短时重复游泳调节SAM8鼠AMPA受体GluR1亚单位的磷酸化

目的观察短时重复游泳训练对SAM鼠AMPA受体GluR1亚单位磷酸化的影响,探讨运动改善脑功能的可能机制。方法选取3月龄SAMP8(prone/8)亚系为研究对象,运动模型采用2 w游泳方案:2次/d,每次6 min的游泳,结束后给予浴巾擦干放回鼠笼;对照组则在相同时间每天给予两次相同的浴巾安抚刺激。采用Western印迹方法,检测SAM8鼠海马和皮层AMPA受体GluR1亚单位Ser831和Ser 845位点的磷酸化水平的变化。结果 SAMP8海马、皮层中AMPA受体GluR1亚单位Ser831和Ser845磷酸化水平与对照组相比均增加(P<0.05)。结论 2 w的短时间重复游泳运动作为一种应激诱导剂促进了AMPA受体的活化,这可能是运动改善脑功能的机制之一。     

亚低温抑制重型颅脑创伤诱导Tau蛋白过度磷酸化的实验研究

目的 观察亚低温对重型颅脑创伤诱导的Tau蛋白磷酸化的影响.方法 体外研究通过细胞液压冲击仪建立SK-N-SH细胞损伤模型,观察冲击1h、6h和12h后Tau蛋白的磷酸化水平.体内研究通过小动物液压冲击仪建立大鼠重型颅脑损伤模型(2.4 atm),接受或不接受亚低温治疗(33℃,4h).观察液压冲击6h、24 h和72 h后Tau蛋白的磷酸化水平,以及亚低温对此变化的影响.结果 SK-N-SH细胞在液压冲击后,Tau蛋白在Thr231和Ser396位点的磷酸化水平从1h开始升高,到6h左右达到高峰.SD大鼠在液压冲击后,Tau蛋白在Thr231和Ser396位点的磷酸化水平从6h开始升高,到24h左右达到高峰,到72 h仍处于高水平;免疫组化的结果也显示,大鼠脑部海马CA1区和皮质区的Tau蛋白磷酸化水平在Thr231位点也明显增高.亚低温可显著逆转液压冲击诱导的SD大鼠Tau蛋白过度磷酸化(P＜0.01).结论 亚低温可抑制重型颅脑创伤诱导的Tau蛋白过度磷酸化.     

Site directed mutagenesis of Drosophila flightin disrupts phosphorylation and impairs flight muscle structure and mechanics

Flightin is a myosin rod binding protein that in Drosophila melanogaster is expressed exclusively in the asynchronous indirect flight muscles (IFM). Hyperphosphorylation of flightin coincides with the completion of myofibril assembly and precedes the emergence of flight competency in young adults. To investigate the role of flightin phosphorylation in vivo we generated three flightin null (fln ⁰ ) Drosophila strains that express a mutant flightin transgene with two (Thr158, Ser 162), three (Ser139, Ser141, Ser145) or all five potential phosphorylation sites mutated to alanines. These amino acid substitutions result in lower than normal levels of flightin accumulation and transgenic strains that are unable to beat their wings. On two dimensional gels of IFM proteins, the transgenic strain with five mutant sites (fln ^5STA ) is devoid of all phosphovariants, the transgenic strain with two mutant sites (fln ^2TSA ) expresses only the two least acidic of the nine phosphovariants, and the transgenic strain with three mutant sites (fln ^3SA ) expresses all nine phosphovariants, as the wild-type strain. These results suggest that phosphorylation of Thr158 and/or Ser162 is necessary for subsequent phosphorylation of other sites. All three transgenic strains show normal, albeit long, IFM sarcomeres in newly eclosed adults. In contrast, sarcomeres in fully mature fln ^5STA and fln ^2TSA adults show extensive breakdown while those in fln ^3SA are not as disordered. The fiber hypercontraction phenotype that characterizes fln ⁰ is fully evident in fln ^5STA and fln ^2TSA but partially rescued in fln ^3SA . Mechanics on skinned fibers from newly eclosed flies show alterations in viscous modulus for fln ^5STA and fln ^2TSA that result in a significant reduction in oscillatory power output. Expression of fln ^5STA and fln ^2TSA , but not fln ^3SA , in a wild-type (fln ⁺ /fln ⁺ ) background resulted in a dominant negative effect manifested as flight impairments and hypercontracted IFM fibers. Our studies indicate that Thr158 and/or Ser162 are (is) indispensable for flightin function and suggest that phosphorylation of one or both residues fulfills an essential role in IFM structural stability and mechanics.     

