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5. Correction: Winkler et al. The Adhesion G-Protein-Coupled Receptor GPR115/ ADGRF4 Regulates Epidermal Differentiation and Associates with Cytoskeletal KRT1. Cells 2022, 11 , 3151.

Author

Winkler, Romy, Quaas, Marianne, Glasmacher, Stefan, Wolfrum, Uwe, Thalheim, Torsten, Galle, Jörg, Krohn, Knut, Magin, Thomas M., and Aust, Gabriela

Subjects
*HORSERADISH peroxidase, *WESTERN immunoblotting, KERATINOCYTE differentiation
Abstract

(f) The percentages of GPR115+ and KRT1/10+ cells were determined in these constructs built with HaCaT WT cells (n = 10 optical fields, n = 20-27 cells/field, means ± SEM). (c) Western blot analysis of lysates of HA-GPR115 Cos-7 cells treated with PNGase F (left) or of HA-GPR115 Cos-7 cells cultured with tunicamycin (right); the Abs used are indicated. (b) HaCaT WT cells and Cos-7 cells, transfected with GPR115 pcDNA3.1, were cell-surface-stained with the GPR115ECD Ab and analyzed by flow cytometry. [Extracted from the article]

Published
2023
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6. The Adhesion G-Protein-Coupled Receptor GPR115/ADGRF4 Regulates Epidermal Differentiation and Associates with Cytoskeletal KRT1

Author

Winkler, Romy, Quaas, Marianne, Glasmacher, Stefan, Wolfrum, Uwe, Thalheim, Torsten, Galle, Jörg, Krohn, Knut, Magin, Thomas M., Aust, Gabriela, Winkler, Romy, Quaas, Marianne, Glasmacher, Stefan, Wolfrum, Uwe, Thalheim, Torsten, Galle, Jörg, Krohn, Knut, Magin, Thomas M., and Aust, Gabriela

Abstract

Among the 33 human adhesion G-protein-coupled receptors (aGPCRs), a unique subfamily of GPCRs, only ADGRF4, encoding GPR115, shows an obvious skin-dominated transcriptomic profile, but its expression and function in skin is largely unknown. Here, we report that GPR115 is present in a small subset of basal and in most suprabasal, noncornified keratinocytes of the stratified epidermis, supporting epidermal transcriptomic data. In psoriatic skin, characterized by hyperproliferation and delayed differentiation, the expression of GPR115 and KRT1/10, the fundamental suprabasal keratin dimer, is delayed. The deletion of ADGRF4 in HaCaT keratinocytes grown in an organotypic mode abrogates KRT1 and reduces keratinocyte stratification, indicating a role of GPR115 in epidermal differentiation. Unexpectedly, endogenous GPR115, which is not glycosylated and is likely not proteolytically processed, localizes intracellularly along KRT1/10-positive keratin filaments in a regular pattern. Our data demonstrate a hitherto unknown function of GPR115 in the regulation of epidermal differentiation and KRT1.

Published
2022

7. To Detach, Migrate, Adhere, and Metastasize: CD97/ADGRE5 in Cancer

Author

Aust, Gabriela, Zheng, Leyu, Quaas, Marianne, Aust, Gabriela, Zheng, Leyu, and Quaas, Marianne

Abstract

Tumorigenesis is a multistep process, during which cells acquire a series of mutations that lead to unrestrained cell growth and proliferation, inhibition of cell differentiation, and evasion of cell death. Growing tumors stimulate angiogenesis, providing them with nutrients and oxygen. Ultimately, tumor cells invade the surrounding tissue and metastasize; a process responsible for about 90% of cancer-related deaths. Adhesion G protein-coupled receptors (aGPCRs) modulate the cellular processes closely related to tumor cell biology, such as adhesion and detachment, migration, polarity, and guidance. Soon after first being described, individual human aGPCRs were found to be involved in tumorigenesis. Twenty-five years ago, CD97/ADGRE5 was discovered to be induced in one of the most severe tumors, dedifferentiated anaplastic thyroid carcinoma. After decades of research, the time has come to review our knowledge of the presence and function of CD97 in cancer. In summary, CD97 is obviously induced or altered in many tumor entities; this has been shown consistently in nearly one hundred published studies. However, its high expression at circulating and tumor-infiltrating immune cells renders the systemic targeting of CD97 in tumors difficult.

