HORMONAL REGULATION OF EPIPHYLLOUS BUD RELEASE AND DEVELOPMENT IN BRYOPHYLLUM CALYCINUM

The effects of various concentrations of several auxins and cytokinins separately and in combination on epiphyllous budding of Bryophyllum calycinum were investigated, using a marginal leaf strip method. The number of buds released per leaf in 10⁻⁶ m benzyladenine (BA) was 2.8 times greater than those in water, and 1.6 times greater in 10⁻⁵ m isopentyladenine (IPA). BA, IPA and kinetin were antagonistic to indoleacetic acid (IAA) or naphthaleneacetic acid (NAA) when used in combination treatments. The IAA oxidase co-factor p-coumaric acid (PCA) increased the number of epiphyllous buds to twice that of the water controls. This stimulatory effect of PCA on bud release suggests that an increase in IAA oxidase activity may be one of the significant changes that precedes the release of epiphyllous buds.     

Interaction of gibberellic acid and photoperiod in the development of epiphyllous buds inBryophyllum tubiflorum

The effect of GA₃ on the initiation and the development of epiphyllous buds inBryophyllum tubiflorum exposed to different photoperiods was studied. It was observed that although the bud primordia were initiated under both photoperiods, they developed as epiphyllous buds only under theLD condition. GA₃ did not affect the magnitude of bud development underSD and inhibited it under theLD condition.     

Non-Reversibility of Gibberellin-Induced Inhibition of Regeneration in Begonia Leaves

With applied to the petioles of detached Begonia x cheimantha leaves before planting, Gibberellic acid (GA₃) inhibited the formation of adventitious buds and roots ill an apparently irreversible manner. Bud formation was entirely suppressed by 10^?6M and higher concentrations and a significant inhibition was still present at 10^?9M the lowest concentration tested. Root formation was not affected by GA₃ below 10^?7M and was possible even at 10^?4 M GA₃. Petiole elongation was stimulated by GA₃ with an optimum at 10^?5M. GA₃ also blocked the action of 6-benzyiamino-purine (BAP) and 1-naphthaleneacetic acid (NAA), compounds which are potent stimulators of bud and root formation, respectively. When applied simultaneously with GA₃ they were, at their optimal concentrations, devoid of any effect in counteracting or reversing the gibberellin-induced inhibitions. Abscisic acid and the growth retardants CCC and Phosfon also were unable to restore bud and root formation. In leaves initially treated with water or 10^?5M BAP, endogenous bud and root formation as well as BAP-induced bud formation were entirety suppressed when 10^?5M GA₃ was applied 8 days after the initial treatments. Even when delayed for 14 days GA₃ treatment inhibited BAP-induced bud formation, while treatment after 21 days bad little effect on bud and root formation. Development of pre-existing, visible bud primordia was not inhibited by GA₃. BAP and NAA competitively inhibited the action of GA₃ in petiole extension growth. The results are discussed in relation to results obtained in other plant systems. It is suggested that GA₃ acts by blocking of the organized cell divisions initiating the formation of bud and root primordia.     

GROWTH REGULATOR EFFECTS ON BUD INITIATION IN CALLUS CULTURES OF MEDICAGO SATIVA

Influence of growth regulators on bud initiation in callus of alfalfa (Medicago sativa L.) was studied by varying levels and combinations in the first medium of a two-medium sequence used to obtain whole plants. Callus of tetraploid clone S-4 (cv. ‘Saranac‘) was initiated from immature ovaries on a modified Blaydes' basal medium containing all combinations of six concentrations (0–36 μM) of kinetin (K), six concentrations (0–44 μM) of naphthaleneacetic acid (NAA), and seven concentrations (0–36 μM) of 2,4-dichlorophenoxyacetic acid (2,4-D). After 28 days the callus was challenged to form buds by transfer to the modified Blaydes' medium containing 2.0 g/liter yeast extract and 0.57 mM inositol. No buds were produced in the absence of 2,4-D in the first medium, and the frequency of bud formation on the second medium was directly proportional to the 2,4-D concentration in the range 2.3–54 μM in the preceding medium. Buds were produced in the absence of kinetin in the first medium, but its presence in the range 2.3–36 μM markedly increased bud formation. NAA was not required for bud formation, and the budding frequency increased only slightly with increasing NAA concentration in the first medium. Budding of callus of two other alfalfa clones was also influenced by the 2,4-D concentration in the initial medium. There were several indications that many of the buds were initiated on the first medium and completed development on the second medium. These included the differential effect on budding of combinations of 2,4-D, NAA and kinetin in the callus initiation medium, the specific media sequence required, and the presence of embryoids on the callus which after transfer to the yeast extract-inositol medium produced buds.     

