Samuel Rogers1, Brian S Gloss2, Christine S Lee1, Claudio Marcelo Sergio1, Marcel E Dinger2, Elizabeth A Musgrove3, Andrew Burgess2, Catherine Elizabeth Caldon2. 1. The Kinghorn Cancer Centre and Cancer Research Program, Garvan Institute of Medical Research, Sydney, NSW Australia. 2. The Kinghorn Cancer Centre and Cancer Research Program, Garvan Institute of Medical Research, Sydney, NSW Australia ; St Vincent's Clinical School, Faculty of Medicine UNSW, Sydney, Australia. 3. Wolfson Wohl Cancer Research Centre, University of Glasgow, Garscube Estate, Glasgow, G61 1QH UK.
Abstract
BACKGROUND: The cyclin E oncogene activates CDK2 to drive cells from G1 to S phase of the cell cycle to commence DNA replication. It coordinates essential cellular functions with the cell cycle including histone biogenesis, splicing, centrosome duplication and origin firing for DNA replication. The two E-cyclins, E1 and E2, are assumed to act interchangeably in these functions. However recent reports have identified unique functions for cyclins E1 and E2 in different tissues, and particularly in breast cancer. FINDINGS: Cyclins E1 and E2 localise to distinct foci in breast cancer cells as well as co-localising within the cell. Both E-cyclins are found in complex with CDK2, at centrosomes and with the splicing machinery in nuclear speckles. However cyclin E2 uniquely co-localises with NPAT, the main activator of cell-cycle regulated histone transcription. Increased cyclin E2, but not cyclin E1, expression is associated with high expression of replication-dependent histones in breast cancers. CONCLUSIONS: The preferential localisation of cyclin E1 or cyclin E2 to distinct foci indicates that each E-cyclin has unique roles. Cyclin E2 uniquely interacts with NPAT in breast cancer cells, and is associated with higher levels of histones in breast cancer. This could explain the unique correlations of high cyclin E2 expression with poor outcome and genomic instability in breast cancer.
BACKGROUND: The cyclin E oncogene activates CDK2 to drive cells from G1 to S phase of the cell cycle to commence DNA replication. It coordinates essential cellular functions with the cell cycle including histone biogenesis, splicing, centrosome duplication and origin firing for DNA replication. The two E-cyclins, E1 and E2, are assumed to act interchangeably in these functions. However recent reports have identified unique functions for cyclins E1 and E2 in different tissues, and particularly in breast cancer. FINDINGS:Cyclins E1 and E2 localise to distinct foci in breast cancer cells as well as co-localising within the cell. Both E-cyclins are found in complex with CDK2, at centrosomes and with the splicing machinery in nuclear speckles. However cyclin E2 uniquely co-localises with NPAT, the main activator of cell-cycle regulated histone transcription. Increased cyclin E2, but not cyclin E1, expression is associated with high expression of replication-dependent histones in breast cancers. CONCLUSIONS: The preferential localisation of cyclin E1 or cyclin E2 to distinct foci indicates that each E-cyclin has unique roles. Cyclin E2 uniquely interacts with NPAT in breast cancer cells, and is associated with higher levels of histones in breast cancer. This could explain the unique correlations of high cyclin E2 expression with poor outcome and genomic instability in breast cancer.
Entities:
Keywords:
Breast cancer; CDK2; Cajal bodies; Centrosome; Cyclin E1; Cyclin E2; Histone Locus bodies (HLB); Histones; NPAT; Spliceosomes
The canonical function of cyclin E is the activation of CDK2 (cyclin dependent kinase 2) to phosphorylate Rb, hence promoting the release of E2F transcription factors and progression of the cell cycle from G1 to S phase [1]. However there are other functions for cyclin E that may be CDK2 dependent or independent, including transcriptional processing, origin firing, and centrosome duplication [2]. The wide range of cyclin E functions may explain the necessity for two cyclin E proteins: E1 and E2. Both these proteins activate CDK2, but are encoded by genes on different chromosomes (cyclin E1: CCNE1 at 19q12; cyclin E2: CCNE2 at 8q22.1). Cyclin E1 and E2 have differences in tissue expression, transcription and post-transcriptional regulation, and have distinct affinities for other proteins, e.g. p107 [1,3]. In this study we examined the localisation of cyclin E1 and E2 and report unique sites of localisation in breast cancer cells.We previously identified that cyclin E1 and E2 are expressed in different cell line subpopulations due to distinct cell cycle regulation [4]. Close examination revealed that cyclin E1 and E2 localise to unique foci within the nucleus of T-47D and MCF-7 breast cancer cells (Figure 1A and Additional file 1). Several large bright foci exclusively localised with either cyclin E1 or E2, while some foci showed co-localisation (Figure 1A, inset, and Additional file 1, inset).
