Effects of N-1-naphthylphthalamic acid on the growth and bud formation of tobacco callus grown in vitro

The effect of N-1 -naphthylphthalamic acid (NPA), indole-3-aceticacid (IAA) and kinetin on callus growth and bud formation wasstudied mainly by a tobacco callus culture method. Callus producedfrom Nicotiana tabacum var. Wisconsin 38 was used as the testplant material. Callus growth on nutrient agar containing 2mg/liter of IAA was promoted by NPA added at a concentrationof 0.5 mg/liter with 0.4 mg/liter of kinetin or by NPA addedat 5 mg/liter in the absence of kinetin. At a high concentrationof 50 mg/liter, however, NPA inhibited growth on the mediumcontaining 2 mg/liter IAA and no kinetin. Kinetin reduced thisNPA inhibition. In the presence of 0.4 mg/liter kinetin and2 mg/liter IAA, when the concentration of NPA was 50 mg/liter,buds were initiated after calluses were grown on the test mediumfor 7 weeks in dim light, but no buds formed when NPA was omittedfrom the above medium. The control of callus growth and bud initiation is based onthe active ratio of auxin (IAA) to cytokinin (kinetin) in themedium and NPA added to the medium can promote or inhibit callusgrowth and induce bud formation. Therefore, it is proposed thatNPA can itself reduce auxin activity or enhance cytokinin activityand hence change the active ratio of the two regulators. NPAmay enhance the activity of cytokinin (here supplied as kinetin)but cannot substitute for it. ¹Present address: Department of Biology, Wisconsin State University,Oshkosh, Wisconsin 54901, U. S. A. (Received March 10, 1969; )     

Induction of auxin-nonrequiring tobacco calluses and its reversal by treatments with auxins

Auxin-nonrequiring calluses were induced with high frequenciesby short treatments with auxins from auxin-requring ones. Auxin-requiringcalluses T22 and XD6S2, subcultured on a medium containing 1mg/liter IAA as plant growth regulator, required quite differenttreatment for induction from auxin-nonrequiring calluses; fromcalluses T22 and XD6S2, auxin-nonrequiring calluses were inducedby treatments with low concentrations of auxins (0.01–0.1mg/liter of IAA or NAA) and high concentrations of syntheticauxins (10–100 mg/liter of NAA or 1–10 mg/literof 2,4-D), respectively. No auxin-nonrequiring calluses wereobtained when they were transferred directly to the basal medium(hormone-free medium). The transformation of auxin-requiring into auxin-nonrequiringcalluses was fully reversible by treatment with 1 mg/liter ofIAA at an early stage of subculturing on the basal medium, butnot after prologed subculturing. ¹Part XXI in the series, ‘Studies on Plant Tissue Cultures’.Part XX, see Proceedings of the IVth International FermentationSymposium: Ferment. Technol. Today 697 (1972). (Received May 29, 1973; )     

ATTEMPTS TO OBTAIN BACTERIA-FREE PLANTS OF PSYCHOTRIA PUNCTATA (RUBIACEAE): GROWTH AND ROOT FORMATION IN CALLUS CULTURES

Attempts were made to obtain bacteria-free plants of Psychotria punctata from tissue cultures. Stem explants and callus derived from them were induced to form roots but failed to form buds on Linsmaier and Skoog medium and 96 chemical modifications of it, including most of those known to induce bud formation in other species. Roots formed with ample IAA (2 mg/liter or more) and a low kinetin concentration (0.25 or 0.50 mg/liter). Adenine inhibited root formation in these media, but tyrosine did not. Tyrosine did lower the percentage of calluses commencing growth. When enzyme-hydrolyzed lactalbumin (1.3 g/liter), kinetin (0.5 mg/liter) and IAA (5 mg/liter) were added to Linsmaier and Skoog medium modified by decreasing inorganic nitrogen and increasing inorganic phosphate, callus grew at the fastest rate observed (increasing threefold in fresh weight in three weeks) and formed numerous roots. This was adopted as the stock callus medium. Casein hydrolysates also stimulated growth but less so than lactalbumin hydrolysate. When lactalbumin hydrolysate or a casein hydrolysate lacking tryptophan was supplied, growth occurred without added auxin if sufficient cytokinin was added. Cytokinin was required at unusually high concentration and was tolerated at still higher concentration. Formation, elongation, and branching of roots persisted on a saturated solution of BA which inhibited callus growth about 70 % and delayed callus senescence. Light caused earlier callus senescence after growth had ceased but did not affect callus growth or root formation. Light-induced senescence was prevented by a high cytokinin concentration.     

