Auxin stability and accumulation during in vitro shoot morphogenesis influences subsequent root induction and development in <Emphasis Type="Italic">Eucalyptus grandis</Emphasis>

Recent results showed that after 16 months in the field, micropropagated eucalyptus plants have an inferior root system to cuttings. Such differences may be due to the plant growth regulators supplied during the culture stages of standard protocols, which are targeted at optimising plantlet yields and not root quality. This study investigated such a proposal, focusing on auxins in an easy-to-root clone. Initial results showed that the auxin provided in the standard protocol (NAA for multiplication and IBA for elongation) enabled 100% rooting in auxin-free medium, where rooting was faster than on IBA-rooting media. When auxin supply was omitted from multiplication and restricted to NAA or IAA during elongation, rooting in an auxin-free medium was reduced to 68 and 31%, respectively, reflecting the stabilities of these auxins in plant tissues. Additionally, 15% of shoots from the NAA-medium and 65% from the IAA-medium produced roots with altered graviperception. GC–MS analysis of these shoots revealed a relationship between free IAA-availability and altered graviperception. This was further tested by adding the IAA-specific transport inhibitor 2,3,5-triiodobenzoic acid to rooting media with IBA, IAA or NAA, which resulted in 100, 70.9 and 20.6% rooting, respectively. At least 40% of the sampled root tips had atypical starch grain deposition and abnormal graviperception. It is proposed that, at least in this clone, while IBA and NAA can be used for in vitro root induction, IAA is necessary for development of graviresponse.     

Involvement of putrescine in the inductive rooting phase of poplar shoots raised in vitro

Micropropagated poplar shoots rooted 100% on a rooting medium (A) containing NAA, but they did not root in the absence of auxin (NA). Putrescine, but not spermidine and spermine, promoted rooting up to 42% when added to the NA medium. Cyclohexylamine (CHA), an inhibitor of spermine synthase, also promoted (up to 36%) rooting in the absence of auxin. The inhibitors of polyamine biosynthesis DFMA (α-difluoromethylarginine) and DFMO (α-difluoromethylomithine), aminoguanidine (AG) and methylglyoxal-bis-guanylhydrazone (MGBG), inhibited rooting when applied in the presence of auxin and had no effect in its absence.
The rooting inductive phase (in the presence of auxin) was determined by periodical transfer of shoots from A to NA medium, and by changes in peroxidase activity, to be 7 h. Putrescine (not spermidine and spermine) accumulated to a maximum during the inductive phase. Both putrescine and CHA promoted rooting on NA medium when applied during the first 7 h. In contrast DFMA and AG inhibited rooting during this period. The results point to the involvement of putrescine and its Δ¹-pyrroline pathway, in the inductive phase of rooting in poplar shoots.     

Promotion by phloroglucinol of adventitious root formation in micropropagated shoots of adult wild cherry (Prunus avium L.)

Micropropagated shoots of wild cherry (Prunus avium L.) produced roots in auxin-free medium. Phloroglucinol (PG) increased the proportion of shoots that rooted, while phloretic acid reduced this response in medium with or without PG, and cancelled the promotive effect of PG. Concentration of PG also significantly affected rooting in media with and without auxin. The proportion of shoots rooting in media containing auxin, or auxin plus PG, increased with the number of successive subculture, but the proportion that rooted with PG alone was unaffected by the number of subcultures. Before the shoots had become responsive to auxin, 1 mM PG was more effective than auxin in inducing root formation.     

The relationship between rooting of poplar shoots and ATPase activity of their crude microsomal vesicles

Poplar shoots raised in vitro were induced to root by a 7 h passage on an auxin (1-naphthaleneacetic acid) medium. The percentage of rooting was reduced from ± 97% to ± 47% when vanadate (200 µM) was included in the auxin medium. Introduction of vanadate in the medium without auxin after the 7 h induction on auxin medium, did not inhibit rooting but affected only the development of the roots produced. The Mg²⁺-dependent ATPase activity of the microsomal vesicles of poplar shoots was increased after 7 h induction on rooting medium and corresponded to an increase in the Vmax of the enzyme. Results from experiments using some inhibitors of the polyamine metabolism suggested that this pathway was not involved in the increase of this activity. The auxin had no effect on the in vitro ATPase activity at any concentration tested except at about 2 mM where it was inhibitory, probably due to a change in the conformation of the enzyme. The transient increase of indole-3-acetic acid during rooting induction could be responsible for the increase in the level of the enzyme. The inhibition of root formation and growth by vanadate indicates strongly that the ATPase activity may be necessary for the induction and expression of rooting.     