Figure 1
Cyclins E1 and E2 localise to unique foci, and have distinct subcellular distribution. A. Confocal images of T-47D breast cancer cells immunoprobed with cyclin E1 (red) or cyclin E2 (green), and counterstained with ToPro3 (blue, nuclei). Inset at higher magnification. Scale bars = 5 μm. Experiments are performed in triplicate. Similar data obtained in MCF-7 cells are shown in Additional file 1. B. T-47D cells were lysed to extract total cell proteins (lane 1), total nuclear (lane 2) and total cytoplasmic (lane 3) lysates. In parallel, cell lysates were purified to extract soluble cytoplasmic proteins, soluble nuclear proteins, and chromatin bound proteins. PAGE separated proteins were western blotted for Cdc6 (predominantly chromatin bound), CDK2 (cytoplasmic, nuclear and chromatin bound), cyclin E1 and cyclin E2. C. Cyclins E1 and E2 were quantitated from duplicate experiments using densitometry (ImageJ), and soluble cytoplasmic, soluble nuclear, and chromatin-bound fractions graphed as a percentage of total extracted protein. Error bars show range.
Cyclins E1 and E2 localise to unique foci, and have distinct subcellular distribution. A. Confocal images of T-47Dbreast cancer cells immunoprobed with cyclin E1 (red) or cyclin E2 (green), and counterstained with ToPro3 (blue, nuclei). Inset at higher magnification. Scale bars = 5 μm. Experiments are performed in triplicate. Similar data obtained in MCF-7 cells are shown in Additional file 1. B. T-47D cells were lysed to extract total cell proteins (lane 1), total nuclear (lane 2) and total cytoplasmic (lane 3) lysates. In parallel, cell lysates were purified to extract soluble cytoplasmic proteins, soluble nuclear proteins, and chromatin bound proteins. PAGE separated proteins were western blotted for Cdc6 (predominantly chromatin bound), CDK2 (cytoplasmic, nuclear and chromatin bound), cyclin E1 and cyclin E2. C. Cyclins E1 and E2 were quantitated from duplicate experiments using densitometry (ImageJ), and soluble cytoplasmic, soluble nuclear, and chromatin-bound fractions graphed as a percentage of total extracted protein. Error bars show range.Cyclins E1 and E2 have cytoplasmic, nuclear and chromatin associated functions [1,2]. Cell fractionation showed that both cyclin E1 and E2 were predominantly nuclear and a large proportion was extracted with chromatin (Figure 1B). However a significant proportion of cyclin E1 was nucleolar and not chromatin associated (18.5%) compared to a smaller proportion of cyclin E2 (4.2%), and both proteins occurred at only very low levels in the cytoplasm (Figure 1B). Thus the majority of cyclin E1 and E2 is located on chromatin, but there is a small but significant proportion of cyclin E1 that is localized to non-chromatin foci.We next examined a range of cyclin E functions to determine if unique localisation of cyclin E1 or E2 was associated with a unique function. Cyclin E binds and activates CDK2, and this activity is inhibited by CDK inhibitors p21Waf1/Cip1 and p27Kip1. Both cyclin E1 and E2 form cyclin/CDK2/CDK inhibitor complexes, although these complexes are mutually exclusive (Figure 2A). Cyclin E/CDK2 phosphorylates splicing complexes which may coordinate pre-mRNA splicing with the G1/S transition [5]. These functional complexes appear common to cyclin E1 and cyclin E2, as in T-47D cells both proteins co-immunoprecipitate a major component of the spliceosome, SAP 145 (Figure 2B). Centrosomes are major cytoplasmic bodies located at the nuclear periphery. We identified that both cyclins E1 and E2 were localised to the centrosome complexes of T-47D and MCF-7 breast cancer cells using sucrose gradient fractionation of centrosomes and western blotting (Figure 2C, and Additional file 2), consistent with previous data showing specific localisation of cyclin E1 to centrosomes by immunofluorescence [6].
