Your search keyword '"Farrar, Dawn"' showing total 25 results

1. Investigation into the role of CTCF in the protection of breast cancer cells from apoptosis : identification of the different isoforms of CTCF and their possible function in apoptosis

Author

Farrar, Dawn

Subjects

616.99449042

Published

2005

2. Supplementary Data from Decreased Poly(ADP-Ribosyl)ation of CTCF, a Transcription Factor, Is Associated with Breast Cancer Phenotype and Cell Proliferation

Author

Docquier, France, primary, Kita, Georgia-Xanthi, primary, Farrar, Dawn, primary, Jat, Parmjit, primary, O'Hare, Michael, primary, Chernukhin, Igor, primary, Gretton, Svetlana, primary, Mandal, Adhip, primary, Alldridge, Louise, primary, and Klenova, Elena, primary

Published

2023

3. Supplementary Figure B from Heightened Expression of CTCF in Breast Cancer Cells Is Associated with Resistance to Apoptosis

Author

Docquier, France, primary, Farrar, Dawn, primary, D'Arcy, Vivien, primary, Chernukhin, Igor, primary, Robinson, Abigail F., primary, Loukinov, Dmitry, primary, Vatolin, Sergei, primary, Pack, Svetlana, primary, Mackay, Alan, primary, Harris, Robert A., primary, Dorricott, Heather, primary, O'Hare, Michael J., primary, Lobanenkov, Victor, primary, and Klenova, Elena, primary

Published

2023

4. Supplementary Figure A from Heightened Expression of CTCF in Breast Cancer Cells Is Associated with Resistance to Apoptosis

Author

Docquier, France, primary, Farrar, Dawn, primary, D'Arcy, Vivien, primary, Chernukhin, Igor, primary, Robinson, Abigail F., primary, Loukinov, Dmitry, primary, Vatolin, Sergei, primary, Pack, Svetlana, primary, Mackay, Alan, primary, Harris, Robert A., primary, Dorricott, Heather, primary, O'Hare, Michael J., primary, Lobanenkov, Victor, primary, and Klenova, Elena, primary

Published

2023

5. Supplementary Tables 1-3 from Heightened Expression of CTCF in Breast Cancer Cells Is Associated with Resistance to Apoptosis

Author

Docquier, France, primary, Farrar, Dawn, primary, D'Arcy, Vivien, primary, Chernukhin, Igor, primary, Robinson, Abigail F., primary, Loukinov, Dmitry, primary, Vatolin, Sergei, primary, Pack, Svetlana, primary, Mackay, Alan, primary, Harris, Robert A., primary, Dorricott, Heather, primary, O'Hare, Michael J., primary, Lobanenkov, Victor, primary, and Klenova, Elena, primary

Published

2023

6. A Novel Mechanism for CTCF in the Epigenetic Regulation of Bax in Breast Cancer Cells

Author

Méndez-Catalá, Claudia Fabiola, Gretton, Svetlana, Vostrov, Alexander, Pugacheva, Elena, Farrar, Dawn, Ito, Yoko, Docquier, France, Kita, Georgia-Xanthi, Murrell, Adele, Lobanenkov, Victor, and Klenova, Elena

Published

2013

7. The UK Impact Transplant Trials Network: An Effective National Strategy to Accelerate the Delivery of Randomized Trials in Stem Cell Transplantation

Author

Craddock, Charles, Marks, David, Potter, Victoria, Ingram, Wendy A, Collings, Rebecca, Tholouli, Eleni, Protheroe, Rachel, Allen, Hugh, Ross, Alex, Farrar, Dawn, Siddique, Shamyla, Bishop, Rebecca, and Chakraverty, Ronjon

Published

2023

8. Expression of the cancer-testis antigen BORIS correlates with prostate cancer

Author

Cheema, Zubair, Hari-Gupta, Yukti, Kita, Georgia-Xanthi, Farrar, Dawn, Seddon, Ian, Corr, John, and Klenova, Elena

Published

2014

9. Generation of Poly(ADP-ribosyl)ation Deficient Mutants of the Transcription Factor, CTCF

Author

Farrar, Dawn, primary, Chernukhin, Igor, additional, and Klenova, Elena, additional

Published

2011

10. Activation of the Androgen Receptor gene by BORIS/CTCFL in prostate cancer cells

Author

Hari-Gupta, Yukti, primary, Kita, Georgia-Xanthi, additional, Farrar, Dawn, additional, and Klenova, Elena, additional

