Relative Contribution of Apices and Mature Tissues to ABA Synthesis in Droughted Maize Root Systems

We investigated whether different parts of maize root systemscould contribute to ABA synthesis, and whether a previous cycleof soil dehydration-rehydration would modify the ability ofroots to synthesize ABA. Maize (Zea mays L.) root tissues, i.e.mature primary root sections, young and unbranched primary rootsections, secondary roots and primary root tips, from both wellwatered plants and previously drought-rewatered plants, weresubjected to different degrees of dehydration and their ABAconcentration changes were assayed. All categories of rootsfrom always well watered plants, including mature tissues containingno apex, could synthesize ABA when dehydrated. Mature primaryroot sections and their previously associated secondary rootsaccumulated less ABA in response to dehydration than the youngprimary roots and primary root tips did, and their ABA accumulationwas not substantial until dehydration was below 65% of relativewater content (RWC). Previous soil dehydration-rehydration cyclessubstantially reduced ABA accumulation in these roots in responseto dehydration again. Young primary root sections and primaryroot tips accumulated ABA much more sensitively in responseto dehydration than mature root sections, although considerablevariations existed among different batches of young primaryroot sections. Results are discussed in the context of the relativecontribution of different categories of roots to ABA synthesiswhen the root system is in drying soil. We concluded that primaryroot apices should not contribute by more than 2% to the totalABA synthesis by the root system. (Received December 15, 1995; Accepted April 19, 1996)     

Accumulation rate of ABA in detached maize roots correlates with root water potential regardless of age and branching order

How much ABA can be supplied by the roots is a key issue for modelling the ABA-mediated influence of drought on shoot physiology. We quantified accumulation rates of ABA ( S _ABA) in maize roots that were detached from well-watered plants and dehydrated to various extents by air-drying. S _ABA was estimated from changes in ABA content in root segments incubated at constant relative water content (RWC). Categories of root segments, differing in age and branching order, were compared (root branches, and nodal roots subdivided into root tips, subapical unbranched sections, and mature sections). All categories of roots accumulated ABA, including turgid and mature tissues containing no apex. S _ABA measured in turgid roots changed with root age and among root categories. This variability was largely accounted for by differences in water content among different categories of turgid roots. The response of S _ABA to changes in root water potential ( Ψ _root) induced by dehydration was common to root tips, nodal roots and branches of several ages, while this was not the case if root dehydration was expressed in terms of RWC. Differences among root categories in the response of S _ABA to RWC were due to different RWC values among categories at a given Ψ _root, and not to differences in the response of S _ABA to Ψ _root.     

Electrophysiological responses of maize roots to low water potentials: relationship to growth and ABA accumulation

The maintenance of root elongation is an important adaptive response to low water potentials (psi(w)), but little is known about its regulation. An important component may be changes in root cell electrophysiology, which both signal and maintain growth maintenance processes. As a first test of this hypothesis, membrane potentials (E(m)) were measured within the cell elongation zone of maize (Zea mays L.) primary roots. Seedlings were grown in oxygenated solution culture, and low psi(w) was imposed by the gradual addition of polyethylene glycol. Cells hyperpolarized approximately 25 mV in response to low psi(w), and after 48 h resting potentials remained significantly hyperpolarized at psi(w) lower than -0.3 MPa compared with roots at high psi(w). Inhibitor experiments showed that the hyperpolarization was dependent on plasma membrane H(+)-ATPase activity. Previous work showed that accumulation of abscisic acid (ABA) is required for the maintenance of maize primary root elongation at low psi(w). To determine if the mechanism of action of ABA involves changes in root electrophysiology, E(m) measurements were made during long-term exposure to low psi(w). Steady-state resting E(m) were measured in regions in which maintenance of cell elongation was dependent on ABA accumulation (2-3 mm from the apex), or in which elongation was inhibited regardless of ABA status (6-8 mm from the apex). E(m) was substantially more negative in ABA-deficient roots specifically in the 2-3 mm region. The results suggest that set-points for ion homeostasis shifted in association with the maintenance of root cell elongation at low psi(w), and that ABA accumulation plays a role in regulating the ion transport processes involved in this response.     