A Multiscale Computational Approach to Dissect Early Events in the Erb Family Receptor Mediated Activation,Differential Signaling,and Relevance to Oncogenic Transformations

We describe a hierarchical multiscale computational approach based on molecular dynamics simulations, free energy-based molecular docking simulations, deterministic network-based kinetic modeling, and hybrid discrete/continuum stochastic dynamics protocols to study the dimer-mediated receptor activation characteristics of the Erb family receptors, specifically the epidermal growth factor receptor (EGFR). Through these modeling approaches, we are able to extend the prior modeling of EGF-mediated signal transduction by considering specific EGFR tyrosine kinase (EGFRTK) docking interactions mediated by differential binding and phosphorylation of different C-terminal peptide tyrosines on the RTK tail. By modeling signal flows through branching pathways of the EGFRTK resolved on a molecular basis, we are able to transcribe the effects of molecular alterations in the receptor (e.g., mutant forms of the receptor) to differing kinetic behavior and downstream signaling response. Our molecular dynamics simulations show that the drug sensitizing mutation (L834R) of EGFR stabilizes the active conformation to make the system constitutively active. Docking simulations show preferential characteristics (for wildtype vs. mutant receptors) in inhibitor binding as well as preferential enhancement of phosphorylation of particular substrate tyrosines over others. We find that in comparison to the wildtype system, the L834R mutant RTK preferentially binds the inhibitor erlotinib, as well as preferentially phosphorylates the substrate tyrosine Y1068 but not Y1173. We predict that these molecular level changes result in preferential activation of the Akt signaling pathway in comparison to the Erk signaling pathway for cells with normal EGFR expression. For cells with EGFR over expression, the mutant over activates both Erk and Akt pathways, in comparison to wildtype. These results are consistent with qualitative experimental measurements reported in the literature. We discuss these consequences in light of how the network topology and signaling characteristics of altered (mutant) cell lines are shaped differently in relationship to native cell lines. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users. These authors contributed equally     

CFTR (ABCC7) is a hydrolyzable-ligand-gated channel

As the product of the gene mutated in cystic fibrosis, the most common genetic disease of Caucasians, CFTR is an atypical ABC protein. From an evolutionary perspective, it is apparently a relatively young member of the ABC family, present only in metazoans where it plays a critical role in epithelial salt and fluid homeostasis. Functionally, the membrane translocation process it mediates, the passive bidirectional diffusion of small inorganic anions, is simpler than the vectorial transport of larger more complex substrates (“allocrites”) by most ABC transporters. However, the control of the permeation pathway which cannot go unchecked is necessarily more stringent than in the case of the transporters. There is tight regulation by the phosphorylation/dephosphorylation of the unique CFTR R domain superimposed on the basic ABC regulation mode of ATP binding and hydrolysis at the dual nucleotide binding sites. As with other ABCC subfamily members, only the second of these sites is hydrolytic in CFTR. The phosphorylation and ATP binding/hydrolysis events do not strongly influence each other; rather, R domain phosphorylation appears to enable transduction of the nucleotide binding allosteric signal to the responding channel gate. ATP hydrolysis is not required for either the opening or closing gating transitions but efficiently clears the ligand-binding site enabling a new gating cycle to be initiated.     

A representative of arylcyanomethylenequinone oximes effectively inhibits growth and formation of hyphae in Candida albicans and influences the activity of protein kinases in vitro

In this study, we applied various assays to reveal new activities of phenylcyanomethylenequinone oxime-4-(hydroxyimino) cyclohexa-2,5-dien-1-ylidene](phenyl)ethanenitrile (4-AN) for potential anti-microbial applications. These assays demonstrated (a) the antimicrobial effect on bacterial and fungal cultures, (b) the effect on the in vitro activity of the kinase CK2, (c) toxicity towards human erythrocytes, the Caco-2 cancer cell line, and embryonic development of Zebrafish. We demonstrated the activity of 4-AN against selected bacteria and Candida spp. The MIC ranging from 4?µg/ml to 125?µg/ml proved effective in inhibition of formation of hyphae and cell aggregation in Candida, which was demonstrated at the cytological level. Noteworthy, 4-AN was found to inhibit the CK2 kinase with moderate potency. Moreover, at low concentrations, it did not exert any evident toxic effects on human erythrocytes, Caco-2 cells, or Zebrafish embryos. 4-AN can be a potential candidate as a novel drug against Candida infections.     

