Muscle protein catabolism and splanchnic arginine consumption drive arginine dysregulation during Pseudomonas Aeruginosa induced early acute sepsis in swine.

Human sepsis is characterized by increased protein breakdown and changes in arginine and citrulline metabolism. However, it is unclear whether this is caused by changes in transorgan metabolism. We therefore studied in a Pseudomonas aeruginosa induced pig sepsis model the changes in protein and arginine related metabolism on whole body (Wb) and transorgan level. We studied 22 conscious pigs for 18 hours during sepsis, induced by infusing live bacteria (Pseudomonas aeruginosa) or after placebo infusion (control). We used stable isotope tracers to measure Wb and skeletal muscle protein synthesis and breakdown, as well as Wb, splanchnic, skeletal muscle, hepatic and portal drained viscera (PDV) arginine and citrulline disposal and production rates. During sepsis, arginine Wb production (p=0.0146), skeletal muscle release (p=0.0035) and liver arginine uptake were elevated (p=0.0031). Wb de novo arginine synthesis, citrulline production, and transorgan PDV release of citrulline, glutamine and arginine did not differ between sepsis and controls. However, Wb (p<0.0001) and muscle (p<0.001) protein breakdown were increased, suggesting that the enhanced arginine production is predominantly derived from muscle breakdown in sepsis. In conclusion, live-bacterium sepsis increases muscle arginine release and liver uptake, mirroring previous pig endotoxemia studies. In contrast to observations in humans, acute live-bacterium sepsis in pigs does not change citrulline production or arterial arginine concentration. We therefore conclude that the arginine dysregulation observed in human sepsis is possibly initiated by enhanced protein catabolism and splanchnic arginine catabolism, while decreased arterial arginine concentration and citrulline metabolism may require more time to fully manifest in patients.

Research Progress on Transorgan Regulation of the Cardiovascular and Motor System through Cardiogenic Exosomes.

The heart is the core organ of the circulatory system. Through the blood circulation system, it has close contact with all tissues and cells in the body. An exosome is an extracellular vesicle enclosed by a phospholipid bilayer. A variety of heart tissue cells can secrete and release exosomes, which transfer RNAs, lipids, proteins, and other biomolecules to adjacent or remote cells, mediate intercellular communication, and regulate the physiological and pathological activities of target cells. Cardiogenic exosomes play an important role in regulating almost all pathological and physiological processes of the heart. In addition, they can also reach distant tissues and organs through the peripheral circulation, exerting profound influence on their functional status. In this paper, the composition and function of cardiogenic exosomes, the factors affecting cardiogenic exosomes and their roles in cardiovascular physiology and pathophysiology are discussed, and the close relationship between cardiovascular system and motor system is innovatively explored from the perspective of exosomes. This study provides a reference for the development and application of exosomes in regenerative medicine and sports health, and also provides a new idea for revealing the close relationship between the heart and other organ systems.

Study on Transorgan Regulation of Intervertebral Disc and Extra-Skeletal Organs Through Exosomes Derived From Bone Marrow Mesenchymal Stem Cells.

Exosomes are membranous lipid vesicles fused with intracellular multicellular bodies and then released into the extracellular environment. They contain various bioactive substances, including proteins, mRNA, miRNAs, lncRNAs, circRNAs, lipids, transcription factors, and cytokine receptors. Under certain conditions, bone marrow mesenchymal stem cells (BMSCs) can differentiate into osteoblasts, chondrocytes, adipocytes, and biological functions. This study provides a theoretical basis for the application of exosomes derived from bone marrow mesenchymal stem cells (BMSC-Exos) in osteology, exploring different sources of exosomes to improve bone microenvironment and resist bone metastasis. We also provided new ideas for the prevention and rehabilitation of human diseases by exosomes.

Analytical and biological assessment of circulating human erythroferrone.

BACKGROUND: Erythroferrone (ERFE) is an erythroid hormone putatively involved in stress erythropoiesis. Its regional clearance and circulating form in humans, as well as levels in normal health and coronary disease remain unclear. METHODS: To establish a reference interval, ERFE was measured in 155 healthy volunteers using the Intrinsic LifeSciences ELISA. To identify trans-organ gradients in ERFE, regional blood sampling was undertaken in patients (n = 13) undergoing clinically indicated cardiac catheterisation. The Intrinsic ELISA was assessed for reproducibility, stability, linearity and possible cross-reactivity, interference and anticoagulant effects. Circulating forms of ERFE were evaluated by HPLC. RESULTS: In healthy individuals, the median concentration of ERFE was 0.51 ng/mL (IQR: 0.12-1.25), with men (n = 78) having higher levels than women (n = 77) (0.67 vs 0.32 ng/mL, p = 0.0001). ERFE concentrations in trans-organ sampling revealed no clear organ of clearance or production. Samples with high endogenous ERFE levels were suppressed by haemoglobin (≥2 g/L), bilirubin (≥200 µmol/L), lipaemia (>1 g/L), and freeze thawing (≥2 cycles), but this was not observed with low ERFE concentrations. Endogenous ERFE immunoreactivity was 46% higher in EDTA plasma compared with serum and lithium heparin plasma. On SE-HPLC, ERFE eluted as intact and cleaved forms. CONCLUSION: We provide a useful reference range for ERFE in EDTA plasma. We found no specific site of secretion or clearance. The Intrinsic ELISA performed adequately but is limited by interference and stability when endogenous levels are high. Circulating forms are multiple and complex.