丹参二萜醌类活性成分通过PKCδ/PKD1μ信号通路抗胰腺癌的作用研究

摘要 目的 验证丹参二萜醌类活性成分对胰腺癌和多发性骨髓瘤的抑制效应，阐明其诱导胰腺癌和多发性骨髓瘤凋亡的作用机制。方法 胰腺癌细胞AsPC-1、BxPC-3用含10% gibco胎牛血清的RPMI1640培养液培养，按隐丹参酮组（30μM）、丹参新酮组（15μM）、去氢丹参新酮组（15μM）分别加药处理。cell-counting-kit-8（CCK8）法检测细胞存活率；AnnexinⅤ-FITC/PI流式细胞术检测细胞凋亡；Western Blot检测相关PKC同工酶磷酸化水平；对AsPC-1和BxPC-3细胞进行siRNA转染，Western Blot检测相关PKC同工酶磷酸化水平。结果 隐丹参酮组AsPC-1、BxPC-3细胞存活率分别为40.1%±5.0%、36.2%±5.4%；丹参新酮组AsPC-1、BxPC-3细胞存活率分别为52.1%±5.1%、47.2%±5.7%；去氢丹参新组AsPC-1、BxPC-3细胞存活率分别为46.1%±5.0%、42.2%±5.4%(P<0.01)。流式细胞术结果显示：AsPC-1组内空白对照组、隐丹参酮组、丹参新酮组、去氢丹参新酮组细胞的凋亡率分别为4.71%、30.10%、52.26%、42.30%；BxPC-3组内空白对照组、隐丹参酮组、丹参新酮组、去氢丹参新酮组细胞的凋亡率分别为5.10%、30.66%、33.76%、51.76%（P<0.01）。Western Blot检测显示隐丹参酮组、丹参新酮组、去氢丹参新酮组较空白对照组，胰腺癌AsPC-1、BxPC-3细胞p-PKD/PKCμ ser916、p-PKCδ thr505、p-PKD/PKCμ ser744/748的水平降低。Western Blot检测显示，siRNA沉默胰腺癌AsPC-1、BxPC-3细胞PKCδ，胰腺癌AsPC-1、BxPC-3细胞PKD/PKCμ ser744/748的磷酸化水平下调。结论 隐丹参酮、丹参新酮、去氢丹参新酮通过抑制PKCδthr505的磷酸化水平，继而PKD1μser744/748磷酸化水平下调，从而显著促进胰腺癌AsPC-1和BxPC-3细胞凋亡发生。     

Hydrogen peroxide mediated the neurotoxicity of an antibody against plasmalemmal neuronspecific enolase in primary cortical neurons

Neuron-specific enolase (NSE) is not only a glycolytic enzyme in the cytosol, but also localized in the synaptic plasma membrane. The plasmalemmal NSE is one of autoantigen targets in post-streptococcal autoimmune central nervous system disease. Although anti-neuronal antibodies in patients bind to a restricted group of NSE in cerebral cortex, it has not yet been clarified how the anti-NSE antibody have negative impacts on cortical neurons. Here, we found that NSE was also localized at neuronal cell bodies and neuritis on the neuronal cell surface in the primary culture of rat cortical neurons. The anti-NSE antibody induced neuronal cell death in a concentration-dependent manner. The neuronal cell death required a lag time and was not accompanied with caspase-3 activation and chromatin condensation. The anti-NSE antibody elevated a level of intracellular H₂O₂ prior to neuronal cell death. Catalase protected neurons from the anti-NSE antibody-induced H₂O₂ generation and cell death. The post-treatment of neurons with catalase after the application of the anti-NSE antibody exhibited neuroprotective effects as well as the co-treatment. The cascade of mitogen-activated protein kinase (MAPK) is one of signal transductions of H₂O₂. Among MAPK, a c-Jun N-terminal kinase partially contributed to the neurotoxicity of anti-NSE antibody. Thus, the anti-NSE antibody acted at the plasmalemmal NSE, produced H₂O₂, and caused neuronal cell death via non-apoptotic pathway in the cortical neurons.     

