Developmental changes and water status in tulip bulbs during storage: visualization by NMR imaging

Magnetic Resonance Imaging (MRI) and light and scanning electron microscopy (SEM) were used to follow time-dependent morphological changes and changes in water status of tulip bulbs (Tulipa gesneriana L., cv. 'Apeldoorn') during bulb storage for 12 weeks at 20 degrees C (non-chilled) or 4 degrees C (chilled) and after planting. MR images reflecting the water content, the relaxation times T1 and T2 (or their reciprocal values, the relaxation rates R1 and R2), and the apparent self-diffusion coefficient of water molecules (ADC), were obtained for intact bulbs. After planting, scape elongation and flowering occurred only in chilled bulbs, while elongation in non-chilled bulbs was retarded. Microscopic observations showed different structural components and high heterogeneity of the bulb tissues. MRI revealed the elongation of the flower bud during storage, which was significantly faster in the chilled bulbs. In addition, MRI demonstrated a redistribution of water between different bulb organs, as well as significant differences in the pattern of this redistribution between the chilled and non-chilled bulbs. Generally, R2 relaxation rates became faster in all bulb organs during storage. At the same time, ADC values remained constant in the chilled bulbs, while exhibiting a significant increase in the non-chilled bulbs.     

Changes in the carbohydrate and hormonal status in <Emphasis Type="Italic">Tulipa bifloriformis</Emphasis> bulbs forced into bloom in a greenhouse and in the open ground

Time-course of ABA, cytokinins, monosaccharides (MS), and water-soluble polysaccharides (WSP) contents were followed during cold dormancy period in the bulbs of tulip (Tulipa bifloriformis Vved.) that stayed over winter in the open ground or were cold-forced into bloom in a greenhouse. In both cases, the level of monosaccharides and water-soluble polysaccharides in the storage scale tissues increased, whereas the MS/WSP ratio in the bulbs planted in the open remained essentially the same and in case of forcing treatment decreased almost fivefold. In the apical bud tissues, the level of monosaccharides also rose in both cases, but the MS/WSP ratio in the open was greater throughout the whole experiment. The level of cytokinins in the apical bud tissues in the open was higher than in the forcing case, although the changes in their total content were identical following both treatments. Following the forcing treatment, the contents of free and bound ABA in the apical bud tissues increased reaching their peaks by the end of cold period. In the open, there were two peaks of free ABA: in October (when early frosts occurred) and in March (at the end of the wintering period). The winter forcing treatment resulted in rapid depletion of energy and plastic resources in T. bifloriformis and the death of 20% of embryonic flower buds (in the open, all flower buds survived). Nevertheless, plant adaptation potential ensured the development of generative shoots with 4–5 normal flowers, which makes it possible to use this species of multiflorous tulip for winter forcing in a greenhouse.     

Exogenous GA<Subscript>3</Subscript> overcomes bud deterioration in tulip (<Emphasis Type="Italic">Tulipa gesneriana</Emphasis> L.) bulbs during dry storage by promoting endogenous IAA activity in the internodes

Endogenous free IAA was examined with an immunohistochemical method for its involvement in the reduction of bud deterioration after GA₃ was injected into the bulbs. We found that tulip bulbs stored at 20°C constantly developed severe bud deterioration, whereas the symptoms of deterioration was lighter in the bulbs with GA₃ injection and not observed in the bulbs with 4°C treatment. 73% success in overcoming bud deterioration was achieved in 20°C with GA₃ treatment after 8 weeks of bulb storage, and the success rate was 7% after 12 weeks of storage. IAA was detected in the parenchyma cells in the internodes of the shoot after the bulbs were stored at 4°C or at 20°C with GA₃ injection for 4 weeks, but little was detected in the bulbs stored at 20°C constantly. Moreover, a weak IAA signal was present in between the cells of the internodes irrespective of bulb treatment. After planting, the bulbs that had been treated differently exhibited different flowering ability. The bulbs stored at 4°C for 4, 8 and 12 weeks attained high flowering percentage, which was lower in the 20°C with GA₃ treatment and lowest in the 20°C treatment. It may be concluded that GA₃ injection decreases bud deterioration of tulip bulbs during dry storage at 20°C by promoting the endogenous IAA in the internodes.     

