Anna Collin

Assessment of the clinical and molecular impact of different cytogenetic subgroups in a series of 272 lipomas with abnormal karyotype

Conventional lipomas harbor karyotypic changes that could be subdivided into four, usually mutually exclusive, categories: rearrangement, in particular through translocations, of chromosome bands 12q13‐15, resulting in deregulation of the HMGA2 gene, loss of material from or rearrangement of chromosome 13, supernumerary ring or giant marker chromosomes, and aberrations of chromosome band 6p21. In the present study, 272 conventional lipomas, two‐thirds of them deep‐seated, with acquired clonal chromosome changes were assessed with regard to karyotypic and clinical features. A nonrandom distribution of breakpoints and imbalances could be confirmed, with 83% of the cases harboring one or more of the previously known cytogenetic hallmarks. Correlation with clinical features revealed that lipomas with rings/giant markers were larger, occurred in older patients, were more often deep‐seated, and seemed to have an increased tendency to recur locally, compared with tumors with other chromosome aberrations. The possible involvement of the HMGA2 gene in cases that did not show any of the characteristic cytogenetic changes was further evaluated by locus‐specific metaphase fluorescence in situ hybridization (FISH) and RT‐PCR, revealing infrequent cryptic disruption of the gene but abundant expression of full length or truncated transcripts. By FISH, we could also show that breakpoints in bands 10q22‐23 do not affect the MYST4 gene, whereas breakpoints in 6p21 or 8q11‐12 occasionally target the HMGA1 or PLAG1 genes, respectively, also in conventional lipomas.

Array based characterization of a terminal deletion involving chromosome subband 15q26.2: an emerging syndrome associated with growth retardation, cardiac defects and developmental delay

BackgroundSubtelomeric regions are gene rich and deletions in these chromosomal segments have been demonstrated to account for approximately 2.5% of patients displaying mental retardation with or without association of dysmorphic features. However, cases that report de novo terminal deletions on chromosome arm 15q are rare.MethodsIn this study we present the first example of a detailed molecular genetic mapping of a de novo deletion in involving 15q26.2-qter, caused by the formation of a dicentric chromosome 15, using metaphase FISH and tiling resolution (32 k) genome-wide array-based comparative genomic hybridization (CGH).ResultsAfter an initial characterization of the dicentric chromosome by metaphase FISH, array CGH analysis mapped the terminal deletion to encompass a 6.48 megabase (Mb) region, ranging from 93.86–100.34 Mb on chromosome 15.ConclusionIn conclusion, we present an additional case to the growing family of reported cases with 15q26-deletion, thoroughly characterized at the molecular cytogenetic level. In the deleted regions, four candidate genes responsible for the phenotype of the patient could be delineated: IGFR1, MEF2A, CHSY1, and TM2D3. Further characterization of additional patients harboring similar 15q-aberrations might hopefully in the future lead to the description of a clear cut clinically recognizable syndrome.

Deletion of the SCN gene cluster on 2q24.4 is associated with severe epilepsy: An array-based genotype-phenotype correlation and a comprehensive review of previously published cases.

PURPOSE To characterize a deletion of chromosome 2q at the molecular level in a patient suffering from severe epilepsy resembling severe myoclonic epilepsy of infancy/Dravets syndrome (SMEI/DS) and to correlate other cases harboring deletions in the same region to morphological and clinical data. METHODS Array-based comparative genomic hybridization (array CGH) was performed on DNA from the patient. Forty-three previously published cases reporting deletions within region 2q21-q31 were collected and analyzed regarding their cytogenetic and clinical data. RESULTS A del(2)(q24.3q31.1) was detected in the patient, spanning a 10.4-megabase (Mb) region between 165.18 and 175.58Mb, harboring 47 genes. FISH analysis was performed, confirming this deletion. Twenty-two of the 43 previously published cases were seizure-positive. The most common dysmorphic features were ear abnormalities, microcephaly, micrognathia and brachysyndactyly for all patients as well as for solely the seizure-positive and -negative ones. For the 22 seizure-positive cases chromosome subband 2q24.3 constituted the smallest commonly deleted region among the majority of the cases, where subbands 2q22.1 and 2q33.3 represented the most proximal and distal breakpoint, respectively. CONCLUSIONS Based on the early age of presentation and the severity of the epilepsy reported for the majority of the seizure-positive cases it was concluded that SMEI/DS could be the epileptic encephalopathy associated with deletions within the 2q22.1-q33.3 region, due to haploinsuffiency of SCN1A and/or complete or partial deletion of other voltage-gated sodium channel genes caused by the aberration. Furthermore, our study supports that array CGH is a competent technique for screening SCN1A mutation-negative patients diagnosed with SMEI/DS-like epilepsies and dysmorphic features, generating rapid and high-resolution data of genomic imbalances present in the patients.

