Project description:Lipoic acid, an endogenous small molecule, is widely utilized in metabolic regulation and disease intervention. While its mechanism of action has been largely attributed to protein lipoylation, the dynamic chemical properties of its five-membered cyclic disulfide moiety remain underexplored. Here, we designed and synthesized alkyne-functionalized lipoic acid-based probes, LAN-yne and LAO-yne. Employing a chemoproteomic strategy, we systematically mapped the covalent targets of lipoic acid's disulfide bond across the cellular proteome and assessed their potential biological functions.

Project description:Lipoic acid, an endogenous small molecule, is widely utilized in metabolic regulation and disease intervention. While its mechanism of action has been largely attributed to protein lipoylation, the dynamic chemical properties of its five-membered cyclic disulfide moiety remain underexplored. Here, we designed and synthesized alkyne-functionalized lipoic acid-based probes, LAN-yne and LAO-yne. Employing a chemoproteomic strategy, we systematically mapped the covalent targets of lipoic acid's disulfide bond across the cellular proteome and assessed their potential biological functions.

Project description:Study gene expression during apoptotic process α Lipoic acid-induced.

Project description:Aging and age-related pathologies can be delayed by specifically targeting the senescence-associated secretory phenotype (SASP), a hallmark feature of senescent cells. Achieving the goal using small molecule inhibitors would have a tremendous impact on the quality of lifespan and burden of age-related chronic diseases. We report the potential of alpha lipoic acid (ALA), a naturally existing antioxidant, in targeting senescent cells via induction of programmed cell death. This study demonstrates the impact of alpha-lipoic acid as a medicinal compound on the expression profile of senescent cells and provides a strong rationale for its future use in geriatric medicine.

Project description:Hematopoietic differentiation from human pluripotent stem cell in vitro is an important approach for the research of hematopoietic stem cell regeneration. Small molecules that can maintenance low ROS level and inhibit cell apoptosis or autophagy are benifit for the maintenance or expansion of hematopoietic stem cells. Lipoic acid (ALA) as a small antioxidant molecule can regulate the ROS level and apoptosis of cells. This study found that lipoic acid promoted the production of hemogenic endothelial cells and hematopoietic progenitor cells. Transcriptome analysis of hemogenic endothelial cells showed that ALA upregulated the endothelial to hematopoietic transition (EHT) related genes and downregulated the EHT negative regulated genes. ALA also up-regulated ROS and apoptosis related genes to inhibit the apoptosis of hematopoietic stem/progenitor cells.These results indicated that ALA might have an important role in the regeneration of hematopoietic stem progenitor cell in vitro.

Project description:Investigation of the transcription profile of cells transformed by Cr6+ in vivo was undertaken. The objective was to elucidate genomic changes underlying the mechanism of action of the carcinogenic dose of Cr6+and their prevention using metabolic antioxidant Lipoic acid (LA). Cr6+ was administered intraperitoneally to LPS+TPA challenged Swiss albino mice in host mediated cell transformation assay using peritoneal macrophages in vivo. The cell transforming potential of Cr6+ test doses was validated by gain of anchorage independent growth potential in soft agar and loss of Fc receptor on target cells. LA was administered in equimolar doses. Compared to non-transformed cells, the gene expression profile of transformed cells was found to be dysregulated substantially and in dose dependent manner. Genes showing down regulation were found to be involved in tumour suppression; apoptosis, DNA repair, and cell-cycle. A similar response was noted in the genes pertaining to immune system, morphogenesis, cell-communication, energy-metabolism, and biosynthesis. The co-administration of lipoic acid prevented the transcription dysregulation and cell transformation by Cr6+ in vivo. The influenced pathways seem to be crucial for progression as well as mitigation of Cr toxicity; and their response to LA indicated their critical role in mechanism of anti-carcinogenic action of LA. Results are of importance to mitigate Cr6+ induced occupational cancer hazard.

Project description:Investigation of the transcription profile of cells transformed by Cr6+ in vivo was undertaken. The objective was to elucidate genomic changes underlying the mechanism of action of the carcinogenic dose of Cr6+and their prevention using metabolic antioxidant Lipoic acid (LA). Cr6+ was administered intraperitoneally to LPS+TPA challenged Swiss albino mice in host mediated cell transformation assay using peritoneal macrophages in vivo. The cell transforming potential of Cr6+ test doses was validated by gain of anchorage independent growth potential in soft agar and loss of Fc receptor on target cells. LA was administered in equimolar doses. Compared to non-transformed cells, the gene expression profile of transformed cells was found to be dysregulated substantially and in dose dependent manner. Genes showing down regulation were found to be involved in tumour suppression; apoptosis, DNA repair, and cell-cycle. A similar response was noted in the genes pertaining to immune system, morphogenesis, cell-communication, energy-metabolism, and biosynthesis. The co-administration of lipoic acid prevented the transcription dysregulation and cell transformation by Cr6+ in vivo. The influenced pathways seem to be crucial for progression as well as mitigation of Cr toxicity; and their response to LA indicated their critical role in mechanism of anti-carcinogenic action of LA. Results are of importance to mitigate Cr6+ induced occupational cancer hazard. Agilent one-color experiment, Organism: Mus musculus, Agilent-Whole Genome Mouse 4x44k (AMADID: 14868), Labeling kit: Agilent Quick-Amp labeling Kit (p/n5190-0442)