Figure 2
Common functional complexes of cyclin E1 and E2. A. Cyclin E1 and E2 both co-immunoprecipitate CDK2/CDK2 inhibitor complexes. Lysates of T-47D cells were immunoprecipitated and then western blotted using the indicated antibodies. Data are representative of duplicate experiments. Similar data from MCF7 cells are shown in [19]. IB: immunoblot; IP: immunoprecipitation B. Cyclin E1 and E2 both co-immunoprecipitate SAP145. Lysates of T-47D cells were immunoprecipitated and then western blotted using the indicated antibodies. Data are representative of triplicate experiments. In A. and B. arrows indicate protein of interest; IgG is non-specific immunoglobulin G staining. C. Cyclins E1 and E2 both co-purify with centrosomes. T-47D cells were arrested and synchronised at G0 with anti-estrogen ICI 182780 followed by estrogen stimulation for 16h. Lysates were separated by ultracentrifugation on sucrose gradients, fractionated, then pelleted and resuspended in sample buffer for western blotting with the indicated antibodies. γ-tubulin and centrin-2 are centrosome components, and estrogen receptor α (ER) is a non-centrosomal negative control. Data are representative of duplicate experiments. Similar data obtained in MCF-7 cells are shown in Additional file 2.
Common functional complexes of cyclin E1 and E2. A. Cyclin E1 and E2 both co-immunoprecipitate CDK2/CDK2 inhibitor complexes. Lysates of T-47D cells were immunoprecipitated and then western blotted using the indicated antibodies. Data are representative of duplicate experiments. Similar data from MCF7 cells are shown in [19]. IB: immunoblot; IP: immunoprecipitation B. Cyclin E1 and E2 both co-immunoprecipitate SAP145. Lysates of T-47D cells were immunoprecipitated and then western blotted using the indicated antibodies. Data are representative of triplicate experiments. In A. and B. arrows indicate protein of interest; IgG is non-specific immunoglobulin G staining. C. Cyclins E1 and E2 both co-purify with centrosomes. T-47D cells were arrested and synchronised at G0 with anti-estrogen ICI 182780 followed by estrogen stimulation for 16h. Lysates were separated by ultracentrifugation on sucrose gradients, fractionated, then pelleted and resuspended in sample buffer for western blotting with the indicated antibodies. γ-tubulin and centrin-2 are centrosome components, and estrogen receptor α (ER) is a non-centrosomal negative control. Data are representative of duplicate experiments. Similar data obtained in MCF-7 cells are shown in Additional file 2.Cyclin E directly coordinates histone gene transcription with G1 to S phase transition via the phosphorylation of histone transcription factor NPAT in the Histone Locus Bodies (HLB) which localise to histone gene clusters on chromosomes 1 and 6 [7-9]. We found by immunofluorescence that cyclin E2 co-localised with the major HLB protein, NPAT, in T-47D (Figure 3A) and MCF-7 breast cancer cells (Additional file 3), but NPAT rarely co-localised with cyclin E1. The strong association between cyclin E2 and NPAT may be due to the relatively high levels of cyclin E2 observed in breast cancer cell lines [4]. However we observe that cyclin E1 does not relocalise to NPAT foci upon cyclin E2 siRNA treatment (Figure 3B and C). This suggests that the specific cyclin E2-NPAT interaction is due to intrinsic features of cyclin E2 rather than excess cyclin E2 preventing an interaction between cyclin E1 and NPAT.
Figure 3
Cyclin E2, but not cyclin E1, co-localises with NPAT by immunofluorescence in breast cancer cells. A. Cyclin E2 localises to NPAT foci. Confocal images of T-47D cells immunoprobed with cyclin E1 or cyclin E2 (red) and NPAT (green). Experiments performed in triplicate. Example of lack of co-localisation of cyclin E1 (antibody: HE12) and NPAT (antibody: C-19) is shown, and is representative of similar data with cyclin E1 (antibody: Epitomics) and NPAT (antibody: 27) co-staining (not shown). Scale bars = 5μm. Similar data obtained in MCF-7 cells are shown in Additional file 3. B. Confocal images of T-47D cells treated with 20nM cyclin E2 siRNA for 48h, and then immunoprobed with cyclin E1 or cyclin E2 (red) and NPAT (green). Scale bars = 10μm. C. Quantitation of co-localisation using Pearson's correlation coefficient (PCC) which quantifies positional relationship from confocal images on a scale of -1 to +1. Statistical significance was calculated with one-way ANOVA and Tukey’s multiple comparisons, where N.S. indicates not significant and ** indicates P < 0.01. Data pooled from duplicate experiments. Similar data obtained in MCF-7 cells are shown in Additional file 3.
