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Growth and development in Achimenes cultivars.
Abstract
Achimenes is a herbaceous perennial of the Gesneriaceae family. Its origin is Central and South America. It has been cultivated as a pot plant since the Victorian era. Extensive hybridization has produced many attractive cultivars which have been Introduced in commercial floriculture both In the United States and Europe. Commercial Achimenes cultivars have short erect stems bearing flowers in the axils of the leaves and form rhizomes at the tips of underground stolons. At the end of the growing period, in late summer, the plants enter a period of senescence and rhizomes undergo a period of dormancy before they sprout for a new plant production in early spring . Thus cultivation of Achimenes is limited to one crop per year.The aim of the present study was to describe the effect of the environment, mainly light and temperature, on plant growth and development In order to realize optimum flower and / or rhizome production . Moreover the possibilities to manipulate plant development and release of rhizomes from dormancy by means of growth regulators are indicated. Vegetative growth and flower development Growth and flowering were strongly affected by treatments involving duration, intensity and quality of light (Chapters 1 through 4). Longer photoperiods increase vegetative growth in most Achimenes cultivars. LD (16 h) increased plant height, shoot weight and number of flowers compared to SD (8 h). Increased duration of illumination, of the same light level, increased shoot dry weight and reduced plant height (Chapter 2). When the same daily light integral was maintained, long day i.e. low light Intensity favoured growth and flowering and increased relative growth rate (Chapter 3). This is due to increase in net assimilation rate but not in leaf area ratio suggesting a better light use efficiency when a low light intensity is combined with longer days. When daylength was extended with low intensity incandescent light (low R/ FR ratio) total leaf area , total dry weight of the plant and leaves Increased . Fluorescent light (high R/ FR ratio) had no effect on total dry weight of the plant. Number of flowers was not influenced by light quality except in 'Rosenelfe' where number of axillary shoots was suppressed by incandescent light and flowering was promoted by fluorescent light . Furthermore, light duration and quality influenced calculated parameters of growth. Daylength extension by either incandescent or fluorescent low intensity light increased relative growth rate , net assimilation rate and lowered leaf area ratio (Chapter 4).Vegetative and generative growth were Influenced by the temperature treatments. Higher temperatures Increased plant height, number of leaf whorls and flowers and reduced time to anthesis (Chapters 2 and 4). At 25 °C , total leaf area and total dry weight of the plant increased compared to 17 °C Application of gibberellic acid (GA 3 ) alone or in combination with benzyladenine (BA) and 1 or naphthalenacetic acid (NAA) increased plant height and weight of aerial plant parts but number of flowers was not affected (Chapters 6 and 7). The growth retardants Ancymidol, Paclobutrazol and 5-3307 suppressed plant height and development of axillary shoots and flowers in 'Viola'. The effects of the growth retardant treatments were more pronounced under shade rather under full sunlight. The growth regulators used in this study do not cause any desirable effects in Achimenes as plants become either too tall (GA 3 ) or stunted (retardants) with subsequent adverse effects on flowering (Chapter 8). Rhizome formation and development In general rhizome development seemed to be correlated to shoot growth. Daylength hardly influences number of rhizomes, however, in some cultivars number and fresh weight of rhizomes increase in SD (Chapter 1). LD or continous ligh tdid not inhibit rhizome formation and development (Chapter 2). Higher irradiance levels, increased number and dry weight of rhizomes, along with increases in dry weight of the aerial parts, indicating that rhizome development depends largely on the accumulation of metabolites provided by increased assimilation of the above ground parts. light quality ( incandescent vs. fluorescent light) affected dry weight of rhizomes depending on the cultivar. Fluorescent light increased dry weight of rhizomes in 