Andrew D. Hanson

Drought and salt tolerance: towards understanding and application

Abstract Only a few desirable traits in plants are understood at the molecular level. Fewer still are amenable to manipulation by molecular biological techniques currently available. The accumulation of glycine betaine, an osmoprotectant compound implicated in drought and salt tolerance, may be one such trait.

Salt-inducible betaine aldehyde dehydrogenase from sugar beet: cDNA cloning and expression

Members of the Chenopodiaceae, such as sugar beet and spinach, accumulate glycine betaine in response to salinity or drought stress. The last enzyme in the glycine betaine biosynthetic pathway is betaine aldehyde dehydrogenase (BADH). In sugar beet the activity of BADH was found to increase two- to four-fold in both leaves and roots as the NaCl level in the irrigation solution was raised from 0 to 500 mM. This increase in BADH activity was paralleled by an increase in level of translatable BADH mRNA. Several cDNAs encoding BADH were cloned from a λgt10 libary representing poly(A)+ RNA from salinized leaves of sugar beet plants, by hybridization with a spinach BADH cDNA. Three nearly full-length cDNA clones were confirmed to encode BADH by their nucleotide and deduced amino acid sequence identity to spinach BADH; these clones showed minor nucleotide sequence differences consistent with their being of two different BADH alleles. The clones averaged 1.7 kb and contained an open reading frame predicting a polypeptide of 500 amino acids with 83% identity to spinach BADH. RNA gel blot analysis of total RNA showed that salinization to 500 mM NaCl increased BADH mRNA levels four-fold in leaves and three-fold in the taproot. DNA gel blot analyses indicated the presence of at least two copies of BADH in the haploid sugar beet genome.

Comparative biochemical and immunological studies of the glycine betaine synthesis pathway in diverse families of dicotyledons

Members of the Chenopodiaceae can accumulate high levels (>100 μmol·(g DW)-1) of glycine betaine (betaine) in leaves when salinized. Chenopodiaceae synthesize betaine by a two-step oxidation of choline (choline→betaine aldehyde→ betaine), with the second step catalyzed by betaine aldehyde dehydrogenase (BADH, EC 1.2.1.8). High betaine levels have also been reported in leaves of species from several distantly-related families of dicotyledons, raising the question of whether the same betaine-synthesis pathway is used in all cases.Fast atom bombardment mass spectrometry showed that betaine levels of >100 μmol·(g DW)-1 are present in Lycium ferocissimum Miers (Solanaceae), Helianthus annuus L. (Asteraceae), Convolvulus arvensis L. (Convolvulaceae), and Amaranthus caudatus L. (Amaranthaceae), that salinization promotes betaine accumulation in these plants, and that they can convert supplied choline to betaine aldehyde and betaine. Nicotiana tabacum L. and Lycopersicon lycopersicum (L.) Karst. ex Farw. (Solanaceae), Lactuca sativa L. (Asteraceae) and Ipomoea purpurea L. (Convolvulaceae) also contained betaine, but at a low level (0.1–0.5 μmol·(g DW)-1. Betaine aldehyde dehydrogenase activity assays, immunotitration and immunoblotting demonstrated that the betaine-accumulating species have a BADH enzyme recognized by antibodies raised against BADH from Spinacia oleracea L. (Chenopodiaceae), and that the Mr of the BADH monomer is in all cases close to 63 000. These data indicate that the choline→betaine aldehyde→betaine pathway may have evolved by vertical descent from an early angiosperm ancestor, and might be widespread (albeit not always strongly expressed) among flowering plants. Consistent with these suggestions, Magnolia x soulangiana was found to have a low level of betaine, and to express a protein of Mr 63 000 which cross-reacted with antibodies to BADH from Spinacia oleracea.