NUTRITIONAL REQUIREMENTS OF FRAXINUS CALLUS CULTURES

A satisfactory synthetic medium has been developed for continuous growth of Fraxinus pennsylvanica Marsh. callus cultures. The medium contains modified Reinert and White (1956) inorganic nutrient solution with 5 mg/liter Fe as NaFe-EDTA and supplemented with myoinositol 10 mg/liter, pyridoxine HCl 0.1 mg/liter, 2,4-dichlorophenoxyacetic acid 0.04 mg/liter, kinetin 1 mg/liter, sucrose 20 g/liter, and agar 10 g/liter. myo-Inositol, pyridoxine and an auxin are essential. α-Naphthaleneacetic acid is an effective alternate auxin. Kinetin and to some extent gibberellic acid improve the yields. Thiamine has no effect.     

Tissue culture inHaworthia

Effects of three auxins and kinetin on growth of the calluses of two species ofHaworthia, H. aristala andH. setata, were investigated. Stock calluses derived from the flower buds of these species were maintained for two years on RM-1964 agar medium containing 5 mg/l NAA. Small pieces of the stock calluses were transferred to the basal medium containing either auxin, IAA, NAA or 2,4-D in six different concentrations (0.1–50 mg/l) combined with three concentrations (0–2 mg/l) of kinetin; in total, 54 kinds of media were used. Fresh weight of the calluses was measured 0 to 30 days from transfer and transformed to the natural logarithm. The linearity of their growth curves against the culture period was tested. The growth curves of theH. aristata calluses grown in dark and under continuous light and that of theH. setata callus grown in dark gave similar regression coefficients of 0.07 to 0.11, indicating that the doubling time of the callus mass was about 6.3 to 10.1 days. After 42 to 50 days from inoculation, the fresh weight of each individual callus was recorded, and the data were statistically analyzed. All auxins at the concentration of 50 mg/l significantly inhibited callus growth. Kinetin did not affect growth of theH. aristata callus in dark, while its effect on theH. setata callus was detected under light. Interaction of kinetin was found with IAA and 2,4-D inH. aristata and with IAA and NAA inH. setata. REsponses of theH. aristata callus to auxins and kinetin, when grown in dark, were different in several points from those of theH. setata callus grown under light. The best callus growth was observed in the following media; 0.2 mg/l kinetin supplemented with 1 mg/l IAA, or 0.5 mg/l 2,4-D, and 2 mg/l kinetin with 0.5 mg/l NAA inH. aristata, and 0.2 mg/l kinetin supplemented with 1 mg/l IAA, 5 mg/l NAA or 0.1 mg/l 2,4-D inH. setata. Contribution from the Laboratory of Genetics, Faculty of Agriculture, Kyoto University, Japan, No. 413.     

Morphactin-kinetin interaction on growth and shoot formation in tobacco callus cultures

Pith-derived calluses of Nicotiana tabacum L. cv. Wisconsinno. 38 were inoculated on an RM-1964 medium containing variousconcentrations of a morphactin, chlorflurenol (CFl) and kinetin(KIN). An addition of KIN (0.1–2 mg/liter) alone was effectivefor shoot formation from the calluses, but a high dose (10 mg/liter)resulted in the inhibition of growth and in no differentiation.The inhibitory effect of a high dose of KIN was counteractedwith CFl. Three combinations of KIN and CFl; CFl (0.1 mg/liter)$KIN(2.0 mg/liter); CFl (0.1 mg/liter)$KIN (10.0 mg/liter) and CFl(1.0 mg/liter) $KIN (2.0 mg/liter), were successful for 100%shoot redifferentiation in inoculated calluses. An appropriatebalance between CFl and KIN seems to be involved in shoot formation.The present results can best be interpreted by assuming thatCFl acts as an auxin in cultured tissues. (Received January 16, 1975; )     

Differentiation of Shoot Buds in vitro in Tissue 1Sisymbrium irio L.

