Maintenance of Genome Stability
2016-09-27JiadongWangTomasLindahl
Jiadong WangTomas Lindahl*b
1Institute of Systems Biomedicine,Department of Radiation Medicine,School of Basic Medical Sciences,Peking University,Beijing 100191,China
2Cancer Research UK London Research Institute,Clare Hall Laboratories,South Mimms EN6 3LD,United Kingdom
PREFACE
Maintenance of Genome Stability
Jiadong Wang1,a,Tomas Lindahl2,*,b
1Institute of Systems Biomedicine,Department of Radiation Medicine,School of Basic Medical Sciences,Peking University,Beijing 100191,China
2Cancer Research UK London Research Institute,Clare Hall Laboratories,South Mimms EN6 3LD,United Kingdom
Available online 18 June 2016
It was ever thought that genomic information is transmitted faithfully from generation to generation.But our current knowledge does not indicate that it is the case.For example,genomic variations can be generated from DNA replication infidelity and unequal chromosome segregation.Natural decay of DNA molecules is also a fundamental source of changing genomic information.In addition,cellular and organismal exposure to exogenous genotoxic agents such as ultraviolet(UV)light,oxidative stress,chemical mutagens,and radiation can lead to a variety of modifications on DNA constituents,resulting in genome alterations.Fortunately,cells have evolved several response systems to tackle numerous DNA lesions in order to maintain their genome integrity.Among them,checkpoint control is probably the most well-known one.For example,checkpoint responds to replication stress,replication fork stalling,double-strand DNA breaks,and various other types of DNA lesions.Increasing experimental evidence indicates that genomic instability is probably the fundamental reason for carcinogenesis.Genomic instability is also found to be a main etiological factor of neurodegenerative diseases,aging,immunodeficiency,etc.Thus,to understand how cells regulate tomaintaintheirgenomicstabilityisoffundamental importance.
The Nobel Prize in Chemistry 2015 was jointly awarded to Tomas Lindahl,Paul Modrich,and Aziz Sancar for their mechanistic studies of DNA repair.The journal Genomics,Proteomics&Bioinformatics(GPB)has thus compiled a special issue Genome Stability following the award announcement. Six mini-reviews are included in this special issue,which cover various aspects of mechanisms underlying the maintenance of genome stability and related diseases.These are designed to introduce our readers to the current understanding,research frontiers,and challenges facing the field.
This special issue starts with a news and views article from Arne Klungland and Yun-Gui Yang[1].They briefly introduced the main scientific achievements of Tomas Lindahl in unraveling fundamental mechanisms of DNA decay and DNA repair,as well as associations with diseases.
DNA damage is the most important factor that induces genome instability.When DNA repair processes fail,irreparable DNA damage including double-strand breaks(DSBs)can occur.Under normal conditions,DSBs in eukaryotic cells can be repaired by either homologous recombination(HR)or non-homologous end-joining(NHEJ)pathways.A vital step in HR repair is DNA end resection.Liu and Huang[2]reviewed the machinery involved in DNA end resection and described in detail the functions of the most important factors that cooperate to complete the process in eukaryotic cells.
Posttranslational modifications(PTMs)such as phosphorylation,acetylation,methylation,ubiquitination,and SUMOylation are key mechanisms to maintain genome stability.Recently some unique PTMs have been shown to be involved in regulating genome stability.Wei and Yu[3]reviewed the role of poly ADP-ribosylation(PARylation)inDNA repair and genomic stability.PARylation is catalyzed by poly(ADP-ribose)polymerases(PARPs)upon activation by DNA lesions,forming PAR chains that serve as signals and docking platforms for DNA repair factors.These authors[3]highlight the molecular mechanisms of PARylation recognition,the role of PARylation in DDR pathways,and the functional interaction between PARylation and ubiquitination. This review offers a better understanding of the biological roles of this unique PTM in maintaining genome stability.
The review from Dr.Xu’s laboratory[4]is focused on ubiquitin-fold modifier 1(UFM1),one of the newly-identified PTMs.Similar to ubiquitin,UFM1 is conjugated to its target proteinsbyathree-stepenzymaticreaction,whileUFM1chains are cleaved from target proteins by UFM1-specific proteases(UfSPs),suggesting that the UFMylation modification is reversible.TheUFM1cascadeisassociatedwithseveralcellular activities including the endoplasmic reticulum stress response,hematopoiesis,and certain human diseases.Wei and Xu believe that this reversible modification process might modulate additionalcellularactivitiesincludingtumorigenesis andcouldserve as potential therapeutic target for cancer treatment.
In addition to protein modifications,post-transcriptional modifications of RNA also have important regulatory roles in cellular processes and might be involved in maintaining genome stability directly or indirectly.Wang and Jia[5]highlighted the functional role of m6A reader YTHDC1 in pre-mRNA alternative splicing[6].Moreover,they also highlighted two transcriptome-wide sequencing methods to identify a new mRNA reversible modification,m1A[7,8]. These two studies provided the first transcriptome-wide methylome map for m1A and suggested potential roles for this modification[7,8].We expect that further investigation of the wider biological functions of m6A and m1A,as well as the related writer,eraser,and reader proteins,will build a comprehensive picture of RNA modifications.
Maintenance of tissue-specific stem cells is vital for organ homeostasis and organismal longevity.DNA lesions are direct threats to the genome integrity of the stem cell population.The DDR not only repairs DNA lesions,but also activates orchestrated signaling pathways,leading to cell cycle regulation,cell death and senescence,transcriptional regulation,as well as chromatin remodeling.Recent studies on murine hematopoietic stem cells(HSCs)have indicated that the DDR has important roles in the homeostasis of the hematopoietic system in DDR-deficient mouse models.Li et al.[9]summarized the current understanding of how the DDR intrinsically and extrinsically regulates HSC maintenance,HSC fate determination,and finally organismal aging.
