RP-HPLC法测定长期盐胁迫下盐爪爪和盐穗木中的甜菜碱

通过对影响甜菜碱提取和测定的各种因素进行研究,建立了一种准确、快速的测定长期盐胁迫下盐爪爪和盐穗木中甜菜碱的HPLC方法。样品采用超声波甲醇提取,并依次通过强阴阳离子交换树脂(Dowex 50×8和Dowex 50×2)进行纯化,得到的样品采用反相C18柱进行分离,色谱条件:流动相为50 mmol/L、pH 4.5的KH2PO4溶液;波长200 nm下紫外测定,流速0.7 mL/min;此方法的检出限为0.02μg/mL,平均回收率为97.2%。通过对0~500 mmol/L NaCl胁迫下的盐爪爪和盐穗木中甜菜碱进行测定,甜菜碱的含量均呈现先增加后减少的趋势,盐爪爪在NaCl浓度为200 mmol/L时达到最大,而盐穗木在NaCl浓度为300 mmol/L时达到最大。     

Betaine distribution in the Malvaceae

Aerial parts of 26 taxa, distributed in 18 genera and all 5 tribes of the Malvaceae have been examined for the presence of betaines. Glycinebetaine was obtained in high yield (0.5-4.6%, dry weight) from all the plants studied, except Abelmoschus moschatus, in extracts of which glycinebetaine was not detected. Trigonelline was recorded for 16 of the plants tested, but the yields were low (0.005-0.07%, dry weight). Roots and flowers of a few of the species were also examined for betaines. The same compounds as those found in the aerial parts were usually detected, but the glycinebetaine contents of the roots and flowers were considerably lower.     

Compatibility of glycinebetaine in rice plants: evaluation using transgenic rice plants with a gene for peroxisomal betaine aldehyde dehydrogenase from barley

Glycinebetaine is synthesized in plants by the two‐step oxidation of choline, with betaine aldehyde as the intermediate. The reactions are catalyzed by choline mono‐oxygenase and betaine aldehyde dehydrogenase. Rice plants, which do not accumulate glycinebetaine, possess a gene encoding betaine aldehyde dehydrogenase, whose activity is detectable at low levels. To evaluate the compatibility in rice of glycinebetaine on growth and tolerance to salt, cold and heat, we produced transgenic rice plants by introduction of a cDNA for betaine aldehyde dehydrogenase of barley, which is localized in peroxisomes unlike the chloroplast‐specific localization of betaine aldehyde dehydrogenase in spinach and sugar beet. The transgenic rice plants converted high levels of exogenously applied betaine aldehyde (up to 10 mol m^–3) to glycinebetaine more efficiently than did wild‐type plants. The elevated level of glycinebetaine in transgenic plants conferred significant tolerance to salt, cold and heat stress. However, very high levels of glycinebetaine, resulting from conversion of applied betaine aldehyde to glycinebetaine or from exogenous application, inhibited increases in length of rice plants but not increases in dry weight. Our results suggested that the benefits of accumulation of glycinebetaine by rice plants might be considerable under high light conditions.     

High-performance liquid chromatographic identification and quantitation of cyclic adenosine 3':5'-monophosphate in higher (Phaseolus vulgaris L.) and lower (Chlorella sp.) plants

Cyclic adenosine 3':5'-monophosphate (cAMP) was extracted from Phaseolus vulgaris L. cv. Limburg seedlings and Chlorella sp. The cAMP was purified by charcoal adsorption, polyvinylpyrrolidone (PVP) and Dowex 50 W × 8 column chromatography and by preparative high-performance liquid chromatography (HPLC). Quantitation was achieved by combining phosphodiesterase (PDE) treatment with analytical HPLC (reversed phase ion-pair partition chromatography) and cAMP-dependent protein kinase activation. This provided a very specific, accurate and sensitive assay for cAMP determinations. The cAMP content found in Chlorella (70–90 pmol/g dry wt) was comparable with previous reports using other quantitation methods, whereas the endogenous concentration found in bean seedlings (92 pmol/g dry wt) was considerably lower than previously reported data.     

Betaine distribution in the Bromeliaceae

Aerial parts of 38 taxa, distributed in 21 genera and all three subfamilies of the Bromeliaceae have been examined for the presence of betaines. Glycinebetaine and trigonelline were isolated from all the plants studied, although the yields of both compounds were low. For glycinebetaine, values (based upon dry weight) varied from 0.0004% for Pitcairnia corallina to 0.087% for Tillandsia usneoides. Trigonelline levels varied from 0.0003 to 0.022%; the highest yields were recorded for Billbergia rubicunda (0.022%) and Vriesia splendens (0.020%).     

