Uptake and translocation of paclobutrazol by shoots of M.26 apple rootstock

When ¹⁴C-paclobutrazol, a gibberellin synthesis inhibitor, was applied to different parts of actively-growing M.26 apple rootstock shoots it was translocated acropetally when applied to the young stem and, to a lesser extent, from the youngest unrolled leaf. Paclobutrazol was not translocated out of leaf laminae, shoot tips or from one-year-old wood but translocation occurred out of a treated petiole into the attached leaf. No basipetal translocation was detected. This translocation pattern suggested movement through the xylem.Localised application of paclobutrazol caused a reduction in shoot extension and leaf production when the young stem or shoot tip were treated; the effect decreased as older parts of the stem were treated. Treatment of laminae or petioles had only a slight effect on shoot extension and treatment of one-year-old wood was ineffective. Combined treatment of the shoot tip plus young stem was similar in effect to treatment of the complete shoot.It is suggested that paclobutrazol exerts its effects on shoot growth by inhibiting gibberellin biosynthesis in the shoot tip and the expanding leaves.The findings contribute to an understanding of the requirements for efficient orchard application of foliar sprays of paclobutrazol.     

Transitory growth control of apple seedlings with less persistent triazole derivatives

Paclobutrazol, triapenthenol (RSW0411), and BAS111 were applied to 4-week-old Delicious apple seedlings (Malus domestica Borkh.) as a root drench at 0.1, 1.0, and 10.0 mg per plant. Paclobutrazol eliminated shoot extension growth for 8 weeks at all three rates. RSW0411 controlled shoot elongation only at the highest rate. BAS111 produced the widest response, with shoot growth ranging from 38% to 93% of controls for the highest and lowest rates, respectively. Generally, leaf area decreased and leaf density increased with increasing rates of all chemicals. Root weight of plants treated with paclobutrazol nearly doubled but increased only slightly with RSW0411 and BAS111. Chemical analysis of the leaf tissue 8 weeks after treatment showed paclobutrazol levels highest, followed by RSW0411 and BAS111. Mention of a trademark, proprietary product, or vendor does not constitute a guarantee or warranty of the product by the U.S. Department of Agriculture and does not imply its approval to the exclusion of other products that may also be suitable.     

Translocation of paclobutrazol and gibberellic acid in Sturt's Desert Pea (Swainsona formosa)

The translocation patterns of paclobutrazol and gibberellic acid were studied by applying these plant growth regulators locally to the main or lateral shoots of Sturt's Desert Pea. Paclobutrazol only reduced the growth of shoots to which it was directly applied indicating that it was readily translocated acropetally within a shoot (via xylem) but not basipetally (via phloem), although some phloem translocation has been reported. Gibberellic acid elongated the main shoot and enhanced apical dominance irrespective of the place of application suggesting it is readily translocated both through xylem and phloem. The translocation patterns did not vary between the main or lateral shoots.     

The Effect of Paclobutrazol on Physiological and Biochemical Changes in the Primary Roots of Pea

Primary roots of pea (Pisum sativum L. cv. Taichung No. 11)were treated with 0, 10 and 50 mg dm^–3 paclobutrazol [(2RS,3RS)-1-(4-chlorophenyl)-4, 4-dimethyl-2-(l,2,4-triazol-l-yl)pentan-3-ol]for 1 h at 48 h after germination. Paclobutrazol treatment inhibitedroot extension, promoted swelling (cell expansion was radialrather than longitudinal), and increased cell volume and theactivity of catalase and peroxidase enzymes. Paclobutrazol alsodecreased root respiration and ethylene production. However,under non-stressed conditions, paclobutrazol treatment did notaffect soluble carbohydrate content, water potential, osmoticpotential or water loss. Under osmotic stress with polyethyleneglycol (PEG), paclobutrazol diminished the increase of waterpotential and decreased the rate of water loss caused by theimposed stress, but had no effect on osmotic potential. Catalaseand peroxidase activity were increased in osmotically-stressedroots of treated plants. Key words: Root growth, paclobutrazol, pea, Pisum sativum, water shortage     

Effect of paclobutrazol on water stress-induced ethylene biosynthesis and polyamine accumulation in apple seedling leaves