Shoot bud formation was induced in the stem callus of Sisymbriumirio L., a Cruciferous plant. The callus was established onMurashige and Skoog medium with IAA (1?0 mg l^–1) and kinetin(0?5 mg l^–1). The effect of three purines (kinetin, 6-benzylaminopurine,and 6-methylaminopurine) incorporated singly along with IAAin MS medium was investigated. It was found that kinetin orMAP (3–5 mg l^–1) along with IAA (0?5 mg l^–1)were the most effective in inducing shoot bud formation. Adeninesulphate (10 mg l^–1) with kinetin (1?0 mg l^–1) alsoinduced bud differentiation. The morphogenetic potential of the callus to differentiate shootbuds was seemingly lost in 2 year old callus cultures. However,on successively subculturing on a regeneration medium shootbuds differentiated and the number of buds formed improved onfurther subculture. Two types of meristematic outgrowths were recognized: (i) arisingfrom superficial cells and (ii) arising from deep-seated cellsin the vicinity of tracheidal elements. However, both typesformed meristematic nodules on the surface of which shoot budsdifferentiated. Some embryoids were also recognized arisingsuperficially.     

SHOOT AND TREE PRODUCTION FROM ASPEN TISSUE CULTURES

Trees were produced from firm white callus tissue of triploid quaking aspen (Populus tremuloides Michx.), initiated on a modified Wolter and Skoog defined medium and subcultured monthly for two years. When subcultured to medium without auxin, kinetin or supplements, but containing 0.15 mg/liter BAP (6-benzylaminopurine), multiple stunted shoots appeared on most inocula. However, at 0.05 mg/liter BAP, only a few vigorous shoots per piece were initiated, but seven rooted on the callus: two in the dark with BAP and five in 200 ft-c of light with 0.04 mg/liter 2,4-D. After proliferation of the roots on the medium surface, four shoots elongated and were planted in semi-sterilized soil, then were given 3100 ft-c of light for rapid growth into trees. Both light sources were on for 16 hr/day. Two trees were also grown from stunted shoots excised from the callus and rooted in soil.     

杜仲叶片愈伤组织诱导的激素优化研究

以杜仲优树L33的幼叶为材料,在B5培养基上添加不同浓度的生长素与细胞分裂素进行愈伤组织诱导研究,结果表明：无激素的培养基上不能诱导出愈伤组织,单独加入2,4-D、NAA和IBA均可诱导出愈伤组织,以0.5 mg·L^-1 2,4-D、0.5～1.0 mg·L^-1 NAA、1.0 mg·L^-1 IBA出愈率最高,达100%,且愈伤组织生长较好;在适宜浓度的生长素的培养基上加入细胞分裂素时,KT的加入对愈伤组织的诱导及生长起抑制作用;1.0 mg·L^-1 NAA+0.3～0.5 mg·L^-1 BA与1.0 mg·L^-1 IBA+0.3～0.5 mg·L^-1 BA 的组合可明显促进愈伤组织的诱导和生长,适合进一步继代培养。     

Cytokinins in Azotobacter vinelandii Culture Medium

Azotobacter vinelandii OP was grown to stationary phase in defined medium. The cell-free culture medium was analyzed for cytokinin content by XAD-2 and Sephadex LH-20 chromatography, thin-layer chromatography, tobacco callus bioassay, and enzyme immunoassay. Three cytokinin-active fractions were detected and tentatively identified as trans-zeatin, isopentenyladenosine, and isopentenyladenine. The total cytokinin activity was equivalent to 0.75 μg of kinetin per liter.     

Effect of External Supply of Growth Substances on Axillary Proliferation and Development in Dioscorea bulbifera

Bulbil development in cultured nodes of D. bulbifera proceededin the absence of growth substances from the medium. When IAAwas incorporated into the medium at the concentrations of 5mg l^–1 and 10 mg l^–1 the cultured nodes producedlarger bulbils than in its absences. When the concentrationof IAA was increased to 15 mg l^–1, however, the culturednodes produced a callus instead of a properly organized bulbil.The dry weight of bulbils increased when kinetin was added tothe medium at the concentrations of 0.05, 0.5, and 2.5 mg l^–1.The greatest increase was with 0.5 mg l^–1 kinetin. Onincreasing the concentration of kinetin in the medium to 5.0mg l^–1 the tissue produced had smaller dry weight thanthose produced in the absence of growth substances. Additionof different combinations of IAA and kinetin to the basal mediumresulted in the production of normal bulbils, roots, and shootsin some instances (suitable combinations) and in the productionof callus and abnormal shoots in others (non suitable combinations).     

