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

• Introduction
• Methods
• Subjects
• Plasma Analysis
• Hemostasis and Thrombosis Gene Panel Analysis
• Optical Genome Mapping Analysis
• Long-Distance Polymerase Chain Reaction and Breakpoint Sequencing
• X-chromosome Inactivation Pattern Detecting
• Bioinformatic Analysis
• Results
• Case Reports
• Unravelling Chromosomal Rearrangements with Optical Genome Mapping
• Elucidating Breakpoint Sequences through Long-Distance Polymerase Chain Reaction
• Discussion
• References

Abstract

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.

Introduction

The F9 gene, located on the X-chromosome at position q27.1, spans 34 kb and consists of eight exons and seven introns. This gene encodes coagulation factor IX (FIX), which plays a crucial role in activating downstream coagulation factors and forming stable fibrin clots.[1] Deficiency of FIX, known as hemophilia B (HB), is an X-linked recessive bleeding disorder associated with reduced plasma FIX activity.[2] Conversely, elevated FIX levels have been identified as an essential risk factor for venous thromboembolism (VTE).[3] [4] [5] The risk of VTE is significantly increased in individuals with FIX levels exceeding 150%, showing a more than 3-fold increase compared with those within the reference range of FIX levels.[4] Furthermore, specific variants such as FIX Padua (p.Arg338Leu) and FIX Shanghai (p.Arg338Gln) have been identified as a cause of juvenile thrombophilia due to significantly increased FIX activity and excessive clotting risk.[6] [7]

The Factor IX Gene Variant Database (https://www.factorix.org/) serves as a comprehensive resource for F9 variants, encompassing 1692 unique variants documented from 5,358 individual case reports.[8] While a significant portion of these variants are point mutations, advancements in understanding chromosomal structural rearrangements have revealed an increasing proportion of larger structural variants (SVs). Among these SVs, the database identified 43 types of gross deletions, with complete deletion of the F9 gene observed in 92 patients across 36 articles.[8] In contrast, only four cases of gross duplications involving F9 have been reported, all of which entail partial duplications of specific exons (exons 1–6, exons 2–6, exons 4–6, and exons 5–8).[9] [10] [11] Deletions of the F9 gene often produce straightforward and severe consequences on FIX activity, leading to severe HB. However, the impact of these partial F9 duplications on FIX activity varies, with reported levels ranging from below 1 to 8% of normal activity levels.[11] Notably, complete duplications of the F9 gene have not been reported in this database, and the impact of whole-gene duplication on FIX expression remains unknown. Currently, most of the information regarding complete duplications of F9 is incidentally reported during studies on large X chromosomal rearrangements.[12] [13] [14] Unfortunately, there is a lack of available clinical phenotype information associated explicitly with bleeding and thrombotic manifestations in individuals with complete F9 duplications.

Understanding the specific breakpoints of F9-related SVs can provide valuable insight into the underlying rearrangement mechanisms and help to predict FIX expression and associated clinical phenotypes. Previous studies have suggested the involvement of DNA repair-based mechanisms, such as nonhomologous end joining and nonallelic homologous recombination (NAHR), and DNA replication-based mechanisms like Fork Stalling and Template Switching/microhomology-mediated break-induced replication (FoSTeS/MMBIR) in F9-related SVs.[15] [16] [17] However, recurrent NAHR rearrangements mediated by low-copy repeats (LCRs), similar to the intron 22 inversion of F8, have not been identified in structural rearrangements involving F9 to date.

The widespread adoption of next-generation sequencing (NGS) allows for the precise identification of some SV breakpoints by relying on the presence of chimeric reads spanning the junction. However, due to the limitations of short reads (150∼300 bp), NGS would generate ambiguous alignments in highly repetitive regions. Interestingly, these regions are more prone to forming SVs.[18] To overcome the limitations of NGS, long-read sequencing technologies such as PacBio and Oxford Nanopore Technologies have been commercialized and hold promise.[19] Nevertheless, the costs associated with achieving the necessary coverage levels for acceptable accuracy with long-read sequencing are exceedingly high, limiting their widespread use in breakpoint characterization. Recently, optical genome mapping (OGM) has recently emerged as a robust, high-throughput technology for detecting SVs.[20] OGM provides a more comprehensive and accurate analysis of SVs by directly analyzing long-range information from single DNA molecules. To date, OGM has been successfully applied in mapping SVs associated with hematologic malignancies, hemophilia A, and other genetic diseases.[21] [22]

In this study, we combined OGM with long-distance polymerase chain reaction (LD-PCR) techniques to characterize the breakpoints of two severe HB patients with complete F9 gene deletion and three VTE patients with complete F9 duplication and triplication. Our findings reveal a shared duplication–triplication/inversion–duplication (DUP–TRP/INV–DUP) rearrangements, resulting in F9 duplication and triplication in two unrelated families. Additionally, we elucidate the underlying structural basis of these rearrangements. To our knowledge, this is the first report of complete F9 duplication and triplication and their effects on FIX expression, which sheds crucial new light on F9-related SVs and their potential relationship with thrombotic phenotypes.

Methods

Subjects

Cases 1 and 2 belonged to the severe HB patients cohort admitted to the Beijing Children's Hospital from 2015 to 2022, who were previously reported to have a deletion spanning all eight exons of the F9 gene.[23] Cases 3, 4, and 5 belonged to the VTE patients cohort registered in Shanghai Ruijin Hospital from 2017 to 2023. They were identified with additional copies of the complete F9 gene through our Hemostasis and Thrombosis Gene Panel analysis. Informed consent was obtained from all patients and their families, and the study was approved by the Ethics Committee of Ruijin Hospital.

