Transcriptional basis of Huntington’s Disease: Gene expression analysis indicate increased immune responses in the brain and mitochondrial dysfunction in adipose tissues of HD model mouse / Transkriptionell grund för Huntingtons sjukdom: Genuttrycksanalys indikerar ökade immunförsvar i hjärnan och mitokondriell dysfunktion i fettvävnader hos HD-modellmus

Salim, Intisar

January 2023

Huntingtons sjukdom (HD) är ett neurodegenerativt tillstånd som orsakas av mutationer i huntingtin gen (Htt), och resulterar till upprepade glutamin (polyQ) i Htt-proteinet. Muterad Htt kan inte vika sig ordentligt och börjar därför aggregera i celler. I detta projekt undersöktes molekylära mekanismerna bakom HD genom att analysera genuttryck hos musvävnader och jämföra detta med biomarkörer identifierats hos HD-patienter. För närvarande finns det ingen behandling för att stoppa utveckling av HD. Därför behövs det mer kunskap om sjukdomen. Projektets mål var att öka vår förståelse på regulatoriska mekanismer som ligger bakom den neurodegenerativa sjukdomen och identifiera potentiella diagnostiska biomarkörer. För denna studie användes mRNA-seq-data från 11 distinkta vävnader från Q175 HD-möss. Vävnader som analyserades inkluderar hjärnstammen, cerebellum, corpus callosum, hippocampus och thalamus/hypothalamus, fettvävnader (brun, vit nära gonad och vit nära tarm) och andra vävnader så som hjärta, hud och gastrocnemius muskel. Efter en grundlig genomgång av HD-litteraturen valdes biomarkörer som sedan undersöktes för mRNA-uttryck hos Q175-möss via Gene Set Enrichment Analysis (GSEA). Genuttrycksförändringar hos HD-möss visade sig vara vävnadsspecifika, med betydande effekter på hud och fettvävnader, men mindre effekter hos hjärnvävnader. Även om gemensamma mRNA-förändringar inte hittas bland de olika vävnader, uppvisade relaterade vävnader förändringar i samma pathways. Immunsvar och ribosomal dysfunktion var utbredd, men varje hjärnregion visade unika förändringar relaterade till sömn, synaptisk signalering och energiprocesser. Muskel- och fettvävnader uppvisar också distinkta mönstrar. Detta understryker vikten av vävnadsspecifik biomarkörforskning för neurodegenerativa sjukdomar. / Huntington's disease (HD) is a neurodegenerative condition caused by a mutation in the Huntingtin (Htt) gene which results in glutamine repeats (polyQ) and a longer Htt-protein. The mutated Htt-protein cannot fold properly and thus, is prone to aggregate in cells. There is currently no treatment available to stop the progression of HD. Therefore, there is a need for more knowledge regarding the disease. This project investigates the molecular mechanisms underlying HD by analysing gene expression program in wild type (Wt) and HD mice. The objective is to investigate changes in gene regulatory mechanisms underlying the neurodegenerative disease and identify potential diagnostic markers. For this study, mRNA-seq data from 11 distinct tissues from Q175 HD model mouse were analysed. These tissues included brainstem, cerebellum, corpus callosum, hippocampus, and thalamus/hypothalamus, adipose tissues (brown, white near gonad and white near intestine), heart, skin and gastrocnemius muscle. Following a thorough literature review, biomarkers of HD were chosen, and their expression investigated in the HD mouse using Gene Set Enrichment Analysis (GSEA). Gene expression changes in HD mouse were specific to different tissues, with significant changes identified in skin and adipose tissues, while smaller changes were detected in the brain tissues. While common changes across the 11 tissues were not found, related tissues exhibited alterations in the same pathways. Changes in immune response and ribosomal dysfunction were widespread across tissues. Moreover, each brain region showed unique changes related to sleep, synaptic signalling, and energy processes. Muscle and adipose tissues displayed distinctive patterns. These results underscore the importance of tissue-specific biomarker research for neurodegenerative diseases.