Published
2022

10. How to Obtain a Mega-Intestine with Normal Morphology: In Silico Modelling of Postnatal Intestinal Growth in a Cd97-Transgenic Mouse

Author

Hofmann, Felix, Thalheim, Torsten, Rother, Karen, Quaas, Marianne, Kerner, Christiane, Przybilla, Jens, Aust, Gabriela, and Galle, Joerg

Subjects
QH301-705.5, fate decision, Mice, Transgenic, individual cell-based model, Areg, Models, Biological, Article, Receptors, G-Protein-Coupled, Kruppel-Like Factor 4, Mice, Organ Culture Techniques, Intestine, Small, Animals, Cd97, Computer Simulation, Biology (General), Intestinal Mucosa, QD1-999, Stem Cells, crypt formation, Klf4, postnatal development, crypt fission, Chemistry, mega-intestine, contact inhibition of growth, stem cell fate
Abstract

Intestinal cylindrical growth peaks in mice a few weeks after birth, simultaneously with crypt fission activity. It nearly stops after weaning and cannot be reactivated later. Transgenic mice expressing Cd97/Adgre5 in the intestinal epithelium develop a mega-intestine with normal microscopic morphology in adult mice. Here, we demonstrate premature intestinal differentiation in Cd97/Adgre5 transgenic mice at both the cellular and molecular levels until postnatal day 14. Subsequently, the growth of the intestinal epithelium becomes activated and its maturation suppressed. These changes are paralleled by postnatal regulation of growth factors and by an increased expression of secretory cell markers, suggesting growth activation of non-epithelial tissue layers as the origin of enforced tissue growth. To understand postnatal intestinal growth mechanistically, we study epithelial fate decisions during this period with the use of a 3D individual cell-based computer model. In the model, the expansion of the intestinal stem cell (SC) population, a prerequisite for crypt fission, is largely independent of the tissue growth rate and is therefore not spontaneously adaptive. Accordingly, the model suggests that, besides the growth activation of non-epithelial tissue layers, the formation of a mega-intestine requires a released growth control in the epithelium, enabling accelerated SC expansion. The similar intestinal morphology in Cd97/Adgre5 transgenic and wild type mice indicates a synchronization of tissue growth and SC expansion, likely by a crypt density-controlled contact inhibition of growth of intestinal SC proliferation. The formation of a mega-intestine with normal microscopic morphology turns out to originate in changes of autonomous and conditional specification of the intestinal cell fate induced by the activation of Cd97/Adgre5.

Published
2021

11. Epigenetic Drifts during Long-Term Intestinal Organoid Culture

Author

Thalheim, Torsten, Siebert, Susann, Quaas, Marianne, Herberg, Maria, Schweiger, Michal R., Aust, Gabriela, and Galle, Joerg

Subjects
Time Factors, Transcription, Genetic, QH301-705.5, H3K27me3, mouse small intestine, H3K4me3, Adaptation, Physiological, MMR-deficient mice, Article, Epigenesis, Genetic, Histones, Organoids, ChIP-seq, Mice, age-related drifts, Organ Culture Techniques, ddc:570, Animals, histone modification, Biology (General), RNA-seq
Abstract

Organoids retain the morphological and molecular patterns of their tissue of origin, are self-organizing, relatively simple to handle and accessible to genetic engineering. Thus, they represent an optimal tool for studying the mechanisms of tissue maintenance and aging. Long-term expansion under standard growth conditions, however, is accompanied by changes in the growth pattern and kinetics. As a potential explanation of these alterations, epigenetic drifts in organoid culture have been suggested. Here, we studied histone tri-methylation at lysine 4 (H3K4me3) and 27 (H3K27me3) and transcriptome profiles of intestinal organoids derived from mismatch repair (MMR)-deficient and control mice and cultured for 3 and 20 weeks and compared them with data on their tissue of origin. We found that, besides the expected changes in short-term culture, the organoids showed profound changes in their epigenomes also during the long-term culture. The most prominent were epigenetic gene activation by H3K4me3 recruitment to previously unmodified genes and by H3K27me3 loss from originally bivalent genes. We showed that a long-term culture is linked to broad transcriptional changes that indicate an ongoing maturation and metabolic adaptation process. This process was disturbed in MMR-deficient mice, resulting in endoplasmic reticulum (ER) stress and Wnt activation. Our results can be explained in terms of a mathematical model assuming that epigenetic changes during a long-term culture involve DNA demethylation that ceases if the metabolic adaptation is disturbed.

Published
2021

12. The Adhesion G-Protein-Coupled Receptor GPR115/ ADGRF4 Regulates Epidermal Differentiation and Associates with Cytoskeletal KRT1.