Plasma Analysis

Peripheral blood was collected from patients and their related family members using vacuum blood collection tubes containing 0.129 mol/L sodium citrate to obtain platelet-poor plasma. Coagulation factors activity levels, including FIX, were assessed using a one-stage clotting method on an automated ACL TOP analyzer (Instrumentation Laboratory, United States). FIX antigen levels were measured using an enzyme-linked immunosorbent assay following the manufacturer's instructions (Enzyme Research Laboratories, South Bend, Indiana, United States). Additional thrombophilia tests, including the activity levels of protein C (PC), protein S (PS), antithrombin III, and lupus anticoagulant, were performed as described previously.[24]

Hemostasis and Thrombosis Gene Panel Analysis

Five probands were subjected to the panel analysis, covering 33 genes associated with hemorrhage and thrombosis ([Supplementary Table S1], available in the online version). Copy number variants (CNVs) were evaluated using CNVplex technology, a high-throughput multiplex CNV analysis (Genesky Biotechnologies Inc., Shanghai, China).[25] Quantitative probes targeting the F9 gene can be found in [Supplementary Table S2] (available in the online version). Additionally, targeted next-generation sequencing was employed to detect mutations in the promoter region, 5′ and 3′ untranslated regions, coding sequence, and exon–intron boundaries of these genes. The identified mutations were further validated using Sanger sequencing in the probands and their remaining family members.

Optical Genome Mapping Analysis

High-molecular weight (HMW) DNA was extracted from the blood samples of five probands using the Bionano Prep SP Blood and Cell Culture DNA Isolation Kit (Bionano Genomics, United States). The integrity and size of extracted HMW DNA were confirmed by pulsed-field gel electrophoresis. The DNA backbone was stained overnight with the Bionano Prep DLS Kit, where the DLE-1 enzyme specifically recognized the CTTAAG base sequence on genomic DNA and labeled them with the DL-Green fluorophore group. Then, Bionano Saphyr Instruments imaged genomic DNA molecules on a chip containing up to 120,000 nanochannels, each detecting DL-Green fluorescent signals within the blue DNA background. High-resolution charge-coupled device cameras generated real-time imaging data for all nanochannels, automatically converting them into molecular data and integrating them into a genome-wide optical map. De novo assembly analysis was performed using Bionano access V1.7 software, focusing on SVs within the X-chromosome F9 gene and its nearby regions. Additionally, the Bionano software incorporates a database of SVs found in 180 phenotypically normal individuals, allowing for filtering SVs polymorphisms in the population.

Long-Distance Polymerase Chain Reaction and Breakpoint Sequencing

Genomic DNA was extracted using the QIAamp DNA blood purification kit (Qiagen, Venlo, The Netherlands). Based on the assembly results from Bionano, amplification primers were designed near the DL-Green fluorescent labels flanking the breakpoint. LD-PCR amplification was performed with the KOD One PCR Master Mix kit (TOYOBO, Shanghai, China) according to the manufacturer's instructions. The extension time was determined by the distance between the two fluorescent labels, with 5 seconds per kb for a range of 1 to 10 kb and 10 seconds per kb for over 10 kb. After confirming the formation of LD-PCR amplified productions through agarose gel electrophoresis, smaller-spaced sequencing primers were designed between the amplification primers for Sanger sequencing. The sequences of the amplification and sequencing primers are provided in [Supplementary Tables S3] and [S4] (available in the online version).

X-chromosome Inactivation Pattern Detecting

The methylation of androgen receptor (AR) and retinitis pigmentosa 2 (RP2) genes were analyzed to assess X-chromosome inactivation (XCI) patterns, as described previously.[26] Genomic DNA of peripheral blood lymphocytes from female individuals with F9 copy number variations was digested with the methylation-sensitive enzyme HhaI (New England Biolabs, United States). HhaI recognition sites are located near the CAG repeat region in AR, and the GAAA repeat region upstream of RP2. The digested DNA was amplified using specific fluorescent primers ([Supplementary Table S5], available in the online version) on the 2720 Thermal Cycler (Applied Biosystems, United States). Capillary electrophoresis was performed on the 3730xl genetic analyze (Applied Biosystems, United States) to analyze the amplified fragments. The peak fluorescence values for allele determination were calculated using the Gene Mapper 5.0 software (Applied Biosystems, United States). To eliminate the effect of allele length difference on the X-chromosome inactivation ratio (XCIR), the following formula was employed: XCIR = (d1/u1)/(d1/u1 + d2/u2), where d and u represent the peak fluorescence value corresponding to the genomic DNA after and before digestion, respectively.[27] Each XCIR value was calculated as an average of two replicate measurements.

Bioinformatic Analysis

Breakpoint analysis was performed using a sequencing alignment-based approach with the hg38 reference genome. Sanger sequencing data containing the breakpoints and potential LCRs near the breakpoints were analyzed using the Human BLAT Search Tool (http://genome.ucsc.edu/cgi-bin/hgBlat). The Repeat Masker Tool (www.repeatmasker.org) was used to identify repetitive elements flanking the breakpoint junction. This tool can identify well-known repetitive elements associated with rearrangement mechanisms, such as long interspersed nuclear elements, short interspersed nuclear elements (SINEs), long terminal repeats, and DNA transposons. To assess clinical relevance of the identified variants, we consulted five databases: dbVAR (https://www.ncbi.nlm.nih.gov/dbvar/), ClinVar (https://www.ncbi.nlm.nih.gov/clinvar/), HGMD (http://www.hgmd.cf.ac.uk/ac/index.php), gnomAD (https://gnomad.broadinstitute.org/), and PubMed (http://www.ncbi.nlm.nih.gov/pubmed).

Results

Case Reports

This study involved the analysis of five unrelated families comprising a total of 12 individuals with F9 copy number variations ([Table 1]).