'Flamenco' only. Number of rhizomes was not affected by light quality. Temperature had no effect on rhizome development or on rhizome weight ratio (percentage of dry matter incorporated into rhizomes ) as shown in Chapters 2 and 4.Application of GA3 reduced rhizome weight ratio whereas the combination of BA and NAA increased dry weight of rhizomes (Chapter 7). BA also increased fresh weight of rhizomes whereas GA3 reduced it (Chapter 3). The use of growth retardants, however, did not promote rhizome development but in some cases even reduced it. This finding confirms that rhizome development depends on good shoot growth. Sprouting of rhizomes Freshly harvested rhizomes are released from dormancy with either benzyladenine (BA) or giberrellic acid (GA <sup> 3 </SUP>). Soaking rhizomes of 'English Waltz' in a BA solution (50 mg.l <sup>-1</SUP>) and keeping them at 25 °C in the dark for two weeks resulted in the highest percentage of sprouting . Soaking rhizomes of 'Viola' in GA <sup>3</SUP>(50 mg.l <sup>-1</SUP>) for 16 h also promoted sprouting depending on subsequent storage treatment. Continous light during storage inhibited sprouting whereas in continous darkness at 21 or 25 °C resulted in 100% sprouting in three weeks. When rhizomes were cut in half the apical halves always sprouted first and more than the basal ones. Rhizomes which had been treated with GA <sup>3</SUP>produced taller plants with more leaf whorls, flowering earlier with more flowers. High temperature pretreatment of rhizomes increases the number of flowers produced. This is the result of the promotive effect of temperature on sprouting which subsequently affects flowering. Earlier sprouting ensures earlier flowering. Varietal differences Several cultivars were studied. Plant height, number of axillary shoots, flowers , earliness , number and dry weight of rhizomes are clearly cultivar characteristics usually not influenced by environmental factors. Certain cultivars are slow in forming rhizomes. During the period of the experiments 'Blauer Planet' did not form any rhizomes at all. 'Prima Donna' , 'Viola ' and 'Hilda' formed very few. In 'Hilda' the relative growth rate was lower than in in 'Flamenco ' or 'Rosenelfe'. Responses to temperature also varied among cultivars. 'Rosenelfe' and 'Hilda' were the most responsive and this was due to increased net assimilation rate at higher temperatures (Chapter 4).Leaf morphology was responsible for some of the differences observed. 'Early Arnold' had greater total leaf area and total dry weight of leaves and plant due to a high net assimilation rate which was attributed to its large thin leaves, 'Linda' on the other hand, had a low net assimilation rate because of its many and small leaves which caused more internal shading. It is concluded that differences in the mean values for net assimilation rate and leaf area ratio are responsible for the differences observed among cultivars.Levels of endogenous hormones may be responsible for some differences among cultivars. 'Flamenco' had a low shoot weight whereas rhizome dry weight was high. It also responded to the far red light treatment by decreasing the dry weight of rhizomes. Relative growth rate and fresh weight per rhizome were greater in 'Flamenco' rather than in 'Hilda' or 'Viola'. It was shown that the number of flowers is correlated to height of the main stem and number of leaf whorls. Furthermore, 'Rosenelfe', 'Blau Import' and 'Tetraelfe' had a higher number of flowers per plant as they bear flowers in clusters of 3 to 9 from the leaf axils where the other cultivars bear only one or two. All cultivars tested flowered regardless of daylength thus confirming that Achimenes is a day neutral plant.It is concluded that it is possible to control growth and flowering in Achimenes through temperature and light, the latter being the more crucial factor . Dormancy of rhizomes can be broken and sprouting enhanced with the use of growth substances. Thus the time interval between two growing seasons can be shortened. However, additional light, at least of the same levels and/or duration as in the present experiments, should be given during winter months. The right choice of cultivar, depending on the intended purpose of cultivation (flower or rhizome production) is also an important factor to consider. Growth regulators are not recommended for application to whole plants except for the purpose of increasing rhizome production.
