Investigations on the growth and metabolism of cultured explants of Daucus carota

Summary The responses of carrot explants to various growth-promoting agents and to certain trace elements with which they interact have been investigated. A great range in the metabolic behavior of the tissue may be brought about in this way. The responses to the exogenously applied substances are described in terms of the growth of the carrot explants in fresh weight and number of cells and also in terms of their metabolism, as shown by the final content and composition of the non-protein N compounds, by the relations between protein and non-protein (alcohol-soluble) N and by the content of nucleic acid in the cultured tissue.The growth-promoting agents employed consisted of (1) the balanced complex of factors found in coconut milk, (2) an active isolate from Aesculus (AF_aesc), which is one of a class of growth factors (AF₁) that interact with inositol (AF₁+inositol) and which in this sense comprise growth-promoting System I, (3) the substance zeatin (Zeat) which is typical of a class of active factors (AF₂) that interact with indoleacetic acid (AF₂+IAA) and which, therefore, function as a growth promoting complex termed System II in the culture of carrot tissue.The carrot explants stimulated by coconut milk grew better than those stimulated by the other combinations of growth factors and they converted their soluble N more effectively to protein. The growth, whether it was induced by coconut milk or by System I or II, and other specific effects attributable to the growth factors employed were markedly affected also by the elements iron and molybdenum.The carrot explants that had responded to coconut milk emphasized alanine in their soluble, non-protein, nitrogenous pool, whereas those subjected to the active components of System I or of System II as clearly emphasized glutamine as the prominent non-protein, nitrogen-rich compound.The partial effects due to the component parts of System I (AF_aesc or inositol) and to the component parts of System II (Zeat. or IAA), as these interacted also with iron and molybdenum in an otherwise trace element free basal medium (B ^**), revealed a pattern of interlocking effects, due to trace elements and to growth factors, upon the metabolism (especially the nitrogen metabolism) of the aseptically cultured carrot explants. These effects show that the individual growth factors do not act alone and that their implications are far reaching. The interactions between growth promoting Systems I and II and their component parts, with each other, with various environmental factors, and especially with trace elements constitute a network, or a matrix, of parameters that will merit further investigation to reveal all that is required to control the growth and metabolism of carrot cells.This investigation was supported by PHS Research Grant No. GM 09609 to one of us (F.C.S.) from the National Institutes of Health.The collaboration with Dr. K. V. N. Rao, later made possible by this grant, was first arranged under the terms of a Fulbright travel grant and the award of a Smith-Mundt stipend.     

Investigations on the growth and metabolism of cultured explants of Daucus carota

Summary Earlier papers of this series relate to different growth-promoting substances and systems which, singly and in combination, have interacted with trace elements (Mn and Mo) and Fe to induce growth and to affect the metabolism of aseptic cultures of carrot. The solutes of cultured carrot cells (K⁺, Na⁺, Cl^–, total solutes) are also affected. Two clones were grown in 9 combinations of growth factors and under 4 trace-element regimes (a complete complement including Fe, and this complement lacking either Mn or Mo, or both Mn and Mo), a total of 36 treatments under otherwise standardized experimental conditions. Under the treatments applied the number of cells varied over a 35fold range and their average size over a 7fold range; the concomitant effects on their solutes are expressed in terms of concentrations and of total content per cell. Both growth and the solutes accumulated were variously affected by carrot growth-promoting system I (mediated by inositol), by system II (mediated by IAA), and by coconut milk in the presence of Fe, with and without Mn, Mo, or Mn and Mo.The greatest concentrations of total solutes occurred in tissue cultured in nutrient solutions which lacked the stimuli to rapid cell multiplication and were also limited by the trace elements Mn and Mo. Moreover, specific regulatory effects of the trace elements on solute content, not solely attributable to their effects on cell growth, have been noted. An imbalanced growth-factor regime (zeatin acting alone, i.e. without IAA) shifted the normal preference for K⁺ over Na⁺ strongly toward Na⁺, a trend which could also be induced by certain trace elements and more balanced growth-factor regimes, e.g. in a basal coconut milk medium lacking only Mn.The data are interpreted in the context of views on the de-novo uptake of salts and solutes in cultured cells as they grow. These cells respond to a network, or matrix, of interacting factors by distinctive effects that are attributable to the component parts of the culture medium acting singly and in various combinations. These interactions (involving trace elements and exogenous growth factors) control growth (fresh weight, number and size of cells) and regulate the solutes (organic and inorganic; K⁺ vs. Na⁺; organic anions vs. Cl^–) which the cells acquire as they grow and develop. The intensity of the response of the cultures to balanced, or imbalanced, growth factors creates the internal spaces accessible to solutes; and the metabolism, as it is also affected by growth factors and trace elements, determines how these spaces are to be filled at a given osmotic value. The evidence shows the range of factors that affect the accumulation of solutes in cells as they grow and is to be contrasted with conventional observations on mature cells held in steady states under conditions that preclude all growth and when only a single ionic species is followed over a very short interval of time.     