Ethylene biosynthesis and polyamine content were determined in [(2RS,3RS)-1-(4-chlorophenyl)-4,4-dimethyl-2-(1,2,4-triazol-1-yl)pentan-3-ol] (paclobutrazol) pre-treated and non-treated water-stressed apple seedling leaves. Paclobutrazol reduced water loss, and decreased endogenous putrescine spermidine content. Gibberellic acid (GA) counteracted the inhibitory effect of paclobutrazol on polyamine content. Paclobutrazol also prevented accumulation of water stress-induced 1-aminocyclopropane-1-carboxylic acid (ACC), 1-(malonylamino)cyclopropane-1-carboxylic acid (MACC), ethylene production and polyamines in apple leaves. α-Difluoromethylarginine (DFMA), but not α-difluoromethylornithine (DFMO), inhibited the rise of putrescine and spermidine in stressed leaves. S-Adenosylmethionine (SAM) was maintained at a steady state level even when ethylene and the polyamines were actively synthesized in stressed apple seedling leaves. The conversion of ACC to ethylene did not appear to be affected by paclobutrazol treatment.     

Precocious gladiolus corm formation in liquid shake cultures

Conditions were defined for precocious differentiation and improved growth of corms at the base of gladiolus shoots. Shoots were derived from explants cultured on agar solidified media, and corm regeneration was obtained in subsequent liquid shake cultures. Benzyladenine (BA), at 10^-7 M, was found to have a stimulating effect mainly when provided to the shoots prior to manifestation of corm growth. Paclobutrazol and sucrose promoted corm formation when supplemented to the liquid media. Paclobutrazol, at 10 mg l^-1, shifted assimilate allocation towards the growing corm. A differential promotion of corm development by sucrose was not observed, and the concentration of sucrose at which the sugar demand for maximal shoot and corm growth is satisfied (60 g l^-1) was unaltered by the presence of paclobutrazol. The rate of corm growth on shoots cultured in a liquid medium supplemented with paclobutrazol and a saturating sucrose concentration, was a function of the length of the shoot's leaf blades, and was similar in light and in dark.     

PP333对离体苹果苗的生长及其生理的影响

在生根培养基中加入0.5或2.0PPm PP333, 明显地减少了苹果离体新梢的鲜重和干重、叶片鲜重和叶面积,增加了比叶重、根的鲜重和干重及根梢鲜重和干重比,并促进了根的形成。PP333对单位叶重量的叶绿素含量没有影响,而增加了单位叶面积的叶绿素含量。经PP333处理后,叶片中的淀粉含量、过氧化物酶活性、蛋白质和游离氨基酸的含量均明显高于对照,可溶性糖与对照差异不明显。     

PP_(333)对离体苹果苗的生长及其生理的影响

在生根焙养基中加入0.5或2.0ppm PP_333,明显地减少了苹果离体新梢的鲜重和干重、叶片鲜重和叶面积,增加了比叶重、根的鲜重和干重及根梢鲜重和干重比,并促进了根的形成。PP_333对单位叶重量的叶绿素含最没有影响,而增加了单位叶面积的叶绿素含量。经PP_333处理后,叶片中的淀粉含量、过氧化物酶活性、蛋白质和游离氨基酸的含量均明显离于对照,可溶性糖与对照差异不明显。     

Apple dwarfing rootstocks and interstocks affect the type of growth units produced during the annual growth cycle: precocious transition to flowering affects the composition and vigour of annual shoots