Proband 1 and proband 2 presented with skin ecchymosis at around 6 months of age and were diagnosed with severe HB. During prothrombin complex concentrate infusion for prevention, both patients experienced allergic reactions in the form of rashes, which were effectively managed by suspending the infusion and employing appropriate desensitization therapy. No other abnormal clinical phenotypes were observed in either patient. Gene panel analysis revealed a complete deletion of the F9 gene in both patients, whereas their mothers were found to have only one copy of the F9 gene. Proband 1's mother reported a medical history including intractable epistaxis, menorrhagia, and gingival bleeding, and proband 2's mother reported excessive menstrual bleeding. Their FIX activity levels were only 22 and 12%, respectively. No additional mutations were found in the exonic regions and exon–intron boundaries of the F9 gene, and no extremely skewed XCI was observed in either case. Furthermore, gene panel analysis detected a heterozygous VWF p.Ala1500Val mutation in proband 2, which might lead to a diagnosis of type 1 von Willebrand disease.[28]

Proband 3 experienced sudden chest pain at 15 and was subsequently diagnosed with pulmonary embolism based on computed tomography angiography. At 17, he developed a sudden headache and epilepsy. Magnetic resonance imaging revealed cerebral venous sinus thrombosis (CVST). At 26, he developed mesenteric vein thrombosis. Subsequently, he received long-term anticoagulant therapy with warfarin. Gene panel analysis identified a heterozygous PROS1 p.Glu67Ala mutation in the patient, along with complete duplication of the F9 gene. Both the PROS1 variant and F9 gene duplication were inherited from his asymptomatic mother. Under treatment with warfarin, the activities of vitamin K-dependent coagulation factors, including FIX and PS, were significantly suppressed in the patient. However, as demonstrated by his mother, the PROS1 p.Glu67Ala mutation significantly reduced the PS activity, whereas the F9 duplication did not result in a notable increase in FIX activity ([Table 1]).

Proband 4 had a history of recurrent CVST involving the transverse sinus and right sigmoid sinuses. At 16, he experienced a brain hemorrhage in the left parietal lobe during one episode of CVST. Subsequently, the patient was prescribed warfarin treatment. Gene panel analysis revealed that the patient inherited both a duplication of the F9 gene and a heterozygous F5 p.Arg575Cys mutation from his asymptomatic mother. During warfarin therapy, the patient's FIX activity decreased to 62% of the normal level. However, his mother exhibited an elevated FIX activity of 177% due to the F9 gene duplication. Interestingly, the F5 variant present in proband 4 and his mother did not affect their factor V (FV) activity, which measured at 101 and 87%, respectively ([Table 1]).

Proband 5 was diagnosed with mesenteric vein, splenic vein, and bilateral iliac vein thrombosis at age 15 and underwent long-term treatment with rivaroxaban for thromboprophylaxis. However, despite the treatment, the patient's symptoms did not significantly improve. Gene panel analysis revealed that the patient, his mother, and his grandmother all carried a triplication of the F9 gene and a heterozygous PROC p.Asn384Ser mutation. After 1 week of drug discontinuation, protein activity assays were performed. While PC activity was within the normal range for his mother and grandmother, his PC activity was slightly below the lower limit of the normal range, measuring at 63%. Additionally, the three patients exhibited significantly elevated FIX activity due to the F9 triplication. FIX activity levels ranged from 182 to 247% ([Table 1]).

Unravelling Chromosomal Rearrangements with Optical Genome Mapping

To determine the specific size and orientation of the rearranged regions, we conducted an OGM analysis on five cases ([Fig. 1]). Results revealed that the deletion region in case 1 reached 2.88 Mb, affecting 13 OMIM genes, including F9. In case 2, the deletion fragment was smaller, measuring 0.20 Mb and involving exons 2 to 26 of the MCF2 gene and complete F9 gene ([Table 2]).

Case 3 exhibited a duplicated fragment with a length of 0.43 Mb, encompassing three complete OMIM genes: F9, MCF2, and ATP11C. Furthermore, OGM matching results only exhibited a single breakpoint, suggesting a tandem orientation for this duplication. Notably, cases 4 and 5 displayed similar rearrangement patterns, referred to as DUP–TRP/INV–DUP rearrangements ([Fig. 1C]). In brief, a triplicated fragment was inserted in reverse orientation onto the same chromosome through two breakpoints. Interestingly, the downstream duplicated regions were completely identical, suggesting a shared rearrangement mechanism. We identified a pair of inverted LCRs (designated LCR-F9A and LCR-F9B, respectively) with approximately 16 kb length in this region. This pair of LCRs contained three highly homologous core sequences with over 98.5% identity: XIRT-31240, XIRT-31246, and XIRT-31253.[29] Within the 0.23 Mb region between LCR-F9A and LCR-F9B in both cases 4 and 5, duplications were observed, but this region did not contain any OMIM genes. The difference between the two cases was that the triplication region extended 0.27 Mb upstream of LCR-F9A in case 4 but 0.51 Mb in case 5, respectively. Additionally, there was another duplicated region with a length of 0.27 and 0.05 Mb on the other side of the triplicated regions, respectively ([Fig. 1]). The F9 gene was located 0.46 Mb upstream of LCR-F9A, explaining why case 5 exhibited F9 triplication, whereas case 4 only had an F9 duplication.

Elucidating Breakpoint Sequences through Long-Distance Polymerase Chain Reaction

To determine the nucleotide sequences at the breakpoints and the specific rearrangement mechanisms, we designed LD-PCR primers to amplify the rearranged regions containing the breakpoint junctions ([Fig. 2]). In cases 1 and 2, the P1F/P1R and P2F/P2R primers were designed to target the upstream and downstream regions of the deletion, respectively. For case 3, the forward primer was designed downstream of the F9 gene, whereas the reverse primer was designed upstream of the F9 gene. In cases 4 and 5, where the breakpoint junctions were inverted, both LCRs9A and LCRs9B primers were created on the DNA positive strand, whereas both P4F/P4R and P5F/P5R primers were designed on the DNA negative strand. These primer design strategies would result in PCR products in individuals carrying F9-related rearrangements but no product in the healthy controls.