Published

2017

11. ADP-ribose polymer depletion leads to nuclear Ctcf re-localization and chromatin rearrangement(1)

Author

Guastafierro, Tiziana, Catizone, Angela, Calabrese, Roberta, Zampieri, Michele, Martella, Oliviano, Bacalini, Maria Giulia, Reale, Anna, Di Girolamo, Maria, Miccheli, Margherita, Farrar, Dawn, Klenova, Elena, Ciccarone, Fabio, Caiafa, Paola, Department of Cellular Biotechnologies and Haematology, Università degli Studi di Roma 'La Sapienza' = Sapienza University [Rome]-Institut Pasteur, Fondation Cenci Bolognetti - Istituto Pasteur Italia, Fondazione Cenci Bolognetti, Réseau International des Instituts Pasteur (RIIP)-Réseau International des Instituts Pasteur (RIIP), Department of Anatomy, Histology, Forensic Medicine and Orthopedics, Università degli Studi di Roma 'La Sapienza' = Sapienza University [Rome], Consorzio Mario Negri Sud, Chieti - Italy, Department of Biological Sciences (DBS), Central Campus, University of Essex, and This work was supported by the International Fondo per gli Investimenti della Ricercadi Base 2006 [grant number RBIN06E9Z8_003] and by the Ministero dell’Istruzione,dell’Universita e della Ricerca (Progetti di Ricerca di Interesse Nazionale 2008, P.C.), Italy.

Subjects

MESH: Cell Nucleus, CCCTC-Binding Factor, Glycoside Hydrolases, Recombinant Fusion Proteins, Active Transport, Cell Nucleus, Poly (ADP-Ribose) Polymerase-1, MESH: Active Transport, Cell Nucleus, Poly(ADP-ribose) Polymerase Inhibitors, Cell Line, MESH: Mutant Proteins, Mice, MESH: DNA Methylation, MESH: Glycoside Hydrolases, MESH: Recombinant Fusion Proteins, Animals, MESH: Animals, [SDV.BBM]Life Sciences [q-bio]/Biochemistry, Molecular Biology, MESH: Mice, MESH: Adenosine Diphosphate Ribose, Cell Nucleus, Adenosine Diphosphate Ribose, MESH: Poly(ADP-ribose) Polymerases, MESH: Chromatin Assembly and Disassembly, MESH: Lamins, DNA Methylation, Chromatin Assembly and Disassembly, MESH: Gene Knockdown Techniques, MESH: Amino Acid Substitution, Lamins, MESH: Cell Line, Repressor Proteins, MESH: Mutagenesis, Site-Directed, Amino Acid Substitution, MESH: Repressor Proteins, Gene Knockdown Techniques, Mutagenesis, Site-Directed, Mutant Proteins, Poly(ADP-ribose) Polymerases

Abstract

International audience; Ctcf (CCCTC-binding factor) directly induces Parp [poly(ADP-ribose) polymerase] 1 activity and its PARylation [poly(ADPribosyl)ation] in the absence of DNA damage. Ctcf, in turn, is a substrate for this post-synthetic modification and as such it is covalently and non-covalently modified by PARs (ADP-ribose polymers). Moreover, PARylation is able to protect certain DNA regions bound by Ctcf from DNA methylation. We recently reported that de novo methylation of Ctcf target sequences due to overexpression of Parg [poly(ADP-ribose)glycohydrolase] induces loss of Ctcf binding. Considering this, we investigate to what extent PARP activity is able to affect nuclear distribution of Ctcf in the present study. Notably, Ctcf lost its diffuse nuclear localization following PAR (ADP-ribose polymer) depletion and accumulated at the periphery of the nucleus where it was linked with nuclear pore complex proteins remaining external to the perinuclear Lamin B1 ring. We demonstrated that PAR depletion-dependent perinuclear localization of Ctcf was due to its blockage from entering the nucleus. Besides Ctcf nuclear delocalization, the outcome of PAR depletion led to changes in chromatin architecture. Immunofluorescence analyses indicated DNA redistribution, a generalized genomic hypermethylation and an increase of inactive compared with active chromatin marks in Parg-overexpressing or Ctcf-silenced cells. Together these results underline the importance of the cross-talk between Parp1 and Ctcf in the maintenance of nuclear organization.

