Restart of Lignification in Micropropagated Walnut Shoots Coincides with Rooting Induction

The lignin content of walnut shoots did not change during in vitro shoot multiplication. Lignin content started to increase as soon as shoots were passed to a rooting medium with auxin. Exogenous auxin (applied for rooting) caused a transient elevation of the endogenous free indoleacetic acid (IAA) content with a simultaneous decrease of peroxidase activity. These events typically marked the completion of the rooting inductive phase (before any visible histological event, that is before the cell divisions beginning the rooting initiation phase). This meant that either the given exogenous auxin or the endogenous IAA has served as signal for the stimulation of lignification. Continued increase of lignification in the shoots required completion of root formation; this increase indeed was slown down when root emergence did not occur. It was further shown that lignification varied conversely to the content of the soluble phenol content, itself apparently being related to the activity of phenylalanine ammonia-lyase activity. This revised version was published online in July 2006 with corrections to the Cover Date.     

Changes in auxin protectors and IAA oxidases during the rooting of chestnut shoots in vitro

Auxin protectors and IAA oxidase activity were comparatively analyzed in the upper and the lower parts of shoots of chestnut ( Castanea sativa Mill.) cultivated in vitro with indolebutyric acid (IBA) pretreatment. Rhizogenesis of the shoots is accompanied by an increase in auxin protectors in the lower parts and by a decrease of these protectors in the upper parts. Besides, the IAA oxidase activity declines in the basal parts during the rooting process while it increases in the upper ones. These biochemical events would enhance the IAA level in the rooting region of the shoots. In untreated, non-rooted cuttings, the IAA oxidase activity remains low in the upper parts and high in the basal parts of the shoots. The results thus indicate that the IBA treatment may control the endogenous auxin level of the cuttings, either through a direct regulation of the IAA oxidase system or more indirectly through the transport of auxin protectors.     

Adventitious root formation 'in vitro' in apple rootstocks (Malus pumila) II. Uptake and distribution of indol-3yl-acetic acid during the auxin-sensitive phase in M.9 and M.26

During the auxin-sensitive phase of root initiation, rates of 3-indolyl- [2-¹⁴C] acetic acid (IAA) uptake into the 1 cm bases of shoots of the apple rootstock M.9 ( Malus pumila Mill.) 'in vitro' were not significantly affected by the presence of 10⁻³ M phloroglucinol (PG) using either liquid or agar-solidified media. The use of a liquid medium did however reduce rates of uptake over a 10-day period of auxin application. The distribution of labelled IAA between the 1-cm base and the shoot remainder was not affected by PG.
Exposure of shoots of the difficult-to-root M.9 and the easy-to-root M.26, to 2.8 × 10⁻⁵ M IAA containing [2-¹⁴C] IAA revealed no positive correlation between the amount of label taken up by the 1-cm base and rooting performance. M.9 bases absorbed almost twice as much label as M.26 after 9 days but had produced only one-third as many roots. Measurements of label distribution between the 1-cm base and the shoot remainder showed that less than 10% of the label moved to the shoot remainder over a 6-day period of auxin application. Dose-response curves of IAA and rooting over the range 1 × 10⁻⁵ M and 3 × 10⁻³ M showed that root number in M.9 was at an optimum at 1 × 10⁻³ M IAA after 6 days whilst M.26 required only 1 × 10⁻⁴ M for a similar response. These data support the hypothesis that differences in rooting of the two rootstocks reflect differences in the endogenous metabolism of exogenous IAA and not differences in its rates of uptake or distribution in the shoots.     

