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【Objective】 To explore the roles of 1,4,5-trisphosphate receptor (IP3Rs) and ryanodine receptors (RyRs), the two main Ca2+ release channels in sarcoplasmic reticulum (SR), in the regulation of intracellular Ca2+ oscillations in neonatal rat cardiomyocytes (NRCMs). 【Methods】 We isolated and cultured NRCMs for different days, then loaded them with Ca2+ indicator fura-2 and performed real-time fluorescent imaging. To distinguish the effects of IP3Rs and RyRs, NRCMs were pre-treated with phenylephrine (PE, IP3Rs agonist), caffeine (RyRs agonist), 2-APB (IP3Rs antagonist), and tetracaine (RyRs antagonists), respectively. 【Results】 The cultured monolayer NRCMs showed spontaneous synchronized Ca2+ oscillations. PE activation or 2-APB blockade of IP3Rs increased or reduced the frequency of Ca2+ oscillations in NRCMs, accordingly, with no significant effect on the amplitude of Ca2+ oscillations. Activation of RyRs with caffeine increased the frequency of Ca2+ oscillations, but unsynchronized the intercellular rhythm of calcium release and beating pace, while blocking RyRs with tetracaine completely abolished the Ca2+ oscillations and beats in NRCMs. In addition, the effect of PE stimulation on Ca2+ oscillation frequency gradually decreased along with cultured days. 【Conclusion】 IP3Rs regulate the rhythm of calcium oscillations, whereas RyRs are the main channel for bulky store Ca2+ release.
RESUMO
Objective To study the effect of N-Methyl-D-asparticacid ( NMDA ) on the intracellular free calcium concentration ( [ Ca2+] i ) in primary cultured rat calvaria osteoblasts. Methods A calcium imaging technique was applied to observe [ Ca2+] i changes in primary cultured rat calvaria osteoblasts after stimulating by NMDA with various concentrations or pretreated with NMDA receptor noncompetitive antagonism MK801 ( Dizocilpin) . Results Different concentrations of NMDA caused [ Ca2+] i increases in varying degrees and by different ways. NMDA could evoke transient increase and secondary change in [ Ca2+] i including calcium oscillation or steady increase. MK801 inhibited NMDA-induced [ Ca2+] i increase in varying degrees. Conclusion These results indicated that there are abundant functional NMDA receptors expressed in primary cultured rat calvaria osteoblasts, showing different forms and varying degrees of [ Ca2+] i increases in response to different concentrations of NMDA. The characters of the blocking effect of MK801 to NMDA-induced [ Ca2+] i increasing, indicated that the NMDA receptors expressed in primary cultured rat calvaria osteoblasts differ in channel properties from those in central nervous system.
RESUMO
Calcium oscillation may regulate gene transcription in a frequency-decoding manner during agonist stimulation,which provides an indicator of transcription level in cells. To determine whether persistent exposure to hypoxia may sensitize or blunt cell response to histamine, the effects of 24 h subacute mild hypoxia on histamine-stimulated calcium oscillation frequency were examined in pulmonary artery endothelial cells (PAECs). The results are: (1) 24 h subacute mild hypoxia significantly increased the histamine-stimulated calcium oscillation frequency in PAECs. The averaged frequency of calcium oscillation in posthypoxic PAECs was significantly higher than that in normoxic ones. (2) NADPH oxidase inhibitor, diphenylene iodonium chloride (DPI, 10 μmol/L), abolished histamine-stimulated calcium oscillations both in normoxic and posthypoxic PAECs. (3) Xanthine oxidase inhibitor, oxypurinol (100 μmol/L), did not affect the calcium oscillation kequency in normoxic PAECs. However, it significantly decreased the elevation of calcium oscillation frequency in posthypoxic PAECs. These results demonstrated that, during pulmonary disease related to persistent hypoxia,PAECs become more sensitive to histamine. During histamine stimulation, NADPH oxidase plays a critical role in generating calcium oscillations, while xanthine oxidase may contribute to, at least in part, the increase of calcium oscillation frequency in posthypoxic PAECs.