Genetic disorder | EPFL Graph Search

A genetic disorder is a health problem caused by one or more abnormalities in the genome. It can be caused by a mutation in a single gene (monogenic) or multiple genes (polygenic) or by a chromosomal abnormality. Although polygenic disorders are the most common, the term is mostly used when discussing disorders with a single genetic cause, either in a gene or chromosome. The mutation responsible can occur spontaneously before embryonic development (a de novo mutation), or it can be inherited from two parents who are carriers of a faulty gene (autosomal recessive inheritance) or from a parent with the disorder (autosomal dominant inheritance). When the genetic disorder is inherited from one or both parents, it is also classified as a hereditary disease. Some disorders are caused by a mutation on the X chromosome and have X-linked inheritance. Very few disorders are inherited on the Y chromosome or mitochondrial DNA (due to their size). There are well over 6,000 known genetic disorder

Identification and characterization of proteins that protect human telomeres from fragility

Anna Christina Näger

Difficulties to replicate telomeres - the ends of our chromosomes - can cause telomere shortening andgenome instability. These difficulties are due to the repetitive DNA sequence and distinct structures at telomeresthat challenge the semi-conservative DNA replication machinery. Among the proteins that help toovercome the obstacles to telomere replication are factors known to be mutated in genetic diseases (forinstance WRN, BLM, RTEL1, CTC1), but we suspect that there are still factors and pathways unknown.DNA replication defects at telomeres manifest as smeary or multiple telomeric fluorescence in situ hybridization(FISH) signals on metaphase chromosomes - commonly called telomere fragility. To identify proteinsthat protect human telomeres from fragility, we depleted 71 proteins (including 8 controls) from HeLa cellsusing siRNA pools and analysed their metaphase chromosomes for fragile telomeres. The majority of theseproteins had been identified by QTIP-iPOND - a proteomic analysis of chromatin near telomere replicationforks. Among the 71 proteins that were depleted in the siRNA screen, we identified 29 novel proteins thatprevent telomere fragility and are therefore crucial to maintain genome stability. The telomere fragilityscreen validated QTIP-iPOND as a technique to identify telomere replication proteins. The hits identified inour telomere fragility screen may for example have functions in regulating telomeric chromatin compositionand compaction, regulating transcription of the telomeric long non-coding RNA TERRA and its associationwith telomeric chromatin, dealing with replication stress and stalled replication forks, modulating DNAdamage signalling and repair, modulating sister chromatid cohesion, and preventing oxidative stress.One of the 29 novel proteins identified in the telomere fragility screen is chromobox 8 (CBX8) whose functionat telomeres was investigated in further detail in this study. CBX8 is a component of the canonical polycombrepressive complex 1 (PRC1), an epigenetic regulator of gene expression. However, CBX8 also hasfunctions that are independent of the PRC1 complex. We show that human CBX8 prevents telomere fragilitycaused by RNA-DNA hybrids which could stall replication forks and induce homologous recombination.CBX8 depletion or knockout did however not affect telomeric RNA-DNA hybrid levels. We hypothesize thatCBX8 may be involved in repair activities at stalled replication forks that arise when the replisome encounterspersistent RNA-DNA hybrids. Moreover, we found that CBX8 localizes to telomeric repeat-binding factor2 (TRF2)-deficient telomeres in a manner that is dependent on RNA-DNA hybrids and ATM signalling.We demonstrate that H3K27me3 (trimethylated histone 3 lysine 27) marks, which have previously beensuggested to help recruitment of CBX proteins to chromatin via the CBX chromodomain, are dispensable forCBX8 recruitment to TRF2-deficient telomeres. Furthermore, we found that CBX8 promotes non-homologousend joining (NHEJ)-mediated telomere fusions of dysfunctional telomeres. We therefore hypothesizethat CBX8 is involved in repair activities that influence the DNA repair pathway choice at TRF2-deficient telomeres.

