Your search keyword '"Diana L. Bordin"' showing total 8 results

1. Rapid genome editing by CRISPR-Cas9-POLD3 fusion

Author

Mamia K, Li Z, Cieslar-Pobuda A, Soppa I, Salla Keskitalo, Diana L. Bordin, Kornel Labun, Jussi Taipale, Eivind Valen, Staerk J, Bernhard Schmierer, Leonardo A. Meza-Zepeda, Tölö E, Hu X, Emma Haapaniemi, Szymanska M, Markku Varjosalo, Suzanne Lorenz, and Ganna Reint

Subjects

0303 health sciences, DNA repair, Cas9, Locus (genetics), Computational biology, Biology, DNA sequencing, 03 medical and health sciences, 0302 clinical medicine, Genome editing, DNA Repair Protein, CRISPR, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

Precision CRISPR gene editing relies on the cellular homology-directed DNA repair (HDR) to introduce custom DNA sequences to target sites. The HDR editing efficiency varies between cell types and genomic sites, and the sources of this variation are incompletely understood. Here, we have studied the effect of 450 DNA repair protein - Cas9 fusions on CRISPR genome editing outcomes. We find the majority of fusions to improve precision genome editing only modestly in a locus- and cell-type specific manner. We identify Cas9-POLD3 fusion that enhances editing by speeding up the initiation of DNA repair. We conclude that while DNA repair protein fusions to Cas9 can improve HDR CRISPR editing, most need to be optimized to the particular cell type and genomic site, highlighting the diversity of factors contributing to locus-specific genome editing outcomes.

Published

2021

2. Increased p53 signaling impairs neural differentiation in HUWE1-promoted intellectual disabilities

Author

Rossana Aprigliano, Magnar Bjørås, Kayla Mae Grooms, Charles E. Schwartz, Merdane Ezgi Aksu, Nicola P. Montaldo, Emil Alexov, Barbara van Loon, Stefano Bradamante, Diana L. Bordin, Kristin Rian, Nina-Beate Liabakk, Wei Wang, Sarah L. Fordyce Martin, Cindy Skinner, Gareth J. Sullivan, Yunhui Peng, Matthias Bosshard, and Boris Mihaljevic

Subjects

p53, HUWE1, Medicine (General), X-linked intellectual disability, Ubiquitin-Protein Ligases, General Biochemistry, Genetics and Molecular Biology, R5-920, Genes, X-Linked, Report, Intellectual Disability, medicine, Humans, Gene, biology, neurodevelopment, Tumor Suppressor Proteins, Disease mechanisms, Cell Differentiation, medicine.disease, Ubiquitin ligase, Key factors, E3 ubiquitin ligase, Mutation, biology.protein, Neural differentiation, Tumor Suppressor Protein p53, P53 signaling, Neuroscience

Abstract

Summary Essential E3 ubiquitin ligase HUWE1 (HECT, UBA, and WWE domain containing 1) regulates key factors, such as p53. Although mutations in HUWE1 cause heterogenous neurodevelopmental X-linked intellectual disabilities (XLIDs), the disease mechanisms common to these syndromes remain unknown. In this work, we identify p53 signaling as the central process altered in HUWE1-promoted XLID syndromes. By focusing on Juberg-Marsidi syndrome (JMS), one of the severest XLIDs, we show that increased p53 signaling results from p53 accumulation caused by HUWE1 p.G4310R destabilization. This further alters cell-cycle progression and proliferation in JMS cells. Modeling of JMS neurodevelopment reveals majorly impaired neural differentiation accompanied by increased p53 signaling. The neural differentiation defects can be successfully rescued by reducing p53 levels and restoring the expression of p53 target genes, in particular CDKN1A/p21. In summary, our findings suggest that increased p53 signaling underlies HUWE1-promoted syndromes and impairs XLID JMS neural differentiation., Graphical abstract, Highlights p53 signaling is hyperactivated in HUWE1-promoted intellectual disabilities Neural differentiation is impaired in Juberg-Marsidi syndrome with HUWE1 p.G4310R Juberg-Marsidi brain organoids have reduced size and aberrant cellular organization Restored p53 signaling rescues neural development in Juberg-Marsidi syndrome, Using transcriptome analysis, Aprigliano et al. identify increased p53 signaling as the most significantly deregulated process in HUWE1-promoted XLIDs. Modeling of a severe HUWE1-promoted XLID, Juberg-Marsidi syndrome, reveals impaired neural differentiation capacity, which is successfully rescued by p53 knockdown and restored expression of p53 target genes, such as CDKN1A/p21.

