Your search keyword '"van Liere, Elsbeth A."' showing total 25 results

1. Oncogenic RAS sensitizes cells to drug-induced replication stress via transcriptional silencing of P53

Author

Segeren, Hendrika A., van Liere, Elsbeth A., Riemers, Frank M., de Bruin, Alain, and Westendorp, Bart

Published

2022

2. Excessive E2F Transcription in Single Cancer Cells Precludes Transient Cell-Cycle Exit after DNA Damage

Author

Segeren, Hendrika A., van Rijnberk, Lotte M., Moreno, Eva, Riemers, Frank M., van Liere, Elsbeth A., Yuan, Ruixue, Wubbolts, Richard, de Bruin, Alain, and Westendorp, Bart

Published

2020

3. E2F-Family Members Engage the PIDDosome to Limit Hepatocyte Ploidy in Liver Development and Regeneration

Author

Sladky, Valentina C., Knapp, Katja, Soratroi, Claudia, Heppke, Julia, Eichin, Felix, Rocamora-Reverte, Lourdes, Szabo, Tamas G., Bongiovanni, Laura, Westendorp, Bart, Moreno, Eva, van Liere, Elsbeth A., Bakker, Bjorn, Spierings, Diana C.J., Wardenaar, René, Pereyra, David, Starlinger, Patrick, Schultze, Simon, Trauner, Michael, Stojakovic, Tatjana, Scharnagl, Hubert, Fava, Luca L., Foijer, Floris, de Bruin, Alain, and Villunger, Andreas

Published

2020

4. Stochastic variation in the FOXM1 transcription program mediates replication stress tolerance.

Author

Segeren, Hendrika A., primary, Wierenga, Kathryn A., additional, Riemers, Frank M., additional, van Liere, Elsbeth A., additional, and Westendorp, Bart, additional

Published

2024

5. Feedback regulation between atypical E2Fs and APC/CCdh1 coordinates cell cycle progression

Author

Boekhout, Michiel, Yuan, Ruixue, Wondergem, Annelotte P, Segeren, Hendrika A, van Liere, Elsbeth A, Awol, Nesibu, Jansen, Imke, Wolthuis, Rob MF, de Bruin, Alain, and Westendorp, Bart

Published

2016

6. CDC6: A novel canine tumour biomarker detected in circulating extracellular vesicles

Author

Andriessen, Anneloes, Bongiovanni, Laura, Driedonks, Tom A P, van Liere, Elsbeth, Seijger, Anne, Hegeman, Charlotte V, van Nimwegen, Sebastiaan A, Galac, Sara, Westendorp, Bart, Nolte-T Hoen, Esther N M, de Bruin, Alain, Andriessen, Anneloes, Bongiovanni, Laura, Driedonks, Tom A P, van Liere, Elsbeth, Seijger, Anne, Hegeman, Charlotte V, van Nimwegen, Sebastiaan A, Galac, Sara, Westendorp, Bart, Nolte-T Hoen, Esther N M, and de Bruin, Alain

Abstract

Circulating nucleic acids and extracellular vesicles (EV) represent novel biomarkers to diagnose cancer. The non-invasive nature of these so-called liquid biopsies provides an attractive alternative to tissue biopsy-based cancer diagnostics. This study aimed to investigate if circulating cell cycle-related E2F target transcripts can be used to diagnose tumours in canine tumour patients with different types of tumours. Furthermore, we assessed if these mRNAs are localised within circulating EV. We isolated total RNA from the plasma of 20 canine tumour patients and 20 healthy controls. Four E2F target genes (CDC6, DHFR, H2AFZ and ATAD2) were selected based on the analysis of published data of tumour samples available in public databases. We performed reverse transcription and quantitative real-time PCR to analyse the plasma levels of selected E2F target transcripts. All four E2F target transcripts were detectable in the plasma of canine tumour patients. CDC6 mRNA levels were significantly higher in the plasma of canine tumour patients compared to healthy controls. A subset of canine tumour patient and healthy control plasma samples (n = 7) were subjected to size exclusion chromatography in order to validate association of the E2F target transcripts to circulating EV. For CDC6, EV analysis enhanced their detectability compared to total plasma analysis. In conclusion, our study reveals circulating CDC6 as a promising non-invasive biomarker to diagnose canine tumours.

