A protein kinase that plays a key role in the global control of plant carbon metabolism is SnRK1 (sucrose non-fermenting-1-related protein kinase 1), so-called because of its homology and functional similarity with sucrose non-fermenting 1 (SNF1) of yeast. This article reviews studies on the characterization of SnRK1 gene families, SnRK1 regulation and function, interacting proteins, and the effects of manipulating SnRK1 activity on carbon metabolism and development.
SummaryThe high affinity potassium transporter, HKT1 from wheat was introduced into Florida wheat in sense and antisense orientation under control of a ubiquitin promoter. Ten transgenic lines expressing the transgene were identified and two of these showed strong down-regulation of the native HKT1 transcript. One line (271) was expressing the antisense construct and the other (223) was expressing a truncated sense construct. The two lines were examined further for phenotype relating to cation transport. Membrane depolarisations were measured in low (0.1 mM) K þ and high (100 mM) NaCl. Under these conditions there was no difference between line 271 and the control at low K þ , but at high Na þ there was a rapid depolarisation that was significantly larger in control plants. 22 Na uptake was measured in this line and there was a significant decrease in uptake at 100 mM NaCl in the transgenic line when compared with the control. The two transgenic lines were grown at high NaCl (200 mM) and analysed for growth and root sodium content. Lines 271 and 223 showed enhanced growth under salinity when compared with the control and had lower sodium in the root. Secondary ion mass spectrometry (SIMS) analysis of transverse sections of the root showed that Na þ and K þ were strongly localised to stelar regions when compared with other ions, and that the Na þ : K þ ratios were reduced in salt-stressed transgenic tissue when compared with the control.
Triple-barrelled microelectrodes measuring K(+) activity (a(K)), pH and membrane potential were used to make quantitative measurements of vacuolar and cytosolic a(K) in epidermal and mesophyll cells of barley plants grown in nutrient solution with 0 or 200 mM added NaCl. Measurements of a(K) were assigned to the cytosol or vacuole based on the pH measured. In epidermal cells, the salt treatment decreased a(K) in the vacuole from 224 to 47 mM and in the cytosol from 68 to 15 mM. In contrast, the equivalent changes in the mesophyll were from 235 to 150 mM (vacuole) and 79 to 64 mM (cytosol). Thus mechanisms exist to ameliorate the effects of salt on a(K) in compartments of mesophyll cells, presumably to minimize any deleterious consequences for photosynthesis. Thermodynamic calculations showed that K(+) is actively transported into the vacuole of both epidermal and mesophyll cells of salinized and non- salinized plants. Comparison of the values of a(K) in K(+)-replete, non-salinized leaf cells with those previously measured in root cells of plants grown under comparable conditions indicates that cytosolic a(K) is similar in cells of both organs, but vacuolar a(K) in leaf cells is approximately twice that in roots. This suggests differences in the regulation of vacuolar a(K), but not cytosolic a(K), in leaf and root cells.
It has been clear for over a decade and a half that ancient signalling pathways controlling fundamental cellular processes are highly conserved throughout the eukaryotes. Two plant protein kinases, sucrose non-fermenting 1 (SNF1)-related protein kinase (SnRK1) and general control non-derepressible 2 (GCN2)-related protein kinase are reviewed here. These protein kinases show an extraordinary level of conservation with their fungal and animal homologues given the span of time since they diverged from them. However, close examination of the signalling pathways in which they operate also reveals intriguing differences in activation and function.
In vivo 15N NMR spectroscopy was used to monitor the assimilation of ammonium by cell-suspension cultures of carrot (Daucus carota 1. cv Chantenay). The cell suspensions were supplied with oxygen in the form of either pure oxygen ("oxygenated cells") or air ("aerated cells"). In contrast to oxygenated cells, in which ammonium assimilation had no effect on cytoplasmic pH, ammonium assimilation by aerated cells caused a decrease in cytoplasmic pH of almost 0.2 pH unit. This led to a change in nitrogen metabolism resulting in the accumulation of 7-aminobutyric acid. The metabolic effect of the reduced oxygen supply under aerated conditions could be mimicked by artificially decreasing the cytoplasmic pH of oxygenated cells and was abolished by increasing the cytoplasmic pH of aerated cells. The activity of glutamate decarboxylase increased as the cytoplasmic pH declined and decreased as the pH recovered. These findings are consistent with a role for the decarboxylation of glutamate, a proton-consuming reaction, in the short-term regulation of cytoplasmic pH, and they demonstrate that cytoplasmic pH influences the pathways of intermediary nitrogen metabolism.