Axillary Bud Inhibition Induced by Young Leaves or Bract in Euphorbia pulcherrima Willd

In plants held under long days in the vegetative stage, youngexpanding leaves of poinsettia (Euphorbia pulcherrima Willd.‘Brilliant Diamond’) are the main source of axillarybud inhibition, while the apical bud, which includes the meristem,primordial leaves and small unfolded leaves, is a secondaryinhibition source. Removal of these expanding leaves resultedin rapid release and growth of axillary buds. Decapitation ofthe apical bud resulted in delayed axillary bud release. Inreproductive plants kept in short days, the pigmented bractsare the primary source of axillary bud inhibition and the cyathiaare the secondary source. Applications of NAA —substitutedfor both young leaves and bract inhibition — maintainedapical dominance. The concentration of endogenous auxin washighest in the apical bud. However, when calculated on wholeorgan basis the auxin level was greater in young developingvegetative leaves and in reproductive bracts than in the apicalbud. Euphorbia pulcherrima Willd, apical bud, apical dominance, auxin, correlative inhibition, cyathia, poinsettia, IAA, NAA     

Regeneration in Streptocarpus Leaf Discs and its Regulation by Temperature and Growth Substances

The formation of adventitious buds and roots in leaf discs of Streptocarpus x bybridus‘Constant Nymph’ were both stimulated by relatively low temperatures (12 and 18°C) applied to isolated discs or to the growing plants before leaf harvest. Auxins also promoted both bud and root formation, the optimum concentration for rooting always being one to two orders of magnitude higher than the optimum for budding. Cytokinins had only a small stimulatory effect on bud formation. At higher concentrations it was inhibitory and even counteracted the stimulatory effect of auxin on bud formation. As usual, root formation was inhibited by cytokinin. GA₃ inhibited both bud and root formation but the inhibition was reversible by auxin. In presence of optimum auxin levels abscisic acid enhanced bud formation. It had little effect on root formation except for an inhibition at high concentrations. The effects of exogenous auxin and cytokinin suggest that Streptocarpus leaves have a high and non-limiting level of endogenous cytokinin with auxin as the limiting factor for both root and bud formation. This would also explain the exceptionally high regeneration ability of this plant.     

Rapid in vitro propagation of Aloe barbadensis Mill

Axillary bud development and adventitious bud formation was obtained with decapitated shoot explants of Aloe barbadensis Mill. Maximal bud growth and rooting of shoots was obtained on a modified medium of Murashige and Skoog supplemented with 5 M IBA. More adventitious and axillary buds developed on nutrient media supplemented with IBA than with NAA. Axillary buds but not adventitious buds developed with IAA in the medium. Morphogenesis was inhibited by 2,4-D. Kinetin, benzyladenine and thidiazuron were toxic to the explants and did not stimulate the development of axillary of adventitious buds. The optimal temperature for bud growth and development was 25°C. Axillary bud growth and the formation of adventitious buds was slowed down at 10°C and totally inhibited by 30°C. The optimal sucrose concentration was 3% with the inhibition of bud growth and development by higher sucrose levels.     

