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.

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.

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.

Neurological manifestations of 2q31 microdeletion syndrome.

Microdeletion of 2q31 involving the HOXD gene cluster is a rare syndrome. The deletion of the HOXD gene cluster is thought to result in skeletal anomalies in these patients. HOX genes encode highly conserved transcription factors that control cell fate and the regional identities along the primary body and limb axes. We experienced a new patient with 2q31 microdeletion encompassing the HOXD gene cluster and some neighboring genes including the ZNF385B. The patient showed digital anomalies, growth failure, epileptic seizures, and intellectual disability. Magnetic resonance imaging showed delayed myelination and low signal intensity in the basal ganglia. The ZNF385B is a zinc finger protein expressed in brain. Disruption of ZNF385B was suspected to be responsible for the neurological features of this syndrome.

Concurrent occurrence of an inherited 16p13.11 microduplication and a de novo 19p13.3 microdeletion involving MAP2K2 in a patient with developmental delay, distinctive facial features, and lambdoid synostosis.

A female patient presented with developmental delay, distinctive facial features, and congenital anomalies, including a heart defect and premature lambdoid synostosis. The patient showed a paternally inherited 16p13.11 microduplication and a de novo 19p13.3 microdeletion involving the mitogen-activated protein kinase kinase 2 gene (MAP2K2), in which mutations cause the cardio-facio-cutaneous (CFC) syndrome. Reports of patients with overlapping 19p13.3 microdeletions of this region describe similar clinical manifestations including distinctive facial features: prominent forehead, horizontal/down-slanting palpebral fissures, long midface, pointed chin/angular jaw, sparse eyebrows, and underdeveloped cheekbones. Some of these findings overlapped to that of the patients with 16p13.11 microduplications and CFC syndrome. Although craniosynostosis was occasionally observed in patients with dominant-negative mutations in RAS/MAP kinase signaling genes (RASopathies) related to CFC syndrome, it was also reported in two patients with 16p13.11 microduplications. Genetic contributions of both chromosomal aberrations were discussed.

Loss-of-function mutations and global rearrangements in GPC3 in patients with Simpson-Golabi-Behmel syndrome.

Simpson-Golabi-Behmel syndrome is a congenital malformation syndrome associated with mutations in GPC3, which is located in the Xq26 region. Three new loss-of-function mutations and a global X-chromosome rearrangement involving GPC3 were identified. A female sibling of the patient, who presented with a cleft palate and hepatoblastoma, carries the same chromosomal rearrangement and a paradoxical pattern of X-chromosome inactivation. These findings support variable GPC3 alterations, with a possible mechanism in female patients.

A 16q12.2q21 deletion identified in a patient with developmental delay, epilepsy, short stature, and distinctive features.

Interstitial deletions of the 16q centromeric region are rarely reported. A microdeletion of the 16q12.2q21 region was identified in a patient with intellectual disability, epilepsy, short stature, and distinctive features; including up-slanting palpebral fissures, hypertelorism, epicanthic folds, anteverted nares, simple philtrum, thin upper lip vermilion, high arched palate, posteriorly rotated ears, and overlapping toes in his right foot. Although the deleted region includes the genes responsible for neurological impairments (GNOA1, GPR56, KATNB1, and BBS2), haploinsufficiency of these genes would not be associated with the patient's phenotype. When NDRG4, present in the deleted region, was knocked out in mice, these mice exhibited spatial learning deficits. Thus, we hypothesize that this gene could be a potential candidate underlying the neurological observations of the patient. Because RSPRY1 was been discovered as the cause of progressive skeletal dysplasia, a loss of this gene might explain the skeletal defects observed in the patient.

A novel TUBB3 mutation in a sporadic patient with asymmetric cortical dysplasia.

Recent advances in molecular technology have led to the discovery of several genes related to human malformations of cortical development (MCDs). The beta-tubulin class III gene (TUBB3) was identified as a gene responsible for MCDs. Although mouse-model experiments have not revealed any findings of neuronal migration disorders, human TUBB3 mutations have been identified in patients with congenital fibrosis of the extraocular muscles. Since the discovery of a TUBB3 mutation, only 15 mutations have been identified. In this study, comprehensive mutation screening through next-generation sequencing identified a novel TUBB3 mutation (p.Ser230Leu) in a sporadic patient with moderate developmental delay associated with mild MCD. Compared to patients with the alpha-tubulin class 1a gene (TUBA1A) mutations, patients with TUBB3 mutations show milder phenotypic manifestations and milder MCD. Therefore, patients with milder MCD manifestations may be under-diagnosed, and TUBB3 mutations may be rarely identified. Additional genotype-phenotype information should be accumulated for further understanding of the TUBB3 functional relevance.

