Initial stages in the course of adventitious bud formation on embryos of Picea abies

Adventitious buds on embryos of Picea abies (L.) Karst. developed after a pulse treatment with 250 μ M benzyladenine (BA) of pH 5.5 for 2 h. Light and temperature regimes were not critical during the initial stages. Adventitious buds developed faster after a pulse treatment and the variation among different experiments was lower compared to when the embryos were cultured on media supplemented with BA. Various stages of the differentiation of adventitious buds were identified: stage 1 - appearance of meristematic centres (approximately the first two weeks); stage 2 - development of adventitious bud primordia (approximately the third week); stage 3 - adventitious bud development (from approximately the 4th to the 8th week). This system may be used for further studies on bud differentiation.     

细叶百合的生物量和营养分配

 以栽培的2年生细叶百合（Lilium pumilum）为材料,于2000年的生长季从蕾期至种子成熟期进行6次取样,对其各器官生物量和氮、磷元素的配置进行了动态研究。结果表明,细叶百合虽然以种子繁殖为主,但在整个生长季用于生殖器官的生物量投资的比例并不很大,大量干物质分配到地下器官鳞茎中（平均为60.17%）;茎、叶的生物量分配比例仅次于鳞茎;雄蕊生物量分配比例明显高于雌蕊。在叶萌动及展叶初期植株全氮百分含量最高;从春季萌动至秋季果实成熟,叶中的氮呈逐渐递减的趋势;茎和生殖器官的全氮含量在蕾期最大;生殖器官与叶、鳞茎的全氮含量相关显著。磷在生殖器官的含量较高,这与磷在植物有性生殖过程中的重要作用相一致;生殖器官与茎的全磷含量相关显著。地下器官全氮、全磷随季节变化有增多的趋势;地上各器官全氮、全磷相关显著,随季节变化有明显减少的趋势。     

Floral morphogenesis and flowering in aseptic cultures ofBrowallia demissa L

Floral buds ofBrowallia demissa, at three stages of development, were cultured on Nitsch and Nitsch basal medium. The supplements used include IAA; several cytokinins— benzyladenine, kinetin and 6-benzyl-9 tetrahydropyran-adenine (SD 8339); gibberellic acid (GA₃); 2, 3, 5-triiodobenzoic acid (TIBA); arginine and cysteine. All three stages of floral buds failed to complete development. In some treatments stages II and III produced callus and/or roots from the morphological basal end. Cytokinins promoted bud formation whereas both IAA and GA₃ depressed bud formation The shoots differentiatedin vitro were capable of setting flowers, fruits and seeds in all the treatments. The seeds were viable. Comparative studies of development of flowersin vivo andin vitro were made. In some treatments the flowers exhibited abnormal corolla, and roecium and gynoecium. Factors affecting normal bud initiation, organization and development are discussed.     

Chitin structures of the cell walls of synchronously grown virgin cells of Saccharomyces cerevisiae.

The ability of a lytic beta-glucanase of Arthrobacter GJM-1 to dissolve cell walls of Saccharomyces cerevisiae with exception of the chitin-containing fraction was employed for the isolation of chitin-rich residues of the cell walls of synchronously growing populations of virgin cells. Electron microscopical examination of such wall residues isolated from cells at various stages of the budding cycle showed that the first phase of chitin deposition in the wall corresponds to the formation of an annular structure found as a part of the bud scar after cell division. The annular chitin-rich structure could not be isolated at cell cycle stages preceding the bud emergence and at earliest stages of bud development. The observations confirmed that the annular structure (chitin ring) formed during bud growth represents a major part of total chitin present in the bud scar after septum closure.     

A staging system for mouse limb development

A series of 15 stages of development for the mouse limb bud have been defined, spanning the time from the first appearance of the limb bud to the completion of limb outgrowth. The stages are based on changes in the morphology of the limb in living preparations. The development and regression of the apical ectodermal ridge (AER) as well as the development of the skeletal structures are also described. This staging system has been developed in response to the need to standardize in situ experimental analyses of the mouse limb bud. Comparable stages of the commonly used chick wing and mouse whole embryo systems are presented.     

Distribution of vimentin in the developing chick taste bud during the perihatching period.