Early responses of maize seedlings to Cu stress include sharp decreases in gibberellins and jasmonates in the root apex

Copper (Cu) interferes with numerous biological functions in plants, including plant growth, which is partly governed by plant hormones. In the present study, Cu stress effect on the roots of pre-emerging maize seedlings in terms of growth, nutrient composition, protein modifications, and root hormone homeostasis was investigated, focusing on possible metabolic differences between the root apex and the rest of the root tissues. Significant decreases in root length and root biomass after 72 h of Cu exposure (50 and 100 μM CuCl₂), accompanied by reductions in Ca, Mg, and P root contents, were found. Cu also generated cell redox imbalance in both root tissues and revealed by altered enzymatic and non-enzymatic antioxidant defenses. Oxidative stress was evidenced by an increased protein carbonylation level in both tissues. Copper also induced protein ubiquitylation and SUMOylation and affected 20S proteasome peptidase activities in both tissues. Drastic reductions in ABA, IAA, JA (both free and conjugated), GA3, and GA4 levels in the root apex were detected under Cu stress. Our results show that Cu exposure generated oxidative damage and altered root hormonal homeostasis, mainly at the root apex, leading to a strong root growth inhibition. Severe protein post-translational modifications upon Cu exposure occurred in both tissues, suggesting that even when hormonal adjustments to cope with Cu stress occurred mainly at the root apex, the entire root is compromised in the protein turnover that seems to be necessary to trigger and/or to sustain defense mechanisms against Cu toxicity.

     

The contribution of different regions of the seminal roots of wheat to uptake of nitrate from soil

A technique was developed to determine the physiological activity of defined sections of seminal roots of wheat grown in sand. Wheat plants were grown for 2 weeks in narrow columns of N-deficient sand to which all other nutrients had been added. The columns were split longitudinally and ¹⁵N-labelled nitrate, in an agar medium, supplied to 2 cm sections of root. Shoots and roots were analysed after 24 h to determine the uptake of ¹⁵N. Three sections were examined on either the secondary or tertiary seminal root: 1 cm from the seed (basal segment), 35 cm from the seed (middle segment) and 4 cm from the root apex (apical segment). Total uptake was greatest from the basal and middle segments, declining by 50% from the apical segment. However, uptake per unit root length, including exposed sections of lateral roots, was not significantly different along the root.     

Aluminium distribution in soybean root tip for a short time Al treatment

Using the lumogallion staining method which we developed (Kataoka et al. 1997a), Al movement in soybean (Glycine max. (L.)Merr. cv. Tsurunoko) root tips treated for a short time was studied. We have indicated that the majority of Al accumulated in the root was found between 0 and 2 mm from the root apex within 2 h (Kataoka et al. 1997a, b). In the study presented here two-day seedlings of the soybean were treated with 50 μmol/L AlCl₃ (pH 4.4), including 0.2 mmol/L CaCl₂, for 1 h, and Al accumulation in the root sections at both 1 and 2 mm apart from root apex was analyzed by a confocal laser microscopy. Although the early indicators, callose induction and the decrease of growth recovery, were not observed in the root when treated for 15 min, a trace amount of Al was already incorporated into the nucleus of cells and the middle tissue of the root. The non-toxic level of Al was more rapidly absorbed than previously thought. The initial increase of callose accumulation and the reduction of the growth recovery were found after 30 min. Therefore, the difference between Al accumulation profiles of 15 and 30 min was analyzed to find out what triggered a toxic Al effect. Increase of Al accumulation in whole root tissue was observed in the root sections, at both 1 and 2 mm from the root apex, and the greatest amount of Al was found in the cytoplasm of the outer cortex, 1 mm away from the root apex. These results are consistent with the fact that Al exclusion from root tip cells is an important mechanism of Al tolerance.     

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.     

Gas chromatography-mass spectrometric determinations of abscisic acid levels in the cap and the apex of maize roots

Quantitative analyses of abscisic acid (ABA) in different parts of maize root tips (Zea mays L. cv. Kelvedon 33) were performed by mass fragmentography using the hexadeuterated analog of ABA as internal standard. It was found that the cap and the apex contained 36.1 g and 66.5 g ABA kg^–1 fresh weight, respectively. The possibility that the growth regulator formed in the cap and inhibiting the elongation of the extending zone of the root is ABA is discussed.Abbreviations ABA abscisic acid - ABA-D₆ hexadeuterated ABA - ABA-Me and ABA-D₆-Me methyl esters of ABA and ABA-D₆, respectively - GC-MS gas chromatograph(y)-mass spectrometry/spectrometer - IAA indol-3-yl-acetic acid - MF mass fragmentography - TMS trimethylsilyl     

Arrest of somatic embryo development in grapevine: histological characterization and the effect of ABA,BAP and zeatin in stimulating plantlet development