Flower Morphogenesis in Rosa hybrida 'Mercedes' as Studied by Cryo-scanning Electron and Light Microscopy. Effects on Light and Shoot Position on a Branch

Flower bud development in Rosa hybrida cv. 'Mercedes' was studied in shoots grown at different irradiances and sprouting from axillary buds at different branch positions. Cryo-scanning electron microscopy and light microscopy were used to visualize, characterize and determine flower morphogenesis during early shoot development. Up to the moment of visible flower bud appearance on the plant, flower morphogenesis was divided into nine stages. This classification was based on external and internal characteristics of the primordium. All shoots of the rose 'Mercedes' whether positioned uppermost or second on a branch and whether grown at 300 or 150 μmol m^-2 s^-1 PAR (12 h d^-1) developed equally up to flower stage 7, i.e. the stage just before visible initiation of stamen and pistils. Signs of flower bud abortion were the compactness of the flower bud at developmental stage 7 (height/width < 1·5) and the sprouting of axillary buds positioned just below the flower bud primordium. It was concluded that once a flower bud has reached a height to width ratio larger than 1·5, and once stamen and pistil developmental has started, it has passed the critical developmental stage in which abortion may occur. Flower developmental stage was closely related to shoot length. This relationship was not affected by irradiance level nor by shoot position on a branch. Therefore, cultivation treatments aimed to improve flower production by reducing flower abortion, such as supplementary lighting, will be most effective when applied during the first 2 weeks of shoot growth in which the flower develops up to stage 7.     

郁金香花芽分化过程中鳞茎碳水化合物和蛋白质含量的变化

以郁金香的两个品种‘朱迪斯＇（‘Judith Leyster＇）和‘大笑＇（‘Big Smile＇）为材料,采用石蜡切片法确定其花芽分化进程,并测定花芽分化期鳞茎内碳水化合物和可溶性蛋白质含量的变化。结果表明,郁金香花芽分化过程中,两个品种的碳水化合物含量的变化趋势较为接近。随着鳞茎含水量的下降,可溶性总糖和可溶性蛋白含量均呈先增加后减少的趋势。淀粉含量的变化呈现波动性,而淀粉酶活性则持续增强并在后期达到稳定水平。鳞片中可溶性糖含量和淀粉酶活性同时增加是郁金香花芽形态分化启动的标志。相比于外层鳞片,内层鳞片是为花芽原基生长发育提供营养物质的首要场所。     

Studies on the Physiology of Hyacinth Bulbs (Hyacinthus orientalis L.): VI. HORMONAL ACTIVITIES IN HYACINTH BULBS DURING FLOWER FORMATION AND DORMANCY RELEASE

The activities of auxin, gibberellin, cytokinin, and abscisicacid were investigated, at 3-weekly intervals, in hyacinth /{Hyadnthusorientalis L.) bulbs during flower bud formation in dry storagefor 12 weeks at 25 /'b0C and during dormancy release in theperiod of 12 weeks of cold treatment at 3 /'b0C after planting.The formation of the flower bud coincided with a gradual increasein the activity of cytokinins and auxins in the bulbs, whereasthe level of abscisic acid was almost stable. Gibberellin activitywas not detectable in lifted bulbs, but it appeared after 6weeks of dry storage and declined in bulbs stored for 12 weeks.The cold storage of bulbs resulted in a gradual decrease ofabscisic acid and it was not detectable in the bulbs cooledfor 12 weeks. The content of auxins was highest in the bulbsduring their rooting in the first 3 weeks of cold treatmentand gradually decreased thereafter. The cytokinin activity declinedin the bulbs cooled for 6 weeks, while gibberellins appearedin them. In the bulbs cooled for a longer time a lack of gibberellinactivity and a gradual increase of cytokinin content was observed.     

