine, Provincial Hospital Affiliated to Shandong University, with ethical approval under Codes of Practice of the China Human Tissue and study approval by the Institutional Review Board of Reproductive Medicine of Shandong University ([2013] IRB No.4).
Human cell lines: HeLa (Human cervix carcinoma cell line), U2OS (Human osteosarcoma cell line), HEK293FT (human embryonic kidney cell line) and COV434 (Human ovarian granulosa tumour cell line) were cultured in DMEM/High Glucose (Thermo) supplemented with 10% fetal bovine serum at 37°C with 5% CO2.
Exome sequencing and data analysis
Genomic DNA was extracted from peripheral blood leukocytes using DNeasy Blood & Tissue Kit (Qiagen), exome sequences were captured with SureSelect Target Enrichment System for Illumina Paired-End Sequencing Library (Agilent Technologies), and DNA sequencing was performed on the Illumina platform (Illumina HiSeq). Reads were mapped to the hg19 reference genome with Burrows-Wheeler Alignment tool (BWA), and variants were called and annotated using GATK, ANNOVAR, and custom pipelines. Protein-coding variants were checked against established databases (1000 Genomes Project and dbSNP, version 134). All unreported variants following an autosomal dominant inheritance model were confirmed in the 5 subjects by Sanger sequencing, and the candidate variants were further validated in other individuals of the family by Sanger sequencing.
Western blot
Tissues grinded and cells harvested by scraping were resuspended and lysed in 200 μl Radio Immunoprecipitation Assay (RIPA) buffer with 1mM Phenylmethanesulfonyl fluoride (PMSF) (Beyotime), and centrifuged in 12000 rpm at 4°C for 10 min. The supernatants were collected and protein concentrations were measured by the BCA method. Equivalent amounts of protein were separated by 8% SDS-PAGE gel and electro-transferred to PVDF membranes. The PVDF membranes were blocked with 5% nonfat milk in TBST for 2 h at room temperature and then incubated with primary antibodies overnight at 4°C. The primary antibodies used were as follows: PGBD3 (Abnova PAB21786, 1:500), RNApol II (Santa Cruz Biotechnology sc-9001, 1:1000), GFP (Proteintech 66002-1-lg, 1:5000), FLAG (Cell Signaling Technology 2368, 1:1000), β-Actin (Sigma-Aldrich SAB1305546, 1:5000), GAPDH (Sigma-Aldrich SAB2103104, 1:10000) and H3 (Merck Millipore 05–499, 1:100000). Membranes were washed with TBST, incubated with HRP-conjugated anti-rabbit or anti-mouse secondary antibody for 1 h at room temperature, and subjected to chemiluminescent detection with ChemiDoc MP System (Bio-Rad).
Immunohistochemistry
An ovary from a rhesus monkey (9 years old) was fixed in 10% neutral formalin, embedded in paraffin and sectioned at 5 um thickness. Immunohistochemistry was performed using the Goat ABC Staining System (Santa Cruz Biotechnology). Briefly, the sections were deparaffinized completely and then immersed in citric acid buffer (10 mmol/L of sodium citrate, 10 mmol/L of citric acid) and boiled in water bath at 92–98°C for 15 min to expose the antigens. Sections were cooled to room temperature and sequentially permeabilized with 0.3% Triton X-100, incubated with 3% H2O2 at 37°C for 15 min to quench endogenous peroxidase, blocked with normal goat serum for 2h, incubated with anti-PGBD3 antibody (Abnova PAB21786, 1:20) at 4°C overnight, incubated with biotinylated secondary antibody at 37°C for 1 h and finally treated with the Streptavidin-HRP for 1 h. Intervening PBS washes were performed after incubation when necessary. Sections were then stained with diaminobenzidine (DAB) and hematoxylin, dehydrated and mounted with coverslips. Primary antibodies were replaced by PBS in negative controls. Signals were recorded with an Olympus IX51 digital camera system (Olympus).