INDUCTION OF XYLEM ELEMENTS IN ISOLATED COLEUS PITH

Small pith explants from the fifth internode of Coleus blumei were placed on a defined medium supplemented with different concentrations of indoleacetic acid (IAA). With all levels of IAA tissue growth was slight; however, when the medium contained more than 10^-7 m IAA, xylem elements developed after 11-14 days. Omission of sucrose from the medium prevented this differentiation of xylem elements. Isolated xylem cells or small nodules were most common, but long strands were also seen. The merits of the Coleus system for study of plant-cell differentiation are discussed.     

A Requirement for DNA Synthesis during Auxin Induction of Cell Enlargement in Tobacco Pith Tissue

IAA (indoleacetic acid) is known to induce cell enlargement without cell division in tobacco pith explants grown on an agar medium without added cytokinin. The very long lag period before IAA (2 × 10^?5M) stimulates growth, about 3 days, can be useful to study the metabolic changes which lead to the promotion of growth. When the disks are transferred to a medium without IAA after 2 days or less of treatment with IAA, the IAA does not stimulate growth. Disks transferred after 3 days, subsequently show an auxin response, almost as great as those given IAA continuously. At 5 × 10^?4M, 5-fluorodeoxyuridine (FUDR), which inhibits DNA synthesis by blocking formation of thymidylate, completely suppresses the lAA-induced growth if it is added together with the IAA or 1 day later. When the FUDR is given 2 days after the IAA, there is a small increment of auxin-induced growth, and an even greater amount if added after 3 days. The period when exogenous auxin must be present to stimulate growth corresponds to the period of FUDR sensitivity. The FUDR inhibition is prevented by thymidine but not by uridine. Other inhibitors of DNA synthesis, hydroxyurea and fluorouracil, also inhibit auxin-induced growth. Thus DNA synthesis seems to be required for auxin induction of cell enlargement in tobacco pith explants. In contrast, FUDR does not inhibit auxin-induced growth in corn coleoptile and artichoke tuber sections.     

Comparative trace element and organic growth factor requirements of five hansenula species

A comparative response of specific trace elements and organic growth factors for the growth of five Hansenula species (H. anomala, H. beijerinckii, H. ciferrii, H. polymorpha and H. sydowiorum) has been studied. Out of twenty three trace elements tested, Fe, Zn, Mn and Cu were found to be essential for the growth of all yeast species studied here, whereas the rest of the elements exhibited variable essentiality. From fifteen organic growth factors tested, thiamine, biotin, pyridoxine and inositol are the most commonly required growth factors by the yeasts, whereas the rest of the organic growth factors showed variable essentiality. All species of yeasts investigated required different concentrations of trace elements and organic growth factors for their optimum growth. Concentrations higher than the optimum have been found to be inhibitory for the growth of all the yeasts studied.     