Background and Aims: Precocious flowering in apple trees is often associated witha smaller tree size. The hypothesis was tested that floral evocationin axillary buds, induced by dwarfing rootstocks, reduces thevigour of annual shoots developing from these buds comparedwith shoots developing from vegetative buds. Methods: The experimental system provided a wide range of possible treevigour using ‘Royal Gala’ scions and M.9 (dwarfing)and MM.106 (non-dwarfing) as rootstocks and interstocks. Second-yearannual shoots were divided into growth units corresponding toperiods (flushes) of growth namely, vegetative spur, extensiongrowth unit, uninterrupted growth unit, floral growth unit (bourse)and extended bourse. The differences between the floral andvegetative shoots were quantified by the constituent growthunits produced. Key Results: The dwarfing influence was expressed, firstly, in reduced proportionsof shoots that contained at least one extension growth unitand secondly, in reduced proportions of bicyclic shoots (containingtwo extension growth units) and shoots with an uninterruptedgrowth unit. In treatments where floral shoots were present,they were markedly less vigorous than vegetative shoots withrespect to both measures. In treatments with M.9 rootstock,vegetative and floral shoots produced on average 0·52and 0·17 extension growth units, compared with 0·77extension growth units per shoot in the MM.106 rootstock treatment.Remarkably, the number of nodes per extension growth unit wasnot affected by the rootstock/interstock treatments. Conclusions: These results showed that rootstocks/interstocks affect thetype of growth units produced during the annual growth cycle,reducing the number of extension growth units, thus affectingthe composition and vigour of annual shoots. This effect isparticularly amplified by the transition to flowering inducedby dwarfing rootstocks. The division of annual shoot into growthunits will also be useful for measuring and modelling effectsof age on apple tree architecture.     

Effect of paclobutrazol on water stress-induced abscisic Acid in apple seedling leaves

Abscisic acid (ABA) was quantitated by enzyme-linked immunosorbent assay (ELISA) in water-stressed leaves from control apple seedlings, and also from apple seedlings treated for 28 days with paclobutrazol ([2RS, 3RS]-1-[4-chlorophenyl]-4,4-dimethyl-2-[1,2,4-triazol-1-yl] pentan-3-ol). The ELISA quantitative estimates were also validated by gas chromatography-electron capture detector and lettuce seed germination inhibition bioassay. Paclobutrazol treatment reduced endogenous ABA levels by about one-third, and prevented the marked accumulation of water-stress-induced ABA that occurred in untreated seedlings. The presence of ABA in the apple leaf extracts was confirmed by gas chromatography-mass spectrometry.     

Growth Responses and Allocation of Assimilates of Rice Seedlings by Paclobutrazol and Gibberellin Treatment

Paclobutrazol [(2RS,3RS)-1-(4-chlorophenyl)methyl-4,4-dimethyl-2-(1h-1,2,4-trizol-1-yl)penten-3-ol] effectively decreased vegetative growth of rice (Oryza sativa L.) seedlings and increased the chlorophyll content. The number of veins in a leaf, the calculated number of stomata per leaf, and the length of guard cells were not altered by the paclobutrazol treatment, suggesting an effect on cell elongation. The allocation pattern of carbohydrates was changed by either gibberellin (GA) or paclobutrazol treatment. GA₃ induced more shoot growth and less accumulation of starch than the control and paclobutrazol-treated seedlings. Photosynthetic ability was not affected by either paclobutrazol or GA₃ treatment. Paclobutrazol-treated plants allocated a smaller amount of photosynthates for vegetative shoot growth and stored more as starch in the crowns than the control and GA₃-treated plants. The same starch degrading activity in the crown tissue of paclobutrazol-treated seedlings as in control plants suggests that the accumulated starch is utilized in a normal activity for growth including leaf emergence, tiller formation, and root production, resulting in improved seedling quality. Received May 30, 1996; accepted December 10, 1996     

Bud composition, branching patterns and leaf phenology in cerrado woody species

BACKGROUND AND AIMS: Plants have complex mechanisms of aerial biomass exposition, which depend on bud composition, the period of the year in which shoot extension occurs, branching pattern, foliage persistence, herbivory and environmental conditions. METHODS: The influence of water availability and temperature on shoot growth, the bud composition, the leaf phenology, and the relationship between partial leaf fall and branching were evaluated over 3 years in Cerrado woody species Bauhinia rufa (BR), Leandra lacunosa (LL) and Miconia albicans (MA). KEY RESULTS: Deciduous BR preformed organs in buds and leaves flush synchronously at the transition from the dry to the wet season. The expansion time of leaves is <1 month. Main shoots (first-order axis, A1 shoots) extended over 30 d and they did not branch. BR budding and foliage unfolds were brought about independently of inter-annual rainfall variations. By contrast, in LL and MA evergreen species, the shoot extension rate and the neoformation of aerial organs depended on rainfall. Leaf emergence was continuous for 2-6 months and lamina expansion took place over 1-4 months. The leaf life span was 5-20 months and the main A1 shoot extension happened over 122-177 d. Both evergreen species allocated biomass to shoots, leaves or flowers continuously during the year, branching in the middle of the wet season to form second-order (A2 shoots) and third-order (A3 shoots) axis in LL and A2 shoots in MA. Partial shed of A1 shoot leaves would facilitate a higher branching intensity A2 shoot production in LL than in MA. MA presented a longer leaf life span, produced a lower percentage of A2 shoots but had a higher meristem persistence on A1 and A2 shoots than LL. CONCLUSIONS: It was possible to identify different patterns of aerial growth in Cerrado woody species defined by shoot-linked traits such as branching pattern, bud composition, meristem persistence and leaf phenology. These related traits must be considered over and above leaf deciduousness for searching functional guilds in a Cerrado woody community. For the first time a relationship between bud composition, shoot growth and leaf production pattern is found in savanna woody plants.     