... The Auxin induced effect on rooting of cuttings is presumed to be mediated through its effect in mobilizing the reserve food material by enhancing the activity of hydrolytic enzymes (Nanda et al. 1968). GA 3 application was reported to increase weight of aerial parts in Viola (Vlahos 1991). Exogenously applied, gibberellin promoted stolon elongation and inhibited tuber formation and increased fresh weight in potato (Xu et al. 1998). ...
p>Vegetative propagation could be an important advantage and also envisioned to be the best alternative for planting stock production in the absence or lack of seeds. In the Pichavaram mangrove forest Ceriops decandra (Rhizophoraceae) is one of the most endangered species and IUCN also declared this species as near threatened. Propagation of Ceriops decandra, by propagule cuttings, treated with Plant growth regulators is feasible and it was possible to produce three saplings from one propagule. The effect of plant growth regulators like IBA, NAA, GA3 on optimum growth medium and period of nursery care for mangrove saplings of Ceriops decandra were studied and the results revealed that best growth performance was recorded when the cuttings were treated with GA3 alone up to 2000 ppm. Combination of NAA and IBA increased the rooting and leaf formation. Among the treatments GA3 enhanced the number of leaves and roots, Shoot and root length, fresh and dry weight of roots increased to larger extent. All the plants are transferred to field in the mangrove forest of Pichavaram, Tamilnadu, India.
ECOPRINT 22: 21-28, 2015</p
... Achimenes have been cultivated since the late 1700s, upon first introduction to England (Jungbauer, 1977). Popularity has waned and surged, largely following breeding efforts undertaken in the 1940s in The Netherlands, Germany, and the United States (Vlahos, 1991). Recently renewed breeding efforts have led to increased interest in achimenes. ...
The dormancy mechanism in achimenes (Achimeneshybrids) has not been thoroughly characterized. Rhizomes of five recently developed achimenes cultivars were stored for 0,4, 8,12, or 16 weeks at 68 °F. Cultivar A09 demonstrated a strong decrease in the time to root after 4 weeks of storage, rooting after 13 weeks postplanting. The rooting response for cultivars A16, A21, and A22 was significantly less than cultivar A09; they developed roots between 2.6 and 7.6 weeks after 4 weeks of storage. Rhizomes stored longer than 8 weeks resulted in decreased rooting responses for all cultivars. Shoot emergence was delayed in all cultivars with cultivars without any storage period; cultivars A09, A16, and A23 exhibited a stronger delay than other cultivars. After 4 weeks of storage, the number of weeks to shoot development decreased for all cultivars and after each additional 4-week storage period, the number of weeks to shoot development decreased or remained the same. After 16 weeks of storage, shoots developed in less than 4 weeks for all cultivars. Pupation occurred in four of five cultivars on rhizomes given no storage or with only 4 weeks of storage. The results obtained suggest that the dormancy period of some newer achimenes cultivars is abbreviated in comparison with older cultivars.
... [33] Exogenously applied, gibberellin promoted stolon elongation and inhibited tuber formation and increased fresh weight in potato. [34] Combined auxin treatment was reported to have a strong effect on the rooting response of stem cuttings/air layers of difficult-to-root species. [15,16] In this study, combined treatment with IBA and NAA also produced highest rooting percentage, root number and length in both the types of cuttings over the controls. ...
Vegetative propagation could be an important advantage and also envisioned to be the best alternative for
planting stock production in the absence or lack of seeds. In Pichavaram, mangrove forest Tamil Nadu, the Ceriops decandra (Rhizophoraceae) is one of the most endangered species and IUCN also declared this species as near threatened. Propagation of C. decandra, by propagule cuttings, treated with plant growth regulators (PGRs) is feasible and it was possible to produce three saplings from one propagule. The effect of PGRs like indole butyric acid (IBA), naphthalene acetic acid (NAA), gibberellic acid (GA3 ) on propagule cuttings of C. decandra were studied and the results revealed that best growth performance was recorded when the cuttings were treated with GA3 2000 ppm. The combination of NAA and IBA increased the rooting and leaf formation. Among the treatments, GA3 enhanced the number of leaves and roots, shoot and root length, fresh and dry weight of roots increased to a larger extent. All the plants are transferred to field in the mangrove forest of Pichavaram, TamilNadu, India.