Tissue culture inHaworthia

Effects of three different auxins and kinetin in various combinations on greening and redifferentiation of the callus ofHaworthia setata were investigated. All auxins at the concentration of 50 mg/l inhibited callus greening. NAA in combination with kinetin promoted both callus greening and production of redifferentiated shoots. Low concentrations of IAA without kinetin promoted redifferentiation of shoots, but not callus greening. Addition of 2,4-D completely inhibited both greening and redifferentiation regardless of the level of kinetin except for the effects on shoot formation in the medium with 0.1 mg/l 2,4-D added. The calluses with the highest chlorophyll content were observed in the medium containing 2.0 mg/l kinetin without any auxins or with 0.1 mg/l NAA added. Most frequent shoot redifferentiation was observed in the medium containing 0.1 mg/l IAA without kinetin (redifferentiation rate; 67%), followed by the medium containing 10 mg/l NAA with 2.0 mg/l kinetin (44%), and 0.1 mg/l 2,4-D with 0.2 mg/l kinetin (33%). Generally, higher degrees of greening were associated with better growth. However, the auxins (IAA, NAA and 2,4-D) given at concentrations optimal for growth did not exhibit the highest degree of callus greening. Differences of the three auxins in their actions and interaction with kinetin were disclosed. Contribution from the Laboratory of Genetics, Faculty of Agriculture, Kyoto University, Japan, No. 423     

Studies on the Culture Conditions of Higher Plant Cells in Suspension Culture

To study the influence of cultural conditions on higher plant cells in suspension culture, the effects of nutritional conditions on the growth of suspended cells were investigated. Calluses were induced from 39 species of Nicotiana plants and 6 species of Populus plants on agar slant media, then these were transferred to suspension cultures. Concentrations of 2,4-D and kinetin suitable for incubation of callus from each plant were investigated and species having high growth rates in the appropriate medium were selected.

The effects of concentrations of auxins and kinetin, a variety of carbon and nitrogen sources, thiamin and myo-inositol on growth of the selected calluses were also studied. Of these calluses studied, N. glutinosa, N. tabacum var. Xanthi ova and P. hybrids were selected as calluses having high growth rates. Myo-inositol had no effect on any callus growth, and thiamin gave a distinct effect on Populus callus only. Nitrate as a nitrogen and sucrose as a carbon sources, and 2,4-D as an auxin were most effective in all calluses studied. Kinetin was essential for N. glutinosa among the calluses studied. Although high sugar concentrations tended to lengthen the lag period in the growth curve, there was no difference in the growth rates of the logarithmic phase among the concentrations.     

Induction of Callus from Flesh of Gardenia jasminoides ELLIS Fruit and Formation of Yellow Pigment in the Callus

Callus cultures were derived from flesh sections of young fruit of Gardenia jasminoides ELLIS on Murashige-Skoog agar medium supplemented with auxin and kinetin in the dark. Colored sections having deep yellow or orange color cells have been maintained for four years (32 generations) by subculturing on Linsmaier-Skoog Gelrite medium containing 1.0 mg/liter of indole-3-acetic acid and 0.1 mg/liter of kinetin in the dark. High-performance liquid chromatography of the yellow pigment showed the presence of crocin as a main component, but at low levels. An excess of gentiobiose, which was tentatively identified by high-performance liquid chromatography, was liberated from the yellow pigment by ammoniacal hydrolysis, but its origin other than crocin remains unknown.     