Changes in peroxidase activity,auxin level and ethylene production during root formation by poplar shoots raised in vitro

Shoots of poplar (Populus tremula × P. tremuloïdes) were multiplied in vitro and rooted on a rooting medium in the presence of NAA. No rooting occurred in the absence of exogenous auxin. A peak of soluble peroxidase activity, which corresponded to a decrease in the free IAA level in the shoots, preceded rooting These events were considered as corresponding to the initiative phase of rooting. They are preceded by a peak in free IAA activity which might initiate the inductive phase of the rooting process. A burst of ethylene production was measured in both rooting and non-rooting shoots, but the ethylene peak from rooting shoots appeared earlier and was higher. The use of ACC indicated that the exogenous auxin might have enhanced ACC-synthetase activity.Abbreviations ACC 1-aminocyclopropane-1-carboxylic acid - NAA naphthaleneacetic acid - IAA indole-3-acetic acid - 2-iP 2-isopentenyladenine - IAAsp indole-3-acetylaspartic acid - IBA indole-3-butyric acid - GC gas-chromatography     

Quantitation of endogenous levels of IAA,IAAsp and IBA in micro-propagated shoots of hybrid chestnut pre-treated with IBA

Endogenous levels of indole-3-acetic acid (IAA), indole-3-acetylaspartic acid (IAAsp) and indole-3-butyric acid (IBA) were measured during the first 8 d of in vitro rooting of rootstock from the chestnut ‘M3’ hybrid by high performance liquid chromatography (HPLC). Rooting was induced either by dipping the basal ends of the shoots into a 4.92-mM IBA solution for 1 min or by sub-culturing the shoots on solid rooting medium supplemented with 14.8-μM IBA for 5 d. For root development, the induced shoots were transferred to auxin-free solid medium. Auxins were measured in the apical and basal parts of the shoots by means of HPLC. Endogenous levels of IAA and IAAsp were found to be greater in IBA-treated shoots than in control shoots. In extracts of the basal parts of the shoots, the concentration of free IAA showed a significant peak 2 d after either root inductive method and a subsequent gradual decrease for the remainder of the time course. The concentration of IAAsp peaked at day 6 in extracts of the basal parts of shoots induced with 14.8-μM IBA for 5 d, whereas shoots induced by dipping showed an initial increase until day 2 and then remained stable. In extracts from basal shoot portions induced by dipping, IBA concentration showed a transient peak at day 1 and a plateau between day 2 and 4, in contrast to the profile of shoots induced on auxin-containing medium, which showed a significant reduction between 4 and 6 d after transferred to auxin-free medium. All quantified auxins remained at a relatively low level, virtually constant, in extracts from apical shoot portions, as well as in extracts from control non-rooting shoots. In conclusion, the natural auxin IAA is the signal responsible for root induction, although it is driven by exogenous IBA independently of the adding conditions.     

Influence of root restriction and ethylene exposure on apicaldominance of petunia (Petunia xhybrida Hort. Vilm.-Andr.)

Reducing rooting volume restricted root growth during theproduction of Petunia x hybrida'Orchid and resulted in an unfavorable increase in apicaldominance. Exposing young petunia seedlings to ethylene counteracted theeffects of root restriction. Rooting volumes of 9, 28, 58, or 160mL restricted the development of lateral shoots, therebyincreasing apical dominance compared to plants grown in 162 mLrooting volumes. Ethephon, an ethylene-producing compound, increased thedevelopment of lateral shoots of seedlings grown in rooting volumes rangingfrom 28 mL to 160 mL. At a rooting volume of 9mL, ethylene exposure was not capable of reducing the growth ofthe main shoot; apical dominance remained strong in both the control andethephon-treated plants. Because lateral shoot development was not restrictedby rooting volumes greater than 160 mL, exposing these plants toethylene did not result in supplementary lateral shoot development. Levels ofindole-3-acetic acid (IAA), isopentenyladenosine (iPA), and zeatin riboside(ZR) decreased on a whole shoot basis as rooting volume decreased from 162 to58 mL. Indoleacetic acid levels in ethephon-exposed plantsdecreased 20% compared to the control. The cytokinins iPA and ZR showedno response to ethylene exposure; however, the ratio of auxin/cytokinindecreased 24% compared to the control. The decrease in theauxin/cytokinin ratio was associated with an increase in the number and lengthof lateral shoots.     

