Human Structural Variation: Mechanisms of Chromosome Rearrangements.

Chromosome structural variation (SV) is a normal part of variation in the human genome, but some classes of SV can cause neurodevelopmental disorders. Analysis of the DNA sequence at SV breakpoints can reveal mutational mechanisms and risk factors for chromosome rearrangement. Large-scale SV breakpoint studies have become possible recently owing to advances in next-generation sequencing (NGS) including whole-genome sequencing (WGS). These findings have shed light on complex forms of SV such as triplications, inverted duplications, insertional translocations, and chromothripsis. Sequence-level breakpoint data resolve SV structure and determine how genes are disrupted, fused, and/or misregulated by breakpoints. Recent improvements in breakpoint sequencing have also revealed non-allelic homologous recombination (NAHR) between paralogous long interspersed nuclear element (LINE) or human endogenous retrovirus (HERV) repeats as a cause of deletions, duplications, and translocations. This review covers the genomic organization of simple and complex constitutional SVs, as well as the molecular mechanisms of their formation.

[1]  M. K. Rudd,et al.  Next-generation sequencing of duplication CNVs reveals that most are tandem and some create fusion genes at breakpoints. , 2015, American journal of human genetics.

[2]  K. Conneely,et al.  Tandem Repeats and G-Rich Sequences Are Enriched at Human CNV Breakpoints , 2014, PloS one.

[3]  Suzanne M. McCahan,et al.  Complex Genomic Rearrangements at the PLP1 Locus Include Triplication and Quadruplication , 2015, PLoS genetics.

[4]  D. Zwijnenburg,et al.  Sequencing of neuroblastoma identifies chromothripsis and defects in neuritogenesis genes , 2012, Nature.

[5]  J. Lupski,et al.  Frequency of nonallelic homologous recombination is correlated with length of homology: evidence that ectopic synapsis precedes ectopic crossing-over. , 2011, American journal of human genetics.

[6]  Mark Gerstein,et al.  Genome-Wide Mapping of Copy Number Variation in Humans: Comparative Analysis of High Resolution Array Platforms , 2011, PloS one.

[7]  J. Lupski Genomic disorders: structural features of the genome can lead to DNA rearrangements and human disease traits. , 1998, Trends in genetics : TIG.

[8]  M. Lieber,et al.  The mechanism of double-strand DNA break repair by the nonhomologous DNA end-joining pathway. , 2010, Annual review of biochemistry.

[9]  Markus J. van Roosmalen,et al.  Constitutional chromothripsis rearrangements involve clustered double-stranded DNA breaks and nonhomologous repair mechanisms. , 2012, Cell reports.

[10]  Human endogenous retroviral elements promote genome instability via non-allelic homologous recombination , 2014, BMC Biology.

[11]  J. Weissenbach,et al.  A sex chromosome rearrangement in a human XX male caused by Alu—Alu recombination , 1987, Cell.

[12]  E. Cuppen,et al.  Genomic and functional overlap between somatic and germline chromosomal rearrangements. , 2014, Cell reports.

[13]  A. Gnirke,et al.  Paired-end sequencing of Fosmid libraries by Illumina , 2012, Genome research.

[14]  Philip M. Kim,et al.  Paired-End Mapping Reveals Extensive Structural Variation in the Human Genome , 2007, Science.

[15]  Ryan L. Collins,et al.  Cryptic and complex chromosomal aberrations in early-onset neuropsychiatric disorders. , 2014, American journal of human genetics.

[16]  Qibin Li,et al.  Characterization of 26 deletion CNVs reveals the frequent occurrence of micro-mutations within the breakpoint-flanking regions and frequent repair of double-strand breaks by templated insertions derived from remote genomic regions , 2015, Human Genetics.

[17]  S. Tapscott,et al.  Intrastrand Annealing Leads to the Formation of a Large DNA Palindrome and Determines the Boundaries of Genomic Amplification in Human Cancer , 2007, Molecular and Cellular Biology.

[18]  Chromosome Instability Is Common in Human Cleavage-Stage Embryos , 2012 .