SCLEREID DISTRIBUTION IN THE LEAVES OF PSEUDOTSUGA UNDER NATURAL AND EXPERIMENTAL CONDITIONS

Al -talib , Khalil H., and John G. Torrey . (U. California, Berkeley.) Sclereid distribution in the leaves of Pseudotsuga under natural and experimental conditions. Amer. Jour. Bot. 48(1): 71–79. Illus. 1961.—A study of the distribution of sclereids in cleared leaves taken from 1-, 2-, and 4-year-old shoots of an adult tree of Pseudotsuga menziesii (Mirb.) Franco showed a repeated pattern of sclereid distribution along the shoot axis with many sclereids in the basal leaves grading into few or no sclereids in the terminal leaves of each year's growth. Attempts were made to influence sclereid distribution by bud defoliation of attached branches with and without auxin treatment and by testing the effects of growth-regulating substances on sclereid formation in leaves of excised buds of Pseudotsuga cultured in vitro. Whereas removal of the basal ¾ of the leaves at the time of bud unfolding had no effect on bud, leaf or sclereid development, removal of the leaves of the upper half or complete defoliation led to premature expansion of next year's terminal bud with leaves developing in part from presumptive bud-scale primordia. Indoleacetic acid at 0.5% in lanolin paste applied to the defoliated region prevented this premature bud expansion. Defoliation of the basal half did not affect sclereid formation in the terminal leaves. Sclereid development in leaves of prematurely expanded buds on defoliated branches was normal except in the few cases where bud expansion occurred in the presence of low-auxin concentrations. Then, sclereid development was inhibited. Sclereid formation in leaves of excised buds grown in nutrient culture was generally much less frequent than in intact branches, and auxin treatment still further reduced the frequency of sclereids. It was concluded that sclereid initiation and differentiation in the intact plant may well be under the control of hormonal factors in the plant, one of which may be auxin.     

Interaction of Growth Retardants and Temperature in Growth, Flowering, Regeneration, and Auxin Activity of Begonia × cheimantha Everett

Soil application of CCC reduced stem and leaf growth in Begonia plants. This effect was evident with all concentrations tested at 18°C, whereas at 21 and 24°C no growth–retarding effect was observed with 2 × 10^?2 M CCC, and with 5 × 10^?3 M growth was even stimulated. Flowering was promoted by CCC in long day and neur–critical temperature, particularly under low light intensity in the winter. The formation of adventitious buds in leaves of plants grown at 21 and 24°C was stimulated when the plants received 5 × 10^?2 and 2 × 10^?2 M CCC, while 8 7times; 10^?2 M was inhibitory. In plants grown at 18°C bud formation was inhibited by all CCC concentrations. Root formation in the the leaves was usually stimulated by high CCC concentrations, while root elongation was reduced. The level of ether–extractable. acidic auxin (presumably IAA) in the leaves was lowered by CCC treatment of the plants, hut this required higher CCC concentrations at higt than at low temperature. When applied to detached leaves CCC stimulated bud formation at concentrations ranging from 10^?4 to 10^?2 M in leaves planted at 18 and 21°C. At 24°C budding was inhibited by 10^?2 M CCC, the lower concentrations being stimulatory also at this temperature. Root formation and growth were not much affected by CCC treatment of the leaves, but increased with the temperature. Soil application of Phosfon (4 × 10^?4 M) had no effect on growth and flowering, nov did it affect the subsequent regeneration of buds and roots in the leaves. In detached leaves Phosfon stimulated bud formation with au optimum at 10^?6 M. Root formation was stimulated by Phosfon at all temperatures, the optimal concentration being 10^?5 M, whereas root length was conversely affected. Foliar application of B-995 to intact plants and treatment of detached leaves greatly inhibited the formation of buds and had little effect on root formation. B-99D reduced the growth and delayed flowering in the plants.     