Exposure of Petunia Seedlings to Ethylene Decreased Apical Dominance by Reducing the Ratio of Auxin to Cytokinin

Seedlings of Petunia x hybrida ‘Orchid’ treated with the ethylene-releasing compound ethephon at 0.9, 1.7, and 3.5 mM evolved ethylene at a higher rate as the concentration of ethephon increased. Regardless of the concentration of ethephon applied, ethylene evolution peaked 6 to 8 h following application. Evidence that ethephon application decreased apical dominance included an increase in the number of new nodes on the main stem and a sustained increase in the length of new and existing lateral shoots compared to the control (no ethephon). Plants treated with 3.5 mM ethephon developed mild chlorosis, whereas a concentration of 1.7 mM ethephon decreased apical dominance without phytotoxic effects. The auxin/cytokinin ratio decreased in the apical shoot section as early as 1 h after ethephon treatment. In contrast, a decrease in the ratio in the subapical shoot section was not detected until 24 h after ethephon application. Reduction in auxin/cytokinin ratio was a result of a decrease in indole-3-acetic acid (IAA) and an increase of zeatin riboside (ZR), but not isopentenyladenosine (iPA). These results suggest that exposing ‘Orchid’ petunia seedlings to ethylene via ethephon lowers the auxin/cytokinin ratio, thereby promoting the outgrowth of lateral shoots.     

Mutual interaction of auxin and cytokinins in regulating correlative dominance

Correlative dominance requires correlative signals from a dominant to a dominated organ. Auxins, particularly IAA, and cytokinins are obviously important components of this correlative system. Using a vegetative pea shoot and a generative apple and tomato fruit system it can be demonstrated that dominant organs always export more IAA and have a higher ³H-IAA transport capacity and velocity compared to dominated organs. In both systems the dominant organ can be replaced by the application of auxin, e.g. NAA, which maintains the differences in IAA export. This is an indication that similar regulatory mechanisms control dominance in both of these diverse systems. The possibility of replacing a dominant organ by auxin also makes it unlikely that growth of that organ or allocation of nutrients regulates the correlative inhibition of the dominated organ.It is suggested that differences in IAA export from, and transport capacities of, dominant and dominated shoots, may be explained by a mechanism of auxin transport autoinhibition (ATA), whereby the earlier and stronger export of IAA from the dominant shoot inhibits auxin export from the dominated shoot at the point where the two auxin streams converge. This hypothesis was tested with explants of pea, apple and tomato. It was shown that the basal application of cold IAA significantly reduced endogenous as well as exogenous IAA transport through these explants.Since the reduced IAA transport of dominated organs was not followed by an accumulation of IAA in the auxin producing subtending organ, it was concluded that IAA biosynthesis was possibly reduced and/or IAA conjugation stimulated. This could have been one of the determinants of their growth inhibition. ATA might also explain how the unidirectional IAA signal may affect the growth rate of organs even lateral or acropetal to its transport pathway and thus polar IAA-transport becomes a ``multidirectional' signal. From the experiments demonstrated it seems that ATA is a sufficient mechanism to impose growth inhibition in the dominated organ, without the need of other regulators.However, to release dominated organs from dominance cessation of ATA may not be sufficient and cytokinins are obviously a powerful antagonist to auxins. Their repeated exogenous application turns dominated lateral buds into strongly growing organs which ultimately may even dominate the previously dominant apex. These lateral shoots finally gain a strong IAA export capacity and inhibit, by ATA, IAA export from the hitherto dominant apex.In other experiments it was shown that interruption of polar IAA transport leads to a strong increase in root derived cytokinins. This can largely be prevented, in a concentration dependent manner, by the application of auxin, indicating that basipolar auxin may control cytokinin production in the roots and its possible delivery to lateral buds. In turn, the increased delivery of cytokinins to the lateral buds promotes a strong increase in IAA production and export. Thus there is a strong mutual interaction between auxin production in the shoots and cytokinin production in the roots, which may be important in regulating the balance between root and shoot growth.     