In an effort to understand the causes of arrest of somatic embryo development, generally observed in grapevine (Vitis sp.), histological studies were undertaken, using two cultivars (CH76 and 41B) which differ in their ability to develop into plants. Embryos with a high conversion rate (70%; CH76) formed a well-structured and functional shoot apex between two thread-like cotyledons. In contrast, embryos with a low conversion rate (10%; 41B) formed a normal root apex but lacked a well-structured shoot apex and developed a wide range of aberrant forms in the intercotyledonary area: uncontrolled cellular proliferation, formation of adventitious buds, over-growth of cotyledonary or leaf meristems. ABA increased the conversion rate of 41B embryos from 10% to 20%, but failed to improve embryo morphology. Zeatin and BAP promoted growth of 41B somatic embryos, but generated a high level of abnormalities and failed to improve conversion rate. Applied in combination with ABA, these PGRs increased the frequency of cotyledonary embryos, but decreased the conversion rate.     

Root Growth Maintenance at Low Water Potentials (Increased Activity of Xyloglucan Endotransglycosylase and Its Possible Regulation by Abscisic Acid)

Previous work suggested that an increase in cell wall-loosening contributes to the maintenance of maize (Zea mays L.) primary root elongation at low water potentials ([psi]w). It was also shown that root elongation at low [psi]w requires increased levels of abscisic acid (ABA). In this study we investigated the effects of low [psi]w and ABA status on xyloglucan endotransglycosylase (XET) activity in the root elongation zone. XET is believed to contribute to wall-loosening by reversibly cleaving xyloglucan molecules that tether cellulose microfibrils. The activity of XET per unit fresh weight in the apical 10 mm (encompassing the elongation zone) was constant at high [psi]w but increased by more than 2-fold at a [psi]w of -1.6 MPa. Treatment with fluridone to decrease ABA accumulation greatly delayed the increase in activity at low [psi]w. This effect was largely overcome when internal ABA levels were restored by exogenous application. Spatial distribution studies showed that XET activity was increased in the apical 6 mm at low [psi]w whether expressed per unit fresh weight, total soluble protein, or cell wall dry weight, corresponding to the region of continued elongation. Treatment with fluridone progressively inhibited the increase in activity with distance from the apex, correlating with the pattern of inhibition of elongation. Added ABA partly restored activity at all positions. The increase in XET activity at low [psi]w was due to maintenance of the rate of deposition of activity despite decreased deposition of wall material. The loss of activity associated with decreased ABA was due to inhibition of the deposition of activity. The results demonstrate that increased XET activity is associated with maintenance of root elongation at low [psi]w and that this response requires increased ABA.     

Root apical meristems ofAllium porrum L. as affected by arbuscular mycorrhizae and phosphorus

Summary Arbuscular mycorrhizal (AM) fungi significantly improve plant growth in soils with low phosphorus availability and cause many changes in root morphology, similar to those produced by increased P nutrition, mainly depending on root apex size and activity. The aim of this work was to discriminate between the morphogenetic role of AM fungi and P in leek (Allium porrum L.) by feeding mycorrhizal and nonmycorrhizal plants with two nutrient solutions containing 3.2 or 96 M P and examining specific parameters related to adventitious root apices (apex size, mitotic cycle, and RNA synthesis). The results showed that AM fungi blocked meristem activity as indicated by the higher percentages of inactive apices and metaphases in the apical meristem of mycorrhizal plants, whereas the high P supply lengthened the mitotic cycle without blocking the apices, resulting in steady, slow root growth. The possible involvement of abscisic acid in the regulation of root apex activity is discussed.Abbreviations ABA abscisic acid - AM arbuscular mycorrhizae - CI and CII nonmycorrhizal control plants grown with low or high phosphorus concentration - MI and MII mycorrhizal plants grown with low or high phosphorus concentration - PGR plant growth regulator     

The Induction of Root Dormancy in Picea sitchensis (Bong.) Carr. by Abscisic Acid

Abscisic acid at 10⁴ M inhibited elongation and induced dormancyin roots of Sitka spruce cuttings growing in solution culture.The dormancy was characterized by superficial browning whichprogressed towards the root tip and by the development of alayer of lignified and suberized cells around the root apex.The dormant roots remained alive and resumed growth on transferto ABA-free solutions. The induction of dormancy was confinedto those roots actually bathed in the ABA solution and a rangeof conditions which affected shoot activity did not alter theresponse. By contrast, the time for which the roots had beenelongating strongly influenced root dormancy since it was notinduced in roots which had recently begun to elongate in solutionculture. The possible role of ABA in inducing root dormancyunder adverse conditions is discussed.     