Published

2022

7. Oncogenic RAS sensitizes cells to drug-induced replication stress via transcriptional silencing of P53

Author

Pathobiologie, dPB RMSC, Chirurgie, dCSCA RMSC-1, Dep Biomolecular Health Sciences, CS_Locomotion, Segeren, Hendrika A, van Liere, Elsbeth A, Riemers, Frank M, de Bruin, Alain, Westendorp, Bart, Pathobiologie, dPB RMSC, Chirurgie, dCSCA RMSC-1, Dep Biomolecular Health Sciences, CS_Locomotion, Segeren, Hendrika A, van Liere, Elsbeth A, Riemers, Frank M, de Bruin, Alain, and Westendorp, Bart

Published

2022

8. CDC6: A novel canine tumour biomarker detected in circulating extracellular vesicles

Author

dPB RMSC, dB&C I&I, Pathobiologie, Afd Pharmaceutics, Chirurgie, dCSCA AVR, Interne geneeskunde GD, dCSCA RMSC-2, Celbiologie, Dep Biomolecular Health Sciences, CS_Cancer, Andriessen, Anneloes, Bongiovanni, Laura, Driedonks, Tom A P, van Liere, Elsbeth, Seijger, Anne, Hegeman, Charlotte V, van Nimwegen, Sebastiaan A, Galac, Sara, Westendorp, Bart, Nolte-T Hoen, Esther N M, de Bruin, Alain, dPB RMSC, dB&C I&I, Pathobiologie, Afd Pharmaceutics, Chirurgie, dCSCA AVR, Interne geneeskunde GD, dCSCA RMSC-2, Celbiologie, Dep Biomolecular Health Sciences, CS_Cancer, Andriessen, Anneloes, Bongiovanni, Laura, Driedonks, Tom A P, van Liere, Elsbeth, Seijger, Anne, Hegeman, Charlotte V, van Nimwegen, Sebastiaan A, Galac, Sara, Westendorp, Bart, Nolte-T Hoen, Esther N M, and de Bruin, Alain

Published

2022

9. CDC6 : A novel canine tumour biomarker detected in circulating extracellular vesicles

Author

Andriessen, Anneloes, primary, Bongiovanni, Laura, additional, Driedonks, Tom A. P., additional, van Liere, Elsbeth, additional, Seijger, Anne, additional, Hegeman, Charlotte V., additional, van Nimwegen, Sebastiaan A., additional, Galac, Sara, additional, Westendorp, Bart, additional, Nolte‐'t Hoen, Esther N. M., additional, and de Bruin, Alain, additional

Published

2021

10. Atypical E2Fs either Counteract or Cooperate with RB during Tumorigenesis Depending on Tissue Context

Author

Moreno, Eva, Pandit, Shusil K, Toussaint, Mathilda J M, Bongiovanni, Laura, Harkema, Liesbeth, van Essen, Saskia C, van Liere, Elsbeth A, Westendorp, Bart, de Bruin, Alain, LS Pathobiologie, dPB RMSC, Dutch Molecular Pathology Centre, Pathobiologie, Dep Biomolecular Health Sciences, LS Pathobiologie, dPB RMSC, Dutch Molecular Pathology Centre, Pathobiologie, and Dep Biomolecular Health Sciences

Subjects

0301 basic medicine, Genetically modified mouse, EXPRESSION, Cancer Research, Interaction, DNA repair, Repressor, interaction, Context (language use), ORGANIZATION, transgenic mice, medicine.disease_cause, Article, 03 medical and health sciences, 0302 clinical medicine, medicine, Transgenic mice, CELL-CYCLE, RETINOBLASTOMA PROTEIN, TRANSCRIPTION, E2F, Rb, RC254-282, ARREST, biology, MUTATIONS, Retinoblastoma protein, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, Cell cycle, GENE, Atypical E2Fs, atypical E2Fs, tumorigenesis, 030104 developmental biology, Oncology, 030220 oncology & carcinogenesis, FAMILY-MEMBER, Tumorigenesis, ENTRY, Cancer research, biology.protein, biological phenomena, cell phenomena, and immunity, Carcinogenesis