Betaine aldehyde dehydrogenase from spinach leaves: Purification, in vitro translation of the mRNA, and regulation by salinity☆

Spinach (Spinacia oleracea L.) leaves contain a nuclear-encoded chloroplastic betaine aldehyde dehydrogenase (EC 1.2.1.8) which is induced several-fold by salinization. Betaine aldehyde dehydrogenase was purified 2400-fold to homogeneity with an overall yield of 14%. The procedure included fractional precipitation with ammonium sulfate, followed by ion-exchange, hydrophobic interaction, and hydroxyapatite chromatography in open columns, and ion-exchange and hydrophobic interaction chromatography in a fast-protein liquid chromatography system. The betaine aldehyde dehydrogenase had a pI of 5.65, and a broad pH optimum between 7.5 and 9.5. The Km values for NAD+ and NADP+ were 20 and 320 microM, respectively; the Vmax of the reaction with NADP+ was 75% of that with NAD+. The native enzyme is a dimer with subunits of Mr 63,000. Highly specific antiserum was raised against the native enzyme, and was used in conjunction with cell-free translation of leaf poly(A)+ RNA to show (a) that betaine aldehyde dehydrogenase is synthesized as a precursor of Mr 1200 higher than the mature polypeptide, and (b) that both chronic salt stress and salt shock provoke a several-fold increase in the level of translatable message for the enzyme.

Translocation and metabolism of glycine betaine by barley plants in relation to water stress.

The glycine betaine which accumulated in shoots of young barley plants (Hordeum vulgare L.) during an episode of water stress did not undergo net destruction upon relief of stress, but its distribution among plant organs changed. During stress, betaine accumulated primarily in mature leaves, whereas it was found mainly in young leaves after rewatering. Well-watered, stressed, and stressed-rewatered plants were supplied with [methyl-14C]betaine (8.5 nmol) via an abraded spot on the second leaf blade, and incubated for 3 d. In all three treatments the added 14C migrated more or less extensively from the second leaf blade, but was recovered quantitatively from various plant organs in the form of betaine; no labeled degradation products were found in any organ. When 0.5 μmol of [methyl-14C]betaine was applied via an abraded spot to the second leaf blades of well-watered, mildly-stressed, and stressed-rewatered plants, 14C was translocated out of the blades at velocities of about 0.2–0.3 cm/min which were similar to velocities found for applied [14C]sucrose. Heat-girdling of the sheath prevented export of [14C]betaine from the blade. When 0.5 μmol [3H]sucrose and 0.5 μmol [14C]betaine were suppled simultaneously to second leaf blades, the 3H/14C ratio in the sheath tissue was the same as that of the supplied mixture. After supplying tracer [14C]betaine aldehyde (the immediate precursor of betaine) to the second leaf blade, the 14C which was translocated into the sheath was in the form of betaine. Thus, betaine synthesized by mature leaves during stress behaves as an inert end product and upon rewatering is translocated to the expanding leaves, most probably via the phloem. Accordingly, it is suggested that the level of betaine in a barley plant might serve as a useful cumulative index of the water stress experienced during growth.

Determination of glycine betaine by pyrolysis-gas chromatography in cereals and grasses

Glycine betaine content of 22 species of cereals and grasses was determined by pyrolysis-gas liquid chromatography assay.

Light Stimulation of Proline Synthesis in Water-Stressed Barley Leaves

The effect of light on [14C]glutamate conversion to free proline during water stress was studied in attached barley (Hordeum vulgare L.) leaves which had been trimmed to 10 cm in length. Plants at the three-leaf stage were stressed by flooding the rooting medium with polyethylene glycol 6000 (osmotic potential-19 bars) for up to 3 d. During this time the free proline content of 10-cm second leaves rose from about 0.02 to 2 μmol/leaf while free glutamate content remained steady at about 0.6 μmol/leaf. In stressed leaves, the amount of [14C]glutamate converted to proline in a 3-h period of light or darkness was taken to reflect the in-vivo rate of proline biosynthesis because the following conditions were met: (a) free-glutamate levels were not significantly different in light and darkness; (b) both tracer [14C]-glutamate and [14C]proline were rapidly absorbed; (c) rates of [14C]proline oxidation and incorporation into protein were very slow. As leaf water potential fell, more [14C]glutamate was converted to proline in both light and darkness, but at any given water potential in the range-12 to-20 bars, illuminated leaves converted twice as much [14C]glutamate to proline.

