Long-read sequence analysis for clustered genomic copy number aberrations revealed architectures of intricately intertwined rearrangements.

Most chromosomal aberrations revealed by chromosomal microarray testing (CMA) are simple; however, very complex chromosomal structural rearrangements can also be found. Although the mechanism of structural rearrangements has been gradually revealed, not all mechanisms have been elucidated. We analyzed the breakpoint-junctions (BJs) of two or more clustered copy number variations (CNVs) in the same chromosome arms to understand their conformation and the mechanism of complex structural rearrangements. Combining CMA with long-read whole-genome sequencing (WGS) analysis, we successfully determined all BJs for the clustered CNVs identified in four patients. Multiple CNVs were intricately intertwined with each other, and clustered CNVs in four patients were involved in global complex chromosomal rearrangements. The BJs of two clustered deletions identified in two patients showed microhomologies, and their characteristics were explained by chromothripsis. In contrast, the BJs in the other two patients, who showed clustered deletions and duplications, consisted of blunt-end and nontemplated insertions. These findings could be explained only by alternative nonhomologous end-joining, a mechanism related to polymerase theta. All the patients had at least one inverted segment. Three patients showed cryptic aberrations involving a disruption and a deletion/duplication, which were not detected by CMA but were first identified by WGS. This result suggested that complex rearrangements should be considered if clustered CNVs are observed in the same chromosome arms. Because CMA has potential limitations in genotype-phenotype correlation analysis, a more detailed analysis by whole genome examination is recommended in cases of suspected complex structural aberrations.

Interstitial microdeletions of 3q26.2q26.31 in two patients with neurodevelopmental delay and distinctive features.

Interstitial microdeletions in the long arm of chromosome 3 are rare. In this study, we identified two patients with approximately 5-Mb overlapping deletions in the 3q26.2q26.31 region. Both patients showed neurodevelopmental delays, congenital heart defects, and distinctive facial features. One of them showed growth deficiency and brain abnormalities, as shown on a magnetic resonance imaging scan. Haploinsufficiency of NLGN1 and FNDC3B present in the common deletion region was considered to be responsible for neurodevelopmental delay and the distinctive features, respectively. The possibility of unmasked variants in PLD1 was considered and analyzed, but no possible pathogenic variant was found, and the mechanism of the congenital heart defects observed in the patients is unknown. Because 3q26.2q26.31 deletions are rare, more information is required to establish genotype-phenotype correlations associated with microdeletions in this region.

A recurrent de novo ZSWIM6 variant in a Japanese patient with severe neurodevelopmental delay and frequent vomiting.

A recurrent ZSWIM6 variant, NM_020928.2:c.2737C>T [p.Arg913*], was identified in a Japanese male patient with severe neurodevelopmental delay, epilepsy, distinctive facial features, microcephaly, growth deficiency, abnormal behavior, and frequent vomiting but without frontonasal or limb malformations. In this patient, distinctive facial features gradually became apparent with age, and severe vomiting caused by gastroesophageal reflux continued even after percutaneous endoscopic gastrostomy.

Deep intronic deletion in intron 3 of PLP1 is associated with a severe phenotype of Pelizaeus-Merzbacher disease.

Recently, altered PLP1 splicing was confirmed as a genetic cause of hypomyelination of early myelinating structures (HEMS). A novel deep intronic deletion in intron 3 of PLP1 (NM_000533.5: c.453+59_+259del) was identified, and an in vitro minigene assay detected abnormal splicing patterns. However, the clinical and radiological findings of the patient were compatible with a severe phenotype of Pelizaeus-Merzbacher disease rather than HEMS, which may be due to undetected abnormal PLP1 splicing.

Induced pluripotent stem cells established from a female patient with Xq22 deletion confirm that BEX2 escapes from X-chromosome inactivation.

