Sugar regulates mRNA abundance of H(+)-ATPase gene family members in tomato.

The plant plasma membrane H(+)-ATPase energizes the secondary uptake of nutrients and may facilitate cell expansion by acidifying the cell wall. In yeast, Glc stimulates the accumulation of H(+)-ATPase mRNA, and the growth rate supported by various sugars is correlated with H(+)-ATPase protein abundance. Expression of three H(+)-ATPase genes, LHA1, LHA2, and LHA4, was previously detected in tomato (Lycopersicon esculentum). We have characterized the sequence of the LHA4 gene and examined the expression of these three tomato H(+)-ATPase genes in growing tissues and in response to exogenous sugars. LHA4 is a member of the H(+)-ATPase subfamily, including the Arabidopsis thaliana genes AHA1, AHA2, and AHA3. The 5' untranslated region of the deduced LHA4 cDNA contains a short, open reading frame very similar to that in the Nicotiana plumbaginifolia gene PMA1. LHA4 transcript abundance in seedlings is correlated with cell growth, being 2.5 times greater in hypocotyls of dark- versus light-grown plants. The accumulation of both LHA4 and LHA2 mRNAs is induced by the addition of exogenous sugars and this induction appears to be dependent on sugar uptake and metabolism, because mannitol and 3-O-methylglucose do not stimulate mRNA accumulation. These results suggest that the induction of expression of H(+)-ATPase genes by metabolizable sugars may be part of a generalized cellular response to increased cell growth and metabolism promoted by the availability of an abundant carbon source.

Two plasma membrane H(+)-ATPase genes expressed in guard cells of Vicia faba are also expressed throughout the plant.

Guard cells modulate stomatal apertures in response to hormones, metabolic demands and environmental stimuli. The guard cell PM H(+)-ATPases play a critical role in this process by generating the electrochemical gradient to drive solute transport and concomitant water flux. The PM H(+)-ATPase activity is specifically regulated by red and blue light, fungal toxins and auxin. To determine if the unique responsiveness of the guard cell PM H(+)-ATPase is due to the expression of a cell-specific isoform, we amplified by PCR, and cloned portions of PM H(+)-ATPase genes VHA1 and VHA2, which are expressed in guard cell protoplasts (GCP). In situ hybridization to leaf tissue sections indicated that VHA1 and VHA2 genes were expressed in guard cells and mesophyll cells but not in epidermal cells or vascular tissues. Furthermore, a gene-specific quantitative reverse transcription (RT)-PCR detected VHA1 and VHA2 mRNAs in both GCP and mesophyll cell protoplast mRNA as well as in mRNA isolated from roots, leaves, stems and flowers. Thus, two PM H(+)-ATPase genes expressed in guard cells are also expressed in many other tissues and cell types. This suggests that the unique responsiveness of the guard cell PM H(+)-ATPases to environmental stimuli results from cell-specific signal transduction pathways rather than the expression of a cell-specific PM H(+)-ATPase.

Higher plant Ca(2+)-ATPase: primary structure and regulation of mRNA abundance by salt.

Calcium-dependent regulatory mechanisms participate in diverse developmentally, hormonally, and environmentally regulated processes, with the precise control of cytosolic Ca2+ concentration being critical to such mechanisms. In plant cells, P-type Ca(2+)-ATPases localized in the plasma membrane and the endoplasmic reticulum are thought to play a central role in regulating cytoplasmic Ca2+ concentrations. Ca(2+)-ATPase activity has been identified in isolated plant cell membranes, but the protein has not been characterized at the molecular level. We have isolated a partial-length cDNA (LCA1) and a complete genomic clone (gLCA13) encoding a putative endoplasmic reticulum-localized Ca(2+)-ATPase in tomato. The deduced amino acid sequence specifies a protein (Lycopersicon Ca(2+)-ATPase) of 1048 amino acids with a molecular mass of 116 kDa, eight probable transmembrane domains, and all of the highly conserved functional domains common to P-type cation-translocating ATPases. In addition, the protein shares approximately 50% amino acid sequence identify with animal sarcoplasmic/endoplasmic reticulum Ca(2+)-ATPases but less than 30% identity with other P-type ATPases. Genomic DNA blot hybridization analysis indicates that the Lycopersicon Ca(2+)-ATPase is encoded by a single gene. RNA blot hybridization analysis indicates the presence of three transcript sizes in root tissue and a single, much less abundant, transcript in leaves. Lycopersicon Ca(2+)-ATPase mRNA levels increase dramatically upon a 1-day exposure to 50 mM NaCl. Thus this report describes the primary structure of a higher-plant Ca(2+)-ATPase and the regulation of its mRNA abundance by salt stress.

Transfer cells and solute uptake in minor veins of Pisum sativum leaves.

Morphometric and physiological studies were conducted to determine whether the wall ingrowths of transfer cells in the minor-vein phloem of Pisum sativum L. leaves increase the capacity of the cells for solute influx. Size and number of wall ingrowths are positively correlated to the photon flux density (PFD) at which the plants are grown. An analysis of plasmodesmatal frequencies indicated that numerous plasmodesmata are present at all interfaces except those between the sieveelement-transfer-cell complex (SE-TCC) and surrounding cells where plasmodesmata are present but few in number. Flux of exogenous sucrose into the SE-TCC was estimated from kinetic profiles of net sucrose influx into leaf discs, quantitative autoradiography, and measurements of sucrose translocation. Flux based both on the saturable (carrier-mediated) and the linear components of influx was 47% greater in leaves of plants grown at high PFD (1000 µmol·m(-2)·s(-1)) than those grown in low PFD (200 µmol·m(-2)·s(-1)) and was paralleled by a 47% increase in SE-TCC plasmalemma surface area. Flux of endogenous photosynthate across the SE-TCC plasmalemma was calculated from carbon balance and morphometric data. The increase in flux in high-light leaves over that in low-light leaves can be explained on the basis of an increase in plasmalemma surface area. In intact leaves, a 'standing osmotic gradient' may facilitate transport of solute into transfer cells with extensive wall elaborations.