Betaine aldehyde dehydrogenase polymorphism in spinach: genetic and biochemical characterization

Spinach (Spinacia oleracea L.) has a major chloroplastic isozyme of betaine aldehyde dehydrogenase (BADH) and a minor cytosolic one. Among a diverse collection of spinach accessions, three electrophoretic banding patterns of chloroplastic BADH were found: two were single banded and one was triple banded. Genetic analysis of these patterns indicated that chloroplastic BADH is encoded by a single, nuclear gene with two alleles, designated slow (S) and fast (F), and that products of these alleles can hybridize to form either homodimers or a heterodimer. The S allele was by far the most common among the accessions examined. Native and sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed that the SS and FF homodimers differ in charge but not molecular weight.

Water stress provokes a generalized increase in phosphatidylcholine turnover in barley leaves

Water and salt stress promote betaine accumulation in leaves of barley (Hordeum vulgare L.) by accelerating the de-novo synthesis of betaine, via choline. Previous radiotracer kinetic studies have implicated stress-enhanced turnover of the choline moiety of phosphatidylcholine (PC) as a major source of choline for betaine synthesis. Two approaches have therefore been followed to show whether stress-induced PC turnover is a cellor organelle-specific phenomenon, or a generalized one. In the first approach, [3H]ethanolamine of high specific activity was supplied to second leaves of unstressed and water-stressed barley plants; after 1 h, paired sections of tissue were excised from each leaf, one for extraction and analysis of [3H]metabolites and the other for autoradiography. The3H-activity remaining in the leaf tissue after washing out the water-soluble3H-metabolites during preparation for autoradiography was taken to be mainly in phospholipids. In unstressed leaves, [3H]phosphatidylethanolamine (PE) was the major labeled phospholipid, whereas there were approximately equal amounts of [3H]PE and [3H]PC in stressed leaves. At the light-microscope level, silver grains were associated with all living cells in both unstressed and stressed leaves; grains were concentrated in the cytoplasmic regions of highly vacuolate mesophyll cells, and were distributed throughout densely cytoplasmic vascular parenchyma. At the electron-microscope level, silver grains were not confined to any particular types of membranes in unstressed or stressed leaves. In the second approach, second leaves of stressed plants received a 1-h pulse of [14C]ethanolamine, and were then homogenized. The brei was subjected to sucrose density gradient centrifugation. The specific radioactivity of [14C]PC was quite similar in the gradient fractions, whether they contained microsomes or mitochondrial plus chloroplast membranes. We infer that stress does not enhance the turnover of any structurally discrete class of PC, but rather stimulates PC turnover in several or all classes of membranes in most cells of the leaf.

BIOCHEMICAL, IMMUNOLOGICAL AND GENETIC CHARACTERIZATION OF NATURAL GRAMINE-FREE VARIANTS OF HORDEUM VULGARE L.*

Abstract Many barley cultivars (e.g. Arimar) contain the indole alkaloid gramine, but some do not. Among seven gramine-free cultivars tested, two phenotypic classes were found: those with a normal level of the N -methyltransferase (NMT) activity that catalyzes the last two steps of gramine synthesis (e.g. Proctor); and those having neither NMT activity nor protein recognized by polyclonal antibodies raised against purified NMT (e.g. Morex). A 3 × 3 diallel cross with reciprocals was made using cultivars Arimar, Proctor and Morex. The pattern of occurrence of gramine and NMT activity among the F 1 hybrids suggested that Proctor and Morex carried defective alleles of the same nuclear gene governing an early step in the indole alkaloid pathway, and that Morex also carried a recessive allele at a nuclear locus encoding NMT activity. However, no non-parental alkaloid phenotypes were found in the F 2 generation from an Arimar × Morex cross and the ratio of progeny with gramine to those with no alkaloids was 3 : 1. One explanation of these results is tight linkage between genes controlling two of the steps in gramine biosynthesis.