[19]  Benjamin P. Blackburne,et al.  Mutation spectrum revealed by breakpoint sequencing of human germline CNVs , 2010, Nature Genetics.

[20]  U. Surti,et al.  A recurrent translocation is mediated by homologous recombination between HERV-H elements , 2012, Molecular Cytogenetics.

[21]  Ira M. Hall,et al.  Characterizing complex structural variation in germline and somatic genomes. , 2012, Trends in genetics : TIG.

[22]  R. Pfundt,et al.  Parental insertional balanced translocations are an important cause of apparently de novo CNVs in patients with developmental anomalies , 2011, European Journal of Human Genetics.

[23]  R. Giorda,et al.  Identification of a recurrent breakpoint within the SHANK3 gene in the 22q13.3 deletion syndrome , 2005, Journal of Medical Genetics.

[24]  Huanming Yang,et al.  High-resolution mapping of genotype-phenotype relationships in cri du chat syndrome using array comparative genomic hybridization. , 2005, American journal of human genetics.

[25]  Dagmar Wieczorek,et al.  Heterozygous submicroscopic inversions involving olfactory receptor-gene clusters mediate the recurrent t(4;8)(p16;p23) translocation. , 2002, American journal of human genetics.

[26]  E. Liu,et al.  Detection of Chromosomal Breakpoints in Patients with Developmental Delay and Speech Disorders , 2014, PloS one.

[27]  Mark D. Johnson,et al.  Functional genomic analysis of chromosomal aberrations in a compendium of 8000 cancer genomes , 2013, Genome research.

[28]  Z. Ou,et al.  Observation and prediction of recurrent human translocations mediated by NAHR between nonhomologous chromosomes. , 2011, Genome research.

[29]  C. Kim,et al.  Complex structural rearrangement features suggesting chromoanagenesis mechanism in a case of 1p36 deletion syndrome , 2014, Molecular Genetics and Genomics.

[30]  J. Lupski,et al.  Microhomology-Mediated Mechanisms Underlie Non-Recurrent Disease-Causing Microdeletions of the FOXL2 Gene or Its Regulatory Domain , 2013, PLoS genetics.

[31]  P. Stankiewicz,et al.  Structural variation in the human genome and its role in disease. , 2010, Annual review of medicine.

[32]  J. Weber,et al.  Olfactory receptor-gene clusters, genomic-inversion polymorphisms, and common chromosome rearrangements. , 2001, American journal of human genetics.

[33]  Richard T. Barfield,et al.  Mouse model implicates GNB3 duplication in a childhood obesity syndrome , 2013, Proceedings of the National Academy of Sciences.

[34]  K. Jones,et al.  The 11q terminal deletion disorder: A prospective study of 110 cases , 2004, American journal of medical genetics. Part A.

[35]  Gregory M. Cooper,et al.  A Copy Number Variation Morbidity Map of Developmental Delay , 2011, Nature Genetics.

[36]  Joshua M. Korn,et al.  Mapping and sequencing of structural variation from eight human genomes , 2008, Nature.

[37]  Andrew J Sharp,et al.  Discovery of previously unidentified genomic disorders from the duplication architecture of the human genome , 2006, Nature Genetics.

[38]  K. Devriendt,et al.  A Balanced Translocation t(6;14)(q25.3;q13.2) Leading to Reciprocal Fusion Transcripts in a Patient with Intellectual Disability and Agenesis of Corpus Callosum , 2010, Cytogenetic and Genome Research.

[39]  M. Talkowski,et al.  Design of Large‐Insert Jumping Libraries for Structural Variant Detection Using Illumina Sequencing , 2014, Current protocols in human genetics.

[40]  Martin Vingron,et al.  Mapping translocation breakpoints by next-generation sequencing. , 2008, Genome research.

[41]  Ira M. Hall,et al.  Complex reorganization and predominant non-homologous repair following chromosomal breakage in karyotypically balanced germline rearrangements and transgenic integration , 2012, Nature Genetics.

[42]  V. Beneš,et al.  Disruption of EXOC6B in a patient with developmental delay, epilepsy, and a de novo balanced t(2;8) translocation , 2013, European Journal of Human Genetics.

