Novel functions of the oncofetal HMGA2 protein in genome stability

The non-histone chromatin factor HMGA2 (High Mobility Group AT-hook 2), which contains three AT-hook motifs as independent DNA binding domains, is normally expressed in ES cells and during embryonic/fetal development. In this study, I investigated its function in protecting the stalled replication f...

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Main Author: Yu, Haojie
Other Authors: Peter Droge
Format: Theses and Dissertations
Language:English
Published: 2014
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Online Access:http://hdl.handle.net/10356/55737
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Institution: Nanyang Technological University
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spelling sg-ntu-dr.10356-557372023-02-28T18:36:36Z Novel functions of the oncofetal HMGA2 protein in genome stability Yu, Haojie Peter Droge School of Biological Sciences DRNTU::Science::Biological sciences::Molecular biology The non-histone chromatin factor HMGA2 (High Mobility Group AT-hook 2), which contains three AT-hook motifs as independent DNA binding domains, is normally expressed in ES cells and during embryonic/fetal development. In this study, I investigated its function in protecting the stalled replication forks. I found that RPA32 (Replication Protein A 32 kDa subunit) co-localises with HMGA2 at on-going or Hydroxyurea (HU)-induced stalled replication forks. The similar results were observed that IdU pulse-labeled replication sites co-localise with HMGA2 signals in the absence and in the presence of HU. Moreover, HMGA2 protects against fork-associated DSBs (Double Strand Breaks) formation as well as degradation of nascent DNA strands after Hydroxyurea (HU)-induced fork stalling. This, in turn, facilitates fork restart, significantly suppresses chromosomal instabilities, and enhances cell viability. Strikingly, in a heterologous cell system Saccharomyces cerevisiae (S. cerevisiae), human HMGA2 alone partially complements the fork-stabilizing function of ATR/Mec1 by reducing the occurrence of pathological fork structures and their subsequent endonucleolytic cleavage into DSBs. Moreover, wild type HMGA2 rather than the DNA-binding motif AT-hook mutants is sufficient to fully complement the Escherichia coli RecA protein in its replication fork-stabilizing role. By employing a hexapeptide wrwycr which specifically binds to and blocks proper processing of YSs (Y-Structures) and HJs (Holliday Junction-Structures) in vitro and in vivo, HMGA2 was found to suppress peptide-induced cleavage at branched DNA structures in vivo. The faithful and complete replication of genome is essential to maintain genome integrity and prevent the accumulation of cancer-promoting mutations. The results of my study thus uncovered an important novel replication fork chaperone activity in mammalian cells which employs direct physical stabilization of branched DNA by forming a scaffold via multiple DNA binding domains in cis. This chaperone seemingly evolved to preserve ES cell genome integrity, but is hijacked by tumor (stem) cells in the adult organism to guard their genomes also against DNA-damaging agents widely used in the clinic. ​Doctor of Philosophy (SBS) 2014-03-24T04:23:17Z 2014-03-24T04:23:17Z 2013 2013 Thesis http://hdl.handle.net/10356/55737 en 145 p. application/pdf
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic DRNTU::Science::Biological sciences::Molecular biology
spellingShingle DRNTU::Science::Biological sciences::Molecular biology
Yu, Haojie
Novel functions of the oncofetal HMGA2 protein in genome stability
description The non-histone chromatin factor HMGA2 (High Mobility Group AT-hook 2), which contains three AT-hook motifs as independent DNA binding domains, is normally expressed in ES cells and during embryonic/fetal development. In this study, I investigated its function in protecting the stalled replication forks. I found that RPA32 (Replication Protein A 32 kDa subunit) co-localises with HMGA2 at on-going or Hydroxyurea (HU)-induced stalled replication forks. The similar results were observed that IdU pulse-labeled replication sites co-localise with HMGA2 signals in the absence and in the presence of HU. Moreover, HMGA2 protects against fork-associated DSBs (Double Strand Breaks) formation as well as degradation of nascent DNA strands after Hydroxyurea (HU)-induced fork stalling. This, in turn, facilitates fork restart, significantly suppresses chromosomal instabilities, and enhances cell viability. Strikingly, in a heterologous cell system Saccharomyces cerevisiae (S. cerevisiae), human HMGA2 alone partially complements the fork-stabilizing function of ATR/Mec1 by reducing the occurrence of pathological fork structures and their subsequent endonucleolytic cleavage into DSBs. Moreover, wild type HMGA2 rather than the DNA-binding motif AT-hook mutants is sufficient to fully complement the Escherichia coli RecA protein in its replication fork-stabilizing role. By employing a hexapeptide wrwycr which specifically binds to and blocks proper processing of YSs (Y-Structures) and HJs (Holliday Junction-Structures) in vitro and in vivo, HMGA2 was found to suppress peptide-induced cleavage at branched DNA structures in vivo. The faithful and complete replication of genome is essential to maintain genome integrity and prevent the accumulation of cancer-promoting mutations. The results of my study thus uncovered an important novel replication fork chaperone activity in mammalian cells which employs direct physical stabilization of branched DNA by forming a scaffold via multiple DNA binding domains in cis. This chaperone seemingly evolved to preserve ES cell genome integrity, but is hijacked by tumor (stem) cells in the adult organism to guard their genomes also against DNA-damaging agents widely used in the clinic.
author2 Peter Droge
author_facet Peter Droge
Yu, Haojie
format Theses and Dissertations
author Yu, Haojie
author_sort Yu, Haojie
title Novel functions of the oncofetal HMGA2 protein in genome stability
title_short Novel functions of the oncofetal HMGA2 protein in genome stability
title_full Novel functions of the oncofetal HMGA2 protein in genome stability
title_fullStr Novel functions of the oncofetal HMGA2 protein in genome stability
title_full_unstemmed Novel functions of the oncofetal HMGA2 protein in genome stability
title_sort novel functions of the oncofetal hmga2 protein in genome stability
publishDate 2014
url http://hdl.handle.net/10356/55737
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