1.Role of p66Shc gene in human longevity.
Jun LI ; Jian GUAN ; Ren-Zhi WANG ; Ning WANG
Acta Academiae Medicinae Sinicae 2014;36(6):686-690
The p66Shc gene has emerged as a novel gerontogene affecting health and life during aging. In murine models of aging,a genetic deficiency of the p66Shc gene,which encodes a phosphotyrosine signal adapter protein,extends life span by 30%. p66Shc is a crucial regulator of reactive oxygen species levels and is involved in age-related dysfunctions. UP to now,oxidative stress has been recognized to be involved in human diseases such as high cholesterol,diabetes,and cardiovascular diseases. Further study on the role of p66Shc will facilitate the research of novel disease-targetted drugs and slow down or cure age-related pathologies.
Aging
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genetics
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Animals
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Humans
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Longevity
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genetics
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Mice
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Oxidative Stress
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physiology
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Reactive Oxygen Species
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metabolism
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Shc Signaling Adaptor Proteins
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genetics
2.Study of senescence protein p66Shc on myocardial tissue repair in adult mice.
Yuan ZHANG ; Cheng-Zhen HUANG ; Hou-Zao CHEN ; Yu NIE ; Miao-Qing HU
Acta Physiologica Sinica 2023;75(6):946-952
Our previous study has shown that p66Shc plays an important role in the process of myocardial regeneration in newborn mice, and p66Shc deficiency leads to weakened myocardial regeneration in newborn mice. This study aims to explore the role of p66Shc protein in myocardial injury repair after myocardial infarction in adult mice, in order to provide a new target for the treatment of myocardial injury after myocardial infarction. Mouse myocardial infarction models of adult wild-type (WT) and p66Shc knockout (KO) were constructed by anterior descending branch ligation. The survival rate and heart-to-body weight ratio of two models were compared and analyzed. Masson's staining was used to identify scar area of injured myocardial tissue, and myocyte area was determined by wheat germ agglutinin (WGA) staining. TUNEL staining was used to detect the cardiomyocyte apoptosis. The protein expression of brain natriuretic peptide (BNP), a common marker of myocardial hypertrophy, was detected by Western blotting. The results showed that there was no significant difference in survival rate, myocardial scar area, myocyte apoptosis, and heart weight to body weight ratio between the WT and p66ShcKO mice after myocardial infarction surgery. Whereas the protein expression level of BNP in the p66ShcKO mice was significantly down-regulated compared with that in the WT mice. These results suggest that, unlike in neonatal mice, the deletion of p66Shc has no significant effect on myocardial injury repair after myocardial infarction in adult mice.
Animals
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Mice
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Body Weight
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Cicatrix/metabolism*
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Mice, Knockout
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Myocardial Infarction/genetics*
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Oxidative Stress
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Shc Signaling Adaptor Proteins/metabolism*
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Src Homology 2 Domain-Containing, Transforming Protein 1/metabolism*
3.ShcD interacts with TrkC through its PTB and SH2 domains.
Yuan-gang YOU ; Wei-qi LI ; Bin YIN ; Xiao-zhong PENG
Acta Academiae Medicinae Sinicae 2009;31(6):720-723
OBJECTIVETo study the interaction between ShcD and TrkC and to reveal the molecular mechanism of the downstream signal transduction of TrkC.
METHODSYeast two-hybrid assay was used. The intracellular domains of TrkC and TrkC mutants were cloned into pAS2-1, and ShcD and its four domains (CH2, PTB, CH1, and SH2 domains) were cloned into pACT2 vector respectively. The constructs were separately cotransformed into yeast. beta-galactosidase activity was measured to detect their interactions. TrkC was cloned into pmRFP (carrying red fluorescent protein), and ShcD was cloned into pEGFP (carrying green fluorescent protein). pmRFP-TrkC and pEGFP-ShcD were co-transfected into 293T cells, and then the cells were fixed and subjected to confocal analysis to study their subcellular localization.
RESULTSShcD interacted with TrkC but not with kinase dead mutant TrkCM1(K572A). Both PTB and SH2 domains were capable of binding to TrkC, and PTB domain bound NPQY motif of TrkC. ShcD colocalized with TrkC throughout the cytoplasm and in the plasma membrane in 293T cells.
CONCLUSIONShcD binds to TrkC in a kinase-activity-dependent manner through its PTB and SH2 domains.
