Magnesium ion leachables induce a conversion of contractile vascular smooth muscle cells to an inflammatory phenotype.

Phenotype switching is a characteristic response of vascular smooth muscle cells (vSMCs) to the dynamic microenvironment and contributes to all stages of atherosclerotic plaque. Here, we immersed pure magnesium and AZ31 alloy in the completed medium under cell culture condition, applied the resultant leaching extracts to the isolated contractile rat aortic vSMCs and investigated how vSMCs phenotypically responded to the degradation of the magnesium-based stent materials. vSMCs became more proliferative and migratory but underwent more apoptosis when exposed to the degradation products of pure magnesium; while the AZ31 extracts caused less cell division but more apoptosis, thus slowing cell moving and growing. Noticeably, both leaching extracts dramatically downregulated the contractile phenotypic genes at mRNA and protein levels while significantly induced the inflammatory adhesive molecules and cytokines. Exogenously added Mg ions excited similar transformations of vSMCs. With the liberation or supplementation of Mg2+ , the expression patterns of the pro-contractile transactivator myocardin and the pro-inflammatory transcriptional factor kruppel-like factor 4 (KLF4) were reversed. Overall, the degradation of the Mg-based materials would evoke a shift of the contractile vSMCs to an inflammatory phenotype via releasing Mg ions to induce a transition from the phenotypic control of vSMCs by the myocardin to that by the KLF4. © 2018 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater 107B: 988-1001, 2019.

[Influence of heavy metal ions on the ATPase activity of actomyosin complex and myosin subfragment-1 from smooth muscle of the uterus].

The effect of divalent cations--Co2+, Cu2+, Mn2+ and Ni2+ (5 mM) on the activity of actomyosin complex ATPase and ATPase of subfragment-1 (S1,head) of myosin from smooth muscle of the uterus was studied. It has been shown that Co2+, Mn2+ and Ni2+ inhibited, while Cu2+ activates the enzyme activity of both actomyosin and myosin S1. Mg and Mn ions had practically no effect on the emission intensity of eosin Y associated with actomyosin, while one could observe the most marked suppression of emission of related fluorescent probe in the presence of Cu cations and less pronounced suppression in the presence of Co2+. In the presence of Mn, Co and Ni cations the average hydrodynamic diameter (HD) of actomyosin complex and of subfragment-1 of the smooth muscle of the uterus is virtually identical to the HD in the presence of Mg2+. In the presence of Cu cations there is a considerable (ten-fold) increase in the size of the protein particles that may be a result of their aggregation. The results obtained evidence for the significant changes in the structure and function of the actomyosin complex of the myometrium in the presence of heavy metals and allow us to assume that the target of the effect of these metals on the contractile proteins is a subfragment-1 of myosin, where the active site of ATPase and actin-binding sites are localized.

Zinc in the physiology and pathology of the CNS.

The past few years have witnessed dramatic progress on all frontiers of zinc neurobiology. The recent development of powerful tools, including zinc-sensitive fluorescent probes, selective chelators and genetically modified animal models, has brought a deeper understanding of the roles of this cation as a crucial intra- and intercellular signalling ion of the CNS, and hence of the neurophysiological importance of zinc-dependent pathways and the injurious effects of zinc dyshomeostasis. The development of some innovative therapeutic strategies is aimed at controlling and preventing the damaging effects of this cation in neurological conditions such as stroke and Alzheimer's disease.

Treatment failures secondary to drug interactions with divalent cations and fluoroquinolone.

We observed four cases of therapeutic failures while patients were simultaneously taking medications that contained divalent cations and oral fluoroquinolones. Patients improved after conversion to the intravenous formulation of the same antibiotics, proper spacing of the divalent cation, or conversion to a different antibiotic class. Patients prescribed oral fluoroquinolones should receive instructions on proper separations of these antibiotics with divalent cations. Health care professionals should be cognizant of these interactions and educated on their potential deleterious effect.

The role of divalent cations in controlling amphibian lens membrane permeability; the mechanisms of toxic cataracts.

The effects of a range of divalent ions on lens sodium and potassium permeability characteristics were studied in calcium competition and replacement experiments. Resting voltage and conductance were measured and also voltage-independent conductance. Strontium and manganese were the only divalent ions able to maintain, in the absence of calcium, both sodium and potassium permeability at or near the control level. Neither cobalt nor magnesium had any effect on lens voltage of conductance in the presence of calcium, but neither of these ions could maintain lens permeability properties in the absence of calcium. Cadmium and barium had little effect on sodium permeability, but the former increased potassium permeability while the latter reduced it. Barium was the only divalent studied that appeared to inactivate voltage-sensitive potassium channels in the presence of calcium. Nickel, zinc and copper increased both sodium and potassium permeability in the presence of calcium and so they are likely to be particularly damaging to the lens. Copper was extremely toxic since it was able to overturn the regulatory influence of calcium when it was present in concentrations as low as 10(-6)M.