In situ hybridization
CSB-PGBD3 probe 5’- GAGGCATCTTGGGACTTAACCGCTGCTTA -3’ was labeled with DIG by using the DIG Oligonucleotide Tailing Kit (Roche). Sections of formalin-fixed and paraffin embedded ovary tissue of rhesus monkey (9 years old) was deparaffinized and washed with 0.1M Phosphate buffered saline treated with 0.1% diethylpyrocarbonate (DEPC-PBS). Then the sections were treated with 0.3% Triton X-100 for 15 min, incubated with 10 ug/ml Proteinase K (diluted in 50 mM Tris with 2 mM Calcium Chloride) for 15 min, fixed with 4% p-formaldehyde/0.1M PBS for 15 min at room temperature, and incubated with 0.25% acetic anhydride for 10 min. Intervening DEPC-PBS washes were performed after incubation when necessary. Then, the sections were incubated with hybridization buffer at 37°C for 2 h, washed with 2X SSC for 5 min, and incubated with 200 ng/ml of DIG-labeled CSB-PGBD3 probe at 37°C overnight. After hybridization, sections were sequentially washed in SSC and washing buffer [100 mM Tris-HCl (pH7.5), 150 mM NaCl], blocked with 2% normal goat serum for 30 min, and incubated with the diluted anti-DIG antibody (1:200) for 4 h at room temperature. Then sections were stained with BCIP/NBT and methylene green, and mounted with coverslips. The oligo probe of comparable length but scrambled sequence was used as a negative control: 5’-TGTAGTGCGGAATCGG CCTTATGCAACCT-3’. Signals were recorded with an Olympus IX51 digital camera system (Olympus).
Laser micro-irradiation and imaging
U2OS cells were cultured and transiently transfected with wild type and the 3 mutant CSB-PGBD3-RFP plasmids together with or without OGG1-GFP plasmid using Lipo2000 (Invitrogen). DNA damage was induced in the nuclei of cultured cells by micro-irradiation with a pulsed nitrogen laser (Photonics Instruments; 365 nm, 10 Hz pulse) [31]. Briefly, cells were seeded onto 35-mm glass bottom dishes (MatTek) overnight before being visualized with a Nikon Eclipse Ti-E inverted microscope equipped with a computer-controlled MicroPoint laser Ablation System (Photonics Instruments) for time-lapse imaging. The output of the laser power was set at 70–90% of the maximum as indicated by the manufacturer. During micro-irradiation and imaging, cells were maintained at 37°C. The growth medium was replaced by CO2-independent medium (Invitrogen) before analysis. The mean fluorescence intensity of CSB-PGBD3-RFP foci in the laser induced damage sites and that of the other nuclear area were determined after subtraction of the extranuclear background signal. The ratio of the foci fluorescence intensity over the other nuclear area fluorescence intensity was used to indicate the quantification of the recruitment. The average and SE of a total of at least 10 cells are depicted in the graph.
Clonogenic survival
HeLa cells were cultured and CSB-PGBD3 fusion protein silenced with siRNA (S5 Table) for 24h. Then, the wild type and mutant p3XFLAG-CSB-PGBD3 and p3XFLAG (as control) plasmids were transiently transfected into the HeLa cells using X-tremeGENE HP DNA Transfection Reagent (Roche). After culture for 24h, cells were exposed to UV irradiation (10J/m2). The cells were next harvested and counted, and reseeded into a new 6-well plate by 500 cells per well (three wells for duplicate) and incubated for 12 days. Media were then removed, and colonies stained with crystal violet. Cells were washed twice with PBS and the blue colonies were counted. This experiment was replicated three times. Data were expressed as percent survival relative to the control: [(average treated count)/(average control count)]x100%.
H2O2 treatment and chromatin analysis
HeLa cells seeded in a 6 cm dish were transiently transfected with wild type and the 3 mutant CSB-PGBD3-eGFP plasmids using X-tremeGENE HP DNA Transfection Reagent (Roche) and cultured for 48 h. Then the cells were treated with H2O2 (5mM) at 4°C for 10 min in serum free medium and recovered at 0min, 15min, 30min, 1h, 2h, 3h, and 4h in complete medium at 37°C. Chromatin fractions were harvested as performed by Zou et al. [32] and analysed by western blot with antibody against GFP (Proteintech 66002-1-lg) and histone H3 (Merck Millipore 05–499).
Immunoprecipitation
HEK293FT cells were transiently transfected with wild type and the 3 mutant p3XFLAG-CSB-PGBD3 plasmids using Lipo2000 (Invitrogen) and cultured for 24 h. Cells were then divided into three groups: without treatment; treatment with ultraviolet light (UV) irradiation (10 J/m2); treatment with H2O2 (5mM, 4°C, 10min). After treatment, protein of the cells was extracted using NETN buffer, and pulled down with anti-FLAG M2 magnetics beads (Sigma-Aldrich M8823). The interaction between CSB-PGBD3 and RNApol II was analyzed by western blot with the antibody against FLAG (Cell Signaling Technology 2368) and RNApol II (Santa Cruz Biotechnology sc-9001). All steps were performed at 4°C.