Lithium ions interfere with pattern control in Hydra vulgaris

Summary LiCl in concentrations exceeding 0.5 mM affects morphogenesis in Hydra vulgaris (formerly named H. attenuata) by interfering with the foot-forming system(s). Pulse treatment of Hydra bearing small buds or of animals that develop a bud within 14 h after the end of treatment prevented foot formation at the bud's base in a concentration-dependent manner. With increasing concentrations of Li⁺ or length of treatment in increasing percentage of the buds remained permanently connected to the parent by a bridge of tissue thus forming a stable secondary axis. Instead of the normal ring-shaped foot a patch of basal disc tissue developed or the bud failed to differentiate foot tissue at all. Long-term culture of animals in 1 mM LiCl inhibited budding from the second day of treatment onwards and detachment of existing buds was delayed. After 4 days of treatment 15%–30% of budless or bud-bearing animals developed up to three patch-like basal discs at various positions along the body axis; these usually grew out one above the other on the same side of the animal but never at the same transverse level. Besides these patch feet broad belts of foot tissue were observed in the lower gastric region. After 1 week of treatment half of the animals developed a constriction located usually in the lower two-thirds of the body axis. The tissue adjacent to this constriction and particularly above it differentiated into mucus-secreting foot tissue. Subsequent separation into two morphologically intact polyps occurred occasionally. When treatment was stopped, budding restarted within the next 3 days at several positions along the body axis whether or not secondary feet or a constriction existed. Buds grew out in different budding zones, which persisted for several days. This burst of budding led to up to 7 buds per animal within 3 days. After about 1 week the animals regulated to normality or became epithelial, i.e. they lost their stem cells during and after treatment.     

Adventitious bud regeneration from leaf and cotyledon explants of Chinese hawthorn (<Emphasis Type="Italic">Crataegus pinnatifida</Emphasis> Bge. var. <Emphasis Type="Italic">major</Emphasis> N.E.Br.)

Hawthorn (Crataegus spp.) is an important plant with a long history as an ornamental and a source of medicine. A protocol is outlined for adventitious bud regeneration from leaf and cotyledon explants of Chinese hawthorn (C. pinnatifida Bge. var. major N.E.Br.). Adventitious buds were induced on both the leaves of sprouting winter buds and the leaves of in vitro plants, but the percentage of bud regeneration from leaves of in vitro plants was very low—less than 6%. On N6 medium supplemented with 31.08 μM BA and 9.67 μM NAA, the percentages of bud regeneration from leaves of sprouting winter buds of cultivars “Liaohong” and “Qiujinxing” were 31.4% and 17.6%, respectively. The regeneration abilities of three kinds of cotyledon explants, immature cotyledon, mature cotyledon, and cotyledon leaf, were compared. The percentage of bud regeneration from cotyledon leaves was higher. On MS media supplemented with 4.44 μM BA and 4.54–9.08 μM TDZ, the percentages of bud regeneration from cotyledon leaves of cultivars “Qiujinxing” and “Xiajinxing” were 27.7 ± 7.8% and 20.1 ± 4.7%, respectively, and the numbers of buds per explant were 5.9 ± 1.6 and 3.2 ± 0.7, respectively. On B5 medium supplemented with 2.22 μM BA, 2.32 μM Kn, and 0.57 μM IAA, adventitious buds grew quickly and 80–100% of buds developed into shoots. The shoots rooted successfully with the two-step rooting method. Ninety days after transplantation, more than 80% plants were survived. This system of adventitious bud regeneration from leaf and cotyledon explants could be useful for the genetic transformation and polyploidization of Chinese hawthorn.     

Influence of Several Growth Regulators and Amino Acids on in vitro Organogenesis of Torenia fournieri Lind.

The effects of several growth regulators and amino acids onin vitro organogenesis of Torenia fournieri Lind. were determinedusing internodal segments. Treatment with 2,4-D¹ resulted innodular callus formation, while NAA and IAA induced roots constantlybut much less frequently shoot buds. Individually BA, zeatin,and 4-PU induced bud formation, but these shoot buds did notdevelop further. Formation of buds by cytokinin was influencedby a simultaneous application of NAA or 2,4-D, but not of IAA,its degree being reduced when BA was simultaneously appliedwith NAA or 2,4-D. When zeatin or kinetin was added with NAA,numerous roots were induced. The effects of various L-amino acids on in vitro organogenesiswere also investigated using the defined medium in which KNO₃was a principal source of nitrogen. The formation of buds wasconsiderably stimulated by alanine and asparagine, and slightlyby glutamic acid in the medium containing both NAA and BA, inwhich bud formation was easily induced. On the other hand, allamino acids except for glutamic acid and aspartic acid inhibitedroom formation in this medium. Root formation was greatly stimulated by proline, alanine, glutamine,glutamic acid, and aspartic acid, and slightly by arginine andtryptophan in the medium containing NAA but no BA. Glutamicacid and aspartic acid also enhanced bud formation in this medium.     