Cyclin E2, but not cyclin E1, co-localises with NPAT by immunofluorescence in breast cancer cells. A. Cyclin E2 localises to NPAT foci. Confocal images of T-47D cells immunoprobed with cyclin E1 or cyclin E2 (red) and NPAT (green). Experiments performed in triplicate. Example of lack of co-localisation of cyclin E1 (antibody: HE12) and NPAT (antibody: C-19) is shown, and is representative of similar data with cyclin E1 (antibody: Epitomics) and NPAT (antibody: 27) co-staining (not shown). Scale bars = 5μm. Similar data obtained in MCF-7 cells are shown in Additional file 3. B. Confocal images of T-47D cells treated with 20nM cyclin E2 siRNA for 48h, and then immunoprobed with cyclin E1 or cyclin E2 (red) and NPAT (green). Scale bars = 10μm. C. Quantitation of co-localisation using Pearson's correlation coefficient (PCC) which quantifies positional relationship from confocal images on a scale of -1 to +1. Statistical significance was calculated with one-way ANOVA and Tukey’s multiple comparisons, where N.S. indicates not significant and ** indicates P < 0.01. Data pooled from duplicate experiments. Similar data obtained in MCF-7 cells are shown in Additional file 3.We confirmed our findings using the in situ Proximity Ligation Assay (PLA), which detects the co-localisation of two antibodies within 40nm on fixed cells by PCR amplification of a linker probe. PLA analysis identified an average of 22 nuclear NPAT-E2 foci per cell, consistent with the multiple HLBs which are detected in aneuploid cancer cell lines [10] (Figure 4A). NPAT-cyclin E2 interactions were 4-fold higher than the number of cyclin E1-NPAT interactions (P < 0.0001; Figure 4B). Cyclin E1-NPAT interactions did not exceed background levels of the αGST/NPAT negative control, and hence are unlikely to represent true HLBs (Figure 4B). Together the immunofluorescence and PLA data indicate that cyclin E2 is the major E-cyclin within HLBs in breast cancer cells and is likely to have a particular role in coordinating the cell cycle with histone transcription.
Figure 4
Cyclin E2, but not cyclin E1, co-localises with NPAT in T-47D cells by PLA. A. Proximity Ligation Assay (PLA) for cyclin E1/NPAT (antibodies: cyclin E1 – Epitomics; NPAT – 27) and cyclin E2/NPAT (antibodies: cyclin E2 – Epitomics; NPAT – 27). Images are 3-D rendered serially stacked confocal images assembled with Imaris software. NPAT/αGST staining was performed as a negative control (antibodies: NPAT – 27, αGST – [23]). Representative cells are shown, scale bars = 10μm. B. Quantitation of A. where number of foci were quantitated from 10-15 cells per antibody pair. Statistical significance was calculated with one-way ANOVA and Tukey’s multiple comparisons, where N.S. indicates not significant and **** indicates P < 0.0001. Data pooled from duplicate experiments. C. Cyclin E1/CDK2 (cyclin E1- HE12, CDK2 – M2) and cyclin E2/CDK2 (cyclin E2 – Epitomics, CDK2 – D12) PLA were performed as positive controls. Representative cells are shown with nuclear foci pseudocoloured in red, and cytoplasmic foci pseudocoloured in white. Scale bars = 10μm. D./E. Quantitation of C. including relative nuclear/cytoplasmic foci (D.) and total foci (E.). Data pooled from duplicate experiments.
Cyclin E2, but not cyclin E1, co-localises with NPAT in T-47D cells by PLA. A. Proximity Ligation Assay (PLA) for cyclin E1/NPAT (antibodies: cyclin E1 – Epitomics; NPAT – 27) and cyclin E2/NPAT (antibodies: cyclin E2 – Epitomics; NPAT – 27). Images are 3-D rendered serially stacked confocal images assembled with Imaris software. NPAT/αGST staining was performed as a negative control (antibodies: NPAT – 27, αGST – [23]). Representative cells are shown, scale bars = 10μm. B. Quantitation of A. where number of foci were quantitated from 10-15 cells per antibody pair. Statistical significance was calculated with one-way ANOVA and Tukey’s multiple comparisons, where N.S. indicates not significant and **** indicates P < 0.0001. Data pooled from duplicate experiments. C. Cyclin E1/CDK2 (cyclin E1- HE12, CDK2 – M2) and cyclin E2/CDK2 (cyclin E2 – Epitomics, CDK2 – D12) PLA were performed as positive controls. Representative cells are shown with nuclear foci pseudocoloured in red, and cytoplasmic foci pseudocoloured in white. Scale bars = 10μm. D./E. Quantitation of C. including relative nuclear/cytoplasmic foci (D.) and total foci (E.). Data pooled from duplicate experiments.As a positive control for PLA analysis we examined cyclin E1-CDK2 and cyclin E2-CDK2 interactions. We observed that both cyclin E1 and cyclin E2 had predominantly nuclear interactions with CDK2 (Figure 4C and D). A proportion of both cyclin E1-CDK2 and cyclin E2-CDK2 foci were cytoplasmic (Figure 4C and D) which is consistent with nuclear-cytoplasmic shuttling of these complexes [11]. Cyclin E1-CDK2 interactions were 2-fold more abundant than cyclin E2-CDK2 (Figure 4E), which again suggests that it is unlikely that excess cyclin E2 prevents cyclin E1 from interacting with other binding partners such as NPAT.Previous publications describe binding of “cyclin E” to NPAT, whereas we here identify that cyclin E2 is the major E-cyclin within HLBs in breast cancer cells. The previous studies were performed prior to the development of