Author

Winkler, Romy, Quaas, Marianne, Glasmacher, Stefan, Wolfrum, Uwe, Thalheim, Torsten, Galle, Jörg, Krohn, Knut, Magin, Thomas M., and Aust, Gabriela

Subjects
*KERATINOCYTES, *KERATIN, *TRANSCRIPTOMES, *EPIDERMIS, *G protein coupled receptors, *FIBERS
Abstract

Among the 33 human adhesion G-protein-coupled receptors (aGPCRs), a unique subfamily of GPCRs, only ADGRF4, encoding GPR115, shows an obvious skin-dominated transcriptomic profile, but its expression and function in skin is largely unknown. Here, we report that GPR115 is present in a small subset of basal and in most suprabasal, noncornified keratinocytes of the stratified epidermis, supporting epidermal transcriptomic data. In psoriatic skin, characterized by hyperproliferation and delayed differentiation, the expression of GPR115 and KRT1/10, the fundamental suprabasal keratin dimer, is delayed. The deletion of ADGRF4 in HaCaT keratinocytes grown in an organotypic mode abrogates KRT1 and reduces keratinocyte stratification, indicating a role of GPR115 in epidermal differentiation. Unexpectedly, endogenous GPR115, which is not glycosylated and is likely not proteolytically processed, localizes intracellularly along KRT1/10-positive keratin filaments in a regular pattern. Our data demonstrate a hitherto unknown function of GPR115 in the regulation of epidermal differentiation and KRT1. [ABSTRACT FROM AUTHOR]

Published
2022
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13. Fighting Against Promoter DNA Hyper-Methylation: Protective Histone Modification Profiles of Stress-Resistant Intestinal Stem Cells

Author

Thalheim, Torsten, Hopp, Lydia, Herberg, Maria, Siebert, Susann, Kerner, Christiane, Quaas, Marianne, Schweiger, Michal R., Aust, Gabriela, and Galle, Joerg

Subjects
computational modeling, irradiation, Stem Cells, DNA, DNA Methylation, promoter dna hyper-methylation, Article, Epigenesis, Genetic, Histone Code, Histones, Intestines, lcsh:Chemistry, Mice, loss of msh2 function, lcsh:Biology (General), lcsh:QD1-999, Animals, histone methylation, dna damage, Promoter Regions, Genetic, lcsh:QH301-705.5
Abstract

Aberrant DNA methylation in stem cells is a hallmark of aging and tumor development. Recently, we have suggested that promoter DNA hyper-methylation originates in DNA repair and that even successful DNA repair might confer this kind of epigenetic long-term change. Here, we ask for interrelations between promoter DNA methylation and histone modification changes observed in the intestine weeks after irradiation and/or following Msh2 loss. We focus on H3K4me3 recruitment to the promoter of H3K27me3 target genes. By RNA- and histone ChIP-sequencing, we demonstrate that this recruitment occurs without changes of the average gene transcription and does not involve H3K9me3. Applying a mathematical model of epigenetic regulation of transcription, we show that the recruitment can be explained by stronger DNA binding of H3K4me3 and H3K27me3 histone methyl-transferases as a consequence of lower DNA methylation. This scenario implicates stable transcription despite of H3K4me3 recruitment, in agreement with our RNA-seq data. Following several kinds of stress, including moderate irradiation, stress-sensitive intestinal stem cell (ISCs) are known to become replaced by more resistant populations. Our simulation results suggest that the stress-resistant ISCs are largely protected against promoter hyper-methylation of H3K27me3 target genes.

Published
2020

16. To Detach, Migrate, Adhere, and Metastasize: CD97/ ADGRE5 in Cancer.

Author

Aust, Gabriela, Zheng, Leyu, and Quaas, Marianne

Subjects
ANAPLASTIC thyroid cancer, TUMOR-infiltrating immune cells, METASTASIS, G protein coupled receptors, CYTOLOGY, CELL differentiation
Abstract

Tumorigenesis is a multistep process, during which cells acquire a series of mutations that lead to unrestrained cell growth and proliferation, inhibition of cell differentiation, and evasion of cell death. Growing tumors stimulate angiogenesis, providing them with nutrients and oxygen. Ultimately, tumor cells invade the surrounding tissue and metastasize; a process responsible for about 90% of cancer-related deaths. Adhesion G protein-coupled receptors (aGPCRs) modulate the cellular processes closely related to tumor cell biology, such as adhesion and detachment, migration, polarity, and guidance. Soon after first being described, individual human aGPCRs were found to be involved in tumorigenesis. Twenty-five years ago, CD97/ADGRE5 was discovered to be induced in one of the most severe tumors, dedifferentiated anaplastic thyroid carcinoma. After decades of research, the time has come to review our knowledge of the presence and function of CD97 in cancer. In summary, CD97 is obviously induced or altered in many tumor entities; this has been shown consistently in nearly one hundred published studies. However, its high expression at circulating and tumor-infiltrating immune cells renders the systemic targeting of CD97 in tumors difficult. [ABSTRACT FROM AUTHOR]

