热量限制延长寿命的分子机制

很多研究均发现,热量限制在很多物种中都有延长寿命的作用.这些报道认为,寿命的延长可 能与氧化应激和炎症过程有关.值得注意的是,热量限制调节氧化应激与脂质代谢调控、抑 制细胞凋亡、DNA保护等分子过程有密切关系.最近,有研究者表明,热量限制调控氧化应激和炎症过程是通过胰岛素/胰岛素样生长因子信号通路起作用的.热量限制在所有的动物模型实验中都显示延长寿命,然而,在人类中应用热量限制,可能还存在很多对人体健康问题值得关注.本文就热量限制如何调控寿命的机制的研究进展作一综述.     

PGC-1α attenuates the oxidative stress-induced impaired osteogenesis and angiogenesis regulation effects of mesenchymal stem cells in the presence of diabetic serum

Oxidative stress is believed to induce dysfunction of the bone remodeling process and be associated with progressive loss of bone mass. The peroxisome proliferator-activated receptor gamma coactivator 1α (PGC-1α) is a master controller during mitochondrial biogenesis and the antioxidant response. We postulated that PGC-1α could function as a cyto-protective e?ector in mesenchymal stem cells (MSCs) under oxidative stress conditions. In this study, diabetic serum was firstly used to treat MSCs to induce oxidative damage. The anti-oxidative protective effects of PGC-1α overexpression on MSCs, as well as MSCs’ osteogenesis and angiogenic regulation effects were investigated in vitro. Results showed that diabetic conditions induced significantly increase of intracellular oxidative damage and mitochondrial permeability transition pore (mPTP) opening activity, decrease of cellular viability, and osteogenic differentiation and pro-angiogenic regulation effects of MSCs. However, the diabetic conditions induced oxidative impair on MSCs were significantly alleviated via PGC-1α overexpression under diabetic conditions. Taken together, this study indicates the anti-oxidative treatment potential of PGC-1α regulation as a promising strategy to promote coupling pro-osteogenesis and pro-angiogenesis effects of MSCs.     

Mitochondrial gene expression and increased oxidative metabolism: role in increased lifespan of fat-specific insulin receptor knock-out mice

Caloric restriction, leanness and decreased activity of insulin/insulin-like growth factor 1 (IGF-1) receptor signaling are associated with increased longevity in a wide range of organisms from Caenorhabditis elegans to humans. Fat-specific insulin receptor knock-out (FIRKO) mice represent an interesting dichotomy, with leanness and increased lifespan, despite normal or increased food intake. To determine the mechanisms by which a lack of insulin signaling in adipose tissue might exert this effect, we performed physiological and gene expression studies in FIRKO and control mice as they aged. At the whole body level, FIRKO mice demonstrated an increase in basal metabolic rate and respiratory exchange ratio. Analysis of gene expression in white adipose tissue (WAT) of FIRKO mice from 6 to 36 months of age revealed persistently high expression of the nuclear-encoded mitochondrial genes involved in glycolysis, tricarboxylic acid cycle, β-oxidation and oxidative phosphorylation as compared to expression of the same genes in WAT from controls that showed a tendency to decline in expression with age. These changes in gene expression were correlated with increased cytochrome c and cytochrome c oxidase subunit IV at the protein level, increased citrate synthase activity, increased expression of peroxisome proliferator-activated receptor γ coactivator 1α (PGC-1α) and PGC-1β, and an increase in mitochondrial DNA in WAT of FIRKO mice. Together, these data suggest that maintenance of mitochondrial activity and metabolic rates in adipose tissue may be important contributors to the increased lifespan of the FIRKO mouse.     