specific cyclin E1 and E2 antibodies, and relied upon the cyclin E HE67 (cyclin E1 aa366-381) and HE11 (full-length protein) antibodies which are raised using epitopes that may not effectively discriminate cyclin E1 and cyclin E2 [8,9]. While cyclin E1 may not influence histone transcription in breast cells via NPAT it could influence it via other pathways. Cyclin E/CDK2 indirectly controls histone transcription via E2F-mediated transcription of NPAT [12], and by phosphorylation of the HIRA protein which is a repressor of histone transcription that operates outside S phase [13].Our observation of a specific NPAT-cyclin E2 interaction in breast cancer cell lines was supported by our findings of high expression of replication-dependent histones in breast cancers that have high expression of cyclin E2. We examined the transcript profiles of breast cancers from The Cancer Genome Atlas (TCGA) for cyclin E and histone expression. In 526 breast cancers, high CCNE2 expression is associated with high levels of replication-dependent histones that are under the control of NPAT (Figure 5A). However this pattern is not observed for CCNE1 (Figure 5A), nor with non-replication dependent histones (Figure 5B).
Figure 5
Increased Cyclin E2 expression is associated with higher levels of replication-dependent histones in breast cancers. Box plots illustrate the change in mRNA expression levels of CCNE2 compared to CCNE1 as replication-dependent (A.) and non-replication-dependent (B.) histone expression increases in 526 breast cancer samples. Breast cancer samples were grouped according to the number of replication dependent and independent histones displaying above median expression. Gene expression was normalized to the median expression of group 0 for each sample. p-values were calculated using a Mann-Whitney-U test. Boxes represent the normalized median expression and the 1st and 3rd quartiles and whiskers extend 1.5x the IQR from median.
Increased Cyclin E2 expression is associated with higher levels of replication-dependent histones in breast cancers. Box plots illustrate the change in mRNA expression levels of CCNE2 compared to CCNE1 as replication-dependent (A.) and non-replication-dependent (B.) histone expression increases in 526 breast cancer samples. Breast cancer samples were grouped according to the number of replication dependent and independent histones displaying above median expression. Gene expression was normalized to the median expression of group 0 for each sample. p-values were calculated using a Mann-Whitney-U test. Boxes represent the normalized median expression and the 1st and 3rd quartiles and whiskers extend 1.5x the IQR from median.Cyclin E1 has been recognised as an important oncogene for 20 years [14]. The high degree of sequence homology between cyclin E1 and E2 suggests that many of their functions may be interchangeable, but recent publications in cancer and liver biology show that these proteins have unique regulation and function [15,16]. Our re-examination of cyclin E function has identified that cyclin E2 is likely to have particular role in histone regulation in breast cancer via its unique interaction with NPAT. Cyclin E2 has a strong prognostic role in breast cancer [15], and induces genomic instability that is associated with defects in chromosome condensation [3]. This could be in part due to excessive histone production, as disruption of histone equilibrium is a predicted cause of genomic instability [17].Our identification of multiple foci that contained only cyclin E1 or E2 indicates that there are other unique interactions. This is not surprising given that the low molecular weight derivatives of cyclin E1 also has unique binding and function in cancer cells compared to the full length protein [18]. Future studies should carefully differentiate cyclin E1 and E2 and their isoforms, especially since each protein has unique expression patterns and their expression has distinct correlation with patient outcome in cancer [1].
Methods
Cell lines
Cell lines were authenticated by STR profiling (CellBank Australia, Westmead, NSW, Australia) and cultured for <6 months after authentication. Cyclin E1 and E2 siRNA treatment was performed and validated by western blotting as described in [19].
Immunoblotting and immunoprecipitation
Collection of whole cell lysates [20], chromatin [21] and sucrose gradient fractions of centrosomes [22] were performed as described. Lysates were separated using NuPage polyacrylamide gels (Invitrogen) prior to transfer to PVDF membranes. Western blotting, immunofluorescence and PLA antibodies are: Cdc6 (180.2), CDK2 (M2, D12), centrin-2 (S-19), cyclin E1 (HE12), estrogen receptor α (HC20), NPAT (C-19, 27), SAP145 (A-20), γ-tubulin (C-11) (Santa Cruz Biotechnology); cyclin E2 (Epitomics); p21 (610234) and p27 (610242) (BD Biosciences); αGST [23]. Immunoprecipitation antibodies are: CDK2 (C-19), cyclin E1 (C-19), NPAT (C-19, 27), non-immune IgG (Santa Cruz Biotechnology), and cyclin E2 (Epitomics). Specificity of cyclin E1 and E2 antibodies was demonstrated in [15,19]. Additionally, we show specific loss of cyclin E1 and cyclin E2 immunofluorescence signal with siRNA treatment to cyclin E1 (Additional file 4) and cyclin E2 (Figure 3).
