Your search keyword '"Bak, Mads"' showing total 8 results

1. Aggressiveness of non-EMT breast cancer cells relies on FBXO11 activity

Author

Bagger, Sofie Otzen, Hopkinson, Branden Michael, Pandey, Deo Prakash, Bak, Mads, Brydholm, Andreas Vincent, Villadsen, Rene, Helin, Kristian, Rønnov-Jessen, Lone, Petersen, Ole William, and Kim, Jiyoung

Published

2018

2. Cryptic breakpoint identified by whole-genome mate-pair sequencing in a rare paternally inherited complex chromosomal rearrangement

Author

Aristidou, Constantia, Theodosiou, Athina, Ketoni, Andria, Bak, Mads, Mehrjouy, Mana M., Tommerup, Niels, and Sismani, Carolina

Published

2018

3. Elevation of brain-enriched miRNAs in cerebrospinal fluid of patients with acute ischemic stroke.

Author

Sørensen, Sofie Sølvsten, Nygaard, Ann-Britt, Carlsen, Anting Liu, Heegaard, Niels H. H., Bak, Mads, and Christensen, Thomas

Published

2017

4. Identification of the BRD1 interaction network and its impact on mental disorder risk.

Author

Fryland, Tue, Christensen, Jane H., Pallesen, Jonatan, Mattheisen, Manuel, Palmfeldt, Johan, Bak, Mads, Grove, Jakob, Demontis, Ditte, Blechingberg, Jenny, Hong Sain Ooi, Nyegaard, Mette, Hauberg, Mads E., Tommerup, Niels, Gregersen, Niels, Mors, Ole, Corydon, Thomas J., Nielsen, Anders L., and Børglum, Anders D.

Subjects

BROMODOMAIN-containing 1 gene, MENTAL illness risk factors, PATHOLOGICAL psychology -- Risk factors, CHROMATIN, NEURAL development, SCHIZOPHRENIA

Abstract

Background: The bromodomain containing 1 (BRD1) gene has been implicated with transcriptional regulation, brain development, and susceptibility to schizophrenia and bipolar disorder. To advance the understanding of BRD1 and its role in mental disorders, we characterized the protein and chromatin interactions of the BRD1 isoforms, BRD1-S and BRD1-L. Methods: Stable human cell lines expressing epitope tagged BRD1-S and BRD1-L were generated and used as discovery systems for identifying protein and chromatin interactions. Protein-protein interactions were identified using co-immunoprecipitation followed by mass spectrometry and chromatin interactions were identified using chromatin immunoprecipitation followed by next generation sequencing. Gene expression profiles and differentially expressed genes were identified after upregulating and downregulating BRD1 expression using microarrays. The presented functional molecular data were integrated with human genomic and transcriptomic data using available GWAS, exome-sequencing datasets as well as spatiotemporal transcriptomic datasets from the human brain. Results: We present several novel protein interactions of BRD1, including isoform-specific interactions as well as proteins previously implicated with mental disorders. By BRD1-S and BRD1-L chromatin immunoprecipitation followed by next generation sequencing we identified binding to promoter regions of 1540 and 823 genes, respectively, and showed correlation between BRD1-S and BRD1-L binding and regulation of gene expression. The identified BRD1 interaction network was found to be predominantly co-expressed with BRD1 mRNA in the human brain and enriched for pathways involved in gene expression and brain function. By interrogation of large datasets from genome-wide association studies, we further demonstrate that the BRD1 interaction network is enriched for schizophrenia risk. Conclusion: Our results show that BRD1 interacts with chromatin remodeling proteins, e.g. PBRM1, as well as histone modifiers, e.g. MYST2 and SUV420H1. We find that BRD1 primarily binds in close proximity to transcription start sites and regulates expression of numerous genes, many of which are involved with brain development and susceptibility to mental disorders. Our findings indicate that BRD1 acts as a regulatory hub in a comprehensive schizophrenia risk network which plays a role in many brain regions throughout life, implicating e.g. striatum, hippocampus, and amygdala at mid-fetal stages. [ABSTRACT FROM AUTHOR]