Leukoencephalopathy associated with 11q24 deletion involving the gene encoding hepatic and glial cell adhesion molecule in two patients.

Leukoencephalopathies are heterogeneous entities with white matter abnormalities. Mutations of the gene encoding hepatic and glial cell adhesion molecule (HEPACAM) located on 11q24 are related to one of the leukoencephalopathies: megalencephalic leukoencephalopathy with subcortical cysts type 2 (MLC2). Genomic copy number aberrations were analyzed by microarray comparative hybridization for two patients. One patient who presented with abnormal intensity of the white matter had been previously been diagnosed with the typical genotype and phenotype of Jacobsen syndrome due to an 11q subtelomere deletion, which was further characterized here. In a second patient who exhibited the characteristic finding of leukoencephalopathy, an interstitial deletion of 11q24 was also identified. HEPACAM was involved in both deletions. We therefore suggest that haploinsufficiency of HEPACAM, a gene previously associated with the features of MLC2 and located on the overlapping deletion region between the two patients, might be related to the observed white matter abnormalities.

Characteristics of 2p15-p16.1 microdeletion syndrome: Review and description of two additional patients.

Many new microdeletion syndromes have been characterized in the past decade, including 2p15-p16.1 microdeletion syndrome. More than 10 patients with this syndrome have been described. Recently, we encountered two additional patients with 2p15-p16.1 microdeletion syndrome. All patients showed variable degrees of intellectual disability, with the autistic features characteristic of this syndrome. Seven out of 16 patients (44%) showed structural abnormalities in the brain, which is also an important feature of this syndrome. The shortest region of microdeletion overlap among the patients includes two genes, USP34 and XPO1. Although these genes have some functional relevance to cancer, they have not been associated with neurological functions. Diagnosis of additional patients with 2p15-p16.1 microdeletion syndrome and identification of pathogenic mutations in this region will help identify the genes responsible for the neurological features of the syndrome.

Holoprosencephaly with cerebellar vermis hypoplasia in 13q deletion syndrome: Critical region for cerebellar dysgenesis within 13q32.2q34.

We describe two unrelated patients with terminal deletions in the long arm of chromosome 13 showing brain malformation consisting of holoprosencephaly and cerebellar vermis hypoplasia. Array comparative genomic hybridization analysis revealed a pure terminal deletion of 13q31.3q34 in one patient and a mosaic ring chromosome with 13q32.2q34 deletion in the other. Mutations in ZIC2, located within region 13q32, cause holoprosencephaly, whereas the 13q32.2q32.3 region is associated with cerebellar vermis hypoplasia (Dandy-Walker syndrome). The rare concurrence of these major brain malformations in our patients provides further evidence that 13q32.2q32.3 deletion, harboring ZIC2 and ZIC5, leads to cerebellar dysgenesis.

Narrowing of the responsible region for severe developmental delay and autistic behaviors in WAGR syndrome down to 1.6 Mb including PAX6, WT1, and PRRG4.

Interstitial deletions of the 11p13 region are known to cause WAGR (Wilms tumor, aniridia, genitourinary malformation, and "mental retardation") syndrome, a contiguous gene deletion syndrome due to haploinsufficiencies of the genes in this region, including WT1 and PAX6. Developmental delay and autistic features are major complications of this syndrome. Previously, some genes located in this region have been suggested as responsible for autistic features. In this study, we identified two patients who showed the chromosomal deletions involving 11p13. Patient 1, having an 8.6 Mb deletion of chr11p14.1p12:29,676,434-38,237,948, exhibited a phenotype typical of WAGR syndrome and had severe developmental delay and autistic behaviors. On the other hand, Patient 2 had a larger aberration region in 11p14.1-p12 which was split into two regions, that is, a 2.2-Mb region of chr11p14.1: 29,195,161-31,349,732 and a 10.5-Mb region of chr11p13p12: 32,990,627-43,492,580. As a consequence, 1.6 Mb region of the WAGR syndrome critical region was intact between the two deletions. This patient showed no symptom of WAGR syndrome and no autistic behaviors. Therefore, the region responsible for severe developmental delay and autistic features on WAGR syndrome can be narrowed down to the region remaining intact in Patient 2. Thus, the unique genotype identified in this study suggested that haploinsufficiencies of PAX6 or PRRG4 included in this region are candidate genes for severe developmental delay and autistic features characteristic of WAGR syndrome.