Response of Eucalyptus nitens seedlings to gibberellin biosynthesis inhibitors

The plant growth regulators (PGRs) paclobutrazol, chlormequat chloride and prohexadione where applied to 11 month old seedling of Eucalyptus nitens to examine their relative effects on precocious flowering, growth and levels of GA20 and GA1 in the shoot apex. Paclobutrazol was most effective in reducing growth and levels of GA20 and GA1 in the seedlings followed by chlormequat chloride with prohexadione being least effective. Paclobutrazol and chlormequat chloride reduced both GA20 and GA1 levels by similar degrees, but prohexadione reduced GA1 levels considerably more than GA20 levels. None of these PGRs was effective in promoting precocious flowering. This suggests that there is an extra level of reproductive control operating in juveniles of this species compared to those of the closely related species E. globulus previously found to flower precociously in response to similar paclobutrazol treatments.     

Controlling plant growth via the gibberellin biosynthesis system – II. Biochemical and physiological alterations in apple seedlings

Some physiological and biochemical changes in apple seedlings ( Malus domestica Borkh cv. 'York Imperial') caused by an inhibitor of gibberellin biosynthesis, paclobutrazol [(2RS, 3RS)-1-(4-chlorophenyl)-4,4-dimethyl-2-(1,2,4-triazol-1-yl) pentan-3-ol], were determined. Paclobutrazol shifted assimilate partitioning from leaves to roots, increased carbohydrates in all parts of apple seedlings, increased chlorophyll content on a leaf area basis, increased soluble protein in leaves, increased mineral element concentration in leaf tissue and increased root respiration. Foliar application of gibberellic acid (GA₃) counteracted the effects induced by paclobutrazol.     

Relative efficacy of paclobutrazol, propiconazole and tetraconazole as stress protectants in wheat seedlings

The stress protective effects of triazoles including paclobutrazol, a plant growth regulator, and two fungicides, propiconazole and tetraconazole, are compared. Wheat (Triticum aestivum L. cv Katepwa) seeds were imbibed for 18 h in distilled water (Ck) or in aqueous solutions of each triazole (50 mg L-1). Seeds were then air dried, planted in sectioned plastic flats and grown in a greenhouse. After 10 days, one set of seedlings were allowed to continue growing under optimal conditions while additional sets were exposed to various stresses including high temperatures, drought and spray with the herbicide paraquat. Compared to wheat leaves from plants grown under optimal conditions, heat stress decreased shoot fresh weight, fluorescence values and chlorophyll levels. It also increased ion leakage. All symptoms of damage were alleviated by the triazoles, with paclobutrazol being the most potent. Similar trends were found under acute drought conditions, where seedlings treated with paclobutrazol had the highest percent survival and the most shoot regrowth upon rewatering. Paclobutrazol was also the best triazole in protecting wheat leaves from damage caused by paraquat, a free radical generator. It is concluded that while all the triazoles have the potential to be stress protectants, paclobutrazol was consistently the most effective.     

