Project description:While angiogenesis serves as a cornerstone of embryogenesis and a defining feature of pathological progression, a critical gap persists in understanding how metabolic signaling precisely converges with nuclear reprogramming to ignite vascular growth. Here, we demonstrate that glucose-derived lactate via glycolysis induces site-specific lactylation at lysine 412 (K412) of histone deacetylase 1 (HDAC1), triggering transcriptional activation of pro-angiogenic genes such as VEGFA. Mechanistically, HDAC2 forms a nuclear complex with HDAC1 to suppress its lactylation modification in the cytoplasm, whereas alanyl-tRNA synthetase (AARS1) promotes its lactylation in cytoplasm to prevent HDAC1 nuclear translocation, leading to nuclear accumulation of H3K56 acetylation and chromatin remodeling that selectively activates angiogenesis-related transcriptional programs. In zebrafish models, HDAC1-K412 mutation caused embryonic lethality, and site-specific lactylation dynamically increased during cardiac development. In the HDAC1 K412A mutation knock-in mouse model, the results showed that this site prevents vascular proliferation in the retinas of streptozotocin (STZ)-induced diabetic mice. Pharmacologically, we found that the HDAC1 activator Exifone suppressed its lactylation and inhibited vascular growth. Strikingly, Exifone attenuates pathological neovascularization in embryonic chick models and halts aberrant vascular proliferation within the retinal vasculature of STZ-diabetic mice. Our findings reveal HDAC1 lactylation as a metabolic-epigenetic nexus governing angiogenesis, providing mechanistic insights into not only obscures developmental principles but hampers therapeutic targeting of aberrant vascularization in diseases ranging from cancer to diabetes.

Project description:Endothelial dysfunction promotes the pathogenesis of diabetic nephropathy (DN), which is considered to be an early event in disease progression. However, the molecular changes associated with glomerular endothelial cell (GEC) injury in early DN are not well defined. Most gene expression studies have relied on the indirect assessment of GEC injury from isolated glomeruli or renal cortices. Here, we present transcriptomic analysis of isolated GECs, using streptozotocin-induced diabetic wildtype (STZ-WT) and diabetic eNOS-null (STZ-eNOS−/−) mice as models of mild and advanced DN, respectively. GECs of both models in comparison to their respective nondiabetic controls showed significant alterations in the regulation of apoptosis, oxidative stress, and proliferation. The extent of these changes was greater in STZ-eNOS−/− than in STZ-WT GECs. Additionally, genes in STZ-eNOS−/− GECs indicated further dysregulation in angiogenesis and epigenetic regulation. Moreover, a biphasic change in the number of GECs, characterized by an initial increase and subsequent decrease over time, was observed only in STZ-eNOS−/− mice. This is consistent with an early compensatory angiogenic process followed by increased apoptosis, leading to an overall decrease in GEC survival in DN progression. From the genes altered in angiogenesis in STZ-eNOS−/− GECs, we identified potential candidate genes, Lrg1 and Gpr56, whose function may augment diabetes-induced angiogenesis. Thus, our results support a role for GEC in DN by providing direct evidence for alterations of GEC gene expression and molecular pathways. Candidate genes of specific pathways, such as Lrg1 and Gpr56, can be further explored for potential therapeutic targeting to mitigate the initiation and progression of DN.

Project description:This project presents a spatial proteomic investigation of vascular smooth muscle cells (VSMCs) and atherosclerotic plaque regions in a diabetic mouse model of atherosclerosis (DMAS). Using ApoE-/- mice fed with a high-fat diet and treated with low-dose streptozotocin (STZ) to induce a diabetic phenotype, we performed laser capture microdissection (LCM) to separately isolate plaque regions and adjacent VSMC-rich areas of the aortic arch. Subsequently, spatially resolved proteomic profiling was carried out using LC-MS/MS, followed by quantitative analysis based on iBAQ values. Differentially expressed proteins between plaque and VSMC regions were identified and enriched pathway analysis revealed significant alterations in oxidative stress response, insulin signaling, mitochondrial function, RNA transport, and extracellular matrix remodeling under diabetic conditions. Of particular interest, the spatial proteomics data highlighted a marked downregulation of the nuclear pore complex protein Nup93 in VSMCs from diabetic mice, implicating impaired nuclear transport and dysregulation of RNA alternative splicing. This finding was supported by transcriptomic integration and functional analyses that revealed aberrant splicing of SerpinE2, a gene associated with cell proliferation and ECM accumulation. This dataset provides region-specific, high-resolution proteomic profiles of vascular tissues in a diabetic atherosclerosis model. It serves as a valuable resource for investigating the spatial heterogeneity of vascular pathology and the molecular mechanisms underlying diabetes-accelerated atherosclerosis. The raw and processed data can be used to explore protein expression dynamics, identify spatiotemporal biomarkers, and validate candidate targets such as Nup93 and SerpinE2 involved in VSMC phenotypic switching.