葡萄基因电子表达分析平台的验证与应用

为了验证作者建立的葡萄(Vitis vinifera L.)基因电子表达分析平台在葡萄果实发育相关基因的表达预测及特定序列快速检索等方面的应用效果,利用NCBI上公布的大量葡萄EST序列及半定量PCR和RT-PCR技术,对葡萄不同器官中VvANR、VvCHI、VvCHS2和VvDFR基因的表达分析预测结果进行验证,并对该平台具有的特定序列快速检索功能进行了简介.预测结果表明:葡萄各器官中VvANR、VvCHI、VvCHS2和VvDFR基因的无冗余EST序列数量均较多,分别为33条、36条、55条和46条;4个基因的表达量有一定差异,VvANR在花序和芽中表达量较高,VvCHI在花序、果实和芽中表达量较高,VvCHS2在果实、芽、花序和花中表达量较高,VvDFR在花序、芽、花、果实和根中表达量均较高.半定量PCR和RT-PCR实验结果显示:VvANR主要在花序、花和小果中表达;VvCHI主要在小果、花、茎和花序中表达;VvCHS2主要在茎、花序、花和小果中表达;VvDFR在各组织中表达量从高至低依次排序为花、花序、茎、叶、小果、中果、大果.验证结果表明:采用葡萄基因电子表达分析平台识别表达量较高的组织时,平台的预测结果与实验结果基本一致;而在预测一些表达量较低的组织时效果较差.应用该平台、通过5个步骤,可以简便、快速检索出特定组织或特定状况下的特定cDNA文库信息.     

Carbohydrate Status of Tulip Bulbs during Cold-Induced Flower Stalk Elongation and Flowering

The effect of a cold treatment on the carbohydrate status of the scales and flower stalk of Tulipa gesneriana L. cv Apeldoorn bulbs during growth after planting was studied and compared with bulbs not given cold treatment. Bulbs were stored dry for 12 weeks at 5[deg]C (precooled) or 17[deg]C (noncooled). Only the 5[deg]C treatment led to rapid flower stalk elongation and flowering following planting at higher temperatures. Precooling enhanced mobilization of starch, fructans, and sucrose in the scales. The cold-stimulated starch breakdown was initially accompanied by increased [alpha]-amylase activity per scale. In noncooled bulbs, [alpha]-amylase activity slightly decreased or remained more or less constant. Cold-induced flower stalk elongation was partially accompanied by a decrease in the sucrose content and an increase in the glucose content and invertase activity per g dry weight. The starch content in internodes initially decreased and subsequently increased; [alpha]-amylase activity per g dry weight of the lowermost internode showed a peak pattern during starch breakdown and increased thereafter. The internodes of noncooled bulbs, on the contrary, accumulated sucrose. Their glucose content and invertase activity per g dry weight remained low. Starch breakdown was not found and [alpha]-amylase activity per g dry weight of the lowermost internode remained at a low level. Precooling of tulip bulbs thus favors reserve mobilization in the scales and flower stalk and glucose accumulation in the elongating internodes.     

Developmental changes and tissue distribution of lectin in Tulipa

A sensitive enzyme-immunoassay was developed to quantify the tulip lectin and used to follow its distribution during the life cycle of tulips cv. Attila.The tulip lectin is predominantly located in the bulbs. At planting time the absolute lectin concentration is approximately the same in all bulb scales. However, as the shoot grows and the plant turns on to flowering, the lectin concentration rapidly decreases, first in the inner bulb scales but later also in the outer bulb scale. Soon after flowering the lectin rapidly accumulates in the new daughter bulbs.Lectin levels in leaves, stems and flowers are very low. The lectin in these tissues is already present before the sprout emerges. During the first two weeks after planting, there is a small increase in lectin concentration, followed by a rapid decrease as the plant turns on to flowering. By flowering time all the lectin has disappeared from the aerial parts.Abbreviations DW dry weight - ELISA enzyme-linked immunosorbent assay - FW fresh weight - PBS phosphate-buffered saline - PBSN phosphate-buffered saline containing 0.02% sodium azide - PBST phosphate-buffered saline containing 0.02% sodium azide and 0.05% Tween 20 - TL tulip lectin - Tris 2-amino-2-(hydroxymethyl)-1,3-propanediol     