Published

2021

3. Increased p53 signaling impairs neural differentiation causing HUWE1-promoted intellectual disabilities

Author

Rossana Aprigliano, Stefano Bradamante, Boris Mihaljevic, Wei Wang, Sarah L. Fordyce Martin, Diana L. Bordin, Matthias Bosshard, Nicola P. Montaldo, Yunhui Peng, Emil Alexov, Cindy Skinner, Nina-Beate Liabakk, Magnar Bjørås, Charles E. Schwartz, and Barbara van Loon

Subjects

Microcephaly, Key factors, biology, Juberg Marsidi syndrome, Lymphoblast, biology.protein, medicine, Neural differentiation, P53 signaling, medicine.disease, Neuroscience, Ubiquitin ligase

Abstract

SUMMARYEssential E3 ubiquitin ligase HUWE1 (HECT, UBA and WWE domain containing 1) regulates key factors, as p53. Mutations in HUWE1 have been associated with neurodevelopmental X-linked intellectual disabilities (XLIDs), however the pathomechanism at the onset of heterogenous XLIDs remains unknown. In this work, we identify p53 signaling as the process hyperactivated in lymphoblastoid cells from patients with HUWE1-promoted XLIDs. The hiPSCs-based modeling of the severe HUWE1-promoted XLID, the Juberg Marsidi syndrome (JMS), reviled majorly impaired neural differentiation, accompanied by increased p53 signaling. The impaired differentiation results in loss of cortical patterning and overall undergrowth of XLID JMS patient-specific cerebral organoids, thus closely recapitulating key symptoms, as microcephaly. Importantly, the neurodevelopmental potential of JMS hiPSCs is successfully rescued by restoring p53 signaling, upon reduction of p53 levels. In summary, our findings indicate that increased p53 signaling leads to impaired neural differentiation and is the common cause of neurodevelopmental HUWE1-promoted XLIDs.

Published

2020

4. Alkyladenine DNA glycosylase associates with transcription elongation to coordinate DNA repair with gene expression

Author

Diana L. Bordin, Per Arne Aas, Marit Otterlei, Alessandro Brambilla, Nicolas Kunath, Magnar Bjørås, Antonia Furrer, Sarah L. Fordyce Martin, Stefano Bradamante, Pål Sætrom, Nicola P. Montaldo, Karine Øian Bjørås, Lene Christin Olsen, Barbara van Loon, Leona D. Samson, and Marcel Rösinger

Subjects

0301 basic medicine, Genome instability, Transcription Elongation, Genetic, DNA Repair, DNA repair, Science, General Physics and Astronomy, Gene Expression, RNA polymerase II, General Biochemistry, Genetics and Molecular Biology, Article, Genomic Instability, DNA Glycosylases, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, RNA polymerase, DNA-(Apurinic or Apyrimidinic Site) Lyase, Humans, lcsh:Science, Gene, Base excision repair, Multidisciplinary, biology, General Chemistry, DNA, DNA Methylation, Chromatin, Cell biology, 030104 developmental biology, HEK293 Cells, chemistry, Gene Expression Regulation, 030220 oncology & carcinogenesis, DNA methylation, biology.protein, lcsh:Q, RNA Polymerase II, Transcriptional Elongation Factors