<Emphasis Type="Italic">In vitro</Emphasis> micropropagation of endangered <Emphasis Type="Italic"> Rhododendron ponticum</Emphasis> L. subsp. <Emphasis Type="Italic">baeticum</Emphasis> (Boissier &; Reuter) Handel-Mazzetti

In vitro propagation of Rhododendron ponticum L. subsp. baeticum, an endangered species present in limited and vulnerable populations as a Tertiary relict in the southern Iberian Peninsula, was attained. Several cytokinin:IAA ratios and a range of zeatin concentrations were evaluated for their effect on shoot multiplication from apical shoots and nodal segments. The type of cytokinin and the origin of the explant were the most important factors affecting shoot multiplication. The highest shoot multiplication rate was obtained from single-nodal explants on medium supplemented with zeatin. Increasing zeatin concentration promotes shoot multiplication independently of explant type, although this effect tends to decrease with higher zeatin concentration. Shoot growth was higher in apical shoots and it was not stimulated by the presence of auxin. A number of experiments were conducted to identify suitable procedures for rooting of in vitro produced shoots. The best results in terms of in vitro rooting were obtained with Andersons modified medium with macrosalts reduced to one-half, regardless of the auxin or its concentration in the medium. Although rooting frequency rose to 97% by basal immersion of shoots in auxin concentrated solution followed by in vitro culture on an auxin-free medium, the survival of the plants after 6 months of acclimatization was poor (50%). Best results (100% rooting and survival) were observed for ex vitro rooting. The micropropagated plants from this study were successfully reintroduced into their natural habitat (87% of survival after 8 months).     

The effect of decapitation on the levels of IAA and ABA in the lateral buds of Betula pendula roth

The level of IAA and ABA in lateral buds of birch shoots 24 h and 5 days after the decapitation of the apical bud was determined. Twenty four hours after decapitation, when visible signs of outgrowth of lateral buds were not observed yet, an increase in the level of IAA and a decrease of ABA, as compared with the buds of non-decapitated shoots, was found. Five days later, when lateral buds were in the period of intensive outgrowth, a decrease in the levels of IAA and ABA was observed. It has been suggested that removing the source of auxin, by the decapitation of the apical bud makes possible the lateral buds to undertake the synthesis of their own auxin. It could lead to the decrease in the content of ABA. These all events could create suitable conditions for the outgrowth of lateral shoots.     

Red Light-Regulated Growth : I. Changes in the Abundance of Indoleacetic Acid and a 22-Kilodalton Auxin-Binding Protein in the Maize Mesocotyl

We examined the changes in the levels of indoleacetic acid (IAA), IAA esters, and a 22-kilodalton subunit auxin-binding protein (ABP1) in apical mesocotyl tissue of maize (Zea mays L.) during continuous red light (R) irradiation. These changes were compared with the kinetics of R-induced growth inhibition in the same tissue. Upon the onset of continuous irradiation, growth decreased in a continuous manner following a brief lag period. The decrease in growth continued for 5 hours, then remained constant at 25% of the dark rate. The abundance of ABP1 and the level of free IAA both decreased in the mesocotyl. Only the kinetics of the decrease in IAA within the apical mesocotyl correlated with the initial change in growth, although growth continued to decrease even after IAA content reached its final level, 50% of the dark control. This decrease in IAA within the mesocotyl probably occurs primarily by a change in its transport within the shoot since auxin applied as a pulse moved basipetally in R-irradiated tissue at the same rate but with half the area as dark control tissue. In situ localization of auxin in etiolated maize shoots revealed that R-irradiated shoots contained less auxin in the epidermis than the dark controls. Irradiated mesocotyl grew 50% less than the dark controls even when incubated in an optimal level of auxin. However, irradiated and dark tissue contained essentially the same amount of radioactivity after incubation in [¹⁴C]IAA indicating that the light treatment does not affect the uptake into the tissue through the cut end, although it is possible that a small subset of cells within the mesocotyl is affected. These observations support the hypothesis that R causes a decrease in the level of auxin in epidermal cells of the mesocotyl, consequently constraining the growth of the entire mesocotyl.     