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     

The Effect of 2,3.5 Triiodobenzoic Acid on Caulogenesis in Callus Cultures of Tomato and Pelargonium

Stem explants from winter grown tomatoes cultured on a cytokinin, auxin-free medium, developed one or two adventitious shoots at the top end of the explant. Addition of the auxin transport inhibitor. 2,3,5-triiodobenzoic acid (TIBA) to the medium stimulated caulogenesis with loss of polarity. Callus, initiation in pelargonium and ‘geranium’ petiole explants requires both auxin and cytokinin. On transfer, after callus induction to an auxin-free medium, rhizogenesis occurs in pelargonium cultures followed by caulogenesis. Few shoots develop and unless these are removed, further caulogenesis is suppressed. Bud-like structures were formed in the callus. Subculture on auxin-free medium containing cytokinin and TIBA resulted in shoot formation from these bud-like organs. An analogy with apical dominance is suggested. In ‘geranium’ callus, shoots developed with a low frequency (c. in 2% of the cultures): caulogenesis was increased to 80% when calli were subcultured from auxin-free, cytokinin medium after green nodule formation to cytokinin-TIBA medium. Histological studies of green nodules in ‘geranium’ callus indicated a variation in morphological development within and between nodules. It is suggested that auxin synthesis may occur at some microscopic stage in morphogenesis in ‘geranium’ cultures which suppresses further caulogenesis. This may be overcome by the addition of TIBA to the medium at the appropriate stage in morphogenesis. The possible interaction of endogenous auxin in morphogenesis is discussed.     

Sequential rooting media and rooting capacity of Sequoiadendron giganteum in vitro. Peroxidase activity as a marker

The rooting capacities of tips of seedling, juvenile and mature shoots of Sequoiadendron giganteum were compared on different rooting media (inductive and expressive media) after passage on an elongating medium. None of the cuttings rooted when continuously kept on medium containing the auxin NAA and vitamin D2. Peroxidase activity of all those cuttings on NAA+D2 first increased during the 7–9 first days and decreased in the days after. Rooting was obtained by transfer of the cuttings after periods longer than 7–9 days from the NAA+D2 inductive medium to a basal medium supplemented or not with rutin (expressive medium). The rooting capacity was emphasized by rutin treatment and was in correlation with the peroxidase peak reached on the NAA+D2 medium. Seedlings, characterised by the highest peroxidase activity, were most performing in rooting.Abbreviations BM basal medium - D2 ergocalciferol - NAA naphtaleneacetic acid     

<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).     

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.     

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).     

Micropropagation of the nickel hyperaccumulator,Hybanthus floribundus (Family Violaceae)

A protocol for micropropagation of the nickel hyperaccumulator Hybanthus floribundus (Lindley) F. Muell. (Shrub Violet) is described in this paper. Healthy callus was first produced from stem and leaf explants on a medium containing half strength Murashige and Skoog medium with 5 M N ⁶-benzylaminopurine (BA) and 0.5 M -naphthaleneacetic acid (NAA). Numerous shoots (>20 shoots per callus) were also successfully grown from callus on this medium. The exposure time of shoots to auxin was critical for successful in vitro rooting. Best rooting efficiency was obtained by transferring shoots to auxin medium (100 M indole-3-butyric acid) for 24 h and then to a medium without growth regulators (about 75% of treated shoots produced healthy roots). Importantly, cloned shoots retained their ability to hyperaccumulate nickel.     