Growth retarding effects of paclobutrazol and RSW 0411 on Granny Smith and Fuji apple trees

The growth retardants paclobutrazol (β-[(4-chlorophenyl)methyl]-α-(1,1-dimethylethyl)-1H-1,2,4-triazole-1-ethanol) and RSW 0411 (β-(cyclohexyl methylene)-α-(1,1-dimethylethyl)-1H-1,2,4-triazole-1-ethanol) were tested on two-year-old trees of Granny Smith and Fuji apple. RSW 0411 at 100 mg/L did not cause any growth reduction in Granny Smith, while 500 and 1000 mg/L significantly reduced growth below that of the control between 27 and 40 days after application. Paclobutrazol at 100 mg/L had significantly reduced shoot growth between 27 and 55 days after application, and 1000 mg/L reduced shoot growth between 27 and 82 days after application. By 100 days after application, there were no longer differences between treatments. Shoot growth on Fuji trees was reduced below that of the control as follows: between 14 and 27 days following a single application of 500 mg/L RSW 0411; between 27 and 55 days following two applications; between 14 and 72 days following three applications; and between 14 and 82 days following four applications. Treatments were applied 14 days apart. Paclobutrazol was a more active growth retardant than RSW 0411 at the same rate, and the growth-retarding effects of RSW 0411 were short-lived.     

The Responses of Young Apple Trees to Supplementary Nitrogen and their Relation to Carbohydrate Resources

Supplementary nitrogen was supplied as ammonium nitrate to pottedtrees of MM.106 apple rootstock during the summer period ofextension growth or during autumn after the end of shoot extension.Effects of autumn nitrogen in the current year were small butsummer nitrogen stimulated shoot growth markedly and increasedleaf-area duration. Neither total root growth nor relative carbohydratecontent were reduced by the treatments. Indeed no direct effectof treatment on relative carbohydrate content was observed.Although a smaller fraction of the total photosynthate was utilizedfor root growth when shoot growth was stimulated by extra nitrogen,total dry-matter production on the basis of available lightenergy intercepted was greater or more efficient when growthwas increased. Additional nitrogen, however, did not preventa seasonal decline in the apparent efficiency of utilizationof incident light energy.     

A novel strategy for the induction and maintenance of shoot regeneration from callus derived from established shoots of apple [Malus×Domestica Borkh.] cv. Golden Delicious

A novel strategy for the production and maintenance of morphogenic callus for 1 year from mature leaf explants of apple has been developed using micropropagated primary leaves of cv. Golden Delicious. The technique required second generation adventitious buds produced from cultured primary leaves also produced from established shoot cultures. The age at which buds were capable of producing morphogenic callus was critical and found to be when leaflets were 2–3 mm in length. Medium composition affected the maintenance but not the induction of shoot regeneration from callus and the best combination was found to be high calcium, low ammonium and low hormone levels. Adventitious shoots were rooted in vitro and established glasshouse-grown plants showed no phenotypic differences from the plants derived from shoot proliferation. The great advantage of this technique for an increased efficiency of recovery of transgenic plants from transformed cells is discussed and the acquisition and maintenance of cell competence with respect to the formation of shoots in culture is explained. Received: 13 August 1996 / Revision received: 13 November 1996 / Accepted: 6 December 1996     

PP333对苹果幼树越冬期间过氧化物酶同工酶的影响

以越冬性强的元帅苹果幼树为对照,用PP333处理越冬性弱的金冠苹果幼树,测定越冬期间其枝条过氧化物酶同工酶的变化,并在翌年春季田间调查越冬情况。结果表明,PP333处理大大增加了过氧化物酶同工酶中与抗寒性有关酶的酶活,并提高了金冠苹果幼树的越冬性。     

Reduction of generation time in Eucalyptus globulus

The plant growth retardant paclobutrazol was applied by foliar spray to seedlings of Eucalyptus globulus (Labill.) to determine its effects on reproductive activity. It was shown to induce flowering in vegetatively juvenile seedlings and increase reproductive activity in vegetatively adult material. The former case represented a 50% (three year) reduction in generation time for commercial seedlings. Paclobutrazol treatment did not appear to have a negative effect on any aspect of reproductive development, germination of new seed, or early seedling growth, while having a distinct positive effect on reproductive output. This suggests that paclobutrazol may be an effective tool enabling tree breeders to reduce generation time and increase reproductive output in E. globulus. Foliar spraying during autumn was shown to be an effective means and timing of paclobutrazol application, with results evident in the following flowering season. Considerable persistence of paclobutrazol effects was noted in the second season after application. Pot size and growth temperatures also play roles in determining the extent of new reproductive activity each season in E. globulus seedlings.