Loss of Cytosolic Phosphoglucose Isomerase Affects Carbohydrate Metabolism in Leaves and Is Essential for Fertility of Arabidopsis

Carbohydrate metabolism in plants is tightly linked to photosynthesis and is essential for energy and carbon skeleton supply of the entire organism. Thus, the hexose phosphate pools of the cytosol and the chloroplast represent important metabolic resources that are maintained through action of phosphoglucose isomerase (PGI) and phosphoglucose mutase interconverting glucose 6-phosphate, fructose 6-phosphate, and glucose 1-phosphate. Here, we investigated the impact of disrupted cytosolic PGI (cPGI) function on plant viability and metabolism. Overexpressing an artificial microRNA targeted against cPGI (amiR-cpgi) resulted in adult plants with vegetative tissue essentially free of cPGI activity. These plants displayed diminished growth compared with the wild type and accumulated excess starch in chloroplasts but maintained low sucrose content in leaves at the end of the night. Moreover, amiR-cpgi plants exhibited increased nonphotochemical chlorophyll a quenching during photosynthesis. In contrast to amiR-cpgi plants, viable transfer DNA insertion mutants disrupted in cPGI function could only be identified as heterozygous individuals. However, homozygous transfer DNA insertion mutants could be isolated among plants ectopically expressing cPGI. Intriguingly, these plants were only fertile when expression was driven by the ubiquitin10 promoter but sterile when the seed-specific unknown seed protein promoter or the Cauliflower mosaic virus 35S promoter were employed. These data show that metabolism is apparently able to compensate for missing cPGI activity in adult amiR-cpgi plants and indicate an essential function for cPGI in plant reproduction. Moreover, our data suggest a feedback regulation in amiR-cpgi plants that fine-tunes cytosolic sucrose metabolism with plastidic starch turnover.Starch and Suc turnover are major pathways of primary metabolism in all higher plants. As such, they are essential for carbohydrate storage and the energy supply of sink tissues and as building blocks for amino acid, fatty acid, or cell wall biosynthesis (Stitt and Zeeman, 2012).A core reaction in both starch and Suc biosynthesis is the reversible interconversion of the hexose phosphate pool metabolites Fru 6-phosphate (Fru6P) and Glc 6-phosphate (Glc6P), which is mediated by phosphoglucose isomerase (PGI). Arabidopsis (Arabidopsis thaliana) contains two isoforms of PGI, one in the plastids and one in the cytosol (Caspar et al., 1985).During the light period, the plastid isoform of PGI (PGI1) is involved in starch biosynthesis by generating Glc6P from the primary photosynthetic product Fru6P. Glc6P is further converted to Glc 1-phosphate (Glc1P) and ADP-glucose via action of phosphoglucomutase (PGM) and ADP-glucose pyrophosphorylase (AGPase), respectively (Stitt and Zeeman, 2012). Finally, transfer of the glucosyl moiety of ADP-glucose to the growing carbohydrate chain of starch is mediated by starch synthases. Any of the enzymatic reactions of this linear pathway is essential for starch synthesis, as illustrated by the virtual absence of transitory starch in chloroplasts of mutant plant lines with impaired function of PGI1 (Yu et al., 2000; Kunz et al., 2010), PGM (Caspar et al., 1985; Kofler et al., 2000), or AGPase (Lin et al., 1988). Interestingly, in a few specific cell types, e.g. leaf guard cells and root columella cells, loss of PGI1 activity can be bypassed by the presence of the plastid Glc6P/phosphate translocator GPT1 (Niewiadomski et al., 2005; Kunz et al., 2010).The cytosolic isoform of PGI (cPGI) is involved in anabolism and catabolism of Suc, the major transport form of carbohydrates in plants. Glc6P and Fru6P interconversion is necessary for both Suc synthesis during the day and during the night. During the day, Suc synthesis in source leaves is fueled mainly by triose phosphates exported from chloroplasts that are eventually converted to Fru6P in the cytosol. However, Fru6P is only one substrate for the Suc-generating enzyme Suc phosphate synthase. The second substrate, UDP-glucose, is synthesized from Fru6P via Glc6P and Glc1P by the cytosolic isoenzymes of PGI1 and PGM as well as UDP-glucose pyrophosphorylase.Because Suc is the major long-distance carbon transport form, its synthesis has to continue throughout the night to supply energy and carbohydrates to all tissues. The nocturnal synthesis of Suc is dependent on breakdown and mobilization of transitory starch from chloroplasts (Zeeman et al., 2007) via export of maltose and Glc (Weber et al., 2000; Niittylä et al., 2004; Weise et al., 2004; Cho et al., 2011). Exported maltose is temporarily integrated into cytosolic heteroglycans (Fettke et al., 2005) mediated by disproportionating enzyme2 (DPE2; Chia et al., 2004; Lu and Sharkey, 2004) yielding Glc and a heteroglycan molecule elongated by an α1-4-bound glucosyl residue. Cytosolic Glc can directly be phosphorylated to Glc6P by the action of hexokinase, while temporarily stored Glc in heteroglycans is released as Glc1P mediated by cytosolic glucan phosphorylase2 (PHS2; Fettke et al., 2004; Lu et al., 2006). Both Glc6P and Glc1P can then be converted to UDP-glucose as during the day.Generation of Fru6P, the second substrate for Suc synthesis, can proceed only to a limited extent from triose phosphates during the night. This limitation is caused mainly by the nocturnal inactivation of Fru 1,6-bisphosphatase (Cséke et al., 1982; Stitt, 1990), a key enzyme in Suc biosynthesis during the day. Hence, in contrast to the situation in the light, cPGI activity is now crucial for providing Fru6P from Glc6P.On the catabolic side, degradation of Suc into its monosaccharides in sink tissues yields both Glc6P and Fru6P, of which only Fru6P can be utilized in glycolytic degradation. Therefore, cPGI is also required for Glc6P conversion to Fru6P in glycolysis, which, in combination with respiration, is the major path of energy production in heterotrophic tissues.Impairment or loss of function of enzymes contributing to the cytosolic hexose phosphate pool has recently been investigated for the Glc1P-forming enzyme PGM (Egli et al., 2010). The Arabidopsis genome encodes three PGM isoforms, with PGM1 localized to plastids and PGM2 and PGM3 localized to the cytosol (Caspar et al., 1985; Egli et al., 2010). Analyses of transfer DNA (T-DNA) mutants showed that homozygous pgm2/pgm3 double mutants were nonviable because of impaired gametophyte development. However, pgm2 and pgm3 single mutants grew like ecotype Columbia (Col-0) wild-type plants, indicating overlapping functions of PGM2 and PGM3 (Egli et al., 2010).By contrast, cPGI is encoded only by a single locus in Arabidopsis (Kawabe et al., 2000). Higher plant mutants reduced in cPGI activity have so far been characterized only in ethyl methanesulfonate-mutagenized Clarkia xantiana (Jones et al., 1986a; Kruckeberg et al., 1989; Neuhaus et al., 1989). The C. xantiana genome encodes for two isoenzymes of cPGI, and homozygous point mutations in each individual cPGI led to significant decrease in cPGI enzyme activity, which was further reduced to a residual activity of 18% in cpgi2/cpgi3 double mutants, where the cPGI3 locus was heterozygous for the mutation (Jones et al., 1986a; Kruckeberg et al., 1989). Detailed physiological analyses of these mutants indicated a negative impact on Suc biosynthesis and elevated starch levels when cPGI activity was decreased at least 3- to 5-fold (Kruckeberg et al., 1989).The physiological impact of decreased or even absent cPGI activity has not been characterized in the genetic model organism Arabidopsis. Here, we show that homozygous T-DNA insertion mutants in the cPGI locus are nonviable and present data from analyses of mature Arabidopsis plants constitutively expressing artificial microRNAs (amiRNAs) targeted against cPGI. These mutants reveal altered photosynthesis, a strong impact on nocturnal leaf starch degradation, and impaired Suc metabolism.     

