Antisense expression of a rice sucrose transporter OsSUT1 in rice (Oryza sativa L.).

We analyzed the function of a rice sucrose transporter, OsSUT1, by using antisense rice. There was no difference between antisense and wild-type plants in carbohydrate content and photosynthetic ability of the flag leaves in the vegetative growth stage, suggesting that OsSUT1 may not play an important role in carbon metabolism, at least in these materials.

Are contents of Rubisco, soluble protein and nitrogen in flag leaves of rice controlled by the same genetics?

Genetic relations among the contents of Rubisco, soluble protein and total leaf nitrogen (N) in leaves of rice (Oryza sativa L.) were studied by quantitative trait loci (QTL) analysis with a population of backcross inbred lines (BILs) of japonica Nipponbarexindica Kasalath. The ratio of Rubisco to total leaf N in leaves is the main target in improving photosynthetic N-use efficiency in plants. QTLs controlling Rubisco content were not detected near QTLs for total leaf N content. These results indicate that contents of Rubisco and total leaf N are controlled by different genetics. QTLs that controlled the ratio of Rubisco to total leaf N (CORNs) were detected. These results suggest that some mechanism(s) may be involved in determining this ratio, while the contents of Rubisco and total leaf N are controlled in other ways. In elite BILs, the ratios of Rubisco to total leaf N were higher than those of both parents. These results suggest a good possibility of improving N-use efficiency by CORNs in cultivated rice. A QTL controlling Rubisco content was mapped near a QTL for soluble protein content on chromosome 8 at 5 d after heading and on chromosome 9 at 25 d. In each chromosome region, the peaks of both QTLs overlapped accurately, giving a high possibility of pleiotropic effects by the same genes. Different QTLs controlling soluble protein or Rubisco were detected from those detected at 5 d or 25 d after heading. This suggests that these traits are genetically controlled depending on the growth stages of leaves.

[Colitis enhances the colorectal carcinogenesis in rats: correlation between the incidence of aberrant crypt foci and the incidence of tumors].

We examined the implication of colitis on the colorectal carcinogenesis in rats. We used 1, 2-dimethylhydrazine (DMH) as a carcinogen and trinitrobenzenesulfonic acid (TNB) as a colitis-inducing agent on F344 rats. After treating the rats with DMH, TNB markedly enhanced the incidence of aberrant crypt foci (ACF), putative preneoplastic lesions, as well as colon cancers in the rats (p < 0.01). There was positive correlation between the incidence of ACF and the incidence of tumors. Furthermore, we treated the rats with two different anti-inflammatory drugs (a non-steroidal anti-inflammatory drug: Fenbufen and a platelet activating factor-receptor antagonist: PAF-RA) after pre-treatment with DMH and TNB. Only PAF-RA significantly decreased the incidence of ACF in the rats (p < 0.05).

Ser162-Dependent inactivation of overproduced sucrose-phosphate synthase protein of maize leaf in transgenic rice plants.

To investigate the role of Ser162 in phosphorylation-dependent regulation of maize sucrose-phosphate synthase (SPS) activities in rice, transgenic rice plants expressing wild-type or mutagenized maize SPS were produced. Our results indicate that Ser162 was responsible for overproduction-induced inactivation of SPS protein and for light/ dark modulation of this protein in vivo.

Sugar uptake and transport in rice embryo. Expression of companion cell-specific sucrose transporter (OsSUT1) induced by sugar and light.

We investigated sugar uptake and transport in rice (Oryza sativa) embryo during grain germination. Endogenous sugar levels, accumulation of starch granules, and gene expression of a rice sucrose transporter (OsSUT1) were examined using rice embryos germinated with or without exogenous sugar supply. Starch granules remarkably accumulated in the cells around vascular bundles as a consequence of the sugar taken up by the embryos, indicating that the taken-up sugars are transiently converted into starch. In situ detection for OsSUT1 mRNA indicated its localization in the phloem companion cells. Furthermore, northern-blot and in situ hybridization analyses showed that OsSUT1 expression is not detectable in embryos subjected to sugar starvation conditions, whereas its expression is enhanced by an increased endogenous sugar level. Overall results indicate that the expression of companion cell-specific sucrose transporter, OsSUT1 is regulated by the endogenous sugar status as well as light exposure.

