Effects of indoleacetic, p-chlorophenoxyisobutyric and 2,4,6-trichlorophenoxyacetic acids on three phases of rooting in Azukia cuttings

In adventitious root formation of disbudded epicotyl cuttingstaken from light-grown, 5-day-old Azukia angularis seedlings,indoleacetic acid (IAA), 1 x 10^–4 M, applied during thefirst day showed no effect, but enhanced the effect of IAA,1 x 10^–4 M, applied during the second day. Treatment duringthe second day promoted rooting by about 70%, and a combinationof treatments for the first and second days promoted rootingsome 200%. p-Chlorophenoxyisobutyric acid (PCIB), 3 x 10^–4M, and2,4,6-trichlorophenoxyacetic acid (2,4,6-T), 2 x 10^–44M, applied the first day also enhanced the effect of IAA, 2x 10^–4 M, applied the second day. When applied the second day, PCIB, 2 x 10^–4M, increasedthe number of root primordia or clusters of small cells, butnot die number of protruded roots. Formation of the cell clusterwas inhibited by 2,4,6-T, 3 x 10^–4M, applied the secondday. Rooting processes in Azukia cuttings seem to include at leastthree phases: the first phase is induced not only by IAA butalso by PCIB or 2,4,6-T, the second phase is induced by IAAor PCIB and the diird phase depends specifically on IAA. (Received October 28, 1970; )     

Anatomical and physiological aspects of developmental processes of adventitious root formation in Azukia cuttings

In Azukia stem cuttings, root primordia always appeared in theinterfascicular regions between the endodermis and the interfascicularcambium. Transverse cell divisions were observed as the first eventsin the process of root formation. They began to occur 10 hrafter cuttings had been made and were restricted to the interfascicularregions about 1 mm above the basal cut end of the cutting. Ineach of interfascicular region, 10 to 20 cells divided. Transversedivisions were followed by longitudinal divisions, which beganto occur 18 hr after cuttings had been made. The early process of root primordium formation is distinguishedby the following three phases: the first phase during whichno cell division occurs (0–8 hr), the second phase duringwhich transverse cell divisions occur (8–16 hr) and thethird phase during which longitudinal divisions occur (16–24hr). Cuttings in each phase responded differently to test substances. ¹Supported in part by Grant No. 139011 from the Ministry ofEducation, Japan. ² Present address: Junior College of Toyo University, Hakusan,Bunkyo-ku, Tokyo 112, Japan. (Received October 24, 1977; )     

Abscisic-acid-stimulated rooting of stem cuttings

Summary Abscisic acid (ABA) has been found to stimulate rooting of stem cuttings of mung beans and English ivy. ABA partially overcame the inhibitory effect of gibberellic acid on root formation of mung bean cuttings but at the concentrations used did not overcome the inhibitory effect of kinetin on root formation.     

Auxin effects on rooting in pea cuttings

Light-grown stem cuttingss of Pisum sativum L. cv. Weibull's Marma were rooted in a nutrient solution. The presence of 10 μ M indolylacetic acid (IAA) in the solution for 24 h or longer periods decreased the number of roots subsequently formed to about 50% of control, provided IAA was present in the solution during any of the 4 first 24 h periods. Treatment for 6 h or shorter periods caused no or small response. IAA did not appreciably change the time needed for root formation, the time course of root appearance or the pattern of root distribution along the basal internode. IAA at 100 μ M usually increased the number of roots although variable results were obtained with this IAA concentration.
The number of roots was strongly increased by treatment with indolylbutyric acid (IBA) or 2,4-dichlorophenoxyacetic acid (2,4-D). None of these or other synthetic auxins decreased the number of roots in suboptimal concentrations. Experiments with 10 μ M IBA showed that stimulation of rooting was obtained only if the auxin was present in the rooting solution for several days. Simultaneous treatment with IAA decreased the stimulating effect of IBA to some extent, whereas no such response was obtained if IAA was combined with 2,4-D.
IAA applied in lanolin to the stem of intact cuttings decreased the number of roots formed. Decapitation and debudding of the cuttings decreased the number of roots formed. If at least 2 leaves were left this decrease was efficiently counteracted by an optimal IAA dose applied to the upper part of the stem. A five times higher dose was less effective, indicating a negative effect on rooting also by IAA applied to the shoots.     