The accuracy of measuring glenohumeral motion with a surface humeral cuff

Conclusions about normal and pathologic shoulder motion are frequently made from studies using skin surface markers, yet accuracy of such sensors representing humeral motion is not well known. Nineteen subjects were investigated with flock of birds electromagnetic sensors attached to transcortical pins placed into the scapula and humerus, and a thermoplastic cuff secured on the arm. Subjects completed two repetitions of raising and lowering the arm in the sagittal, scapular and coronal planes, as well as shoulder internal and external rotation with the elbow at the side and abducted to 90°. Humeral motion was recorded simultaneously from surface and bone fixed sensors. The average magnitude of error was calculated for the surface and bone fixed measurements throughout the range of motion. ANOVA tested for differences across angles of elevation, raising and lowering, and differences in body mass index. For all five motions tested, the plane of elevation rotation average absolute error ranged from 0-2°, while the humeral elevation rotation average error ranged from 0-4°. The axial rotation average absolute error was much greater, ranging from 5° during elevation motions to approaching 30° at maximum excursion of internal/external rotation motions. Average absolute error was greater in subjects with body mass index greater than 25. Surface sensors are an accurate way of measuring humeral elevation rotations and plane of elevation rotations. Conversely, there is a large amount of average error for axial rotations when using a humeral cuff to measure glenohumeral internal/external rotation as the primary motion.     