The tissue environment within which taste bud cells develop has not been wholly elaborated. Previous studies of taste bud development in vertebrates, including the avian chick, have suggested that taste bud cells could arise from one, or several tissue sources (e.g. crest-mesenchyme, local ectoderm or endoderm). Thus, molecular markers which are present in gemmal as well as interfacing (peribud epithelium; mesenchyme-epithelium) regions, and their degree of expression during stages of taste bud development, are of special interest. The intermediate filament protein, vimentin, occurs in mesenchymal and mesodermally-derived (e.g. endothelial, fibroblast) cells as well as highly proliferating epithelium (e.g. tumors). The present study in chick gustatory tissue utilized antibodies against vimentin and the avidin-biotin-peroxidase technique to evaluate vimentin immunoreactivity (IR) within a timeframe which includes: 1) early stages of the taste bud primordium [embryonic days (E)17-E18)]; 2) the beginning of an accelerated bud cell proliferation at the time of initial, taste bud pore opening [around E19]; 3) attaining the adult complement of taste buds [around posthatch (H) day 1], and 4) completed organogenesis (H 17). During this time span, vimentin-IR was characterized in a region including and sometimes bridging taste bud and subepithelial connective tissue, whereas non-gustatory surrounding epithelium and salivary glands were vimentin-immuno-negative. Intragemmally, the proportion of vimentin-IR cells as related to total taste bud cells peaked at E19. These results indicate that vimentin expression, in part, is related to the onset of taste bud cell proliferation and suggest that mesenchyme could be one source of taste bud cells. Secondly, fibronectin, an extracellular matrix component of the epithelial basement membrane interface with mesenchyme, was expressed at or near the apical surfaces of taste bud cells projecting into the bud lumen, and in the basal gemmal region suggesting the possible role of fibronectin as a chemotactic anchor for differentiating and migrating taste bud receptor cells. Lastly, neuron-specific enolase-IR indicates that axonal varicosities are already present intragemmally at E17-E18, that is, during the incipient period of identifiable taste bud primordia.     

Changes in water potential and its components during shoot formation in tobacco callus

Addition of plant growth regulators (5 nM NAA and 5μM BAP) to a defined basal medium stimulated adventitious bud formation of Douglas fir (Pseudotsuga menziesii [Mirb.] Franco) cotyledon explants in culture. Cytoplasmic soluble proteins synthesized during early stages of adventitious bud formation were analyzed by electrophoresis of ³H- and ¹⁴C-leucine labeled proteins on SDS polyacrylamide gels. Increased synthesis of low molecular weight proteins (16,000 to 20,000 daltons) was detected after 2 days in culture and reached a maximal level at day 4. When cotyledon explants cultured on bud medium for 2 days were transferred to callus medium (which suppressed adventitious bud formation), suppression of the synthesis of low molecular weight proteins was also observed, suggesting that these proteins may be associated with early stages of adventitious bud formation.     

Phenological growth stages of North American ginseng (Panax quinquefolius)

The BBCH (Biologische Bundesanstalt, Bundessortenamt, Chemische Industrie) scale is used to describe the phonological growth stages of North American ginseng (Panax quinquefolius). Eight principal growth stages for germination and bud development, leaf development (crop canopy), root and perennating bud formation, peduncle elongation and inflorescence development, flowering and fruit set, development of fruit, ripening of fruit and senescence, and 42 secondary growth stages are described. A practical use of the scale is proposed with reference to the timing of application of agrochemicals for disease control.     

Immunohistochemical distribution of CD44 and some of its isoforms during human taste bud development

