Calcium activation of mougeotia potassium channels

Phytochrome mediates chloroplast movement in the alga Mougeotia, possibly via changes in cytosolic calcium. It is known to regulate a calcium-activated potassium channel in the algal plasma membrane. As part of a characterization of the potassium channel, we examined the properties of calcium activation. The calcium ionophore A23187 activates the channel at external [Ca(2+)] as low as 20 micromolar. However, external [Ca(2+)] is not required for activation of the channel by photoactivated phytochrome. Furthermore, when an inhibitor of calcium release from internal stores, 8-(diethylamino)-octyl-3,4,5-trimethoxybenzoate, hydrochloride (TMB-8), is present, red light no longer stimulates channel activity. We conclude that phytochrome activates the plasma membrane potassium channel by releasing calcium from intracellular calcium vesicles; the elevated cytosolic calcium then stimulates channel activity by an unknown mechanism. In the presence of TMB-8, red light does induce chloroplast rotation; thus, potassium channel activation may not be coupled to chloroplast rotation.     

New insights into the bioenergetics of mitochondrial disorders using intracellular ATP reporters

Mutations in mitochondrial DNA (mtDNA) cause impairment of ATP synthesis. It was hypothesized that high-energy compounds, such as ATP, are compartmentalized within cells and that different cell functions are sustained by different pools of ATP, some deriving from mitochondrial oxidative phosphorylation (OXPHOS) and others from glycolysis. Therefore, an OXPHOS dysfunction may affect different cell compartments to different extents. To address this issue, we have used recombinant forms of the ATP reporter luciferase localized in different cell compartments- the cytosol, the subplasma membrane region, the mitochondrial matrix, and the nucleus- of cells containing either wild-type or mutant mtDNA. We found that with glycolytic substrates, both wild-type and mutant cells were able to maintain adequate ATP supplies in all compartments. Conversely, with the OXPHOS substrate pyruvate ATP levels collapsed in all cell compartments of mutant cells. In wild-type cells normal levels of ATP were maintained with pyruvate in the cytosol and in the subplasma membrane region, but, surprisingly, they were reduced in the mitochondria and, to a greater extent, in the nucleus. The severe decrease in nuclear ATP content under "OXPHOS-only" conditions implies that depletion of nuclear ATP plays an important, and hitherto unappreciated, role in patients with mitochondrial dysfunction.     

Ca2+ homeostasis in permeabilized human neutrophils. Characterization of Ca2+-sequestering pools and the action of inositol 1,4,5-triphosphate

The regulation of Ca2+ transport by intracellular compartments was studied in digitonin-permeabilized human neutrophils, using a Ca2+-selective electrode. When incubated in a medium containing ATP and respiratory substrates, the cells lowered within 6 min the ambient [Ca2+] to a steady state of around 0.2 microM. A vesicular ATP-dependent and vanadate-sensitive non-mitochondrial pool maintained this low [Ca2+] level. In the absence of ATP, a higher Ca2+ steady state of 0.6 microM was seen, exhibiting the characteristics of a mitochondrial Ca2+ "set point." Both pools were shown to act in concert to restore the previous ambient [Ca2+] following its elevation. Thus, the mitochondria participate with the other pool(s) in decreasing [Ca2+] to the submicromolar range whereas only the nonmitochondrial pool(s) lowers [Ca2+] to the basal level. The action of inositol 1,4,5-triphosphate (IP3) which has been inferred to mediate Ca2+ mobilization in a few cell types was studied. IP3 released (detectable within 2 s) Ca2+ accumulated in the ATP-dependent pool(s) but had no effect on the mitochondria. The response was transient and resulted in desensitization toward subsequent IP3 additions. Under experimental conditions in which the ATP-dependent Ca2+ influx was blocked, the addition of IP3 resulted in a very large Ca2+ release from nonmitochondrial pool. The results strongly suggest that IP3 is a second messenger mediating intracellular Ca2+ mobilization in human neutrophils. Furthermore, the nonmitochondrial pool appears to have independent influx and efflux pathways for Ca2+ transport, a Ca2+ ATPase (the influx component) and an IP3-sensitive efflux component activated during Ca2+ mobilization.     