Abstract

Simple SummaryIn virtually all human malignancies, the CDK-RB-E2F pathway is dysregulated resulting in the activation of the E2F transcriptional network. Rb and atypical E2Fs are the most important negative regulators of E2F-dependent transcription during tumorigenesis. However, it is unknown whether they cooporate or act independently in tumor development. Here we show that combined loss of RB and atypical E2Fs in mice enhances tumorigenesis in the liver, while in the pituitary gland, we observe inhibition of tumorigenesis. These findings suggest that the interaction between RB and atypical E2Fs in controlling tumorigenesis occurs in a tissue cell-type specific manner.E2F-transcription factors activate many genes involved in cell cycle progression, DNA repair, and apoptosis. Hence, E2F-dependent transcription must be tightly regulated to prevent tumorigenesis, and therefore metazoan cells possess multiple E2F regulation mechanisms. The best-known is the Retinoblastoma protein (RB), which is mutated in many cancers. Atypical E2Fs (E2F7 and -8) can repress E2F-target gene expression independently of RB and are rarely mutated in cancer. Therefore, they may act as emergency brakes in RB-mutated cells to suppress tumor growth. Currently, it is unknown if and how RB and atypical E2Fs functionally interact in vivo. Here, we demonstrate that mice with liver-specific combinatorial deletion of Rb and E2f7/8 have reduced life-spans compared to E2f7/8 or Rb deletion alone. This was associated with increased proliferation and enhanced malignant progression of liver tumors. Hence, atypical repressor E2Fs and RB cooperatively act as tumor suppressors in hepatocytes. In contrast, loss of either E2f7 or E2f8 largely prevented the formation of pituitary tumors in Rb+/- mice. To test whether atypical E2Fs can also function as oncogenes independent of RB loss, we induced long-term overexpression of E2f7 or E2f8 in mice. E2F7 and -8 overexpression increased the incidence of tumors in the lungs, but not in other tissues. Collectively, these data show that atypical E2Fs can promote but also inhibit tumorigenesis depending on tissue type and RB status. We propose that the complex interactions between atypical E2Fs and RB on maintenance of genetic stability underlie this context-dependency.

Published

2021

11. E2F7 is a potent inhibitor of liver tumor growth in adult mice

Author

Moreno, Eva, Toussaint, Mathilda J M, van Essen, Saskia C, Bongiovanni, Laura, van Liere, Elsbeth A, Koster, Mirjam H, Yuan, Ruixue, van Deursen, Jan, Westendorp, Bart, de Bruin, Alain, Pathobiologie, dPB RMSC, LS Pathobiologie, Dep Biomolecular Health Sciences, Pathobiologie, dPB RMSC, LS Pathobiologie, and Dep Biomolecular Health Sciences

Subjects

0301 basic medicine, Genetically modified mouse, Male, Transcriptional Activation, DNA damage, Transgene, Atypical E2Fs, liver cancer, transgenic mouse models, Apoptosis, Biology, medicine.disease_cause, 03 medical and health sciences, Mice, 0302 clinical medicine, E2F7 Transcription Factor, Liver Biology/Pathobiology, medicine, Animals, Humans, Cell Proliferation, Mice, Knockout, Hepatology, Cell growth, Cell Cycle, Liver Neoplasms, Retinoblastoma protein, DNA replication, Original Articles, Mice, Inbred C57BL, Repressor Proteins, 030104 developmental biology, Cancer research, biology.protein, Hepatocytes, 030211 gastroenterology & hepatology, Original Article, Carcinogenesis, DNA Damage, HeLa Cells

Abstract

Background and Aims Up-regulation of the E2F-dependent transcriptional network has been identified in nearly every human malignancy and is an important driver of tumorigenesis. Two members of the E2F family, E2F7 and E2F8, are potent repressors of E2F-dependent transcription. They are atypical in that they do not bind to dimerization partner proteins and are not controlled by retinoblastoma protein. The physiological relevance of E2F7 and E2F8 remains incompletely understood, largely because tools to manipulate their activity in vivo have been lacking.Approach and Results Here, we generated transgenic mice with doxycycline-controlled transcriptional activation of E2f7 and E2f8 and induced their expression during postnatal development, in adulthood, and in the context of cancer. Systemic induction of E2f7 and, to lesser extent, E2f8 transgenes in juvenile mice impaired cell proliferation, caused replication stress, DNA damage, and apoptosis, and inhibited animal growth. In adult mice, however, E2F7 and E2F8 induction was well tolerated, yet profoundly interfered with DNA replication, DNA integrity, and cell proliferation in diethylnitrosamine-induced liver tumors.Conclusion Collectively, our findings demonstrate that atypical E2Fs can override cell-cycle entry and progression governed by other E2F family members and suggest that this property can be exploited to inhibit proliferation of neoplastic hepatocytes when growth and development have subsided during adulthood.