Identification of Abscisic Acid in Tulipa gesneriana L. by Gas-Liquid Chromatography with Electron Capture and Combined Gas-Liquid Chromatography and Mass Spectrometry

A major growth inhibitory substance of tulip bulbs (Tulipa gesneriana L. cv Paul Richter) has been unequivocally shown to be abscisic acid (ABA). The ABA methyl ester of the free ether-soluble acid fractions of tulip organs had the identical retention time on gas-liquid chromatography with electron capture detector as authentic ABA methyl ester. In addition, the mass spectra were the same. On a unit dry matter basis, the basalplate and floral shoot contained 3.6 and 2.6 times more ABA than the fleshy scales, respectively.     

Mobilisation of nutrients and transport via the xylem sap in a shrub (Ligustrum ovalifolium) during spring growth: N and C compounds and interactions

In open-field soilless culture there can be great deal of leaching, particularly in rainy springs. Ligneous plants have the capacity to store large quantities of nutrients in perennial organs. Knowledge of the plant's internal nutrient mobilisation during spring to supply growing organs could lead to reduction of fertiliser application. To quantify the fraction of storage mobilisation available for growth of new organs during spring, Ligustrum ovalifolium shrubs were grown for 2 years with or without fertilisation in the second spring. Nitrogen (N) absorption and N and carbon (C) mobilisation from storage were followed during spring growth via the sap quality. A mathematical combination of the sap composition with flow velocity provided the transported quantities of N and C. Nitrogen and C mobilisation towards new shoots took place during all the spring growth from bud break onwards. In unfertilised plants, C was mobilised primarily as sugars (stachyose, mannose and sucrose) and starch. In fertilised plants, the same sugars were transported in the xylem sap, but at lower concentrations. Stachyose concentration was lower in fertilised than in unfertilised plants and decreased during spring growth. Nitrogen was transported in the xylem sap mainly as amino acids in both fertilisation treatments. Glutamine was the predominant form at bud break and during shoot elongation. In fertilised plants, arginine became predominant after shoot elongation, and was related to low C availability. The interactions of N with C are discussed; specifically, insufficient availability of N limits the use of C, more of which is directed to aerial organs by sap flow.     

Soluble and insoluble invertase activity in elongating Tulipa gesneriana flower stalks

Previously 'frozen' Tulipa gesneriana L. bulbs cv. Apeldoorn, were planted and grown at higher temperatures to study the role of invertase (EC 3.2.1.26) in the cold-induced elongation of the flower stalk internodes. After planting, flower stalks were left intact, or, the leaves and flower bud were both removed to inhibit internode elongation. In intact flower stalks, elongation of the internodes was accompanied by an accumulation of glucose and an initial decrease in the sucrose content g,⁻¹ dry weight. Insoluble invertase activity g,⁻¹ dry weight hardly changed, but soluble invertase activity showed a peak pattern, that was related, at least for the greater part, to the changes in the sugar contents. Peak activities of soluble invertase were found during (lower- and uppermost internodes) or around the onset of the rapid phase of internode elongation (middle internodes). Internode elongation and glucose accumulation immediately ceased when the leaves and flower bud were removed. Insoluble invertase activity g,⁻¹ dry weight remained at its initial level (lowermost internode) or increased more towards the upper internodes. Soluble invertase activity did not further increase (uppermost internode) or decreased abruptly to a low level. It is concluded that soluble invertase may be one of the factors contributing to glucose accumulation and internode elongation in the tulip flower stalk.     