Immunofluorescence and microscopy
Cells were fixed with 4% PFA/PBS for 20 min at room temperature, with or without methanol post-fixation ( -20°C for 20 min). Samples were blocked with 1% BSA/PBS, stained with the indicated antibodies and counterstained with ToPro3/DAPI (Jackson ImmunoResearch Laboratories). Co-localisation was quantitated by detecting overlapping pixels with Imaris v8.0 (Bitplane) and analysed with Pearson’s Correlation Coefficient [24]. For PLA, PFA fixed cells were subjected to the Duolink Proximity Ligation Assay (Sigma) as described by the manufacturer. Confocal microscopy was performed on Leica DMRBE/DMIRE2. Images were analysed with Imaris where individual spots were defined with a variable and initial size estimate of 0.5 μm. Images were processed with Adobe Photoshop, and adjusted for optimal brightness/contrast. Minimal gamma changes were made to enable visualisation of overlaid signals.
Bioinformatics
Expression values in 526 breast cancer samples of CCNE1, CCNE2 and representative replication-dependent and -independent histones (Additional file 5) were accessed from the cBioPortal [25] using the CGDSR package [26] in R [27]. For each sample the number of histones with high expression (> median across patients) was established for histone subsets. Samples were grouped according to the number of histones having above median expression. For each group, the expression level of CCNE1 and CCNE2 was normalised to 100% of the median expression in the patient group with zero highly expressed histones.
Authors: C Elizabeth Caldon; Alexander Swarbrick; Christine S L Lee; Robert L Sutherland; Elizabeth A Musgrove Journal: Cancer Res Date: 2008-04-15 Impact factor: 12.701
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Authors: Roger L Milne; Karoline B Kuchenbaecker; Kyriaki Michailidou; Jonathan Beesley; Siddhartha Kar; Sara Lindström; Shirley Hui; Audrey Lemaçon; Penny Soucy; Joe Dennis; Xia Jiang; Asha Rostamianfar; Hilary Finucane; Manjeet K Bolla; Lesley McGuffog; Qin Wang; Cora M Aalfs; Marcia Adams; Julian Adlard; Simona Agata; Shahana Ahmed; Habibul Ahsan; Kristiina Aittomäki; Fares Al-Ejeh; Jamie Allen; Christine B Ambrosone; Christopher I Amos; Irene L Andrulis; Hoda Anton-Culver; Natalia N Antonenkova; Volker Arndt; Norbert Arnold; Kristan J Aronson; Bernd Auber; Paul L Auer; Margreet G E M Ausems; Jacopo Azzollini; François Bacot; Judith Balmaña; Monica Barile; Laure Barjhoux; Rosa B Barkardottir; Myrto Barrdahl; Daniel Barnes; Daniel Barrowdale; Caroline Baynes; Matthias W Beckmann; Javier Benitez; Marina Bermisheva; Leslie Bernstein; Yves-Jean Bignon; Kathleen R Blazer; Marinus J Blok; Carl Blomqvist; William Blot; Kristie Bobolis; Bram Boeckx; Natalia V Bogdanova; Anders Bojesen; Stig E Bojesen; Bernardo Bonanni; Anne-Lise Børresen-Dale; Aniko Bozsik; Angela R Bradbury; Judith S Brand; Hiltrud Brauch; Hermann Brenner; Brigitte Bressac-de Paillerets; Carole Brewer; Louise Brinton; Per Broberg; Angela Brooks-Wilson; Joan Brunet; Thomas Brüning; Barbara Burwinkel; Saundra S Buys; Jinyoung Byun; Qiuyin Cai; Trinidad Caldés; Maria A Caligo; Ian Campbell; Federico Canzian; Olivier Caron; Angel Carracedo; Brian D Carter; J Esteban Castelao; Laurent Castera; Virginie Caux-Moncoutier; Salina