Large deletions in Xq22 are responsible for neurodevelopmental disorders, including severe intellectual disability and behavioral abnormalities. Although the deletion regions contain PLP1, the gene related to Pelizaeus-Merzbacher disease (PMD), patients with Xq22 deletions show no clinical features of PMD such as paraplegia and white matter abnormalities. This could be due to skewed X-chromosome inactivation (XCI) occurring predominantly in the affected allele. Isogenic pairs of wild type and mutant induced pluripotent stem cells (iPSCs) were established from the patient. In the iPSC line in which the wild type allele was inactivated, PLP1 was not expressed, but biallelic expression of BEX2 was identified. This suggests that BEX2 escaped from XCI and haploinsufficiency of BEX2 may be related to the phenotype of Xq22 deletions.

Novel COL4A1 mutations identified in infants with congenital hemolytic anemia in association with brain malformations.

Genetic causes of undiagnosed hemolytic anemia in nineteen patients were analyzed by whole-exome sequencing, and novel COL4A1 variants were identified in four patients (21%). All patients were complicated with congenital malformations of the brain, such as porencephaly or schizencephaly. In these patients, hemolysis became less severe within 2 months after birth, and red cell transfusion was no longer required after 50 days, whereas chronic hemolysis continued.

Breakpoint junction analysis for complex genomic rearrangements with the caldera volcano-like pattern.

Chromosomal triplications can be classified into recurrent and nonrecurrent triplications. Most of the nonrecurrent triplications are embedded in duplicated segments, and duplication-inverted triplication-duplication (DUP-TRP/INV-DUP) has been established as one of the mechanisms of triplication. This study aimed to reveal the underlying mechanism of the TRP-DUP-TRP pattern of chromosomal aberrations, in which the appearance of moving averages obtained through array-based comparative genomic hybridization analysis is similar to the shadows of the caldera volcano-like pattern, which were first identified in two patients with neurodevelopmental disabilities. For this purpose, whole-genome sequencing using long-read Nanopore sequencing was carried out to confirm breakpoint junctions. Custom array analysis and Sanger sequencing were also used to detect all breakpoint junctions. As a result, the TRP-DUP-TRP pattern consisted of only two patterns of breakpoint junctions in both patients. In patient 1, microhomologies were identified in breakpoint junctions. In patient 2, more complex architectures with insertional segments were identified. Thus, replication-based mechanisms were considered as a mechanism of the TRP-DUP-TRP pattern.

Molecular Profiles of Breast Cancer in a Single Institution.

BACKGROUND/AIM: Historically, breast cancer has been treated according to an evaluation of biomarkers, such as the estrogen receptor and HER2 status. Recently, molecular profiling has been used to detect driver mutations and select anti-cancer treatment strategies. In addition to detecting pathogenic mutations, the total mutation count (tumor mutation burden) has been considered as another biomarker. MATERIALS AND METHODS: We performed molecular profiling of 143 breast cancer tissues obtained from resected tissues via surgical operation. RESULTS: Suspected germline mutations were detected in 10% of the patients with a higher somatic mutation ratio. CONCLUSION: As hypermutated breast cancers are more likely to benefit from certain anti-cancer treatment strategies, molecular profiling can be used as a biomarker.

Novel LAMA2 variants identified in a patient with white matter abnormalities.

Comprehensive genomic analysis was performed in a patient with mild psychomotor developmental delay, elevated creatine kinase, and white matter abnormalities. The results revealed biallelic pathogenic variants in the gene related to merosin-deficient congenital muscular dystrophy, NM_000426.3(LAMA2):c.1338_1339del [p.Gly447Phefs*7] and c.2749 + 2dup, which consist of compound heterozygous involvement with predicted loss-of-function and splicing abnormalities.

Complex chromosomal rearrangements of human chromosome 21 in a patient manifesting clinical features partially overlapped with that of Down syndrome.