Effect of phytohormones on plant regeneration in callus culture of <Emphasis Type="Italic">Iris ensata</Emphasis> Thunb

The effect of phytohormones on plant regeneration in callus culture of Iris ensata Thunb. was studied. 2,4-Dichlorophenoxyacetic acid (2,4-D) proved to be the most suitable auxin for the induction and subculturing of morphogenic callus. Organogenic calluses were induced from isolated embryos at the waxphase in MS medium supplemented with 2,4-D (1.0–2.0 mg/l) and kinetin (0.2–0.5 mg/l). Changes in the medium hormonal composition favor the development of adventitious structures. The setting of adventitious shoot buds took place in the presence of 6-benzylaminopurine, while the development of shoots and root primordia was observed after 2,4-D replacement with indoleacetic acid (2.0 mg/l). The root initiation in regenerating plants required a hormone-free medium. The development of intact seedling and regenerated plants of I. ensata were studied. Analysis of the shoot structure demonstrated that in vitro cultured plants are at the juvenile stage.     

Hormonal Control of Xylogenesis in Pith Parenchyma Explants of Lactuca

The time course of xylem differentiation was determined in explantsof lettuce pith parenchyma (Lactuca sativa L. cv. Romana) culturedon Murashige and Skoog (1962) medium using different concentrationsof auxin (IAA) and one cytokinin (zeatin or kinetin). Increasinglevels of auxin from I mg 1^–1 to 15 mg 1^–1 in thepresence of a constant level of a cytokinin (zeatin or kinetin)yielded up to 10 mg 1^–1 IAA, an increase in the numberof tracheary element formations. Cytokinin concentrations aboveand below o.1 mg 1^–1 interacting with an optimal xylogenicamount of auxin inhibited xylogenesis. The IAA (10 mg 1^–1)-zeatin(0.1 mg ^1–1) treatment produced the greatest number oftracheids, while kinetin compared to zeatin did not producesuch an effect. The different effectiveness of zeatin and kinetinin inducing tracheary element formations was not due to a differentcapacity of the two cytokinins to stimulate cell division butit seems likely that zeatin, because of interaction with IAA,is more active than kinetin in the determination of the dividingcells in a specific type of cytodifferentiation. The IAA (10mg 1^–1)-zeatin (0.1 mg 1^–1) treatment produced about6.9 per cent tracheids with respect to cell division while IAA(10 mg 1^–1)-kinetin (0.1 mg 1^–1) produced 4.2 percent. These results are discussed with reference to the problemsof hormonal control of xylem differentiation.     

Effects of Auxin and Phenobarbital on Morphogenesis and Production of Digitoxin in Digitalis Callus

Pieces of callus obtained from seedlings of Digitalis purpureawere grown on solid Murashige-Skoog's medium supplemented with1 mg liter^–1 BA and 0.1 mg liter^–1 IAA or NAA, withor without phenobarbital (40 mg liter^–1). The replacementof the natural auxin IAA by the synthetic auxin NAA increasedcallus growth and inhibited organogenesis, whereas the additionof phenobarbital had the opposite effect. Morphometric measurementsrevealed a high ratio of vacuole to cytoplasm (v/v) in calluscells. This ratio was affected by the different treatments inthe same way as the fresh weight. The activity of mitochondrialcytochrome P450scc (the enzyme that provides the precursor,pregnenolone, for the biosynthesis of cardenolide in foxgloveplants) was detected in the relevant fraction of callus grownunder all experimental conditions, and its activity was increasedby the addition of phenobarbital. The different treatments testedincreased the cardenolide content and quantifiable amounts ofdigitoxin were detected in all callus tissues. It is of specialinterest that phenobarbital added to the culture medium increasedthe accumulation of digitoxin. The mechanism affecting the developmentand production of cardenolide in callus tissues of D. purpureaby phenobarbital and the replacement of IAA by NAA is discussed. (Received July 18, 1994; Accepted December 14, 1994)     

Auxin activity of substituted benzoic acids and their effect on polar auxin transport