Analysis of the transgenic tobacco plants expressing Panicum miliaceum aspartate aminotransferase genes.

Expression of Panicum miliaceum L. (proso millet) mitochondrial and cytosolic aspartate aminotransferase (mAspAT and cAspAT, respectively) genes in transgenic tobacco plants (Nicotiana tabacum) and their influences on protein synthesis were examined. The mAspAT- or cAspAT-transformed plants had about threefold or 3.5-fold higher AspAT activity in the leaf than non-transformed plants, respectively. Interestingly, the leaves of both transformed plants had increased levels of phosphoenolpyruvate carboxylase (PEPC) and transformed plants with cAspAT also had increased levels of mAspAT in the leaf. These results suggest that the increased expression of Panicum cAspAT in transgenic tobacco enhances the expression of its endogenous mAspAT and PEPC, and the increased expression of Panicum mAspAT enhances the expression of its endogenous PEPC.

Molecular cloning and expression analysis of a gene for a sucrose transporter in maize (Zea mays L.).

Here we report the cloning of a sucrose transporter cDNA from maize (Zea mays L.) and an analysis of the expression of the gene. A cDNA clone (ZmSUT1) was identified as a sucrose transporter cDNA from its sequence homology at the amino acid level to sucrose transporters that have been cloned from other higher plant species. Based on the results of genomic Southern hybridization, ZmSUT1 appears to be a single copy gene. A Northern blot analysis of seedlings and leaf blades suggests that the sucrose transporter is involved in the export of accumulated carbohydrates from source leaf blades. From the measurements of transcript levels and carbohydrate contents in mature leaf blades, we propose that the expression of the gene for the maize sucrose transporter is positively regulated by the amounts of soluble sugars such as sucrose and glucose in source leaves of maize. In addition, based on the tissue specificity of the expression of the gene in maize plants at the reproductive stage, it is possible that the sucrose transporter acts in sink tissues such as pedicles as well as in source tissues such as leaf blades.

Carbonic anhydrase activity and CO2-transfer resistance in Zn-deficient rice leaves

It has been reported that carbonic anhydrase (CA) activity in plant leaves is decreased by Zn deficiency. We examined the effects of Zn deficiency on the activity of CA and on photosynthesis by leaves in rice plants (Oryza sativa L.). Zn deficiency increased the transfer resistance from the stomatal cavity to the site of CO2 fixation 2. 3-fold and, consequently, the value of the transfer resistance relative to the total resistance in the CO2-assimilation process increased from 10% to 21%. This change led to a reduced CO2 concentration at the site of CO2 fixation, resulting in an increased gradient of CO2 between the stomatal cavity and this site. The present findings support the hypothesis that CA functions to facilitate the supply of CO2 from the stomatal cavity to the site of CO2 fixation. We also showed that the level of mRNA for CA decreased to 13% of the control level during Zn deficiency. This decrease resembled the decrease in CA activity, suggesting the possible involvement of the CA mRNA level in the regulation of CA activity.

cDNA cloning and tissue specific expression of a gene for sucrose transporter from rice (Oryza sativa L.).

We describe the cloning and expression analysis of a sucrose transporter cDNA from a monocot (the rice plant, Oryza sativa L.). The cDNA clone (OsSUT1) encoded an open reading frame of 1,611 bp (537 amino acids) and showed 76.8 to 79.7% similarity at the amino acid level to other sucrose transporters of dicot species. The predicted membrane topology of OsSUT1 protein is made up of 12 transmembrane helices which is consistent with most of the mono- and disaccharide transporters previously identified. When OsSUT1 cDNA was introduced into yeast and expressed, the cells rapidly accumulated sucrose demonstrating that OsSUT1 does, in fact, encode a sucrose transporter. From genomic Southern hybridization OsSUT1 appeared to be a single copy gene. OsSUT1 was expressed in source organs such as leaf blade, leaf sheath and germinating seed whereas little or no expression was observed in some sink organs such as the panicles before heading and the roots. Transcript was observed at high levels in panicles after heading, particularly in the portion containing endosperm and embryo. In addition, expression of OsSUT1 was high in etiolated seedlings and decreased during light-induced greening.