Huntington’s Disease

mRNA-seq

tissue specific gene expression

cerebrospinal fluid

biomarker

Huntingtons sjukdom

mRNA-seq

vävnadsspecifik genexpression

cerebrospinalvätska

biomarkör

A Novel Approach to Identify Candidate Imprinted Genes in Humans

Shapiro, Jonathan

21 March 2012

Many imprinted genes are necessary for normal human development. Approximately 70 imprinted genes have been identified in humans. I developed a novel approach to identify candidate imprinted genes in humans using the premise that imprinted genes are often associated with nearby parent-of-origin-specific DNA differentially methylated regions (DMRs). I identified parent-of-origin-specific DMRs using sodium bisulfite-based DNA (CpG) methylation profiling of uniparental tissues, mature cystic ovarian teratoma (MCT) and androgenetic complete hydatidiform mole (AnCHM), and biparental tissues, blood and placenta. In support of this approach, the CpG methylation profiling led to the identification of parent-of-origin-specific differentially methylated CpG sites (DMCpGs) in known parent-of-origin-specific DMRs. I found new DMRs for known imprinted genes NAP1L5 and ZNF597. Most importantly, I discovered many new DMCpGs, which were associated with nearby genes, i.e., candidate imprinted genes. Allelic expression analyses of one candidate imprinted gene, AXL, suggested polymorphic imprinting of AXL in human blood.

Allele

Allele-specific DNA Methylation

Allele-specific Gene Expression

Allele-specific Expression

Allele-specific Methylation

AnCHM

Androgenetic

Androgenetic Mole

Mole

Complete Mole

Hydatidiform Mole

Complete Hydatidiform Mole

Androgenetic Hydatidiform Mole

Androgenetic Complete Hydatidiform Mole

Biparental Tissue

Bisulfite

Bisulphite

Blood

Blood DNA

Computational Biology

DNA Methylation

DNA Methylation Profiling

Epigenetic

Epi-genetic

Epigenomic

Epi-genomic

Expression

Expression Regulation

Gene Expression

Gene Expression Regulation

Genetic

Genetic Imprint

Genetic Imprinting

Genomic

Genomic DNA

Genomic Imprint

Genomic Imprinting

Human

Imprint

Imprinting

Teratoma

Ovarian Teratoma

Cystic Teratoma

Mature Teratoma

Mature Cystic Teratoma

Mature Ovarian Teratoma

Cystic Ovarian Teratoma

Mature Cystic Ovarian Teratoma

MCT

Methylation

Cytosine Methylation

Microarray

Neoplasm

Ovarian Neoplasm

Placenta

Profiling

Promoter

Promoter Region

Sodium Bisulfite

Sodium Bisulphite

Uniparental Tissue

WB

WBC

Imprinted Gene

Polymorphic Imprinting

Parent-of-origin

Parent-of-origin-specific Methylation

Parent-of-origin-specific Expression

0369

0307

A Novel Approach to Identify Candidate Imprinted Genes in Humans

Shapiro, Jonathan

21 March 2012

Many imprinted genes are necessary for normal human development. Approximately 70 imprinted genes have been identified in humans. I developed a novel approach to identify candidate imprinted genes in humans using the premise that imprinted genes are often associated with nearby parent-of-origin-specific DNA differentially methylated regions (DMRs). I identified parent-of-origin-specific DMRs using sodium bisulfite-based DNA (CpG) methylation profiling of uniparental tissues, mature cystic ovarian teratoma (MCT) and androgenetic complete hydatidiform mole (AnCHM), and biparental tissues, blood and placenta. In support of this approach, the CpG methylation profiling led to the identification of parent-of-origin-specific differentially methylated CpG sites (DMCpGs) in known parent-of-origin-specific DMRs. I found new DMRs for known imprinted genes NAP1L5 and ZNF597. Most importantly, I discovered many new DMCpGs, which were associated with nearby genes, i.e., candidate imprinted genes. Allelic expression analyses of one candidate imprinted gene, AXL, suggested polymorphic imprinting of AXL in human blood.