Distribution of indole-3-acetic acid in Petunia hybrida shoot tip cuttings and relationship between auxin transport, carbohydrate metabolism and adventitious root formation

To determine the contribution of polar auxin transport (PAT) to auxin accumulation and to adventitious root (AR) formation in the stem base of Petunia hybrida shoot tip cuttings, the level of indole-3-acetic acid (IAA) was monitored in non-treated cuttings and cuttings treated with the auxin transport blocker naphthylphthalamic acid (NPA) and was complemented with precise anatomical studies. The temporal course of carbohydrates, amino acids and activities of controlling enzymes was also investigated. Analysis of initial spatial IAA distribution in the cuttings revealed that approximately 40 and 10 % of the total IAA pool was present in the leaves and the stem base as rooting zone, respectively. A negative correlation existed between leaf size and IAA concentration. After excision of cuttings, IAA showed an early increase in the stem base with two peaks at 2 and 24 h post excision and, thereafter, a decline to low levels. This was mirrored by the expression pattern of the auxin-responsive GH3 gene. NPA treatment completely suppressed the 24-h peak of IAA and severely inhibited root formation. It also reduced activities of cell wall and vacuolar invertases in the early phase of AR formation and inhibited the rise of activities of glucose-6-phosphate dehydrogenase and phosphofructokinase during later stages. We propose a model in which spontaneous AR formation in Petunia cuttings is dependent on PAT and on the resulting 24-h peak of IAA in the rooting zone, where it induces early cellular events and also stimulates sink establishment. Subsequent root development stimulates glycolysis and the pentose phosphate pathway.     

Effect of genotype on rooting of hypocotyls and in vitro-produced shoots of Pinus radiata

Significant genotypic variation at both the family and clone-within-family levels was seen for hypocotyl rooting and the rooting of adventitious shoots produced in vitro for Pinus radiata D. Don. High rooting frequencies for hypocotyls were obtained in the absence of exogenous auxin; auxin greatly stimulated the rooting of adventitious shoots. No correlation was seen between the rooting of hypocotyls and shoots; families whose hypocotyls rooted at high frequencies did not necessarily produce shoots that rooted at high frequency. No correlation was seen between adventitious shoot production and subsequent rooting at either the family or clone level. The lack of a negative correlation indicated that selecting families or clones for high levels of shoot production will not automatically select for low rooting ability, obviating a possible bottleneck for commercial propagation of Pinus radiata. Significant family by replication interaction suggests that rooting protocols could be optimized through manipulations of the rooting environment for each family.     

The effect of etiolation and shading of stock plants on rhizogenesis in stem cuttings of <Emphasis Type="Italic">Cotinus coggygria</Emphasis>

In order to improve vegetative propagation of a difficult to root Cotinus coggygria the stock plants were subjected to: etiolation, shading and spraying with IBA, combined with the application of two commercially available rooting powders. The IBA treatment was more suitable for rooting of C. coggygria cuttings than the NAA application and it enhanced rhizogenesis regardless of the form of auxin application (foliar application to a stock plant or a rooting powder used directly on cuttings) and the amount of light provided to stock plants. Etiolation did not improve rhizogenesis in stem cuttings, however, reduction of light intensity by 50% and 96% of the ambient prior to harvest of cuttings affected rooting positively. Positive effects of shading can be ascribed to changes in shoot anatomy, i.e. a weaker sclerenchyma development. Synergistic effect of shading and foliar auxin application can result from the increase in leaf blade area and/or thinner lower epiderm. Enhanced rooting in cuttings from shoots grown out under reduced light intensity was accompanied by decrease in the contents of total soluble sugars, soluble proteins and free ABA and by increase in total chlorophyll, free amino acids, polyphenolic acids and free IAA contents.     