Published

2021

12. Atypical E2Fs either Counteract or Cooperate with RB during Tumorigenesis Depending on Tissue Context

Author

LS Pathobiologie, dPB RMSC, Dutch Molecular Pathology Centre, Pathobiologie, Dep Biomolecular Health Sciences, Moreno, Eva, Pandit, Shusil K, Toussaint, Mathilda J M, Bongiovanni, Laura, Harkema, Liesbeth, van Essen, Saskia C, van Liere, Elsbeth A, Westendorp, Bart, de Bruin, Alain, LS Pathobiologie, dPB RMSC, Dutch Molecular Pathology Centre, Pathobiologie, Dep Biomolecular Health Sciences, Moreno, Eva, Pandit, Shusil K, Toussaint, Mathilda J M, Bongiovanni, Laura, Harkema, Liesbeth, van Essen, Saskia C, van Liere, Elsbeth A, Westendorp, Bart, and de Bruin, Alain

Published

2021

13. E2F7 is a potent inhibitor of liver tumor growth in adult mice

Author

Pathobiologie, dPB RMSC, LS Pathobiologie, Dep Biomolecular Health Sciences, Moreno, Eva, Toussaint, Mathilda J M, van Essen, Saskia C, Bongiovanni, Laura, van Liere, Elsbeth A, Koster, Mirjam H, Yuan, Ruixue, van Deursen, Jan, Westendorp, Bart, de Bruin, Alain, Pathobiologie, dPB RMSC, LS Pathobiologie, Dep Biomolecular Health Sciences, Moreno, Eva, Toussaint, Mathilda J M, van Essen, Saskia C, Bongiovanni, Laura, van Liere, Elsbeth A, Koster, Mirjam H, Yuan, Ruixue, van Deursen, Jan, Westendorp, Bart, and de Bruin, Alain

Published

2021

14. Oncogenic RAS sensitizes cells to drug-induced replication stress via transcriptional silencing of P53

Author

Segeren, Hendrika A., primary, van Liere, Elsbeth A., additional, Riemers, Frank M., additional, de Bruin, Alain, additional, and Westendorp, Bart, additional

Published

2021

15. Excessive E2F Transcription in Single Cancer Cells Precludes Transient Cell-Cycle Exit after DNA Damage

Author

Pathobiologie, dPB RMSC, Chirurgie, dCSCA RMSC-1, LS Pathobiologie, IOV CCB, Celbiologie, dB&C I&I, Dep Biomolecular Health Sciences, CS_Locomotion, Segeren, Hendrika A., van Rijnberk, Lotte M., Moreno, Eva, Riemers, Frank M., van Liere, Elsbeth A., Yuan, Ruixue, Wubbolts, Richard, de Bruin, Alain, Westendorp, Bart, Pathobiologie, dPB RMSC, Chirurgie, dCSCA RMSC-1, LS Pathobiologie, IOV CCB, Celbiologie, dB&C I&I, Dep Biomolecular Health Sciences, CS_Locomotion, Segeren, Hendrika A., van Rijnberk, Lotte M., Moreno, Eva, Riemers, Frank M., van Liere, Elsbeth A., Yuan, Ruixue, Wubbolts, Richard, de Bruin, Alain, and Westendorp, Bart