The nature of the dual effect of auxin on root formation in Azukia cuttings

In disbudded Azukia stem cuttings, auxin exerted a dual effecton root formation. The first phase of auxin action is identifiedwith the acceleration of cell division, especially longitudinaldivision. In cuttings treated with auxin during the first 24hr, longitudinally divided cells were observed in all 12 rootprimordia, while in water-treated cuttings, such cells wereobserved only in 8 root primordia. The second phase is the promotionof the reaction in which root primordia unable to develop furtherwithout auxin supply develop into roots. Irrespective of thetreatment during the first 24 hr, the auxin-treatment duringthe second 24 hr increased the number of roots protruding fromthe cuttings. Portulal applied during the first 24 hr increased the numberof root primordia which contained longitudinally divided cells.Gibberellin applied during the first 24 hr inhibited both transverseand longitudinal divisions in root primordia. ¹ Supported in part by Grant No. 139011 from the Ministry ofEducation, Japan. ² Present address: Junior College of Toyo University, Hakusan,Bunkyo-ku, Tokyo 112, Japan. (Received June 13, 1978; )     

Interaction of abscisic acid and auxins in rooting of cuttings

Abscisic acid (ABA) at optimum concentrations promoted rootingof Phaseolus aureus ROXB. and Lycopersicon esculentum MILL,stem cuttings. In combination with IAA (indole-3-acetic acid)ABA has mostly given additive effects. Synergistic effect ofABA was noted on IBA (-indolebutyric acid)-induced rooting ofLycopersicon cuttings. Rooting of Phaseolus vulgaris L. cuttingscompletely failed when ABA (50 mg/liter) was applied in combinationwith IBA or NAA (-naphthaleneacetic acid). The results suggestthat abscisic acid may be an important natural regulator ofrooting in cuttings. (Received March 19, 1970; )     

Clonal differences in rooting ofAlnus incana leafy cuttings

Summary Green cuttings ofAlnus incana (L.) Moench, consisting of one internode and one leaf with its axillary bud, were easily rooted in aerated liquid substrate under growth-chamber conditions. In tests on material of up to 8 years-old, the age of the stock plants was shown to have no influence on rooting. Tap water or a diluted nutrient solution gave higher rooting percentages than a full strength nutrient solution. Root growth was most rapid in the diluted nutrient solution. Eight out of 9 clones ofA. incana gave a rooting percentage of 80–100% while one clone gave only 40%. Good rooting ofA. incana leafy cuttings, therefore, seems to be genetically controlled.     

The effects of a fogging system on the physiological status and rooting capacity of leafy cuttings of woody species

The early responses of leafy stem cuttings of Prunus and Castanea species with differing rooting abilities were assessed in a fog system using fluorescence measurements. Different types of cuttings of each species were used: cherry Prunus (‘GiSelA 5’, Prunus cerasus × Prunus canescens—148/2) and chestnut Castanea (‘Marsol’ and ‘Maraval’, Castanea crenata × Castanea sativa). The physiological status of cuttings in the early initiation phase was compared to the rooting results. For all cuttings, fluorescence measurements revealed a close-to-optimum photochemical efficiency, indicating that physiological stress (severance, water, etc.) was minimal. In cherry, the potential photochemical efficiency (Fv/Fm) differed slightly between terminal and basal cherry cuttings, being lower in the basal ones at the time of severance. Later in the propagation process, the differences were smaller. The photochemical efficiency did not differ between two ‘difficult-to-root’ Castanea clones, nor was it dependent on the length of the cuttings. The high rooting capacity of long Castanea cuttings (50 cm) indicated that physiological stress could be minimized under a fogging system. An erratum to this article can be found at     

Conditions for rooting of leafy cuttings of Alnus incana

The rooting of softwood cuttings of Alnus incana (L.) Moench in nutrient solution was studied under controlled conditions. Cuttings consisting of one internode with the leaf and axillary bud attached rooted easily and more rapidly than shoot tip cuttings. Light was necessary for rooting but good rooting was obtained in photon flux densities of both 40 and 190 μmol m^-2s^-1. Root number and root length was reduced when light reached the base of the cuttings. Treatment with indolebutyric acid (10^-6–10^-4M) increased the number of roots but 10^-4M delayed rooting and decreased the root length. Debudded internode cuttings rooted as well as intact cuttings, and detached leaves also contained sufficient substances for rooting.     