Adventitious rooting of Jatropha curcas L. is stimulated by phloroglucinol and by red LED light

An efficient root induction system has been established for in vitro-regenerated Jatropha curcas L. shoots. Callus formation on shoots transferred to auxin containing medium was found to be a prominent and recurrent problem for rooting of in vitro-cultivated J. curcas. In particular, the type of auxins and cytokinins applied in the culture media were shown to strongly influence the severity of callus formation. Shoots cultivated on meta-methoxytopolin riboside (MemTR) were free of callus and produced elongated stems and well-developed leaves in comparison to the cytokinins benzyl adenine, zeatin, and thidiazuron. Subsequent root induction experiments were performed with shoots precultured on MemTR-containing medium. Shoots were excised and transferred to Murashige and Skoog (MS) medium supplemented with different concentrations of indole-3-butyric acid (IBA), indole-3-acetic acid (IAA), and α-naphtaleneacetic acid (NAA). The induction of excessive callus formation was avoided only on IBA-containing medium. The optimum rooting medium with good root induction (35%) and 1.2 roots per shoot contained half-strength MS salts supplemented with 2.5 μM IBA. The same medium supplemented with 0.25% (w/v) activated charcoal produced 46% rooted shoots. Further improvement of rooting was obtained by transferring in vitro grown shoots to woody plant medium containing phloroglucinol (PG). In the presence of 2.5 μM IBA and 238 μM PG, 83% of the shoots rooted with on average 3.1 roots per shoot. We also analyzed the impact of light quality on the rooting capacity of Jatropha in vitro grown shoots. In general, light-emitting diodes (LEDs) light sources were less efficient for root induction. Red LED light provided the most favorable growth conditions, inducing a rooting response in 65% of the shoots, which produced on average 5.5 roots per shoot. These results indicate that adventitious rooting in J. curcas is under control of photoreceptors and that optimal rooting requires fine-tuning of the salt concentration, auxin, and cytokinin balance and application of synergistic compounds.     

In vitro culture of Safflower L. cv. Bhima: initiation,growth optimization and organogenesis

Callus induction and in vitro plantlet regeneration systems for safflower (Carthamus tinctorius L.) cv. Bhima using root, hypocotyl, cotyledon and leaf explants were optimized by studying the influence on organogenesis of seedling age, media factors, growth regulators and excision orientation. Supplementation of the medium with an auxin: cytokinin ratio < 1 enhanced the growth rate of callus cultures; however, for 2,4-D the ratio was > 1.34–11.41 μM concentrations of growth regulators (IAA, NAA, BA and Kinetin) in the medium were found effective for callus induction and regeneration in all explants. The calli could be maintained over 32 months. BA (4.43 μM) combined with casein hydrolysate (10 mg l-1) yielded the highest rate of shoot production on hypocotyl (3–6) and cotyledon (5–7) explants and cotyledonary derived callus (4–8). More shoots were produced on explants cut from the most basal region of cotyledons from 5 to 7-day-old seedlings than from older seedlings or more distal cut sites. Apolar placement of explants, inhibited shoot regeneration. The shoot regeneration potential remained upto 7 months in calli developed on NAA + BA. Of three media tested, MS was superior to SH-M and B5. Rooting of shoots was not efficient; 42% of the shoots were rooted on MS medium containing sucrose (7–8%) + IAA (2.8–5.7 μM). Capitula induction was observed in both callus mediated shoots on cotyledons and shoots on rooting medium with sucrose, IAA, NAA and IBA. Well developed plantlets were transferred to the field with a 34% success rate. This revised version was published online in June 2006 with corrections to the Cover Date.     

In vitro regeneration of <Emphasis Type="Italic">Carlina acaulis</Emphasis> subsp. <Emphasis Type="Italic">simplex</Emphasis> from seedling explants

The aim of the study was to obtain an efficient system for Carlina acaulis subsp. simplex propagation. The experimental materials were shoot tips, fragments of hipocotyls, cotyledons and roots isolated from 10-day-old seedlings. The explants were transferred to the proliferation medium supplemented with different types of cytokinin: BA (13.3 μM), kinetin (13.9 μM) and zeatin (13.7 μM) in combination with NAA (0.54 μM). The best morphogenetic response was observed when explants were cultured on the BA supplemented medium. The maximum shoot organogenesis frequency was observed for shoot tip (nearly 94%). On average 8.6 axillary shoots were induced per explant. Multiplication rate increased during the first three subcultures. The shoots revealed a wide range of morphogenetic responses. Differences were observed in the presence or absence of hair on the surface of lamina. These changes had epigenetic character and were the effect of changes in DNA methylation, which is shown by differences in methylation pattern between 18S rRNA and 25S rRNA genes in the analyzed regenerated plants. Nearly 94% of plantlets were rooted on auxin lacking medium. Addition of auxin (NAA or IAA) increased both the rooting percentage (100%) and the number of roots per shoot, but their growth was inhibited. Shortening of the auxin exposition time reduced the number of roots. Moreover, high efficiency (90%) was observed for ex vitro rooting. Plantlets with a large number of roots survived better than the ones with only a few roots. Plants were able to flower and gave viable seeds.     