Creation of a library of induced pluritent stem cell models from Parkinsonian patients

Induced pluripotent stem cells (iPSCs) are becoming an important source of pre-clinical models for research focusing on neurodegeneration. They offer the possibility for better understanding of common and divergent pathogenic mechanisms of brain diseases. Moreover, iPSCs provide a unique opportunity to develop personalized therapeutic strategies, as well as explore early pathogenic mechanisms, since they rely on the use of patients’ own cells that are otherwise accessible only post-mortem, when neuronal death-related cellular pathways and processes are advanced and adaptive. Neurodegenerative diseases are in majority of unknown cause, but mutations in specific genes can lead to familial forms of these diseases. For example, mutations in the superoxide dismutase 1 gene lead to the motor neuron disease amyotrophic lateral sclerosis (ALS), while mutations in the SNCA gene encoding for alpha-synuclein protein lead to familial Parkinson’s disease (PD). The generations of libraries of familial human ALS iPSC lines have been described, and the iPSCs rapidly became useful models for studying cell autonomous and non-cell autonomous mechanisms of the disease. Here we report the generation of a comprehensive library of iPSC lines of familial PD and an associated synucleinopathy, multiple system atrophy (MSA). In addition, we provide examples of relevant neural cell types these iPSC can be differentiated into, and which could be used to further explore early disease mechanisms. These human cellular models will be a valuable resource for identifying common and divergent mechanisms leading to neurodegeneration in PD and MSA.

Clinical Variability of Waardenburg-Shah Syndrome in Patients With Proximal 13q Deletion Syndrome Including the Endothelin-B Receptor Locus

Waardenburg–Shah syndrome (Waardenburg syndrome type IV‐WS4) is an auditory‐pigmentary disorder that combines clinical features of pigmentary abnormalities of the skin, hair and irides, sensorineural hearing loss, and Hirschsprung disease (HSCR). Mutations in the endothelin‐B receptor (EDNRB) gene on 13q22 have been found to cause this syndrome. Mutations in both alleles cause the full phenotype, while heterozygous mutations cause isolated HSCR or HSCR with minor pigmentary anomalies and/or sensorineural deafness. We investigated the status of the EDNRB gene, by FISH analysis, in three patients with de novo proximal 13q deletions detected at cytogenetic analysis and examined the clinical variability of WS4 among these patients. Chromosome 13q was screened with locus specific FISH probes and breakpoints were determined at 13q22.1q31.3 in Patients 1 and 3, and at 13q21.1q31.3 in Patient 2. An EDNRB specific FISH probe was deleted in all three patients. All patients had common facial features seen in proximal 13q deletion syndrome and mild mental retardation. However, findings related to WS4 were variable; Patient 1 had hypopigmentation of the irides and HSCR, Patient 2 had prominent bicolored irides and mild bilateral hearing loss, and Patient 3 had only mild unilateral hearing loss. These data contribute new insights into the pathogenesis of WS4.

dup(19)(q12q13.2): array-based genotype-phenotype correlation of a new possibly obesity-related syndrome.

Small supernumerary marker chromosomes (sSMCs) derived from the near‐centromeric area of chromosome 2 are very rare. In addition, duplications of the 2p11.2→q11.2 region have displayed considerable variability between patients harboring and lacking clinical findings. Moreover, constitutional duplication of the 19q12→q13.2 region has previously only been described in two cases and was associated with delay of developmental milestones, corpus callosum anomalies, and obesity. Herein, we present a genotype–phenotype correlation in a patient harboring two sSMCs derived from chromosomes 2 and 14 or 22, respectively. The DNA was studied using G‐banding, fluorescence in situ hybridization techniques, and array‐based comparative genomic hybridization. A 48,XX,+der(2)del(2)(p11)del(2)(q11.2),+der(14)t(14;19)(q11;q12)del(19)(q13.31) or 48,XX,+der(2)del(2)(p11)del(2)(q11.2),+der(22)t(22;19)(q11;q12)del(19)(q13.31) was detected in the patient. The sSMC 14;19 or 22;19, with its centromere originating from either chromosome 14 or 22, encompassed a 13.56 megabase (Mb) 19q derived region, harboring 263 genes, and the sSMC 2 a 2.71 Mb region including 29 genes. The patient had symptoms including a ventral septal defect, bilateral grade IV urinary reflux, corpus callosum agenesis, microphthalmia, and obesity. The 19q segment contained the genes AKT2, CEACAM1, CEBPA, LIPE, and TGFB1 which are involved in adipose tissue homeostasis and insulin resistance, and could potentially contribute to the obese phenotype observed. Array‐based genetic characterization and long‐term clinical evaluation with attention toward weight gain in patients with chromosome 19q duplications might in the future lead to the description of a obesity‐associated genetic syndrome, something that could have implications in management and treatment of patients carrying a dup(19)(q12q13.2). Whether the der(2)(p11q11.2) contributes to the phenotype remains inconclusive.