Role of pharmacogenomics and pharmacodynamics in the treatment of acute lymphoblastic leukaemia

Pharmacodynamic studies have been used to establish the relationships between the administered dosage and the concentration of drugs and metabolites in the blood or tissues and that between these concentrations and pharmacological effects. Polymorphisms in the genes that encode drug-metabolizing enzymes, drug transporters and drug targets can affect a person's response to therapy and may affect the development of de novo or therapy-related leukaemias. The burgeoning field of pharmacogenomics elucidates inherited differences in drug metabolism and treatment response. Increasingly, pharmacodynamic and pharmacogenomic studies are being used to individualize therapy to enhance efficacy and reduce toxicity.     

Chemoprevention of liver cancer by plant polyphenols

Primary liver cancer or hepatocellular carcinoma (HCC) is one of the most frequent tumors representing the fifth commonest malignancy worldwide and the third cause of mortality from cancer. Currently, the treatments for HCC are not so effective and new strategies are needed for its fight. Chemoprevention, the use of natural or synthetic chemical agents to reverse, suppress or prevent carcinogenesis is considered an important way for confronting HCC. Many of the chemopreventive agents are phytochemicals, namely non-nutritive plant chemicals with protective or disease preventive properties. In this review, we focus on plant polyphenols, one of the most important classes of phytochemicals, their chemopreventive properties against HCC and discuss the molecular mechanisms accounting for this activity.     

Chronic methylphenidate induces increased quinone production and subsequent depletion of the antioxidant glutathione in the striatum

BackgroundMethylphenidate (Ritalin®) is a psychostimulant used chronically to treat attention deficit hyperactivity disorder. Methylphenidate acts by preventing the reuptake of dopamine and norepinephrine, resulting in an increase in these neurotransmitters in the synaptic cleft. Excess dopamine can be autoxidized to a quinone that may lead to oxidative stress. The antioxidant, glutathione helps to protect the cell against quinones via conjugation reactions; however, depletion of glutathione may result from excess quinone formation. Chronic exposure to methylphenidate appears to sensitize dopaminergic neurons to the Parkinsonian toxin 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP). We hypothesized that oxidative stress caused by the autooxidation of the excess dopamine renders dopaminergic neurons within the nigrostriatal pathway to be more sensitive to MPTP.MethodsTo test this hypothesis, male mice received chronic low or high doses of MPH and were exposed to saline or MPTP following a 1-week washout. Quinone formation in the striatum was examined via dot blot, and striatal GSH was quantified using a glutathione assay.ResultsIndeed, quinone formation increased with increasing doses of methylphenidate. Additionally, methylphenidate dose-dependently resulted in a depletion of glutathione, which was further depleted following MPTP treatment.ConclusionsThus, the increased sensitivity of dopamine neurons to MPTP toxicity following chronic methylphenidate exposure may be due to quinone production and subsequent depletion of glutathione.     

Small changes in enzyme function can lead to surprisingly large fitness effects during adaptive evolution of antibiotic resistance

In principle, evolutionary outcomes could be largely predicted if all of the relevant physicochemical variants of a particular protein function under selection were known and integrated into an appropriate physiological model. We have tested this principle by generating a family of variants of the tetracycline resistance protein TetX2 and identified the physicochemical properties most correlated with organismal fitness. Surprisingly, small changes in the K_m(MCN), less than twofold, were sufficient to produce highly successful adaptive mutants over clinically relevant drug concentrations. We then built a quantitative model directly relating the in vitro physicochemical properties of the mutant enzymes to the growth rates of bacteria carrying a single chromosomal copy of the tet(X2) variants over a wide range of minocycline (MCN) concentrations. Importantly, this model allows the prediction of enzymatic properties directly from cellular growth rates as well as the physicochemical-fitness landscape of TetX2. Using experimental evolution and deep sequencing to monitor the allelic frequencies of the seven most biochemically efficient TetX2 mutants in 10 independently evolving populations, we showed that the model correctly predicted the success of the two most beneficial variants tet(X2)_T280A and tet(X2)_N371I. The structure of the most efficient variant, TetX2_T280A, in complex with MCN at 2.7 Å resolution suggests an indirect effect on enzyme kinetics. Taken together, these findings support an important role for readily accessible small steps in protein evolution that can, in turn, greatly increase the fitness of an organism during natural selection.     