[43]  Swaroop Aradhya,et al.  An evidence-based approach to establish the functional and clinical significance of copy number variants in intellectual and developmental disabilities , 2011, Genetics in Medicine.

[44]  M. K. Rudd,et al.  Unbalanced translocations arise from diverse mutational mechanisms including chromothripsis , 2015, Genome research.

[45]  A. Conti,et al.  Pure 16q21q22.1 deletion in a complex rearrangement possibly caused by a chromothripsis event , 2013, Molecular Cytogenetics.

[46]  D. Ledbetter,et al.  Diverse mutational mechanisms cause pathogenic subtelomeric rearrangements. , 2011, Human molecular genetics.

[47]  Andrew J Sharp,et al.  The genetics of microdeletion and microduplication syndromes: an update. , 2014, Annual review of genomics and human genetics.

[48]  N. Tommerup,et al.  The strength of combined cytogenetic and mate-pair sequencing techniques illustrated by a germline chromothripsis rearrangement involving FOXP2 , 2013, European Journal of Human Genetics.

[49]  J. Lupski,et al.  The DNA replication FoSTeS/MMBIR mechanism can generate genomic, genic and exonic complex rearrangements in humans , 2009, Nature Genetics.

[50]  Neil J Ganem,et al.  DNA breaks and chromosome pulverization from errors in mitosis , 2012, Nature.

[51]  M. Shago,et al.  A common molecular mechanism underlies two phenotypically distinct 17p13.1 microdeletion syndromes. , 2010, American journal of human genetics.

[52]  L. Cuisset,et al.  Inverted duplication with deletion: First interstitial case suggesting a novel undescribed mechanism of formation , 2014, American journal of medical genetics. Part A.

[53]  Katherine L Hill-Harfe,et al.  Fine mapping of chromosome 17 translocation breakpoints > or = 900 Kb upstream of SOX9 in acampomelic campomelic dysplasia and a mild, familial skeletal dysplasia. , 2005, American journal of human genetics.

[54]  Bradley P. Coe,et al.  Formation of chimeric genes by copy-number variation as a mutational mechanism in schizophrenia. , 2013, American journal of human genetics.

[55]  R. Pfundt,et al.  Further clinical and molecular delineation of the 9q subtelomeric deletion syndrome supports a major contribution of EHMT1 haploinsufficiency to the core phenotype , 2009, Journal of Medical Genetics.

[56]  Eric Vilain,et al.  Clinical exome sequencing for genetic identification of rare Mendelian disorders. , 2014, JAMA.

[57]  J. Lupski,et al.  Spastic paraplegia type 2 associated with axonal neuropathy and apparent PLP1 position effect , 2006, Annals of neurology.

[58]  Nobuhiko Okamoto,et al.  Pelizaeus-Merzbacher disease caused by a duplication-inverted triplication-duplication in chromosomal segments including the PLP1 region. , 2012, European journal of medical genetics.

[59]  N. Carter,et al.  Massive Genomic Rearrangement Acquired in a Single Catastrophic Event during Cancer Development , 2011, Cell.

[60]  T. Ogata,et al.  Transactivation function of an approximately 800-bp evolutionarily conserved sequence at the SHOX 3' region: implication for the downstream enhancer. , 2006, American journal of human genetics.

[61]  M. Gerstein,et al.  CNVnator: an approach to discover, genotype, and characterize typical and atypical CNVs from family and population genome sequencing. , 2011, Genome research.

[62]  P. Stankiewicz,et al.  The Alu-rich genomic architecture of SPAST predisposes to diverse and functionally distinct disease-associated CNV alleles. , 2014, American journal of human genetics.

[63]  L. Shaffer,et al.  Large Inverted Duplications in the Human Genome Form via a Fold-Back Mechanism , 2014, PLoS genetics.

[64]  B. Emanuel,et al.  Chromosomal translocations and palindromic AT-rich repeats. , 2012, Current opinion in genetics & development.

[65]  Steven A. Roberts,et al.  An APOBEC cytidine deaminase mutagenesis pattern is widespread in human cancers , 2013, Nature Genetics.