Project description:Diabetic retinopathy (DR) is one of the main causes of blindness in working age populations in industrialized countries. It is estimated that close to 100 million individuals worldwide suffer from DR. Regrettably, relatively little is known of the cellular processes at play during late stages of the disease, especially concerning diabetic macular edema (DME). Streptozotocin-induced diabetic retinopathy (STZ) allows to reproduce experimentally in the mouse retina the retina vascular leakage and neuroegeneration features observed in human pathological retina with non-proliferative DR. Using agnostic and orthogonal approaches, in our work we demonstrate that in contrast to healthy retina, the STZ diabetic retina engages pathways of cell cycle arrest, resulting in cellular senescence. These findings combined with further pharmacological approaches provide mechanistic evidence supporting that targeting selectively senescent vessels in DR represents a potential treatment for high vascular permeability in DME.

Project description:The purpose of this study was to develop a comprehensive picture of the STZ-diabetic host transcriptional response during the acute stage of melioidosis and investigate the interplay between the diabetic host response and Burkholderia pseudomallei. To adress this, we compared the transcriptome of infected STZ-diabetic liver and spleen with uninfected STZ-diabetic tissues over an infection period of 42 hr (16 hpi, 24 hpi and 42 hpi, respectively) to identify genes whose expression is altered in response to an acute infection. The microarray experimental design included 3 biological replicates for each time point and both liver and spleen were harvested for RNA extraction. The microarray data from each time point was compared relative to uninfected diabetic mice. In addition, the transcriptome of uninfected STZ-diabetic liver and spleen were also compared with uninfected buffer (sodium citrate) control mice.

Project description:N-glycosylated proteome of STZ diabetic mice with diabetic nephropathy

Project description:Protein lactylation is a process that is fueled by lactate, generated by the enzyme lactate dehydrogenase (Ldh) from pyruvate. Despite prior research, the precise role of protein lactylation in controlling the identity of mouse embryonic stem cells (ESCs) is still not fully understood. We observed that inhibiting or eliminating Ldha causes a reduction in global protein lactylation in ESCs, and RNA-seq analysis suggests that Ldha inhibition induces a 2-cell-like cell (2CLC) signature in ESCs. To probe the underlying mechanisms, we performed quantitative lactylation proteomics analysis, we discovered that Hdac1, a gene with significant regulatory roles during the 2-cell stage (2C), undergoes lactylation modification. Additionally, we observed that treatment with an Ldh (lactate dehydrogenase) inhibitor can decrease the lactylation levels of Hdac1. Mechanistically, we discovered that Ldha positively regulates the lactylation of Hdac1, promoting its direct binding to zygotic genome activation (ZGA) gene promoters and has stronger deacetylase activity. This leads to the removal of acetyl groups from H3K27 on these loci, effectively suppressing the expression of 2C genes. Our study presents novel evidence supporting protein lactylation's potential as a means of inhibiting the generation of 2CLCs and modulating acetylation activity.

Project description:Protein lactylation is a process that is fueled by lactate, generated by the enzyme lactate dehydrogenase (Ldh) from pyruvate. Despite prior research, the precise role of protein lactylation in controlling the identity of mouse embryonic stem cells (ESCs) is still not fully understood. We observed that inhibiting or eliminating Ldha causes a reduction in global protein lactylation in ESCs, and RNA-seq analysis suggests that Ldha inhibition induces a 2-cell-like cell (2CLC) signature in ESCs. To probe the underlying mechanisms, we performed quantitative lactylation proteomics analysis, we discovered that Hdac1, a gene with significant regulatory roles during the 2-cell stage (2C), undergoes lactylation modification. Additionally, we observed that treatment with an Ldh (lactate dehydrogenase) inhibitor can decrease the lactylation levels of Hdac1. Mechanistically, we discovered that Ldha positively regulates the lactylation of Hdac1, promoting its direct binding to zygotic genome activation (ZGA) gene promoters and has stronger deacetylase activity. This leads to the removal of acetyl groups from H3K27 on these loci, effectively suppressing the expression of 2C genes. Our study presents novel evidence supporting protein lactylation's potential as a means of inhibiting the generation of 2CLCs and modulating acetylation activity.

Project description:The effect of liraglutide on the kidney proteome in the STZ mouse model compared to healthy and STZ diabetic control groups.

Project description:Still in its infancy, the functions of lactylation remain elusive. To address this, we established a comprehensive workflow for lactylation studies that integrates the discovery of lactylation sites with proteomics, the expression of site-specifically lactylated proteins in living cells via genetic code expansion (GCE), and the evaluation of the resulting biological consequences. Specifically, we developed a wet-and-dry-lab combined proteomics strategy, and identified highly conserved lactylation at ALDOA-K147. Driven by its potential biological significance, we site-specifically expressed this lactylated ALDOA in mammalian cells and interrogated the biological changes. We discovered that it not only inhibited enzyme activity but also elicited gain-of-function effects——it dramatically reshaped the functionality of ALDOA by improving stability, enhancing nuclear translocation and affecting gene expression. Further, we demonstrated broad applicability of this workflow to study distinct histone lactylation sites. Together, we anticipate its wide uses in elucidating causative links between site-specific lactylation and target-centric or cell-wide changes.