Effect of applied and endogenous indol-3-yl-acetic acid on maize root growth

The level of endogenous Indol-3-yl-acetic acid (IAA) measured by gas chromatography-mass spectrometry in the elongating zone of intact primary roots of Zea mays showed a good linear correlation with the growth rate of these roots. When they were treated with IAA, their relative elongation decreased; this indicates a supraoptimal content of endogenous IAA. However, the growth of some of the relatively rapidly extending roots was enhanced by such treatment. Interactions between endogenous and applied IAA in the control of root growth are discussed.Abbreviations GC-MS gas chromatography-mass spectrometry - IAA Indol-3-yl-acetic acid     

Water stress and indol-3yl-acetic acid content of maize roots

Water-stress conditions were applied to the apical 12 mm of intact or excised roots ofZea mays L. (cv. LG 11) using mannitol solutions (0 to 0.66 M) and changes in weight, water content, growth and IAA level of these roots were investigated. With increasing stress a decrease in growth, correlated with an increased IAA level, was observed. The largest increase in IAA (about 2.7-fold) was found in the apical 5 mm of the root and was obtained under a stress corresponding to an osmotic potential of −1.39 MPa in the solution. This stress led to an isotonic state in the cells after 1 h. When the duration of water stress (−1.09 MPa) was increased to 2 or 3 h, no further increase in the IAA content was observed in the root segments. This indicated that there was no correlation between a hypothetical passive penetration of mannitol in the cells and IAA content. Indol-3yl-acetic acid rose to the same level in excised as in intact roots. In both cases, IAA accumulation was apparently independent of the hydrolysis of the conjugated form. The caryopsis and shoot seem not to be necessary to induce the increase of the IAA level in the roots during water stress (−1.09 MPa). Therefore, there seems to be a high rate of IAA biosynthesis in excised maize roots under water-stress conditions. Exodiffusion of IAA was observed during an immersion in either buffer or stress (−1.09 MPa) solution. In both cases, this IAA efflux into the medium represented about 50% of the endogenous level. Considering the present results, IAA appears to play an important part in the regulation of maize root metabolism and growth under water deficiency.     

Applied indol-3yl-acetic acid on the cap and auxin movements in gravireacting maize roots

The graviresponsiveness of intact and primary maize roots kept horizontally in darkness and humid air is analysed. A precise local application of IAA is possible when using resin beads (diameter: 0.45 +/- 0.05 mm) loaded with IAA. The beads are placed on the upper or lower sides of the caps. They significantly change the root gravireaction. The effect of IAA is discussed in terms of its possible level in the growing and gravibending zones and its transport (acropetal, lateral and basipetal) respectively in the stele, the cap and the cortex of the elongating root.     

Saturable uptake of indol-3yl-acetic Acid by maize roots

The uptake of 5-[³H]indol-3yl-acetic acid (IAA^*) by segments of Zea mays L. roots was measured in the presence of nonradioactive indol-3yl-acetic acid (IAA°) at different concentrations. IAA uptake was found to have a nonsaturable component and a saturable part with (at pH 5.0) an apparent K_m of 0.285 micromolar and apparent V_max 55.0 picomoles per gram fresh mass per minute. These results are consistent with those which might be expected for a saturable carrier capable of regulating IAA levels. High performance liquid chromatography analyses showed that very little metabolism of IAA^* took place during 4 minute uptake experiments. Whereas nonsaturable uptake was similar for all 2 millimeter long segments prepared within the 2 to 10 millimeter region, saturable uptake was greatest for the 2 to 4 millimeter region. High levels of uptake by stelar (as compared with cortical) segments are partly attributable to the saturable carrier, and also to a high level of uptake by nonsaturable processes. The carrier may play an essential role in controlling IAA levels in maize roots, especially the accumulation of IAA in the apical region. The increase in saturable uptake toward the root tip may also contribute to the acropetal polarity of auxin transport.     