The chromosomal region critical in Down syndrome has long been analyzed through genotype-phenotype correlation studies using data from many patients with partial trisomy 21. Owing to that, a relatively small region of human chromosome 21 (35.9 ~ 38.0 Mb) has been considered as Down syndrome critical region (DSCR). In this study, microarray-based comparative genomic hybridization analysis identified complex rearrangements of chromosome 21 in a patient manifesting clinical features partially overlapped with that of Down syndrome. Although the patient did not show up-slanting palpebral fissures and single transverse palmar creases, other symptoms were consistent with Down syndrome. Rearrangements were analyzed by whole-genome sequencing using Nanopore long-read sequencing. The analysis revealed that chromosome 21 was fragmented into seven segments and reassembled by six connected points. Among 12 breakpoints, 5 are located within the short region and overlapped with repeated segments. The rearrangement resulted in a maximum gain of five copies, but no region showed loss of genomic copy numbers. Breakpoint-junctions showed no homologous region. Based on these findings, chromoanasynthesis was considered as the mechanism. Although the distal 21q22.13 region was not included in the aberrant regions, some of the genes located on the duplicated regions, SOD1, SON, ITSN1, RCAN1, and RUNX1, were considered as possible candidate genes for clinical features of the patient. We discussed the critical region for Down syndrome, with the literature review.

Analyses of breakpoint junctions of complex genomic rearrangements comprising multiple consecutive microdeletions by nanopore sequencing.

The widespread use of genomic copy number analysis has revealed many previously unknown genomic structural variations, including some which are more complex. In this study, three consecutive microdeletions were identified in the same chromosome by microarray-based comparative genomic hybridization (aCGH) analysis for a patient with a neurodevelopmental disorder. Subsequent fluorescence in situ hybridization (FISH) analyses unexpectedly suggested complicated translocations and inversions. For better understanding of the mechanism, breakpoint junctions were analyzed by nanopore sequencing, as a new long-read whole-genome sequencing (WGS) tool. The results revealed a new chromosomal disruption, giving rise to four junctions in chromosome 7. According the sequencing results of breakpoint junctions, all junctions were considered as the consequence of multiple double-strand breaks and the reassembly of DNA fragments by nonhomologous end-joining, indicating chromothripsis. KMT2E, located within the deletion region, was considered as the gene responsible for the clinical features of the patient. Combinatory usage of aCGH and FISH analyses would be recommended for interpretation of structural variations analyzed through WGS.

Establishment of a simple and rapid method to detect MECP2 duplications using digital polymerase chain reaction.

Genomic copy number variations (CNVs) can be detected by chromosomal microarray testing. However, upon final diagnosis, other methods may be recommended for a validation method to confirm CNVs. Trio analyses or carrier detection in family members are also frequently required. Previously, fluorescence in situ hybridization and/or quantitative PCR have been used; however, these methods present limitations. The purpose of this study was to establish a simple and rapid method to detect genomic copy numbers. We utilized droplet digital PCR (dPCR) with an intercalation method. Thirteen patients, who were diagnosed with MECP2 duplications via chromosomal microarray testing, were enrolled in this study. Four of their female relatives, who were verified as carriers of MECP2 duplications, were also included. Genomic copy numbers of MECP2 and IRAK1 were analyzed in comparison with reference genes: XIST and AR on the X-chromosome, and RPP30 and RPPH1 on the autosomal chromosomes. As a result, genomic copy numbers of MECP2 were rapidly and precisely detected by the dPCR system established in this study. This method can be widely applied as a diagnostic method to confirm CNVs on other chromosomal regions.

Primrose syndrome associated with unclassified immunodeficiency and a novel ZBTB20 mutation.

Primrose syndrome is a congenital malformation syndrome characterized by intellectual disability, developmental delay, progressive muscle wasting, and ear lobe calcification. Mutations in the ZBTB20 gene have been established as being accountable for this syndrome. In this study, a novel de novo ZBTB20 mutation, NM_001164342.2:c.1945C>T (p.Leu649Phe), has been identified through whole exome sequencing (WES) in a female patient presenting a typical Primrose phenotype. Because the present patient exhibited recurrent otitis media, detailed immunological examinations were performed in this study and subnormal immunoglobulin levels were firstly identified in a Primrose patient. Anatomical anomaly of the inner ear has never been reported in this patient and WES data did not include any relevant variants causally linked with the immunologic defect. Thus, there is a possibility of a relation between an unclassified immunodeficiency with selective IgG2 deficiency and Primrose syndrome and this may be the reason of recurrent otitis media frequently observed in Primrose patients. Because subnormal levels of IgG2 in this patient might be caused by an unrelated and still uncharacterized genetic cause, further studies are required to prove the causal link between aberrant ZBTB20 function and immunodeficiency.