The sequencing results across breakpoint junctions are shown in [Fig. 3] and [Supplementary Fig. S1] (available in the online version). In case 1, the breakpoint region exhibited approximately 86% identity with a homologous sequence spanning around 120 bp. Repeat Masker analysis revealed that both sequences constituting the breakpoint, ChrX:139282455–139282768 and ChrX:142160680–142160800, belong to SINEs, specifically AluY and AluSx subfamily, respectively. These two elements together formed a chimeric Alu element, mediating a 2.88Mb deletion encompassing F9. In contrast, no repetitive element was detected at the breakpoints of F9 deletion in case 2 and F9 duplication in case 3, with the two chromosome regions being joined solely by a 3 bp microhomology sequence. As predicted by OGM analysis, cases 4 and 5 shared the same breakpoint, resulting from a rearrangement mediated by the hybrid LCRs element formed by LCR-F9A and LCR-F9B. Due to the length (16 kb) and high similarity (95%) between LCR-F9A and LCR-F9B, Sanger sequencing could not determine the exact rearrangement breakpoints. Therefore, the rearrangement was confirmed by a specific 17 kb PCR product unique to the LCR-F9A/LCR-F9B recombination. Different positions were observed for the other breakpoints involved in the DUP–TRP/INV–DUP rearrangement in cases 4 and 5. Again, no repetitive element was identified, and only 2 and 4-bp microhomology sequence was found at the breakpoint junction.

Discussion

Breakpoint characterization provides crucial information for understanding rearrangement mechanisms. In case 1, we identified a chimeric Alu element at the breakpoint, resulting from NAHR between an AluSx and an AluY element. The 2.88Mb chromosomal segment between these two Alu elements was deleted during recombination ([Fig. 4A]). The rearrangements observed in cases 2 and 3 exhibit more random breakpoints flanked by only 3-bp microhomology sequences. Replication-based mechanisms such as FoSTeS/MMBIR can explain this phenomenon ([Fig. 4B]): during DNA replication, when replication fork stalling or breakage occurs, the lagging strand disengages from the original template switches to another template via microhomology and restarts DNA synthesis.[30] When invading a new template downstream of the replication fork, a deletion similar to case 2 is generated; conversely, switching to an upstream template results in the observed tandem duplication in case 3.[31] Furthermore, these dissociations and invasions can occur multiple times.[32] As shown in case 3, the first template switch leads to a 35-bp skipping at the breakpoint, whereas the second template switch results in a tandem duplication, including the complete F9 gene ([Fig. 3]).

Remarkably, we have identified similar DUP–TRP/INV–DUP rearrangements in cases 4 and 5, which are mediated by a pair of inverted LCRs. Similar DUP–TRP/INV–DUP rearrangements facilitated by inverted LCRs have been observed in other genes, such as MECP2, DMD, and PLP1.[33] [34] [35] The proposed mechanism involves two template switches during the DNA replication process ([Fig. 4C]): the first template switch occurs between inverted LCRs via break-induced replication, reversing the replication direction. 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. This variability can result in no change, duplication, or triplication of the F9 gene ([Fig. 4C]).

Understanding the mechanisms underlying SVs facilitates clinical interpretation and further risk prediction. The complete F9 deletions in probands 1 and 2 explain their reduced FIX activity and diagnosis of severe HB. According to Radic et al patients develop extra-hematologic phenotypes such as partial hypopituitarism, intellectual disability, and developmental delay when the deletion region encompasses the SOX3 gene.[15] However, proband 1 had a chromosomal deletion affecting multiple genes, including SOX3, but did not exhibit any unique medical history records beyond HB. One possible explanation could be attributed to compensatory mechanisms within the genome that can mitigate the functional loss of the SOX3 gene. Furthermore, some phenotypes may only manifest in adulthood,[37] whereas proband 1 is only 5 years old. Another noteworthy fact in cases 1 and 2 is that their mothers, both had low FIX activity despite the absence of skewed XCI. Interestingly, we found four additional female HB patients (FIX: Ac: 10–20%) with only F9 gene deletions in different literature sources, one of whom had undergone XCI analysis in peripheral blood leukocytes, also showing no evidence of skewed XCI.[38] [39] One possible explanation could be that the XCI patterns observed in a peripheral blood sample do not necessarily align with the pattern observed in the liver.[40] Another more intriguing hypothesis is that the expression of the F9 gene on the normal chromosome is repressed by the other chromosome with large deletion.

Unlike deletions directly affecting protein expression and function, complete gene duplications are expected to enhance protein expression through a dosage effect. The intuitive hypothesis would suggest that duplication and triplication of F9 would lead to a doubling or tripling of FIX expression levels. However, our findings indicated that the F9 tandem duplication in case 3 did not significantly increase FIX activity; only the additional F9 copies, generated by the DUP–TRP/INV–DUP rearrangement, showed a notable increase in FIX activity in cases 4 and 5. Interestingly, compared with F9 duplication in case 4, the triplication of F9 in case 5 did not exhibit a markedly higher FIX activity. These observations suggest that FIX expression might be influenced by regulatory mechanisms beyond the F9 gene.