KLF6和WWOX蛋白在结直肠癌组织中的表达及意义

目的:探讨KLF6和WWOX蛋白在结直肠癌组织中的表达及其临床病理意义.方法:采用免疫组织化学法分别检测40例结直肠癌及40例正常结直肠黏膜组织中KLF6和WWOX蛋白的表达,并分析两者的表达水平与其,临床病理因素的关系.结果:结直肠癌组织中的KLF6和WWOX蛋白的阳性表达率明显低于正常结直肠黏膜组织(45.0% v...     

WWOX,the common fragile site FRA16D gene product,regulates ATM activation and the DNA damage response

Genomic instability is a hallmark of cancer. The WW domain-containing oxidoreductase (WWOX) is a tumor suppressor spanning the common chromosomal fragile site FRA16D. Here, we report a direct role of WWOX in DNA damage response (DDR) and DNA repair. We show that Wwox deficiency results in reduced activation of the ataxia telangiectasia-mutated (ATM) checkpoint kinase, inefficient induction and maintenance of γ-H2AX foci, and impaired DNA repair. Mechanistically, we show that, upon DNA damage, WWOX accumulates in the cell nucleus, where it interacts with ATM and enhances its activation. Nuclear accumulation of WWOX is regulated by its K63-linked ubiquitination at lysine residue 274, which is mediated by the E3 ubiquitin ligase ITCH. These findings identify a novel role for the tumor suppressor WWOX and show that loss of WWOX expression may drive genomic instability and provide an advantage for clonal expansion of neoplastic cells.Genomic instability is a common characteristic of human cancers. The DNA damage response (DDR) maintains the integrity of the genome in response to DNA damage. DDR is a complex signaling process that results in cell cycle arrest followed by either DNA repair or apoptosis if the DNA damage is too extensive to be repaired (1–3). Key mammalian damage response sensors are ataxia telangiectasia-mutated (ATM), ATM and Rad3-related, and DNA-dependent PKs (4, 5). Disruption of the DDR machinery in human cells leads to genomic instability and an increased risk of cancer progression (6, 7).The WW domain-containing oxidoreductase (WWOX) gene spans the common fragile site (CFS) FRA16D (8, 9). Genomic alterations affecting the WWOX locus have been reported in several types of cancer and include homozygous and hemizygous deletions (10–13). Ectopic expression of WWOX in WWOX-negative cancer cells attenuates cell growth and suppresses tumor growth in immunocompromised mice (10, 11, 14). Importantly, targeted ablation of Wwox in mice results in higher incidence of spontaneous lesions resembling osteosarcomas and lung and mammary tumors (14–16). These findings suggest WWOX as a tumor suppressor. The WWOX protein contains two N-terminal WW domains mediating WWOX interaction with PP(proline)x(amino acid)Y(tyrosine)-containing proteins (11, 17) and a central short-chain deyhdrogenase/reductase domain that has been proposed to function in steroidogenesis (18). Recent characterization of WWOX domains revealed that they interact, mainly through the WW1 domain, with multiprotein networks (3). The mechanism by which WWOX suppresses tumorigenicity is, however, not well-known.In vitro, CFSs are defined as gaps or breaks on metaphase chromosomes that occur in cells treated with inhibitors of DNA replication (19, 20). In vivo, CFSs are preferential targets of replication stress in preneoplastic lesions (21), and emerging evidence suggests that they represent early warning sensors for DNA damage (22–24). Both genetic and epigenetic factors are thought to regulate the fragility of CFS (25, 26). Recent profiling studies of CFS provide evidence that the functional fragility of CFS is tissue-specific (27–29). High-throughput genomic analyses of 3,131 cancer specimens (12) and 746 cancer cell lines (13) have recently identified large deletions in CFSs, including the FRA16D/WWOX locus. Although these deletions have been linked to the presence of DNA replication stress (30), the molecular function of gene products of CFSs, including the WWOX protein, is poorly understood. Here, we identify a direct role of WWOX in the DDR and show that the WWOX gene product functions as a modulator of the DNA damage checkpoint kinase ATM.