Methyl gallate and its 3-glucoside promote rooting in bean cuttings

Methyl gallate stimulated adventitious root formation in cuttings of bean (Phaseolus vulgaris L.). This polyphenol was quickly metabolized into 3-glucosyl methyl gallate to such an extent that 4 h after application no methyl gallate was detected. The isolated glucoside when supplied exogenously at 0.5 mM also enhanced rooting; the effect was 2-fold greater than that of methyl gallate. The glucoside persisted in the cuttings for 72 h after treatment. Because methyl gallate is rapidly transformed to a stable glucoside, we suggest that the root stimulation effect could be ascribed to its glucoside.     

Morpho-anatomical and biochemical changes associated with rooting of micropropagated ninebark cuttings

Ninebark (Physocarpus opulifolius) is an attractive ornamental shrub with poor rooting characteristics in some cultivars, which is a limiting factor in commercial production This study was designed to optimize rooting conditions of ninebark cuttings and to observe the effect of exogenous auxin IBA on some morpho-anatomical and biochemical changes associated with rhizogenesis in the in vitro conditions. Both auxins under study: the indole-3-butyric acid (IBA) and 1-naphthalene acetic acid (NAA) gave comparable effects but the combination of ½ MS?+?1 mg·L^?1 IBA was the most cost effective for all rooting parameters. Anatomical changes at the cuttings’ bases during root formation were typical for woody plants and they were accelerated by auxin in the culture medium. High levels of the endogenous indole acid and hydrogen peroxide were temporarily associated with intensive cell divisions in cuttings, and the polyphenolic acid contents kept increasing during rooting above the initial levels and those in controls.

     

Effect of some benzyl alcohols on rooting of bean cuttings

The root differentiating properties of various benzyl alcohols were studied using a bean rooting test. The results showed that the methoxy derivatives enhanced rooting more efficiently than did the hydroxy derivatives. Only 4-hydroxybenzyl alcohol inhibited rooting, but the addition of IAA at 10^?5M nullified the inhibition. Root promotion by the alcohols with a hydroxy group in the o-or p-position was increased by the addition of IAA. Auxin did not modify the rooting stimulation caused by the methoxy derivatives. The position of the methoxy group did not influence the rooting activity.     

微域环境因子对落基山圆柏插穗生根的影响

以8年生落基山圆柏(Juniperus scopulorum)的嫩枝为试验材料, 采用不同扦插密度和基质等处理措施, 研究了微域环境因子对插穗生根的影响。结果表明, 两种不同扦插密度的生根部位、愈伤率、生根率、炼存率、生根效果指数(root effect index, REI)、离散度指数(rooting dispersion index, RDI)和分形特征均存在显著差异。综合分析生根率、炼存率、REI和RDI等发现, 密插处理的效果好于稀插, 稀插处理的插穗生根能力较差, 生根性状离散度较大。密插处理的插穗的根系平均分形维数是稀插处理的1.24倍, 两者差异极显著(p < 0.01)。不同扦插密度下插穗的生根部位和生根机制不同: 插穗在密插处理下形成诱生根, 在稀插处理下形成原基根。不同的扦插密度造成了落基山圆柏微域环境的显著差异, 但同一密度下不同基质种类对微域环境因子的调控作用有限。密插处理下插穗的微域环境相对湿度较高(最高可达83.5%), 温度较低, 光合有效辐射较小。这些环境因子的差异导致密插处理下插穗的净光合速率(P_n)较高, 蒸腾速率(T_r)较低。在0-60天内, 密插和稀插处理的插穗的P_n均呈上升趋势, 并且二者相差的幅度随着试验时间的延长而迅速增大; 在60天以后, 二者均呈下降趋势, 相差幅度基本保持不变。密插处理下的T_r值在0-30天内基本保持不变, 而此时稀插处理下的T_r迅速增加。在30-60天内密插处理下的T_r快速增加, 60天时达到最大值, 但仍低于稀插处理。这些结果表明, 外部微域环境因子对插穗生根的影响是通过影响其内在生理指标来实现的, 插穗营养状况的差异是造成生根机制不同的主要原因。     