Published

2020

16. E2F-Family Members Engage the PIDDosome to Limit Hepatocyte Ploidy in Liver Development and Regeneration

Author

Pathobiologie, dPB RMSC, Dep Biomolecular Health Sciences, Sladky, Valentina C., Knapp, Katja, Soratroi, Claudia, Heppke, Julia, Eichin, Felix, Rocamora-Reverte, Lourdes, Szabo, Tamas G., Bongiovanni, Laura, Westendorp, Bart, Moreno, Eva, van Liere, Elsbeth A., Bakker, Bjorn, Spierings, Diana C.J., Wardenaar, René, Pereyra, David, Starlinger, Patrick, Schultze, Simon, Trauner, Michael, Stojakovic, Tatjana, Scharnagl, Hubert, Fava, Luca L., Foijer, Floris, de Bruin, Alain, Villunger, Andreas, Pathobiologie, dPB RMSC, Dep Biomolecular Health Sciences, Sladky, Valentina C., Knapp, Katja, Soratroi, Claudia, Heppke, Julia, Eichin, Felix, Rocamora-Reverte, Lourdes, Szabo, Tamas G., Bongiovanni, Laura, Westendorp, Bart, Moreno, Eva, van Liere, Elsbeth A., Bakker, Bjorn, Spierings, Diana C.J., Wardenaar, René, Pereyra, David, Starlinger, Patrick, Schultze, Simon, Trauner, Michael, Stojakovic, Tatjana, Scharnagl, Hubert, Fava, Luca L., Foijer, Floris, de Bruin, Alain, and Villunger, Andreas

Published

2020

17. E2F-Family Members Engage the PIDDosome to Limit Hepatocyte Ploidy in Liver Development and Regeneration

Author

Sladky, Valentina C., Knapp, Katja, Soratroi, Claudia, Heppke, Julia, Eichin, Felix, Rocamora-Reverte, Lourdes, Szabo, Tamas G., Bongiovanni, Laura, Westendorp, Bart, Moreno, Eva, van Liere, Elsbeth A., Bakker, Bjorn, Spierings, Diana C.J., Wardenaar, René, Pereyra, David, Starlinger, Patrick, Schultze, Simon, Trauner, Michael, Stojakovic, Tatjana, Scharnagl, Hubert, Fava, Luca L., Foijer, Floris, de Bruin, Alain, Villunger, Andreas, Damage and Repair in Cancer Development and Cancer Treatment (DARE), Stem Cell Aging Leukemia and Lymphoma (SALL), Restoring Organ Function by Means of Regenerative Medicine (REGENERATE), Pathobiologie, dPB RMSC, and Dep Biomolecular Health Sciences

Subjects

p53, Cyclin-Dependent Kinase Inhibitor p21, Male, Death Domain Receptor Signaling Adaptor Proteins, caspases, liver development, PIDDosome, polyploidy, regeneration, Polyploidy, Mice, Animals, Humans, Cytokinesis, Centrosome, Mice, Knockout, Caspase 2, CRADD Signaling Adaptor Protein, Aneuploidy, E2F Transcription Factors, Liver Regeneration, Hepatocytes, Female, Tumor Suppressor Protein p53

Abstract

E2F transcription factors control the cytokinesis machinery and thereby ploidy in hepatocytes. If or how these proteins limit proliferation of polyploid cells with extra centrosomes remains unknown. Here, we show that the PIDDosome, a signaling platform essential for caspase-2-activation, limits hepatocyte ploidy and is instructed by the E2F network to control p53 in the developing as well as regenerating liver. Casp2 and Pidd1 act as direct transcriptional targets of E2F1 and its antagonists, E2F7 and E2F8, that together co-regulate PIDDosome expression during juvenile liver growth and regeneration. Of note, whereas hepatocyte aneuploidy correlates with the basal ploidy state, the degree of aneuploidy itself is not limited by PIDDosome-dependent p53 activation. Finally, we provide evidence that the same signaling network is engaged to control ploidy in the human liver after resection. Our study defines the PIDDosome as a primary target to manipulate hepatocyte ploidy and proliferation rates in the regenerating liver. Sladky et al. report a key role for the PIDDosome in regulating p53 activation to limit hepatocyte polyploidy during juvenile liver growth and regeneration. Expression of essential PIDDosome components is controlled by a E2F-family regulated circuitry. The study defines the PIDDosome as a putative target to enhance liver regeneration.