Analysis of DNA methylation during spontaneous rooting from the stem apex in <Emphasis Type="Italic">Rubus idaeus</Emphasis>

Rubus idaeus L. is of great economic value. Some varieties of Rubus idaeus have a unique feature of spontaneous rooting from the stem apex. To determine whether DNA methylation is associated with the spontaneous rooting process, variations in the methylation at stem apex during four root developmental stages were investigated, using the methylation-sensitive amplification polymorphism (MSAP) technique and the bisulfite sequencing analysis (BSA). The results showed that the DNA methylation levels and patterns were significantly different between the four developmental stages. A total of 824 CCGG amplified sites were detected by MSAP. MSAP screening revealed that the level of DNA methylation at stages I to IV was 34.95, 36.04, 36.29, and 37.50%, respectively. The number of methylated sites and their methylation levels tended to decrease at stages III and IV (root differentiation and elongation) compared with those at stage I (stem elongation). After cloning and sequencing of the 16 polymorphic differentially methylated DNA fragments, BLAST search results indicated that they might be involved in differentiation of the lateral root primordium, plant defense, signal transduction, and energy metabolism. Results of the qRT-PCR and BSA analyses confirmed that methylation of some key genes was closely associated with their expression at the different developmental stages. These findings could be useful for future studies on the potential role of DNA methylation in spontaneous rooting from the stem apex, implying its importance in rooting regulation and rapid expansion of raspberry populations.     

Cell-wall pectin and its degree of methylation in the maize root-apex: significance for genotypic differences in aluminium resistance

Cell-wall (CW) pectin content and its degree of methylation in root apices of selected maize cultivars were studied in relation to genotypic Al resistance. Maize cultivars differing in Al resistance were grown in nutrient solution treated with or without Al, and pectin content of the root tips was determined. Control plants did not differ in pectin content in the 5 mm root apex. Al treatment increased the pectin content of the root apex in all cultivars but more prominently in the Al-sensitive cultivars. Pectin and Al contents in 1 mm root sections decreased from the apex to the 3–4 mm zone. Pectin contents of the apical root sections were consistently higher although significantly different only in the 1–2 mm zone in the Al-sensitive cv Lixis. Al contents in most root sections were significantly higher in cv Lixis than in Al-resistant cv ATP-Y. Localization of pectins by immunofluorescence revealed that Al-sensitive cv. Lixis has a higher proportion of low-methylated pectin and thus a higher negativity of the cell wall than Al-resistant cv ATP-Y. This is in agreement with the higher Al content and Al sensitivity of cv Lixis. It is concluded that differences in CW pectin and its degree of methylation contribute to genotypic differences in Al resistance in maize in addition to the release of organic acid anions previously reported.     

Some Cytological Changes accompanying the Regeneration of Meristematic Activity at the Apex of Decapitated Roots of Vicia faba L.

The changes that took place in mitotic index (MI), labellingindex (LI) and the relative proportions of interphase nucleiwith different amounts of DNA have been investigated duringthe regeneration of meristematic activity at the apex of rootsof Vicia faba over the 144 h period following removal of thecap and apical mm of the meristem. Measurements were also madeof the corresponding changes that took place as cells were displacedbasally along the root from the apex over the experimental period.In both parts of the root, MI and the relative proportions ofnuclei with different DNA contents changed from levels similarto those at the apex of the controls at the start and end ofthe experiment to levels resembling those found in more matureparts of the root at 24 and 48 h. In contrast to these results,LI declined over the experimental period. These cytologicalchanges were aresult of the development of lateral root primordiain both the apical 2 mm of the decapitated roots and as cellswere displaced out of the meristem into more basal parts ofthe root. It was concluded that the events leading to the regenerationof meristematic activity at the apex of roots from which thecap and apical mm of the meristem were removed, are no differentfrom those which result in lateral formation as cells are displacedbasally along the primary root from the apex, and they takeplace over the same time interval in both systems.     