Fusion of the FUS and CREB3L2 genes in a supernumerary ring chromosome in low-grade fibromyxoid sarcoma.

Low-grade fibromyxoid sarcoma (LGFMS) is a rare, low-grade malignant soft tissue tumor that is often mistaken for either benign or more malignant tumor types. Commonly, this tumor affects young adults and typically arises in the deep proximal extremities or trunk with frequent recurrences and can metastasize to the lungs many years later. Most cases have a recurrent balanced translocation involving chromosomes 7 and 16, t(7;16)(q32-34;p11), which leads to the fusion of the FUS and CREB3L2 genes. However, supernumerary ring chromosomes have been identified in a subset of FUS/CREB3L2-positive LGFMS, but it has not yet been formally demonstrated that such ring chromosomes harbor the FUS/CREB3L2 fusion gene. Here, we report the genetic findings of a supernumerary ring chromosome from an LGFMS from a 77-year-old man. Chromosome banding analysis revealed a supernumerary ring chromosome, and further studies with fluorescence in situ hybridization and reverse transcriptase-polymerase chain reaction (RT-PCR) showed that the ring contained material from chromosomes 7 and 16, that the FUS gene was present in two rearranged copies, and that it expressed the FUS/CREB3L2 fusion gene. Moreover, an assessment of previously reported cases showed that tumors with ring chromosomes relapsed more often than tumors with a balanced t(7;16), suggesting that ring formation in LGFMS is correlated with tumor progression.

Generation of an induced pluripotent stem cell line (CSC-41) from a Parkinson's disease patient carrying a p.G2019S mutation in the LRRK2 gene

The leucine-rich repeat kinase 2 (LRRK2) p.G2019S mutation is the most common genetic cause of Parkinsons disease (PD). An induced pluripotent stem cell (iPSC) line CSC-41 was generated from a 75-year old patient diagnosed with PD caused by a p.G2019S mutation in LRRK2. Skin fibroblasts were reprogrammed using a non-integrating Sendai virus-based technology to deliver OCT3/4, SOX2, c-MYC and KLF4 transcription factors. The generated iPSC line exhibits expression of common pluripotency markers, differentiates into the three germ layers and has a normal karyotype. The iPSC line can be used to explore the association between LRRK2 mutation and PD.

Generation of a human induced pluripotent stem cell line (CSC-42) from a patient with sporadic form of Parkinson's disease

Skin fibroblasts were collected from a 44-year-old patient with sporadic case of Parkinsons disease (PD). The non-integrating Sendai virus vector encoding OCT3/4, SOX2, c-MYC and KLF4 was used to reprogram fibroblasts into induced pluripotent stem cells (iPSCs). Generated iPSCs had normal karyotypes, expressed common stem cell markers, and were capable of differentiating into all three germ layers. Generated line could be used for PD modeling to understand the mechanisms that influence the disorder.

Generation of a human induced pluripotent stem cell line (CSC-40) from a Parkinson's disease patient with a PINK1 p.Q456X mutation

Parkinsons disease (PD) is a neurodegenerative disease with unknown etiology. Here we show the generation of an induced pluripotent stem cell (iPSC) line, named CSC-40, from dermal fibroblasts obtained from a 59-year-old male patient with a homozygous p.Q456X mutation in the PTEN-induced putative kinase 1 (PINK/PARK6) gene and a confirmed diagnosis of PD, which could be used to model familial PD. A non-integrating Sendai virus-based delivery of the reprogramming factors OCT3/4, SOX2, c-MYC and KLF4 was employed. The CSC-40 cell line showed normal karyotyping and fingerprinting following transduction as well as sustained expression of several pluripotency markers and the ability to differentiate into all three germ layers.