The polarity of endogenous regulatory substances inBryophyllum crenatum leaves and stems

In isolated leaves ofBryophylluni crenatum the intensity of marginal bud formation decreases from the apex towards the blade base, which is associated with the decreasing content of enioganous gibberallins. As proved by Dostál (1930), the formation of marginal buds on transversely divided blade of the isolated leaf increases in comparison with the non-divided control leaf. The results of our experiments have revealed that the increase in the formation of marginal buds in the blade transversely divided into the apical, middle and basal parts is connected with the increasing level of endogenous gibberellins, especially in the apical part. This rising level appears as early as 7 days following blade division,i.e. at the time preceding the formation of marginal bud bases. InBryophyllum crenatum plants the level of endogenous cytokinins was estimated in apical, middle and basal leaves, as well as in adjacent internodia. Maximum content was found out in the leaves from the middle stem part, which is probably associated with the capacity of this part to form marginal buds spontaneously also in intact plants. However, prior to flowering the maximum of cytokinin activity is shifted to the apical stem part.     

Induction of adventitious buds in cultured petal explants ofChelidonium majus L.

Petal explants ofChelidonium majus L. (Papaveraceae) formed noteworthy adventitious buds without any intermediate callus when cultured under appropriate conditions. Bud formation was favored by combinations of 1–2 mg/l indoleacetic acid (IAA) and/or 2,4-dichlorophenoxyacetic acid (2,4-D) and 0.1–0.5 mg/l kinetin (K). In the present study, neither bud formation nor callus formation occurred in cultures of excised leaves. A histological study revealed that adventitious bud formation occurred only in single epidermal layers of petals, while several subepidermal parenchyma layers did not join in its formation. Activation zones arising from the epidermis underwent intense cell divisions to initiate buds on the epidermal surface. These buds later turned green in color, developing into shoots which eventually grew into plantlets after root formation.     

Role of hormones on flower bud formation in thin-layer expiants of tobacco

Flower bud formation was studied in thin-layer tissue expiants of epidermis plus subepidermal cortex from the inflorescence ramifications ofNicotiana tabacum cv. Samsun. With appropriate hormone concentrations of BA and NAA expiants from flowerv and fruitbearing stalks regenerate flower buds only, while those from the internodes of the inflorescence ramifications produce generative as well as vegetative buds. In both types of expiants the number of buds formed depend mainly on the hormone concentrations but, in addition, the age of stalks and internodes from which expiants are taken also affects bud formation. Both ABA and JA inhibit flower bud formation in expiants of flower stalks. JA was shown to particularly inhibit bud initiation.     

Differential Reactivity in Epidermal Cells of Begonia rex Excised and Grown in vitro

Thin explants composed of the epidermis and underlying collenchyma excised from leaf veins of Begonia rex and cultured in vitro are capable of neoformation of unicellular hairs, roots and buds. Unicellular hairs were formed over the entire surface of the explant when 10⁻⁶M indole acetic acid or 10⁻⁷M naphthaleneacetic acid (NAA) was added to the basal medium; each epidermal cell was potentially involved. The epidermis was most sensitive to a NAA treatment during the first few days of culture but 30% of the explants could still react after 4 days of culture without NAA. When NAA (5 × 10⁻⁷M) and a cytokinin, zeatin (10⁻⁷M), were added together, roots were formed from epidermal tissue after numerous divisions in the original cells. Their initiation was not related to particular cells. Buds were formed when a cytokinin (10⁻⁶M) was added to the basal medium; bud meristems were formed from small groups of cells surrounding basal cells of glandular hairs. Hair formation was inhibited by either high (32–27°C) or low (12°C) temperatures applied continuously. 32–27°C seemed to inhibit elongation of the hairs specifically, whereas 12°C inhibited earlier phases in hair formation. This hypothesis was supported by short temperature treatments applied at different times during hair formation.     