Six dichloro-, 3 trichloro-, 2 triiodo-, and 3 heterosubstituted benzoic acids (amiben, dinoben, dicamba), and N-1-naphthylphthalamic acid have been tested for effects on growth and on polar auxin transport. Growth activity with and without kinetin was measured by effects on fresh and dry weights of 30-day cultures of fresh tobacco pith. Transport inhibition was measured by following uptake and output of IAA-2-¹⁴C through 10 mm bean epicotyl sections. The distribution of callus growth on vascularized tobacco stem segments was also observed. Avena first internode extension assays established the relative activities: dicamba > amiben > dinoben suggested by pith growth results. Growth effects of active compounds were similar with and without kinetin, except that amiben was less active with kinetin, while 2,3,6-trichlorobenzoic acid was more active with kinetin than alone. The weak auxin activity of NPA was confirmed. Transport experiments showed that NPA was the most inhibitory compound tested, followed by TIBA. Other compounds tested were at least 300 times less inhibitory to IAA transport. The best growth promoters were the least inhibitory to transport, and the most effective transport inhibitors were at best poor auxins. It is suggested that the weak auxin and auxin synergistic activity of TIBA (and perhaps 2,3-dichlorobenzoic acid) in extension growth tests arises from its inhibition of transport of endogenous or added auxin out of the sections, rather than from its intrinsic auxin activity. Chemically induced apolar callus growth on vascularized tobacco stem explants can arise from inhibition of native auxin transport, apolar growth stimulation by auxinic action of the test compound, or both.     

Toward the production of artemisinin through tissue culture: Determining nutrient-hormone combinations suitable for cell suspension cultures

Summary Artemisia annua L. is the source of a potent antimalarial, artemisinin. As part of a program to produce artemisinin through tissue culture, a series of 14 multifactorial experiments were conducted to determine suitable conditions for initiating and maintaining friable callus fromA. annua. In the first six experiments, three different nutrient formulations [Gamborg B5 (B5), Murashige and Skoog (MS), and Whetmore and Rier (WR)], each with 32 combinations of auxins and cytokinins [2,4-dichlorophenoxyacetic acid (2,4-D) with benzyladenine (BA), or 1-naphthaleneacetic acid (NAA) with 6-furfurylaminopurine (kinetin)], were tested. Both B5 and WR nutrients supported friable callus formation from leaf explants with some combinations of auxin and cytokinin. Inasmuch as friable callus seemed to be produced over a wider range of auxin and cytokinin concentrations in combination with B5, the remaining experiments were conducted solely with this nutrient formulation. In the remaining eight experiments, it was determined that friable callus formed when combinations of NAA with kinetin or 2,4-D and BA were used with B5 medium. Lighter colored, more friable callus formed in response to 2,4-D and BA than with NAA and kinetin. No single combination of concentrations of auxin and cytokinin seemed to be &#x201C;ideal&#x201D; for producing friable callus. Ranges of 2,4-D from 0.5 to 2.0 with BA between 0.025 and 0.1, or NAA between 0.5 and 2.0 with kinetin between 0.5 and 1.0 mg/liter, produced acceptable results.     

Organogenesis in leafy spurge (Euphorbia esula L.)

Summary All parts of leafy spurge seedlings can be regenerated when isolated and placed onto B5 medium. One-centimeter isolated hypocotyl segments were tested successfully for their usefulness as a bioassay system by comparing the response of auxins, herbicides, and cytokinins. Indole-3-acetic acid (IAA) was the most effective auxin to stimulate root formation. IAA was effective whether the hypocotyl segments remained on the same medium up to 60 days, or the segments were transferred to basal media after 2 or 5 days (pulse treatment). Pulse treatments with the other auxins resulted in stimulation of root formation; continuous or 5-day pulses of higher concentrations of indole-3-butyric acid,&#x03B1;-naphthaleneacetic acid and especially 2,4-dichlorophenoxyacetic acid and picloram formed excessive callus instead of roots. Picloram did not stimulate root formation, whether the treatment was continuous or pulse-treated. No roots formed with continuous picloram at 0.1 mg/liter or greater, but transfer to basal media did result in root and shoot formation at about 50% of the number formed on the controls. Lesser picloram concentrations had no effect. Shoots formed readily on untreated (control) segments, but continuous treatment with all three cytokinins, kinetin, zeatin, and zeatin riboside, increased the numbers of shoots about equally. Root formation was inhibited by the cytokinins at the higher concentrations (0.1 to 0.2 mg/liter). With the exception of a 5-day pulse of 0.04 mg/liter IAA, the auxins did not stimulate shoot formation, but generally inhibited shoot formation, even in pulse-treated cultures.