Involvement of calmodulin in platelet reaction

Penothiazines, known as selective inhibitors of calmodulin, completely inhibited platelet aggregation and secretion induced by ADP, collagen, epinephrine, thrombin or calcium ionophore. They also completely inhibited aggregation induced by exogenous arachidonate (AA) or a mixture of thromboxane A₂ and prostaglandin endoperoxides (TxA₂/PG G₂,H₂). Also, in the presence of these calmodulin inhibitors, the release of AA from platelet phospholipids (PL) was dosedependently inhibited in stimulated platelets. These observations suggest that in platelet reaction, calmodulin is involved in at least two different steps of the reaction: activation of phospholipases and contraction of platelet actomyosin after the formation of TxA₂.     

In silico identification of potential new latex allergens

BACKGROUND: Allergy to latex of Hevea brasiliensis is a frequent problem. In spite of the significant progress of research, the identity and cross-reactivity of some latex allergens are unknown. OBJECTIVE: To identify, among the fully characterized latex proteins, those with a higher probability to be allergenic. METHODS: We used in silico techniques (amino acid sequence comparison and molecular modelling) to identify potential new allergens among the known proteins of H. brasiliensis. RESULTS: Cu/Zn superoxide dismutase, heat shock protein and calmodulin of H. brasiliensis show highly significant (E < 10(-9)) amino acid sequence homologies with known allergens. CONCLUSION: On the basis of our data, Cu/Zn superoxide dismutase, heat shock protein and calmodulin are the most probable allergens among fully characterized proteins of H. brasiliensis, and could potentially explain, at least in part, the multiple cross-reactivities of latex with vegetable foods and other plant-derived products. Consequently, we think that the above proteins should be particularly considered in the future laboratory and clinical research.     

Evidence for a calmodulin inhibitory substance(s) isolated from human meningiomas

Summary Calmodulin (CaM), a calcium-binding protein, is present in human tumor tissues and in meningioma. Following a purification procedure using DEAE-cellulose and the polymeric resin 3520, the CaM content of tumor extracts was assayed using CaM-deficient phosphodiesterase (PDE). In the presence of low amounts of the extracts, a concentration dependent stimulation of PDE was observed. However, further addition of higher concentrations of the extract produced a marked inhibition of the CaM stimulation of PDE in 13 of 15 specimens. A wide range (2.44–51.31 units/1 mg tumor [wet weight]) of inhibitor concentration was noted. However, no detectable inhibitory activity of this magnitude was observed in normal human meningeal extracts. The final extracts showed no calcineurin-phosphatase activity in the presence of Ni⁺⁺, a known activator of this phosphatase. SDS-polyacrylamide gel (10%) electrophoresis of the extracts revealed the typical calmodulin band at 17 kDa plus two additional bands with apparent molecular masses of 21 and 36 kDa respectively. These bands were not seen using normal meningeal extracts.     

香茶菜甲素酯对依赖钙调素的环核苷酸磷酸二酯酶的抑制作用

香茶菜甲素酯是香茶菜甲素的一种新的衍生物。研究发现该化合物能明显抑制CaM激活的PDE活性,其IC_(50)为75μmol/L。抑制动力学测定表明它以非竞争方式拮抗CaM对PDE的活化。CaM荧光测定显示,香茶菜甲素酯可以降低ca~(2+)诱导的CaM酪氨酸荧光强度,提示它可能通过改变Ca~(2+)—CaM构象而抑制CaM—PDE。     

Zinc inhibition of calmodulin: a proposed molecular mechanism of zinc action on cellular functions.

Calcium stimulates, and zinc inhibits, a wide variety of cell types. In the erythrocyte, we have found calcium and zinc to have antagonist actions in a variety of systems. An important mechanism for calcium effects on cells is activation of calmodulin. Calmodulin is a small ubiquitous protein which, when activated by calcium, has a large array of cellular regulatory functions. We now report that calmodulin function is inhibited by low concentrations of zinc. Zinc inhibition of calmodulin provides a rational molecular mechanism for the diverse cellular inhibitory effects of zinc, as well as for zinc's antagonism of calcium effects.     