Epstein-Barr Virus Infection in Chronically Inflamed Periapical Granulomas

Periapical granulomas are lesions around the apex of a tooth caused by a polymicrobial infection. Treatment with antibacterial agents is normally performed to eliminate bacteria from root canals; however, loss of the supporting alveolar bone is typically observed, and tooth extraction is often selected if root canal treatment does not work well. Therefore, bacteria and other microorganisms could be involved in this disease. To understand the pathogenesis of periapical granulomas more precisely, we focused on the association with Epstein-Barr virus (EBV) using surgically removed periapical granulomas (n = 32). EBV DNA was detected in 25 of 32 periapical granulomas (78.1%) by real-time PCR, and the median number of EBV DNA copies was approximately 8,688.01/μg total DNA. In contrast, EBV DNA was not detected in healthy gingival tissues (n = 10); the difference was statistically significant according to the Mann-Whitney U test (p = 0.0001). Paraffin sections were also analyzed by in situ hybridization to detect EBV-encoded small RNA (EBER)-expressing cells. EBER was detected in the cytoplasm and nuclei of B cells and plasma cells in six of nine periapical granulomas, but not in healthy gingival tissues. In addition, immunohistochemical analysis for latent membrane protein 1 (LMP-1) of EBV using serial tissue sections showed that LMP-1-expressing cells were localized to the same areas as EBER-expressing cells. These data suggest that B cells and plasma cells in inflamed granulomas are a major source of EBV infection, and that EBV could play a pivotal role in controlling immune cell responses in periapical granulomas.     

玉米赤霉烯酮在冬小麦短日春化中的作用

应用酶联免疫技术,研究了冬小麦品种燕大１８１７ 在不同光周期条件下,体内内源玉米赤霉烯酮（ＺＥＮ） 和ＡＢＡ 含量的变化。结果表明,冬小麦品种燕大１８１７ 具有短日春化性,苗期经４ 周ＳＤ 处理后转到ＬＤ 下能正常抽穗。ＳＤ 诱导春化的幼苗茎尖和叶片中ＺＥＮ 含量高于未经诱导的ＬＤ 幼苗,而在两种光周期条件下生长的幼苗中ＡＢＡ 含量变化趋势并无明显差异。马拉硫磷（ ＭＡＬ） 抑制ＳＤ 幼苗体内ＺＥＮ 含量高峰的出现,也部分抑制抽穗;外源ＺＥＮ 可部分抵消ＭＡＬ对植株的影响,降低茎尖内源ＡＢＡ 含量,并有促进小麦拔节的作用。说明在冬小麦短日春化过程中,ＺＥＮ 具有促进作用,而ＡＢＡ 没有直接影响。     

Morphological and physiological changes in roots of various wheat genotypes as related to cytoskeleton disruption

A depolymerizing effect of anti-microtubule drug oryzalin on the roots of three winter wheat (Triticum aestivum L.) cultivars contrasting in their frost-resistance was studied. The influence of plant cold acclimation (3°C, 7 days) and ABA treatment (30 μM) on oryzalin action was evaluated. Plant growing in the presence of 10 μM oryzalin under optimum temperature of 23°C resulted in the root-length decrease by 19–24% and root-apex swelling. All cells, especially in the root cortex, changed their radial dimensions. The cells acquired a rounded or irregular shape and increased in size. This indicates the loss of correct cell growth polarity. Most pronounced changes in the root apex diameter and most severe linear growth suppression were observed in the cultivar of moderate frost-resistance. The roots of this cultivar contained the highest amounts of actin and tubulins, as was evident from the immunoblot analysis. The effect of oryzalin on root growth and apex swelling was correlated with the content of actin in the roots of different wheat cultivars. Cold acclimation and exogenous ABA reduced (or prevented) oryzalin action on roots in a cultivar-specific manner. The conclusion was made that the bulk of the cytoskeletal net determined the efficiency of the cytoskeletal control of plant growth and morphogenesis. During autumn and winter periods, this is important for a better adaptation to temperature fluctuations of moderately frost-resistant plants, which are characterized by a high ecological plasticity.     

Abscissic acid localization by light microscopic immunohistochemistry in Chenopodium polyspermum L. Effect of water stress

An indirect immunohistochemical technique was developed using a rabbit anti-abscissic acid (ABA) serum and the soluble peroxidase-antiperoxidase (PAP) complex for the localization of endogenous ABA in the aerial parts of Chenopodium. Terminal bud, axillary bud bearing nodes, and adult leaves were prefixed by a soluble carbodiimide to obtain the coupling of ABA on cellular proteins and postfixed by a conventional mixture of aldehydes. They were then embedded in paraffin or in plastic. Numerous controls were carried out on sections and on a model system to test the validity of the technique. Based on the staining patterns observed along the plant, an apico-basal gradient of ABA was revealed. In the older buds, ABA was mainly concentrated in the quiescent meristematic cells of the apex. Phloem cells of the main axis and chloroplasts of the leaves were specifically labeled. No reaction product was visualized in the parenchyma cells or in the cambial zone. Water stress, which is known to increase ABA content, induced an increase of immunoreactivity within the same compartments. This physiological test validates the stain.