A Mechanistic Analysis of Gene Regulation and its Evolution in a Drosophila Model

Camino, Eric M.

18 May 2016

No description available.

Biology

cis-regulatory element

gene regulatory network

gene regulation

GRN evolution

Revealing the Structure and Evolution of a Fruit Fly Gene Regulatory Network by Varied Genetic Approaches

Hughes, Jesse T.

January 2021

No description available.

Biology

Evolution and Development

Genetics

transcription factor

gene regulatory network

cis-regulatory element

Drosophila

pigmentation

evo-devo

morphology

dimorphism

convergence

Understanding trait evolution at the levels of a cis-regulatory element and a gene regulatory network

Rogers, William A.

January 2014

No description available.

Developmental Biology

Evolution and Development

Biology

cis regulatory element

Drosophila melanogaster

CRE

Enhance

CRM

Developmental biology

Gene network

Morphological evolution

Etude de la complexité des éléments Cis-régulateurs chez les mammifères en utilisant des approches à haut débit / Study of cis-regulatory elements complexity in mammals using high-throughput approaches

Griffon, Aurelien

02 June 2015

La régulation des gènes est à l’origine de la diversité cellulaire en permettant aux cellules de se différencier et de se spécialiser. La régulation génique repose largement sur l’existence de séquences d’ADN non codantes dans le génome, appelées "éléments cis-régulateurs", qui vont permettre de recruter de nombreux facteurs de transcription afin de former d’importants complexes (nucléo)protéiques qui vont agir sur le niveau de transcription des gènes. Ce recrutement est notamment contrôlé par des modifications épigénétiques. Le développement des techniques de séquençage et des méthodes d’analyse bioinformatiques permettent d’intégrer de grandes quantités de données pour étudier le fonctionnement des éléments régulateurs. Dans un premier temps, l’intégration de l’ensemble des données ChIP-seq disponibles dans les bases de données nous a permis de créer un catalogue d’éléments régulateurs putatifs chez l’Homme. L’analyse de ce catalogue nous a alors mené à caractériser ces éléments et à mettre en évidence la complexité combinatoire des facteurs de transcription. Dans un deuxième temps, nous avons réalisé une étude basée sur l’analyse des éléments régulateurs impliqués dans la différenciation précoce des lymphocytes T chez la souris. Cette étude a permis de mettre en évidence deux niveaux de complexité impliqués dans la régulation des gènes : le premier est basé sur la combinatoire des facteurs de transcription au sein des éléments régulateurs et le second repose sur la combinatoire des éléments eux-mêmes. Finalement, nous avons développé une nouvelle technique d’analyse quantitative et à haut débit de l’activité régulatrice de régions génomiques chez les mammifères. / Gene regulation is responsible for cell diversity by allowing cell differentiation and specialisation. Gene expression regulation relies mainly on the existence of non-coding DNA sequences in the genome, called "cis-regulatory elements", which recruit numerous transcription factors to form (nucleo)protein complexes which act on the gene transcription level. This recruitment is controlled in particular by epigenetic modifications. The rapid development of sequencing technologies and bioinformatics methods makes possible the integration of large amounts of data to study regulatory elements. First, the integration of ChIP-seq data for all transcription factors available in public databases has allowed us to create an extensive catalogue of putative regulatory elements in the human genome. The overall analysis of this catalogue led us to further characterize these elements and to highlight the high level of combinatorial complexity of transcription factors in the genome. Secondly, we conducted a more specific study based on the analysis of the regulatory elements involved in the early differentiation of T-cells in mice. This study provided an opportunity to highlight two levels of complexity based on regulatory elements and involved in gene regulation: the first rests on the transcription factor combinatorial in regulatory elements and the second is based on the combinatorial of elements themselves within loci. Finally, to validate experimentally the regulatory elements, we have developed a new quantitative and high-throughput technique to assess the regulatory activity of genomic regions in mammals.

Régulation des gènes

Elément cis-Régulateur

Facteur de transcription

Gène rapporteur

Epigénétique

Combinatoire

Gene regulation

Cis-Regulatory element

Transcription factor

Gene reporter assay

Epigenetics

Combinatorial

576

Krüppel-Like Factor 5 Regulates Expression of Key Genes in Human Airway Epithelial Cells, Including <i>CFTR</i>

Paranjapye, Alekh

26 August 2022

No description available.

