Role of ascorbic acid in auxin induced cell elongation

Summary Cytochemical detection of ascorbic acid in cultured root tips of Zea mays shows that dividing cells accumulate ascorbic acid in the cytoplasm. The localization pattern alters in the root tip as the cells begin to elongate. In elongating cells ascorbic acid is distinctly localized on cell walls. Ascorbic acid content per cell inreases with the onset of cell elongation. Fully elongated cells contain fivefold more ascorbic acid than meristematic cells. Cytophotometric analysis reveals a sharp and positive correlation (r=+0.93) between percentage increase in content of ascorbic acid per cell and corresponding increase in cell size at different phases of cell elongation. IAA treatment to the roots raises the content of ascorbic acid per cell with a parallel increase in size of cell. Involvement of ascorbic acid in IAA induced cell elongation is discussed.     

Changes in hormonal balance and meristematic activity in primary root tips on the slowly rotating clinostat and their effect on the development of the rapeseed root system

The morphometry of the root system, the meristematic activity and the level of indole-3-acetic acid (IAA), abscisic acid (ABA) and zeatin in the primary root tips of rapeseed seedlings were analyzed as functions of time on a slowly rotating clinostat (1 rpm) or in the vertical controls (1 rpm). The fresh weight of the root system was 30% higher throughout the growth period (25 days) in clinorotated seedlings. Morphometric analysis showed that the increase in biomass on the clinostat was due to greater primary root growth, earlier initiation and greater elongation of the secondary roots, which could be observed even in 5-day-old seedlings. However, after 15 days, the growth of the primary root slowed on the clinostat, whereas secondary roots still grew faster in clinorotated plants than in the controls. At this time, the secondary roots began to be initiated closer to the root tip on the clinostat than in the control. Analysis of the meristematic activity and determination of the levels in IAA, ABA and zeatin in the primary root tips demonstrated that after 5 days on the clinostat, the increased length of the primary root could be the consequence of higher meristematic activity and coincided with an increase in both IAA and ABA concentrations. After 15 days on the clinostat, a marked increase in IAA, ABA and zeatin, which probably reached supraoptimal levels, seems to cause a progressive disturbance of the meristematic cells, inducing a decrease of primary root growth between 15 and 25 days. These modifications in the hormonal balance and the perturbation of the meristematic activity on the clinostat were followed by a loss of apical dominance, which was responsible for the early initiation of secondary roots, the greater elongation of the root system and the emergence of the lateral roots near the tip of the primary root.     

Preliminary observations on organogenesis inTaraxacum officinale tissue cultures

Summary Tissue cultures ofTaraxacum officinale have been isolated from the secondary thickened root. Callus development and leaf and root formation occur on a basal medium supplemented with coconut milk and IAA or NAA, and the addition of kinetin to these media enhances callus growth and organogenesis. Cultures grown on the basal medium with coconut milk and 2,4-D show only callus growth, but organogenesis is induced by the substitution of IAA for 2,4-D. In the 2,4-D grown callus a layer of secondary meristematic tissue is present and organogenesis apparently occurs from localized regions of this tissue which have undergone de-differentiation to the primary meristematic condition.     

根域限制对葡萄根中IAA含量及其代谢相关基因表达的影响

以1年生"玫瑰香"葡萄为试验材料,进行根域限制栽培处理,以传统地栽为对照,研究根域限制对葡萄根系构型、细胞结构、IAA含量及其代谢和根系生长发育相关基因表达丰度的影响,以探讨根域限制栽培影响葡萄根系构型变化的内在机制.结果表明:(1)根域限制处理后,葡萄根系构型发生显著变化,主要表现在根尖处出现大量集群根、不定根持续发...     

Cytohistological Studies on the Tissue Culture of Olea europaea L. II. Histogenesis and Organogenesis

After the calli derived from Olea europaea stem tissue have been introduced to the subculture on the solid medium for differentiation, a periderm was partially formed from the wound cambium in the outer region of the callus. At the same time, some scattered tracheids and vascular bundles were differentiated in the inside of the callus. These vascular bundles did not form a vascular system and also had no rela- tion to the organogenesis. In addition, there were some embryonic cells induced at random from parenchymatous cells in the callus, and these embryonic cells were characterized as the meristematic cells. Two types of meristematic tissues, namely, meristematic cellular mass and meristematic nodule, were produced by different types of mitotic division respectively. The meristematic nodules formed a growth center without any differentiation, but later, they were differentiated tracheids in the inner surrounded by the cambium-like cells. With monopolarity the root primordia were produced from this type of nodules. But the adventitious buds were derived from the meristematic cellular masses. Therefore, realize that the process of differentiation and dedifferentiation all occurs in the callus tissue. The structural differences among the nodules with tracheids, and the origin of buds and root primordia are also briefly discussed.     

