Correlation between induction of auxin-nonrequiring tobacco calluses and increase in inhibitor (s) of IAA-destruction activity

Decreased IAA-destruction activity by tobacco calluses (T22and XD6S2) was observed only when the calluses were culturedon a medium favorable for auxin-nonrequiring callus induction.The medium used to induce auxin-nonrequiring calluses from auxin-requiringones contained 0.1 mg/liter IAA for callus T22 and 10 mg/literNAA for XD6S2. It was clearly demonstrated both in vivo andin vitro that the result was not due to decreased IAA-destroyingenzyme activity itself, but to the increase of an inhibitor(s)of IAA-destruction activity. The accumulated inhibitor(s), whichinduced a lag in IAA oxidation, was a heat-stable low molecularweight substance(s), unstable in air at room temperature. The possible involvement of an inhibitor(s) of IAA-destructionin the process of induction for auxin-nonrequiring calluseswas discussed. (Received July 15, 1978; )     

Effects of cytokinins on the auxin requirement and auxin content of tobacco calluses

High concentrations (0.1–1 mg/liter) of kinetin permittedcontinuous growth of auxin-requiring and cytokinin-nonrequiringtobacco calluses on a medium without auxin. This effect of kinetindid not seem to be due to perpetuating change in the tissuecharacter, because tissue was auxin-requiring when returnedto a kinetin free medium. Cytokinins, i.e. benzylaminopurineand geranylaminopurine, showed the same effect as kinetin inmaking auxin-requiring calluses grow without a supply of auxin. In auxin-requiring and cytokinin-nonrequiring calluses subculturedfor 3 years on a medium containing 1 mg/liter kinetin withoutauxin, at least 3 auxins were detected by bioassay; 2 in theacidic and 1 in the neutral fraction. One was identified asIAA by paper chromatography (bioassay), thin-layer chromatographyand gas chromatography. Reduced or no auxin activity was foundin calluses transferred to a medium without kinetin. Kinetinwas apparently required to maintain the endogenous auxin levelin callus tissues. Kinetin may act on the auxin requirement of callus via its effectson auxin metabolism. ¹ Part XVI in the series "Studies on Plant Tissue Cultures". (Received April 11, 1972; )     

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)     

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.     

Micropropagation of Indian Rosewood by Tissue Culture

Multiple shoots were induced on excised hypocotyl segments andshoot tips of in vitro germinated seedlings of Indian rosewood(Dalbergia latifolia) on Murashige and Skoog's medium supplementedwith cytokinins and auxins. Roots were induced when individualshoots were treated first with half strength MS medium supplementedwith NAA, IAA and IBA (1 mg 1^–1 each) and subsequentlytransferred to hormone-free half-strength MS medium. The plantletswere then transferred to pots and grown in the greenhouse. Dalbergia latifolia, micropropagation, tissue culture, clonal propagation     

Somatic Embryogenesis and Plant Regeneration from Inflorescence Culture of Java Citronella: (Cymbopogon winterianus)

Embryogenic callus was induced from immature inflorescence segmentsof Java citronella (Cymbopogon winterianus) and maintained for2 years on Murashige and Skoog's medium supplemented with 2,4-D(l mg l^–1). The callus cells retained the original chromosomenumber of 2n = 20. The somatic embryos germinated into plantletson MS basal medium or medium with IAA, NAA, BAP or KN individually(l mg l^–1). The regenerated plantlets developed a goodroot system on full strength solid MS inorganics medium withIAA (1 mg l^–1). The regenerated plants were similar tothe donor plant in morphology and had the same chromosome number,but showed some variation in the essential oil content. Java citronella, Cymbopogon winterianus, somatic embryogenesis, regeneration, inflorescence culture     

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.     

Somatic Embryogenesis and Its Hormonal Regulation in Tissue Cultures of Freesia refracta