Systems Dynamic Modeling of a Guard Cell Cl? Channel Mutant Uncovers an Emergent Homeostatic Network Regulating Stomatal Transpiration

Stomata account for much of the 70% of global water usage associated with agriculture and have a profound impact on the water and carbon cycles of the world. Stomata have long been modeled mathematically, but until now, no systems analysis of a plant cell has yielded detail sufficient to guide phenotypic and mutational analysis. Here, we demonstrate the predictive power of a systems dynamic model in Arabidopsis (Arabidopsis thaliana) to explain the paradoxical suppression of channels that facilitate K⁺ uptake, slowing stomatal opening, by mutation of the SLAC1 anion channel, which mediates solute loss for closure. The model showed how anion accumulation in the mutant suppressed the H⁺ load on the cytosol and promoted Ca²⁺ influx to elevate cytosolic pH (pH_i) and free cytosolic Ca²⁺ concentration ([Ca2+]_i), in turn regulating the K⁺ channels. We have confirmed these predictions, measuring pH_i and [Ca2+]_i in vivo, and report that experimental manipulation of pH_i and [Ca2+]_i is sufficient to recover K⁺ channel activities and accelerate stomatal opening in the slac1 mutant. Thus, we uncover a previously unrecognized signaling network that ameliorates the effects of the slac1 mutant on transpiration by regulating the K⁺ channels. Additionally, these findings underscore the importance of H⁺-coupled anion transport for pH_i homeostasis.Guard cells surround stomatal pores in the epidermis of plant leaves and regulate pore aperture to balance the demands for CO₂ in photosynthesis with the need to conserve water by the plant. Transpiration through stomata accounts for much of the 70% of global water usage associated with agriculture, and it has a profound impact on the water and carbon cycles of the world (Gedney et al., 2006; Betts et al., 2007). Guard cells open the pore by transport and accumulation of osmotically active solutes, mainly K⁺ and Cl⁻ and the organic anion malate²⁻ (Mal), to drive water uptake and cell expansion. They close the pore by coordinating the release of these solutes through K⁺ and anion channels at the plasma membrane. The past half-century has generated a wealth of knowledge on guard cell transport, signaling, and homeostasis, resolving the properties of the major transport processes and metabolic pathways for osmotic solute uptake and accumulation, and many of the signaling pathways that control them (Blatt, 2000; Schroeder et al., 2001; McAinsh and Pittman, 2009; Hills et al., 2012). Even so, much of stomatal dynamics remains unresolved, especially how the entire network of transporters in guard cells works to modulate solute flux and how this network is integrated with organic acid metabolism (Wang and Blatt, 2011) to achieve a dynamic range of stomatal apertures.This gap in understanding is most evident in a number of often unexpected observations, many of which have led necessarily to ad hoc interpretations. Among these, recent studies highlighted a diurnal variation in the free cytosolic Ca²⁺ concentration ([Ca2+]_i), high in the daytime despite the activation of primary ion-exporting ATPases, and have been interpreted to require complex levels of regulation (Dodd et al., 2007). Other findings wholly defy intuitive explanation. For example, the tpk1 mutant of Arabidopsis (Arabidopsis thaliana) removes a major pathway for K⁺ flux across the tonoplast and suppresses stomatal closure, yet the mutant has no significant effect on cellular K⁺ content (Gobert et al., 2007). Similarly, the Arabidopsis clcc mutant eliminates the H⁺-Cl⁻ antiporter at the tonoplast; it affects Cl⁻ uptake, reduces vacuolar Cl⁻ content, and slows stomatal opening; however, counterintuitively, it also suppresses stomatal closure (Jossier et al., 2010). In work leading to this study, we observed that the slac1 anion channel mutant of Arabidopsis paradoxically profoundly alters the activities of the two predominant K⁺ channels at the guard cell plasma membrane. The SLAC1 anion channel is a major pathway for anion loss from the guard cells during stomatal closure (Negi et al., 2008; Vahisalu et al., 2008), and its mutation leads to incomplete and slowed closure of stomata in response to physiologically relevant signals of dark, high CO₂, and the water-stress hormone abscisic acid. Guard cells of the slac1 mutant accumulate substantially higher levels of Cl⁻, Mal, and also K⁺ when compared with guard cells of wild-type Arabidopsis (Negi et al., 2008). The latter observation is consistent with additional impacts on K⁺ transport; however, a straightforward explanation for these findings has not been not forthcoming.Quantitative systems analysis offers one approach to such problems. Efforts to model stomatal function generally have been driven by a “top-down” approach (Farquhar and Wong, 1984; Eamus and Shanahan, 2002) and have not incorporated detail essential to understanding the molecular and cellular mechanics that drive stomatal movement. Only recently we elaborated a quantitative systems dynamic approach to modeling the stomatal guard cell that incorporates all of the fundamental properties of the transporters at the plasma membrane and tonoplast, the salient features of osmolite metabolism, and the essential cytosolic pH (pH_i) and [Ca2+]_i buffering characteristics that have been described in the literature (Hills et al., 2012). The model resolved with this approach (Chen et al., 2012b) successfully recapitulated a wide range of known stomatal behaviors, including transport and aperture dependencies on extracellular pH, KCl, and CaCl₂ concentrations, diurnal changes in [Ca2+]_i (Dodd et al., 2007), and oscillations in membrane voltage and [Ca2+]_i thought to facilitate stomatal closure (Blatt, 2000; McAinsh and Pittman, 2009; Chen et al., 2012b). We have used this approach to resolve the mechanism behind the counterintuitive alterations in K⁺ channel activity uncovered in the slac1 mutant of Arabidopsis. Here, we show how anion accumulation in the mutant affects the H⁺ and Ca²⁺ loads on the cytosol, elevating pH_i and [Ca2+]_i, and in turn regulating the K⁺ channels. We have validated the key predictions of the model and, in so doing, have uncovered a previously unrecognized homeostatic network that ameliorates the effects of the slac1 mutant on transpiration from the plant.     