Abstract

Base excision repair (BER) initiated by alkyladenine DNA glycosylase (AAG) is essential for removal of aberrantly methylated DNA bases. Genome instability and accumulation of aberrant bases accompany multiple diseases, including cancer and neurological disorders. While BER is well studied on naked DNA, it remains unclear how BER efficiently operates on chromatin. Here, we show that AAG binds to chromatin and forms complex with RNA polymerase (pol) II. This occurs through direct interaction with Elongator and results in transcriptional co-regulation. Importantly, at co-regulated genes, aberrantly methylated bases accumulate towards the 3′end in regions enriched for BER enzymes AAG and APE1, Elongator and active RNA pol II. Active transcription and functional Elongator are further crucial to ensure efficient BER, by promoting AAG and APE1 chromatin recruitment. Our findings provide insights into genome stability maintenance in actively transcribing chromatin and reveal roles of aberrantly methylated bases in regulation of gene expression., How genome stability is maintained at regions of active transcription is currently not entirely clear. Here, the authors reveal an association between base excision repair factors and transcription elongation to modulate DNA repair.

Published

2019

5. 'Alkyladenine DNA glycosylase associates with transcription elongation to coordinate DNA repair with gene expression'

Author

Stefano Bradamante, Pål Sætrom, Antonia Furrer, Barbara van Loon, Sarah L. Fordyce Martin, Leona D. Samson, Marcel Rösinger, Alessandro Brambilla, Nicola P. Montaldo, Magnar Bjørås, Diana L. Bordin, Karine Øian Bjørås, Lene Christin Olsen, Marit Otterlei, and Per Arne Aas

Subjects

Genome instability, chemistry.chemical_compound, biology, chemistry, DNA repair, RNA polymerase, Gene expression, biology.protein, RNA polymerase II, Base excision repair, Gene, Chromatin, Cell biology

Abstract

Base excision repair (BER) initiated by alkyladenine DNA glycosylase (AAG; aka MPG) is essential for removal of aberrantly methylated DNA bases. Genome instability and accumulation of aberrant bases accompany multiple diseases including cancer and neurological disorders. While BER is well studied on naked DNA, it remains unclear how BER efficiently operates on chromatin. Here we show that AAG binds to chromatin and forms complex with active RNA polymerase (pol) II. This occurs through direct interaction with Elongator and results in transcriptional co-regulation. Importantly, at co-regulated genes aberrantly methylated bases accumulate towards 3’end, in regions enriched for BER enzymes AAG and APE1, Elongator and active RNA pol II. Active transcription and functional Elongator are further crucial to ensure efficient BER, by promoting AAG and APE1 chromatin recruitment. Our findings provide novel insights to maintaining genome stability in actively transcribing chromatin, and reveal roles of aberrantly methylated bases in regulation of gene expression.

Published

2019

6. Cellular response to endogenous DNA damage: DNA base modifications in gene expression regulation

Author

Diana L. Bordin, Lisa Lirussi, and Hilde Nilsen

Subjects

Guanine, DNA Repair, DNA damage, DNA repair, Biology, Biochemistry, Chromatin remodeling, DNA Glycosylases, Epigenesis, Genetic, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Transcription (biology), Animals, Humans, Epigenetics, Molecular Biology, 030304 developmental biology, 0303 health sciences, DNA, Cell Biology, Base excision repair, Cell biology, Gene Expression Regulation, chemistry, DNA glycosylase, 030220 oncology & carcinogenesis, 5-Methylcytosine, DNA Damage

Abstract

The integrity of the genetic information is continuously challenged by numerous genotoxic insults, most frequently in the form of oxidation, alkylation or deamination of the bases that result in DNA damage. These damages compromise the fidelity of the replication, and interfere with the progression and function of the transcription machineries. The DNA damage response (DDR) comprises a series of strategies to deal with DNA damage, including transient transcriptional inhibition, activation of DNA repair pathways and chromatin remodeling. Coordinated control of transcription and DNA repair is required to safeguardi cellular functions and identities. Here, we address the cellular responses to endogenous DNA damage, with a particular focus on the role of DNA glycosylases and the Base Excision Repair (BER) pathway, in conjunction with the DDR factors, in responding to DNA damage during the transcription process. We will also discuss functions of newly identified epigenetic and regulatory marks, such as 5-hydroxymethylcytosine and its oxidative products and 8-oxoguanine, that were previously considered only as DNA damages. In light of these resultsthe classical perception of DNA damage as detrimental for cellular processes are changing. and a picture emerges whereDNA glycosylases act as dynamic regulators of transcription, placing them at the intersection of DNA repair and gene expression modulation.