Published
2022
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19. Additional file 7: of Loss of Msh2 and a single-radiation hit induce common, genome-wide, and persistent epigenetic changes in the intestine

Author

Herberg, Maria, Siebert, Susann, Quaas, Marianne, Thalheim, Torsten, Rother, Karen, Hussong, Michelle, AltmĂźller, Janine, Kerner, Christiane, Joerg Galle, Schweiger, Michal, and Aust, Gabriela

Abstract

Comparison of epigenetic states in intestinal tissue and isolated intestinal cells [22]. (DOCX 515Â kb)

Published
2019
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20. Additional file 5: of Loss of Msh2 and a single-radiation hit induce common, genome-wide, and persistent epigenetic changes in the intestine

Author

Herberg, Maria, Siebert, Susann, Quaas, Marianne, Thalheim, Torsten, Rother, Karen, Hussong, Michelle, AltmĂźller, Janine, Kerner, Christiane, Joerg Galle, Schweiger, Michal, and Aust, Gabriela

Abstract

Results of the SOM analysis of the epigenetic profiles. SOM portraits and additional information about affected gene sets. (DOCX 389Â kb)

Published
2019
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21. Additional file 8: of Loss of Msh2 and a single-radiation hit induce common, genome-wide, and persistent epigenetic changes in the intestine

Author

Herberg, Maria, Siebert, Susann, Quaas, Marianne, Thalheim, Torsten, Rother, Karen, Hussong, Michelle, AltmĂźller, Janine, Kerner, Christiane, Joerg Galle, Schweiger, Michal, and Aust, Gabriela

Abstract

Molecular characterization of Set1 and Set2 genes in isolated intestinal cells. Published MBD- and RNA-seq data on Set1 and Set2 genes [22]. (DOCX 73Â kb)

Published
2019
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22. Additional file 9: of Loss of Msh2 and a single-radiation hit induce common, genome-wide, and persistent epigenetic changes in the intestine

Author

Herberg, Maria, Siebert, Susann, Quaas, Marianne, Thalheim, Torsten, Rother, Karen, Hussong, Michelle, AltmĂźller, Janine, Kerner, Christiane, Joerg Galle, Schweiger, Michal, and Aust, Gabriela

Abstract

Set1 and Set2 genes in mouse and human intestinal tissue. Comparison of Set1 and Set2 genes in mouse and human tissue [3]. (DOCX 888Â kb)

Published
2019
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25. Indirect p53-dependent transcriptional repression of Survivin, CDC25C, and PLK1 genes requires the cyclin-dependent kinase inhibitor p21/CDKN1A and CDE/CHR promoter sites binding the DREAM complex

Author

Fischer, Martin, Quaas, Marianne, Nickel, Annina, and Engeland, Kurt

Subjects
p53, Cyclin-Dependent Kinase Inhibitor p21, Chromatin Immunoprecipitation, Survivin, Molecular Sequence Data, Down-Regulation, Cell Cycle Proteins, E2F4 Transcription Factor, Protein Serine-Threonine Kinases, Transfection, Gene Expression Regulation, Enzymologic, Inhibitor of Apoptosis Proteins, Proto-Oncogene Proteins, Humans, cdc25 Phosphatases, Promoter Regions, Genetic, Conserved Sequence, p53-p21-DREAM-CDE/CHR pathway, Binding Sites, Base Sequence, Retinoblastoma-Like Protein p130, CDE-CHR, DREAM, HCT116 Cells, CDKN1A, Gene Expression Regulation, Neoplastic, Multiprotein Complexes, Mutation, Trans-Activators, Tumor Suppressor Protein p53, Colorectal Neoplasms, Priority Research Paper
Abstract