Quantitative estimation of betaines in commercial seaweed extracts using overpressured layer chromatography

An off-line, overpressured layer chromatographic procedure has been developed for the evaluation of betaines in commercial seaweed extracts using Dragendorff's reagent for the detection of the compounds and densitometry for their quantitative estimation. Using continuous development and a low sample volume, the amounts of -aminobutyric acid betaine and -aminovaleric acid betaine can be estimated, but a larger sample volume is necessary for the estimation of glycinebetaine and minor betaines.The critical steps of this analytical method are the visualization and the quantitative evaluation of the spots produced. Temperature plays a major role in the resolution, sensitivity and precision after derivatization with Dragendorff's reagent; this has led to the adoption of standardized conditions.Author for correspondence     

Determination of betaine metabolites and dimethylsulfoniopropionate in coral tissues using liquid chromatography–time-of-flight mass spectrometry and stable isotope-labeled internal standards

A convenient procedure for determination of seven betaine analogs and dimethylsulfoniopropionate (DMSP) in extracts of coral tissues using LC–MS stable isotope dilution is described. Extraction procedures were optimized for selective extraction of polar metabolites from coral tissues. The LC–MS protocol employed a pentafluorophenylpropyl (PFPP) column for HPLC separation, with chromatographic resolution of isobaric and isomeric zwitterionic metabolites optimized by adjusting the acidity of the mobile phase. A ternary gradient was used to exploit the unusual retention characteristics of cationic metabolites on the PFPP column, with incorporation of ammonium acetate in a later gradient stage promoting elution of more hydrophobic betaines which are retained at high organic content in the absence of ammonium acetate. We demonstrate that the new LC–MS based method provides accurate measurements from nanomolar to high micromolar concentrations, and can be applied for profiling of betaine metabolites and DMSP in corals or other aquatic organisms.     

Betaine distribution in Angiosperms

Over 140 Angiosperm species, included in 45 of the 62 orders listed by Engler, have been investigated for the presence of betaines, which were detected in 86% of the species examined and in 43 of the orders. Moreover, betaines were reported earlier in a further seven of the orders. Thus, it can be concluded that betaines are very widely distributed in Angiosperms. The most commonly detected betaines in the study were glycinebetaine and trigonelline, although others, such as prolinebetaine, trans-4-hydroxyprolinebetaine and pipecolatebetaine were found, although with a very restricted distribution. In the large majority of species tested, betaine levels were low (below 0.1%, dry weight).     

Targeting Glycinebetaine for Abiotic Stress Tolerance in Crop Plants: Physiological Mechanism,Molecular Interaction and Signaling

In the era of climate change, abiotic stresses (e.g., salinity, drought, extreme temperature, flooding, metal/metalloid(s), UV radiation, ozone, etc.) are considered as one of the most complex environmental constraints that restricts crop production worldwide. Introduction of stress-tolerant crop cultivars is the most auspicious way of surviving this constraint, and to produce these types of tolerant crops. Several bioengineering mechanisms involved in stress signaling are being adopted in this regard. One example of this kind of manipulation is the osmotic adjustment. The quarternary ammonium compound glycinebetaine (GB), also originally referred to as betaine is a methylated glycine derivative. Among the betaines, GB is the most abundant one in plants, which is mostly produced in response to dehydration caused by different abiotic stresses like drought, salinity, and extreme temperature. Glycinebetaine helps in decreased accumulation and detoxification of ROS, thereby restoring photosynthesis and reducing oxidative stress. It takes part in stabilizing membranes and macromolecules. It is also involved in the stabilization and protection of photosynthetic components, such as ribulose-1, 5-bisphosphate carboxylase/oxygenase, photosystem II and quarternary enzyme and protein complex structures under environmental stresses. Glycinebetaine was found to perform in chaperone-induced protein disaggregation. In addition, GB can confer stress tolerance in very low concentrations, and it acts in activating defense responsive genes with stress protection. Recently, field application of GB has also shown protective effects against environmental adversities increasing crop yield and quality. In this review, we will focus on the role of GB in conferring abiotic stress tolerance and the possible ways to engineer GB biosynthesis in plants.     

Significance of betaines in the increased chlorophyll content of plants treated with seaweed extract

Seaweed extract, prepared by alkaline extraction of Ascophyllum nodosum (L.) Le Jol., applied either to the soil or to the foliage of tomato plants, produced leaves with higher chlorophyll levels than those of control plants. The effects on leaf chlorophyll content were investigated using a cucumber bioassay procedure devised for cytokinins. The seaweed extract was shown to increase the chlorophyll levels of the cucumber cotyledons, but ‘peaks’ of activity were obtained when widely different concentrations were used. The possibility that these effects were the result of betaines present in the extract was considered. Glycinebetaine, γ-aminobutyric acid betaine and δ-aminovaleric acid betaine all produced significantly enhanced chlorophyll concentrations in the cotyledons. ‘Peaks’ of activity were observed for each betaine: for glycinebetaine at 10⁻⁶ and between 10⁻⁴ and 10¹ mg 1⁻¹, for γ-aminobutyric acid betaine at 10⁻⁶, between 10⁻⁴ and 10⁻¹, and 10¹ mg 1⁻¹, and for δ-aminovaleric acid betaine between 10⁻⁵ and 10¹ mg 1⁻¹. It was concluded that the effects of enhancing chlorophyll levels produced by the seaweed extract were due, at least in part, to betaines.