Project description:Background: Intestinal failure-associated liver disease (IFALD) is a common complication of long-term parenteral nutrition (PN) that is associated with significant morbidity and mortality. Ferroptosis, as an iron-dependent regulated cell death, has been shown to play an important role in the development of several liver diseases. This study focuses on investigating whether the ferroptosis phenomenon is present in TPN-induced IFALD and further exploring the potential regulatory mechanisms. Methods: Ferroptosis hallmarkers were measured in children with short bowel syndrome (SBS) who had long-term PN use and caused IFALD. Sprague-Dawley (SD) rats were used to establish a rat model of IFALD with a concomitant ferroptosis inhibition intervention using liproxstain-1. The mir-431 lineage was identified as a potential upstream regulatory mir-RNA by mir-RNA sequencing. HepG2 and 293T cell line was used to demonstrate that mir-431 regulates ferroptosis through the GPX4 pathway at the cellular level in vitro. Results: Ferroptosis is upregulated in liver of children with IFALD. Liproxstain-1 downregulates ferroptosis in a rat model of IFALD and attenuates hepatic steatosis through the lipid metabolism pathway. In vitro HepG2 and 293T cell experiments reveal that mir-431 affects ferroptosis by regulating GPX4 protein. Conclusions: Ferroptosis plays an important role in the development of IFALD. Liproxstain-1 inhibits ferroptosis and attenuates hepatic steatosis in a rat model of IFALD through the lipid metabolism pathway. Mir-431 negatively regulates GPX4 protein-induced ferroptosis.

Project description:Background: Intestinal failure-associated liver disease (IFALD) is a common complication of long-term parenteral nutrition (PN) that is associated with significant morbidity and mortality. Ferroptosis, as an iron-dependent regulated cell death, has been shown to play an important role in the development of several liver diseases. This study focuses on investigating whether the ferroptosis phenomenon is present in TPN-induced IFALD and further exploring the potential regulatory mechanisms. Methods: Ferroptosis hallmarkers were measured in children with short bowel syndrome (SBS) who had long-term PN use and caused IFALD. Sprague-Dawley (SD) rats were used to establish a rat model of IFALD with a concomitant ferroptosis inhibition intervention using liproxstain-1. The mir-431 lineage was identified as a potential upstream regulatory mir-RNA by mir-RNA sequencing. HepG2 and 293T cell line was used to demonstrate that mir-431 regulates ferroptosis through the GPX4 pathway at the cellular level in vitro. Results: Ferroptosis is upregulated in liver of children with IFALD. Liproxstain-1 downregulates ferroptosis in a rat model of IFALD and attenuates hepatic steatosis through the lipid metabolism pathway. In vitro HepG2 and 293T cell experiments reveal that mir-431 affects ferroptosis by regulating GPX4 protein. Conclusions: Ferroptosis plays an important role in the development of IFALD. Liproxstain-1 inhibits ferroptosis and attenuates hepatic steatosis in a rat model of IFALD through the lipid metabolism pathway. Mir-431 negatively regulates GPX4 protein-induced ferroptosis.

Project description:Triple-gene knockout pig RBC transfusion induces iron-mediated liver ferroptosis in nonhuman primates

Project description:Ex vivo normothermic machine perfusion has been proposed to protect deceased donor kidneys. However, its benefits remain ambiguous. We postulate that the use of red blood cells (RBCs) and associated secondary hemolysis may in fact cause renal injury, offsetting potential advantages. During 48-hour normothermic perfusion of seven human donor kidneys, we observed progressive hemolysis, leading to iron accumulation in perfusate, tissue, and urine. Untargeted lipidomic profiling revealed significant increases in oxidized phospholipid species in perfused kidneys, pointing towards iron-dependent cell death known as ferroptosis. Next, in twelve additional perfusions, we assessed strategies to mitigate hemolysis-driven injury. Dialysis-based free hemoglobin removal reduced lipid peroxidation, but a ferroptosis gene signature persisted. In contrast, cell-free perfusion at subnormothermia negated iron accumulation, the ferroptosis gene signature, phospholipid peroxidation, and acute kidney injury. Our findings highlight the pathological role of hemolysis and iron on the kidney, urging restraint in the clinical application of RBC-based kidney perfusion.

Project description:Acute liver failure is a critical clinical issue in liver diseases, characterized by extensive hepatocyte death involving various mechanisms, including apoptosis, necroptosis, and ferroptosis. Ferroptosis, an iron-dependent form of non-apoptotic cell death marked by significant lipid peroxidation, plays a crucial role in the pathogenesis of multiple liver disorders.This cell death results in elevated levels of acute phase proteins synthesized and secreted by the liver. While previous studies indicated that the ORM2 protein does not directly influence apoptotic signaling pathways, our findings reveal that its knockout in acute liver injury models significantly worsens damage and reduces the median survival time of mice. In contrast, liver-specific overexpression of Orm2 markedly mitigates acute liver injury.We found that Orm2 exerts its protective effects by non-competitively binding to NCOA4, inhibiting ferroautophagy, and reducing iron ion accumulation, thereby decreasing ferroptosis during acute liver injury. Additionally, interference with TAX1BP1 gene expression compensates for the increased sensitivity to ferroptosis resulting from Orm2 knockdown. Importantly, ORM2 infusion therapy protects against acute damage in various organs, including the liver. Mechanistically, ORM2 in plasma enters damaged cells via endocytosis, regulating iron homeostasis and alleviating acute injury caused by ferroptosis.In summary, Orm2 is a potential protective factor against abnormal iron accumulation and ferroptosis, reducing acute organ damage. These findings suggest that acute phase proteins may play a role in cellular resistance to death during organ injury and offer a potential adjunctive therapeutic strategy for acute organ damage caused by ferroptosis.

