Tandem and inverted duplications in haemophilia A: Breakpoint characterisation provides insight into possible rearrangement mechanisms

Li, Y.D.; Ding, Biying; Mao, Yinqi; Zhang, Huayang; Wang, Xuefeng; Ding, Qiulan

doi:10.1111/hae.14799

Cited by 3 publications

(9 citation statements)

References 58 publications

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“…These duplications are illustrated using NAHR at repetitive elements, but similar structures could be generated at non-repetitive sequences through repair of DNA breaks by NHEJ, MMEJ or MMBIR. This particular outcome has recently been reported at the Factor 8 locus where NAHR at long, highly homologous inverted repeats generates one of the junctions and the second junction occurs at regions of little to no homology [35]. It produces the pattern of a deletion and inverted duplication separated by a stretch of copy-neutral DNA in between (1-0-1-2-1; Figure 4A; Figure 5; Table 1, examples 24-25, 39, 44-45).…”

Section: Inverted Duplications Associated With Deletionsmentioning

confidence: 57%

“…A) The original sequence near the Xq telomere; F8 is the Factor 8 gene, highlighted in blue. Diagram is adapted from [35]. Exons of three adjacent genes (green arrows) and three different low-copy repeats (LCRs, black and gray arrows) are highlighted.…”

Section: Figure Legendsmentioning

confidence: 99%

“…Exons of three adjacent genes (green arrows) and three different low-copy repeats (LCRs, black and gray arrows) are highlighted. B) Stylized aCGH data for the male patient with Factor 8 deficiency (reported in [35] 6: Mechanism that generates an inverted triplication of the SUL1 region in yeast (ODIRA)-modified from Figure 1 in Martin et al, 2023 [13]. A) The structure of the SUL1 locus in yeast includes an origin of replication (ARS228) and adjacent short (~5 nt) inverted repeats separated by 40-80 nt of sequence.…”

Section: Figure Legendsmentioning

confidence: 99%

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A unifying model that explains the origins of human inverted copy number variants

Brewer,

Dunham,

Raghuraman

2023

Preprint

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With the release of the telomere-to-telomere human genome sequence and the availability of both long-read sequencing and optical genome mapping techniques, the identification of copy number variants and other structural variants is providing new insights into human genetic disease. Different mechanisms have been proposed to account for the novel junctions in these complex architectures, including aberrant forms of DNA replication, non-allelic homologous recombination and various pathways that repair DNA breaks. Here we have focused on a set of structural variants that include an inverted segment and propose that they share a common initiating event: an inverted triplication with long, unstable palindromic junctions. The secondary rearrangement of these palindromes gives rise to the various forms of inverted structural variants. We postulate that this same mechanism (ODIRA: Origin Dependent Inverted Repeat Amplification) that creates the inverted copy number variants in inherited syndromes also generates the palindromes found in cancers.

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Section: Inverted Duplications Associated With Deletionsmentioning

confidence: 57%

Section: Figure Legendsmentioning

confidence: 99%

Section: Figure Legendsmentioning

confidence: 99%

See 1 more Smart Citation

A unifying model that explains the origins of human inverted copy number variants

Brewer,

Dunham,

Raghuraman

2023

Preprint

View full text Add to dashboard Cite

show abstract

“…These duplications are illustrated using NAHR at repetitive elements, but similar structures could be generated at non-repetitive sequences through repair of DNA breaks by NHEJ, MMEJ, or MMBIR. This particular outcome has recently been reported at the Factor 8 locus where NAHR at long, highly homologous inverted repeats generates one of the junctions and the second junction occurs at regions of little to no homology [ 37 ]. It produces the pattern of a deletion and inverted duplication separated by a stretch of copy-neutral DNA in between (1-0-1-2-1; Figs 4A and 5 and Table 1 , examples 24, 25, 39, 44, 45).…”

Section: Resultsmentioning

confidence: 72%

A unifying model that explains the origins of human inverted copy number variants

