Project description:Hydrogen sulfide is a signaling molecule that regulates essential processes for plant performance, such as autophagy. In Arabidopsis thaliana, hydrogen sulfide negatively regulates autophagy independently of reactive oxygen species, but the underlying mechanism remains to be understood. To determine whether persulfidation, an emergent posttranslational modification, has a main role in the control of autophagy by sulfide, we have used a proteomic approach targeting ATG4, a cysteine protease that plays a crucial role in autophagy progression. We showed that AtATG4a from A. thaliana, which is the predominant ATG4 protease in this plant species, contains a specific site for persulfidation, the residue Cys170, included in the characteristic catalytic triad Cys-His-Asp of cysteine proteases. We tested whether persulfidation regulates the activity of ATG4 by setting up a heterologous assay using the Chlamydomonas reinhardtii CrATG8 protein as a substrate. Our findings demonstrate that sulfide significantly inactivates AtATG4a cleavage activity in a reversible manner. The biological significance of the reversible inhibition of the ATG4 protease by sulfide is supported by our findings in Arabidopsis leaves under both basal and autophagy-inducing conditions. We also observed a significant increase in the overall ATG4 activity in Arabidopsis under nitrogen starvation and osmotic stress, which is inhibited by sulfide. Therefore, our data strongly suggest that the negative regulation of autophagy by sulfide is mediated, at least, by the specific persulfidation of the protease ATG4.

Project description:Hydrogen sulfide (H2S) is a cytoprotective redox-active metabolite that signals through protein persulfidation (R-SSnH). Despite the known importance of persulfidation on relatively few identified proteins, tissue-specific sulfhydrome profiles and their associated functions are not well characterized, specifically under conditions known to modulate H2S production. We hypothesized that dietary restriction (DR), which increases lifespan and can boost H2S production, expands tissue-specific sulfhydromes. Here, we found protein persulfidation was enriched in liver, kidney, muscle, and brain but decreased in heart of young and aged male mice under two forms of DR, with DR promoting persulfidation in numerous metabolic and aging-related pathways. Mice lacking H2S producing enzyme cystathionine γ-lyase (CGL) had overall decreased tissue protein persulfidation and failed to functionally augment sulfhydromes in response to DR. Overall, we defined tissue- and CGL-dependent sulfhydromes and how diet transforms their makeup, underscoring the breadth for DR and H2S to impact biological processes and organismal health.

Project description:Hydrogen sulfide (H2S) is a cytoprotective redox-active metabolite that signals through protein persulfidation (R-SSnH). Despite the known importance of persulfidation on relatively few identified proteins, tissue-specific sulfhydrome profiles and their associated functions are not well characterized, specifically under conditions known to modulate H2S production. We hypothesized that dietary restriction (DR), which increases lifespan and can boost H2S production, expands tissue-specific sulfhydromes. Here, we found protein persulfidation was enriched in liver, kidney, muscle, and brain but decreased in heart of young and aged male mice under two forms of DR, with DR promoting persulfidation in numerous metabolic and aging-related pathways. Mice lacking H2S producing enzyme cystathionine γ-lyase (CGL) had overall decreased tissue protein persulfidation and failed to functionally augment sulfhydromes in response to DR. Overall, we defined tissue- and CGL-dependent sulfhydromes and how diet transforms their makeup, underscoring the breadth for DR and H2S to impact biological processes and organismal health.

Project description:Hydrogen sulfide (H2S) is a cytoprotective redox-active metabolite that signals through protein persulfidation (R-SSnH). Despite the known importance of persulfidation on relatively few identified proteins, tissue-specific sulfhydrome profiles and their associated functions are not well characterized, specifically under conditions known to modulate H2S production. We hypothesized that dietary restriction (DR), which increases lifespan and can boost H2S production, expands tissue-specific sulfhydromes. Here, we found protein persulfidation was enriched in liver, kidney, muscle, and brain but decreased in heart of young and aged male mice under two forms of DR, with DR promoting persulfidation in numerous metabolic and aging-related pathways. Mice lacking H2S producing enzyme cystathionine γ-lyase (CGL) had overall decreased tissue protein persulfidation and failed to functionally augment sulfhydromes in response to DR. Overall, we defined tissue- and CGL-dependent sulfhydromes and how diet transforms their makeup, underscoring the breadth for DR and H2S to impact biological processes and organismal health.

Project description:Hydrogen sulfide (H2S)-mediated signaling pathways regulate many physiological and pathophysiological processes in mammalian and plant systems. The molecular mechanism by which hydrogen sulfide exerts its action involves the post-translational modification of cysteine residues to form a persulfidated thiol motif, and it is named protein Persulfidation. We have developed a comparative and label-free quantitative proteomic analysis approach for the detection of endogenous persulfidated proteins in Arabidopsis thaliana nitrogen-starved roots and carbon-starved leaves by using the tag-switch method. In this work, we have identified 5214 and 4691 unique proteins from root and leaf tissue, respectively, that represent almost a 13% of the entire annotate proteome in Arabidopsis. Bioinformatic analysis revealed that persulfidated cysteines are part of a wide range of biological functions, regulating important processes such as carbon metabolism, plant responses to abiotic and biotic stresses, plant growth and development, RNA translation and protein degradation. Quantitative analysis in both tissues showed important H2S-regulated metabolic processes through changes in the persulfidation level of key protein targets involved in ubiquitin-dependent protein degradation and autophagy, among others.

