DARPP-32磷酸化状态与左旋多巴诱发异动症形成间关系的研究

目的:研究纹状体区DARPP-32磷酸化水平变化和直接通路活动的改变在左旋多巴诱发的异动症(LID)形成中所起的作用。方法:以SCH23390(D1受体拮抗剂)治疗LID大鼠,观察LID大鼠的行为学改变,并用逆转录聚合酶链反应技术检测LID大鼠纹状体区前强啡肽原(PDyn)基因mRNA的表达情况,免疫印迹技术检测纹状体内DARPP-32蛋白Thr-34位点和Thr-75位点磷酸化修饰水平的变化。结果:LID大鼠纹状体区PDyn mRNA基因表达和磷酸化的Thr-34位点DARPP-32水平较对照组均明显增高,Thr-75位点磷酸化无显著改变。经SCH23390治疗后,LID大鼠异常不自主运动明显减少,PDyn基因表达和Thr-34位点磷酸化水平降低,Thr-75位点磷酸化水平升高。结论:大鼠纹状体区PDyn基因表达和Thr-34位点磷酸化水平的升高与LID的形成有关,提示直接通路活动异常及基底节环路功能异常参与了LID的发生。     

Methylmalonic and propionic acids increase the in vitro incorporation of P into cytoskeletal proteins from cerebral cortex of young rats through NMDA glutamate receptors

In this study we investigated the effects of methylmalonic acid (MMA) and propionic acid (PA) on the phosphorylation of cytoskeletal proteins of cerebral cortex of rats. Slices of tissue were incubated with ³²P-orthophosphate in the presence or absence of glutamate, MMA, PA and ionotropic or metabotropic glutamate receptor agonists. The cytoskeletal fraction was isolated and the radioactivity incorporated into the cytoskeletal proteins was measured. Results demonstrated that the acids, glutamate and NMDA increased the phosphorylation of the proteins studied. However, this effect was not observed for non-NMDA ionotropic agonists or metabotropic agonists. Experiments using glutamate receptor antagonists confirmed that MMA and PA at the same concentrations as found in tissues from propionic or methylmalonic acidemic children increase the phosphorylation of cytoskeletal proteins, possibly via NMDA glutamate receptors. Therefore, it is feasible that these findings may be related to the neurological dysfunction characteristic of these disorders.     

A cyclic nucleotide and calcium-independent protein kinase of chick brain: Activation by a heat-stable protein

A heat-stable trichloracetic acid-stable protein fraction stimulates protein kinase activity in chick brain cytosol. This protein kinase (tentatively referred to as protein kinase S) can be partially purified by chromatography on DEAE-cellulose and Sepharose G-100. The partially purified protein kinase has an absolute requirement for magnesium and the heat-stable protein for the phosphotransferase activity and is not influenced by cyclic nucleotides, calcium or ethylenediaminetetraacetic acid. The substrate specificity of protein kinase S indicates that it is not a casein kinase and prefers histones over the substrates tested. The specific activity of this protein kinase changes with chick brain development and the activity increased by two-fold by the second post-hatch week, suggesting a role of this protein kinase in chick brain development.     

Expression of the HFE allelic variant H63D in SH-SY5Y cells affects tau phosphorylation at serine residues

A number of genetic association studies have appeared that address HFE gene variants in neurodegenerative disorders. However, the cellular impact of HFE in the nervous system has received little attention. To begin to address the role of the HFE allelic variants on cellular events associated with neurodegeneration, we examined the hypothesis that HFE polymorphisms are associated with alterations in tau phosphorylation in a human neuroblastoma cell line (SH-SY5Y). The results show that in a cell culture model, the H63D allele is associated with increased tau phosphorylation. The mechanisms responsible for these changes appear related to increased glycogen synthase kinase (GSK)-3β activity. GSK-3β activity is up-regulated in the cells expressing H63D HFE and can be modified by the addition of iron or treatment with an iron chelator in SH-SY5Y cells expressing wild-type HFE. Oxidative stress, also associated with elevated cellular iron, is associated with increased tau phosphorylation at the same sites as seen in H63D cells and treatment with Trolox, an anti-oxidant, lowered tau phosphorylation. These results suggest H63D HFE increases tau phosphorylation via GSK-3β activity and iron-mediated oxidative stress.     

An immediate-early protein of white spot syndrome virus modulates the phosphorylation of focal adhesion kinase of shrimp

WSSV interacts with integrin during infection of shrimps and modulate the focal adhesion kinase which is known as a regulator of several downstream signaling pathways. Viral protein kinases are thought to be important for virus infection by regulating the host signaling pathways. WSV083 is an immediate-early gene of white spot syndrome virus that contains a Ser/Thr protein kinase domain. So, does WSSV modulate FAK phosphorylation via the WSV083 molecule? In this study, co-transfection of WSV083 and MjFAK genes proceeded in insect cells revealed that the MjFAK phosphorylation and cell adhesion activity could be inhibited by the expression of WSV083. Kinase domain mutants of WSV083 lost its ability of inhibiting FAK phosphorylation. Moreover, silencing of FAK gene through RNAi accelerated the shrimp death rate upon WSSV challenge. These results demonstrate for the first time that modulation of FAK phosphorylation by WSV083 plays a critical role in the pathogenesis of WSSV infection.     

β1-integrin mediates pressure-stimulated phagocytosis

Background

Extracellular pressure alterations in infection, inflammation, or positive pressure ventilation may influence macrophage phagocytosis. We hypothesized that pressure modulates β1-integrins to stimulate phagocytosis.

Methods

We assayed fibroblast phagocytosis of fluorescent latex beads at ambient or 20 mm Hg increased pressure, and macrophage integrin phosphorylation by Western blot.

