Use of the Z-DNA binding domain of ADAR1 as a probe for nucleic acids in left-handed conformation

Both DNA and RNA can be in Z-conformation. Compared to classical B-DNA conformation, Z-DNA is in a higher energy state and studied extensively, so far mainly in vitro. It has been recognized that Z-DNA plays roles in many biological activities, including regulation of transcription, chromatin remode...

Full description

Saved in:
Bibliographic Details
Main Author: Li, Heng
Other Authors: Peter Droge
Format: Theses and Dissertations
Language:English
Published: 2009
Subjects:
Online Access:https://hdl.handle.net/10356/15657
Tags: Add Tag
No Tags, Be the first to tag this record!
Institution: Nanyang Technological University
Language: English
id sg-ntu-dr.10356-15657
record_format dspace
spelling sg-ntu-dr.10356-156572023-02-28T18:36:31Z Use of the Z-DNA binding domain of ADAR1 as a probe for nucleic acids in left-handed conformation Li, Heng Peter Droge School of Biological Sciences DRNTU::Science::Biological sciences::Human anatomy and physiology::Deoxyribonucleic acids Both DNA and RNA can be in Z-conformation. Compared to classical B-DNA conformation, Z-DNA is in a higher energy state and studied extensively, so far mainly in vitro. It has been recognized that Z-DNA plays roles in many biological activities, including regulation of transcription, chromatin remodeling, genetic instability, etc. Bioinformatics analyses and experimental studies on particular genomic loci suggest that the Z-DNA forming sequences are enriched in gene regulatory regions, where the formation of Z-DNA is drived by transcription-induced negative supercoiling. However, the global distribution of Z-DNA in the human genome in vivo is still experimentally elusive, due to instable nature of Z-DNA and lack of Z-DNA specific probe. Here, we show for the first time the distribution of Z-DNA hotspots in the genome of cultured human cancer cells A549 by exploiting the Zα domain from human ADAR1 (ZαADAR1, simplified as Zα for convenience in the thesis) as a Z-DNA specific probe with a novel experimental strategy. A protocol for in vitro chromatin affinity precipitation (ChAP) was developed and a Z-DNA library was constructed and sequenced. In total, 186 Z-DNA hotspots were identified. Enrichment of hotspots in gene regulation regions was not found. Unexpectedly, 46 hotspots localize to the centromeric regions. Further examination on hotspots therein suggests that Z-DNA hotspots are strongly correlated with high occurrences of SNPs (single nucleotide polymorphism). Bioinformatics analysis using a Z-DNA prediction program shows that most of these Z-DNA forming hotspots (143 out of 186) could be transited to Z-conformation only at σ < - 0.08, suggesting particular regions in the centromeres contain high negative superhelical torsional strain. Genetic instability and gene conversion promoted by Z-DNA provide a new clue for the rapid evolution of the centromere. Z-RNA shares many similar structural features with Z-DNA. But so far its existence in vivo and potential biological roles are still elusive. In the second part of this study, we found that Zα could bind to RNA in vivo which was identified as rRNA. Further studies suggested that Zα could bind to mammalian ribosomes in a conformation-dependent manner. The effect of the binding of Zα to ribosomes was examined and Zα could inhibit in vitro translation efficiently. DOCTOR OF PHILOSOPHY (SBS) 2009-05-14T01:18:28Z 2009-05-14T01:18:28Z 2008 2008 Thesis Li, H. (2008). Use of the Z-DNA binding domain of ADAR1 as a probe for nucleic acids in left-handed conformation. Doctoral thesis, Nanyang Technological University, Singapore. https://hdl.handle.net/10356/15657 10.32657/10356/15657 en 171 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::Human anatomy and physiology::Deoxyribonucleic acids
spellingShingle DRNTU::Science::Biological sciences::Human anatomy and physiology::Deoxyribonucleic acids
Li, Heng
Use of the Z-DNA binding domain of ADAR1 as a probe for nucleic acids in left-handed conformation
description Both DNA and RNA can be in Z-conformation. Compared to classical B-DNA conformation, Z-DNA is in a higher energy state and studied extensively, so far mainly in vitro. It has been recognized that Z-DNA plays roles in many biological activities, including regulation of transcription, chromatin remodeling, genetic instability, etc. Bioinformatics analyses and experimental studies on particular genomic loci suggest that the Z-DNA forming sequences are enriched in gene regulatory regions, where the formation of Z-DNA is drived by transcription-induced negative supercoiling. However, the global distribution of Z-DNA in the human genome in vivo is still experimentally elusive, due to instable nature of Z-DNA and lack of Z-DNA specific probe. Here, we show for the first time the distribution of Z-DNA hotspots in the genome of cultured human cancer cells A549 by exploiting the Zα domain from human ADAR1 (ZαADAR1, simplified as Zα for convenience in the thesis) as a Z-DNA specific probe with a novel experimental strategy. A protocol for in vitro chromatin affinity precipitation (ChAP) was developed and a Z-DNA library was constructed and sequenced. In total, 186 Z-DNA hotspots were identified. Enrichment of hotspots in gene regulation regions was not found. Unexpectedly, 46 hotspots localize to the centromeric regions. Further examination on hotspots therein suggests that Z-DNA hotspots are strongly correlated with high occurrences of SNPs (single nucleotide polymorphism). Bioinformatics analysis using a Z-DNA prediction program shows that most of these Z-DNA forming hotspots (143 out of 186) could be transited to Z-conformation only at σ < - 0.08, suggesting particular regions in the centromeres contain high negative superhelical torsional strain. Genetic instability and gene conversion promoted by Z-DNA provide a new clue for the rapid evolution of the centromere. Z-RNA shares many similar structural features with Z-DNA. But so far its existence in vivo and potential biological roles are still elusive. In the second part of this study, we found that Zα could bind to RNA in vivo which was identified as rRNA. Further studies suggested that Zα could bind to mammalian ribosomes in a conformation-dependent manner. The effect of the binding of Zα to ribosomes was examined and Zα could inhibit in vitro translation efficiently.
author2 Peter Droge
author_facet Peter Droge
Li, Heng
format Theses and Dissertations
author Li, Heng
author_sort Li, Heng
title Use of the Z-DNA binding domain of ADAR1 as a probe for nucleic acids in left-handed conformation
title_short Use of the Z-DNA binding domain of ADAR1 as a probe for nucleic acids in left-handed conformation
title_full Use of the Z-DNA binding domain of ADAR1 as a probe for nucleic acids in left-handed conformation
title_fullStr Use of the Z-DNA binding domain of ADAR1 as a probe for nucleic acids in left-handed conformation
title_full_unstemmed Use of the Z-DNA binding domain of ADAR1 as a probe for nucleic acids in left-handed conformation
title_sort use of the z-dna binding domain of adar1 as a probe for nucleic acids in left-handed conformation
publishDate 2009
url https://hdl.handle.net/10356/15657
_version_ 1759854438277709824