Regeneration of plantlets from leaf and petiole explants of Pelargonium x hortorum

Summary The in vitro plant regeneration potential of vegetatively propagated geraniums (Pelargonium x hortorum) has been investigated. Using various combinations of growth regulators and a choice of different explants, a regeneration protocol has been developed to raise in vitro plantlets from young petiole and leaf explants from three different cultivars of geraniums. In all three cultivars, very young petiole explants exhibited a higher regeneration potential as compared with leaf explants. Regeneration efficiencies were found to be highly dependent on the cultivar, with cv. Samba showing the highest regeneration potential, followed by cvs. Yours Truly and then Sincerity. Samba also showed the highest number of shoots from both the petiole [57 shoot buds per petiole explant in the presence of 3 μM zeatin and 1 μM indole-3-acetic acid (IAA) and leaf explants (43 shoots per leaf explant with 10 μM zeatin and 2 μM IAA). Shoot buds transferred to Murashige and Skoog (MS) medium supplemented with 0.44 μM N⁶-benzyladenine and 0.11 μM IAA grew vigorously and attained 1–2 cm in length in 3–4 wk. These shoots rooted with 100% efficiency on MS basal medium, and plants developed that showed normal growth and flowering under greenhouse conditions.     

TDZ-induced high frequency plant regeneration through multiple shoot formation in witloof chicory (<Emphasis Type="Italic">Cichorium intybus</Emphasis> L.)

A very efficient and rapid regeneration system via multiple shoot formation was developed for Cichorium intybus L. when leaf explants excised from sterile seedlings were cultured on medium supplemented with different concentrations and combinations of various plant growth regulators. In a comparison of leaf lamina and petiole explants, lamina explants produced over three times more shoots than petiole explants, with a mean of 7.5 shoots compared to 2.4. Of the combinations of KIN/IAA, KIN/NAA, BAP/IAA, or BAP/NAA, 0.5 mg l⁻¹ KIN combined with 0.3 mg l⁻¹ IAA was the most effective, producing a mean of 19.7 shoots per lamina explant while the control treatment involving no plant growth regulators produced no shoots at all. When either cytokinin was used alone, BAP was found nearly twice more successful than KIN. However, the most effective treatment of all was the combination of 0.01 mg l⁻¹ TDZ and 1.0 mg l⁻¹ IAA, producing as many as 35.8 shoots per lamina explant. This rate of shoot regeneration is remarkably higher than those previously reported for C. intybus, most likely due to the highly inductive effect of TDZ, which was tested for the first time in this species. Rooting of the shoots was readily achieved on medium containing different concentrations of IAA or IBA. IAA was more effective than IBA and resulted in the highest frequency of shoots that rooted (100%) and mean number of roots per shoot (4.2) when used at 0.5 mg l⁻¹. Hardening off process resulted in a production of more than 80% healthy plantlets.     

Reversal of cytokinin action by riboflavin during stage II micropropagation: The role of 3-methyleneoxindole

Summary Nicotiana tabacum explants were grown on stage II micropropagation medium containing 6-[γ,γ dimethylallyl amino]-purine (2iP), a cytokinin, and indole-3-acetic acid (IAA), an auxin, under a photon fluence rate of ≈60 μmol m⁻² s⁻¹. In the presence of riboflavin the explants showed growth patterns suggesting that IAA had assumed a dominant regulatory role, even though the medium contained a high 2iP:IAA molar ratio. It was determined that this effect was produced by 3-methyleneoxindole, a product of the riboflavin-catalyzed photooxidation of IAA. Methyleneoxindole was recovered from the riboflavin-treated agar medium and found to be much more active than IAA in supporting stage II and stage III micropropagation of tobacco explants. Reversal of cytokinin action by riboflavin did not result from the inhibition of any cytokinin-specified growth function because, in the presence of riboflavin, normal stage II growth was obtained if naphthaleneacetic acid was used as the auxin.     