Published

2012

12. Targeting of CTCF to the nucleolus inhibits nucleolar transcription through a poly(ADP-ribosyl)ation-dependent mechanism

Author

Torrano Moya, Verónica, Navascués Ortega, Joaquín, Docquier, France, Zhang, Ru, Burke, Les J., Chernukhin, Igor, Farrar, Dawn, León Serrano, Javier, Berciano Blanco, María Teresa, Renkawitz, Rainer, Klenova, Elena, Lafarga Coscojuela, Miguel Ángel, Delgado Villar, María Dolores, and Universidad de Cantabria

Subjects

Apoptosis induction, Neurons, Nucleolus, Myeloid differentiation, CTCF, PARP

Abstract

Multiple functions have been reported for the transcription factor and candidate tumour suppressor, CTCF. Among others, they include regulation of cell growth, differentiation and apoptosis, enhancer-blocking activity and control of imprinted genes. CTCF is usually localized in the nucleus and its subcellular distribution during the cell cycle is dynamic; CTCF was found associated with mitotic chromosomes and the midbody, suggesting different roles for CTCF at different stages of the cell cycle. Here we report the nucleolar localization of CTCF in several experimental model systems. Translocation of CTCF from nucleoplasm to the nucleolus was observed after differentiation of K562 myeloid cells and induction of apoptosis in MCF7 breast cancer cells. CTCF was also found in the nucleoli in terminally differentiated rat trigeminal ganglion neurons. Thus our data show that nucleolar localization of CTCF is associated with growth arrest. Interestingly, the 180 kDa poly(ADP-ribosyl)ated isoform of CTCF was predominantly found in the nucleoli fractions. By transfecting different CTCF deletion constructs into cell lines of different origin we demonstrate that the central zinc-finger domain of CTCF is the region responsible for nucleolar targeting. Analysis of subnucleolar localization of CTCF revealed that it is distributed homogeneously in both dense fibrillar and granular components of the nucleolus, but is not associated with fibrillar centres. RNA polymerase I transcription and protein synthesis were required to sustain nucleolar localization of CTCF. Notably, the labelling of active transcription sites by in situ run-on assays demonstrated that CTCF inhibits nucleolar transcription through a poly(ADP-ribosyl)ation-dependent mechanism.

Published

2006

13. Expression of the cancer-testis antigen BORIS correlates with prostate cancer

Author

Cheema, Zubair, primary, Hari-Gupta, Yukti, additional, Kita, Georgia-Xanthi, additional, Farrar, Dawn, additional, Seddon, Ian, additional, Corr, John, additional, and Klenova, Elena, additional

Published

2013

14. ADP-ribose polymer depletion leads to nuclear Ctcf re-localization and chromatin rearrangement

Author

Guastafierro, Tiziana, primary, Catizone, Angela, additional, Calabrese, Roberta, additional, Zampieri, Michele, additional, Martella, Oliviano, additional, Bacalini, Maria Giulia, additional, Reale, Anna, additional, Di Girolamo, Maria, additional, Miccheli, Margherita, additional, Farrar, Dawn, additional, Klenova, Elena, additional, Ciccarone, Fabio, additional, and Caiafa, Paola, additional

Published

2013

15. CTCF Interacts with and Recruits the Largest Subunit of RNA Polymerase II to CTCF Target Sites Genome-Wide

Author

Chernukhin, Igor, Shamsuddin, Shaharum, Kang, Sung Yun, Bergström, Rosita, Kwon, Yoo-Wook, Yu, WenQiang, Whitehead, Joanne, Mukhopadhyay, Rituparna, Docquier, France, Farrar, Dawn, Morrison, Ian, Vigneron, Marc, Wu, Shwu-Yuan, Chiang, Sheng-Ming, Loukinov, Dimitri, Ohlsson, Rolf, Klenova, Elena, Chernukhin, Igor, Shamsuddin, Shaharum, Kang, Sung Yun, Bergström, Rosita, Kwon, Yoo-Wook, Yu, WenQiang, Whitehead, Joanne, Mukhopadhyay, Rituparna, Docquier, France, Farrar, Dawn, Morrison, Ian, Vigneron, Marc, Wu, Shwu-Yuan, Chiang, Sheng-Ming, Loukinov, Dimitri, Ohlsson, Rolf, and Klenova, Elena