Published

2021

7. The influence of micronutrients in cell culture: a reflection on viability and genomic stability

Author

Ana Lúcia Vargas Arigony, João Antonio Pêgas Henriques, Iuri Marques de Oliveira, Lothar Bergter, Daniel Prá, Miriana da Silva Machado, and Diana L. Bordin

Subjects

General Immunology and Microbiology, Cell Survival, lcsh:R, Cell Culture Techniques, lcsh:Medicine, General Medicine, Review Article, Biology, Micronutrient, General Biochemistry, Genetics and Molecular Biology, In vitro, Genomic Instability, Genomic Stability, Cell biology, Culture Media, Metabolic pathway, Nutrient, Animals, Humans, Viability assay, Micronutrients, Fetal bovine serum, Homeostasis

Abstract

Micronutrients, including minerals and vitamins, are indispensable to DNA metabolic pathways and thus are as important for life as macronutrients. Without the proper nutrients, genomic instability compromises homeostasis, leading to chronic diseases and certain types of cancer. Cell-culture media try to mimic thein vivoenvironment, providingin vitromodels used to infer cells' responses to different stimuli. This review summarizes and discusses studies of cell-culture supplementation with micronutrients that can increase cell viability and genomic stability, with a particular focus on previousin vitroexperiments. In these studies, the cell-culture media include certain vitamins and minerals at concentrations not equal to the physiological levels. In many common culture media, the sole source of micronutrients is fetal bovine serum (FBS), which contributes to only 5–10% of the media composition. Minimal attention has been dedicated to FBS composition, micronutrients in cell cultures as a whole, or the influence of micronutrients on the viability and genetics of cultured cells. Further studies better evaluating micronutrients' roles at a molecular level and influence on the genomic stability of cells are still needed.

Published

2013

8. DNA alkylation damage and autophagy induction

Author

João Antonio Pêgas Henriques, Alexandre E. Escargueil, Annette K. Larsen, Michelle de Souza Lima, Daniele G. Soares, Diana L. Bordin, Jenifer Saffi, Guido Lenz, Paul Mésange, and Lisiane B. Meira

Subjects

Programmed cell death, Alkylating Agents, Alkylation, DNA repair, DNA damage, Health, Toxicology and Mutagenesis, Autophagy, Context (language use), Apoptosis, Biology, Cell cycle, Cell biology, DNA Alkylation, Cancer cell, Genetics, Animals, Humans, Antineoplastic Agents, Alkylating, DNA Damage

Abstract

Many alkylating agents are used as chemotherapeutic drugs and have a long history of clinical application. These agents inflict a wide range of DNA damage resulting in a complex cellular response. After DNA damage, cells trigger a series of signaling cascades promoting cellular survival and cell cycle blockage which enables time for DNA repair to occur. More recently, induction of autophagy has been observed in cancer cells after treatment with different DNA-targeted anticancer drugs, including alkylating agents. Several studies have demonstrated that induction of autophagy after DNA damage delays apoptotic cell death and may therefore lead to chemoresistance, which is the limiting factor for successful chemotherapy. On the other hand, depending on the extent of damage and the cellular context, the induction of autophagy may also contribute to cell death. Given these conflicting results, many studies have been conducted to better define the role of autophagy in cancer cells in response to chemotherapy. In this review, we describe the main alkylating agents used in clinical oncology as well as the cellular response they evoke with emphasis on autophagy.

Published

2012