LeProT1, a transporter for proline, glycine betaine, and gamma-amino butyric acid in tomato pollen.

During maturation, pollen undergoes a period of dehydration accompanied by the accumulation of compatible solutes. Solute import across the pollen plasma membrane, which occurs via proteinaceous transporters, is required to support pollen development and also for subsequent germination and pollen tube growth. Analysis of the free amino acid composition of various tissues in tomato revealed that the proline content in flowers was 60 times higher than in any other organ analyzed. Within the floral organs, proline was confined predominantly to pollen, where it represented >70% of total free amino acids. Uptake experiments demonstrated that mature as well as germinated pollen rapidly take up proline. To identify proline transporters in tomato pollen, we isolated genes homologous to Arabidopsis proline transporters. LeProT1 was specifically expressed both in mature and germinating pollen, as demonstrated by RNA in situ hybridization. Expression in a yeast mutant demonstrated that LeProT1 transports proline and gamma-amino butyric acid with low affinity and glycine betaine with high affinity. Direct uptake and competition studies demonstrate that LeProT1 constitutes a general transporter for compatible solutes.

A major isoform of the maize plasma membrane H(+)-ATPase: characterization and induction by auxin in coleoptiles.

The plasma membrane (PM) H(+)-ATPase has been proposed to play important transport and regulatory roles in plant physiology, including its participation in auxin-induced acidification in coleoptile segments. This enzyme is encoded by a family of genes differing in tissue distribution, regulation, and expression level. A major expressed isoform of the maize PM H(+)-ATPase (MHA2) has been characterized. RNA gel blot analysis indicated that MHA2 is expressed in all maize organs, with highest levels being in the roots. In situ hybridization of sections from maize seedlings indicated enriched expression of MHA2 in stomatal guard cells, phloem cells, and root epidermal cells. MHA2 mRNA was induced threefold when nonvascular parts of the coleoptile segments were treated with auxin. This induction correlates with auxin-triggered proton extrusion by the same part of the segments. The PM H(+)-ATPase in the vascular bundies does not contribute significantly to auxin-induced acidification, is not regulated by auxin, and masks the auxin effect in extracts of whole coleoptile segments. We conclude that auxin-induced acidification in coleoptile segments most often occurs in the nonvascular tissue and is mediated, at least in part, by increased levels of MHA2.

FAD is a further essential cofactor of the NAD(P)H and O2-dependent zeaxanthin-epoxidase.

In chloroplasts of plants the xanthophyll cycle is suggested to function as a protection mechanism against photodamage. Two enzymes catalyze this cycle. One of them, violaxanthin de-epoxidase, transforms violaxanthin (Vio) to zeaxanthin (Zea) via antheraxanthin (Anth) and is bound to the lumenal surface of the thylakoid vesicles, when being in its active state. The other enzyme, Zea-epoxidase, is responsible for the backward reaction (Zea-->Anth-->Vio) and is active at the stromal side of the thylakoid. For the epoxidation of Zea this enzyme requires NAD(P)H and O2 as cosubstrates. Using isolated thylakoid membranes we found that FAD enhances the epoxidase activity (decrease of apparent Km for NAD(P)H and two-fold increase of Vmax). The flavin functions as a third cofactor which is partially lost during the isolation procedure of thylakoids. Other flavins, such as FMN or riboflavin are without effect. The involvement of FAD in the enzymatic reaction is also demonstrated by the inhibitory action of diphenyleneiodoniumchloride (DPI) (IC50 = 2.3 microM), a compound that blocks the reoxidation of reduced flavins within enzymes. The Zea-epoxidase is a multi-component enzyme system which can be classified as FAD-containing, NAD(P)H- and O2-dependent monooxygenase that is able to epoxidize 3-hydroxy beta-ionone rings of xanthophylls in the 5,6 position.

Auxin induces exocytosis and the rapid synthesis of a high-turnover pool of plasma-membrane H(+)-ATPase.

Auxin causes elongation growth of plant cells by increasing the plastic extensibility of the cell wall. Putative cellular events involved in this hormone action were studied using maize (Zea mays L.) coleoptiles with the following results: (i) Auxin enhances membrane flow from the endoplasmic reticulum to the plasma membrane (PM). This effect was demonstrated by pulse-labeling of the endoplasmic reticulum with myo-[(3)H]inositol in coleoptile segments and by measuring the distribution of the label within isolated and separated microsomal membrane fractions, (ii) Auxin rapidly increases the amount of antibody-detectable H(+)-ATPase in the PM. This augmentation is already significant 10 min after the addition of indole-3-acetic acid (IAA) and reaches a new higher steady-state level after about 30 min. (iii) Cycloheximide, a potent inhibitor of both protein synthesis and extension growth, quickly diminishes the auxin-enhanced level of the PM H(+)-ATPase, indicating an apparent half-life of the enzyme of around 12 min. (iv) Cordycepin, which blocks the synthesis of mRNAs, reduces the auxin-elevated level of the H(+)-ATPase similar to cycloheximide. (v) Changes in the growth rate of coleoptile segments in response to IAA, cycloheximide, and cordycepin exactly reflect the changes of the H(+)-ATPase level in the PM. (vi) The elongation growth induced by fusicoccin, or ester compounds, or by an elevated CO2 concentration in the incubation medium, is not related to an increased number of H(+)-ATPase molecules within the PM. (vii) The necessity of H(+) for cell-wall-loosening processes is again demonstrated by growth experiments with abraded coleoptile segments. The adjustment of the cell wall to a pH of ≥6.5 completely abolishes the auxin-induced elongation growth; no inhibition occurs with non-abraded segments. Buffer solutions of pH ≤6.0 induce "acid growth" of abraded segments for several hours. It is suggested that auxin activates a cluster of genes responsible (i) for the induction and acceleration of exocytotic processes (e.g. by the synthesis of either proteins, necessary for the fusion of membranes, or of other effectors); (ii) for the synthesis of PM H(+)-ATPases, increasing the capacity for H(+)-extrusion into the apoplast as a precondition for wall enlargement ("acid growth"); (iii) for a supposed synthesis and exocytosis of certain proteins, enzymes and wall precursors necessary for wall metabolism and the "repair" of the proton-loosened and turgor-stretched cell wall. Both, fusicoccin and auxin affect cell-wall plasticity according to the "acid-growth" theory. However, the mechanisms leading to this event are completely different; the auxinenhanced H(+)-extrusion is a gene-controlled process.