Quantification of indol-3-yl acetic acid in pea and maize seedlings by gas chromatography-mass spectrometry

A procedure is described for the identification and quantification of IAA in plant tissues by GC/MS analysis of the N-heptafluorobutyryl ethyl ester of IAA using [²H₅]IAA as an internal standard. The detection limit is ca 3 pmol IAA/tissue sample. By using this method, IAA levels of 30–90 pmol/g fr. wt were obtained for dark-grown Pisum sativum epicotyls and 71–199 pmol/g fr. wt for dark-grown Zea mays seedlings. When either methanol or ethanol was used as extraction solvent, some esterification of IAA during sample preparation was observed. No evidence for the natural occurrence of methyl or ethyl esters of IAA in Pisum sativum seedlings was found.     

Temperature depression while aerating moist soils and the resultant effect on maize seedling growth

Summary Moist soil surfaces were aerated with air at relative humidities from 4 to 100%, flowing at rates from 0.07 to 3.5 liters per min. Evaporation occurred and resulted in measureable depressions of soil temperature when the aerating air was less than 100% saturated with water vapor and flowing at rates above 0.1 liter per min. Growth of young maize seedlings was markedly affected by depressed soil temperatures when the aerating air was at 30% relative humidity and flowing at 3.0 liters per min. Growth was affected even though the soil containers were submerged in constant temperature water baths to help maintain the uniformity of soil temperature. In containers similar to those used in this study, plant growth would be affected by aerating soils with air that is less than saturated with water vapor and is flowing at rates as low as 0.5 to 1.0 liter per min. On the other hand, plant growth would probably not be affected when aerated even with very dry air flowing at rates below about 0.1 liter per min.     

Phytotoxic effects of fumonisin B1 on maize seedling growth

Fumonisin B₁ toxin is produced by the fungusFusarium moniliforme Sheldon, which is systemic to maize (Zea mays L.) and maize seeds. The effects of zero to 100 parts per million fumonisin B₁ on the germination process of maize seeds was determined. The presence of fumonisin had no effect on percent seed germination, but fumonisin inhibited radicle elongation by up to 75% after 48 hours of imbibition. An analysis of amylase secretion in the maize endosperm indicated that fumonisins inhibited amylase production in the germinating seed. Isoelectric focusing of endosperm extracts indicated that secretion of the low pI class of amylases was affected more that other amylase isozymes. The results suggested that the presence of high levels of fumonisin in maize seed may have deleterious effects on seedling emergence.     

Rhizospheric Enterobacter enhanced maize seedling health and growth

Phyto-beneficial effects of rhizobacteria specifically Enterobacter species were evaluated on maize seedling health and growth. Out of the 19 isolates examined, two were remarkable in their phosphate solubilization efficiency (PSE > 70%), chitinase enzyme activity (CEA > 85%) and antifungal activity with evidence of no or low disease expression in maize seedling. The selected isolates (OSR7 and IGGR11) were identified and 16S rDNA revealed both isolates as Enterobacter species. Re-evaluation of both isolates ascertains that their combined effects are more effective on maize seedling than their individual effects. Their combinations completely suppressed pathogenic activity of Fusarium verticillioides on maize seedling with evidence of no disease symptoms. Other treatments significantly (p < 0.05) expressed varied maize seedling diseases such as leaf curl and stem rot. Apart from treatment T2 (maize + pathogen), other treatments most especially their combinations significantly (p < 0.05) enhanced seedling height, stem girth, leaf area, nitrogen and potassium contents. The phyto-beneficial effects of these Enterobacter species suggest that they could be employed as bio-inoculant for maize seedling health and growth.     

