Ketamine-induced cardiac depression is associated with increase in [Mg2+]i and activation of p38 MAP kinase and ERK 1/2 in guinea pig.

This study investigated the signaling pathways responsible for ketamine-induced cardiac depression in guinea pigs. The left ventricular development pressure (LVDP), velocity of the change in pressure (dP/dt), and heart rate (HR) accompanied with the total magnesium efflux ([Mg]e) were measured simultaneously in perfused hearts. The level of activation of the extracellular signal-regulated kinases 1/2 (ERK 1/2) and p38 mitogen-activated protein (MAP) kinase. The intracellular ionized magnesium concentration ([Mg2+]i) was measured using Mag-fura 2 AM in a single cardiomyocyte. Ketamine produced reversible decreases in the LVDP, dP/dt, and HR accompanied by increases in the [Mg]e. Ketamine also produced significant activation of p38 MAP kinase and ERK 1/2, and produced a dose-dependent increase in the [Mg2+]i, which was inhibited SB203580 and PD98059. These results suggest that ketamine-induced cardiac depression can be partly responsible for the increase in [Mg2+]i and [Mg]e, accompanied by the activation of p38 MAP kinase and ERK 1/2 in guinea pigs.

Immunosuppressants inhibit hormone-stimulated Mg2+ uptake in mouse distal convoluted tubule cells.

Immunosuppressants such as cyclosporinA and FK506 (tacrolimus) are widely prescribed to treat numerous disorders and to treat organ transplant recipients. However, cyclosporine A and FK506 are both known to produce hypomagnesaemia. The mechanism of this effect is still unclear. The present study determined the effects of immunosuppressant treatment on the parathyroid hormone (PTH) mediated Mg(2+) uptake and the mitogen-activated protein kinase (MAPK) activation in mouse distal convoluted tubule (MDCT) cells. The intracellular Ca(2+) and Mg(2+) concentrations in a single MDCT cell were measured by using the fluorescentdye Fura-2 AM and Mag-fura-2 AM, respectively. Cyclosporine A and FK506 illicited a transient increase of intracellular Ca(2+) from a basal level of 99 +/- 16 nM to 685 +/- 105 and 608 +/- 96 nM, respectively. In order to determine the Mg(2+) transport, the MDCT cells were Mg(2+)-depleted by culturing them in Mg(2+)-free media for 16 h, and the Mg(2+) uptake was measured by microfluorescence after placing the depleted cells in 1.5mM MgCl(2). The mean rate of Mg(2+) uptake, d([Mg(2+)](i))/dt, was 140 +/- 16 nM/s in the control MDCT cells. PTH increased the Mg(2+) uptake more than 2 times in this cell. Cyclosporine A (10 microM) and FK506 (0.1 microM) did not affect the basal Mg(2+)uptake (140 +/- 16 and 142 +/- 14 nM/s, respectively), but they inhibited the PTH-stimulated Mg(2+) entry, decreasing it from 248+/-12 to 147 +/- 7 and 148 +/- 14 nM/s, respectively. These effects were inhibited by L685818, which is a potent competitive antagonist of FK506. PTH stimulated the extracellular signal-regulated kinase1/2 (ERK1/2) protein synthesis. This PTH-stimulated ERK1/2 activation was inhibited by cyclosporine A and FK506. In the present study, the role of ERK1/2 activation on the PTH-dependent magnesium uptake was examined in MDCT cells, and we showed that immunosuppressants inhibit the hormone-stimulated Mg(2+) uptake into the MDCT cells by inhibiting the MAPK pathway.

alpha(1)-Agonists-induced Mg(2+) efflux is related to MAP kinase activation in the heart.