MLC1 mutations in Japanese patients with megalencephalic leukoencephalopathy with subcortical cysts.

Megalencephalic leukoencephalopathy with subcortical cysts (MLC) is an autosomal recessive neurological disorder manifesting early onset macrocephaly and delayed-onset neurological deterioration. Characteristic radiological findings revealed by brain magnetic resonance imaging are the most important factors for obtaining a clinical diagnosis. In this study, we analyzed the causative gene, MLC1, in seven unrelated Japanese patients. The most common mutation in our study was p.S93L; this mutation was observed in 11 alleles (78.6%). The second most common mutation, p.A275D, was observed in two alleles (14.3%). A novel single-nucleotide deletion, c.578delG (p.V194Sfs*2), was identified in one allele. As the clinical severities of patients with MLC were variable even among those sharing identical genotypes, this condition may be modified by environmental factors, modifier genes or epigenetic factors.

Microdeletions of 5.5 Mb (4q13.2-q13.3) and 4.1 Mb (7p15.3-p21.1) associated with a saethre-chotzen-like phenotype, severe intellectual disability, and autism.

We observed a patient with a Saethre-Chotzen-like phenotype with severe neurological features. Saethre-Chotzen syndrome (acrocephalosyndactyly type III; SCS; OMIM #101400) is an autosomal dominant craniosynostosis syndrome characterized by craniofacial and mild limb abnormalities. The phenotypic features of chromosomal microdeletions involving the 7p21.1, where the twist homolog 1 gene (TWIST1) responsible for SCS is located, are recognized as a contiguous gene deletion syndrome with SCS and other phenotypic manifestations. In this study, we identified microdeletions in 4q13.2 and 7p21.1 in a patient with SCS and severe neurological features including developmental delay and autistic behavior. In comparison to other SCS patients with intragenic mutations or small deletions in 7p21.1, neurological features seen in this patient were extremely severe, likely modified by a concurrent deletion of 4q13.2. Both microdeletions were de novo and paternal in origin. Further information on such concurrent chromosomal deletions should be accumulated for better understanding of the mechanism.

Clinical manifestations of Xq28 functional disomy involving MECP2 in one female and two male patients.

Subtelomeric imbalances are a frequent cause of cytogenetic abnormalities in patients with unexplained intellectual disability. Functional disomy of Xq28 involving the methyl-CpG-binding protein 2 gene (MECP2) has been observed mostly in subtelomeric duplications. We identified three patients with functional disomy of Xq28. A female patient showed an unbalanced translocation between 12q24.33 and Xq28. Two male patients showed an unbalanced translocation between Xq27.1- Yq11.22 and a recombinant X-chromosome containing duplicated material from Xq27.1 on Xp telomere, respectively. All three patients exhibited severe developmental delay, hypotonia, seizures, and distinctive facial features, including flat nasal bridge and hypertelorism. Additionally, brain magnetic resonance imaging (MRI) showed characteristic findings in each patient, including frontal dominant brain atrophy and hypoplasia of the corpus callosum, which are common findings in patients with functional disomies of Xq28 and interstitial duplications of Xq28, including MECP2. Brain MRI revealed a cystic lesion in the periventricular white matter in a patient, similar to our previous experience in patients with MECP2 duplication syndrome. Thus, white matter abnormalities may frequently be seen in cases of patients with additional MECP2 copies. © 2013 Wiley Periodicals, Inc.

MECP2 duplication syndrome in both genders.