B Chan; Jenny Chang-Claude; Stephen J Chanock; Xiaoqing Chen; Ting-Yuan David Cheng; Jocelyne Chiquette; Hans Christiansen; Kathleen B M Claes; Christine L Clarke; Thomas Conner; Don M Conroy; Jackie Cook; Emilie Cordina-Duverger; Sten Cornelissen; Isabelle Coupier; Angela Cox; David G Cox; Simon S Cross; Katarina Cuk; Julie M Cunningham; Kamila Czene; Mary B Daly; Francesca Damiola; Hatef Darabi; Rosemarie Davidson; Kim De Leeneer; Peter Devilee; Ed Dicks; Orland Diez; Yuan Chun Ding; Nina Ditsch; Kimberly F Doheny; Susan M Domchek; Cecilia M Dorfling; Thilo Dörk; Isabel Dos-Santos-Silva; Stéphane Dubois; Pierre-Antoine Dugué; Martine Dumont; Alison M Dunning; Lorraine Durcan; Miriam Dwek; Bernd Dworniczak; Diana Eccles; Ros Eeles; Hans Ehrencrona; Ursula Eilber; Bent Ejlertsen; Arif B Ekici; A Heather Eliassen; Christoph Engel; Mikael Eriksson; Laura Fachal; Laurence Faivre; Peter A Fasching; Ulrike Faust; Jonine Figueroa; Dieter Flesch-Janys; Olivia Fletcher; Henrik Flyger; William D Foulkes; Eitan Friedman; Lin Fritschi; Debra Frost; Marike Gabrielson; Pragna Gaddam; Marilie D Gammon; Patricia A Ganz; Susan M Gapstur; Judy Garber; Vanesa Garcia-Barberan; José A García-Sáenz; Mia M Gaudet; Marion Gauthier-Villars; Andrea Gehrig; Vassilios Georgoulias; Anne-Marie Gerdes; Graham G Giles; Gord Glendon; Andrew K Godwin; Mark S Goldberg; David E Goldgar; Anna González-Neira; Paul Goodfellow; Mark H Greene; Grethe I Grenaker Alnæs; Mervi Grip; Jacek Gronwald; Anne Grundy; Daphne Gschwantler-Kaulich; Pascal Guénel; Qi Guo; Lothar Haeberle; Eric Hahnen; Christopher A Haiman; Niclas Håkansson; Emily Hallberg; Ute Hamann; Nathalie Hamel; Susan Hankinson; Thomas V O Hansen; Patricia Harrington; Steven N Hart; Jaana M Hartikainen; Catherine S Healey; Alexander Hein; Sonja Helbig; Alex Henderson; Jane Heyworth; Belynda Hicks; Peter Hillemanns; Shirley Hodgson; Frans B Hogervorst; Antoinette Hollestelle; Maartje J Hooning; Bob Hoover; John L Hopper; Chunling Hu; Guanmengqian Huang; Peter J Hulick; Keith Humphreys; David J Hunter; Evgeny N Imyanitov; Claudine Isaacs; Motoki Iwasaki; Louise Izatt; Anna Jakubowska; Paul James; Ramunas Janavicius; Wolfgang Janni; Uffe Birk Jensen; Esther M John; Nichola Johnson; Kristine Jones; Michael Jones; Arja Jukkola-Vuorinen; Rudolf Kaaks; Maria Kabisch; Katarzyna Kaczmarek; Daehee Kang; Karin Kast; Renske Keeman; Michael J Kerin; Carolien M Kets; Machteld Keupers; Sofia Khan; Elza Khusnutdinova; Johanna I Kiiski; Sung-Won Kim; Julia A Knight; Irene Konstantopoulou; Veli-Matti Kosma; Vessela N Kristensen; Torben A Kruse; Ava Kwong; Anne-Vibeke Lænkholm; Yael Laitman; Fiona Lalloo; Diether Lambrechts; Keren Landsman; Christine Lasset; Conxi Lazaro; Loic Le Marchand; Julie Lecarpentier; Andrew Lee; Eunjung Lee; Jong Won Lee; Min Hyuk Lee; Flavio Lejbkowicz; Fabienne Lesueur; Jingmei Li; Jenna Lilyquist; Anne Lincoln; Annika Lindblom; Jolanta Lissowska; Wing-Yee Lo; Sibylle Loibl; Jirong Long; Jennifer T Loud; Jan Lubinski; Craig Luccarini; Michael Lush; Robert J MacInnis; Tom Maishman; Enes Makalic; Ivana Maleva Kostovska; Kathleen E Malone; Siranoush Manoukian; JoAnn E Manson; Sara Margolin; John W M Martens; Maria Elena Martinez; Keitaro Matsuo; Dimitrios Mavroudis; Sylvie