The transcription factor p53 is central to cell cycle control by downregulation of cell cycle-promoting genes upon cell stress such as DNA damage. Survivin (BIRC5), CDC25C, and PLK1 encode important cell cycle regulators that are repressed following p53 activation. Here, we provide evidence that p53-dependent repression of these genes requires activation of p21 (CDKN1A, WAF1, CIP1). Chromatin immunoprecipitation (ChIP) data indicate that promoter binding of B-MYB switches to binding of E2F4 and p130 resulting in a replacement of the MMB (Myb-MuvB) by the DREAM complex. We demonstrate that this replacement depends on p21. Furthermore, transcriptional repression by p53 requires intact DREAM binding sites in the target promoters. The CDE and CHR cell cycle promoter elements are the sites for DREAM binding. These elements as well as the p53 response of Survivin, CDC25C, and PLK1 are evolutionarily conserved. No binding of p53 to these genes is detected by ChIP and mutation of proposed p53 binding sites does not alter the p53 response. Thus, a mechanism for direct p53-dependent transcriptional repression is not supported by the data. In contrast, repression by DREAM is consistent with most previous findings and unifies models based on p21-, E2F4-, p130-, and CDE/CHR-dependent repression by p53. In conclusion, the presented data suggest that the p53-p21-DREAM-CDE/CHR pathway regulates p53-dependent repression of Survivin, CDC25C, and PLK1.

Published
2015

26. p53 and cell cycle dependent transcription of kinesin family member 23 (KIF23) is controlled via a CHR promoter element bound by DREAM and MMB complexes

Author

Fischer, Martin, Grundke, Inga, Sohr, Sindy, Quaas, Marianne, Knörck, Arne, Gumhold, Catalina, and Rother, Karen

Subjects
CHR, p53, KIF23 repression, tumor suppressor, Zellzyklus, Kinesin, Repression, DREAM/MMB complex, KIF23, Tumorsuppressor-Gen, DREAM/MMB-Komplex, cell cycle, ddc:500, ddc:620, %22">Repression , Protein p53
Abstract

The microtubule-dependent molecular motor KIF23 (Kinesin family member 23) is one of two components of the centralspindlin complex assembled during late stages of mitosis. Formation of this complex is known as an essential step for cytokinesis. Here, we identified KIF23 as a new transcriptional target gene of the tumor suppressor protein p53. We showed that p53 reduces expression of KIF23 on the mRNA as well as the protein level in different cell types. Promoter reporter assays revealed that this repression results from downregulation of KIF23 promoter activity. CDK inhibitor p21WAF1/CIP1 was shown to be necessary to mediate p53-dependent repression. Furthermore, we identified the highly conserved cell cycle genes homology region (CHR) in the KIF23 promoter to be strictly required for p53-dependent repression as well as for cell cycle-dependent expression of KIF23. Cell cycle- and p53-dependent regulation of KIF23 appeared to be controlled by differential binding of DREAM and MMB complexes to the CHR element. With this study, we describe a new mechanism for transcriptional regulation of KIF23. Considering the strongly supporting function of KIF23 in cytokinesis, its p53-dependent repression may contribute to the prevention of uncontrolled cell growth.

Published
2013
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27. Cyclin F suppresses B-Myb activity to promote cell cycle checkpoint control

Author

Klein, Ditte Kjærsgaard, Hoffmann, Saskia, Ahlskog, Johanna K, O'Hanlon, Karen, Quaas, Marianne, Larsen, Brian D, Rolland, Baptiste, Rösner, Heike I, Walter, David, Kousholt, Arne Nedergaard, Menzel, Tobias, Lees, Michael, Johansen, Jens Vilstrup, Rappsilber, Juri, Engeland, Kurt, Sørensen, Claus Storgaard, Klein, Ditte Kjærsgaard, Hoffmann, Saskia, Ahlskog, Johanna K, O'Hanlon, Karen, Quaas, Marianne, Larsen, Brian D, Rolland, Baptiste, Rösner, Heike I, Walter, David, Kousholt, Arne Nedergaard, Menzel, Tobias, Lees, Michael, Johansen, Jens Vilstrup, Rappsilber, Juri, Engeland, Kurt, and Sørensen, Claus Storgaard

Abstract

Cells respond to DNA damage by activating cell cycle checkpoints to delay proliferation and facilitate DNA repair. Here, to uncover new checkpoint regulators, we perform RNA interference screening targeting genes involved in ubiquitylation processes. We show that the F-box protein cyclin F plays an important role in checkpoint control following ionizing radiation. Cyclin F-depleted cells initiate checkpoint signalling after ionizing radiation, but fail to maintain G2 phase arrest and progress into mitosis prematurely. Importantly, cyclin F suppresses the B-Myb-driven transcriptional programme that promotes accumulation of crucial mitosis-promoting proteins. Cyclin F interacts with B-Myb via the cyclin box domain. This interaction is important to suppress cyclin A-mediated phosphorylation of B-Myb, a key step in B-Myb activation. In summary, we uncover a regulatory mechanism linking the F-box protein cyclin F with suppression of the B-Myb/cyclin A pathway to ensure a DNA damage-induced checkpoint response in G2.