Aldehyde oxidase (AO) in the root nodules of Lupinus albus and Medicago truncatula: identification of AO in meristematic and infection zones

Phytohormones are involved in the organogenesis of legume root nodules. The source of the auxin indole-3-acetic acid (IAA) in nodules has not been clearly determined. We studied the enzyme aldehyde oxidase (AO; EC 1.2.3.1), that catalyzes the last step of IAA biosynthesis in plants, in the nodules of Lupinus albus and Medicago truncatula. Primordia and young lupin nodules and mature M. truncatula nodules showed AO activity bands after native polyacrylamide gel electrophoresis. Gel activity analyses using indole-3-aldehyde as substrate indicated that the nodules of white lupin and M. truncatula have the capability to synthesize IAA via the indole-3-pyruvic acid pathway. Immunolocalization and in situ hybridization experiments revealed that AO is preferentially expressed in the meristematic and the invasion zones in Medicago nodules and in the lateral meristematic zone of Lupinus nodules. High IAA immunolabeling was also detected in the meristematic and invasion zones. Low expression levels and no AO activity were detected in lupin Fix- nodules that displayed restricted growth and early senescence. We propose that local synthesis of IAA in the root nodule meristem and modulation of AO expression and activity are involved in regulation of nodule development.     

Distribution of linker histone variants during plant cell differentiation in the developmental zones of the maize root, dedifferentiation in callus culture after auxin treatment

Although several linker histone variants have been studied in both animal and plant organisms, little is known about their distribution during processes that involve alterations in chromatin function, such as differentiation, dedifferentiation and hormone treatment. In this study, we identified linker histone variants by using specific anti-histone Hl antibodies. Each variant's ratio to total Hl in the three developmental zones of maize (Zea mays L.) root and in callus cultures derived from them was estimated in order to define possible alterations either during plant cell differentiation or during their dedifferentiation. We also evaluated linker histone variants' ratios in the developmental zones of maize roots treated with auxin in order to examine the effects of exogenous applied auxin to linker histone variant distribution. Finally, immunohistochemical detection was used to identify the root tissues containing each variant and correlate them with the physiological status of the plant cells. According to the results presented in this study, linker histone variants' ratios are altered in the developmental zones of maize root, while they are similar to the meristematic zone in samples from callus cultures and to the differentiation zone in samples from roots treated with auxin. We propose that the alterations in linker histone variants' ratios are correlated with plant cell differentiation and dedifferentiation.     

Studies on induced changes in growth patterns and polarity in roots of Vicia faba L.

Summary Roots of Vicia faba were treated with colchicine (0.025%), or IAA (4.7×10^-6 M), or both, for 3 hours and fixed at various intervals over the following 11 days. The axis of spindle orientation and the distribution of mitotic figures, lateral root primordia and xylem vessel elements was examined in the apical 10 mm of median longitudinal sections of these roots.No effect of IAA was found on the orientation of the spindle. However, evidence was obtained indicating that the systems controlling the polarity of cell division and cell expansion differ in some way.The number of lateral root primordia formed was greater in roots treated with IAA or colchicine than in control roots. These primordia were always initiated adjacent to a xylem vessel. Thus, no primordium was closer to the apex than the most apical xylem vessel, suggesting that an endogenous factor involved in primordia initiation is transported in the xylem. The primordia which develop after colchicine treatment grow out as lateral roots; this is in contrast with those which form after IAA treatment and which do not undergo elongation. These results, which it must be emphasized apply only to the apical 1 cm of treated roots, indicate that lateral root primordia become sensitive to IAA at a certain stage in their development. Exogenous IAA acts as an inhibitor.The new meristem, which forms in the primary root apex after colchicine treatment, contains both diploid and polyploid cells, i.e. it was formed from cells that were unaffected and from cells that were affected by colchicine. Following colchicine treatment the size of the meristem shrinks and this can be prevented by treatment with IAA. This and other evidence presented here, suggests that IAA is a factor involved in the control of the size of the apical meristem in normal roots.     