Further investigation of the genomic breakpoints revealed potential structural differences. F9 triplication in case 5 includes the upstream 32- and 80-kb regions of the F9 gene, and F9 duplication in case 4 encompasses the upstream 65-kb region. However, the duplication region in case 3 only extends up to 7-kb upstream ([Fig. 2]). In addition, we reported an F9 partial duplication in a mild HB patient before.[11] Despite retaining an intact F9 gene, the patient exhibited FIX levels of only 8%. Breakpoint analysis showed this duplication contained only a 13-kb upstream sequence extension of the intact F9 gene. Therefore, we speculate the presence of long-range gene regulatory elements like enhancers between the 32- and 65-kb region upstream of the F9 gene. Despite being far from the target gene, these elements may engage in looping interactions with the F9 gene promoter.[41] [42] In other words, the additional F9 copies can achieve sufficient expression only when the duplicated segments retain these long-range regulatory interactions. Johnsen et al conducted sequencing of the F9 coding regions, splice sites, and 300-bp upstream and 1417-bp downstream untranslated sequences in 1,616 HB patients, revealing that 31 patients still could not receive a definitive genetic diagnosis.[43] Although deep intronic variation remains to be examined, we suggest detecting long-range gene regulatory elements upstream of the F9 gene may also provide some diagnostic value.

Elevated FVIII, FIX, and FXI levels have been identified as a common risk factor for VTE.[3] [4] [44] [45] Previous studies have shown that additional copies of the F8 gene are associated with increased FVIII levels and an augmented VTE risk.[44] Similarly, duplication of the F11 gene leads to elevated plasma levels of FXI and an increased susceptibility to VTE.[45] The ISTH Gold Variants project reported a patient with complete F9 duplication who also experienced recurrent thrombosis, yet details regarding FIX levels or the specific duplication rearrangement were not provided.[46] Recently, Turkut et al reported a 554-kb X-chromosome duplication encompassing the F9 gene, contributing to the elevated FIX activity level and subsequent cerebral venous thrombosis development.[47] Our study provides further evidence that the duplication or triplication of the F9 gene may result in the upregulation of FIX expression, thereby contributing to the manifestation of thrombotic phenotypes. Furthermore, like HB, extra copies of the F9 gene tend to have a greater impact on males than on female carriers. Theoretically, if the expression of the F9 gene on a single X-chromosome is doubled, the plasma FIX levels in females would only increase to 150% due to the presence of a normal X-chromosome and random inactivation providing dosage compensation,[48] rather than the theoretical 200% in males. This may explain why clinical manifestations are predominantly observed in affected males within families exhibiting elevated FIX activity.[6] [7] [47]

Of note, the pathogenesis of thrombosis is complex, involving multiple genetic and environmental elements.[3] In our study, tandem F9 duplication in case 3 did not significantly elevate FIX levels. Instead, it is possible that the patient's coexisting PROS1 (p.Glu67Ala) mutation, a hotspot mutation in the Chinese population leading to type 1 PS deficiency,[24] may be the actual cause of the patient's thrombophilia phenotype. Additionally, the thrombotic phenotypes observed in probands 4 and 5 could be attributed to the combined effects of increased F9 copy number and coexisting heterozygous mutations in F5 (p.Arg575Cys) and PROC (p.Asn384Ser). F5 (p.Arg575Cys) has not been previously reported. Although the associated FV activity in case 4 was within the normal range, F5 (p.Arg575Cys) was predicted to be “disease causing” by online bioinformatics tools (SIFT, PolyPhen-2 and Mutation taster, [Supplementary Table S6], available in the online version). It is worth noting that although F5 (p.Arg575Cys) does not belong to any known activated protein C (APC) resistance-associated site,[49] the introduced cysteine residue may potentially form additional disulfide bonds and influence APC binding and hydrolysis through conformational changes, thereby increasing the risk for VTE. Similarly, PROC (p.Asn384Ser) only slightly reduced the PC activity in proband 5, but PROC (p.Asn384Lys) has been reported in thrombosis patients with PC levels at the lower limit of the normal range.[50] Therefore, these mutations may have contributed to thrombus formation alongside elevated FIX activity.

In conclusion, our study comprehensively characterized SVs breakpoints in five unrelated families, exhibiting deletions, duplications, and triplications encompassing the F9 gene. Using OGM technology, we have provided the first report on DUP–TRP/INV–DUP rearrangements that result in F9 duplication and triplication. Additionally, we analyzed the impact of increased F9 copy number on FIX expression and clinical phenotypes. These findings have important implications for the clinical management and risk assessment of individuals with F9 duplications and triplications, particularly those with a history of thrombosis.

Conflict of Interest

None declared.

Authors' Contribution

Y.M. and Y.L. designed and performed the experiments and contributed to the writing of the manuscript. J.S., Q.L., and R.W., collected and organized the clinical cases. Q.D. and J.D. analyzed the data, reviewed and revised the manuscript, and provided supervision for the entire project.

^* These authors contributed equally as co-first authors.