K-Nutrition, Growth Bud Formation, and Amine and Hydroxycinnamic Acid Amide Contents in Leaf Explants of Nicotiana tabacum Variety Xanthi n.c. Cultivated in Vitro

The effects of K-nutrition on growth (increase of fresh weight), bud formation (time of emergence, number of buds), and amine and hydroxycinnamic acid amide contents in foliar explants of Nicotiana tabacum cv Xanthi n.c. cultivated in vitro were examined. In K-deficient medium and in high K medium growth and bud formation were markedly inhibited. Marked changes of amine content (a diamine, putrescine; a phenolic amine, phenethylamine) were observed after a few days of culture. No apparent relationship was found between these amines and growth or bud differentiation. In contrast, changes in hydroxycinnamic acid levels were shown to correlate well with growth and bud formation. The greatest stimulation of budding and growth was correlated with the greatest accumulation of these amides. The highest contents of hydroxycinnamic acid amides were found during the first 15 days in culture when intensive cell division took place. Then they declined sharply after 26 days in culture as the rate of cell division decreased and differentiation occurred.     

Studies on the role of abscisic acid in the initiation of bud dormancy in Alnus glutinosa and Betula pubescens

Summary The effects of leaf-applied (+-)-abscisic acid on the growth and dormancy of Betula pubescens Ehrh. and Alnus glutinosa Gaertn. growing under long days provide no evidence that leaf-applied abscisic acid induces or promotes the formation of resting buds in these species. Radiotracer studies show that a small percentage of the radioactivity applied as [2-¹⁴C]abscisic acid to the leaves accumulates in the apical region of the shoot. Of the radioactivity that was recovered from this region after 8 days, less than 10% was chromatographically similar to [2-¹⁴C]abscisic acid. The significance of these results with respect to the role of abscisic acid in regulating the induction of bud dormancy is discussed.Abbreviation ABA abscisic acid     

Floral morphogenesis in thin-layer tissue cultures of Nicotiana tabacum

The morphological changes in thin-layer tissues of Nicotiana labacum L. cv. Samsun, cultured on Murashige and Skoog medium with 1 μ M each of naphthalene acetic acid (NAA) and benzyladenine (BA), were studied during the first 8 days of culture with light and scanning electron microscopy. The first three days of culture arc characterized by enlargement of all cells and cell divisions starling in the cortical parenchyma cells adjacent to the medium. Between days 3 and 6, epidermal and/or subepidermal cells start to divide, resulting in division centers, which lead to flower bud formation. The hormones NAA and BA in different concentrations affect the formation and distribution of flower buds, bud morphology and callus formation. BA influences particularly bud formation and bud morphology, while NAA affects callus formation in particular. In addition, polarity may occur in the formation of both callus and flower buds, the degree of which depends upon the hormone concentrations.     

Regeneration from Leaf Squares of Peperomia sandersii A .DC: a Relationship between Rooting and Budding

Evidence is presented to show that in leaf squares of Peperomiasandersii bud initiation does not occur independently of rooting.Buds were formed close to the point of origin of roots and,in treatments where rooting was delayed, budding was affectedsimilarly. Promotion of root formation by pretreatment of squareswith 3-indolylbutyric acid was accompanied by increases in thenumber of buds initiated. Kinetin and N⁶-benzyladenine whichinhibited the initiation of roots also inhibited the initiationof buds. This was in contrast to the effect of these two compoundson leaf squares of Begonia rex where rooting was similarly inhibitedbut bud initiation was markedly promoted. When leaf squaresof Peperomia were grown in contact with relatively high concentrationsof kinetin buds were occasionally formed in the absence of roots.Removal of roots from leaf squares of Peperomia by excisionprevented the formation of buds.