The effect of zeatin and iso-pentenyladenine on IAA transport from the shoot to the root of Pinus pinea seedlings

The tips of the tap roots of Pinus pinea seedlings were dipped in zeatin or iso-pentenyladenine solutions. Immediately after cytokinin application to the root tip or after a 24 h lag phase, [2-¹⁴C]IAA was applied to the shoot apex. Treating with zeatin resulted in an increase in [2-¹⁴C]IAA transport from the shoot to the root. Iso-pentenyladenine also caused a slight increase in transport of radioactivity to the root but this was less pronounced compared to the results obtained with zeatin. With zeatin treatment increasing amounts of radioactivity accumulated in the lateral root emerging zone of the tap root (Section III). This was in sharp contrast to the treatment with iso-pentenyladenine where little radioactivity accumulated in this section of the root. Recovery of radioactivity 48 h after applying [2-¹⁴C]IAA showed that 33% of the recovered radioactivity co-chromatographed with authentic IAA. The implications of the effect of different cytokinins on the distribution of radioactivity along the tap root of Pinus pinea following [2-¹⁴C]IAA application to the shoot are discussed.Abbreviations Z zeatin - iP iso-pentenyladenine - TCL thin-layer chromatography     

Tubulin conformation in microtubule-free cells ofVigna sinensis

Summary The primary leaf, epicotyl, and root cells ofVigna sinensis seedlings grown continuously in a 0.08% colchicine solution, become microtubule-free and polyploid. In meristematic root cells a tubulin transformation is detected 1–3 h after the treatment had begun. Tubulin strands are organized at the positions of the pre-existing microtubules. Frequently, the strands converge on or are organized in the cortical cytoplasmic zone where in normal cells the preprophase microtubule band (PMB) is assembled. In meristematic root cells subjected to a 6–12 h colchicine treatment, the tubulin strands become perinuclear, entering the cortical cytoplasm at regions close to the nucleus. One day after the onset of the treatment, tubulin generally forms a continuous reticulum of interconnected strands in all the organs examined. In most cells this reticulum surrounds the nucleus partly or totally or lies close to it, exhibiting variable configurations in different cells. After prolonged treatments, the organization of the tubulin reticulum changes further. Now this consists of crystal-like structures interconnected by thin strands.On thin sections of fixed tissue the tubulin strands consist of paracrystalline material. The distribution of this material in the affected cells coincides with that of tubulin reticulum visualized by immunofluorescence. In transverse planes each strand exhibits circular subunits arranged close to one another in a hexagonal pattern but in longitudinal ones variable images were observed. The paracrystalline material persists in root cells subjected to an 8-day continuous colchicine treatment. The immunolabeled strands seem to be composed of tubulin-colchicine complexes and not pure tubulin.     

缺磷胁迫对小麦根细胞周期蛋白基因cyc1At表达的影响

用液培方法研究了缺磷胁迫对小麦(TriticumaestivumL.)根系生长的影响。结果表明,随着介质磷水平的提高,小麦根轴长度和植株生长素浓度均降低。在低磷条件下用生长素极性运输抑制剂三碘苯甲酸(TIBA)处理后,小麦的根轴长度明显降低,表明生长素参与了缺磷小麦根轴生长的调控。缺磷小麦根部生长素浓度的提高诱导了细胞周期蛋白基因cyclAt的表达,促进了根分生组织细胞的分裂并驱动了根的生长。     

The involvement of wheat and common bean lectins in the control of cell division in the root apical meristems of various plant species

The effects of wheat germ agglutinin (WGA) and phytohemagglutinin (PHA) at the concentration of 1 mg/l on the rate of cell division in the root apical meristem of wheat (Triticum aestivum L.), barley (Hordeum vulgare L.), rice (Oryza sativa L.), and common bean (Phaseolus vulgaris L.) seedlings were compared. WGA enhanced cell division in the roots of barley and rice approximately similarly as in wheat roots but did not affect division of meristematic cells in the roots of common bean seedlings. In contrast PGA enhanced mitotic activity in the root apical meristem of common bean seedlings but did not affect division in the wheat and barley roots. Seedling treatment with lectins shifted the hormonal balance in them toward accumulation of growth activators (IAA and cytokinins). The relationship between lectin and hormonal systems in the control of cell division is discussed.     