Adaptor Proteins, Signal Transducing ; genetics ; metabolism ; Binding Sites ; Cells, Cultured ; Genetic Vectors ; Humans ; Plasmids ; genetics ; Protein Binding ; Receptor, trkC ; genetics ; metabolism ; Shc Signaling Adaptor Proteins ; genetics ; metabolism ; Transfection ; Transformation, Bacterial ; Two-Hybrid System Techniques ; src Homology Domains ; genetics
4.Regulation of tumor cell migration by protein tyrosine phosphatase (PTP)-proline-, glutamate-, serine-,and threonine-rich sequence (PEST).
Chinese Journal of Cancer 2013;32(2):75-83
Protein tyrosine phosphatase (PTP)-proline-, glutamate-, serine-, and threonine-rich sequence (PEST) is ubiquitously expressed and is a critical regulator of cell adhesion and migration. PTP-PEST activity can be regulated transcriptionally via gene deletion or mutation in several types of human cancers or via post-translational modifications, including phosphorylation, oxidation, and caspase-dependent cleavage. PTP-PEST interacts with and dephosphorylates cytoskeletal and focal adhesion-associated proteins. Dephosphorylation of PTP-PEST substrates regulates their enzymatic activities and/or their interaction with other proteins and plays an essential role in the tumor cell migration process.
Cell Adhesion
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Cell Movement
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Focal Adhesion Protein-Tyrosine Kinases
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metabolism
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Humans
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Neoplasms
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metabolism
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pathology
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Oxidation-Reduction
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Phosphorylation
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Protein Processing, Post-Translational
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Protein Tyrosine Phosphatase, Non-Receptor Type 12
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metabolism
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Shc Signaling Adaptor Proteins
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metabolism
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rho GTP-Binding Proteins
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metabolism
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src-Family Kinases
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metabolism
5.Construction of a recombinant adenovirus Ad5F35-SD-EGFP and its effect on K562 cell proliferation.
Jing SHI ; Jing HU ; Qing XIAO ; Zhi PENG ; Wei-xi CAO ; Qiu-ping LUO ; Fang WANG ; Wen-li FENG
Journal of Southern Medical University 2011;31(11):1806-1811
OBJECTIVETo construct a recombinant adenovirus vector for SH2-DED fusion gene and assess its inhibitory effect on the proliferation of K562 cells.
METHODSSH2-DED fusion gene and its mutant SH2mt-DED were amplified by splicing PCR and cloned into pAdTrack-CMV plasmid separately to construct the shuttle plasmids pAdT-SD-EGFP and pAdT-SmD-EGFP, respectively. After Pme I digestion, the shuttle plasmids were transformed into ultra-competent pAd5F35-BJ5183 cells to generate defective adenovirus vectors pAd5F35-SD-EGFP and pAd5F35- SmD-EGFP by homologous recombination. The vectors, linearized by Pac I digestion, were further transfected into AD293 cells for packaging and amplified by infecting AD293 cells repeatedly. K562 cells were then infected by the recombinant adenoviruses and the expression of SD was detected by Western blotting. MTT assay and flow cytometry were used to investigate the effect of Ad5F35-SD-EGFP and Ad5F35-SmD-EGFP on the proliferation of K562 cells.
RESULTSThe recombinant adenovirus vectors pAd5F35-SD-EGFP and pAd5F35-SmD-EGFP were constructed correctly, with a titer reaching 1.5×10(12) pfu/ml after amplification. Western blotting demonstrated that the target proteins were effectively expressed in transfected K562 cells. MTT assay and flow cytometry showed that transfection with pAd5F35-SD-EGFP resulted in growth inhibition rate of 55.21% in K562 cells, significantly higher than the inhibition rate of 17.95% following transfection with pAd5F35- SmD-EGFP and 7.33% following PBS treatment (P<0.05).
CONCLUSIONThe recombinant adenovirus vector Ad5F35-SD-EGFP we constructed can significantly inhibit the proliferation of K562 cells in vitro.
Adenoviridae ; genetics ; metabolism ; Apoptosis Regulatory Proteins ; biosynthesis ; genetics ; Cell Proliferation ; drug effects ; Cloning, Molecular ; Genetic Vectors ; Green Fluorescent Proteins ; biosynthesis ; genetics ; Humans ; K562 Cells ; Leukemia, Myelogenous, Chronic, BCR-ABL Positive ; pathology ; Mutant Proteins ; genetics ; Recombinant Fusion Proteins ; biosynthesis ; genetics ; Repressor Proteins ; biosynthesis ; genetics ; Shc Signaling Adaptor Proteins ; biosynthesis ; genetics ; Transfection
6.Regulatory effects of Shc-related phosphotyrosine adaptor proteins on aging.