Abstract

CTCF is a transcription factor with highly versatile functions ranging from gene activation and repression to the regulation of insulator function and imprinting. Although many of these functions rely on CTCF-DNA interactions, it is an emerging realization that CTCF-dependent molecular processes involve CTCF interactions with other proteins. In this study, we report the association of a subpopulation of CTCF with the RNA polymerase II (Pol II) protein complex. We identified the largest subunit of Pol II (LS Pol II) as a protein significantly colocalizing with CTCF in the nucleus and specifically interacting with CTCF in vivo and in vitro. The role of CTCF as a link between DNA and LS Pol II has been reinforced by the observation that the association of LS Pol II with CTCF target sites in vivo depends on intact CTCF binding sequences. "Serial" chromatin immunoprecipitation (ChIP) analysis revealed that both CTCF and LS Pol II were present at the β-globin insulator in proliferating HD3 cells but not in differentiated globin synthesizing HD3 cells. Further, a single wild-type CTCF target site (N-Myc-CTCF), but not the mutant site deficient for CTCF binding, was sufficient to activate the transcription from the promoterless reporter gene in stably transfected cells. Finally, a ChIP-on-ChIP hybridization assay using microarrays of a library of CTCF target sites revealed that many intergenic CTCF target sequences interacted with both CTCF and LS Pol II. We discuss the possible implications of our observations with respect to plausible mechanisms of transcriptional regulation via a CTCF-mediated direct link of LS Pol II to the DNA.

Published

2007

16. Poly(ADP-ribosyl)ation regulates CTCF-dependent chromatin insulation

Author

Yu, Wenqiang, Ginjala, Vasudeva, Pant, Vinod, Chernukhin, Igor, Whitehead, Joanne, Docquier, France, Farrar, Dawn, Tavoosidana, Gholamreza, Mukhopadhyay, Rituparna, Kanduri, Chandrasekhar, Oshimura, Mitsuo, Feinberg, Andrew P, Lobanenkov, Victor, Klenova, Elena, Rolf Ohlsson, Rolf, Yu, Wenqiang, Ginjala, Vasudeva, Pant, Vinod, Chernukhin, Igor, Whitehead, Joanne, Docquier, France, Farrar, Dawn, Tavoosidana, Gholamreza, Mukhopadhyay, Rituparna, Kanduri, Chandrasekhar, Oshimura, Mitsuo, Feinberg, Andrew P, Lobanenkov, Victor, Klenova, Elena, and Rolf Ohlsson, Rolf

Abstract

Chromatin insulators demarcate expression domains by blocking the cis effects of enhancers or silencers in a position-dependent manner1, 2. We show that the chromatin insulator protein CTCF carries a post-translational modification: poly(ADP-ribosyl)ation. Chromatin immunoprecipitation analysis showed that a poly(ADP-ribosyl)ation mark, which exclusively segregates with the maternal allele of the insulator domain in the H19 imprinting control region, requires the bases that are essential for interaction with CTCF3. Chromatin immunoprecipitation−on−chip analysis documented that the link between CTCF and poly(ADP-ribosyl)ation extended to more than 140 mouse CTCF target sites. An insulator trap assay showed that the insulator function of most of these CTCF target sites is sensitive to 3-aminobenzamide, an inhibitor of poly(ADP-ribose) polymerase activity. We suggest that poly(ADP-ribosyl)ation imparts chromatin insulator properties to CTCF at both imprinted and nonimprinted loci, which has implications for the regulation of expression domains and their demise in pathological lesions.

Published

2004

17. Mutational Analysis of the Poly(ADP-Ribosyl)ation Sites of the Transcription Factor CTCF Provides an Insight into the Mechanism of Its Regulation by Poly(ADP-Ribosyl)ation

Author

Farrar, Dawn, primary, Rai, Sushma, additional, Chernukhin, Igor, additional, Jagodic, Maja, additional, Ito, Yoko, additional, Yammine, Samer, additional, Ohlsson, Rolf, additional, Murrell, Adele, additional, and Klenova, Elena, additional

Published

2010

18. Decreased Poly(ADP-Ribosyl)ation of CTCF, a Transcription Factor, Is Associated with Breast Cancer Phenotype and Cell Proliferation

Author

Docquier, France, primary, Kita, Georgia-Xanthi, additional, Farrar, Dawn, additional, Jat, Parmjit, additional, O'Hare, Michael, additional, Chernukhin, Igor, additional, Gretton, Svetlana, additional, Mandal, Adhip, additional, Alldridge, Louise, additional, and Klenova, Elena, additional