Influence of indole-3-acetic acid on adventitious root primordia of brittle willow

Summary Removal of the stem apex and certain leaves and axillary buds of brittle willows (Salix fragilis) was employed to limit the supply of endogenous auxin to adventitious root primordia during their formation, which occurs at predetermined sites. Limiting endogenous auxin by this surgical treatment resulted in reduced primordium initiation and, to a lesser degree, primordium growth in cell number. Root primordium cells in surgically treated plants differentiated into mature parenchyma after losing their meristematic character. Application of indole-3-acetic acid (IAA) to surgically treated plants partially overcame the effects of the surgical tretament, increasing root primordium initiation and growth by cell division. When IAA-2-¹⁴C was applied to surgically treated plants, label was detected in root primordium cells by means of autoradiography. Root primordium cells took up more label during the earliest stage of initiation than during a later stage of growth. The data indicate that the initiation of these primordia is more dependent on a supply of auxin than is their subsequent development. Further, the auxin apparently acts directly in the cells which initiate primordia.This investigation was supported in part by Public Health Service Research Grant No. UI 00110-07 (now 5R01 FD 00074-09) from the National Center for Urban and Industrial Health. Paper No. 7138, Min nesota Agricultural Experiment Station.     

The role of auxins in differentiation of rice tissues culturein Vitro

Effects of various auxins on callus induction (dedifferentiation) and organ redifferentiation from the callus were studied by using various tissues of rice,Oryza sativa L. cv. Kyoto Asahi. 2,4-D, NAA and IAA were used as auxins for the test of their ability to induce callus. All of these were active. This callus induction by auxin was successful in all tissues used; seed, root, shoot nodule, anther and ovary. In all of the calluses induced by various auxins such as 2,4-D, NAA and IAA and derived from various tissues such as seed, root, shoot nodule, anther and ovary, organ redifferentiation, i.e., formation of shoots and roots was achieved by removing the auxins from the medium used for the callus calture. Cytokinins were not necessary for the organ redifferentiation in these calluses. These results suggest that auxin is the only exogenous factor that determines dedifferentiation and redifferentiation in rice plant tissues culturedin vitro.     

Cytological study of inhibitory effects of IAA on the root growth in the Pinus silvestris

It has been found that IAA at the concentrations 0.1--10.0 ppm retards the pine root growth and decreases mitotic activity. All the applied concentrations of this hormone cause a decrease of the 3H-thymidine incorporation index and inhibit endomitotic polyploidization in suprameristematic segments. The mean time of the cell cycle prolongs and the heterogeneity of cellular populations increases in parallel with the increase of IAA concentration. The template activity of DNA decreases under the influence of the applied concentrations of IAA; this effect is being particularly strong in the meristematic root segment. IAA exerts also an inhibitory influence on protein synthesis, especially reducing the synthesis of histones.     

Residual Nuclear structures fromZea mays L.

Nuclei fromZea mays L. root tip meristematic cells were treated according to the conventional method for nuclear matrix isolation and according to a recently adapted procedure for isolation of nuclear shells from plant cells. In the first case, after high salt extraction of proteins and DNase I and RNase digestions, residual structures are obtained consisting of a periferal layer and an internal network. The obtained structures are very similar to the nuclear matrix preparations from animal cells. In case nuclei are swollen in EDTA first, digested with DNase II and RNase prior high salt treatment, structures devoid of internal network are obtained. The analogous residual structures were shown forPhaseolus vulgaris L. meristematic root cells nuclei (Galcheva-Gargovaet al. 1988). The morphology and the protein composition of the two types of residual structures suggest that the organization of scaffold structures from plant nuclei is very similar to the one from animal cell nuclei.     

Lateral Root Development in Attached and Excised Roots of Zea mays L. Cultivated in the Presence or Absence of Indol-3-yl Acetic Acid

The initiation of lateral root primordia and their subsequentemergence as secondary roots have been examined in attachedand excised roots of Zea mays grown in the presence or absenceof indol-3-yl acetic acid (IAA). Exposure to IAA enhanced anlageinception in both batches of roots. In the attached roots, theIAA-induced stimulation of primordium initiation was followedby a similar increase in lateral emergence. IAA treatment, however,had no effect on the number of laterals produced, per centimetreof root, in the excised primaries. Thus, exposure to IAA didnot directly enhance lateral emergence in the attached rootsnor did it stimulate such emergence in the excised ones. Nocorrelation was found between proliferative activity in themeristem at the apex of the primary or the rate of root elongationon the one hand, and either the number of primordia initiated,or the number of laterals produced, per centimetre of primary,on the other. Zea mays, maize, root, primordium, lateral, indol-3-yl acetic acid, meristematic activity     