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• 17 Nakamura Y, Ando Y, Takagi Y. et al. Distinct X chromosomal rearrangements in four haemophilia B patients with entire F9 deletion. Haemophilia 2016; 22 (03) 433-439
  CrossrefPubMedGoogle Scholar
• 18 Onishi-Seebacher M, Korbel JO. Challenges in studying genomic structural variant formation mechanisms: the short-read dilemma and beyond. BioEssays 2011; 33 (11) 840-850
  CrossrefPubMedGoogle Scholar
• 19 Mantere T, Kersten S, Hoischen A. Long-read sequencing emerging in medical genetics. Front Genet 2019; 10: 426
  CrossrefPubMedGoogle Scholar
• 20 Yuan Y, Chung CY, Chan TF. Advances in optical mapping for genomic research. Comput Struct Biotechnol J 2020; 18: 2051-2062
  CrossrefPubMedGoogle Scholar
• 21 Smith AC, Neveling K, Kanagal-Shamanna R. Optical genome mapping for structural variation analysis in hematologic malignancies. Am J Hematol 2022; 97 (07) 975-982
  CrossrefPubMedGoogle Scholar
• 22 Fahiminiya S, Oikonomopoulos S, Rivard GE. et al. Deciphering a novel complex inversion affecting F8 in a family with severe haemophilia A by optical genome mapping. Haemophilia 2023; 29 (03) 921-924
  CrossrefPubMedGoogle Scholar
• 23 Liu G, Sun J, Li Z, Chen Z, Wu W, Wu R. F9 mutations causing deletions beyond the serine protease domain confer higher risk for inhibitor development in hemophilia B. Blood 2023; 141 (06) 677-680
  CrossrefPubMedGoogle Scholar
• 24 Li L, Wu X, Wu W, Ding Q, Cai X, Wang X. Clinical Manifestation and Mutation Spectrum of 53 Unrelated Pedigrees with Protein S Deficiency in China. Thromb Haemost 2019; 119 (03) 449-460
  Article in Thieme ConnectPubMedGoogle Scholar
• 25 Cao P, Yang A, Wang R. et al. Germline duplication of SNORA18L5 increases risk for HBV-related hepatocellular carcinoma by altering localization of ribosomal proteins and decreasing levels of p53. Gastroenterology 2018; 155 (02) 542-556
  CrossrefPubMedGoogle Scholar
• 26 Miranda-Furtado CL, Luchiari HR, Chielli Pedroso DC. et al. Skewed X-chromosome inactivation and shorter telomeres associate with idiopathic premature ovarian insufficiency. Fertil Steril 2018; 110 (03) 476-485.e1
  CrossrefPubMedGoogle Scholar
• 27 Dardik R, Avishai E, Lalezari S. et al. Molecular mechanisms of skewed X-chromosome inactivation in female hemophilia patients-lessons from wide genome analyses. Int J Mol Sci 2021; 22 (16) 9074
  CrossrefPubMedGoogle Scholar
• 28 Veyradier A, Boisseau P, Fressinaud E. et al; French Reference Center for von Willebrand disease. A laboratory phenotype/genotype correlation of 1167 French patients from 670 families with von Willebrand disease: a new epidemiologic picture. Medicine (Baltimore) 2016; 95 (11) e3038
  CrossrefPubMedGoogle Scholar
• 29 Dittwald P, Gambin T, Gonzaga-Jauregui C. et al. Inverted low-copy repeats and genome instability–a genome-wide analysis. Hum Mutat 2013; 34 (01) 210-220
  CrossrefPubMedGoogle Scholar
• 30 Zhang F, Khajavi M, Connolly AM, Towne CF, Batish SD, Lupski JR. The DNA replication FoSTeS/MMBIR mechanism can generate genomic, genic and exonic complex rearrangements in humans. Nat Genet 2009; 41 (07) 849-853
  CrossrefPubMedGoogle Scholar
• 31 Burssed B, Zamariolli M, Bellucco FT, Melaragno MI. Mechanisms of structural chromosomal rearrangement formation. Mol Cytogenet 2022; 15 (01) 23
  CrossrefPubMedGoogle Scholar
• 32 Lee JA, Carvalho CM, Lupski JR. A DNA replication mechanism for generating nonrecurrent rearrangements associated with genomic disorders. Cell 2007; 131 (07) 1235-1247
  CrossrefPubMedGoogle Scholar
• 33 Carvalho CM, Ramocki MB, Pehlivan D. et al. Inverted genomic segments and complex triplication rearrangements are mediated by inverted repeats in the human genome. Nat Genet 2011; 43 (11) 1074-1081
  CrossrefPubMedGoogle Scholar
• 34 Ishmukhametova A, Chen JM, Bernard R. et al. Dissecting the structure and mechanism of a complex duplication-triplication rearrangement in the DMD gene. Hum Mutat 2013; 34 (08) 1080-1084
  CrossrefPubMedGoogle Scholar
• 35 Bahrambeigi V, Song X, Sperle K. et al. Distinct patterns of complex rearrangements and a mutational signature of microhomeology are frequently observed in PLP1 copy number gain structural variants. Genome Med 2019; 11 (01) 80
  CrossrefPubMedGoogle Scholar
• 36 Li Y, Ding B, Mao Y, Zhang H, Wang X, Ding Q. Tandem and inverted duplications in haemophilia A: breakpoint characterisation provides insight into possible rearrangement mechanisms. Haemophilia 2023; 29 (04) 1121-1134
  CrossrefPubMedGoogle Scholar
• 37 Anson DS, Blake DJ, Winship PR, Birnbaum D, Brownlee GG. Nullisomic deletion of the mcf.2 transforming gene in two haemophilia B patients. EMBO J 1988; 7 (09) 2795-2799
  CrossrefPubMedGoogle Scholar
• 38 Jourdy Y, Chatron N, Carage ML. et al. Study of six patients with complete F9 deletion characterized by cytogenetic microarray: role of the SOX3 gene in intellectual disability. J Thromb Haemost 2016; 14 (10) 1988-1993
  CrossrefPubMedGoogle Scholar
• 39 Stoof SCM, Kersseboom R, de Vries FAT, Kruip MJHA, Kievit AJA, Leebeek FWG. Hemophilia B in a female with intellectual disability caused by a deletion of Xq26.3q28 encompassing the F9. Mol Genet Genomic Med 2018; 6 (06) 1220-1224
  CrossrefPubMedGoogle Scholar
• 40 Mason JA, Robertson JD. Extreme skewing of X-inactivation: rethinking severe haemophilia in women and girls. Haemophilia 2019; 25 (04) e286-e287
  CrossrefPubMedGoogle Scholar
• 41 Sanyal A, Lajoie BR, Jain G, Dekker J. The long-range interaction landscape of gene promoters. Nature 2012; 489 (7414) 109-113
  CrossrefPubMedGoogle Scholar
• 42 Yao L, Berman BP, Farnham PJ. Demystifying the secret mission of enhancers: linking distal regulatory elements to target genes. Crit Rev Biochem Mol Biol 2015; 50 (06) 550-573
  CrossrefPubMedGoogle Scholar
• 43 Johnsen JM, Fletcher SN, Dove A. et al. Results of genetic analysis of 11 341 participants enrolled in the My Life, Our Future hemophilia genotyping initiative in the United States. J Thromb Haemost 2022; 20 (09) 2022-2034
  CrossrefPubMedGoogle Scholar
• 44 Shen W, Gu Y, Zhu R, Zhang L, Zhang J, Ying C. Copy number variations of the F8 gene are associated with venous thromboembolism. Blood Cells Mol Dis 2013; 50 (04) 259-262
  CrossrefPubMedGoogle Scholar
• 45 Van Laer C, Peerlinck K, Jacquemin M. et al. F11 gene duplication causes elevated FXI plasma levels and is a risk for venous thrombosis. Thromb Haemost 2022; 122 (06) 1058-1060
  Article in Thieme ConnectPubMedGoogle Scholar
• 46 Megy K, Downes K, Morel-Kopp MC. et al. GoldVariants, a resource for sharing rare genetic variants detected in bleeding, thrombotic, and platelet disorders: communication from the ISTH SSC Subcommittee on Genomics in Thrombosis and Hemostasis. J Thromb Haemost 2021; 19 (10) 2612-2617
  CrossrefPubMedGoogle Scholar
• 47 Turkut Tan T, Pariltay E, Avci Durmusaliogu E. et al. A unique case of thrombophilia: the role of F9 gene duplication and increased factor IX activity in cerebral venous thrombosis. J Thromb Haemost 2023; 21 (10) 2913-2916
  CrossrefPubMedGoogle Scholar
• 48 Fang H, Deng X, Disteche CM. X-factors in human disease: impact of gene content and dosage regulation. Hum Mol Genet 2021; 30 (R2): R285-R295
  CrossrefPubMedGoogle Scholar
• 49 Kujovich JL. Factor V Leiden thrombophilia. Genet Med 2011; 13 (01) 1-16
  CrossrefPubMedGoogle Scholar
• 50 Rovida E, Merati G, D'Ursi P. et al. Identification and computationally-based structural interpretation of naturally occurring variants of human protein C. Hum Mutat 2007; 28 (04) 345-355
  CrossrefPubMedGoogle Scholar