Pei ZHANG ; Takashi IKEJIMA ; Nozomu MORI
Acta Pharmaceutica Sinica 2008;43(8):793-800
Aging-related oxidative stress and free radical theory has become accepted increasingly as explaination, at least in part of the aging process. In murine models of aging, a genetic deficiency of the p66(Shc) (66-kilodalton isoform of Shc gene products) gene, which encodes a phosphotyrosine signal adapter protein, extends life span by 30%, and confers resistance to oxidative stress. Upon oxidative stress, p66(Shc) is phosphorylated at Ser36, contributing to inactivation of the forkhead-type transcription factors (FKHR/ FoxO1), which regulates the gene expression of cellular antioxidants. The p66(Shc) has a direct connection with the life span related signaling, which is conserved evolutionarily. Shc is basically not expressed in mature neurons of the adult brain and spinal cord. Instead, two Shc homologues, Sck/ShcB and N-Shc/ ShcC, which have been proved to be effective on oxidative stress and aging, are expressed in neural system. The expression of Shc-related genes is affected in the aging process, which may be relevant to cellular dysfunction, stress response and/or cognitive decline during aging.
Aging
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physiology
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Animals
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Brain
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metabolism
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Forkhead Box Protein O1
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Forkhead Transcription Factors
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metabolism
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Gene Deletion
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Humans
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Mice
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Neurons
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metabolism
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Oxidative Stress
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physiology
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Phosphorylation
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Shc Signaling Adaptor Proteins
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deficiency
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genetics
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metabolism
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physiology
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Signal Transduction
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physiology
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Spinal Cord
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metabolism
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Src Homology 2 Domain-Containing, Transforming Protein 1
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Src Homology 2 Domain-Containing, Transforming Protein 2
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Src Homology 2 Domain-Containing, Transforming Protein 3
7.Roles of PKCβ/P66Shc oxidative stress signal pathway in mediating hyperoxia-induced ROS production in alveolar epithelial cells.
Zhong-Li CHE ; Wen-Bin DONG ; Qing-Ping LI ; Xiao-Ping LEI ; Lan KANG ; Lin GUO ; Xue-Song ZHAI ; Feng CHEN
Chinese Journal of Contemporary Pediatrics 2015;17(3):275-280
OBJECTIVETo explore the roles of PKCβ/P66Shc oxidative stress signal pathway in mediating hyperoxia-induced reactive oxgen species (ROS) production in alveolar epithelial cells (A549) and the protective effects of PKCβ inhibitor on hyperoxia-induced injuries of alveolar epithelial cells.
METHODSA549 cells were cultured in vitro and randomly divided into three groups: control, hyperoxia and PKCβ inhibitor LY333531 treatment. The hyperoxia group was exposed to a mixture of O2 (950 mL/L) and CO2 (50 mL/L) for 10 minutes and then cultured in a closed environment. The LY333531 group was treated with PKCβ inhibitor LY333531 of 10 µmol/L for 24 hours before hyperoxia induction. Cells were collected 24 hours after culture and the levels of PKCβ, Pin1, P66Shc and P66Shc-Ser36 were detected by Western blot. The intracellular translocation of P66Shc, the production of ROS and cellular mitochondria membrane potential were measured using the confocal microscopy.
RESULTSCompared with the control group, the levels of PKCβ, Pin1, P66Shc and P-P66Shc-Ser36 in A549 cells 24 hours after culture increased significantly in the hyperoxia group. These changes in the hyperoxia group were accompanied with an increased translocation rate of P66Shc from cytoplasm into mitochondria, an increased production of mitochondrial ROS, and a reduced mitochondrial membrane potential. Compared with the hyperoxia group, the levels of Pin1, P66Shc and P66Shc-Ser36 in A549 cells, the translocation rate of P66Shc from cytoplasm into mitochondria and the production of mitochondrial ROS decreased significantly, while the mitochondrial membrane potential increased significantly in the LY333531 treatment group. However, there were significant differences in the above mentioned measurements between the LY333531 treatment and control groups.
CONCLUSIONSHyperoxia can increase the expression of PKCβ in alveolar epithelial cells and production of mitochondrial ROS and decrease mitochondrial membrane potential. PKCβ inhibitor LY333531 can partially disrupt these changes and thus alleviate the hyperoxia-induced alveolar epithelial cell injury.
Cell Hypoxia ; Cells, Cultured ; Epithelial Cells ; metabolism ; Humans ; Indoles ; pharmacology ; Maleimides ; pharmacology ; Oxidative Stress ; Protein Kinase C beta ; physiology ; Pulmonary Alveoli ; cytology ; metabolism ; Reactive Oxygen Species ; metabolism ; Shc Signaling Adaptor Proteins ; physiology ; Signal Transduction ; physiology ; Src Homology 2 Domain-Containing, Transforming Protein 1