Project description:To determine the effects of age and lipoic acid supplementation on hepatic gene expression, we fed young (3 months) and old (24 months) male Fischer 344 rats a diet with or without 0.2% (w/w) R-?-lipoic acid (LA) for two weeks. Total RNA isolated from liver tissue was analyzed by Affymetrix microarray to examine changes in transcriptional profile. Results showed an increase in pro-inflammatory gene expression in the aging liver, with increased immune cell function and tissue remodeling genes, representing 45% of the age-related transcriptome changes. Increased inflammation was corroborated by increases in soluble ICAM1 levels with age. There were also observed age-related increases in transcription of genes related to lipid and cholesterol synthesis including Acetyl CoA Carboxylase (Acacb) and Fatty acid Synthase (Fasn). Supplementation of old animals with LA did not reverse this necro-inflammatory phenotype, yet limited age-associated hepatic dyslipidemia. Dietary LA further affected a small but concerted number of hepatic genes regardless of age. These included declines in lipid and bile synthesis genes. Decline in lipid synthesis genes was further corroborated by a decrease in Fasn and Acc protein levels. Intriguingly, LA also altered the expression of genes governing circadian rhythm, most notably Bmal1, Npas2, and Per2, which changed in a coordinated manner with respect to their rhythmic transcription. Thus, advanced age is associated with a necro-inflammatory phenotype and increased lipid synthesis, while chronic LA supplementation influences hepatic genes associated with energy metabolism and circadian rhythm regardless of age. Young (3 months) and old (24 months) Fischer 344 male rats were fed an AIN-93M diet ± 0.2% (w/w) R-?-lipoic acid for two weeks prior to sacrifice. Total RNA was extracted from the median lobe of the liver and analyzed using Affymetrix Rat Genome 230 2.0 Genechips. There were hybridizations for 8 animals in each of the young control, young LA-supplemented, and old control groups, and 6 animals in the old LA-supplemented group. There are only 6 animals in the old LA group because two animals died during the two-week feeding period. This is the reason for nonsequential numbering of animals in this group.

Project description:The multi-subunit pyruvate dehydrogenase complex (PDC) plays a crucial role in glucose oxidation as it determines whether pyruvate is used for mitochondrial oxidative phosphorylation, or is converted to lactate for aerobic glycolysis. PDC contains three lipoic acid groups, covalently attached at lysine residues to give lipoyllysine, which are responsible for acyl group transfer and critical to complex activity. We have recently reported that both free lipoic acid, and lipoyllysine in alpha-keto glutarate dehydrogenase, is highly susceptible to singlet oxygen (1O2)-induced oxidation. We therefore hypothesized that PDC activity and structure would be influenced by 1O2 (generated using Rose Bengal and light) via modification of the lipoyllysines and other residues. PDC activity was decreased by photooxidation, with this being dependent on light exposure, and the presence of O2, Rose Bengal, and D2O consistent with 1O2-mediated reactions. These changes were modulated by pre-illumination addition of free lipoic acid and lipoamide. Activity loss occurred concurrently with lipoyllysine and sidechain modification (determined by mass spectrometry) and protein aggregation (detected by SDS-PAGE). Peptide mass mapping provided evidence for modification at 43 residues (Met, Trp, His and Tyr; with modification extents of 20-50%) and all three lipoyllysine sites (6-20% modification). Structure modelling indicated the modifications occur across all 4 subunit types, and occur in functional domains or at multimer interfaces, consistent with damage at multiple sites contributing to the overall loss of activity. These data indicate that PDC activity and structure are highly susceptible to 1O2-induced damage with potential effects on cellular pathways of glucose metabolism.

Project description:To determine the effects of age and lipoic acid supplementation on hepatic gene expression, we fed young (3 months) and old (24 months) male Fischer 344 rats a diet with or without 0.2% (w/w) R-α-lipoic acid (LA) for two weeks. Total RNA isolated from liver tissue was analyzed by Affymetrix microarray to examine changes in transcriptional profile. Results showed an increase in pro-inflammatory gene expression in the aging liver, with increased immune cell function and tissue remodeling genes, representing 45% of the age-related transcriptome changes. Increased inflammation was corroborated by increases in soluble ICAM1 levels with age. There were also observed age-related increases in transcription of genes related to lipid and cholesterol synthesis including Acetyl CoA Carboxylase (Acacb) and Fatty acid Synthase (Fasn). Supplementation of old animals with LA did not reverse this necro-inflammatory phenotype, yet limited age-associated hepatic dyslipidemia. Dietary LA further affected a small but concerted number of hepatic genes regardless of age. These included declines in lipid and bile synthesis genes. Decline in lipid synthesis genes was further corroborated by a decrease in Fasn and Acc protein levels. Intriguingly, LA also altered the expression of genes governing circadian rhythm, most notably Bmal1, Npas2, and Per2, which changed in a coordinated manner with respect to their rhythmic transcription. Thus, advanced age is associated with a necro-inflammatory phenotype and increased lipid synthesis, while chronic LA supplementation influences hepatic genes associated with energy metabolism and circadian rhythm regardless of age.