杨树试管苗嫩茎生根过程中内源IAA的免疫金银定位

生长素类物质在木本植物生根过程中发挥重要作用。杨树生根与生长素的关系及生根过程中内源激素的变化已有大量报道, 而生根过程中生长素的组织定位分析则尚未见报道。该文应用免疫化学分析方法对741杨(Populus alba × (P. davidiana × P. simonii) × P. tomentosa)嫩茎生根过程中内源IAA在组织中的分布进行了研究。结果显示, 741杨的嫩茎在无外源激素的1/2MS培养基上诱导10天后可生根, 14天后生根率达100%。诱导前, 嫩茎基部组织中几乎没有IAA信号; 诱导8天后, 嫩茎基部维管组织中有大量的IAA积累, 而且中部的维管组织中也有明显的IAA信号(主要分布在韧皮部和维管形成层); 10天后, 形成不定根原基, 此时IAA主要分布在根原基; 12天后, 根原基分化成不定根并突破表皮, IAA在不定根中的分布主要集中在根尖和中柱。该文对741杨的嫩茎生根过程中IAA的组织分布特点及运输途径进行了讨论。     

Does Auxin Play a Role in the Release of Apical Dominance by Shoot Inversion in Ipomoea nil?

According to the auxin-inhibition hypothesis of apical dominance,apically produced auxin moves down the stem and inhibits axillarybud outgrowth, either directly or indirectly. This hypothesishas been examined further by monitoring changes in basipetalauxin transport and endogenous auxin concentration in Ipomoeanil caused by shoot inversion, a stimulus that releases apicaldominance. The results indicate that inversion reduces auxintransport in the main stem. In upright shoots of intact plants,a 16-h pretreatment with [³H]IAA 4 cm below the apex resultsin downward movement of label and accumulation in nodes, especiallythe cotyledonary node. Label does not accumulate in the lateralbuds. GC-MS determinations of endogenous free auxin level inthe fourth node, where a lateral bud grows out following inversionof the upper part of the shoot, show no changes at 3 and 8 hafter inversion, the range of times for inversion-induced budrelease, or at 24 h, when bud outgrowth is continuing. However,inversion did cause a just-detectable decrease (approx. 10%)in the IAA level of the shoot's elongation region. Althoughauxin transport in segments of the main stem is partially inhibitedby inversion over a period shorter than the latent time of budrelease, thus providing a means for the expected depletion ofauxin in the fourth node, no depletion could be detected there.These results suggest that either a decrease in IAA level inthe main stem is not causal of bud release or that the decreasedIAA pool responsible for bud release is compartmented and cannotbe measured in whole-tissue extracts.Copyright 1993, 1999 AcademicPress Apical dominance, auxin content, auxin transport, axillary bud release, GC-MS, Ipomoea nil, Pharbitis nil, shoot inversion     

The Relationship between Flower Abortion and Endogenous Auxin Content of Rose Shoots

The amount of endogenous growth substances in stem, flowers and leaves of rose plants grown under different temperature and light conditions has been determined. It appeared to be two main growth promoting factors in the acidic fraction of the ether extract. One of them is assumed to be an auxin, probably indol-3yl-acetic acid (IAA); the other is not identified. The level of auxin was much higher in extracts from shoots grown at high temperature than in shoots grown at low temperature. Increasing light intensity also seemed to increase the auxin content of the shoots. Shoots which developed after a high cut back of the rose stem had a higher auxin content than shoots which developed after a low cut back. These findings are discussed in relation to the effect of temperature, light intensity and cut back practise on blind shoot formation in roses. The result of these investigations strongly indicate that abortion in roses is promoted by a low auxin level in the shoots.     