[66]  Markus J. van Roosmalen,et al.  Chromothripsis as a mechanism driving complex de novo structural rearrangements in the germline. , 2011, Human molecular genetics.

[67]  Zhaoshi Jiang,et al.  Characterization of six human disease-associated inversion polymorphisms , 2009, Human molecular genetics.

[68]  E. Cuppen,et al.  Chromothripsis in healthy individuals affects multiple protein-coding genes and can result in severe congenital abnormalities in offspring. , 2015, American journal of human genetics.

[69]  Thomas Bourgeron,et al.  Mutations in the gene encoding the synaptic scaffolding protein SHANK3 are associated with autism spectrum disorders , 2007, Nature Genetics.

[70]  E. Cuppen,et al.  Chromothripsis in congenital disorders and cancer: similarities and differences. , 2013, Current opinion in cell biology.

[71]  J. Lupski,et al.  Replicative mechanisms for CNV formation are error prone , 2013, Nature Genetics.

[72]  Magalie S Leduc,et al.  Molecular findings among patients referred for clinical whole-exome sequencing. , 2014, JAMA.

[73]  David C. Schwartz,et al.  A large, complex structural polymorphism at 16p12.1 underlies microdeletion disease risk , 2010, Nature Genetics.

[74]  J. Lupski,et al.  Complex human chromosomal and genomic rearrangements. , 2009, Trends in genetics : TIG.

[75]  Derek Y. Chiang,et al.  High-resolution mapping of copy-number alterations with massively parallel sequencing , 2009, Nature Methods.

[76]  A. Goodeve,et al.  Homeologous recombination between AluSx‐sequences as a cause of hemophilia , 2004, Human mutation.

[77]  M. Gerstein,et al.  PEMer: a computational framework with simulation-based error models for inferring genomic structural variants from massive paired-end sequencing data , 2009, Genome Biology.

[78]  J. Vermeesch,et al.  Nonallelic homologous recombination between retrotransposable elements is a driver of de novo unbalanced translocations , 2013, Genome research.

[79]  P. Stankiewicz,et al.  Position effects due to chromosome breakpoints that map approximately 900 Kb upstream and approximately 1.3 Mb downstream of SOX9 in two patients with campomelic dysplasia. , 2005, American journal of human genetics.

[80]  M. Hurles,et al.  Absence of heterozygosity due to template switching during replicative rearrangements. , 2015, American journal of human genetics.

[81]  Margaret B. Fish,et al.  Disruption of autoregulatory feedback by a mutation in a remote, ultraconserved PAX6 enhancer causes aniridia. , 2013, American journal of human genetics.

[82]  Mark J. P. Chaisson,et al.  Resolving the complexity of the human genome using single-molecule sequencing , 2014, Nature.

[83]  P. Stankiewicz,et al.  Chromosome Catastrophes Involve Replication Mechanisms Generating Complex Genomic Rearrangements , 2011, Cell.

[84]  L. Vissers,et al.  Rare pathogenic microdeletions and tandem duplications are microhomology-mediated and stimulated by local genomic architecture. , 2009, Human molecular genetics.

[85]  A. Battaglia,et al.  Natural History of Wolf-Hirschhorn Syndrome: Experience With 15 Cases , 1999, Pediatrics.

[86]  Jonathan A. Bernstein,et al.  Clinical whole-exome sequencing: are we there yet? , 2014, Genetics in Medicine.

[87]  D. Conrad,et al.  Global variation in copy number in the human genome , 2006, Nature.

[88]  Kali T. Witherspoon,et al.  Refining analyses of copy number variation identifies specific genes associated with developmental delay , 2014, Nature Genetics.

[89]  E. Eichler,et al.  Discovery of large genomic inversions using pooled clone sequencing , 2015, bioRxiv.

[90]  J. Rosenfeld,et al.  Recurrence, submicroscopic complexity, and potential clinical relevance of copy gains detected by array CGH that are shown to be unbalanced insertions by FISH. , 2011, Genome research.

[91]  A. Reymond,et al.  The effect of translocation-induced nuclear reorganization on gene expression. , 2010, Genome research.