EPFL2022

Functional analysis of Bicc1 and novel interacting proteins in renal tubule cell metabolism and polycystic kidneys

Lucía Carolina Leal Esteban

Genetic disorders known as ciliopathies develop polycystic kidneys, including autosomal dominant and autosomal recessive polycystic kidney diseases (ADPKD and ARPKD). Several signaling pathways including the cAMP/PKA pathway are implicated in driving cystic growth. However, the mechanisms underlying cysts formation is still elusive. Renal cysts also arise in patients and in mouse models with mutations in the RNA-binding protein Bicaudal-C (Bicc1). Bicc1 binds specific mRNAs such as adenylate cyclase VI (AC6) mRNA for translational repression. Conducting a structure-function analysis, we demonstrated that Bicc1 self-polymerizes through its sterile alpha motif (SAM domain) to form cytoplasmic clusters, which specifically localize and silence bound mRNAs. Altered glucose and lipid metabolism also sustain cystic growth in polycystic kidneys, but the cause of these perturbations is unclear. Here, we found that Bicc1 is essential for normal expression of the gluconeogenic enzymes FBP1 and PEPCK specifically in kidneys, and to maintain euglycemia. In a proteomic interactome screen using a knock-in cell line, we found that TAP-tagged Bicc1 binds the C-Terminal to Lis-Homology domain (CTLH) complex, the mammalian orthologue of the glucose-induced degradation (Gid) complex that triggers degradation of FBP1 in S. cerevisiae. Bicc1 stimulates FBP1 expression in vitro in cultured murine inner medullary collecting duct (mIMCD3) cells, albeit independently of its interaction with the CTLH complex. Instead, Bicc1 and CTLH complex seem to mutually downregulate each other. Bicc1 interactome is also enriched with metabolic related proteins. Here we found that Bicc1 coimmunoprecipitates with rate-limiting metabolic enzymes and contributes to maintain their protein levels, and that deletion of Bicc1 significantly alters the renal metabolome while enhances autophagy. Altogether, these results implicate Bicc1 as an important metabolic regulator in the etiology of polycystic kidneys.

EPFL2017

Identification and characterisation of small-molecule inhibitors targeting STING

Simone Margret Haag

The recognition of pathogen-derived nucleic acids is a critical mechanism by which the innate immune system detects viral infection. Upon activation, nucleic acid sensors initiate the expression of type I interferons and other inflammatory mediators, subsequently leading to potent antiviral immune responses. However, erroneous detection of nucleic acids can have deleterious consequences for the host by inducing the development of certain autoinflammatory disorders. Inappropriate sensing of self- nucleic acids underlies a spectrum of monogenic disease referred to as type interferonopathies, including the Aicardi-Goutières syndrome (AGS). These disorders are often driven by mutations in genes encoding for components of nucleic acid recognition pathways, thereby resulting in the constitutive activation of type I interferon responses. Insight into the molecular pathology of AGS has highlighted promising new targets that may be harnessed for the development of novel therapeutics to counter this disorder. Stimulator of interferon genes (STING) - a central adaptor of the cytosolic DNA sensing pathway - has been strongly implicated in the pathogenesis of distinct inflammatory disorders, including AGS. Therefore, pharmacological inhibition of STING presents a promising approach for the development of potent treatment strategies against these and potentially other STING-mediated, autoinflammatory diseases. Performing a cell-based small-molecule screen, we identified and characterized two series of compounds, which potently and selectively inhibit STING through a mechanism that blocks the activation-induced palmitoylation of STING. The identified small-molecules mediate this inhibition through covalent binding to a transmembrane predicted cysteine residue (Cys91) - a palmitoylation site required for STING activation. Using the inhibitors, we show that the palmitoylation of STING mediates the formation of multimeric complexes at the Golgi and the subsequent recruitment and activation of the direct downstream kinase TBK1. We also provide evidence that representatives of both identified compound classes potently inhibit STING-induced expression of inflammatory cytokines including type I interferon, in human and mouse cells. Furthermore, we also demonstrate that the identified STING inhibitors attenuate autoinflammatory disease features in a mouse model of AGS. Taken together, this work uncovers a small-molecule mediated mechanism to inhibit STING and demonstrates the pharmacological potential of targeting STING for the treatment of type I interferon driven disease such as AGS.

EPFL2019