Somatic embryogenesis can be induced in tissue cultures of Freesiarefracta either directly from the epidermal cells of explants,or indirectly via intervening callus. These two pathways ofsomatic embryogenesis can be controlled and regulated by varyingthe combinations and levels of exogenous hormones. When younginflorescence segments were cultured in vitro on modified N₄(MN₄) medium supplemented with 2 mg l^–1 indoleacetic acid(IAA) and 3 mg l^–1 6-benzylaminopurine (BAP), some ofthe epidermal cells began to exhibit the features of embryogeniccells. These cells produced embryoids and developed into newplants through direct somatic embryogenesis. If the same explantswere placed on Murashige and Skoog's (MS) medium containing2 mg l^–1 IAA, 05 mg l^–1 BAP and 05 mg l^–1naphthaleneacetic acid (NAA), pale-yellow translucent nodularcalluses appeared on the surface of the explants. When thiskind of callus was transferred to MN6 medium with 2 mg l^–1IAA and 3 mg l^–1 BAP, embryoids formed which further developedinto plantlets. The regenerated plants were morphologicallynormal and possessed the normal diploid chromosome number of2n = 22. A similar result has also been obtained with youngleaf explants of this plant. The early segmentations of embryogeniccells and the development of embryoids were studied using histologicaland scanning electron microscopic techniques, and the resultshave been discussed in association with the ontogeny and originof the embryoids. Freesia refracta Klatt, somatic embryogenesis, plant regeneration, exogenous hormones     

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).     

Effect of Some Known Growth Regulators on Growth and Fertility in Male Clones of the Moss Microdus brasiliensis (Dub.) Ther.

Among the auxins (IAA, 2,4-D, NAA and NOA) LAA proves inhibitoryfor antheridial formation. The rest promote this response, andNAA is most effective. Cytokinin (2iP) stimulates vegetativegrowth as well as antheridial formation, but the effect is morepronounced on the former. Interaction of kinetin and IAA provesbetter for antheridial production as compared to IAA alone.Gibberellic acid enhances gametangial induction as well as vegetativegrowth at lower levels (10^–8–10^–8 mol dm^–3).With abscisic acid both the responses are markedly reduced.Anti-auxins and cycocel promote antheridial production and vegetativegrowth. Testosterone is more potent than progesterone in promotingantheridial formation and vegetative growth. Key words: Fertility, growth hormones, moss     

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     

Callus, Organogenesis and Plantlet Formation in Tissue Cultures of Clitoria ternatea

Decoated seeds of Clitoria ternatea L. germinated on Murashigeand Skoog (Physiologia Plantarum 1962, 15, 473–97) basalmedium (BM) and differentiated callus and bipolar embryoids(two-step method) in low frequency. Calluses developed on lateralroots [BM+KN(0.1 mg 1^–1)], on roots and hypocotyls [BM+KN(0.5mg 1^–1)], and on roots [BM+KN+IAA (0.5 mg 1^–1 ofeach)]. On basal medium with KN (0.5 mg 1^–1) and withKN+IAA (0.5 mg1^–1 of each), multiple shoot buds and embryoids(one-step method) were differentiated directly on split hypocotylsand roots. In the former, shoot buds developed even on unsplithypocotyls. Rhizogenesis on isolated shoot buds occurred efficientlyin BM+indole butyric acid (IBA 0.1 mg 1^–1) and BM+IAA(0.1 mg 1^–1 and 0.5 mg 1^–1). Profuse direct embryoidsand shoot buds developing on root systems are interesting morphogeneticphenomena rarely reported. Clitoria ternatea L., callus, embryoids, multiple shoot buds, regeneration     

Direct Organogenesis from Petiole and Thin Cell Layer Explants in Sugar Beet Cultured In Vitro

Detrez, C., Tetu, T., Sangwan, R. S. and Sangwan-Norreel, B.S., 1988. Direct organogenesis from petiole and thin cell layerexplants in sugar beet cultured in vitro.—J. exp. Bot.39: 917–926. Plant regeneration was obtained by direct bud formation frompetiole as well as from thin cell layer explants taken fromsugar beet (Beta vulgaris L.) plants grown in vitro. The budswere mainly induced in the blade-petiole transition zone ofthe explants. High frequency bud regeneration was observed inpetiole and thin layer explants of 10 different breeding linesof sugar beet tested. Organogenesis resulted when petiole explantsexcised from 8-d-old seedlings grown on half-strength Murashigeand Skoog medium (MS) containing 3.0 mg dm^–3 naphthaleneacetic acid (NAA), 3.0 mg dm^–3 6-benzylaminopurine (BAP)and 1.0 mg dm^–3 2, 3, 5, triiodobenzoic acid (TIBA) werecultured on MS with 3.0 mg dm^–3 NAA and 3.0 mg dm^–3BAP. Thin cell layer strips isolated from shoot apices culturedon MS medium supplemented with 0–9 mg dm^–3 BAP or1.0 mg dm^–3 indolebutyric acid (IBA) formed adventitiousbuds on MS medium containing 0–5 mg dm^–3 NAA + 5.0mg dm^–3 BAP. Histological studies confirmed the sub-epidermalorigin of shoots. Key words: Beta vulgaris, direct organogenesis, in vitro culture, petiole, regeneration, thin cell layer     