水杨酸对盐胁迫下黄瓜幼苗生长抑制的缓解效应

研究了水杨酸对盐胁迫下黄瓜幼苗生长抑制的缓解效应及其机制。结果证明,盐胁迫条件下水杨酸能提高幼苗相对含水量,降低Na^ 、K^ 向上运输的选择性,通过促进子叶内超氧化物歧化酶、过氧化物酶活性降低膜脂过氧化产物丙二醛含量和质膜透性,缓解了盐胁迫对幼苗生长的抑制。     

Indole-3-acetic acid and 2-(indol-3-ylmethyl)indol-3-yl acetic acid in the thermophilic archaebacterium Sulfolobus acidocaldarius.

Indole-3-acetic acid (IAA) and 2-(indol-3-ylmethyl)indol-3-yl acetic acid were identified in lipid extracts of Sulfolobus acidocaldarius; they occurred at concentrations of 0.57 and 0.59 mumol/g (dry weight), respectively. The amount of IAA found in these cells is more than a thousand times greater than that found in a typical extract of a plant in which IAA serves as a plant growth hormone. Neither of these compounds was detected in the other archaebacteria that were analyzed; these included Sulfolobus sulfataricus, Halobacterium salinarium, and several strains of methanogenic bacteria. This is the first report of the natural occurrence of 2-(indol-3-ylmethyl)indol-3-yl acetic acid.     

Non-Decarboxylating transformation of indol-3-ylacetic acid in apple seeds

An enzyme extract from apple(Pyrus malus Borb.) seeds which causes the disappearance of free indol-3-ylacetic acid (IAA) requires the presence of oxygen, but is not inhibited by cyanide. Using 1-¹⁴C-IAA it has been demonstrated that the IAA transformation is not accompanied by its decarboxylation. Decarboxylating IAA oxidase is absent during the whole period of apple seed cold stratification. Free IAA has not been detected in dormant apple seeds and in seeds stratified at low temperature. It appears during stratification at 25 °C. Ethyl ester of IAA and indol-3-ylacetyl aspartate have been identified in dormant and after-ripened seeds. Exogenous 1-¹⁴C IAA taken up by apple embryos is converted into conjugates with aspartate and short peptides containing an aspartate moiety.     

Tissue zinc distribution in maize seedling roots and its action on growth

Zinc (Zn) distribution over tissues and organs of maize (Zea mays L.) seedlings and its action on root growth, cell division, and cell elongation were studied. Two-day-old seedlings were incubated in the 0.25-strength Hoagland solution containing 2 or 475 μM Zn(NO₃)₂. Zn toxicity was assessed after the inhibition of primary root increment during the first and second days of incubation. The content of Zn was determined by atomic absorption spectrometry in the apical (the first centimeter from the root tip) and basal (the third centimeter from the kernel) root parts. Zn distribution in various tissues was studied by histochemical methods, using a metallochromic indicator zincon and fluorescent indicator Zinpyr-1 and light and confocal scanning fluorescent light microscopy, respectively. To evaluate Zn effects on growth processes, the average length of the meristem; the length of fully elongated cells; the number of meristematic cells in the cortex row; and duration of the cell cycle were measured. When the Zn concentration in the solution was high, the Zn content per weight unit was higher in the basal root part due to its accumulation in lateral root primordial. Zn was also accumulated in both the meristem apoplast and cell protoplasts. In the basal and middle root parts, Zn was detected essentially in all tissues predominantly in the apoplast. Zn inhibited both cell division and elongation. Under Zn influence, the size of the meristem and the number of meristematic cells decreased, which was determined by an increase in the cell cycle duration. The length of the fully elongated cells was also reduced. A comparison of Zn distribution and growth-suppressing activity with other heavy metals studied earlier allows a conclusion that toxic action of heavy metals is mainly determined by physical and chemical properties of their ions and specific patterns of their transport and distribution. As a result, two basic processes determining root growth, e.g., cell division and elongation, could be affected differently.     