Influence of Cycloheximide and Actinomycin D on Initiation and Early Development of Adventitious Roots

From leaf cuttings of the bean Phaseolus vulgaris L. adventitious roots form on the petiole. This root formation is stimulated by treatment with auxin. Simultaneous or subsequent application of cycloheximide irreversibly inhibited dedifferentiation, so that root production was completely prevented. The effects of actinomycin D application depended upon the stage of development of the root primordium. Cells in the first stage of dedifferentiation were extremely sensitive. When actinomycin D was applied later than 6 h after cutting, its inhibiting effect gradually diminished. It is concluded that an actinomycin D-sensitive process occurring early in dedifferentiation is crucial for root initiation. A second, less actinomycin D-sensitive process occurring later in dedifferentiation is required for the further development of the root primordium. During the initiation and development of the root primordium protein synthesis is required.     

Changes in mitotic indices in roots of Vicia faba

Roots of Vicia faba were treated with solutions of colchicine or IAA or both. Mitotic indices and the frequencies of the different stages of mitosis were determined immediately after a three hour treatment or following a 24 hour period of recovery. Roots scored after treatment with colchicine for three hours showed several effects, none of which were reversed by simultaneous treatment with IAA. Treatment with IAA for three hours had little detectable effect on mitotic index (MI) on the frequencies of the various stages of mitosis. After a recovery period, following a three hour treatment, of 24 hours, colchicine treated roots showed a significant increase in their MI; this was due largely to an increase in the number of metaphases but it was also due in part to the presence of tetraploid cells in division. IAA treated roots revealed an inhibition of mitotic activity, which was most marked at 3.13–6.26×10^–4 M IAA. The results from roots treated with mixtures of colchicine and IAA for three hours and fixed 24 hours later showed: 1) the increase in MI induced by colchicine is reversed by IAA, the intensity of the reversal increasing with increasing concentrations of IAA; 2) reductions in the total numbers of cells in prophase or in metaphase occur after treatment with different concentrations of IAA; 3) IAA leads to a reduction in the number of tetraploid cells seen in division.It appears that colchicine induces a change in the pattern of mitotic activity 24 hours after the end of treatment and its effects are reversed by IAA. At 4.2×10^–4 M IAA a balance occurs between the opposing effects of colchicine and IAA and the MI is not significantly different from that of the controls. It is suggested that one result of a treatment with colchicine is a change in the level of growth factors in root meristems. This change, which appears to result in a temporary increase in MI is reversed by the addition of IAA. Thus one of the growth factors, the level of which has been affected, is replaceable by exogenous IAA.     

Expression in different populations of cells of the root meristem is controlled by different domains of the rolB promoter

Selective gene expression in different populations of cells of the root apex of transgenic tobacco could be evidenced by means of GUS constructs with deletions of the rolB promoter and fusions with the CaMV 35S minimal promoter. Five regulatory regions have been broadly identified in the rolB 5 non-coding region. The presence of all five domains (A to E) directs gene expression in the root cap, in the protoderm and in the different tissues within the root meristematic region: the dermatocalyptrogen, the cortex and the vascular cylinder. Deletion of domain A (–623 to –471) selectively suppresses expression in non-meristematic cells, i.e. the root cap and the protoderm. Deletion of either domain B (–341 to –306) or E (80 bp around the TATA box) causes loss of expression in all cells of the root apex: constructs C+D+E, B+C+D, B+C are inactive. Domain D (70 bp around the CAAT box) is necessary for gene expression in the dermatogen and in meristematic cells of the cortex but not in the innermost meristematic layer: construct B+C+E is active only in vascular meristematic cells. Domain C (–216 to –158) seems to have a double regulatory role as construct B+E is no longer expressed in meristematic cells of the vascular cylinder but is very active in the protoderm. Constructs allowing gene expression in meristematic cells are also inducible by auxin in leaf protoplasts, while activation of the regulatory elements necessary for gene expression in the non-meristematic cells of the root apex do not seem to depend upon the hormone. The connection between auxin induction and meristematic expression is discussed.