SHOOT TIP ABORTION IN ULMUS AMERICANA

Millington , W. F. (Marquette U., Milwaukee, Wis.) Shoot tip abortion in Ulmus americana. Amor. Jour. Bot. 50(4): 371–378. Illus. 1963.—Phenological observations of American elm have shown that the phenomenon of shoot tip abortion in which the distal several plastochrons of each shoot turn yellow and abort, inducing sympodial growth, occurs over a period of several weeks starting at the time fruits are shed from older trees. Time of abortion varies among plants of different age, among individuals of the same age, and among shoots on the same individual. In the latter case, time of abortion is inversely correlated with the vigor of the shoot, the most vigorous shoots on a branch being the last to abort. Abortion is first evident in the yellowing of the entire shoot tip. Cytohistological studies show that necrosis commences at the sixth to eighth node back of the apex, where it is apparent in autolysis of internal cells of the stipules. Necrosis progresses acropetally in the stipules and young leaves and ultimately involves the leaf primordia at the shoot apex. Mitosis ceases in the shoot apex and its meristematic appearance is lost. These changes follow in basipetal sequence in the axillary buds down to the bud below the abscission site. This bud remains active and will resume growth the following season. The abscission site is evident externally as a green-yellow boundary in the basal part of the internode. No protective layer is present at the time of abscission, but it develops after the shoot tip abscises. There is no indication of blocking of vascular tissues before shoot tip abortion and limitation of water supply probably is not a causal factor. Photoperiod studies show that shoot tip abortion is accelerated in short days and delayed but not prevented in long days. Greenhouse experiments show that abortion is delayed also in seedlings, in plants supplied with organic fertilizer, or grown with the roots unconfined. Plants grown in a nutrient solution deficient in nitrogen aborted ahead of controls and plants deficient in calcium. Although shoot tip abortion occurs coincident with fruit drop, there is no indication of a causal relationship. The literature relating to shoot tip abortion is discussed in relation to the above observations.     

The southernmost myco-heterotrophic plant, Arachnitis uniflora: root morphology and anatomy

Root morphology and anatomy of the myco-heterotrophic Arachnitis uniflora (Corsiaceae) were studied in relation to their association with a Glomus species (Glomeromycota). The mycorrhizal features were studied in three distinctive stages of development: (i) shoot and flower restricted to a small, underground bud; (ii) shoot and flower bud up to 1.5 cm; and (iii) shoot and flower already withered. The hyphae penetrate through and between the epidermal and exodermal cells; the exodermis and outer cortical cells become colonized in an inter- and intracellular manner, with some coils being formed in these layers. The fungi colonize the middle cortex, where intracellular vesicles in bundles are abundant. Arbuscules are formed profusely at very early stages of development, while in older stages they almost disappear and abundant vesicles are formed. Except for some details, the pattern of root colonization corresponds to a Paris-type. Presence of storage substances (starch and oil) also was recorded. Starch is produced and stored within root cells, mainly in the outer and inner root cortex. In senescent stages, plant and fungal tissues collapse.     

Mitochondrial Activity and Carbohydrate Levels in Tulip Bulbs in Relation to Cold Treatment

Changes in mitochondrial activity and in the levels of variouscarbohydrates were followed in tulip bulbs (cv. Apeldoorn) keptin the dark at low and high temperatures (9 and 18 ?C respectively)from the time of flower differentiation until anthesis. Afterthe first 10 weeks at either temperature, the activity of themitochondria, measured by their ability to oxidize succinate,malate, or 2-oxoglutarate, was at a minimum. Thereafter oxidationrates improved up to about the 26th week when mitochondria fromcooled (9 ?C) bulbs were usually more active than those fromuncooled (18 ?C) bulbs. Subsequently, rates for both treatmentsfell rapidly. In contrast, levels of total alcohol-soluble carbohydratesand of sucrose in the cooled bulbs were at a maximum after 10weeks and were falling rapidly by the 26th week. Statisticallysignificant inverse correlations between mitochondrial activity,typified by the succinate oxidation rate, and these carbohydrateswere established. No such relationships were found for uncooledbulbs, however, and carbohydrate levels in such bulbs tendedto increase slowly throughout the growing period. In addition,transfer of carbohydrates to the growing shoot was slow, andthe flowers either failed to develop normally or were of poorquality. The mechanism whereby the bulb controls the activityof its mitochondria is at present unknown, but the rise in sucroselevels and its subsequent redeployment to the shoot broughtabout by cold treatment appear essential for normal flowering.     