Photoinactivation and carbethoxylation of leucine aminopeptidase.

In the present paper the reactivity of histidyl residues of leucine aminopeptidase from bovine eye lens was studied by dye-sensitized photooxidation and by carbethoxylation of the enzyme protein using diethylpyrocarbonate. Of all the different amino acids modified by photooxidation only histidine is connected with the enzymic acticity, whereas tyrosine seems to be involved in structure stabilization. By changing the pH and varying the effectors (Mg2+ and/or dodecylsulfate) of the reaction mixture a different number of histidyl residues of the enzyme protein is caused to react with diethylpyrocarbonate. No secondary reactions with tyrosyl or tryptophyl residues could be observed by spectrophotometric investigations. The enzyme modified by one of the above-mentioned methods shows changes in the capacity of Mn2+ binding measured by autoradiography as well as in the degree of enhancement of enzymic activity by Mn2+ or Mg2+ ions. Of the 48 histidyl residues of the enzyme (Mr = 326000) up to 2 histidyl residues per subunit (Mr = 54000) may be involved in Mn2+ or Mg2+ binding and up to 4 histidyl residues have a strong influence on Zn2+ binding.     

Role of AMT1;1 in NH4+ acquisition in Arabidopsis thaliana

AtAMT1;1 was the founding member of the family of AMT/Rh ammonium transporters and accounts for about one third of the total ammonium absorption in the roots of the model plant Arabidopsis. Recent evidence suggested that at least some AMT/Rh proteins are NH3 gas channels. In order to evaluate the transported form of ammonium in AtAMT1;1, the protein was functionally expressed in Xenopus oocytes. AtAMT1;1 elicited NH4+ and methylammonium (MeA+) inward currents that saturated in a voltage-dependent manner with a half maximal concentration of 2.7 +/- 1.6 microM for NH4+ and 5.0 +/- 0.7 microM for the transport analogue methylammonium. AtAMT1;1 was plasma membrane localized and expressed in the root cortex and epidermis, including root hairs. The AtAMT1;1-GFP fusion construct under control of its endogenous promoter revealed additional localization of the protein in the pericycle, in the leaf epidermis, and in mesophyll cells. The functional data and its localization suggest that AtAMT1;1 participates in concentrative NH4+ acquisition in roots, in long-distance transport to the shoots, and in re-uptake of apoplastic NH4+ that derives from photorespiration in shoots.     

Cooperative binding promotes demand-driven recruitment of AnxA8 to cholesterol-containing membranes

The functionality of cellular membranes is critically determined by their lipid composition. Within the endolysosomal system, cholesterol is mainly found in more peripheral compartments. In contrast, cholesterol levels are low in late endosomes/lysosomes (LEL), and the occurrence of enlarged pools of this lipid is commonly linked to endolysosomal dysfunction. Here, we show that Annexin A8 (AnxA8), a member of the annexin family of Ca^2 +-dependent membrane-binding proteins, participates in the endosomal regulation of cholesterol homeostasis. Depletion of AnxA8 caused accumulation of cholesterol in LEL, and pharmacological inhibition of the LEL cholesterol export recruited AnxA8 to the cholesterol-laden LEL. Biophysical analysis revealed that cholesterol enhanced the Ca^2 +-dependent affinity of AnxA8 to lipid bilayers, and induced positive cooperativity of membrane binding. Our findings identify AnxA8 as a regulator of LEL cholesterol balance and point to altered membrane binding cooperativity induced by aberrant lipid composition in the target membrane as a means to control the demand-driven recruitment of this cytosolic regulatory protein.     

Inward Rectification in ClC-0 Chloride Channels Caused by Mutations in Several Protein Regions