 Taste buds are accumulations of elongated bipolar cells situated on lingual papillae. The factors that determine the sites where a taste bud may develop are largely obscure, although it is known that the early invasion of nerve fibers plays one of the key roles in taste bud development and maturation. The conditions under which taste bud primordium cells develop are influenced by the interaction between epithelial cells and extracellular matrix molecules of the mesenchyma, such as hyaluronan. Thus, we investigated immunohistochemically the distribution pattern of the receptor for hyaluronan, CD44s, and its epithelial variant isoforms CD44v6 and CD44v9, in taste buds of human embryonic, fetal, perinatal, and adult tongues. Furthermore, we wanted to determine the temporal and spatial relationships of CD44 to sensory innervation of taste bud primordia. In early gestational stages (weeks 7–9), CD44 and its isoforms are expressed on membranes of apical perigemmal (marginal) cells covering taste bud primordia. It seems that CD44 serves as a marker for marginal cells (perigemmal cells) in early developmental stages. The expression of CD44 follows rather than precedes the invasion of sensory nerve fibers and the development of taste bud primordia (weeks 7–8). In new-born and adult taste bud cells, only the standard molecule, CD44s, is expressed; the variant isoforms, CD44v6 and CD44v9, occur only in the adjacent epithelium. From these results it is likely that marginal cells are of the utmost importance for the development and maturation of taste buds. We presume that CD44 is involved in local binding, reuptake, and degradation of hyaluronan in the early stages of taste bud formation. CD44 probably does not induce the transformation of epithelial cells into taste bud primordial cells. What is more, CD44 may change its function in the course of developmental events. Accepted: 13 January 1998     

芋侧球茎发生发育的形态学机理

观察了魁芋和多子芋腋芽、侧球茎发生发育的形态学变化规律,分析了主球茎顶芽和不同发育期腋芽中蛋白质的组成。结果表明,魁芋每一叶轮上腋芽数目为１;多子芋为３或３个以上,其中一个体积较大。魁芋侧球茎发育初期伸长的速度大于增粗,首先形成圆柱型,然后顶端膨大形成体积很小的侧球茎。多子芽腋芽伸的同时茎部明显变粗,首先形成圆锥型,然后发育成品种特有的形状。根据发育进程将腋芽发育分成ＡＢ１－ＡＢ９个时期,将主球茎     

Morphological markers to correlate bud and anther development with microsporogenesis and microgametogenesis in pepper (Capsicum annuum L.)

The identification of microspores or pollen grains at particular developmental stages during microsporogenesis or microgamentogenesis is an important step for different basic and applied purposes. Among them, the most relevant example from a biotechnological perspective is the production of androgenic doubled haploids. For this and other techniques, precise, fast, easy and reliable criteria to identify flower buds carrying microspores or pollen at particular stages are essential. In anthocyanin-producing pepper types, the particularities of flower development allow for the identification of several morphological markers potentially useful as criteria for such an identification. In this work, our aim was to determine the easiest and more accurate criterion to correlate visible, measurable traits of bud and anther development with each of the individual stages of microsporogenesis and microgametogenesis. For this, we used three Spanish sweet pepper F1 hybrids (‘Herminio’, ‘Gacela’ and ‘Águila’). We analyzed and discussed the accuracy and practical usefulness of using anther length, bud length, anther purple pigmentation and the ratio between calyx length and bud length (calyx/bud ratio) as predictors of individual microspore/pollen developmental stages. According to our results, we propose a combination of calyx/bud ratio and anther pigmentation as an easy, fast and accurate criterion potentially applicable to anthocyanin-producing pepper cultivars to determine their particular markers.     

Stage-dependent effects of retinoic acid on regenerating urodele limbs

Summary Following amputation through the distal zeugopodium, regenerating limbs of larvalAmbystoma mexicanum and pre and post-metamorphicPleurodeles waltlii were treated with 150 g of retinoic acid (RA) per gram of body weight, at the dedifferentiation, early bud, medium bud, late bud or early redifferentiation stages of regeneration. The effect of RA on regenerate morphogenesis differed as a function of the stage at which it was administered. When given during dedifferentiation or at early bud stages, RA evoked proximodistal duplications of stump segments in the regenerates. The maximum duplication index (DI) inAbystoma was achieved when RA was injected at 4 days post-amputation, which corresponds to the stage of dedifferentiation; and inPleurodeles at 10 days post-amputation, which corresponds to a stage midway between early bud and medium bud. When RA was administered at later stages, the DI declined progressively to zero or nearly zero by the stage of early redifferentiation in both species. The decline in DI was due to a decreased frequency of duplication, not to a decrease in the magnitude of duplication in individual regenerates. At the same time, there was an increase in hypomorphism and aberrant morphogenesis of both duplicating and non-duplicating regenerates. These results indicate that regenerative cells are differentially sensitive to RA in a stage-dependent way.     