Protein kinase C isoforms as specific targets for modulation of vascular smooth muscle function in hypertension

Vascular contraction is an important determinant of the peripheral vascular resistance and blood pressure. The mechanisms underlying vascular smooth muscle (VSM) contraction and the pathological changes that occur in hypertension have been the subject of numerous studies and interpretations. Activation of VSM by vasoconstrictor stimuli at the cell surface causes an increase in [Ca(2+)](i), Ca(2+)-dependent activation of myosin light chain (MLC) kinase, MLC phosphorylation, actin-myosin interaction and VSM contraction. Additional signaling pathways involving Rho-kinase and protein kinase C (PKC) may increase the myofilament force sensitivity to [Ca(2+)](i) and MLC phosphorylation, and thereby maintain vascular contraction. PKC is a particularly intriguing protein kinase as it comprises a family of Ca(2+)-dependent and Ca(2+)-independent isoforms, which have different tissue and subcellular distribution, and undergo differential translocation during cell activation. PKC translocation to the cell surface may trigger a cascade of protein kinases, such as mitogen-activated protein kinase (MAPK) and MAPK kinase (MEK) that ultimately interact with the contractile myofilaments and cause VSM contraction. Also, PKC translocation to the nucleus may promote VSM growth and proliferation. Increased PKC expression and activity have been identified in several forms of hypertension. The subcellular location of PKC may determine the state of VSM activity, and may be useful in the diagnosis/prognosis of hypertension. Vascular PKC isoforms may represent specific targets for modulation of VSM hyperactivity, and isoform-specific PKC inhibitors may be useful in treatment of Ca(2+) antagonist-resistant forms of hypertension.     

Cholinergic innervation of pyramidal cells and parvalbumin-immunoreactive interneurons in the rat basolateral amygdala

The basolateral nucleus of the amygdala receives an extremely dense cholinergic innervation from the basal forebrain that is critical for memory consolidation. Although previous electron microscopic studies determined some of the postsynaptic targets of cholinergic afferents, the majority of postsynaptic structures were dendritic shafts whose neurons of origin were not identified. To make this determination, the present study analyzed the cholinergic innervation of the anterior subdivision of the basolateral amygdalar nucleus (BLa) of the rat using electron microscopic dual-labeling immunocytochemistry. The vesicular acetylcholine transporter (VAChT) was used as a marker for cholinergic terminals; calcium/calmodulin-dependent protein kinase II (CaMK) was used as a marker for pyramidal cells, the principal neurons of the BLa; and parvalbumin (PV) was used as a marker for the predominant interneuronal subpopulation in this nucleus. VAChT(+) terminals were visualized by using diaminobenzidine as a chromogen, whereas CAMK(+) or PV(+) neurons were visualized with Vector very intense purple (VIP) as a chromogen. Quantitative analyses revealed that the great majority of dendritic shafts receiving cholinergic inputs were CAMK(+) , indicating that they were of pyramidal cell origin. In fact, 89% of the postsynaptic targets of cholinergic terminals in the BLa were pyramidal cells, including perikarya (3%), dendritic shafts (47%), and dendritic spines (39%). PV(+) structures, including perikarya and dendrites, constituted 7% of the postsynaptic targets of cholinergic axon terminals. The cholinergic innervation of both pyramidal cells and PV(+) interneurons may constitute an anatomical substrate for the generation of oscillatory activity involved in memory consolidation by the BLa.     

CaMKⅡ信号转导通路在病理性疼痛中的研究进展

背景钙／钙调素依赖性蛋白激酶II（Ca2/almodulin—dependent protein kinaseⅡ,CaMKⅡ）是一种多功能的丝氨酸苏氨酸蛋白激酶,广泛分布在周围和中枢神经系统。目的有研究表明CaMKⅡ在感觉信息特别是伤害性信息的传人与整合中具有重要作用,为此现作一综述。内容此文阐述了背根神经节（dorsal root ganglion,DRG）、脊髓背角（Spinal dorsalhom,SDH）及脊髓上水平的、CaMK11在病理性疼痛的作用及其调节因素的研究进展。趋势CaMKⅡ可能为阐明疼痛机制提供依据,为临床治疗疼痛提供方向和思路。     

α-Actinin2 cytoskeletal protein is required for the functional membrane localization of a Ca2+-activated K+ channel (SK2 channel)

The importance of proper ion channel trafficking is underpinned by a number of channel-linked genetic diseases whose defect is associated with failure to reach the cell surface. Conceptually, it is reasonable to suggest that the function of ion channels depends critically on the precise subcellular localization and the number of channel proteins on the cell surface membrane, which is determined jointly by the secretory and endocytic pathways. Yet the precise mechanisms of the entire ion channel trafficking pathway remain unknown. Here, we directly demonstrate that proper membrane localization of a small-conductance Ca²⁺-activated K⁺ channel (SK2 or K_Ca2.2) is dependent on its interacting protein, α-actinin2, a major F-actin crosslinking protein. SK2 channel localization on the cell-surface membrane is dynamically regulated, and one of the critical steps includes the process of cytoskeletal anchoring of SK2 channel by its interacting protein, α-actinin2, as well as endocytic recycling via early endosome back to the cell membrane. Consequently, alteration of these components of SK2 channel recycling results in profound changes in channel surface expression. The importance of our findings may transcend the area of K⁺ channels, given that similar cytoskeletal interaction and anchoring may be critical for the membrane localization of other ion channels in neurons and other excitable cells.