Published

2016

5. Genome-wide DNA methylation analysis of transient neonatal diabetes type 1 patients with mutations in ZFP57.

Author

Bak, Mads, Boonen, Susanne E., Dahl, Christina, Hahnemann, Johanne M. D., Mackay, Deborah J. D. G., Tümer, Zeynep, Grønskov, Karen, Temple, Karen, Guldberg, Per, and Tommerup, Niels

Subjects

*TYPE 1 diabetes, *DIABETES, *FETAL growth retardation, *TYPE 2 diabetes, *PEOPLE with diabetes, *DNA methylation

Abstract

Background: Transient neonatal diabetes mellitus 1 (TNDM1) is a rare imprinting disorder characterized by intrautering growth retardation and diabetes mellitus usually presenting within the first six weeks of life and resolves by the age of 18 months. However, patients have an increased risk of developing diabetes mellitus type 2 later in life. Transient neonatal diabetes mellitus 1 is caused by overexpression of the maternally imprinted genes PLAGL1 and HYMAI on chromosome 6q24. One of the mechanisms leading to overexpression of the locus is hypomethylation of the maternal allele of PLAGL1 and HYMAI. A subset of patients with maternal hypomethylation at PLAGL1 have hypomethylation at additional imprinted loci throughout the genome, including GRB10, ZIM2 (PEG3), MEST (PEG1), KCNQ1OT1 and NESPAS (GNAS-AS1). About half of the TNDM1 patients carry mutations in ZFP57, a transcription factor involved in establishment and maintenance of methylation of imprinted loci. Our objective was to investigate whether additional regions are aberrantly methylated in ZFP57 mutation carriers. Methods: Genome-wide DNA methylation analysis was performed on four individuals with homozygous or compound heterozygous ZFP57 mutations, three relatives with heterozygous ZFP57 mutations and five controls. Methylation status of selected regions showing aberrant methylation in the patients was verified using bisulfite-sequencing. Results: We found large variability among the patients concerning the number and identity of the differentially methylated regions, but more than 60 regions were aberrantly methylated in two or more patients and a novel region within PPP1R13L was found to be hypomethylated in all the patients. The hypomethylated regions in common between the patients are enriched for the ZFP57 DNA binding motif. Conclusions: We have expanded the epimutational spectrum of TNDM1 associated with ZFP57 mutations and found one novel region within PPP1R13L which is hypomethylated in all TNDM1 patients included in this study. Functional studies of the locus might provide further insight into the etiology of the disease. [ABSTRACT FROM AUTHOR]

Published

2016

6. The segregation of different submicroscopic imbalances underlying the clinical variability associated with a familial karyotypically balanced translocation.

Author

Fonseca, Ana Carolina S., Bonaldi, Adriano, Fonseca, Simone A. S., Otto, Paulo A., Kok, Fernando, Bak, Mads, Tommerup, Niels, and Vianna-Morgante, Angela M.

Subjects

KARYOTYPES, CHROMOSOMES, CHROMOSOMAL translocation, MUSCLE dysmorphia, BODY dysmorphic disorder

Abstract

Background: About 7 % of karyotypically balanced chromosomal rearrangements (BCRs) are associated with congenital anomalies due to gene or regulatory element disruption, and cryptic imbalances on rearranged chromosomes. Rare familial BCRs segregating with clinical features are a powerful source for the identifying of causative genes due to the presence of several affected carriers. Case presentation: We report on a karyotypically balanced translocation t(2;22)(p13;q12.2) associated with variable learning disabilities, and craniofacial and hand dysmorphisms, detected in six individuals in a three-generation family. Combined a-CGH, FISH and mate-pair sequencing revealed a ten-break complex rearrangement, also involving chromosome 5. As the consequence of the segregation of the derivative chromosomes der(2), der(5) and der(22), different imbalances were present in affected and clinically normal family members, thus contributing to the clinical variability. A 6.64 Mb duplication of a 5q23.2-23.3 segment was the imbalance common to all affected individuals. Although LMNB1, implicated in adult-onset autosomal dominant leukodystrophy (ADLD) when overexpressed, was among the 18 duplicated genes, none of the adult carriers manifested ADLD, and LMNB1 overexpression was not detected in the two tested individuals, after qRT-PCR. The ectopic location of the extra copy of the LMBN1 gene on chromosome 22 might have negatively impacted its expression. In addition, two individuals presenting with more severe learning disabilities carried a 1.42 Mb 2p14 microdeletion, with three genes (CEP68, RAB1A and ACTR2),which are candidates for the intellectual impairment observed in the previously described 2p14p15 microdeletion syndrome, mapping to the minimal overlapping deleted segment. A 5p15.1 deletion, encompassing 1.47 Mb, also detected in the family, did not segregate with the clinical phenotype. Conclusion: The disclosing of the complexity of an apparently simple two-break familial rearrangement illustrates the importance of reconstructing the precise structure of derivative chromosomes for establishing genotype-phenotype correlations. [ABSTRACT FROM AUTHOR]