Address for correspondence

Publication History

Received: 08 September 2023

Accepted: 21 November 2023

Accepted Manuscript online:
27 November 2023

Article published online:
26 December 2023

© 2023. The Author(s). This is an open access article published by Thieme under the terms of the Creative Commons Attribution-NonDerivative-NonCommercial License, permitting copying and reproduction so long as the original work is given appropriate credit. Contents may not be used for commercial purposes, or adapted, remixed, transformed or built upon. (https://creativecommons.org/licenses/by-nc-nd/4.0/)

Georg Thieme Verlag KG
Rüdigerstraße 14, 70469 Stuttgart, Germany

• References

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• 18 Onishi-Seebacher M, Korbel JO. Challenges in studying genomic structural variant formation mechanisms: the short-read dilemma and beyond. BioEssays 2011; 33 (11) 840-850
  CrossrefPubMedGoogle Scholar
• 19 Mantere T, Kersten S, Hoischen A. Long-read sequencing emerging in medical genetics. Front Genet 2019; 10: 426
  CrossrefPubMedGoogle Scholar
• 20 Yuan Y, Chung CY, Chan TF. Advances in optical mapping for genomic research. Comput Struct Biotechnol J 2020; 18: 2051-2062
  CrossrefPubMedGoogle Scholar
• 21 Smith AC, Neveling K, Kanagal-Shamanna R. Optical genome mapping for structural variation analysis in hematologic malignancies. Am J Hematol 2022; 97 (07) 975-982
  CrossrefPubMedGoogle Scholar
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  CrossrefPubMedGoogle Scholar
• 23 Liu G, Sun J, Li Z, Chen Z, Wu W, Wu R. F9 mutations causing deletions beyond the serine protease domain confer higher risk for inhibitor development in hemophilia B. Blood 2023; 141 (06) 677-680
  CrossrefPubMedGoogle Scholar
• 24 Li L, Wu X, Wu W, Ding Q, Cai X, Wang X. Clinical Manifestation and Mutation Spectrum of 53 Unrelated Pedigrees with Protein S Deficiency in China. Thromb Haemost 2019; 119 (03) 449-460
  Article in Thieme ConnectPubMedGoogle Scholar
• 25 Cao P, Yang A, Wang R. et al. Germline duplication of SNORA18L5 increases risk for HBV-related hepatocellular carcinoma by altering localization of ribosomal proteins and decreasing levels of p53. Gastroenterology 2018; 155 (02) 542-556
  CrossrefPubMedGoogle Scholar
• 26 Miranda-Furtado CL, Luchiari HR, Chielli Pedroso DC. et al. Skewed X-chromosome inactivation and shorter telomeres associate with idiopathic premature ovarian insufficiency. Fertil Steril 2018; 110 (03) 476-485.e1
  CrossrefPubMedGoogle Scholar
• 27 Dardik R, Avishai E, Lalezari S. et al. Molecular mechanisms of skewed X-chromosome inactivation in female hemophilia patients-lessons from wide genome analyses. Int J Mol Sci 2021; 22 (16) 9074
  CrossrefPubMedGoogle Scholar
• 28 Veyradier A, Boisseau P, Fressinaud E. et al; French Reference Center for von Willebrand disease. A laboratory phenotype/genotype correlation of 1167 French patients from 670 families with von Willebrand disease: a new epidemiologic picture. Medicine (Baltimore) 2016; 95 (11) e3038
  CrossrefPubMedGoogle Scholar
• 29 Dittwald P, Gambin T, Gonzaga-Jauregui C. et al. Inverted low-copy repeats and genome instability–a genome-wide analysis. Hum Mutat 2013; 34 (01) 210-220
  CrossrefPubMedGoogle Scholar
• 30 Zhang F, Khajavi M, Connolly AM, Towne CF, Batish SD, Lupski JR. The DNA replication FoSTeS/MMBIR mechanism can generate genomic, genic and exonic complex rearrangements in humans. Nat Genet 2009; 41 (07) 849-853
  CrossrefPubMedGoogle Scholar
• 31 Burssed B, Zamariolli M, Bellucco FT, Melaragno MI. Mechanisms of structural chromosomal rearrangement formation. Mol Cytogenet 2022; 15 (01) 23
  CrossrefPubMedGoogle Scholar
• 32 Lee JA, Carvalho CM, Lupski JR. A DNA replication mechanism for generating nonrecurrent rearrangements associated with genomic disorders. Cell 2007; 131 (07) 1235-1247
  CrossrefPubMedGoogle Scholar