The stimulation of the alpha(1)-adrenergic receptor with phenylephrine results in the significant extrusion of Mg(2+) from the rat heart and cardiomyocytes. Phenylephrine-induced Mg(2+) extrusion is prevented by the removal of extracellular Ca(2+) or by the presence of Ca(2+)-channel blockers such as verapamil, nifedipine, or (+)BAY-K8644. Mg(2+) extrusion is almost completely inhibited by PD98059 (a MAP kinase inhibitor). The simultaneous addition of 5mM Ca(2+) and phenylephrine increases the extrusion of Mg(2+) from perfused hearts and cardiomyocytes. This Mg(2+) extrusion is inhibited by more than 90% when the hearts are preincubated with PD98059. ERKs are activated by perfusion with either phenylephrine or 5mM Ca(2+). This ERK activation is inhibited by PD98059. Overall, these results suggest that stimulating the cardiac alpha(1)-adrenergic receptor by phenylephrine causes the extrusion of Mg(2+) via the Ca(2+)-activated, Na(+)-dependent transport pathway, and the ERKs assists in Mg(2+) transport in the heart.

Evaluation of fluorescence hs-CRP immunoassay for point-of-care testing.

BACKGROUND: C-reactive protein (CRP) is one of acute phase respondents that has been used to monitor infection and inflammation episodes. Recent studies have shown that high-sensitivity C-reactive protein (hs-CRP) is a potential risk predictor for future atherosclerosis and cardiovascular diseases (CVD). METHODS: We previously developed a fluorescence-based immunochromatographic method for measuring hs-CRP concentrations (i-CHROMAtrade mark hs-CRP assay) in blood. Whole blood was mixed with detector buffer, and then loaded onto a test cartridge. After 10 min of incubation, the test cartridge was inserted and scanned for acquisition of fluorescence intensity in a laser fluorescence reader (i-CHROMAtrade mark reader). The fluorescence intensity was microprocessed and converted into the concentration of CRP in blood. The test result of 150 samples by the i-CHROMAtrade mark hs-CRP assay method was compared and evaluated with those by TBA 200FR turbidimetry and BN II nephelometry method. The Deming regression and the Bland-Altman difference plot analysis were used for comparison of hs-CRP test result. RESULTS: The i-CHROMAtrade mark hs-CRP assay system exhibited a good linearity with in the whole measuring range (R=0.997). The imprecision of intra- and the inter-assay CVs (coefficient of variation) of assay system were CVs< 3% and < 5% in the range of 0.5-20 mg/l, respectively. The i-CHROMAtrade mark hs-CRP assay method correlated well with TBA 200FR turbidimetry and BN II nephelometry assay method (R=0.988, N=143 and R=0.989, N=143). CONCLUSION: The i-CHROMAtrade mark hs-CRP assay system is comparable to those of other well-known fully automated hs-CRP assay and is suitable for point-of-care testing (POCT) in detection and quantification of hs-CRP.

Calixarene derivative as a tool for highly sensitive detection and oriented immobilization of proteins in a microarray format through noncovalent molecular interaction.

One important factor in fabricating protein microarray is to immobilize proteins without losing their activity on a solid phase. To keep them functional, it is necessary to immobilize proteins in a way that preserve their folded structural integrity. In a previous study, we developed novel Calixarene derivatives for the immobilization of proteins on the surface of a glass slide (1). In this study, we compared the sensitivity and the specificity of the linker molecules with those of five other protein attachment agents on glass slides using a prostate-specific antigen and its antibodies as a model system. The Calixcrown-coated protein chip showed a superior sensitivity and a much lower detection limit than those chips prepared by other methods. When we tested the capability of Calixcrown to immobilize antibody molecules, it appeared that Calixcrown makes arrangement of antibody be more regular with the vertical orientation than the covalent-bond agent. We also observed that the Calixcrown chip could be used for the diagnostic application with clinical samples from prostate cancer and HIV patients. Finally, we applied the Calixcrown chip using an antibody microarray to identify up- or down-regulated proteins in specific tissue and detected several up- or down-regulated proteins from a rat liver by administering toxin. Thus, the Calixcrown chip can be used as a powerful tool with a wide range of applications, including protein-protein interaction, protein-DNA interaction, and an enzyme activity assay.