Effects of exogenous gibberellins and paclobutrazol on floral stalk growth of tulip sprouts isolated from cooled and non-cooled tulip bulbs

The involvement of gibberellins (GAs) in the regulation of floral stalk elongation and flower development has been studied in tulip. The biological activity of GA₄ and GA₉, both endogenous in tulip bulb sprouts, and GA₁, was tested in vitro on sprouts of cooled and non-cooled tulip bulbs ( Tulipa gesneriana L. cv. Apeldoorn), in the presence or absence of the GA biosynthesis inhibitor paclobutrazol. At early starting dates of incubation, floral stalks from both cooled and non-cooled bulbs hardly showed any elongation in the absence of exogenous GA. Paclobutrazol had no effect on floral stalk elongation, and the response to GAs of sprouts from cooled bulbs was greater than that of sprouts from non-cooled bulbs. At later starts of incubation, considerable floral stalk elongation occurred without GA application. Paclobutrazol inhibited this floral stalk elongation, and the growth of sprouts from both cooled and non-cooled bulbs was stimulated by GA application. The effect of paclobutrazol was reversed by simultaneous application of GA₄ or GA₉. Application of GA with and without paclobutrazol resulted in the same elongation of the floral stalk, indicating the absence of substantial side effects of the inhibitor. The isolated sprouts did not develop a full-grown flower without the addition of GA. GA₄ was more effective than GA₉ in stimulating this flower development. The results demonstrate that both sprouts from cooled and non-cooled bulbs are responsive to exogenous GAs in vitro, and may be a site of GA biosynthesis.     

Flower bud abortion influences clonal growth and sexual dimorphism in the understorey dioecious shrub Aucuba japonica (Cornaceae)

Sexual differences were investigated to determine the significance of flower bud abortion in the dioecious shrub Aucuba japonica Thunb. The mean number of flowers per inflorescence and the mean number of flowering inflorescences (as opposed to aborted inflorescences) per individual were greater in males than in females in 1997 and 1998. Reproductive investment by males was 0.4-times (1997) and 1.4-times (1998) that by females. In addition, females aborted 30.9% (1997) and 42.7% (1998) of their total flower buds without blooming, whereas no male flower buds aborted. One of the architectural traits of this shrub is that in the year that a flower bud is produced at the shoot apex, the shoot will branch into two or more shoots. Thus, there was less sexual difference in the number of current shoots per individual than there was in the number of flowering inflorescences. The relationship between annual growth and reproduction, and the probability of reproduction in the following year, suggested that the higher investment in female reproduction was manifested as a cost for reproductive frequency rather than as a cost for annual growth. The spatial distribution of both males and females was clumped, which may be the result of clonal growth. In addition, overall sex ratios were not skewed and the number of sprouts did not differ significantly between sexes. These results suggested that flower bud abortion by females might reduce sexual dimorphism in terms of clonal growth.     

Augusta disease in tulip - a reassessment

In an experiment in which the roots of field-grown tulip were commonly infected with tobacco necrosis virus (TNV), Augusta disease did not develop in the year of infection or when progeny bulbs were grown in the field or glass-house. When tulip bulbs of other stocks, including grades of 11 and 12 cm circumference, were forced, the disease developed sporadically, in some instances as the result of infection with TNV from the soil in which they were planted and in others as a result of infection by bulb-borne virus. The incidence of disease produced by current year infection was increased by warming the plunge bed. Different strains of TNV were obtained from field-grown plants with Augusta disease and different strains of the virus produced the disease when inoculated to tulip. Some, but not all, naturally diseased plants contained satellite virus, which therefore does not cause or prevent disease development. The disease was produced in some plants by TNV transmitted by Olpidium brassicae, but neither a vector nor a non-vector isolate of O. brassicae completed its life cycle in tulip. However, Olpidium-like zoospores were observed in some washings of tulip roots from TNV-infested soils. TNV was not obtained from all tulip plants with necrotic leaf symptoms resembling Augusta disease. Some were infected with tomato bushy stunt virus or cucumber mosaic virus, or with another agent that was transmitted by inoculation of sap to Nicotiana clevelandii and Chenopodium quinoa, and carried by bulbs of up to 11 cm circumference.     