• 33 Carvalho CM, Ramocki MB, Pehlivan D. et al. Inverted genomic segments and complex triplication rearrangements are mediated by inverted repeats in the human genome. Nat Genet 2011; 43 (11) 1074-1081
  CrossrefPubMedGoogle Scholar
• 34 Ishmukhametova A, Chen JM, Bernard R. et al. Dissecting the structure and mechanism of a complex duplication-triplication rearrangement in the DMD gene. Hum Mutat 2013; 34 (08) 1080-1084
  CrossrefPubMedGoogle Scholar
• 35 Bahrambeigi V, Song X, Sperle K. et al. Distinct patterns of complex rearrangements and a mutational signature of microhomeology are frequently observed in PLP1 copy number gain structural variants. Genome Med 2019; 11 (01) 80
  CrossrefPubMedGoogle Scholar
• 36 Li Y, Ding B, Mao Y, Zhang H, Wang X, Ding Q. Tandem and inverted duplications in haemophilia A: breakpoint characterisation provides insight into possible rearrangement mechanisms. Haemophilia 2023; 29 (04) 1121-1134
  CrossrefPubMedGoogle Scholar
• 37 Anson DS, Blake DJ, Winship PR, Birnbaum D, Brownlee GG. Nullisomic deletion of the mcf.2 transforming gene in two haemophilia B patients. EMBO J 1988; 7 (09) 2795-2799
  CrossrefPubMedGoogle Scholar
• 38 Jourdy Y, Chatron N, Carage ML. et al. Study of six patients with complete F9 deletion characterized by cytogenetic microarray: role of the SOX3 gene in intellectual disability. J Thromb Haemost 2016; 14 (10) 1988-1993
  CrossrefPubMedGoogle Scholar
• 39 Stoof SCM, Kersseboom R, de Vries FAT, Kruip MJHA, Kievit AJA, Leebeek FWG. Hemophilia B in a female with intellectual disability caused by a deletion of Xq26.3q28 encompassing the F9. Mol Genet Genomic Med 2018; 6 (06) 1220-1224
  CrossrefPubMedGoogle Scholar
• 40 Mason JA, Robertson JD. Extreme skewing of X-inactivation: rethinking severe haemophilia in women and girls. Haemophilia 2019; 25 (04) e286-e287
  CrossrefPubMedGoogle Scholar
• 41 Sanyal A, Lajoie BR, Jain G, Dekker J. The long-range interaction landscape of gene promoters. Nature 2012; 489 (7414) 109-113
  CrossrefPubMedGoogle Scholar
• 42 Yao L, Berman BP, Farnham PJ. Demystifying the secret mission of enhancers: linking distal regulatory elements to target genes. Crit Rev Biochem Mol Biol 2015; 50 (06) 550-573
  CrossrefPubMedGoogle Scholar
• 43 Johnsen JM, Fletcher SN, Dove A. et al. Results of genetic analysis of 11 341 participants enrolled in the My Life, Our Future hemophilia genotyping initiative in the United States. J Thromb Haemost 2022; 20 (09) 2022-2034
  CrossrefPubMedGoogle Scholar
• 44 Shen W, Gu Y, Zhu R, Zhang L, Zhang J, Ying C. Copy number variations of the F8 gene are associated with venous thromboembolism. Blood Cells Mol Dis 2013; 50 (04) 259-262
  CrossrefPubMedGoogle Scholar
• 45 Van Laer C, Peerlinck K, Jacquemin M. et al. F11 gene duplication causes elevated FXI plasma levels and is a risk for venous thrombosis. Thromb Haemost 2022; 122 (06) 1058-1060
  Article in Thieme ConnectPubMedGoogle Scholar
• 46 Megy K, Downes K, Morel-Kopp MC. et al. GoldVariants, a resource for sharing rare genetic variants detected in bleeding, thrombotic, and platelet disorders: communication from the ISTH SSC Subcommittee on Genomics in Thrombosis and Hemostasis. J Thromb Haemost 2021; 19 (10) 2612-2617
  CrossrefPubMedGoogle Scholar
• 47 Turkut Tan T, Pariltay E, Avci Durmusaliogu E. et al. A unique case of thrombophilia: the role of F9 gene duplication and increased factor IX activity in cerebral venous thrombosis. J Thromb Haemost 2023; 21 (10) 2913-2916
  CrossrefPubMedGoogle Scholar
• 48 Fang H, Deng X, Disteche CM. X-factors in human disease: impact of gene content and dosage regulation. Hum Mol Genet 2021; 30 (R2): R285-R295
  CrossrefPubMedGoogle Scholar
• 49 Kujovich JL. Factor V Leiden thrombophilia. Genet Med 2011; 13 (01) 1-16
  CrossrefPubMedGoogle Scholar
• 50 Rovida E, Merati G, D'Ursi P. et al. Identification and computationally-based structural interpretation of naturally occurring variants of human protein C. Hum Mutat 2007; 28 (04) 345-355
  CrossrefPubMedGoogle Scholar

• Supplementary Material