Characteristics of Diprophylline-Induced Bidirectional Modulation on Rat Jejunal Contractility

In this study, we propose that diprophylline exerts bidirectional modulation (BM) on the isolated rat jejunal segment depending on its contractile state. The results supported the hypothesis. Diprophylline (20 µM) exerted stimulatory effects on the contractility of jejunal segment in six low contractile states while inhibitory effects in six high contractile states, showing the characteristics of BM. Diprophylline-induced stimulatory effect was significantly blocked by atropine, indicating the correlation with cholinergic activation. Diprophylline-induced inhibitory effect was partially blocked by phentolamine, propranolol, and L-N-Nitro-Arginine respectively, indicating their correlation with sympathetic activation and nitric oxide-mediated relaxing mechanisms. Diprophylline-induced BM was abolished by tetrodotoxin or in a Ca²⁺ free condition or pretreated with tyrosine kinase inhibitor imatinib, suggesting that diprophylline-induced BM is Ca²⁺ dependent, and that it requires the presence of enteric nervous system as well as pacemaker activity of interstitial cells of Cajal. Diprophylline significantly increased the reduced MLCK expression and myosin extent in constipation-prominent rats and significantly decreased the increased MLCK expression and myosin extent in diarrhea-prominent rats, suggesting that the change of MLCK expression may also be involved in diprophylline-induced BM on rat jejunal contractility. In summary, diprophylline-exerted BM depends on the contractile states of the jejunal segments, requires the presence of Ca²⁺, enteric nervous system, pacemaker activity of interstitial cells of Cajal, and MLCK-correlated myosin phosphorylation. The results suggest the potential implication of diprophylline in relieving alternative hypo/hyper intestinal motility.     

Threonine-17 phosphorylation of phospholamban: a key determinant of frequency-dependent increase of cardiac contractility

Multiple studies have shown that phospholamban (PLN) plays a key role in regulation of frequency-dependent increase of cardiac contraction, a hallmark of the contractile reserve in myocardium. However, the mechanisms underlying this relationship remain elusive. Phosphorylation of PLN occurs on residues: serine-16 (Ser(16)) and threonine-17 (Thr(17)) in vivo. In isolated wild-type cardiomyocytes, we found that increases of stimulation frequency from 0.5 to 5 Hz were associated with increased Thr(17) phosphorylation of PLN and cardiac contractility. To further delineate the role of PLN phosphorylation in the frequency-dependent increases of cardiac function, three transgenic mouse models, expressing wild-type, Ser16Ala (S16A), or Thr17Ala (T17A) mutant PLN in the null background were generated. Transgenic lines expressing similar levels of wild-type or mutant PLN were selected and isolated cardiomyocytes were paced from 0.5 to 5 Hz. Upon increases in pacing frequency, the fractional shortening (FS) and rates of contraction (+dL/dt) and relaxation (-dL/dt) increased in wild-type and S16A mutant PLN cardiomyocytes. In contrast, in myocytes expressing the T17A mutant PLN, there were no increases in FS and +/-dL/dt upon increasing the frequency of stimulation. The time to 50% peak shortening (TTP(50)) and to 50% relaxation (TTR(50)) were also abbreviated to a much higher extent (two-fold) in wild-type and S16A mutant compared to T17A mutant PLN cardiomyocytes. These results indicate that Thr(17) phosphorylation of PLN is the major contributor to frequency-dependent increases of contractile and relaxation parameters in mouse cardiomyocytes, although some increases in these parameters occur even in the absence of PLN phosphorylation. Thus, the positive force-frequency relationship in cardiomyocytes is mechanistically and mainly related to PLN phosphorylation.