... nigricans Dinsm.), which may be attributed to the growth-promotion effect of GA in stimulating and accelerating cell division, increasing cell elongation and enlargement, or both [25]. Other studies have also revealed the effectiveness of GA in inducing flowering262728 , although Garner and Armit- age [29] observed no effect of GA on stem quality of caspia (Limonium 'Misty Blue'). However, many previous studies indicated that exogenous GA inhibited flower bud formation , e.g. in citrus [30], in apples [31], in pears [32], and in cherries and peaches [33]. ...
To elucidate the possible functions of endogenous hormones in the flowering of chestnut, concentrations of four endogenous hormones [indole-3-acetic acid (IAA), gibberellic acid (GA), abscisic acid (ABA), zeatin riboside (ZR)) and the soluble sugars content were measured in both normal and developmentally abnormal Chinese chestnut (Castanea mollissima) during flowering and fruiting stages. Our results showed that the contents of ZR, ABA, and GA exhibited a significant different pattern in normal trees from that in abnormal trees, while the contents of IAA and soluble sugars showed a similar change pattern between them. These results suggest that quantitative changes in endogenous hormones may correspond to different flowering and fruiting mechanisms.
In this study, 5 μmol·L−1 abscisic acid (ABA) and gibberellic acid (GA3) were used to study the effect of both growth regulators on the morphological parameters and pigment composition of Andrographis paniculata. The growth regulators were applied by means of foliar spray during morning hours. ABA treatment inhibited the growth of the stem and internodal length when compared with control, whereas GA3 treatment increased the plant height and internodal length. The total number of leaves per plant decreased in the ABA-treated plants, but GA3 treatment increased the total number of leaves when compared with the control. Both growth regulators (ABA and GA3) showed increased leaf area. ABA and GA3 treatments slightly decreased the total root growth at all the stages of growth. The growth regulator treatments increased the whole plant fresh and dry weight at all stages of growth. ABA enhanced the fresh and dry weight to a larger extent when compared with GA3. An increase in the total chlorophyll content was recorded in ABA and GA3 treatments. The chlorophyll-a, chlorophyll-b, and carotenoids were increased by ABA and GA3 treatments when compared with the control plants. The xanthophylls and anthocyanin content were increased with ABA and GA3 treatments in A. paniculata plants.
The effects of application method and concentration of gibberellic acid (GA3), paclobutrazol and chlormequat on black iris performance were assessed. Plants (10 cm high, 4 ± 1 leaves) were sprayed with 125, 250, 375 or 500 mg L−1 or drenched with 0.25, 0.5, 1 or 2 mg L−1 GA3. In a second experiment, the plants were sprayed with 100, 250, 500 or 1000 mg L−1 or drenched with 0.25, 0.5, 1 or 2 mg L−1 paclobutrazol. Other plants were sprayed with 250, 500, 1000 or 1500 mg L−1 or drenched with 100, 250, 375 or 550 mg L−1 chlormequat. In each experiment, the control treatment consisted of untreated plants. Results indicated that the tallest plants (37.3 cm) in the GA3 experiment were those sprayed with 250 mg L−1. The most rapid flowering (160 days after planting) occurred when a 375 mg L−1 GA3 spray was used, whereas flowering was delayed to 200 days using 1 mg L−1 GA3 drench. Drenching with 1 mg L−1 GA3 increased height of the flower stalk by 7 cm compared to the control. Though relatively slow to flower, plants drenched with 1 mg L−1 GA3 had long and rigid stalks, which were suitable as cut flowers. Number and characteristics of the sprouts were not affected by GA3. All paclobutrazol sprays resulted in leaf falcation. A 500 or 1000 mg L−1 paclobutrazol spray resulted in severe and undesirable control of plant height, drastic reduction in stalk height and weight, and delayed flowering. Plants drenched with 0.25 or 1 mg L−1 paclobutrazol were suitable as pot plants. Chlormequat reduced plant height only at the highest drench concentration, which also reduced flowering to 70%. No leaf falcation was observed with GA3 or chlormequat. Chemical names: ( ± )-(R*,R*)-beta-((4-chlorophenyl)methyl)-alpha-(1,1,-dimethylethyl)-1H-1,2,4,-triazol-1-ethanol (paclobutrazol); (2-chloroethyl) trimethylammonium chloride (chlormequat).
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