Published

2009

19. CTCF Interacts with and Recruits the Largest Subunit of RNA Polymerase II to CTCF Target Sites Genome-Wide

Author

Chernukhin, Igor, primary, Shamsuddin, Shaharum, additional, Kang, Sung Yun, additional, Bergström, Rosita, additional, Kwon, Yoo-Wook, additional, Yu, WenQiang, additional, Whitehead, Joanne, additional, Mukhopadhyay, Rituparna, additional, Docquier, France, additional, Farrar, Dawn, additional, Morrison, Ian, additional, Vigneron, Marc, additional, Wu, Shwu-Yuan, additional, Chiang, Cheng-Ming, additional, Loukinov, Dmitri, additional, Lobanenkov, Victor, additional, Ohlsson, Rolf, additional, and Klenova, Elena, additional

Published

2007

20. The Potential of BORIS Detected in the Leukocytes of Breast Cancer Patients as an Early Marker of Tumorigenesis

Author

D'Arcy, Vivien, primary, Abdullaev, Ziedulla K., additional, Pore, Naresh, additional, Docquier, France, additional, Torrano, Verónica, additional, Chernukhin, Igor, additional, Smart, Melissa, additional, Farrar, Dawn, additional, Metodiev, Metodi, additional, Fernandez, Nelson, additional, Richard, Carlos, additional, Delgado, M. Dolores, additional, Lobanenkov, Victor, additional, and Klenova, Elena, additional

Published

2006

21. Targeting of CTCF to the nucleolus inhibits nucleolar transcription through a poly(ADP-ribosyl)ation-dependent mechanism

Author

Torrano, Verónica, primary, Navascués, Joaquín, additional, Docquier, France, additional, Zhang, Ru, additional, Burke, Les J., additional, Chernukhin, Igor, additional, Farrar, Dawn, additional, León, Javier, additional, Berciano, María T., additional, Renkawitz, Rainer, additional, Klenova, Elena, additional, Lafarga, Miguel, additional, and Delgado, M. Dolores, additional

Published

2006

22. Heightened Expression of CTCF in Breast Cancer Cells Is Associated with Resistance to Apoptosis

Author

Docquier, France, primary, Farrar, Dawn, additional, D'Arcy, Vivien, additional, Chernukhin, Igor, additional, Robinson, Abigail F., additional, Loukinov, Dmitry, additional, Vatolin, Sergei, additional, Pack, Svetlana, additional, Mackay, Alan, additional, Harris, Robert A., additional, Dorricott, Heather, additional, O'Hare, Michael J., additional, Lobanenkov, Victor, additional, and Klenova, Elena, additional

Published

2005

23. Poly(ADP-ribosyl)ation regulates CTCF-dependent chromatin insulation

Author

Yu, Wenqiang, primary, Ginjala, Vasudeva, additional, Pant, Vinod, additional, Chernukhin, Igor, additional, Whitehead, Joanne, additional, Docquier, France, additional, Farrar, Dawn, additional, Tavoosidana, Gholamreza, additional, Mukhopadhyay, Rituparna, additional, Kanduri, Chandrasekhar, additional, Oshimura, Mitsuo, additional, Feinberg, Andrew P, additional, Lobanenkov, Victor, additional, Klenova, Elena, additional, and Ohlsson, Rolf, additional

Published

2004

24. ADP-ribose polymer depletion leads to nuclear Ctcf re-localization and chromatin rearrangement

Author

Tiziana Guastafierro, Anna Reale, Oliviano Martella, Angela Catizone, Margherita Miccheli, Dawn Farrar, Fabio Ciccarone, Maria Di Girolamo, Michele Zampieri, Roberta Calabrese, Maria Giulia Bacalini, Paola Caiafa, Elena Klenova, Guastafierro, Tiziana, Catizone, Angela, Calabrese, Roberta, Zampieri, Michele, Martella, Oliviano, Bacalini, Maria Giulia, Reale, Anna, Di Girolamo, Maria, Miccheli, Margherita, Farrar, Dawn, Klenova, Elena, Ciccarone, Fabio, and Caiafa, Paola