Mutations in certain components of the DDR machinery can lead to genomic instability disorders that culminate in developmental defects,tissue impairment,premature aging,and cancer.Kaminsky et al.[10]reviewed recent progress on the role of the DDR in the etiology of various brain degenerative diseases(BDDs),and summarized the evidence suggestingthatBDDsinvolvethedysfunctionofglialcells. Malfunctioning glial cells can severely hamper neural-glial interactions,thereby leading to BDDs.
Li and Liu[11]provided a comprehensive review on the effect of topoisomerase 1(TOP1)on genome stability.TOP1 relaxes supercoiled DNA to remove helical constraints that can otherwise hinder DNA replication and transcription. Unfortunately,such activity can generate toxic TOP1-DNA covalent products that can lead to cell death or mutagenesis,a precursor for tumorigenesis.In an apparent contradiction to the negative effect of TOP1 activity on genome stability,the detrimental effect of TOP1-induced DNA lesions on cell survival has made this enzyme a prime target for cancer therapies to kill fast-growing cancer cells.The impact of TOP1 research on human health is multifold.In this article,they summarized the current understanding of how TOP1 contributes to human diseases and how its activity can be targeted for disease treatment.
In conclusion,comprehensive understanding of the mechanisms underlying the DDR will not only help us to discover new factors for maintaining genome stability,but also shed light on the development of novel therapeutic strategies for treatment of diseases.We believe that this special issue will serve as a valuable resource to update the current status of genome stability research.
Competing interests
The authors have declared no competing interests.
Acknowledgments
We thank all the authors for nice contributions and great input from all the reviewers.Special thanks are also extended to Drs Zhao-Qi Wang,Xingzhi Xu,Daochun Kong,Yungui Yang,and Dongyi Xu for organizing the special issue.
References
[1]Klungland A,Yang YG.Endogenous DNA damage and repair enzymes—A short summary of the scientific achievements of Tomas Lindahl,Nobel Laureate in Chemistry 2015.Genomics Proteomics Bioinformatics 2016;14:122-5.
[2]Liu T,Huang J.DNA end resection:facts and mechanisms. Genomics Proteomics Bioinformatics 2016;14:126-30.
[3]Wei H,Yu X.Functions of PARylation in DNA damage repair pathways.Genomics Proteomics Bioinformatics 2016;14:131-9.
[4]Wei Y,Xu X.UFMylation:a unique&fashionable modification for life.Genomics Proteomics Bioinformatics 2016;14:140-6.
[5]Wang Y,Jia G.New edges of RNA adenosine methylation modifications.GenomicsProteomicsBioinformatics 2016;14:172-5.
[6]Xiao W,Adhikari S,Dahal U,Chen YS,Hao YJ,Sun BF,et al. Nuclear m(6)A reader YTHDC1 regulates mRNA splicing.Mol Cell 2016;61:507-19.
[7]Dominissini D,Nachtergaele S,Moshitch-Moshkovitz S,Peer E,Kol N,Ben-Haim MS,et al.The dynamic N(1)-methyladenosine methylomeineukaryoticmessengerRNA.Nature 2016;530:441-6.
[8]Li X,Xiong X,Wang K,Wang L,Shu X,Ma S,et al. Transcriptome-wide mapping reveals reversible and dynamic N1-methyladenosine methylome.Nat Chem Biol 2016;12:311-6.
[9]Li T,Zhou ZW,Ju Z,Wang ZQ.DNA damage response in hematopoietic stem cell ageing.Genomics Proteomics Bioinformatics 2016;14:147-54.
[10]Kaminsky N,Bihari O,Kanner S,Barzilai A.Connecting malfunctioning glial cells and brain degenerative disorders. Genomics Proteomics Bioinformatics 2016;14:155-65.
[11]Li M,Liu Y.Topoisomerase I in human disease pathogenesis and treatments.Genomics Proteomics Bioinformatics 2016;14:166-71.
Dr.Tomas Lindahl was the Director of the Clare Hall Laboratories at ICRF and Cancer Research UK(1984-2006).His research has focused on understanding DNA repair,which has a long-lasting impact on the fields of cancer therapy and inherited human genetic disorders,among others.Beyond his own outstanding scientific achievements,his stewardship established Clare Hall Laboratories as an internationally-renowned center of research on DNA processing.The success of colleagues working together with him is a measure of his insight,support,and leadership.Dr.Lindahl was jointly awarded the Nobel Prize in Chemistry 2015 for his mechanistic studies on DNA repair.
9 May 2016;accepted 14 June 2016
*Corresponding author.
E-mail:Tomas.Lindahl@crick.ac.uk(Lindahl T).
aORCID:0000-0002-0324-9931.
bORCID:0000-0003-0174-8152.
Peer review under responsibility of Beijing Institute of Genomics,Chinese Academy of Sciences and Genetics Society of China.
http://dx.doi.org/10.1016/j.gpb.2016.06.001
1672-0229ⓒ2016 The Authors.Production and hosting by Elsevier B.V.on behalf of Beijing Institute of Genomics,Chinese Academy of Sciences and Genetics Society of China.
This is an open access article under the CC BY license(http://creativecommons.org/licenses/by/4.0/).
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Genomics,Proteomics & Bioinformatics的其它文章
- Endogenous DNA Damage and Repair Enzymes—A short summary of the scientific achievements of Tomas Lindahl,Nobel Laureate in Chemistry 2015
- DNA Damage Response in Hematopoietic Stem Cell Ageing
- Connecting Malfunctioning Glial Cells and Brain Degenerative Disorders
- Topoisomerase I in Human Disease Pathogenesis and Treatments
- New Edges of RNA Adenosine Methylation Modifications