Published

2019

18. Atypical E2f functions are critical for pancreas polyploidization

Author

Matondo, Ramadhan B, Moreno, Eva, Toussaint, Mathilda J M, Tooten, Peter C J, van Essen, Saskia C, van Liere, Elsbeth A, Youssef, Sameh A, Bongiovanni, Laura, de Bruin, Alain, LS Pathobiologie, dPB RMSC, LS Pathobiologie, and dPB RMSC

Subjects

0301 basic medicine, Genetics and Molecular Biology (all), Blood Glucose, Angiogenesis, medicine.medical_treatment, Amylases, Animals, E2F Transcription Factors, Growth, Insulin, Lipase, Mice, Pancreas, Survival Analysis, Polyploidy, Biochemistry, Genetics and Molecular Biology (all), Agricultural and Biological Sciences (all), lcsh:Medicine, Biochemistry, Blood serum, Endocrinology, Spectrum Analysis Techniques, Medicine and Health Sciences, Amylase, lcsh:Science, 2. Zero hunger, Staining, Multidisciplinary, biology, Cell Staining, food and beverages, Animal Models, Flow Cytometry, medicine.anatomical_structure, Experimental Organism Systems, Spectrophotometry, Cytophotometry, Anatomy, Research Article, medicine.medical_specialty, Endocrine System, Mouse Models, Research and Analysis Methods, 03 medical and health sciences, Exocrine Glands, Model Organisms, Internal medicine, medicine, Genetics, Endocrine system, Diabetic Endocrinology, lcsh:R, Biology and Life Sciences, Embryonic stem cell, Hormones, Nuclear Staining, 030104 developmental biology, Specimen Preparation and Treatment, biology.protein, lcsh:Q, Departures from Diploidy, Hormone

Abstract

The presence of polyploid cells in the endocrine and exocrine pancreas has been reported for four decades. In rodents, pancreatic polyploidization is initiated after weaning and the number of polyploid cells increases with age. Surprisingly the molecular regulators and biological functions of polyploidization in the pancreas are still unknown. We discovered that atypical E2f activity is essential for polyploidization in the pancreas, using an inducible Cre/LoxP approach in new-born mice to delete ubiquitously the atypical E2f transcription factors, E2f7 and E2f8. In contrast to its critical role in embryonic survival, conditional deletion of both of both atypical E2fs in newborn mice had no impact on postnatal survival and mice lived until old age. However, deficiency of E2f7 or E2f8 alone was sufficient to suppress polyploidization in the pancreas and associated with only a minor decrease in blood serum levels of glucose, insulin, amylase and lipase under 4 hours starvation condition compared to wildtype littermates. In mice with fewer pancreatic polyploid cells that were fed ad libitum, no major impact on hormones or enzymes levels was observed. In summary, we identified atypical E2fs to be essential for polyploidization in the pancreas and discovered that postnatal induced loss of both atypical E2fs in many organs is compatible with life until old age.

Published

2018

19. Atypical E2f functions are critical for pancreas polyploidization

Author

LS Pathobiologie, dPB RMSC, Matondo, Ramadhan B, Moreno, Eva, Toussaint, Mathilda J M, Tooten, Peter C J, van Essen, Saskia C, van Liere, Elsbeth A, Youssef, Sameh A, Bongiovanni, Laura, de Bruin, Alain, LS Pathobiologie, dPB RMSC, Matondo, Ramadhan B, Moreno, Eva, Toussaint, Mathilda J M, Tooten, Peter C J, van Essen, Saskia C, van Liere, Elsbeth A, Youssef, Sameh A, Bongiovanni, Laura, and de Bruin, Alain

Published

2018

20. Feedback regulation between atypical E2Fs and APC/C Cdh1 coordinates cell cycle progression

Author

Boekhout, Michiel, Yuan, Ruixue, Wondergem, Annelotte P, Segeren, Hendrika A, Van Liere, Elsbeth A, Awol, Nesibu, Jansen, Imke, Wolthuis, Rob Mf, De Bruin, Alain, Westendorp, Bart, Boekhout, Michiel, Yuan, Ruixue, Wondergem, Annelotte P, Segeren, Hendrika A, Van Liere, Elsbeth A, Awol, Nesibu, Jansen, Imke, Wolthuis, Rob Mf, De Bruin, Alain, and Westendorp, Bart