[92]  J. Raes,et al.  Deletions involving long-range conserved nongenic sequences upstream and downstream of FOXL2 as a novel disease-causing mechanism in blepharophimosis syndrome. , 2005, American journal of human genetics.

[93]  V. Jobanputra,et al.  Prenatal diagnosis of chromothripsis, with nine breaks characterized by karyotyping, FISH, microarray and whole‐genome sequencing , 2015, Prenatal diagnosis.

[94]  D. Cleveland,et al.  Chromoanagenesis and cancer: mechanisms and consequences of localized, complex chromosomal rearrangements , 2012, Nature Medicine.

[95]  J. Shendure,et al.  Characterization of apparently balanced chromosomal rearrangements from the developmental genome anatomy project. , 2008, American journal of human genetics.

[96]  L. Vissers,et al.  Genome sequencing identifies major causes of severe intellectual disability , 2014, Nature.

[97]  J. Lupski,et al.  Inverted genomic segments and complex triplication rearrangements are mediated by inverted repeats in the human genome , 2011, Nature Genetics.

[98]  J. Lupski,et al.  Mechanisms of change in gene copy number , 2009, Nature Reviews Genetics.

[99]  P. Stankiewicz,et al.  Position effects due to chromosome breakpoints that map ∼900 Kb upstream and ∼1.3 Mb downstream of SOX9 in two patients with campomelic dysplasia , 2005 .

[100]  Y. Fukushima,et al.  Aniridia-associated cytogenetic rearrangements suggest that a position effect may cause the mutant phenotype. , 1995, Human molecular genetics.

[101]  E. Eichler,et al.  Fine-scale structural variation of the human genome , 2005, Nature Genetics.

[102]  E. Eichler,et al.  A Human Genome Structural Variation Sequencing Resource Reveals Insights into Mutational Mechanisms , 2010, Cell.

[103]  Z. Ou,et al.  Insertional translocation detected using FISH confirmation of array‐comparative genomic hybridization (aCGH) results , 2010, American journal of medical genetics. Part A.

[104]  J. Rosenfeld,et al.  NAHR-mediated copy-number variants in a clinical population: Mechanistic insights into both genomic disorders and Mendelizing traits , 2013, Genome research.

[105]  Pengfei Liu,et al.  Mechanisms for recurrent and complex human genomic rearrangements. , 2012, Current opinion in genetics & development.

[106]  T. Ogata,et al.  Transactivation function of an ∼800-bp evolutionarily conserved sequence at the SHOX 3' region : Implication for the downstream enhancer , 2006 .

[107]  M. Raffeld,et al.  Chromothriptic Cure of WHIM Syndrome , 2015, Cell.

[108]  J. Lupski,et al.  Dosage changes of a segment at 17p13.1 lead to intellectual disability and microcephaly as a result of complex genetic interaction of multiple genes. , 2014, American journal of human genetics.

[109]  D. Conrad,et al.  Inverted duplications on acentric markers: mechanism of formation. , 2009, Human molecular genetics.

[110]  C. Baker,et al.  Resolving the breakpoints of the 17q21.31 microdeletion syndrome with next-generation sequencing. , 2012, American journal of human genetics.

[111]  Emmanuel Barillot,et al.  Breakpoint Features of Genomic Rearrangements in Neuroblastoma with Unbalanced Translocations and Chromothripsis , 2013, PloS one.

[112]  S. Julia,et al.  Constitutional chromoanasynthesis: description of a rare chromosomal event in a patient. , 2014, European journal of medical genetics.

[113]  Kenny Q. Ye,et al.  Mapping copy number variation by population scale genome sequencing , 2010, Nature.

[114]  Leslie G Biesecker,et al.  Consensus statement: chromosomal microarray is a first-tier clinical diagnostic test for individuals with developmental disabilities or congenital anomalies. , 2010, American journal of human genetics.

[115]  Anna Gambin,et al.  Genome-wide analyses of LINE–LINE-mediated nonallelic homologous recombination , 2015, Nucleic acids research.

[116]  M. Claustres,et al.  Dissecting the Structure and Mechanism of a Complex Duplication–Triplication Rearrangement in the DMD Gene , 2013, Human mutation.