Activation of ITLN-1 attenuates oxidative stress injury via activating SIRT1/PGC1-α signaling in neuroblastoma cells

Cerebral injury is closely associated with enhanced oxidative stress. A newly discovered secretory adipocytokine, intelectin-1 (ITLN-1), has been shown to have beneficial effects in neuroprotection in epidemiological studies. However, the specific molecular mechanism of ITLN-1 in protecting against cerebral oxidative stress needs further investigation. In this study, we hypothesize that ITLN-1 plays a protective role against oxidative stress injury through the SIRT1/PGC1-α signaling pathway in neuromatocytes. We used hydrogen peroxide (H₂O₂) as a oxidative stress model to simulate oxidative stress injury. Then, small interfering RNAs (siRNAs) was used to knock down SIRT1 in N2a cells with or without ITLN overexpression, followed by H₂O₂-induced injury. We observed that H₂O₂ injury significantly decreased the levels of ITLN-1, SIRT1, and PGC-1α. However, ITLN overexpression reversed H₂O₂-induced decline in cell viability and rise in apoptosis and intracellular ROS levels in N2a cells, while ITLN siRNA worsened the neurocyte injury. Furthermore, SIRT1 knockdown reversed the positive effect of ITLN overexpression on oxidative stress injury in N2a cells. Taken together, these findings suggest that ITLN-1 exerts neuroprotective effects against oxidative stress injury primarily through the SIRT1/PGC-1α axis.     

环境变化和时序衰老过程中酵母蛋白激酶Sch9磷酸化的调控

出芽酵母(Saccharomyces cerevisiae)蛋白激酶Sch9与哺乳动物蛋白激酶S6K1同源.S6K1是哺乳动物雷帕霉素靶蛋白(mTOR)和磷脂酰肌醇3激酶(PI3K)的底物,且与很多人类疾病相关,包括肥胖症、糖尿病和癌症.Sch9和S6K1都对不同营养条件和环境胁迫条件下的细胞生长调控很重要.Sch9激活环内的磷酸化位点570位苏氨酸残基也被称为PDK1位点,而737位苏氨酸位点也被称为PDK2位点,这两个位点的磷酸化对Sch9的活性非常重要.蛋白激酶Pkh1/2磷酸化Sch9的PDK1位点,而雷帕霉素靶蛋白复合体1(TORC1)磷酸化PDK2位点.为了深入了解Sch9在细胞中的功能,阐明不同环境条件下及时序衰老过程中Sch9的PDK1和PDK2位点磷酸化的调控就显得尤为重要.利用特异性识别570位苏氨酸残基磷酸化的Sch9蛋白和特异性识别737位苏氨酸残基磷酸化的Sch9蛋白的两种抗体,对不同环境条件下和时序衰老过程中Sch9的两个位点的磷酸化调控进行了研究.研究结果揭示了Sch9的两个磷酸化位点在营养感受、胁迫应答、热量限制和时序衰老过程中的调控方式.揭示Sch9的PDK1位点磷酸化的调控与热量限制延长出芽酵母时序寿命密切相关.     

Relationship between alpha synuclein phosphorylation, proteasomal inhibition and cell death: relevance to Parkinson's disease pathogenesis

Alpha synuclein can be phosphorylated at serine129 (P-S129), and the presence of highly phosphorylated α-synuclein in Lewy bodies suggests changes to its phosphorylation status has an important pathological role. We demonstrate that the kinase(s) responsible for α-synuclein S129 phosphorylation is constitutively active in SH-SY5Y cells and involves casein kinase 2 activity. Increased oxidative stress or proteasomal inhibition caused significant elevation of P-S129 α-synuclein levels. Under these conditions, similar increases in P-S129 α-synuclein were found in both sodium dodecyl sulphate lysates and Triton extracts indicating the phosphorylated protein was soluble and did not lead to aggregation. The rate of S129 phosphorylation was increased in response to proteasomal inhibition indicating a higher activity of the relevant kinase. Cells expressing the phosphorylation mimic, S129D α-synuclein increased cell death and enhanced sensitivity to epoxomycin exposure. Proteasomal inhibition markedly decreased S129D α-synuclein turnover suggesting proteasomal inhibition leads to the accumulation of P-S129 α-synuclein through an increase in the kinase activity and a decrease in protein turnover resulting in increased cell death. We conclude that S129 phosphorylation is toxic to dopaminergic cells and both the levels of S129 phosphorylated protein and its toxicity are increased with proteasomal inhibition emphasising the interdependence of these pathways in Parkinson's disease pathogenesis.