Purification and Characterization of NAD Malic Enzyme from Leaves of Eleusine coracana and Panicum dichotomiflorum.

NAD malic enzyme (EC 1.1.1.39), which is involved in C(4) photosynthesis, was purified to electrophoretic homogeneity from leaves of Eleusine coracana and to near homogeneity from leaves of Panicum dichotomiflorum. The enzyme from each C(4) species was found to have only one type of subunit by SDS polyacrylamide gel electrophoresis. The M(r) of subunits of the enzme from E. coracana and P. dichotommiflorum was 63 and 61 kilodaltons, respectively. The native Mr of the enzyme from each species was determined by gel filtration to be about 500 kilodaltons, indicating that the NAD malic enzyme from C(4) species is an octamer of identical subunits. The purified NAD malic enzyme from each C(4) species showed similar kinetic properties with respect to concentrations of malate and NAD; each had a requirement for Mn(2+) and activation by fructose- 1,6-bisphosphate (FBP) or CoA. A cooperativity with respect to Mn(2+) was apparent with both enzymes. The activator (FBP) did not change the Hill value but greatly decreased K(0.5) (the concentration giving half-maximal activity) for Mn(2+). The enzyme from E. coracana showed a very low level of activity when NADP was used as substrate, but this activity was also stimulated by FBP. Significant differences between the enzymes from E. coracana and P. dichotomiflorum were observed in their responses to the activators and their immunochemical properties. The enzyme from E. coracana was largely dependent on the activators FBP or CoA, regardless of concentration of Mn(2+). In contrast, the enzyme from P. dichotomiflorum showed significant activity in the absence of the activator, especially at high concentrations of Mn(2+). Both immunodiffusion and immunoprecipitation, using antiserum raised against the purified NAD malic enzyme from E. coracana, revealed partial antigenic differences between the enzymes from E. coracana and P. dichotomiflorum. The activity of the NAD malic enzyme from Amaranthus edulis, a typical NAD malic enzyme type C(4) dicot, was not inhibited by the antiserum raised against the NAD malic enzyme from E. coracana.

Light Modulation and Localization of Sucrose Phosphate Synthase Activity between Mesophyll Cells and Bundle Sheath Cells in C(4) Species.

Experiments were conducted with several Panicum species (representing the different C(4) subtypes) to examine the light modulation of sucrose phosphate synthase (SPS) activity and the effect of illumination on the distribution of SPS activity between mesophyll cells (MC) and bundle sheath cells (BSC). Activity of SPS in the light decreased in the order: C(4) > C(3)-C(4) intermediate > C(3). In illuminated leaves, SPS activities were similar among the three C(4) subtypes, but SPS activity was higher for NAD-malic enzyme (NAD-ME) species with centripetal chloroplasts in BSC (NAD-ME(P) species) than for NAD-ME species with centrifugal chloroplasts in BSC (NAD-ME(F) species). Transfer of plants into darkness for 30 minutes resulted in decreased SPS activity for all species tested except Panicum bisulcatum (C(3) species) and Panicum virgatum (NAD-ME(P) species) which showed little or no change. All C(4) subtypes had some SPS activity both in MC and BSC. In the light, SPS activity was mainly in the MC for NADP-ME, NAD-ME(F) and phosphoenolpyruvate carboxykinase species, while it was mainly in the BSC for NAD-ME(P) species. In the dark, for all C(4) subtypes, SPS activity in the MC was decreased to a greater extent than that in the BSC. It is intriguing that NAD-ME(F) and NAD-ME(P) species differed in the activity and distribution of SPS activity between MC and BSC, although they are otherwise identical in the photosynthetic carbon assimilation pathway. Diurnal changes in SPS activity in the MC and BSC were also examined in maize leaves. SPS activity in the MC in maize leaves was high and relatively constant throughout the middle of the light period, dropped rapidly after sunset and increased again prior to the light period. On the other hand, SPS activity in the BSC was lower and changed more coincidently with light intensity than that in the MC. The results suggested that light activation of SPS activity located in the BSC may require higher irradiance for saturation than the SPS in the MC. We conclude that SPS may function in both MC and BSC for sucrose synthesis in the light, particularly at high light intensity, while in the dark, the major function may be in the BSC during starch degradation.