The effect of sodium fluoride on cereal seed germination and seedling growth

Abstract. Fluoride has been shown to inhibit germination and seedling establishment in barley cv. Natasha, wheat cv. Axona and rice cv. Ishikari. The concentrations of fluoride were selected so as to give a satisfactory dose-response relationship and also to relate to levels of fluoride present under natural conditions. Concentrations used were zero, 0.5, 1.0, 10 and 40 mol m⁻³ sodium fluoride. In germination studies, barley was found to be least tolerant and rice most tolerant of fluoride. The inhibition was found to be a response to fluoride itself and the observed effects were not due to pH, sodium or an unspecific effect of halide ion. Phosphate, applied at two concentration levels, was unable to overcome the inhibition. Fluoride was also shown to inhibit seedling growth. The inhibitory effects of fluoride may be accounted for by a wide range of metabolic effects including inhibition of gibberellic acid–triggered alpha amylase activity during germination, and later on to inhibition of chlorophyll synthesis in the developing leaves.     

The effect of Drechslera teres seed infection on spring barley seedling growth

Barley seedlings (cv. Beatrice) emerging from seed infected with Drechslera teres were sorted into healthy seedlings, those with leaf sheath lesions and those with leaf blade lesions. Leaf area, plant height and total weight were reduced relative to healthy plants; leaf emergence also appeared to be delayed.     

骆驼蓬提取物对豌豆幼苗生长的影响

用不同浓度的骆驼蓬提取物处理豌豆种子,明显导致幼苗根系活力及叶绿素和叶片可溶性蛋白质含量下降,膜透性增加。分析表明,骆驼蓬提取物处理下幼苗叶片膜脂过氧化作用增强;过氧化物酶(POD)活性提高;而超氧化物歧化酶(SOD)和过氧化氢酶(CAT)活性降低。     

Chemical ionization mass spectrometry of indol-3yl-acetic acid and cis-abscisic acid: Evaluation of negative ion detection and quantification of cis-abscisic acid in growing maize roots

Mass spectra of the derivatives of indol-3yl-acetic acid and cis-abscisic acid were obtained in electron impact and chemical ionization positive ion and negative ion modes. The respective merits of methane, isobutane, and ammonia as reagent gases for structure determination and sensitive detection were compared using the methyl esters. From one to 10 fluorine atoms were attached to IAA to improve the electron-capturing properties of the molecule. The best qualitative information was obtained when using positive ion chemical ionization with methane. However, the most sensitive detection, with at least two ions per molecule, was achieved by electron impact on the IAA-HFB-ME derivative and by negative ion chemical ionization with NH₃ on the ABA-methyl ester derivative. p ]Quantitative analyses of ABA in different parts of maize (Zea mays cv. LG 11) root tips were performed by the latter technique. It was found that the cap and apex contained less ABA than the physiologically older parts of the root such as the elongation zone and the more differentiated tissues. This technique was also used to show a relation between maize root growth and the endogenous ABA level of the elongation zone and root tip: there is more ABA in the slowly growing roots than in the rapidly growing ones.     

The effect of nutrients on seedling growth of native and introduced Phragmites australis

Differing responses to abiotic stresses and increased nutrient availability may play a role in the invasion and spread of introduced Phragmites australis Cav. (Trin.) ex. Steud. and the decline of native P.a. americanus Saltonstall, P.M. Peterson & Soreng in North America. We present results from an outdoor experiment where native and introduced P. australis seedlings were grown under two nutrient treatments. Both subspecies responded positively to increased nutrients but introduced plants clearly outperformed natives, growing taller, producing more stems, and had three to four times higher biomass. The biomass of introduced P. australis growing in low nutrients was similar to that of the native in high nutrients. Aboveground:belowground biomass ratios were nearly 1.25 for both native and introduced plants across treatments and reflect the high investment P. australis seedlings place on shoot production in their first year of growth. Our results also demonstrate that introduced P. australis can have explosive growth over a single growing season, even when established from seed. This implies that management of young, newly established populations may be prudent where introduced P. australis is considered undesirable, irregardless of whether eutrophication is an issue.