Abstract

E2F transcription factors control the oscillating expression pattern of multiple target genes during the cell cycle. Activator E2Fs, E2F1–3, induce an upswing of E2F targets, which is essential for the G1-to-S phase transition, whereas atypical E2Fs, E2F7 and E2F8, mediate a downswing of the same targets during late S, G2, and M phases. Expression of atypical E2Fs is induced by E2F1–3, but it is unknown how atypical E2Fs are inactivated in a timely manner. Here, we demonstrate that E2F7 and E2F8 are substrates of the anaphase-promoting complex/cyclosome (APC/C). Removal of CDH1, or mutating the CDH1-interacting KEN boxes, stabilized E2F7/8 from anaphase onwards and during G1. Expressing KEN mutant E2F7 during G1 impairs S phase entry and eventually results in cell death. Furthermore, we show that E2F8, but not E2F7, interacts also with APC/C Cdc20 . Importantly, atypical E2Fs can activate APC/C Cdh1 by repressing its inhibitors cyclin A, cyclin E, and Emi1. In conclusion, we discovered a feedback loop between atypical E2Fs and APC/C Cdh1 , which ensures balanced expression of cell cycle genes and normal cell cycle progression.

Published

2016

21. Feedback regulation between atypical E2Fs and APC/C Cdh1 coordinates cell cycle progression

Author

LS Pathobiologie, dPB RMSC, Boekhout, Michiel, Yuan, Ruixue, Wondergem, Annelotte P, Segeren, Hendrika A, Van Liere, Elsbeth A, Awol, Nesibu, Jansen, Imke, Wolthuis, Rob Mf, De Bruin, Alain, Westendorp, Bart, LS Pathobiologie, dPB RMSC, Boekhout, Michiel, Yuan, Ruixue, Wondergem, Annelotte P, Segeren, Hendrika A, Van Liere, Elsbeth A, Awol, Nesibu, Jansen, Imke, Wolthuis, Rob Mf, De Bruin, Alain, and Westendorp, Bart

Published

2016

22. E2F8 is essential for polyploidization in mammalian cells

Author

Pandit, Shusil K, Westendorp, Bart, Nantasanti, Sathidpak, van Liere, Elsbeth, Tooten, Peter C J, Cornelissen, Peter W A, Toussaint, Mathilda J M, Lamers, Wouter H, de Bruin, Alain, LS Pathobiologie, Tytgat Institute for Liver and Intestinal Research, LS Pathobiologie, Anatomie & Embryologie, and RS: NUTRIM - R2 - Gut-liver homeostasis

Subjects

Liver cytology, Knockout, Cellular differentiation, genetic processes, Repressor, Biology, Polyploidy, Mice, E2F7 Transcription Factor, medicine, Animals, Humans, E2F1, E2F, Mice, Knockout, Activator (genetics), fungi, food and beverages, Cell Differentiation, Hep G2 Cells, Cell Biology, pathological conditions, signs and symptoms, Cell biology, Repressor Proteins, medicine.anatomical_structure, Liver, Hepatocyte, Hepatocytes, Cancer research, biological phenomena, cell phenomena, and immunity, E2F1 Transcription Factor, Cytokinesis

Abstract

Polyploidization is observed in all mammalian species and is a characteristic feature of hepatocytes, but its molecular mechanism and biological significance are unknown. Hepatocyte polyploidization in rodents occurs through incomplete cytokinesis, starts after weaning and increases with age. Here, we show in mice that atypical E2F8 is induced after weaning and required for hepatocyte binucleation and polyploidization. A deficiency in E2f8 led to an increase in the expression level of E2F target genes promoting cytokinesis and thereby preventing polyploidization. In contrast, loss of E2f1 enhanced polyploidization and suppressed the polyploidization defect of hepatocytes deficient for atypical E2Fs. In addition, E2F8 and E2F1 were found on the same subset of target promoters. Contrary to the long-standing hypothesis that polyploidization indicates terminal differentiation and senescence, we show that prevention of polyploidization through inactivation of atypical E2Fs has, surprisingly, no impact on liver differentiation, zonation, metabolism and regeneration. Together, these results identify E2F8 as a repressor and E2F1 as an activator of a transcriptional network controlling polyploidization in mammalian cells.