Published

2015

7. Dysregulation of FOXG1 by ring chromosome 14.

Author

Alosi, Daniela, Klitten, Laura Line, Bak, Mads, Hjalgrim, Helle, Møller, Rikke Steensbjerre, and Tommerup, Niels

Subjects

CHROMOSOMES, INTELLECTUAL disabilities, EPILEPSY, QUADRIPLEGIA, KARYOTYPES, MOSAICISM

Abstract

In this study we performed molecular characterization of a patient with an extra ring chromosome derived from chromosome 14, with severe intellectual disability, epilepsy, cerebral paresis, tetraplegia, osteoporosis and severe thoraco-lumbal scoliosis. Array CGH analysis did not show any genomic imbalance but conventional karyotyping and FISH analysis revealed the presence of an interstitial 14q12q24.3 deletion and an extra ring chromosome derived from the deleted material. The deletion and ring chromosome breakpoints were identified at base-pair level by mate-pair and Sanger sequencing. Both breakpoints disrupted putative long non-coding RNA genes (TCONS00022561;RP11-148E17.1) of unknown function. However, the proximal breakpoint was 225 kb downstream of the forkhead box G1 gene (FOXG1), within the known regulatory landscape of FOXG1. The patient represents the first case of a r(14) arising from an interstitial excision where the phenotype is compatible with dysregulation of FOXG1. In turn, the phenotypic overlap between the present case, the FOXG1 syndrome and the r(14) syndrome supports that dysregulation of FOXG1 may contribute to the classical r(14)-syndrome, likely mediated by dynamic mosaicism. [ABSTRACT FROM AUTHOR]

Published

2015

8. Profiling microRNAs in lung tissue from pigs infected with Actinobacillus pleuropneumoniae.

Author

Podolska, Agnieszka, Anthon, Christian, Bak, Mads, Tommerup, Niels, Skovgaard, Kerstin, H. Heegaard, Peter M., Gorodkin, Jan, Cirera, Susanna, and Fredholm, Merete

Subjects

ACTINOBACILLUS pleuropneumoniae, RNA, IMMUNE response, COMMUNICABLE diseases, INFECTION

Abstract

Background: MicroRNAs (miRNAs) are a class of non-protein-coding genes that play a crucial regulatory role in mammalian development and disease. Whereas a large number of miRNAs have been annotated at the structural level during the latest years, functional annotation is sparse. Actinobacillus pleuropneumoniae (APP) causes serious lung infections in pigs. Severe damage to the lungs, in many cases deadly, is caused by toxins released by the bacterium and to some degree by host mediated tissue damage. However, understanding of the role of microRNAs in the course of this infectious disease in porcine is still very limited. Results: In this study, the RNA extracted from visually unaffected and necrotic tissue from pigs infected with Actinobacillus pleuropneumoniae was subjected to small RNA deep sequencing. We identified 169 conserved and 11 candidate novel microRNAs in the pig. Of these, 17 were significantly up-regulated in the necrotic sample and 12 were down-regulated. The expression analysis of a number of candidates revealed microRNAs of potential importance in the innate immune response. MiR-155, a known key player in inflammation, was found expressed in both samples. Moreover, miR-664-5p, miR-451 and miR-15a appear as very promising candidates for microRNAs involved in response to pathogen infection. Conclusions: This is the first study revealing significant differences in composition and expression profiles of miRNAs in lungs infected with a bacterial pathogen. Our results extend annotation of microRNA in pig and provide insight into the role of a number of microRNAs in regulation of bacteria induced immune and inflammatory response in porcine lung. [ABSTRACT FROM AUTHOR]

Published

2012