Clonal propagation byin vitro culture of Corchorus (jute)

Callus was produced on cotyledon, shoot tip, hypocotyl and root explants of twoCorchorus species on several media. Cytokinin was necessary for callus production on cotyledon explants. BothC.olitorius genotypes produced most callus on media with zeatin and either NAA or IAA, and theC.capsularis genotype produced most callus on media with IAA and either zeatin or BA. High frequencies of regenerated shoots were obtained from shoot tip explants of both species, from the apical meristem and from callus. Media with 2.0 mg 1⁻¹ BA were superior for both species, and media with zeatin were equally good forC.capsularis only. More regeneration was obtained for all genotypes after subculture of callus on media with 2.0 mg 1⁻¹ zeatin. Cotyledon callus produced less regeneration, also with differences between genotypes; explants of both genotypes ofC.olitorius produced regeneration on a medium with NAA and zeatin, and theC.capsularis genotype produced regeneration on a medium with IAA and BA. Limited regeneration from root explant callus was obtained forC.capsularis only on medium with BA and IAA. Regeneration was not obtained from hypocotyl callus. Further regeneration of shoots of both species was obtained from secondary callus after subculture, and from nodal segments of regenerated shoots and of seedling shoots cultured on basic MS medium without growth hormones. Roots were produced on about 80% of all shoots after transference to medium with 0.2 mg 1⁻¹ IBA, and rooted plantlets survived and flowered normally after transference to compost.     

Interaction of auxin, cytokinin, and gibberellin on cell division and xylem differentiation in cultured explants of Jerusalem artichoke.

Dark-cultured explants of parenchymatous cells isolated fromJerusalem artichoke tubers were induced to divide and differentiateas tracheary elements on Murashige and Skoog medium containingdifferent combinations of plant growth-hormones such as auxin(IAA), cytokinin (zeatin), and gibberellin (GA₃). Addition ofauxin to the growth-medium induced after a short lag period,very rapid cell division which was followed by differentiationof some of the divided cells as tracheary elements. At the optimallevel of IAA (5.0 mg/liter), the percentage of tracheids differentiatedwith respect to the total number of cell population was 13.54.When the explants were cultured in the presence of both auxin(IAA 5.0 mg/liter) and one cytokinin (zeatin 0.1 mg/liter),not only a strong interaction on cell division and trachearyelement formation was observed but also an increase in the percentageof tracheids differentiated in relation to the total cell population.Auxin-gibberellin and auxin-gibberellin-cytokinin treatmentsalso produced interaction on cell division and cytodifferentiation.In explants treated with the three growth-hormones about 20%of the total cell population differentiated as tracheary elements.Further, all the hormonal treatments gave different patternsof cytodifferentiation which reflected meristematic patterns. ¹ This research was supported by a grant from C. N. R. Italy. (Received April 18, 1973; )     

The role of GA,IAA and BAP in the regulation of <Emphasis Type="Italic">in vitro</Emphasis> shoot growth and microtuberization in potato

The effect of auxin, GA and BAP on potato shoot growth and tuberization was investigated under in vitro condition. The shoot length of potato explants increased with the increasing of concentrations (0.5 – 10 mg dm⁻³) of IAA treatment especially with the addition of GA₃ (0.5 mg dm⁻³), but was inhibited by BAP (5 mg dm⁻³). The root number and root fresh weight of potato explants increased with the increasing of IAA levels either in the presence of GA₃ (treatment IAA+GA) or not (IAA alone). However, no root was observed in the treatment IAA+BAP, instead there were brown swollen calli formed around the basal cut surface of the explants. The addition of GA₃ remarkably increased the fresh weight and diameter of calli. Microtubers were formed in the treatments of IAA+BAP and IAA + GA + BAP but not observed in the treatments of IAA alone or IAA + GA. IAA of higher concentrations (2.5 – 10 mg dm⁻³) was helpful to form sessile tubers. With the increasing of IAA levels, the fresh weight and diameter of microtubers increased progressively. At 10 mg/L IAA, the fresh weight and diameter of microtubers in the treatment of IAA + GA + BAP were 409.6 % and 184.4 % of that in the treatment of IAA + BAP respectively, indicating the interaction effect of GA and IAA in potato microtuberization.     