Results

Pressure did not alter phagocytosis in β₁-integrin null GD25 fibroblasts, but stimulated phagocytosis in fibroblasts expressing wild-type β₁-integrin. In phorbol myristate acetate-differentiated THP-1 macrophages, pressure stimulated β₁-integrin T788/789 phosphorylation, but not S785 phosphorylation. Furthermore, pressure stimulated phagocytosis in cells expressing an inactivating S785A point mutation or a T788D substitution to mimic a constitutively phosphorylated threonine, but not in cells expressing an inactivating TT788/9AA mutation.

Conclusions

The effects of pressure on phagocytosis are not limited to macrophages but generalize to other phagocytic cells. These results suggest that pressure stimulates phagocytosis via increasing β₁-integrin T789 phosphorylation. Interventions that target β₁-integrin threonine 789 phosphorylation may modulate phagocytic function.     

Troponin phosphorylation and regulatory function in human heart muscle: dephosphorylation of Ser23/24 on troponin I could account for the contractile defect in end-stage heart failure

We made quantitative measurements of phosphorylation in troponin isolated from 6 non-failing donor hearts and 6 explanted hearts with end-stage heart failure in SDS-PAGE gels using Pro-Q Diamond phosphoprotein stain. The troponin T phosphorylation level was the same in troponin from failing and non-failing heart (3.1 mol Pi/mol). However, troponin I phosphorylation was significantly lower in failing (0.37+/-0.18 mol Pi/mol) compared with non-failing heart troponin (2.25+/-0.36 mol Pi/mol). Levels of troponin I PKA-dependent phosphorylation, measured with a phosphoserine 23/24-specific antibody, were also significantly lower in failing heart troponin (0.19+/-0.06 mol Pi/mol) compared to non-failing troponin (1.14+/-0.09 mol Pi/mol). We calculate that there is phosphorylation in addition to serine 23/24 of 1.11+/-0.34 mol Pi/mol in non-failing reduced to 0.18+/-0.17 mol Pi/mol in failing heart troponin, attributed to phosphorylation on the PKC sites. To test for the functional role of troponin I phosphorylation, the native troponin I from either non-failing or failing heart troponin was exchanged for a recombinant (unphosphorylated) human cardiac troponin I. Thin filament Ca(2+)-regulatory function was studied with the quantitative in vitro motility assay: thin filaments containing the replaced troponin I resulted in a failing phenotype of a 17-26% reduced sliding speed and an increased Ca(2+)-sensitivity relative to non-failing troponin (EC(50) TnI-exchanged/non-failing=0.57, p<0.001). When exchanged with troponin I phosphorylated with PKA motility parameters reverted to a pattern indistinguishable from non-failing troponin (p=0.35-0.75). We suggest that changes in troponin function can account for the contractile abnormality in failing heart muscle and that the functional changes in troponin are due to reduced phosphorylation of troponin I at the PKA sites.     

Temporal dissociation of frequency-dependent acceleration of relaxation and protein phosphorylation by CaMKII

Frequency-dependent acceleration of relaxation (FDAR) is an important intrinsic mechanism that allows for diastolic filling of the ventricle at higher heart rates, yet its molecular mechanism is still not understood. Previous studies showed that FDAR is dependent on functional sarcoplasmic reticulum (SR) and can be abolished by phosphatase or by Ca/CaM kinase (CaMKII) inhibition. Additionally, CaMKII activity/autophosphorylation has been shown to be frequency-dependent. Thus, we tested the hypothesis that CaMKII phosphorylation of SR Ca(2+)-handling proteins (Phospholamban (PLB), Ca(2+) release channel (RyR)) mediates FDAR. Here we show that FDAR occurs abruptly in fluo-4 loaded isolated rat ventricular myocytes when frequency is raised from 0.1 to 2 Hz. The effect is essentially complete within four beats (2 s) with the tau of [Ca(2+)](i) decline decreasing by 42+/-3%. While there is a detectable increase in PLB Thr-17 and RyR Ser-2814 phosphorylation, the increase is quantitatively small (PLB<5%, RyR approximately 8%) and the time-course is clearly delayed with regard to FDAR. The low substrate phosphorylation indicates that pacing of myocytes only mildly activates CaMKII and consistent with this CaMKIIdelta autophosphorylation did not increase with pacing alone. However, in the presence of phosphatase 1 inhibition pacing triggered a net-increase in autophosphorylated CaMKII and also greatly enhanced PLB and RyR phosphorylation. We conclude that FDAR does not rely on phosphorylation of PLB or RyR. Even though CaMKII does become activated when myocytes are paced, phosphatases immediately antagonize CaMKII action, limit substrate phosphorylation and also prevent sustained CaMKII autophosphorylation (thereby suppressing global CaMKII effects).     

Thick ascending limb: the Na+:K+:2Cl− co-transporter, NKCC2, and the calcium-sensing receptor, CaSR

The thick ascending limb of Henle’s loop is a nephron segment that is vital to the formation of dilute and concentrated urine. This ability is accomplished by a consortium of functionally coupled proteins consisting of the apical Na⁺:K⁺:2Cl⁻ co-transporter, the K⁺ channel, and basolateral Cl⁻ channel that mediate electroneutral salt absorption. In thick ascending limbs, salt absorption is importantly regulated by the calcium-sensing receptor. Genetic or pharmacological disruption impairing the function of any of these proteins results in Bartter syndrome. The thick ascending limb is also an important site of Ca²⁺ and Mg²⁺ absorption. Calcium-sensing receptor activation inhibits cellular Ca²⁺ absorption induced by parathyroid hormone, as well as passive paracellular Ca²⁺ transport. The present review discusses these functions and their genetic and molecular regulation.