A regeneration protocol for sunflower (Helianthus annuus L.) protoplasts

Summary Hypocotyl protoplasts of four different Helianthus annuus genotypes were cultivated for 22–28 days in agarose droplets covered with liquid medium. In the first week, supplementation of the medium with plant growth regulators was at a 0.8/1 ratio of cytokinin and auxin followed by a high auxin concentration in the second week and a cytokinin to auxin ratio of 8/1 in the third and fourth week. Following transfer onto solid medium containing cytokinin and auxin in a proportion of 40/1 morphogenic callus started to form globular structures that developed into leaf primordia. Subsequent shoot elongation and rooting were obtained on hormone free medium after dipping the cut shoots into high auxin solution. Thirteen weeks after protoplast isolation, plantlets could be transferred to the greenhouse. Shoot regeneration was obtained for all four cultivars (Florom-328, Cerflor, Euroflor, Frankasol) at different rates reflecting their regenerative potential.Abbreviations BAP 6-benzylaminopurine - 2,4-D 2,4-dichlorophenoxyacetic acid - FeNaEDTA ethylenediamine tetraacetic acid ferric sodium salt - IAA indole acetic acid - MES morpholinoethane sulfonic acid - NAA 1-naphtalene acetic acid     

In vitro root induction in axillary microshoots of Quercus robur L.

Whilst considerable efforts have been made to optimise shoot multiplication and rooting in oak, little attention has been paid to the impact of conditions used for multiplication on subsequent root formation. An optimised technique for rooting of oak microshoots has been developed to assess the effect of cytokinin treatments applied to shoot multiplication cultures on the subsequent rooting of microshoots. We found IBA to be more effective at inducing root formation in microshoots than NAA. Efficient rooting of oak microshoots (80%) was achieved after 35 days on medium supplemented with 1.0 mg litre^-1 IBA. Lower concentrations of IBA reduced the frequency of root formation and significantly increased the time taken for microshoots to form roots. High concentrations of IBA (3.0 mg litre^-1) produced similar rooting frequencies but with significantly increased numbers of roots formed by each microshoot. However, high concentrations of IBA stimulated the production of basal callus. Rooting of microshoots was unaffected by the concentration of BA used during shoot multiplication, although basal callusing was greater in microshoots taken from multiplication medium supplemented with the highest concentration of BA (1.0 mg litre^-1) and rooted on medium supplemented with 3.0 mg litre IBA. Reducing the period of exposure to auxin to 7 days by transferring microshoots to auxin-free medium increased the frequency of root formation (84%), led to more rapid root formation and a reduction in basal callus formation.     

Rhizogenesis and root growth ofCarica papaya L.in vitro in relation to auxin sensitive phases and use of riboflavin

High rooting percentages and high-quality adventitious root systems for papaya (Carica papaya L.) were obtainedin vitro by appropriate auxin source, duration of exposure to auxin and use of riboflavin. Root initiation of papaya shoots was higher using IBA than IAA, NAA or PCPA. Maximum rooting percentage (96%) was achieved by exposure of shoots to a medium containing 10 µM IBA for 3 days before transfer to a hormone-free medium. However, the resultant plants had small shoots and callused roots. Shoot and root growth were improved when shoots were transferred after 2 days from medium containing 10 µM IBA to hormone-free medium containing 10 µM riboflavin. Good root initiation, and root and shoot growth were also obtained when shoots were incubated for 2 days in darkness on a medium containing 10 µM IBA and 31 µM riboflavin before transfer to light. Alternatively, cultures could be placed in the light on medium containing 10 µM IBA, and after 1 day the medium overlaid with 300 µM riboflavin (1 ml over 10 ml of medium).     