Somatic Embryogenesis from Clonal Leaf Tissues of Cassava

Leaf lobes were isolated from palmate leaves of clonal cassava(Manihot esculenta Crantz) material growing in vitro or in glasshouseconditions and subjected to a two-stage culture procedure involvingincubation on Murashige and Skoog (MS2) basal medium supplementedwith 2–12 mg l^–1 2,4-D for 20 d (Stage I) beforetransfer to MS2 basal medium supplemented with 0.01 mg l^–12,4-D and 0.1 mg l^–1 6-benzylamino purine (BAP) (StageII medium). Embryogenetic tissues, foliose structures and somatic embryosdeveloped from leaf lobes at all Stage I 2,4-D concentrations,except on those explants isolated from shoot-tip cultures incubatedon MS2 basal medium supplemented with 0.1 mg l^–1 NAA and1.0 mg l^–1 BAP. Leaf lobes isolated directly from glasshouse plants showed optimalembryogenetic competence when subjected to a Stage I cultureperiod of 17 d, although foliose structure initiation was optimalwith shorter Stage I durations. Leaf lobes of 2–4 mm lengthand those isolated from phyllotaxic leaf numbers 4 and 5 showedthe greatest embryogenetic competence. Manihot esculenta, cassava, somatic embryogenesis, tissue culture, morphogenetic competence     

Morphogenesis in Cultured Floral Parts of African Violet

Callus tissue was induced from floral parts of African violetcultured on MS medium containing NAA (2 mg I^–1) and BAP(0.2 mg I^–1). When maintained on this medium in the presenceof light, the callus produced many shoots and roots. Large numbersof adventitious shoot buds were formed apparently in the absenceof callusing when ovary, sepal, and petal tissue was culturedon MS medium supplemented with BAP (1 mg I^–1) and NAA(1 mg I^–1). In contrast, culturing the same floral partson MS medium augmented with kinetin (1 mg I^–1) and NAA(0.5 mg I^–1) and NAA (0.5 mg 1-¹) led to the profuse developmentof roots. Organs seemed to be initiated from the epidermis ofcultured floral parts and did not appear to be related to particularcells or loci. Transfer of shoots to MS medium deviod of growthsubstances resulted in the formation of plantlets, which ata height of 3 cm could be transferred to soil and grown to maturitywithout variation in morophology or cytology.     

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,α-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.     

High frequency somatic embryogenesis and plant regeneration in root explant cultures of carnation

Root explants excised from carnation plants maintained in vitro formed off-white, friable calluses after three weeks of culture on Murashige and Skoog (MS) medium supplemented with 1 mg l⁻¹ thidiazuron (TDZ) and 1 mg l⁻¹ α-naphthalaneacetic acid (NAA). These calluses were subsequently transferred to MS basal medium where, after an additional four weeks of culture, approximately 50% of the calluses formed somatic embryos. However, calluses formed on root explants that had been cultured on MS medium supplemented with 2,4-dichlorophenoxyacetic acid did not produce somatic embryos upon transfer to MS basal medium. Somatic embryos developed into plantlets and subsequently were grown to maturity. These results indicate that root explants have a high competence for somatic embryogenesis in carnation. J. Seo and S.W. Kim contributed equally to this work.     

Differential Responses of Buckwheat Leaf Cells to Growth Substances Stimulating Cell Division

Isolated buckwheat cotyledons form calli, roots or buds whencultured in an appropriate medium. A medium containing high2,4-D (5 mg 1^–1) and low KN (01 mg I^–1), which inducescallus formation, was found to stimulate cell division in thelayer between palisade and spongy parenchyma tissue after 72h. Low 2,4-D and low KN (01 mg I^–1 each), which stimulatesroot formation in buckwheat cotyledons, induces divisions primarilyin spongy parenchyma cells. In a high benzylaminopurine (10^–5M) and a low IAA (10^–6 M) medium, which favours bud induction,cell divisions were localized to the palisade layer. The differentialresponsiveness of leaf cells to various hormone treatments isdiscussed.     

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.