Comparative Genomic View of The Inositol-1,4,5-Trisphosphate Receptor in Plants

Mikami, Koji

doi:10.4172/2329-9029.1000132

Cited by 1 publication

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References 55 publications

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“…The IP 3 signaling in plants is controversial (Munnik and Vermeer, 2010), but there is increasing experimental evidence connecting transient concentration increases of IP 3 and cytoplasmic Ca 2+ in circadian rhythms and upon exposure to range of abiotic stresses in higher plants (Krinke et al, 2007; Tang et al, 2007). Further, IP 3 and DAG (diacylglycerol, formed at the same time as IP 3 ) can be phosphorylated in plants to form IP 6 and phosphatidic acid, which may also act as second messengers (Mikami, 2014).…”

Section: Introductionmentioning

confidence: 99%

Modeling the Action Potential in Characeae Nitellopsis obtusa: Effect of Saline Stress

et al. 2019

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Action potentials (AP) of characean cells were the first electrical transients identified in plants. APs provide information about plethora of environmental cues. Salinity stress is critical for plants and impacts on excitability. The AP of brackish Characeae Nitellopsis obtusa , obtained in artificial pond water (APW) and under osmotic stress of 90 or 180 mM sorbitol APW or saline stress of 50 or 100 mM NaCl APW, were simulated by the Thiel-Beilby model (Beilby and Al Khazaaly, 2016 ). The model is based on a paradigm from animal systems, featuring the second messenger inositol 1,4,5-triphosphate (IP 3 ) mediating the opening of Ca 2+ channels on internal stores. In plants the IP 3 receptors have not been identified, so other second messengers might translate the threshold plasma membrane depolarization to Ca 2+ release. The increased Ca 2+ concentration in the cytoplasm activates Cl − channels, which lead to the depolarizing phase of the AP. The repolarization to normal resting potential difference (PD) results from the Ca 2+ being re-sequestered by the Ca 2+ pumps, the closure of the Cl − channels, efflux of K + through the depolarization-activated outward rectifier channels and the continuing activity of the proton pump. The Nitellopsis AP form is longer in APW compared to that of Chara , with more gradual repolarization. The tonoplast component of the AP is larger than that in Chara australis . The plasma membrane AP is prolonged by the exposure to saline to a “rectangular” shape, similar to that in Chara . However, the changes are more gradual, allowing more insight into the mechanism of the process. It is possible that the cells recover the original AP form after prolonged exposure to brackish conditions. Some cells experience tonoplast APs only. As in Chara , the proton pump is transiently inhibited by the high cytoplasmic Ca 2+ and gradually declines in saline media. However, if the cells are very hyperpolarized at the start of the experiment, the pump inhibition both by the AP and by the saline medium is mitigated. The model parameters and their changes with salinity are comparable to those in Chara .

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