Successful propagation in vitro of apple rootstock MM106 and influence of phloroglucinol.

Successful in vitro propagation of clonal apple rootstock MM106 was achieved by culturing axillary buds on MS basal medium with BAP (1 mg/L), GA3 (0.5 mg/L) and IBA (0.1 mg/L). Use of liquid medium (LM) in initial cultures reduced phenol exudation to a greater extent and gave maximum sprouting percentage when transferred to solid MS medium. Phloroglucinol (PG) did not enhance sprouting of buds but increased the rate of multiplication when added in the medium. Maximum number of shoots were obtained when MS medium was supplemented with BAP (0.5 mg/L), GA3 (1 mg/L), IBA (0.1 mg/L) and PG (100 mg/L). For rooting, in vitro regenerated shoots were placed in IBA (30 mg/L) for 3 hr and transferred to solidified auxin free medium. Rooting was recorded in about 80% of shoots. Inclusion of PG in rooting medium was not beneficial but shoot cultures grown in its presence gave higher rooting percentage. Rooted plantlets showed about 70% survival rate in potting mixture of sand:soil:perlite (1:1:1).     

In vitro rooting of cloned shoots in Pinus pinaster

In vitro plantlet regeneration will be a sueful tool in reforestation only when rooting problems are overcome. Our study was therefore focused on Pinus pinaster rooting conditions.
Methods were used which permit multiple axillary (instead of adventitious) bud production in order to obtain genetically identical explants and hence to procure more homogeneous resutls. The hormonal treatment efficiency was then tested on several clones for rooting. Different substrates were compared. A mixture of peat and perlite (1/3, v/v) permitted rooting and the further development of the root system if humidity was properly controlled. The use of an agar medium avoided this difficulty; it supported root induction but resulted in limited growth.
For hormonal treatment, explants, submitted to a 12-day-period with NAA (10⁻⁶ M ) and then subcultured in an auxin-free medium, gave rooting percentages ranging from 80 to 100%. In terms of rooting quality (intensity, growth rate and branching ability), a 15-to 19-day-period of auxin treatment was more effective.
Application of this optimal treatment to several clones revealed slight differences within clones and between clones (80 to 100% of rooting according to the clone). Regenerated plantlets were able to undergo an autotrophic growth after transplantation under greenhouse conditions.     

In vitro PPFD and media composition affect both in and ex vitro performance of Alstroemeria Butterfly-hybrids

The objective was to reduce in vitro production costs while retaining or improving plant quality, in particular the suitability for pot plant production. Plants were grown at photosynthetic photon flux densities (PPFD) of 0–40 μmol m^-2 s^-1 and sucrose concentrations of 3–7% during the multiplication phase and the effects of sucrose, BA, and NAA during root formation were investigated. Ex vitro growth were tested in both experiments. A small reduction in the rhizome multiplication rate was found with increasing PPFD and sucrose concentration. Increasing sucrose concentration reduced the number of aerial shoots. Aerial shoots were etiolated when cultured in darkness and their number increased with increasing PPFD at 3% sucrose, whereas PPFD did not affect the number of aerial shoots at 5 or 7% sucrose. During the multiplication phase a synergistic promoting effect of PPFD and sucrose was observed on root formation. Root formation after transfer to rooting medium was affected by sucrose and PPFD during the multiplication phase. PPFD did not influence root formation after propagation on 7% sucrose, whereas on 3 or 5 % sucrose root formation was gradually inhibited when PPFD was decreased below 17 μmol m^-2 s^-1. The formation of thick roots was promoted by propagation in light, and not influenced by sucrose concentration. Ex vitro growth was not affected by in vitro conditions, except for 7% sucrose during the multiplication phase that reduced flowering. Root formation on rooting medium was reduced by BA and promoted both by NAA and high levels of sucrose. The root inhibiting effect of BA could not completely be overcome by simultaneous application of NAA and high sucrose concentrations. Thick roots were only produced in the presence of NAA, and not affected by sucrose treatment. Ex vitro flowering was negatively influenced by the presence of BA during root formation and by high levels of sucrose if BA was absent in the rooting medium. High sucrose levels and NAA could partially compensate for the negative effect of BA on flowering. This revised version was published online in June 2006 with corrections to the Cover Date.