Molecular Cloning of Tomato Plasma Membrane H-ATPase.

Two cDNA clones (LHA1 and LHA2) from tomato (Lycopersicon esculentum) which likely encode isoforms of the plasma membrane H(+)-ATPase were isolated. The longest cDNA (3229 base pairs), LHA1, comprises an open reading frame that encodes a 956 amino acid, 105 kilodalton polypeptide with several potential transmembrane domains. In vitro transcription and translation of LHA1 yields a major translation product of approximately 100 kilodaltons that is immunoprecipitable with antiserum to the corn root plasma membrane H(+)-ATPase. LHA2 encodes a portion of a coding sequence that is 96% identical to LHA1, suggesting that LHA2 encodes an isoform of the H(+)-ATPase. Genomic DNA gel blot analysis indicates that both LHA1 and LHA2 hybridize to a common set of six to eight restriction fragments at moderate stringency and to single distinct fragments at high stringency. LHA1 and LHA2 map to distinct sites on chromosomes three and six, respectively. RNA gel blot analysis indicates that both LHA1 and LHA2 hybridize to 3.4 kilobase pair transcripts present in both leaves and roots, although the LHA2 transcript is relatively more abundant in leaves than in roots. These results indicate that in tomato as many as six to eight genes may encode the plasma membrane H(+)-ATPase, two of which are expressed at the level of mRNA in both roots and leaves.

Different Patterns of Vein Loading of Exogenous [C]Sucrose in Leaves of Pisum sativum and Coleus blumei.

Vein loading of exogenous [(14)C]sucrose was studied using short uptake and wash periods to distinguish between direct loading into veins and loading via mesophyll tissue. Mature leaf tissue of Pisum sativum L. cv Little Marvel, or Coleus blumei Benth. cv Candidum, was abraded and leaf discs were floated on [(14)C]sucrose solution for 1 or 2 minutes. Discs were then washed for 1 to 30 min either at room temperature or in the cold and were frozen, lyophilized, and autoradiographed. In P. sativum, veins were clearly labeled after 1 minute uptake and 1 minute wash periods. Autoradiographic images did not change appreciably with longer times of uptake or wash. Vein loading was inhibited by p-chloromercuribenzenesulfonic acid. These results indicate that uptake of exogenous sucrose occurs directly into the veins in this species. When C. blumei leaf discs were floated on [(14)C]sucrose for 2 minutes and washed in the cold, the mesophyll was labeled but little, if any, minor vein loading occurred. When discs were labeled for 2 minutes and washed at room temperature, label was transferred from the mesophyll to the veins within minutes. These results indicate that there may be different patterns of phloem loading of photosynthetically derived sucrose in these two species.

Scintillation counting of 14C-labeled soluble and insoluble compounds in plant tissue.

A method is described for the liquid scintillation counting of 14C in plant tissues. Samples are fixed, in the scintillation vial, in a solution of ethanol and acetic acid (3:1) and decolorized with commercial bleach before the addition of scintillation liquid. The method was compared to other techniques of tissue oxidation or digestion and found to be equally effective at least with thin tissue samples. The technique is simple, rapid, and inexpensive and does not result in loss of 14C.

Photoassimilate-transport characteristics of nonchlorophyllous and green tissue in variegated leaves of Coleus blumei Benth.

The nonchlorophyllous (albino) tissue of mature C. blumei leaves is a sink for photoassimilate. Transport from the green to the albino region of the same leaf was inhibited by cold and anoxia. When the green tissue of mature leaves was removed, the remaining albino portion imported labeled translocate from other mature leaves in the phloem. Photoassimilate unloading in the albino region of mature leaves was studied by quantitative autoradiography. The unloading was inhibited by cold but not by anoxia. No labeled photoassimilate could be detected in the free space of mature albino tissue by compartmental efflux analysis as phloem unloading proceeded in a N2 atmosphere, indicating that unloading, may occur by a symplastic pathway as it apparently does in sink leaves of other species. The minor veins of mature albino leaf tissue did not accumulate exogenous [(14)C]sucrose. Minor veins of green tissue in the same leaves accumulated [(14)C]sucrose but, in contrast to other species studied to date, this accumulation was insensitive to the inhibitor p-chloromercuribenzensulfonic acid (PCMBS).In its capacity to import and unload photoassimilate, and in the inability, of the minor veins to accumulate exogenous sucrose, the albino region of the mature C. blumei lamina differs from mature albino tobacco leaves and darkened mature leaves of other species. This, together with evidence indicating that phloem loading in C. blumei and other species may occur by different routes and with different sensitivity to PCMBS, indicates that the mechanism of transfer of photoassimilates between veins and surrounding tissues, and the mechanism of the sink-source transition, may not be the same in the leaves of all species. It is speculated that the unusual properties of the C. blumei leaf may be a consequence of the presence, in the minor veins, of "intermediary cells", large companion cells connected to the bundle sheath by abundant plasmodesmata.