[Research progress in pharmacological effects of Erigeron breviscapus and its active ingredients for treatment of Alzheimer's disease].

Alzheimer's disease(AD) is a neurodegenerative disease that has no effective drug to cure it. Studies in several AD models have shown that Erigeron breviscapus and its active ingredients(scutellarin and caffeoylquinic acid) could improve/enhance the learning and memory ability, and the mechanisms are associated with inhibiting amyloid ß(Aß) production, aggregation, fibrosis and Aß neurotoxicity toxicity, regulating cholinergic nervous system, inhibiting oxidative stress and inflammation, inhibiting tau hyperphosphorylation, improving mitochondrial function, and resisting neuronal apoptosis. This article systematically reviewed the research progress of E. breviscapus and its active ingredients for treatment of AD in AD models, in the expectation of providing references for further development of E. breviscapus's medicinal potential.

The Effects of Age and Reproduction on the Lipidome of Caenorhabditis elegans.

Aging is a complex life process, and a unified view is that metabolism plays key roles in all biological processes. Here, we determined the lipidomic profile of Caenorhabditis elegans (C. elegans) using ultraperformance liquid chromatography high-resolution mass spectrometry (UPLC-HRMS). Using a nontargeted approach, we detected approximately 3000 species. Analysis of the lipid metabolic profiles at young adult and ten-day-old ages among wild-type N2, glp-1 defective mutant, and double mutant daf-16;glp-1 uncovered significant age-related differences in the total amount of phosphatidylcholines (PC), sphingomyelins (SM), ceramides (Cer), diglycerides (DG), and triglycerides (TG). In addition, the age-associated lipid profiles were characterized by ratio of polyunsaturated (PUFA) over monounsaturated (MUFA) lipid species. Lipid metabolism modulation plays an important role in reproduction-regulated aging; to identify the variations of lipid metabolites during germ line loss-induced longevity, we investigated the lipidomic profiles of long-lived glp-1/notch receptor mutants, which have reproductive deficiency when grown at nonpermissive temperature. The results showed that there was some age-related lipid variation, including TG 40:2, TG 40:1, and TG 41:1, which contributed to the long-life phenotype. The longevity of glp-1 mutant was daf-16-dependent; the lipidome analysis of daf-16;glp-1 double mutant revealed that the changes of some metabolites in the glp-1 mutant were daf-16-dependent, while other metabolites displayed more complex epistatic patterns. We first conducted a comprehensive lipidome analysis to provide novel insights into the relationships between longevity and lipid metabolism regulated by germ line signals in C. elegans.

Quantitative proteomics analysis of Caenorhabditis elegans upon germ cell loss.

The abrogation of the germ cells in Caenorhabditis elegans (C. elegans) by either genetic means or cell ablation results in about 60% increase of longevity. Upon the inhibition of germline stem cell proliferation, certain signaling molecules inhibit the target of rapamycin (TOR), activate the transcription factors including DAF-16, DAF-12, and PHA-4, leading to altered fatty acid lipolysis, autophagy, stress resistance, and the extended lifespan. But the exact cascades and interactions of those signaling pathways are still obscure. To understand how the reproductive system affects aging at the protein level, we determined the protein expression profile of the long-lived temperature-sensitive mutant glp-1(e2141) and wild-type N2 using isobaric tags for relative and absolute quantitation (iTRAQ) technology. Our results showed that the abundance of proteins relevant to transcription, RNA processing, translation, protein folding, and proteolytic process were decreased, while collagen proteins and proteins involved in detoxification and innate immune responses were increased in C. elegans glp-1 mutant, these alterations of protein abundance might attenuate protein metabolism and enhance immune response and stress resistance, and finally contribute to germline-mediated longevity. BIOLOGICAL SIGNIFICANCE: This study provides an overview of the altered protein expression upon germline ablation. Germ-cell loss results in decreased abundance of proteins involved in protein synthesis and breakdown, and increased abundance of proteins involved in detoxification and immune response, suggesting that protein synthesis and metabolism might be attenuated, while detoxification and immune responses might be increased. The altered protein abundance might result in physiological adaptations that contribute to extended longevity in germline-deficient C. elegans. This study brings new light on the role of reproductive control of lifespan.

Metabolomic signature associated with reproduction-regulated aging in Caenorhabditis elegans.

In Caenorhabditis elegans (C. elegans), ablation of germline stem cells (GSCs) leads to infertility, which extends lifespan. It has been reported that aging and reproduction are both inextricably associated with metabolism. However, few studies have investigated the roles of polar small molecules metabolism in regulating longevity by reproduction. In this work, we combined the nuclear magnetic resonance (NMR) and ultra-performance liquid chromatography-mass spectrometry (UPLC-MS) to profile the water-soluble metabolome in C. elegans. Comparing the metabolic fingerprint between two physiological ages among different mutants, our results demonstrate that aging is characterized by metabolome remodeling and metabolic decline. In addition, by analyzing the metabolic profiles of long-lived germline-less glp-1 mutants, we discovered that glp-1 mutants regulate the levels of many age-variant metabolites to attenuate aging, including elevated concentrations of the pyrimidine and purine metabolism intermediates and decreased concentrations of the citric acid cycle intermediates. Interestingly, by analyzing the metabolome of daf-16;glp-1 double mutants, our results revealed that some metabolic exchange contributing to germline-mediated longevity was mediated by transcription factor FOXO/DAF-16, including pyrimidine metabolism and the TCA cycle. Based on a comprehensive metabolic analysis, we provide novel insight into the relationship between longevity and metabolism regulated by germline signals in C. elegans.