Metabolic changes during rooting in stem cuttings of five mangrove species

Vegetative propagation through rooting in stem cuttings in five tree mangroves namely Bruguiera parviflora, Cynometra iripa, Excoecaria agallocha, Heritiera fomes, and Thespesia populnea using IAA, IBA and NAA was reported. Spectacular increase in the root number was noted in the cuttings of H. fomes and C. iripa treated together with IBA (5000 ppm) and NAA (2500 ppm). The highest number of roots was obtained with IBA (2500 ppm) and NAA (500 ppm) in E. agallocha. B. parviflora and T. populnea responded better to IAA and IBA treatment. The species specific variation in the rooting response to exogenous application of auxins was reflected in the metabolic changes during initiation and development of roots in cuttings. Biochemical analysis showed increase of reducing sugar in the above-girdled tissues at initiation as well as subsequent development of roots which was further enhanced by the use of auxins. Decreases in the total sugar, total carbohydrate and polyphenols and increase in total nitrogen were recorded in the girdled tissues and the high C/N ratio at the initial stage helped in initiation of roots in all the species. Interaction of IBA and NAA promoted starch hydrolysis better than IAA and IBA during root development and subsequently reduced the C/N ratio and increased the protein-nitrogen activity during root development which suggest the auxin influenced mobilization of nitrogen to the rooting zone.Abbreviations IAA Indole-3-acetic acid - IBA Indole-butyric acid - NAA A-naphthalene acetic acid     

Influence of soil aggregation on the rooting of carnation cuttings

Summary Cuttings of a carnation variety of the Chabaud type were rooted in a fine textured soil which had been broken down to yield 3 different soil structures,C, M andF (coarse, medium-sized and fine aggregates).Root initials were found in the basal callus of cuttings growing in all soil treatments already two weeks after planting.Throughout the rooting process, the best results were obtained with coarse aggregated soil and the worst with the medium aggregated one. The fine aggregated soil showed intermediate results, probably due to fissures formed at the point of insertion of cuttings, which improved aeration.The amount of roots at the end of the experiment was greatest with cuttings from theC treatment, while those ofM andF treatments did not differ significantly in this respect.     

The original basal stem section influences rooting in Pinus banksiana cuttings

Photosystem II (PSII) from Cu-deficient pea plants ( Pisum sativum L., cv. Lincoln) has been investigated for electron transport activity, Cu content, and changes in some lipid components. Total fatty acid content was lower that in control plants, with an additional shift in the C₁₈ fatty acid patterns. Less α-linolenic and more linoleic and oleic acids were found. PSII preparations from Cu-depleted plants showed a decreased carotenoid content in light harvesting chlorophyll a/b complex of photosystem II (LHCII) and additional variations in pigment composition of pigment-protein complexes. In the green alga Dunaliella the effect of Cu deficiency on fatty acid composition was similar to that in pea plants, but the influence on the carotenoid pattern was much less pronounced.     

A relationship between irradiation, carbohydrates and rooting in cuttings of Pisum sativum

Rooting ability was studied for cuttings derived from pea plants ( Pisum sativum , L. cv. Alaska) grown in controlled environment rooms. When the cuttings were rooted at 70 μmol m⁻² s⁻, ¹ (photosynthetic photon flux density) or more, a stock plant irradiance at 100 μmol m⁻² s⁻¹ decreased rooting ability in cuttings compared to 5 μmol m⁻², s⁻¹, However, cuttings rooted at 160 μmol m⁻² s⁻¹ formed more roots compared to 5 (μmol m⁻² s⁻¹. Although a high irradiance increased the number of roots formed, it could not overcome a decreased potential for root formation in stock plants grown at high irradiance. Light compensation point and dark respiration of cuttings decreased by 70% during the rooting period, and the final levels were strongly influenced by the irradiance to the cuttings. Respiratory O₂ uptake decreased in the apex and the base of the cutting from day 2 onwards, whereas a constant level was found in the leaves. Only the content of extractable fructose, glucose, sucrose and starch varied during the early part of the rooting period. We conclude that the observed changes in the cuttings are initiated by excision of the root system, and are not involved in the initiation of adventitious roots.