Experimental manipulation leading to induction of dorsal ectodermal ridges on normal limb buds results in a phenocopy of the eudiplopodia chick mutant

Elongation of chick limb buds depends on the presence of the apical ectodermal ridge which is induced by subjacent limb bud mesoderm. Recombination experiments have shown that the limb bud mesoderm loses the capacity to induce ridges by late stage 17. Moreover, in normal limb development only one ridge forms. However, in the eudiplopodia chick mutant accessory ectodermal ridges form on the dorsal surface of limb buds as late as stage 22. Tissue recombinant experiments show that the mutation affects the ectoderm, extending the time it responds to ridge induction (Fraser and Abbott, 1971a, Fraser and Abbott, 1971b while the mesoderm is normal. The result is polydactyly, with extra digits dorsal to the normal digits. Because eudiplopodia limb bud dorsal mesoderm can induce ridges at stage 22 but is unaffected by the gene, genetically normal dorsal limb bud mesoderm may also be able to induce ridges after stage 17. To test this possibility we grafted stages 14–18 flank ectoderm to normal limb bud dorsal mesoderm and found that mesoderm from stages 17 through 20 was able to induce a ridge and subsequently dorsal digits developed. Limbs with duplicate digits were similar to eudiplopodia limbs. In other experiments, stage 18, 19, and 20 leg bud dorsal ectoderm did not form ridges when grafted to leg bud dorsal mesoderm of the same stage, indicating a lack of response to the mesoderm. Finally, the inductive capacity of limb bud mesoderm appeared to be reduced compared to mesoderm at pre-limb bud stages. These experiments demonstrate a spatially generalized potential in limb bud dorsal mesoderm to induce ridges during the stages when the apical ridge is induced. The determination of where the ridge will form and the acquired inability of limb bud dorsal ectoderm to respond to induction by underlying mesoderm are necessary early pattern forming events which assure that a single proximodistal limb axis will form.     

2个果梅品种雌蕊分化进程及相关生化指标分析

为了解果梅(Prunus mume Sieb.et Zucc.)雌蕊分化进程及其败育机制,采用石蜡切片法观察了不同时期果梅品种‘龙眼’(‘Longyan’)和‘大嵌蒂’(‘Daqiandi’)花芽纵切面的解剖结构,并对2个品种不同时期花器官发育状况、花芽百分率、花芽纵径和横径以及花芽中的可溶性糖、可溶性蛋白质和淀粉含量进行了测定分析.结果显示:雌蕊分化期、雌蕊分化末期及盛花期,品种‘龙眼’的不完全花比例均显著小于品种‘大嵌蒂’,其中,盛花期‘龙眼’不完全花比例仅为5.0％,而‘大嵌蒂’不完全花比例高达76.3％.品种‘龙眼’雌蕊分化过程经历未分化期、分化初期、分化期及分化末期4个阶段,且最终有95.0％的花芽在分化末期能顺利形成完全花;品种‘大嵌蒂’雌蕊分化过程则包含未分化期、分化初期、分化期、解体期、解体后修复期和分化末期6个阶段,且仅有23.7％的花芽能形成完全花.雌蕊分化的不同阶段2个品种花芽纵径和横径的变化与其分化进程基本一致.品种‘龙眼’完全花的可溶性糖和可溶性蛋白质含量均高于品种‘大嵌蒂’的完全花和不完全花、淀粉含量则低于后两者;品种‘大嵌蒂’不完全花的可溶性糖和可溶性蛋白质含量最低、淀粉含量则最高,与2个品种的完全花有显著差异.综合分析结果表明:品种‘大嵌蒂’的花芽在12月中上旬停止伸长生长、雌蕊分化停滞直至逐渐解体,这一时期即为品种‘大嵌蒂’雌蕊败育的关键时期;导致果梅雌蕊选择性败育的原因可能与花芽中大分子营养物质的分解代谢有关.     