Project description:N-glycolylneuraminic acid (Neu5Gc) is generated by hydroxylation of CMP-Neu5Ac to CMP-Neu5Gc, catalyzed by CMP-Neu5Ac hydroxylase (CMAH). However, humans lack this common mammalian cell surface molecule, Neu5Gc, due to inactivation of the CMAH gene during evolution. CMAH is one of several human-specific genes whose function has been lost by disruption or deletion of the coding frame. It has been suggested that CMAH inactivation has resulted in biochemical or physiological characteristics that have resulted in human-specific diseases. To identify differential gene expression profiles associated with the loss of Neu5Gc expression, we performed microarray analysis using Illumina MouseRef-8 v2 Expression BeadChip, using the main tissues (liver, lung, kidney, and heart) from a control mouse and a Cmah-null mouse.

Project description:Iron overload, characterized by accumulation of iron in tissues, induces a multiorgan toxicity whose mechanisms are not fully understood. Using cultured cell lines, Caenorhabditis elegans, and mice, we found that ferroptosis occurs in the context of iron-overload-mediated damage. Exogenous oleic acid protected against iron-overload-toxicity in cell culture and Caenorhabditis elegans by suppressing ferroptosis. In mice, oleic acid protected against FAC-induced liver lipid peroxidation and damage. Oleic acid changed the cellular lipid composition, characterized by decreased levels of polyunsaturated fatty acyl phospholipids and decreased levels of ether-linked phospholipids. The protective effect of oleic acid in cells was attenuated by GW6471 (a PPAR-𝛂 antagonist), as well as in Caenorhabditis elegans lacking the nuclear hormone receptor NHR-49 (a PPAR-𝛂 functional homologue). These results highlight ferroptosis as a driver of iron-overload-mediated damage, which is inhibited by oleic acid. This monounsaturated fatty acid represents a potential therapeutic approach to mitigating organ damage in iron overload individuals.

Project description:Iron overload, characterized by accumulation of iron in tissues, induces a multiorgan toxicity whose mechanisms are not fully understood. Using cultured cell lines, Caenorhabditis elegans, and mice, we found that ferroptosis occurs in the context of iron-overload-mediated damage. Exogenous oleic acid protected against iron-overload-toxicity in cell culture and Caenorhabditis elegans by suppressing ferroptosis. In mice, oleic acid protected against FAC-induced liver lipid peroxidation and damage. Oleic acid changed the cellular lipid composition, characterized by decreased levels of polyunsaturated fatty acyl phospholipids and decreased levels of ether-linked phospholipids. The protective effect of oleic acid in cells was attenuated by GW6471 (a PPAR- antagonist), as well as in Caenorhabditis elegans lacking the nuclear hormone receptor NHR-49 (a PPAR- functional homologue). These results highlight ferroptosis as a driver of iron-overload-mediated damage, which is inhibited by oleic acid. This monounsaturated fatty acid represents a potential therapeutic approach to mitigating organ damage in iron overload individuals.

Project description:Clinical cohort data suggest that high consumption of red meat containing N-glycolylneuraminic acid (Neu5Gc) may increase colorectal prevalence, therefore, we investigated the effect of high Neu5Gc intake on colon cancer using the APCMin/+ mouse model . Ten APCMin/+ male mice were divided into two groups and fed normal (control group: 0.0507 mg per mouse per day) and high concentrations (treatment group: 1.014 mg per mouse per day) of Neu5Gc to mimic Normal and excessive consumption of red meat in humans, respectively. After two weeks of feeding, colorectal and liver were collected for histopathological diagnosis and transcriptome analysis.

Project description:Human beings are unable to synthetize the glycolylated neuraminidic acid (Neu5Gc) following a mutation of the CMAH gene and diet induced anti-Neu5Gc antibodies develop in the first year of life. However, because humans can absorb Neu5Gc which deposits at low levels on endothelial cells (EC), activation of endothelium by anti-Neu5Gc has been raised. Understanding whether this interaction contributes to EC normal biology or may induce a potentially detrimental EC activation is crucial, particularly in patients developing elicited anti-Neu5Gc following introduction of animal derived molecules or bio-devices. Ten EC lines were cultured with immune-affinity purified anti-Neu5Gc from normal sera (diet induced) or sera harvested following rabbit-IgG infusion (elicited) anti-Neu5Gc. After a 4h-incubation of Neu5Gc loaded ECs at levels close to those of freshly harvested ECs, ECs were stimulated with both anti-Neu5Gc types and with or without human complement. Anti-Neu5Gc induce a differential expression (DE) of 967 out of expressed 12,208 genes, with transcript accumulation in 93%. Most DE transcripts are shared following activation by pre-existing or elicited anti-Neu5Gc. Compared to ATG pre-existing antibodies, elicited anti-Neu5Gc down-regulated 66 genes, involving master genes such as IL8, ICAM1, MAPKINASES or NFKb1. Furthermore, addition of elicited anti-Neu5Gc to non-heat inactivated sera down-regulated most of the transcripts mobilized by serum alone, including key transcripts involved in apoptosis, fitting with no increase in apoptotic cells. Altogether, the RNA profiling following culture of human ECs and anti-Neu5Gc suggests that pre-existing anti-Neu5Gc contribute to normal human EC homeostasis rather than to an inflammatory oriented transcriptome. Elicited anti-Neu5Gc do not also skew EC transcriptome toward inflammation either, but trigger the release cytokines or chemokines in culture supernatants.