Published

2012

23. E2F8 is essential for polyploidization in mammalian cells

Author

LS Pathobiologie, Pandit, Shusil K, Westendorp, Bart, Nantasanti, Sathidpak, van Liere, Elsbeth, Tooten, Peter C J, Cornelissen, Peter W A, Toussaint, Mathilda J M, Lamers, Wouter H, de Bruin, Alain, LS Pathobiologie, Pandit, Shusil K, Westendorp, Bart, Nantasanti, Sathidpak, van Liere, Elsbeth, Tooten, Peter C J, Cornelissen, Peter W A, Toussaint, Mathilda J M, Lamers, Wouter H, and de Bruin, Alain

Published

2012

24. E2F7 Is a Potent Inhibitor of Liver Tumor Growth in Adult Mice.

Author

Moreno E, Toussaint MJM, van Essen SC, Bongiovanni L, van Liere EA, Koster MH, Yuan R, van Deursen JM, Westendorp B, and de Bruin A

Subjects

Animals, Apoptosis physiology, Cell Cycle physiology, DNA Damage, E2F7 Transcription Factor deficiency, E2F7 Transcription Factor genetics, HeLa Cells, Humans, Liver Neoplasms genetics, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, Repressor Proteins deficiency, Repressor Proteins genetics, Transcriptional Activation, Cell Proliferation, E2F7 Transcription Factor physiology, Hepatocytes metabolism, Liver Neoplasms pathology, Repressor Proteins physiology

Abstract

Background and Aims: Up-regulation of the E2F-dependent transcriptional network has been identified in nearly every human malignancy and is an important driver of tumorigenesis. Two members of the E2F family, E2F7 and E2F8, are potent repressors of E2F-dependent transcription. They are atypical in that they do not bind to dimerization partner proteins and are not controlled by retinoblastoma protein. The physiological relevance of E2F7 and E2F8 remains incompletely understood, largely because tools to manipulate their activity in vivo have been lacking., Approach and Results: Here, we generated transgenic mice with doxycycline-controlled transcriptional activation of E2f7 and E2f8 and induced their expression during postnatal development, in adulthood, and in the context of cancer. Systemic induction of E2f7 and, to lesser extent, E2f8 transgenes in juvenile mice impaired cell proliferation, caused replication stress, DNA damage, and apoptosis, and inhibited animal growth. In adult mice, however, E2F7 and E2F8 induction was well tolerated, yet profoundly interfered with DNA replication, DNA integrity, and cell proliferation in diethylnitrosamine-induced liver tumors., Conclusion: Collectively, our findings demonstrate that atypical E2Fs can override cell-cycle entry and progression governed by other E2F family members and suggest that this property can be exploited to inhibit proliferation of neoplastic hepatocytes when growth and development have subsided during adulthood., (© 2020 The Authors. Hepatology published by Wiley Periodicals LLC on behalf of American Association for the Study of Liver Diseases.)

Published

2021

25. Atypical E2f functions are critical for pancreas polyploidization.

Author

Matondo RB, Moreno E, Toussaint MJM, Tooten PCJ, van Essen SC, van Liere EA, Youssef SA, Bongiovanni L, and de Bruin A

Subjects

Amylases blood, Animals, Blood Glucose metabolism, Growth, Insulin blood, Lipase blood, Mice, Survival Analysis, E2F Transcription Factors physiology, Pancreas cytology, Polyploidy

Abstract

The presence of polyploid cells in the endocrine and exocrine pancreas has been reported for four decades. In rodents, pancreatic polyploidization is initiated after weaning and the number of polyploid cells increases with age. Surprisingly the molecular regulators and biological functions of polyploidization in the pancreas are still unknown. We discovered that atypical E2f activity is essential for polyploidization in the pancreas, using an inducible Cre/LoxP approach in new-born mice to delete ubiquitously the atypical E2f transcription factors, E2f7 and E2f8. In contrast to its critical role in embryonic survival, conditional deletion of both of both atypical E2fs in newborn mice had no impact on postnatal survival and mice lived until old age. However, deficiency of E2f7 or E2f8 alone was sufficient to suppress polyploidization in the pancreas and associated with only a minor decrease in blood serum levels of glucose, insulin, amylase and lipase under 4 hours starvation condition compared to wildtype littermates. In mice with fewer pancreatic polyploid cells that were fed ad libitum, no major impact on hormones or enzymes levels was observed. In summary, we identified atypical E2fs to be essential for polyploidization in the pancreas and discovered that postnatal induced loss of both atypical E2fs in many organs is compatible with life until old age.

Published

2018