Project description:The gasotransmitter hydrogen sulfide (H2S) is thought to be involved in the post-translational modification of cysteine residues to produce reactive persulfides. A persulfide-specific chemoselective proteomics approach with mammalian cells has identified a broad range of zinc finger (ZF) proteins as targets of persulfidation. Parallel studies with isolated ZFs show that persulfidation is mediated by Zn(II), O2, and H2S, with intermediates involving oxygen- and sulfur-based radicals detected by mass spectrometry and optical spectroscopies. A small molecule Zn(II) complex exhibits analogous reactivity with H2S and O2, giving a persulfidated product. These data show that Zn(II) is not just a biological structural element, but also plays a critical role in mediating H2S-dependent persulfidation. ZF persulfidation appears to be a general post-translational modification and a possible conduit for H2S signaling. This work has implications for our understanding of H2S-mediated signaling and the regulation of ZFs in cellular physiology and development.

Project description:Medicago truncatula engages in root nodule symbiosis by developing a de novo plant organ (known as nodule) in its roots in response to the infection by rhizobia. These nodules are de novo plant organs that provide an optimal environment for the rhizobia to fix nitrogen in exchange for photosynthates. The establishment of root nodule symbioses (RNS) requires the coordination of two distinct processes: bacterial infection and nodule organogenesis. In this study we used single-cell RNA-seq to investigate the first hours of the establishment of the root nodule symbiosis aiming to identify the transcriptional mechanisms governing this process.

Project description:Effect of cadmium in the microalga Chlorella sorokiniana

Project description:A hallmark of immune-inflammatory responses is the generation of reactive oxygen and nitrogen species by innate immune cells, in particular macrophages. How macrophages cope with excess oxidant production and associated redox stress is not fully understood. Recent evidence implicates reactive sulfur species (RSS) in inflammatory responses, however, how RSS affect macrophage function and its ability to cope with oxidative-inflammatory stress remains poorly understood. Herein, we investigated endogenous pathways of RSS biogenesis and clearance in macrophages, and in particular, explored how hydrogen sulfide (H2S) and thiol persulidation influences macrophage oxidative-inflammatory response. We report that classical activation of mouse or human macrophages with lipopolysaccharide and interferon-γ (LPS/IFN-γ) triggers a marked production of H2S/RSS, leading to a widespread increase in protein persulfidation. Endogenous H2S/persulfidation levels were governed by the activity of the cystine importer xCT, the H2S-generating enzyme cystathionine γ-lyase and the sulfide-metabolizing enzyme sulfide quinone oxidoreductase (SQOR). High levels of H2S/persulfidation, observed upon LPS/IFN-γ stimulation or SQOR inhibition, were associated with a state of increased resistance to oxidative stress. Furthermore, enhanced persulfidation correlated with attenuated activation of the macrophage inflammasome and diminished inflammatory cell death. These findings shed light on the metabolism and effects of RSS in macrophages and point to an important role for persulfides in enabling macrophages to cope with oxidative-inflammatory stress.

Project description:Neddylation is a post-translational mechanism that adds a ubiquitin-like protein, namely neural precursor cell expressed developmentally down-regulated protein 8, to target proteins, with yet-unknown consequences. Here we show in mice that neddylation in liver is modulated by nutrient availability. Inhibition of neddylation in mouse liver (either pharmacologically or genetically) reduces gluconeogenic capacity and the hyperglycemic actions of counterregulatory hormones (glucagon, adrenaline and glucocorticoids). Further, people with obesity and type 2 diabetes (compared to people with obesity and normoglycemia) display elevated hepatic neddylation levels that correlate positively with fasting glucose levels. Mechanistically, we determined that fasting or caloric restriction of mice leads to neddylation of phosphoenolpyruvate carboxykinase 1 (PCK1) at three lysine residues—K278, K342 and K387. PCK1 is a key control point for gluconeogenesis regulation that can be post-translationally modified by acetylation and phosphorylation, but to date no modifications are known to affect its gluconeogenic capacity. Of note, we find that mutating the three PCK1 lysines that are neddylated reduces its gluconeogenic activity rate. Molecular dynamics simulations show that neddylation of PCK1 could re-position two loops surrounding the catalytic center into an open configuration, rendering the catalytic center more accessible. Our study reveals that neddylation of PCK1 provides a finely-tuned mechanism of controlling glucose metabolism by linking whole nutrient availability to metabolic homeostasis.