Statistical analysis
The continuous data were checked for normality and described as mean ± SD or mean (95% confidence interval for mean). We calculated differences of clinical features between sporadic POF patients and controls using independent sample T-tests. For the mRNA expression of DNA repair factors, we calculated using Kruskal-Wallis one-way ANOVA on ranks, as well as a multiple comparison procedure using Dunnett’s method. For the percentage of cells in which RFP tagged protein was localized at the damaged sites, we calculated using Pearson chi-square test. We used SPSS (version 19) for all statistical analyses.
Supporting Information
Zdroje
1. Nelson LM. (2009) Clinical Practice. Primary ovarian insufficiency. N Engl J Med 360: 606–614. doi: 10.1056/NEJMcp0808697 19196677
2. Van Kasteren YM, Hundscheid RD, Smits AP, Cremers FP, van Zonneveld P, et al. (1999) Familial idiopathic premature ovarian failure: an overrated and underestimated genetic disease? Hum Reprod 14: 2455–2459. 10527968
3. Wittenberger MD, Hagerman RJ, Sherman SL, McConkie-Rosell A, Welt CK, et al. (2007) The FMR1 premutation and reproduction. Fertil Steril 87: 456–465. 17074338
4. Lourenco D, Brauner R, Lin L, De Perdigo A, Weryha G, et al. (2009) Mutations in NR5A1 associated with ovarian insufficiency. N Engl J Med 360: 1200–1210. doi: 10.1056/NEJMoa0806228 19246354
5. Dixit H, Rao LK, Padmalatha VV, Kanakavalli M, Deenadayal M, et al. (2006) Missense mutations in the BMP15 gene are associated with ovarian failure. Hum Genet 119: 408–415. 16508750
6. Qin Y, Choi Y, Zhao H, Simpson JL, Chen ZJ, et al. (2007) NOBOX homeobox mutation causes premature ovarian failure. Am J Hum Genet 81: 576–581. 17701902
7. Zhao H, Chen ZJ, Qin Y, Shi Y, Wang S, et al. (2008) Transcription factor FIGLA is mutated in patients with premature ovarian failure. Am J Hum Genet 82: 1342–1348. doi: 10.1016/j.ajhg.2008.04.018 18499083
8. Mansouri MR, Schuster J, Badhai J, Stattin EL, Losel R, et al. (2008) Alterations in the expression, structure and function of progesterone receptor membrane component-1 (PGRMC1) in premature ovarian failure. Hum Mol Genet 17: 3776–3783. doi: 10.1093/hmg/ddn274 18782852
9. Chand AL, Ponnampalam AP, Harris SE, Winship IM, Shelling AN (2006) Mutational analysis of BMP15 and GDF9 as candidate genes for premature ovarian failure. Fertil Steril 86: 1009–1012. 17027369
10. Qin Y, Shi Y, Zhao Y, Carson SA, Simpson JL, et al. (2009) Mutation analysis of NOBOX homeodomain in Chinese women with premature ovarian failure. Fertil Steril 91: 1507–1509. doi: 10.1016/j.fertnstert.2008.08.020 18930203
11. Qin Y, Zhao H, Xu J, Shi Y, Li Z, et al. (2012) Association of 8q22.3 locus in Chinese Han with idiopathic premature ovarian failure (POF). Hum Mol Genet 21: 430–436. doi: 10.1093/hmg/ddr462 21989058
12. Pyun JA, Kim S, Cha DH, Kwack K (2013) Epistasis between IGF2R and ADAMTS19 polymorphisms associates with premature ovarian failure. Hum Reprod 28: 3146–3154. doi: 10.1093/humrep/det365 24014609
13. Knauff EA, Franke L, van Es MA, van den Berg LH, van der Schouw YT, et al. (2009) Genome-wide association study in premature ovarian failure patients suggests ADAMTS19 as a possible candidate gene. Hum Reprod 24: 2372–2378. doi: 10.1093/humrep/dep197 19508998
14. Pierce SB, Gersak K, Michaelson-Cohen R, Walsh T, Lee MK, et al. (2013) Mutations in LARS2, encoding mitochondrial leucyl-tRNA synthetase, lead to premature ovarian failure and hearing loss in Perrault syndrome. Am J Hum Genet 92: 614–620. doi: 10.1016/j.ajhg.2013.03.007 23541342
15. Meduri G, Bachelot A, Duflos C, Bstandig B, Poirot C, et al. (2010) FOXL2 mutations lead to different ovarian phenotypes in BPES patients: Case Report. Hum Reprod 25: 235–243. doi: 10.1093/humrep/dep355 19819892
16. Caburet S, Arboleda VA, Llano E, Overbeek PA, Barbero JL, et al. (2014) Mutant cohesin in premature ovarian failure. N Engl J Med 370: 943–949. doi: 10.1056/NEJMoa1309635 24597867
17. Wang J, Zhang W, Jiang H, Wu BL (2014) Mutations in HFM1 in recessive primary ovarian insufficiency. N Engl J Med 370: 972–974. doi: 10.1056/NEJMc1310150 24597873
18. Newman JC, Bailey AD, Fan HY, Pavelitz T, Weiner AM (2008) An abundant evolutionarily conserved CSB-PiggyBac fusion protein expressed in Cockayne syndrome. PLoS Genet 4: e1000031. doi: 10.1371/journal.pgen.1000031 18369450
19. Svejstrup JQ (2002) Mechanisms of transcription-coupled DNA repair. Nat Rev Mol Cell Biol 3: 21–29. 11823795
20. Laugel V, Dalloz C, Durand M, Sauvanaud F, Kristensen U, et al. (2010) Mutation update for the CSB/ERCC6 and CSA/ERCC8 genes involved in Cockayne syndrome. Hum Mutat 31: 113–126. doi: 10.1002/humu.21154 19894250
21. Bailey AD, Gray LT, Pavelitz T, Newman JC, Horibata K, et al. (2012) The conserved Cockayne syndrome B-piggyBac fusion protein (CSB-PGBD3) affects DNA repair and induces both interferon-like and innate antiviral responses in CSB-null cells. DNA Repair (Amst) 11: 488–501.