Published
2015

30. Cyclin F suppresses B-Myb activity to promote cell cycle checkpoint control

Author

Klein, Ditte Kjærsgaard, primary, Hoffmann, Saskia, additional, Ahlskog, Johanna K., additional, O’Hanlon, Karen, additional, Quaas, Marianne, additional, Larsen, Brian D., additional, Rolland, Baptiste, additional, Rösner, Heike I., additional, Walter, David, additional, Kousholt, Arne Nedergaard, additional, Menzel, Tobias, additional, Lees, Michael, additional, Johansen, Jens Vilstrup, additional, Rappsilber, Juri, additional, Engeland, Kurt, additional, and Sørensen, Claus Storgaard, additional

Published
2015
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37. p53 and Cell Cycle Dependent Transcription of kinesin family member 23 (KIF23) Is Controlled Via a CHR Promoter Element Bound by DREAM and MMB Complexes

Author

Fischer, Martin, Grundke, Inga, Sohr, Sindy, Quaas, Marianne, Hoffmann, Saskia, Knörck, Arne, Gumhold, Catalina, and Rother, Karen

Subjects
P53 protein, CELL cycle, GENETIC transcription, KINESIN, PROMOTERS (Genetics), MOLECULAR motor proteins, DNA, CYTOKINESIS
Abstract

The microtubule-dependent molecular motor KIF23 (Kinesin family member 23) is one of two components of the centralspindlin complex assembled during late stages of mitosis. Formation of this complex is known as an essential step for cytokinesis. Here, we identified KIF23 as a new transcriptional target gene of the tumor suppressor protein p53. We showed that p53 reduces expression of KIF23 on the mRNA as well as the protein level in different cell types. Promoter reporter assays revealed that this repression results from downregulation of KIF23 promoter activity. CDK inhibitor p21WAF1/CIP1 was shown to be necessary to mediate p53-dependent repression. Furthermore, we identified the highly conserved cell cycle genes homology region (CHR) in the KIF23 promoter to be strictly required for p53-dependent repression as well as for cell cycle-dependent expression of KIF23. Cell cycle- and p53-dependent regulation of KIF23 appeared to be controlled by differential binding of DREAM and MMB complexes to the CHR element. With this study, we describe a new mechanism for transcriptional regulation of KIF23. Considering the strongly supporting function of KIF23 in cytokinesis, its p53-dependent repression may contribute to the prevention of uncontrolled cell growth. [ABSTRACT FROM AUTHOR]

Published
2013
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39. The Forkhead Transcription Factor FOXM1 Controls Cell Cycle-Dependent Gene Expression through an Atypical Chromatin Binding Mechanism.

Author

Xi Chen, Müller, Gerd A., Quaas, Marianne, Fischer, Martin, Han, Namshik, Stutchbury, Benjamin, Sharrocks, Andrew D., and Engeland, Kurt

Subjects
TRANSCRIPTION factors, DNA-binding proteins, CELL cycle regulation, MOLECULAR structure of chromatin, BINDING sites, GENE expression, HUMAN genome
Abstract

There are nearly 50 forkhead (FOX) transcription factors encoded in the human genome and, due to sharing a common DNA binding domain, they are all thought to bind to similar DNA sequences. I t is therefore unclear how these transcription factors are targeted to specific chromatin regions to elicit specific biological effects. Here, we used chromatin immunoprecipitation followed by sequencing (ChIP-seq) to investigate the genome-wide chromatin binding mechanisms used by the forkhead transcription factor FOXM1. In keeping with its previous association with cell cycle control, we demonstrate that FOXM1 binds and regulates a group of genes which are mainly involved in controlling late cell cycle events in the G2 and M phases. However, rather than being recruited through canonical RYAAAYA forkhead binding motifs, FOXM1 binding is directed via CHR (cell cycle genes homology region) elements. FOXM1 binds these elements through protein-protein interactions with the MMB transcriptional activator complex. Thus, we have uncovered a novel and unexpected mode of chromatin binding of a FOX transcription factor that allows it to specifically control cell cycle-dependent gene expression. [ABSTRACT FROM AUTHOR]

Published
2013
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