Genetics

Molecular Biology

Epigenetics

airway epithelial cells

CFTR

Krüppel-like Factor

proinflammatory response

wound repair

cis-regulatory element

CTCF

CRISPR HDR

ChIP-seq

4C-seq

Charakterisierung molekularer und pathogenetischer Mechanismen einer isolierten Brachydaktylie Typ E auf der Grundlage der balancierten Translokation t(8;12)(q13;p11.2)

Maaß, Philipp Georg

28 September 2009

In dieser Dissertation wurde eine isolierte Brachydaktylie vom Typ E (BDE) untersucht. Grundlage war eine Familie mit autosomal-dominanten Erbgang BDE. Der genetische Hintergrund ist eine balancierte Translokation t(8;12)(q13;p11.2). Der Bruchpunkt auf derivativem Chromosom der(8) liegt 86 kb strangaufwärts des chondrogenetisch essentiellen Kandidatengens PTHLH (Parathyroid hormone like hormone). PTHLH ist für die Differenzierungsrate von proliferativen Chondrozyten verantwortlich. Positiv oder negativ reguliertes Pthlh führen zu einer Dysbalance mit Brachydaktylie-ähnlichen Phänotypen in murinen Tiermodellen. Der Leserahmen des Kaliumkanals KCNB2 auf Chromosom 8 wurde durch die Translokation in Intron 2 getrennt. Chrondrogenetische KCNB2 Funktionen konnten durch in situ Hybridisierungen ausgeschlossen werden. Der Translokationsbruchpunkt auf der(8) liegt in einer in Mammalia hochkonservierten Region und beeinhaltet ein Bindungsmotiv für AP1 Transkriptionsfaktoren. Durch die Translokation befindet sich in unmittelbarer Nähe eine Kernkonsensussequenz für ETS Transkriptionsfaktoren. AP1 und ETS Transkriptionsfaktoren interagieren und wurden auf eine potentielle PTHLH Regulation untersucht. Epigenetische Histonmodifizierungen, charakteristisch für cis-regulatorische Elemente, sowie Reportergenassays mit AP1 und ETS1 Bindungsmotiven zeigten einen Bezug zur PTHLH Regulation. Bindungsassays mit AP1 und ETS1 Transkriptionsfaktoren an den Bruchpunktsequenzen, sowie funktionelle in vitro Experimente mit Chondrozyten verifizierten die Hypothese, dass der Translokationsbruchpunkt strangaufwärts von PTHLH regulatorische Eigenschaften besitzt. Die AP1 und ETS1 Transkriptionsfaktoren regulierten PTHLH positiv in ATDC5 und C28/I2 Chondrozyten. In chondrogeninduzierten Patientenfibroblasten war die PTHLH Expression inhibiert. Die molekulare Pathogenese der BDE wurde durch die bisher unbekannte chondrogene PTHLH Fehlregulation dargestellt. / We studied a 3-generation family with Brachydactyly Type E (BDE) and identified a t(8;12)(q13;p11.2) translocation. We identified PTHLH (Parathyroid hormone like hormone) on chromosome 12p11.2 and the ionchannel KCNB2 on chromosome 8q13 as candidate genes. KCNB2 was disrupted in intron 2, while the chromosome 12 breakpoint is localized 86 kb upstream of PTHLH; only the latter gene is involved in chondrogenesis. The 12p11.2 breakpoint is conserved and features an AP1 binding site 86 kb upstream of PTHLH. Due to the translocation, an ETS binding site from 8q13 resided near the AP1 site. Since both transcription factors interact, we tested if AP1 and ETS1 can activate PTHLH in ATDC5 and C28/I2 chondrocytes. We used the breakpoint sequences of the derivative chromosomes 8 and 12 and the nonaffected chromosome 8 and 12 allele sequences in reporter-gene assays. Reporter-gene constructs containing the der(8) breakpoint revealed activation in murine and human chondrocytes. The enrichment of histone modifications, implicating cis-regulatory effects were investigated in the breakpoint area. We found the enriched histone H3K4me1 modification at the chromosome 12 breakpoint position in murine and human chondrocytes, while affected fibroblasts showed higher H3K4me1 enrichment at the der(8) breakpoint compared to wt(12) allele. Furthermore, the breakpoint sequence bound to AP1 and C-ets-1 in EMSA. Western blotting after PMA-stimulated AP1 and ETS1 activation and overexpression of different AP1 and ETS1 combinations showed activated PTHrP expression in chondrocytes. In chondrogenic induced BDE fibroblasts PTHLH was inhibited, while IHH was upregulated. We suggest that PTHLH was dysregulated by the translocation in BDE chondrocytes. This could lead to BDE. We highlight the impact to characterize genomic breakpoints in detail and demonstrate a novel AP1- and ETS1-directed chondrogenic PTHLH regulation in wild-type chondrocytes and dysregulation in the pathogenesis of BDE.