22. Laugel V, Dalloz C, Stary A, Cormier-Daire V, Desguerre I, et al. (2008) Deletion of 5' sequences of the CSB gene provides insight into the pathophysiology of Cockayne syndrome. Eur J Hum Genet 16: 320–327.24. doi: 10.1038/sj.ejhg.5201991 18183039
23. Gray LT, Fong KK, Pavelitz T, Weiner AM (2012) Tethering of the conserved piggyBac transposase fusion protein CSB-PGBD3 to chromosomal AP-1 proteins regulates expression of nearby genes in humans. PLoS Genet 8: e1002972.25. doi: 10.1371/journal.pgen.1002972 23028371
24. Laugel V (2013) Cockayne syndrome: the expanding clinical and mutational spectrum. Mech Ageing Dev 134: 161–170. doi: 10.1016/j.mad.2013.02.006 23428416
25. Carroll J, Marangos P (2013) The DNA damage response in mammalian oocytes. Front Genet 4: 117. doi: 10.3389/fgene.2013.00117 23805152
26. Titus S, Li F, Stobezki R, Akula K, Unsal E, et al. (2013) Impairment of BRCA1-related DNA double-strand break repair leads to ovarian aging in mice and humans. Sci Transl Med 5: 172ra121.
27. Adelman CA, Lolo RL, Birkbak NJ, Murina O, Matsuzaki K, et al. (2013) HELQ promotes RAD51 paralogue-dependent repair to avert germ cell loss and tumorigenesis. Nature 502: 381–384. doi: 10.1038/nature12565 24005329
28. Wei K, Clark AB, Wong E, Kane MF, Mazur DJ, et al. (2003) Inactivation of Exonuclease 1 in mice results in DNA mismatch repair defects, increased cancer susceptibility, and male and female sterility. Genes Dev 17: 603–614. 12629043
29. AlAsiri S, Basit S, Wood-Trageser MA, Yatsenko SA, Jeffries EP, et al. (2015) Exome sequencing reveals MCM8 mutation underlies ovarian failure and chromosomal instability. J Clin Invest 125: 258–262. doi: 10.1172/JCI78473 25437880
30. Wood-Trageser MA, Gurbuz F, Yatsenko SA, Jeffries EP, Kotan LD, et al. (2014) MCM9 mutations are associated with ovarian failure, short stature, and chromosomal instability. Am J Hum Genet 95: 754–762. doi: 10.1016/j.ajhg.2014.11.002 25480036
31. Zhang X, Lv L, Chen Q, Yuan F, Zhang T, et al. (2013) Mouse DNA polymerase kappa has a functional role in the repair of DNA strand breaks. DNA Repair (Amst) 12: 377–388.
32. Zou L, Cortez D, Elledge SJ (2002) Regulation of ATR substrate selection by Rad17-dependent loading of Rad9 complexes onto chromatin. Genes Dev 16: 198–208. 11799063
Štítky
Genetika Reprodukčná medicínaČlánok vyšiel v časopise
PLOS Genetics
2015 Číslo 7
- Je „freeze-all“ pro všechny? Odborníci na fertilitu diskutovali na virtuálním summitu
- Gynekologové a odborníci na reprodukční medicínu se sejdou na prvním virtuálním summitu
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