Does indoleacetic acid promote growth via cell wall acidification?

Growth of Triticum aestivum L. cv. Cappelle Desprez coleoptiles is promoted by 5.7×10^–5 M indole acetic acid (IAA) as effectively in pH 3.4 buffer as in water, but IAA is not effective in the presence of buffer at pH 3.0 or 3.2 A combination of 5.7×10^–5 M IAA and pH 3.4 buffer promotes growth to a greater extent than pH 3.2 buffer alone, which is optimal for acid-induced growth. IAA employed at 10^–7 M is still effective at promoting growth in the presence of pH 3.4 buffer, moreover, IAA at 10^–7 M interacts synergistically with the acidic buffer to promote growth. It is concluded that IAA and acid promote growth via separate mechanisms, and that IAA does not promote cell wall loosening by rendering the cell wall more acid.Abbreviation IAA Indoleacetic acid     

Adventitious shoot regeneration from Sinningia speciosa leaf discs in vitro and stability of ploidy level in subcultures

Summary Leaf explants of Sinningia speciosa were cultured in vitro on Murashige and Skoog (MS) basal medium with various growth substances in order to regenerate shoots. On MS medium supplemented with indoleacetic acid (IAA) and kinetin, 80% of the explants produced green callus and 25 to 30 shoots with roots per explant. On MS supplemented with IAA and N⁶ benzyladenine (BA), 80% of the explants produced green callus and 40 to 50 shoots per explant but lacked roots. After 3–4 mo., these shoots were removed from the initial explants and transferred separately onto MS supplemented with indolebutyric acid for their elongation and successive rooting (3 mo.). Histological studies showed that the callus was associated with mesophyll cell layers, primarily with the spongy parenchyma. The shoots regenerated at the callus surface and were associated with newly differentiated vascular areas. Recurrent regenerations were obtained from leaf explants or apical meristems excised from shoots of the previous subcultures. These explants, as compared to initial cultures, had a high frequency of regeneration and also produced more shoots per explant. Chromosome numbers of root tip cells of the mother plant and of all in vitro-regenerated plants remained constant: 2n=26.     

Effects of auxins and cytokinins on tissue culture of Grateloupia dichotoma (Gigartinales,Rhodophyta)

The role played by plant growth regulators in algae is poorly known. In order to increase the knowledge about the function of auxins and cytokinins in seaweeds, explants such as apical and intercalary segments and callus-like structures (CLS) of Grateloupia dichotoma were cultured in semi-solid or liquid artificial media ASP 12-NTA. Two auxins, indole-3-acetic acid (IAA) and 2,4-dichlorophenoxyacetic acid (2,4-D), and one cytokinin, 6-benzylaminopurine (BA), at concentrations of 0.5 and 5.0 mg l^–1 were tested. Moreover, IAA and BA were tested together at concentrations of 1:5 and 5:1 mg l^–1. All treatments promoted the growth of CLS in intercalary segments; CLS from apical segments were significantly higher in treatments with 2,4-D or IAA:BA (1:5 mg 1^–1). The morphogenetic responses for auxins and BA were opposite, auxins inhibited while BA promoted the formation of lateral branches; however, auxins promoted the elongation of such branches. The process of plant regeneration observed on CLS was stimulated significantly by treatment with high concentration of BA or IAA:BA (1:5 mg 1^–1) in semi-solid and liquid media. The growth of upright axes was stimulated significantly by treatment with 2,4-D in semi-solid medium, and IAA:BA (1:5 mg l^–1) in liquid medium. These results show the importance that plant growth regulators could have in the control of growth, morphogenetic processes and micropropagation in red algae.This paper is part of the PhD thesis of NSY.     