A DNA fragment corresponding to part of an SNF1 (sucrose non-fermenting-1)-related protein kinase (SnRK1) transcript was amplified by a polymerase chain reaction (PCR) from a wheat (Triticum aestivum) endosperm cDNA library. It was used to construct a chimaeric gene, pUasSnRKN, comprising a ubiquitin promoter, the SnRK1 PCR product in the antisense orientation and the nopaline synthase (Nos) gene terminator. This construct was used in transient gene expression experiments in cultured wheat embryos together with a series of reporter gene constructs. These included the wheat alpha amylase gene alpha-Amy2 promoter with UidA (Gus) coding region (palpha2GT), rice actin promoter with Gus (pActIDGus), ubiquitin promoter with Gus (pAHC25) and actin promoter with green fluorescent protein (GFP) gene (pAct1Is-GFP1). All of the reporter genes were found to be active when bombarded into scutellae isolated from immature grains at 25 d post-anthesis and incubated on MS medium for 24 h prior to bombardment. However, co-bombardment of palpha2GT with equimolar amounts of pUasSnRKN resulted in no detectable Gus activity, indicating that the antisense SnRK1 construct repressed the alpha-Amy2 promoter. Co-bombardment with pUasSnRKN had no effect on the activity of the other promoters used in the study. A triple bombardment with palpha2GT, pAct1Is-GFP-1 and pUasSnRKN resulted in clear green fluorescence, indicating that the bombarded cells were still viable, but no Gus activity. RT-PCR analysis showed clearly that the antisense SnRK1 gene was expressing. Northern and RT-PCR analyses confirmed that SnRK1 and both alpha-amylase genes, alpha-Amy1 and alpha-Amy2, are expressed in cultured wheat embryos harvested from grain 25 d post-anthesis. Expression of alpha-Amy1 and alpha-Amy2 was up-regulated by sugar starvation.
Ion transport across the plasma membrane of suspension-culture cells derived from immature barley embryos has been studied in low (15 mM KCl) and high (additional 150 mM NaCl) salt conditions to understand how plants discriminate between K(+) and Na(+) during ion uptake. In both media about 50% of the cells exhibited resting potentials more negative than any of the passive diffusion potentials. In whole-cell patch clamp experiments membrane hyperpolarization activated large inward currents. Whilst the instantaneous current components did not discriminate between K(+) and Na(+), the time-dependent current, I(in), was selective for K(+) over Na(+). Further analysis of I(in) revealed the following properties: double exponential current activation (time-constants 0.03 s and 0.3 s, half activation potential - 171 mV); no inactivation; complete block by Ba(2+) (30 mM in 100 mM KCl) and part block by TEA(+) (maximum 50% with 20 mM); dependence on millimolar concentrations of cytoplasmic ATP; no block by external or cytoplasmic Na(+). The selectivity sequences K(+) ≫ Rb(+) > NH(+)(4) > Na(+) ≫ Cl(-) and K(+) ≫ NH(+)(4) > Na(+) > Rb(+) were determined from measurements of reversal potentials and relative steady-state currents respectively. P(Na):P(K) was 0.07 ± 0.02 (from reversal potentials) and I(Na):I(K) was 0.17 + 0.05 (from relative currents). A high variance among the observed permeability ratios suggested that several channels with different ion-selectivities contributed to the time-dependent whole-cell currents. In single channel experiments, several inward channels with distinct properties were found. The major channels were (i) a voltage-gated, K(+)-selective channel (12 pS), (ii) an ATP-activated non-selective cation channel (7 pS) and (iii) an inward-rectifying anion-channel (150 pS, all unitary conductances given for 100 mM KCI). No significant differences were found in whole-cell currents or single-channel characteristics between cells that had been adapted to a high-salt growth-medium (150 mM NaCl) and non-adapted cells. The idea that differential regulation of plasma membrane ion channels gives rise to a physiological flexibility, allowing the cells to control Na(+) uptake under varying external conditions, is discussed.
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