Brewer,

Dunham,

Raghuraman

2024

PLoS Genet

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With the release of the telomere-to-telomere human genome sequence and the availability of both long-read sequencing and optical genome mapping techniques, the identification of copy number variants (CNVs) and other structural variants is providing new insights into human genetic disease. Different mechanisms have been proposed to account for the novel junctions in these complex architectures, including aberrant forms of DNA replication, non-allelic homologous recombination, and various pathways that repair DNA breaks. Here, we have focused on a set of structural variants that include an inverted segment and propose that they share a common initiating event: an inverted triplication with long, unstable palindromic junctions. The secondary rearrangement of these palindromes gives rise to the various forms of inverted structural variants. We postulate that this same mechanism (ODIRA: origin-dependent inverted-repeat amplification) that creates the inverted CNVs in inherited syndromes also generates the palindromes found in cancers.

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“…After a distance of reverse replication, the second template switch occurs through MMBIR, restoring the original direction of replication for subsequent DNA synthesis. 35 36 In other words, one rearrangement breakpoint is fixed within inverted LCRs, whereas the second breakpoints are relatively random. Therefore, the impact of LCR-F9A/LCR-F9B-induced DUP–TRP/INV–DUP rearrangements on the F9 copy number depends on the length of backward-directed replication and the position of the second template switch.…”

Section: Discussionmentioning

confidence: 99%

Complete F9 Gene Deletion, Duplication, and Triplication Rearrangements: Implications for Factor IX Expression and Clinical Phenotypes

Ma,

Li,

Sun

et al. 2023

Thromb Haemost

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Background Factor IX (FIX) plays a critical role in blood coagulation. Complete deletion of F9 results in severe hemophilia B, whereas the clinical implications of complete F9 duplication and triplication remain understudied. Objective To investigate the rearrangement mechanisms underlying complete F9 deletion (cases 1 and 2), duplication (cases 3 and 4), and triplication (case 5), and to explore their association with FIX expression levels and clinical impacts. Methods Plasma FIX levels were detected using antigen and activity assays. CNVplex technology, optical genome mapping, and long-distance polymerase chain reaction were employed to characterize the breakpoints of the chromosomal rearrangements. Results Cases 1 and 2 exhibited FIX activities below 1%. Case 3 displayed FIX activities within the reference range. However, cases 4 and 5 showed a significant increase in FIX activities. Alu-mediated nonallelic homologous recombination was identified as the cause of F9 deletion in case 1; FoSTeS/MMBIR (Fork Stalling and Template Switching/microhomology-mediated break-induced replication) contributed to both F9 deletion and tandem duplication observed in cases 2 and 3; BIR/MMBIR (break-induced replication/microhomology-mediated break-induced replication) mediated by the same pair of low-copy repeats results in similar duplication–triplication/inversion–duplication (DUP–TRP/INV–DUP) rearrangements in cases 4 and 5, leading to complete F9 duplication and triplication, respectively. Conclusion Large deletions involving the F9 gene exhibit no apparent pattern, and the extra-hematologic clinical phenotypes require careful analysis of other genes within the deletion. The impact of complete F9 duplication and triplication on FIX expression might depend on the integrity of the F9 upstream sequence and the specific rearrangement mechanisms. Notably, DUP–TRP/INV–DUP rearrangements significantly elevate FIX activity and are closely associated with thrombotic phenotypes.

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Tandem and inverted duplications in haemophilia A: Breakpoint characterisation provides insight into possible rearrangement mechanisms

Cited by 3 publications

References 58 publications

A unifying model that explains the origins of human inverted copy number variants

A unifying model that explains the origins of human inverted copy number variants

A unifying model that explains the origins of human inverted copy number variants

Complete F9 Gene Deletion, Duplication, and Triplication Rearrangements: Implications for Factor IX Expression and Clinical Phenotypes

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