Subjects

CCCTC-Binding Factor, Glycoside Hydrolase, Poly (ADP-Ribose) Polymerase-1, CCCTC-binding factor (Ctcf), chromatin structure, poly(ADP-ribose) glycohydrolase (Parg), poly(ADP-ribose) polymerase 1 (Parp1), poly(ADP-ribosyl) ation (PARylation), active transport, cell nucleus, adenosine diphosphate ribose, amino acid substitution, animals, CCCTC-binding factor, cell line, chromatin assembly and disassembly, DNA methylation, gene knockdown techniques, glycoside hydrolases, lamins, mice, mutagenesis, site-directed, mutant proteins, poly (ADP-ribose) polymerase-1, Poly(ADP-ribose) polymerase Inhibitors, poly(ADP-ribose) polymerases, recombinant fusion proteins, repressor proteins, Biochemistry, Poly(ADP-ribose) Polymerase Inhibitor, Mice, 0302 clinical medicine, PARP1, Mutant Protein, Cell Nucleu, Poly(ADP-ribose) Polymerase, 0303 health sciences, PARG, Poly(ADP-ribose) glycohydrolase (Parg), Active Transport, Cell Nucleu, Cell biology, Chromatin, medicine.anatomical_structure, 030220 oncology & carcinogenesis, Poly ADP ribose polymerase, Biology, Chromatin structure, Cell Line, 03 medical and health sciences, Poly(ADP-ribose) polymerase 1 (Parp1), medicine, Settore BIO/10, Molecular Biology, 030304 developmental biology, Adenosine Diphosphate Ribose, Animal, Poly(ADP-ribosyl) ation (PARylation), Cell Biology, DNA Methylation, Repressor Protein, Chromatin Assembly and Disassembly, Molecular biology, Cell nucleus, Amino Acid Substitution, CTCF, Gene Knockdown Technique, Mutagenesis, Site-Directed, Lamin, Recombinant Fusion Protein

Abstract

Ctcf (CCCTC-binding factor) directly induces Parp [poly(ADPribose) polymerase] 1 activity and its PARylation [poly(ADPribosyl) ation] in the absence of DNA damage. Ctcf, in turn, is a substrate for this post-synthetic modification and as such it is covalently and non-covalently modified by PARs (ADP-ribose polymers). Moreover, PARylation is able to protect certain DNA regions bound by Ctcf from DNA methylation. We recently reported that de novo methylation of Ctcf target sequences due to overexpression of Parg [poly(ADP-ribose)glycohydrolase] induces loss of Ctcf binding. Considering this, we investigate to what extent PARP activity is able to affect nuclear distribution of Ctcf in the present study. Notably, Ctcf lost its diffuse nuclear localization following PAR (ADP-ribose polymer) depletion and accumulated at the periphery of the nucleus where it was linked with nuclear pore complex proteins remaining external to the perinuclear Lamin B1 ring. We demonstrated that PAR depletion-dependent perinuclear localization of Ctcf was due to its blockage from entering the nucleus. Besides Ctcf nuclear delocalization, the outcome of PAR depletion led to changes in chromatin architecture. Immunofluorescence analyses indicated DNA redistribution, a generalized genomic hypermethylation and an increase of inactive compared with active chromatin marks in Parg-overexpressing or Ctcf-silenced cells. Together these results underline the importance of the cross-talk between Parp1 and Ctcf in the maintenance of nuclear organization. © The Authors Journal compilation © 2013 Biochemical Society.

Published

2013

25. Generation of poly(ADP-ribosyl)ation deficient mutants of the transcription factor, CTCF.

Author

Farrar D, Chernukhin I, and Klenova E

Subjects

Animals, Blotting, Western, CCCTC-Binding Factor, Cell Line, Chromatin Immunoprecipitation, Humans, Mice, Mutagenesis, Site-Directed, Polymerase Chain Reaction, Protein Binding, Rats, Repressor Proteins chemistry, Repressor Proteins genetics, Poly Adenosine Diphosphate Ribose metabolism, Repressor Proteins metabolism

Abstract

Generation of the mutated versions of proteins deficient for poly(ADP-ribosyl)ation (PARylation) is a major challenge because there is no clearly defined consensus site for PARylation. In this chapter, we describe possible strategies to produce such mutants, demonstrated by the example of CTCF, a transcription factor. To achieve this in our study, the protein domain modified by PARylation was mapped and the amino acids, which can be potentially PARylated, selected. Mutations of such individual amino acids as either single or combinatorial mutations were introduced by site-directed mutagenesis, using mutagenic primers and the wild-type sequences as a template. Mutants were validated by DNA sequencing and assessed for the presence of the PARylation mark. The latter was achieved by ectopic expression of mutated proteins in cells, followed by immunoprecipitation with the polyclonal anti-PAR antibody and Western analysis with a protein-specific antibody. The PARylation-deficient CTCF mutant was identified and compared with the wild-type protein. Based on several general characteristics (nuclear distribution/localisation, stability and levels of expression in the cell), the PARylation-deficient mutant was comparable with the wild-type CTCF.

Published

2011