Advantages of ddPCR in detection of PLP1 duplications.

Pelizaeus-Merzbacher disease (PMD) is an X-linked, recessively inherited disorder associated with hypomyelination in the brain white matter. Mutations involving the proteolipid protein 1 gene (PLP1) located on Xq22.2 are responsible for PMD. PLP1 duplication is the major genetic abnormality in PMD patients. In this study, we utilized droplet-digital polymerase chain reaction (ddPCR) as a potential method to detect PLP1 duplications. Samples from four PMD patients and one of their mothers were used as positive controls. They had been previously diagnosed as having an additional PLP1 copy by chromosomal microarray testing. Genomic copy number of PLP1 was analyzed in triplicate experiments and compared with reference genes XIST and AR on the X-chromosome, and RPP30 and RPPH1 on the autosomes. As a result, precise results were obtained for each triplicate procedure. Thus, we concluded that triplicate experiments are no longer necessary. Compared to other methods, including fluorescence in-situ hybridization, multiplex ligation-dependent probe amplification, chromosomal microarray testing, and quantitative PCR, we were able to establish ddPCR results rapidly with very small amounts of DNA. In conclusion, we showed that ddPCR can be a potential diagnostic tool to confirm genomic copy number as a routine clinical application, including in prenatal diagnostic settings.

Genomic backgrounds of Japanese patients with undiagnosed neurodevelopmental disorders.

BACKGROUND: Recently, many genes related to neurodevelopmental disorders have been identified by high-throughput genomic analysis; however, a comprehensive understanding of the mechanism underlying neurodevelopmental disorders remains to be established. To further understand these underlying mechanisms, we performed a comprehensive genomic analysis of patients with undiagnosed neurodevelopmental disorders. METHODS: Genomic analysis using next-generation sequencing with a targeted panel was performed for a total of 133 Japanese patients (male/female, 81/52) with previously undiagnosed neurodevelopmental disorders, including developmental delay (DD), intellectual disability (ID), autism spectrum disorder (ASD), and epilepsy. Genomic copy numbers were also analyzed using the eXome Hidden Markov Model (XHMM). RESULTS: Thirty-nine patients (29.3%) exhibited pathogenic or likely pathogenic findings with single-gene variants or chromosomal aberrations. Among them, 20 patients were presented here. Pathogenic or likely pathogenic variants were identified in 18 genes, including ACTG1, CACNA1A, CHD2, CDKL5, DNMT3A, EHMT1, GABRB3, GABRG2, GRIN2B, KCNQ3, KDM5C, MED13L, SCN2A, SHANK3, SMARCA2, STXBP1, SYNGAP1, and TBL1XR1. CONCLUSION: A diagnostic yield of 29.3% in this study was nearly the same as that previously reported from other countries. Thus, we suggest that there is no difference in genomic backgrounds in Japanese patients with undiagnosed neurodevelopmental disabilities. Although most of the patients possessed de novo variants, one of the patients showed an X-linked inheritance pattern. As X-linked recessive disorders exhibit the possibility of recurrent occurrence in the family, comprehensive molecular diagnosis is important for genetic counseling.

Elucidation of the pathogenic mechanism and potential treatment strategy for a female patient with spastic paraplegia derived from a single-nucleotide deletion in PLP1.