Mazoyer; Catriona McLean; Hanne Meijers-Heijboer; Primitiva Menéndez; Jeffery Meyer; Hui Miao; Austin Miller; Nicola Miller; Gillian Mitchell; Marco Montagna; Kenneth Muir; Anna Marie Mulligan; Claire Mulot; Sue Nadesan; Katherine L Nathanson; Susan L Neuhausen; Heli Nevanlinna; Ines Nevelsteen; Dieter Niederacher; Sune F Nielsen; Børge G Nordestgaard; Aaron Norman; Robert L Nussbaum; Edith Olah; Olufunmilayo I Olopade; Janet E Olson; Curtis Olswold; Kai-Ren Ong; Jan C Oosterwijk; Nick Orr; Ana Osorio; V Shane Pankratz; Laura Papi; Tjoung-Won Park-Simon; Ylva Paulsson-Karlsson; Rachel Lloyd; Inge Søkilde Pedersen; Bernard Peissel; Ana Peixoto; Jose I A Perez; Paolo Peterlongo; Julian Peto; Georg Pfeiler; Catherine M Phelan; Mila Pinchev; Dijana Plaseska-Karanfilska; Bruce Poppe; Mary E Porteous; Ross Prentice; Nadege Presneau; Darya Prokofieva; Elizabeth Pugh; Miquel Angel Pujana; Katri Pylkäs; Brigitte Rack; Paolo Radice; Nazneen Rahman; Johanna Rantala; Christine Rappaport-Fuerhauser; Gad Rennert; Hedy S Rennert; Valerie Rhenius; Kerstin Rhiem; Andrea Richardson; Gustavo C Rodriguez; Atocha Romero; Jane Romm; Matti A Rookus; Anja Rudolph; Thomas Ruediger; Emmanouil Saloustros; Joyce Sanders; Dale P Sandler; Suleeporn Sangrajrang; Elinor J Sawyer; Daniel F Schmidt; Minouk J Schoemaker; Fredrick Schumacher; Peter Schürmann; Lukas Schwentner; Christopher Scott; Rodney J Scott; Sheila Seal; Leigha Senter; Caroline Seynaeve; Mitul Shah; Priyanka Sharma; Chen-Yang Shen; Xin Sheng; Hermela Shimelis; Martha J Shrubsole; Xiao-Ou Shu; Lucy E Side; Christian F Singer; Christof Sohn; Melissa C Southey; John J Spinelli; Amanda B Spurdle; Christa Stegmaier; Dominique Stoppa-Lyonnet; Grzegorz Sukiennicki; Harald Surowy; Christian Sutter; Anthony Swerdlow; Csilla I Szabo; Rulla M Tamimi; Yen Y Tan; Jack A Taylor; Maria-Isabel Tejada; Maria Tengström; Soo H Teo; Mary B Terry; Daniel C Tessier; Alex Teulé; Kathrin Thöne; Darcy L Thull; Maria Grazia Tibiletti; Laima Tihomirova; Marc Tischkowitz; Amanda E Toland; Rob A E M Tollenaar; Ian Tomlinson; Ling Tong; Diana Torres; Martine Tranchant; Thérèse Truong; Kathy Tucker; Nadine Tung; Jonathan Tyrer; Hans-Ulrich Ulmer; Celine Vachon; Christi J van Asperen; David Van Den Berg; Ans M W van den Ouweland; Elizabeth J van Rensburg; Liliana Varesco; Raymonda Varon-Mateeva; Ana Vega; Alessandra Viel; Joseph Vijai; Daniel Vincent; Jason Vollenweider; Lisa Walker; Zhaoming Wang; Shan Wang-Gohrke; Barbara Wappenschmidt; Clarice R Weinberg; Jeffrey N Weitzel; Camilla Wendt; Jelle Wesseling; Alice S Whittemore; Juul T Wijnen; Walter Willett; Robert Winqvist; Alicja Wolk; Anna H Wu; Lucy Xia; Xiaohong R Yang; Drakoulis Yannoukakos; Daniela Zaffaroni; Wei Zheng; Bin Zhu; Argyrios Ziogas; Elad Ziv; Kristin K Zorn; Manuela Gago-Dominguez; Arto Mannermaa; Håkan Olsson; Manuel R Teixeira; Jennifer Stone; Kenneth Offit; Laura Ottini; Sue K Park; Mads Thomassen; Per Hall; Alfons Meindl; Rita K Schmutzler; Arnaud Droit; Gary D Bader; Paul D P Pharoah; Fergus J Couch; Douglas F Easton; Peter Kraft; Georgia Chenevix-Trench; Montserrat García-Closas; Marjanka K Schmidt; Antonis C Antoniou; Jacques Simard Journal: Nat Genet Date: 2017-10-23 Impact factor: 38.330
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