Effects of phenolic compounds on adventitious root formation and oxidative decarboxylation of applied indoleacetic acid in <Emphasis Type="Italic">Malus</Emphasis> ‘Jork 9’

Stem slices (1-mm thick) cut from apple microshoots were cultured on a modified Murashige-Skoog medium with indole-3-acetic acid (IAA) or α-naphthaleneacetic acid (NAA), and increasing concentrations of various phenolic compounds. Both auxins were added at a concentration suboptimal for rooting. Indole-3-acetic acid is metabolized through oxidation and conjugation but NAA through conjugation only; which might have affected the results. With IAA, all tested orthodiphenols, paradiphenols and triphenols promoted adventitious root formation from the stem slices. Ferulic acid (FA, a methylated orthodiphenol) had the largest effect and increased the number of adventitious roots from 0.9 to 5.8. With NAA there was little or no promotion after addition of phenolics. Phloroglucinol (a triphenol) and FA were examined in detail. Their effects on the dose–response curve of IAA and the timing of their action indicated that both acted as antioxidants protecting IAA from decarboxylation and the tissue from oxidative stress. Experiments with carboxyl-labelled IAA showed that IAA was massively decarboxylated by the slices and that decarboxylation was strongly reduced by phenolics. Decarboxylation was to a great extent attributable to the wound response and did not occur to such an extent in non-wounded plant tissues. In shoots, FA promoted little rooting. Slices were cultured on top of the medium and shoots were stuck into the medium. Possibly, the anaerobic conditions in the medium near the basal part of the stem of shoots reduced the wound response and consequently decarboxylation of IAA. The monophenolic compound salicylic acid (SA) promoted IAA decarboxylation. Accordingly, SA reduced rooting when added during the initial days of the rooting process (the period during which auxin enhances rooting), and promoted outgrowth of root primordia later on (the period during which auxin inhibits rooting).     

Levels of endogenous indole-3-acetic acid and indole-3-acetyl-aspartic acid during adventitious rooting in avocado microcuttings

Quantification of endogenous IAA and lAAsp was carried out duringadventitious root formation in avocado microcuttings. Both auxinand conjugate were monitored in control cuttings (rooted inthe absence of auxin) as well as in cuttings treated with arooting promotor (IBA) or an auxin transport inhibitor (TIBA).Additionally, a histological study to follow root differentiationwas carried out. In control cuttings IAA levels remained constantthroughout the rooting process, however, in IB A-treated cuttingsIAA levels increased 2-fold during the first 6 d. Addition of200 µM TIBA induced a slight decrease of IAA levels andinhibited root formation. As for IAAsp levels, both control and IBA-treated cuttings showeda big increase before root differentiation occurred and as theprocess went on, a progressive decrease took place. However,in TIBA-treated cuttings IAAsp levels not only did not increasebut diminished progressively during the process. The role ofauxin conjugates during the rooting process of avocado is discussed. Key words: Avocado, IAA, IAAsp, rooting     

Relations between auxin and cytokinin contents and in vitro rooting of tree Peony (Paeonia suffruticosa Andr.)

In this work, a combined HPLC-ELISA technique was used to associate in vitro rooting capacity of tree peony micro-cuttings with contents of cytokinin and auxin; the cytokinin mainly detected corresponded to the N⁶-benzyladenine which had been added to the multiplication medium. Rooting capacity of explants was favoured by a preliminary accumulation of endogenous IAA only when levels of the BA absorbed from the multiplication medium had decreased. Main shoots coming from a 5-weeks subculture fulfilled these hormonal conditions and were the best microcuttings for rooting (87% rooting). Main shoots coming from shorter cycles or axillary shoots coming from a 5-weeks cycle always contained high benzyladenine levels and had a low rooting capacity (25–55% rooting). Root induction was associated with an early peak of indole-3-acetic acid followed by a 10-fold lower peak of endogenous ribofuranosyl-isopentenyladenine. Only a low and transitory accumulation of isopentenyladenine occurred during root development, and this could explain the lack of shoot development. Root development was efficient, especially in a medium containing activated charcoal, which led to an almost 3-fold decrease of IAA contents in roots.Abbreviations AC activated charcoal - BA N⁶-benzyladenine - ELISA enzyme linked immunosorbent assay - HPLC high performance liquid chromatography - IAA indole-3-acetic acid - IBA indole-3-butyric acid - iP N⁶-(²-isopentenyl)adenine - RDM root development medium - RIM root induction medium - 9RIP 9--d-ribofuranosyl-iP - 9RZ 9--d ribofuranosyl-zeatin - Z zeatin