Age decline in the activity of the Ca2+-sensitive K+ channel of human red blood cells

The Ca(2+)-sensitive K(+) channel of human red blood cells (RBCs) (Gardos channel, hIK1, hSK4) was implicated in the progressive densification of RBCs during normal senescence and in the mechanism of sickle cell dehydration. Saturating RBC Ca(2+) loads were shown before to induce rapid and homogeneous dehydration, suggesting that Gardos channel capacity was uniform among the RBCs, regardless of age. Using glycated hemoglobin as a reliable RBC age marker, we investigated the age-activity relation of Gardos channels by measuring the mean age of RBC subpopulations exceeding a set high density boundary during dehydration. When K(+) permeabilization was induced with valinomycin, the oldest and densest cells, which started nearest to the set density boundary, crossed it first, reflecting conservation of the normal age-density distribution pattern during dehydration. However, when Ca(2+) loads were used to induce maximal K(+) fluxes via Gardos channels in all RBCs (F(max)), the youngest RBCs passed the boundary first, ahead of the older RBCs, indicating that Gardos channel F(max) was highest in those young RBCs, and that the previously observed appearance of uniform dehydration concealed a substantial degree of age scrambling during the dehydration process. Further analysis of the Gardos channel age-activity relation revealed a monotonic decline in F(max) with cell age, with a broad quasi-Gaussian F(max) distribution among the RBCs.     

Scaffold-mediated symmetry breaking by Cdc42p

Cell polarization generally occurs along a single well-defined axis that is frequently determined by environmental cues such as chemoattractant gradients or cell-cell contacts, but polarization can also occur spontaneously in the apparent absence of such cues, through a process called symmetry breaking. In Saccharomyces cerevisiae, cells are born with positional landmarks that mark the poles of the cell and guide subsequent polarization and bud emergence to those sites, but cells lacking such landmarks polarize towards a random cortical site and proliferate normally. The landmarks employ a Ras-family GTPase, Rsr1p, to communicate with the conserved Rho-family GTPase Cdc42p, which is itself polarized and essential for cytoskeletal polarization. We found that yeast Cdc42p was effectively polarized to a single random cortical site even in the combined absence of landmarks, microtubules and microfilaments. Among a panel of Cdc42p effectors and interacting proteins, we found that the scaffold protein Bem1p was uniquely required for this symmetry-breaking behaviour. Moreover, polarization was dependent on GTP hydrolysis by Cdc42p, suggesting that assembly of a polarization site involves cycling of Cdc42p between GTP- and GDP-bound forms, rather than functioning as a simple on/off switch.     

Chronic exposure to lead causes persistent alterations in the electric membrane properties of neurons in cell culture

The effects of chronic lead (Pb) exposure on neuronal electric membrane properties (EMP) were determined using neural cell cultures of adult mouse dorsal root ganglia (DRG). Cultures were exposed to Pb concentrations ranging from 0 to 100 microM for 12 days (8 DIV to 20 DIV). EMP were determined in Pb-free medium either immediately after withdrawal (IWD), or 6 days after withdrawal (6WD) from Pb. For IWD, regression analysis indicated that a number of EMP varied significantly with increasing Pb concentration. The largest such change occurred for electrical excitability which decreased significantly with increasing Pb (P = 0.000), being reduced by approximately two-thirds for neurons exposed to 100 microM Pb; resting membrane potential increased with Pb (P = 0.000); membrane time constant decreased with Pb (P = 0.007); action potential afterhyperpolarization decreased with Pb (P = 0.023). There was also evidence that the time course of action potentials was accelerated with increasing Pb concentrations, the rate of fall of neurons with biphasic falling phases being particularly increased (P = 0.047). This general pattern of altered EMP was observed for the 6WD condition also, indicating that chronic exposure to Pb caused persistent abnormalities in neuronal membranes even after 6 days of cultivation in Pb-free medium. The patterns of alterations in EMP suggested that chronic Pb exposure caused a prolonged increase in potassium permeability. It was proposed that the latter was mediated through a Pb-induced increase in intracellular ionic calcium and the associated disruption of calcium homeostasis.