The Effect of Various Media on the Growth Responses of Different Clones of Carrot Explants

The induction of growth in otherwise quiescent tissue explantedfrom carrot root has been investigated with reference to theeffects of different kinds of growth-promoting substances addedas supplements to a basal medium, singly and in combination.The effects of these media upon different clones of carrot explantsare described. The idiosyncrasies of different clones of explantswere detected by their responses measured by the incidence ofcell division, the extent of cell enlargement, and by theirnucleic acid content. The basal medium which contains salts,sugar, and vitamins supported only a minimal amount of growth;the basal medium supplemented with casein hydrolysate and coconutmilk (10 per cent by volume) supported the highest level ofgrowth obtained in any of the treatments tried. The active componentsof the coconut milk (AF_cm) when refined required the furtherparticipation of either indole-3yl-acetic acid (IAA) or inositol,and were further stimulated by casein hydrolysate (CH). Thusthe over-all stimulus of the coconut milk comprised two parts—nowrecognized as growth-promoting systems I and II, respectively.The effects of System I were mediated by appropriate combinationsof inositol and the corresponding active growth-promoting factors(AF₁) which were, in turn, represented by a purified factorpreviously isolated from Aesculus (AF₂). System I induced bothcell division and cell enlargement in balance, whereas SystemII stimulated internal cell division more than cell enlargement.The effects of System II were mediated by appropriate combinationsof IAA and active growth-promoting factors (AF₂), which wererepresented by the substance zeatin. The maximum growth of anygiven clone of carrot explants isolated from a given carrotroot was only supported by exogenous requirements, over andabove a basal nutrient medium, which meet its specific endogenouslimitations. The paper shows how these limitations may be diagnosed,and discusses the over-all growth stimulus due to coconut milkin terms of the partial responses elicited by the known componentsof Systems I and II.     

Effect of exogenous application of IAA and GA3 on growth,protein content,and antioxidant enzymes of Solanum tuberosum L. grown in vitro under salt stress

Indole-3-acetic acid (IAA) and gibberellic acid (GA₃) are essential for the growth and development of plants. In the present study, the ameliorative potential of these phytohormones on growth, protein content, and antioxidant enzymes was investigated in in vitro-grown Solanum tuberosum L. cultivars ‘Cardinal’ and ‘Desiree’ under salt stress. A 4 × 3 factorial combination of 0, 40, 60, or 80 mM NaCl with 0, 7, or 14 μM IAA, or 0, 14, or 21 μM GA₃, were added to Murashige and Skoog (MS) basal medium, followed by inoculation of nodal explants or callus cultures. The data for root and shoot number and length, number of nodes and leaves, fresh weight of plants, increase or decrease in fresh weight of callus cultures, total soluble protein, and superoxide dismutase (SOD) and peroxidase (POD) activities were recorded after 30 d. The growth of both callus cultures and nodal explants subjected to NaCl stress was substantially reduced compared with the control. Both IAA and GA₃ successfully alleviated the harmful effects of salt stress on all of the growth parameters studied. Salt stress resulted in decreased protein content, which increased when the media also contained phytohormones. The activities of SOD and POD were increased with either IAA or GA₃ under NaCl stress. Therefore, the exogenous application of both IAA and GA₃ not only played a positive role in terms of in vitro potato growth but also significantly affected the biochemical parameters tested.

     

In vitro propagation of the alkaloid producing plant Datura insignis Barb. Rodr.

A method is presented for the in vitro propagation of Datura insignis Barb. Rodr. Nodal explants were cultured on Murashige and Skoog medium supplemented either with BA alone or in combination with 2,4-D or IAA. Shoot multiplication and elongation were obtained in various growth regulator concentrations. Best results were obtained in a medium with 1.0 mgl^-1 of BA. Individual shoots were excised and transfered to growth regulator-free medium for rooting. Additional multiplication was obtained by single-node culture using explants from these in vitro rooted shoots. Rooted plantlets were successfully grown in soil.     

Micropropagation of the medicinal plant, Scilla natalensis Planch.