BACKGROUND: Duplications involving the methyl-CpG-binding protein 2 gene (MECP2) locus at Xq28 have been frequently identified in male patients who exhibit a phenotype unique from that of Rett syndrome, which is mainly characterized by severe mental retardation, recurrent infections, and epilepsy. This combination of features is recognized as MECP2 duplication syndrome. METHODS: Genomic copy number was investigated for patients with unexplained mental retardation, and phenotypic features of the patients having interstitial duplications including MECP2 were analyzed. RESULTS: Three male and one female patients with MECP2 duplication were identified. The phenotypic features of all the four patients were compatible with MECP2 duplication syndrome. The X-chromosome inactivation (XCI) pattern was analyzed in the female patient, identifying a skewed XCI that activated the X-chromosome containing the MECP2 duplication. Her mother possessed the same MECP2 duplication and a random XCI pattern but exhibited no phenotypic features, indicating a nonsymptomatic carrier. The brain magnetic resonance imaging revealed periventricular cystic lesions in all four patients, including the female patient. CONCLUSION: This study suggested clinical implications of the MECP2 duplication syndrome not only in the male but also in female patients with unexplained mental retardation.

Whole-exome sequencing of a unique brain malformation with periventricular heterotopia, cingulate polymicrogyria and midbrain tectal hyperplasia.

We report a case of an infant with unique and unreported combinations of brain anomalies. The patient showed distinctive facial findings, severe delay in psychomotor development, cranial nerve palsy and seizures. Brain magnetic resonance imaging performed at 5 days of age revealed complex brain malformations, including heterotopia around the mesial wall of lateral ventricles, dysmorphic cingulate gyrus, and enlarged midbrain tectum. The patient unexpectedly died at 13 months of age. Postmortem pathological findings included a polymicrogyric cingulate cortex, periventricular nodular heterotopia, basal ganglia and thalamic anomalies, and dysmorphic midbrain tectum. Potential candidate genes showed no abnormalities by traditional PCR-based sequencing. Whole-exome sequencing confirmed the presence of novel gene variants for filamin B (FLNB), guanylate binding protein family member 6, and chromosome X open reading frame 59, which adapt to the autosomal recessive mode or X-linked recessive mode. Although immunohistochemical analysis confirmed the expression of FLNB protein in the vessel walls and white matter in autopsied specimens, there may be functional relevance of the compound heterozygous FLNB variants during brain development.

Challenges in genetic counseling because of intra-familial phenotypic variation of oral-facial-digital syndrome type 1.

Oral-facial-digital syndrome type 1 (OFD1; MIM 311200) is characterized by multiple anomalies of the oral cavity, face and digits. We report a family with OFD1, where two female siblings and their mother shared the same mutation of the responsible gene (OFD1) c.1193_1196delAATC. Phenotypic variability was observed among them; the mother showed minimal features of OFD1, whereas her two daughters showed partial features and the full spectrum of OFD1, respectively. Thus, OFD1 was suspected only after a health check-up during pregnancy of the second patient showing fetal brain anomaly and maternal polycystic kidney. For these reasons, there was a delay in the recognition of OFD1 in this family. Patients with OFD1 show phenotypic variability, which poses challenges for genetic counseling.

Novel nucleotide mutation leading to a recurrent amino acid alteration in SH3BP2 in a patient with cherubism.

Cherubism is a rare genetic disorder characterized by progressive facial deformity caused by non-neoplastic bone lesions in the mandible and/or the maxilla. Src homology-3 binding protein 2 gene (SH3BP2) has been found to be the responsible gene, with alterations in six amino acids noted in patients with this condition. Recently, mutations in this domain have been found to cause stabilization of SH3BP2 by uncoupling with tankyrase. In this study, we identified a new 2-bp mutation that led to a recurrent amino acid change in a sporadic case of cherubism. Our findings indicate that it is important to understand the pattern of progress in typical cherubism.

A de novo interstitial deletion of 8p11.2 including ANK1 identified in a patient with spherocytosis, psychomotor developmental delay, and distinctive facial features.

The contiguous gene syndrome involving 8p11.2 is recognized as a combined phenotype of both Kallmann syndrome and hereditary spherocytosis, because the genes responsible for these 2 clinical entities, the fibroblast growth factor receptor 1 (FGFR1) and ankyrin 1 (ANK1) genes, respectively, are located in this region within a distance of 3.2Mb. We identified a 3.7Mb deletion of 8p11.2 in a 19-month-old female patient with hereditary spherocytosis. The identified deletion included ANK1, but not FGFR1, which is consistent with the absence of any phenotype or laboratory findings of Kallmann syndrome. Compared with the previous studies, the deletion identified in this study was located on the proximal end of 8p, indicating a pure interstitial deletion of 8p11.21. This patient exhibited mild developmental delay and distinctive facial findings in addition to hereditary spherocytosis. Thus, some of the genes included in the deleted region would be related to these symptoms.