Effect of Assimilate Supply on Development and Growth Potential of Axillary Buds in Roses

The effect of assimilate supply on axillary bud developmentand subsequent shoot growth was investigated in roses. Differencesin assimilate supply were imposed by differential defoliation.Fresh and dry mass of axillary buds increased with increasedassimilate supply. The growth potential of buds was studiedeither by pruning the parent shoot above the bud, by graftingthe bud or by culturing the bud in vitro. Time until bud breakwas not clearly affected by assimilate supply during bud development,Increase in assimilate supply slightly increased the numberof leaves and leaf primordia in the bud; the number of leavespreceding the flower on the shoot grown from the axillary budsubstantially increased. No difference was found in the numberof leaves preceding the flower on shoots grown from buds attachedto the parent shoot and those from buds grafted on a cutting,indicating that at the moment of release from inhibition thebud meristem became determined to produce a specific numberof leaves and to develop into a flower. Assimilate supply duringaxillary bud development increased the number of pith cells,but the final size of the pith in the subsequent shoot was largelydetermined by cell enlargement, which was dependent on assimilatesupply during shoot growth. Shoot growth after release frominhibition was affected by assimilate supply during axillarybud development only when buds sprouted attached to the parentshoot, indicating that shoot growth is, to a major extent, dependenton the assimilate supply available while growth is taking place.Copyright1994, 1999 Academic Press Assimilate supply, axillary bud, cell number, cell size, defoliation, development, growth potential, meristem programming, pith, Rosa hybrida, rose, shoot growth     

Study on the Annual Periodicity of Growth and Development of Friellaria Palldiclora Schrenk

According to the observations under the climate at 1700 meters above sea level of mountainous district, the annual periodity of growth and development of fritillary (Fritillaria pallidifora Schrenk.) is briefly described as folldowing: The young shoot sprouts out of the bulb and emerges from the soil in April every year, and forms flowers and fruits in succession. During this period the nutrients of underground bulbs exhaust themselves and a new buld is thereby regenerated. In the middle of June, the aerial part dried up. The regeneration bud in the underground bulb differentiats itself under the condition of 8–22 ℃ in surmruer and an axillary bud is simultaneously initiated. The bulb thus formed dormants in the winter. The growing period of fritillary is only 80–90 days above the ground and 270–280 days beneath the ground. Hence, the whole developmental process of a regeneration bud of fritillary has to pass through three successive growing seasons under the normal conditions in which the growth confined to the inside of bulb lengthens to 600 days approximately. With comparison of the other bulbous plants the characteristics of the development of fritillary may be defined as follows: 1. The regeneration bulb can be formed under the condition of short-day light on even under complete darkness. In contrast with fritillary, the formation of new bulb of onion and other bulbous plants occurs under the longdag light. 2. It is certainly known that a critical size of rhizome or bulb is required for flower formation of Iris and tulip. A similar phenomena has been observed for fritillary in the present experiment. The critical size of bulb for flower initiation of fritillary is taken by us as 1.8–2.7 girfresh weight and 1.2–2.2 cm in diameter. This has nothing to do with the age of the bulb. 3. Different optimum tempertures are neccessary for various developmental stages of fritillary respeetivtly. The normal development periodicity of fritillary may be modified by the onset of dormancy under the condition of low temperatures. Using this method, a secondary shoot will grow up in one growing season. This is in confirmation of the report on the experiment of an other fritillary.