Mapping of quantitative trait loci controlling adaptive traits in coastal Douglas-fir. I. Timing of vegetative bud flush

Thirty three unique quantitative trait loci (QTLs) affecting the timing of spring bud flush have been identified in an intraspecific mapping population of coastal Douglas-fir [Pseudotsuga menziesii (Mirb.) Franco var. menziesii]. Both terminal and lateral bud flush were measured over a 4-year period on clonal replicates at two test sites, allowing for the repeated estimation of QTLs. QTLs were detected on 12 linkage groups and, in general, each explained a small proportion of the total phenotypic variance and were additive in effect. Several QTLs influence the timing of bud flush over multiple years, supporting earlier evidence that the timing of bud flush through developmental stages is under moderate to strong genetic control by the same suite of genes through developmental stages. However, only a few QTLs controlling the timing of bud flush were detected at both test sites, suggesting that geographic location plays a major role in the phenology of spring growth. A small number of QTLs with year and site interactions were also estimated. Received: 20 July 2000 / Accepted: 19 October 2000     

Distribution of retinoids in the chick limb bud: analysis with monoclonal antibody

Retinoic acid induces anteroposterior duplicate formation in developing chick limb bud, and it may be a natural morphogen involved in limb pattern formation. Retinoic acid is produced from retinol locally in the limb bud via retinal, and thus, to elucidate the distribution of these retinoids in the limb bud seems to be important for the understanding of the morphogen formation. We produced a monoclonal antibody against the retinoids with BSA-RA (bovine serum albumin-retinoic acid) conjugate for antigen, and investigated the distribution of retinoids in the chick limb bud. The antibody predominantly bound to retinoic acid, but weakly to retinol and retinal. Retinoids appeared in the limb bud at stage 18 and were distributed through stages 20-24, when the pattern formation in distal mesoderm was in progress. Initially they were found evenly in the whole mesoderm, but disappeared gradually from core mesoderm and remained only in the region of peripheral mesoderm at stage 24. At stage 26, retinoids were detected only in ectoderm. These results support the idea that the retinoids actually play roles in limb pattern formation and suggest that the retinoids in the peripheral mesoderm are important for pattern formation. Further, the role of retinoids in epidermis development at later limb bud stages is also suggested.     

Floral gradient in flowering tobacco in relation to free amino acids

By employing TCLs (thin cell layers) culture, the floral gradient in flowering tobacco of different developmental stages was confirmed. The TCLs from early flowering tobacco regenerated more floral buds than those from the tobacco plants in full blooming or fruiting stages. Analysis of free amino acid levels revealed the acropetal gradient of Pro in flowering tobacco stem. L-Pro. L-Trp. D,L-Met and L-Arg were respectively added into the culture medium for testing their influence on floral bud formation from tobacco pedicel segments. Only L-Trp evidently enhanced the floral bud neoformation.     

银杏LEAFY同源基因的时空表达

以银杏雄株、雌株成年树和还未开过花的幼树的根、茎、叶,雌株幼果和不同时期的雄花芽、雌花芽为材料,利用同位素标记,制备Ginlfy和GinNdly两个特异探针,进行Northern分子杂交,研究银杏LFY同源基因Ginlfy、GinNdly在银杏不同器官,花芽不同生长发育时期的时空表达情况。结果显示,无论是幼树,还是成年的雌株、雄株,Ginlfy基因在各个器官,如根、茎、叶、雌花芽、雄花芽、幼果以及雌花芽、雄花芽的不同发育时期都有表达,属组成型表达,而GinNdly基因只在叶和不同时期的雄花芽、雌花芽中表达,其他器官都不表达,属特异性表达。银杏双拷贝LFY同源基因中的GinNdly基因可能与开花关系更为密切。 Abstract: Expressions of Ginlfy and GinNdly gene were studied by northern blotting in different organs and stages of Ginkgo Biloba. Ginlfy gene was expressed in different organs such as root, stem, leaf of juvenile tree, male tree and female tree, and in different stages of male flower bud and female flower bud. It was inferred that Ginlfy gene could be expressed constitutionally. GinNdly gene was only expressed in leaf of juvenile tree, male tree and female tree and in different stages of male flower bud and female flower bud, while GinNdly gene was not expressed in the other organs. Therefore it was thought that GinNdly gene could be expressed differentially and be a close relation to development of flower.