Pelizaeus-Merzbacher disease (PMD) is an X-linked recessive disorder caused by abnormalities in the gene PLP1. Most females harboring heterozygous PLP1 abnormalities are basically asymptomatic. However, as a result of abnormal patterns of X-chromosome inactivation, it is possible for some female carriers to be symptomatic. Whole-exome sequencing of a female patient with unknown spastic paraplegia was performed to obtain a molecular diagnosis. As a result, a de novo heterozygous single-nucleotide deletion in PLP1 [NM_000533.5(PLP1_v001):c.783del; p.Thr262Leufs*20] was identified. RNA sequencing was performed in a patient-derived lymphoblastoid cell line, confirming mono-allelic expression of the mutated allele and abnormal inactivation of the wild-type allele. The patient-derived lymphoblastoid cell line was then treated with VX680 or 5azadC, which resulted in restored expression of the wild-type allele. These two agents thus have the potential to reverse inappropriately-skewed inactivation of the X-chromosome.

Phenotypic features of 1q41q42 microdeletion including WDR26 and FBXO28 are clinically recognizable: The first case from Japan.

1q41q42 microdeletion syndrome has been established in 2007. Since then, more than 17 patients have been reported so far. The reported deletions showed random breakpoints and deletion regions are aligned as roof tiles. Patients with 1q41q42 microdeletion syndrome show intellectual disability, seizures, and distinctive features. Many genotype-phenotype correlation studies have been performed and some genes included in this region have been suggested as potential candidate genes. Recently, de novo variants in WDR26 and FBXO28 were identified in patients who showed consistent phenotypes with 1q41q42 microdeletion syndrome. Thus, both genes are now considered as the genes possibly responsible for 1q41q42 microdeletion syndrome. Here, the first case of a Japanese patient with a de novo 1q41q42 microdeletion is reported. Owing to the distinctive features, this syndrome would be clinically recognizable.

Natural histories of patients with Wolf-Hirschhorn syndrome derived from variable chromosomal abnormalities.

Wolf-Hirschhorn syndrome (WHS) is a subtelomeric deletion syndrome affecting the short arm of chromosome 4. The main clinical features are a typical craniofacial appearance, growth deficiency, developmental delays, and seizures. Previous genotype-phenotype correlation analyses showed some candidate regions for each clinical finding. The WHS critical region has been narrowed into the region 2 Mb from the telomere, which includes LETM1 and WHSC1; however, this region is insufficient to cause "typical WHS facial appearance". In this study, we identified 10 patients with a deletion involving 4p16.3. Five patients showed pure terminal deletions and three showed unbalanced translocations. The remaining patients showed an interstitial deletion and a suspected inverted-duplication-deletion. Among 10 patients, one patient did not show "typical WHS facial appearance" although his interstitial deletion included LETM1 and WHSC1. On the other hand, another patient exhibited "typical WHS facial appearance" although her small deletion did not include LETM1 and WHSC1. Instead, FGFRL1 was considered as the candidate for this finding. The largest deletion of 34.7 Mb was identified in a patient with the most severe phenotype of WHS.

Three Japanese patients with 3p13 microdeletions involving FOXP1.

BACKGROUND: FOXP1 is known as the gene responsible for neurodevelopmental delay associated with language impairment. Broad clinical findings also include feeding difficulty, muscular hypotonia, and distinctive features. These findings are common between patients with loss-of-function mutations in FOXP1 and 3p13 microdeletion involving FOXP1. Thus, "FOXP1-related intellectual disability syndrome" is now recommended. METHODS: After obtaining informed consent, chromosomal microarray testing was performed for patients with unknown etiology. RESULTS: We identified three Japanese patients with 3p13 microdeletions involving FOXP1. One of the patients showed an additional 1q31.3q32.1 deletion as de novo, which was rather considered as a benign copy number variant. CONCLUSION: This is the first report of patients with 3p13 microdeletions from Japan. All patients showed growth delay, moderate to severe developmental delay, hearing loss, and distinctive facial features including prominent forehead and mid facial hypoplasia. In addition, "square shaped face" commonly observed in all three patients may be a characteristic finding undescribed previously. From the obtained findings, "FOXP1-related intellectual disability syndrome" was considered to be clinically recognizable.