Several cloned ClC-type Cl⁻ channels open and close in a voltage-dependent manner. The Torpedo electric organ Cl⁻ channel, ClC-0, is the best studied member of this gene family. ClC-0 is gated by a fast and a slow gating mechanism of opposite voltage direction. Fast gating is dependent on voltage and on the external and internal Cl⁻ concentration, and it has been proposed that the permeant anion serves as the gating charge in ClC-0 (Pusch, M., U. Ludewig, A. Rehfeldt, and T.J. Jentsch. 1995. Nature (Lond.). 373:527–531). The deactivation at negative voltages of the muscular ClC-1 channel is similar but not identical to ClC-0. Different from the extrinsic voltage dependence suggested for ClC-0, an intrinsic voltage sensor had been proposed to underlie the voltage dependence in ClC-1 (Fahlke, C., R. Rüdel, N. Mitrovic, M. Zhou, and A.L. George. 1995. Neuron. 15:463–472; Fahlke, C., A. Rosenbohm, N. Mitrovic, A.L. George, and R. Rüdel. 1996. Biophys. J. 71:695–706). The gating model for ClC-1 was partially based on the properties of a point-mutation found in recessice myotonia (D136G). Here we investigate the functional effects of mutating the corresponding residue in ClC-0 (D70). Both the corresponding charge neutralization (D70G) and a charge conserving mutation (D70E) led to an inwardly rectifying phenotype resembling that of ClC-1 (D136G). Several other mutations at very different positions in ClC-0 (K165R, H472K, S475T, E482D, T484S, T484Q), however, also led to a similar phenotype. In one of these mutants (T484S) the typical wild-type gating, characterized by a deactivation at negative voltages, can be partially restored by using external perchlorate (ClO₄ ⁻) solutions. We conclude that gating in ClC-0 and ClC-1 is due to similar mechanisms. The negative charge at position 70 in ClC-0 does not specifically confer the voltage sensitivity in ClC-channels, and there is no need to postulate an intrinsic voltage sensor in ClC-channels.     

Molecular mechanisms of ammonium transport and accumulation in plants

The integral membrane proteins of the ammonium transporter (AMT/Rh) family provide the major route for shuttling ammonium (NH(4)(+)/NH(3)) across bacterial, archaeal, fungal and plant membranes. These proteins are distantly related to the Rh (rhesus) glycoproteins, which are absent in higher plants, but are present in many species, including bacteria and mammals. It appears that the large nitrogen requirement of plants resulted in unique strategies to acquire, capture and/or release ammonium. The biological function of plant ammonium transporters will be discussed and compared to other AMT/Rh proteins.     

The micronucleus test in pigs: induction of micronuclei in polychromatic erythrocytes by various doses of X-rays

This paper describes the results of a study in which pigs were used in the bone marrow micronucleus assay. In a first experiment the spontaneous frequency of micronucleated polychromatic erythrocytes (MPE) among polychromatic erythrocytes (PE) was investigated in 78 animals. It was found that it is low with individual values of 0-4 MPE/1000 PE and a group average of 1.76 +/- 1.06% (mean +/- SD). In a second set of investigations animals were exposed to 0.25, 0.5, 1.0, 1.5, 2.25 and 2.75 Gy of 9-MeV X-irradiation performed as a single whole-body exposure. Time- and dose-dependent changes in micronucleus incidence were observed. Maximal group averages appeared nearly uniform 36 h post irradiation (p.i.). Considering the 36-h values in the dose range of 0-2.25 Gy there is a marked dose-effect relationship (r = 0.971). The data yield best to a regression curve of a third-grade polynomial indicating a complex interaction between dose and micronucleus formation. In conclusion, the results demonstrate that it appears feasible to use swine as target organisms in the micronucleus test to estimate the cytogenetic damage caused by ionizing radiations or, potentially, chemical compounds.     

Nitration of Tyrosine 247 Inhibits Protein Kinase G-1α Activity by Attenuating Cyclic Guanosine Monophosphate Binding

The cGMP-dependent protein kinase G-1α (PKG-1α) is a downstream mediator of nitric oxide and natriuretic peptide signaling. Alterations in this pathway play a key role in the pathogenesis and progression of vascular diseases associated with increased vascular tone and thickness, such as pulmonary hypertension. Previous studies have shown that tyrosine nitration attenuates PKG-1α activity. However, little is known about the mechanisms involved in this event. Utilizing mass spectrometry, we found that PKG-1α is susceptible to nitration at tyrosine 247 and 425. Tyrosine to phenylalanine mutants, Y247F- and Y425F-PKG-1α, were both less susceptible to nitration than WT PKG-1α, but only Y247F-PKG-1α exhibited preserved activity, suggesting that the nitration of Tyr²⁴⁷ is critical in attenuating PKG-1α activity. The overexpression of WT- or Y247F-PKG-1α decreased the proliferation of pulmonary artery smooth muscle cells (SMC), increased the expression of SMC contractile markers, and decreased the expression of proliferative markers. Nitrosative stress induced a switch from a contractile to a synthetic phenotype in cells expressing WT- but not Y247F-PKG-1α. An antibody generated against 3-NT-Y247 identified increased levels of nitrated PKG-1α in humans with pulmonary hypertension. Finally, to gain a more mechanistic understanding of how nitration attenuates PKG activity, we developed a homology model of PKG-1α. This model predicted that the nitration of Tyr²⁴⁷ would decrease the affinity of PKG-1α for cGMP, which we confirmed using a [³H]cGMP binding assay. Our study shows that the nitration of Tyr²⁴⁷ and the attenuation of cGMP binding is an important mechanism regulating in PKG-1α activity and SMC proliferation/differentiation.