Primary bulb explants of Scilla natalensis were cultured in vitro on modified MS medium. Some of these explants initiated shoots, which provided a sterile source of secondary leaf and bulb explants. The secondary explants responded similarly to various combinations of plant growth regulators. Shoots were initiated spontaneously on medium containing no plant growth regulators. The number of shoots initiated was increased by the addition of kinetin or thidiazuron (TDZ) alone, but was reduced by the addition of indole-3-acetic acid (IAA) or naphthalene acetic acid (NAA) alone. Optimal shoot initiation occurred on medium containing 1 to 2 mg l^–1 kinetin and 1 to 2 mg l^–1 IAA. These shoots were rooted on medium containing 1 mg l^–1 IAA. The plantlets were successfully acclimatised in the misthouse/shadehouse.     

Growth stimulation by catecholamines in plant tissue/organ cultures

Addition of catecholamines at micromolar concentrations caused a dramatic stimulation of growth of tobacco (Nicotiana tabacum) thin cell layers (TCLs) and Acmella oppositifolia “hairy” root cultures. A threefold increase in the rate of ethylene evolution was observed in the catecholamine-treated explants. Aminooxyacetic acid and silver thiosulfate, inhibitors of ethylene biosynthesis and action, respectively, reduced the growth-promoting effect of dopamine. However, these compounds alone could also inhibit the growth of the TCL explants. When ethylene in the culture vessel was depleted by trapping with mercuric perchlorate, dopamine-stimulated growth was still obtained, suggesting that ethylene does not mediate the dopamine effect. Dopamine potentiated the growth of TCLs grown in Murashige and Skoog medium supplemented with indoleacetic acid (IAA) and kinetin. When IAA was replaced by 2,4-dichlorophenoxyacetic acid, dopamine addition showed no growth-promoting effect. Instead, 2,4-dichlorophenoxyacetic acid stimulated the growth of TCL explants to the same extent as that obtained with IAA plus dopamine. Because synthetic auxins do not appear to be substrates for IAA oxidizing enzymes, we hypothesized that catecholamines exert their effect by preventing IAA oxidation. Consistent with this explanation, dopamine (25 micromolar) inhibited IAA oxidase activity by 60 to 100% in crude enzyme extracts from tobacco roots and etiolated corn coleoptiles, but had no effect on peroxidase activity in the same extracts. Furthermore, addition of dopamine to TCL cultures resulted in a fourfold reduction in the oxidative degradation of [1-¹⁴C]IAA fed to the explants. Because the growth enhancement by catecholamines is observed in both IAA-requiring and IAA-independent cultures, we suggest that these aromatic amines may have a role in the regulation of IAA levels in vivo.     

Micropropagation ofCereus peruvianus mill. (cactaceae) by areole activation

Summary Currently,Cereus peruvianus plants can be rapidly clonedin vitro via adventitious organogenesis using callus cultures; however, somaclonal variation is a problem. A method is described herein using lateral bud explants to produce multiple shoots for clonal propagation. Apical and lateral explants were cultured on MS (Murashige and Skoog, 1962) media with factorial combinations of the auxins indole-3-acetic acid (IAA), 1-naphthaleneacetic acid (NAA), and cytokinins 6-ben-zyladenine (BA) and N-(2-furanyl-methyl)-1-purine-6 amine (kinetin) at the concentrations 0.0, 0.01, 0.1, 1.0 mg“l⁻¹. Positive results were obtained from the lateral explants in all conditions tested, but apical explants did not respond toin vitro multiplication ofC. peruvianus cactus at all growth regulator combinations tested. Formation of axillary shoots inC. peruvianus seems most frequent in medium containing BA at 1.0 mg·l⁻¹ (4.44 μM) and IAA or NAA at 1.0 mg·l⁻¹ (5.71 μM or 5.37 μM respectively), but the frequency of shoot formation in the BA or kinetin and NAA or IAA combinations indicated that any of the combinations tested can be used for multiplication ofC. peruvianus plants regenerated from callus tissue culture. Root formation occurred in all (100%) of the cactus shoots after 9 wk in the same culture medium. All the cacti that developed at the different auxin and cytokin combinations continued growth after transfer to a potting mix of red earth (Paleudult) and ground river sand (1∶1).