PTHLH

KCNB2

Translokation

cis-regulatorisches Element

Histonmodifikationen

AP1

ETS1

Brachydaktylie Typ E

IHH

PTHLH

KCNB2

translocation

cis-regulatory element

histone modification

AP1

ETS1

Brachydactyly Type E

IHH

570 Biowissenschaften, Biologie

32 Biologie

WG 1890

XG 2200

ddc:570

Functional Genetic Analysis Reveals Intricate Roles of Conserved X-box Elements in Yeast Transcriptional Regulation

Voll, Sarah

13 November 2013

Understanding the functional impact of physical interactions between proteins and DNA on gene expression is important for developing approaches to correct disease-associated gene dysregulation. I conducted a systematic, functional genetic analysis of protein-DNA interactions in the promoter region of the yeast ribonucleotide reductase subunit gene RNR3. I measured the transcriptional impact of systematically perturbing the major transcriptional regulator, Crt1, and three X-box sites on the DNA known to physically bind Crt1. This analysis revealed interactions between two of the three X-boxes in the presence of Crt1, and unexpectedly, a significant functional role of the X-boxes in the absence of Crt1. Further analysis revealed Crt1- independent regulators of RNR3 that were impacted by X-box perturbation. Taken together, these results support the notion that higher-order X-box-mediated interactions are important for RNR3 transcription, and that the X-boxes have unexpected roles in the regulation of RNR3 transcription that extend beyond their interaction with Crt1.

functional genetic analysis

transcription factor (TF)

cis-regulatory element (CRE)

binary interaction

higher order interaction

multiple linear regression

additive

multiplicative

synthetic genetic array (SGA)

green fluorescent protein (GFP)

ribonucleotide reductase (RNR)

yeast

X-box

transcriptional regulation

RNR3

Functional Genetic Analysis Reveals Intricate Roles of Conserved X-box Elements in Yeast Transcriptional Regulation

Voll, Sarah

January 2013

Understanding the functional impact of physical interactions between proteins and DNA on gene expression is important for developing approaches to correct disease-associated gene dysregulation. I conducted a systematic, functional genetic analysis of protein-DNA interactions in the promoter region of the yeast ribonucleotide reductase subunit gene RNR3. I measured the transcriptional impact of systematically perturbing the major transcriptional regulator, Crt1, and three X-box sites on the DNA known to physically bind Crt1. This analysis revealed interactions between two of the three X-boxes in the presence of Crt1, and unexpectedly, a significant functional role of the X-boxes in the absence of Crt1. Further analysis revealed Crt1- independent regulators of RNR3 that were impacted by X-box perturbation. Taken together, these results support the notion that higher-order X-box-mediated interactions are important for RNR3 transcription, and that the X-boxes have unexpected roles in the regulation of RNR3 transcription that extend beyond their interaction with Crt1.

functional genetic analysis

transcription factor (TF)

cis-regulatory element (CRE)

binary interaction

higher order interaction

multiple linear regression

additive

multiplicative

synthetic genetic array (SGA)

green fluorescent protein (GFP)

ribonucleotide reductase (RNR)

yeast

X-box

transcriptional regulation

RNR3