Caractérisation de nouveaux inhibiteurs de la kinase RIPK1 et de la nécroptose / Characterization of new necroptosis inhibitors targeting RIPK1

Le Cann, Fabienne

02 June 2017

La nécroptose est une mort cellulaire régulée impliquée dans les pathologies inflammatoires, ischémiques et dégénératives. RIPK1 serait une cible thérapeutique intéressante car son activité kinase serait à l’origine de leur initiation ou aggravation. Nous avons caractérisé les effets biologiques de deux nouveaux inhibiteurs de RIPK1. La sibiriline protège les souris d’une hépatite autoimmune et 6E11 protège les cellules endothéliales de l’aorte de la mort par ischémie froide/réoxygénation, suggérant des propriétés intéressantes pour ces inhibiteurs. Ces composés diffèrent par leur mode d’action, d’interaction et de sélectivité, et restent à optimiser en vue d’une utilisation thérapeutique. / Necroptosis is a regulated cell death pathway involved in inflammatory, ischemic or degenerative diseases. RIPK1 would be an interesting therapeutic target since its kinase activity is probably responsible of their initiation or aggravation. We have characterized the biological effects of two new RIPK1 inhibitors. Sibirilin protects mice from autoimmune hepatitis and 6E11 protects endothelial aortic cells from death due to cold ischemia/reoxygenation, suggesting interesting properties for these inhibitors. These compounds differ in their mode of action, interaction and selectivity, and still need to be optimized for therapeutic use.

Nécroptose

Ripk1

Inhibiteur de kinase

Modélisation moléculaire

Hépatite

Foie

Ischémie

Necroptosis

Ripk1

Kinase inhibitor

Molecular docking

Hepatitis

Liver

Ischemia

The Role of RIPK1 Kinase Activity in Regulating Inflammation and Necroptotic Death

Zelic, Matija

18 January 2018

Necroptosis, a type of regulated necrotic cell death, involves cell membrane permeabilization and has been implicated in various acute and chronic pro-inflammatory diseases, including ischemia-reperfusion injury and neurodegenerative diseases. By using in vitro reconstitution studies and a chemical inhibitor, the kinase activity of the serine/threonine kinase RIPK1 had been shown to regulate necroptotic signaling downstream of TNF and Toll-like receptors (TLRs). To investigate the contribution of RIPK1 kinase activity to inflammation and necroptosis in vivo, we generated kinase inactive RIPK1 knock-in mice. Utilizing fibroblasts and macrophages from these mice, we demonstrate that RIPK1 kinase activity is required for necroptotic complex formation and death induction downstream of TNFR1 and TLRs 3 and 4. We show that RIPK1 kinase inactive mice are resistant to TNF-induced shock and exhibit impaired upregulation of TNF-induced cytokines and chemokines in vitro and in vivo. By using bone marrow reconstitution experiments, we demonstrate that RIPK1 kinase activity in a non-hematopoietic lineage drives TNF-induced lethality. We establish that RIPK1 kinase activity is required for TNF-induced increases in intestinal and vascular permeability and clotting, and implicate endothelial cell necroptosis as an underlying factor contributing to TNF/zVAD-induced shock. Thus, work in this thesis reveals that RIPK1 kinase inhibitors may have promise in treating shock and sepsis.

Inflammation

cell death

RIPK1

TNF

shock

sepsis

Animal Experimentation and Research

Other Immunology and Infectious Disease

Post-Transcriptional Control of RIPK1 in Macrophage Inflammation and Necroptosis

Zhou, Zier

08 December 2022

Receptor-interacting protein kinase 1 (RIPK1) is a major upstream mediator of inflammation and cell death. These processes are key to common inflammatory diseases such as atherosclerosis, where macrophages play an important role in their progression. Closely linked to the expression of downstream genes, long non-coding RNAs (lncRNAs) are critical to controlling cellular processes in health and disease. As post-transcriptional regulatory mechanisms for RIPK1 are largely unknown, this project seeks to study the stability of Ripk1 mRNA and RIPK1 protein, along with Ripk1 mRNA interactions with relevant lncRNAs under various conditions. Using transcription and translation inhibitors, we determined that both Ripk1 mRNA and RIPK1 protein are relatively unstable with half-lives of approximately 3 h. Their turnover in macrophages is further influenced by the timing and duration of inflammation. We also implemented a novel RNA pull-down procedure to capture Ripk1 mRNA and attached lncRNAs for next-generation sequencing. Through differential expression analysis, we discovered significant upregulation of known lncRNA AC125611 and novel lncRNA MSTRG.5894.1 in Ripk1-targeted samples subject to inflammation. MSTRG.7477.1 was upregulated during necroptosis, while MSTRG.5684.5 was upregulated during both inflammation and necroptosis. GapmeR-mediated knockdowns of AC125611 and MSTRG.5684.5 under inflammatory conditions resulted in decreased Ripk1 mRNA expression and RIPK1 protein expression, respectively. Meanwhile, MSTRG.7477.1 knockdowns were connected to decreased RIPK1 at both the mRNA and protein levels. Our research ultimately advances the current understanding of RIPK1 regulation by focusing on Ripk1 mRNA-lncRNA associations and turnover of its mRNA and protein in macrophages, paving the way for future investigations into their capacity to act as therapeutic targets.

Long non-coding RNA

mRNA half-life

Protein half-life

Gene regulation

Macrophages

Inflammation

Cell death

RIPK1