Allele

Allele-specific DNA Methylation

Allele-specific Gene Expression

Allele-specific Expression

Allele-specific Methylation

AnCHM

Androgenetic

Androgenetic Mole

Mole

Complete Mole

Hydatidiform Mole

Complete Hydatidiform Mole

Androgenetic Hydatidiform Mole

Androgenetic Complete Hydatidiform Mole

Biparental Tissue

Bisulfite

Bisulphite

Blood

Blood DNA

Computational Biology

DNA Methylation

DNA Methylation Profiling

Epigenetic

Epi-genetic

Epigenomic

Epi-genomic

Expression

Expression Regulation

Gene Expression

Gene Expression Regulation

Genetic

Genetic Imprint

Genetic Imprinting

Genomic

Genomic DNA

Genomic Imprint

Genomic Imprinting

Human

Imprint

Imprinting

Teratoma

Ovarian Teratoma

Cystic Teratoma

Mature Teratoma

Mature Cystic Teratoma

Mature Ovarian Teratoma

Cystic Ovarian Teratoma

Mature Cystic Ovarian Teratoma

MCT

Methylation

Cytosine Methylation

Microarray

Neoplasm

Ovarian Neoplasm

Placenta

Profiling

Promoter

Promoter Region

Sodium Bisulfite

Sodium Bisulphite

Uniparental Tissue

WB

WBC

Imprinted Gene

Polymorphic Imprinting

Parent-of-origin

Parent-of-origin-specific Methylation

Parent-of-origin-specific Expression

0369

0307

Generierung und Analyse EMA/E2F-6-defizienter Mäuse

Pohlers, Michael

12 December 2005

The present study focuses on the biological functions of the transcription factor EMA/E2F-6, a member of the E2F-family of transcription factors that play an import role in cell cycle progression, differentiation and apoptosis. EMA/E2F-6 functions as a transcriptional repressor by recruiting a large protein complex, that includes polycomb group proteins, to specific target genes in order to silence their expression. To identify the biological functions of EMA/E2F-6 mice lacking this factor were developed and subsequently analysed. EMA/E2F6-/- mice are born with the expected frequency, are fertile and develop normally up to 18 months of age. Then about 25 % of these mice develop a paralysis of the hind limbs and present with a severe primary myelination defect of the spinal cord (and in part of peripheral nerves, too) that is accompanied by a massive infiltration of macrophages. Importantly, the histological findings were also detected in EMA/E2F-6-/- mice lacking clinical symptoms albeit to a lesser extend. With respect to EMA/E2F-6 association with polycomb group (Pc-G) proteins there were no significant findings such as skeletal transformations. In addition, only a mild proliferation defect of T-lymphocytes was observed that, in a more severe form, is typical for Pc-G mutations in the mice. Surprisingly, embryonic fibroblasts from EMA/E2F-6-/- mice have no obvious cell cycle defects. Accordingly, gene expression profiles showed that classical E2F target genes were normally regulated in these cells. However, EMA/E2F-6-/- fibroblasts ubiquitously express genes like alpha-tubulin-3 and -7 that are normally expressed in a strictly testis-specific manner. All EMA/E2F-6-dependent target genes identified contain a conserved E2F-binding site in their promoters that is required both for EMA/E2F-6 binding and regulation.

Zellzyklus

Demyelinisierungen

Gehirnveränderungen

Geninaktivierung

Gewebsspezifische Genexpression

Lähmungen

Makrophageninfiltration

Mäuse/Nullmutanten

Neuronenuntergang

Oligodendrozytenreduktion

Polycomb-Gruppe-Proteine

Proliferation von T-Lymphozyten

Regulation der Genexpression

Rückenmarksveränderungen

Skeletttransformationen

Transkriptionsfaktoren

Brain/Abnormalities

Cell Cycle

Demyelinisations

Gene Targeting

Infiltration of Makrophages

Mice/Knockout

Neuron Death

Paralyses

Polycomb-Group Proteins

Proliferation of T-Lymphocytes

Reduktion of Oligodendrocytes

Regulation of Gene Expression

Skeletal Transformations

Spinal Cord/Abnormalities

Tissue-specific Gene Expression

Transkription Factors

570 Biowissenschaften, Biologie

32 Biologie

WG 3580

WG 3700

ddc:570