神经干细胞定向分化过程中溶酶体表达变化的研究

目的对神经干细胞向神经元定向分化过程中溶酶体的表达变化进行观察研究。方法采用细胞培养技术、荧光免疫细胞化学技术以及光电镜酶细胞化学技术对神经干细胞向神经元定向分化过程中溶酶体的表达变化进行观察。结果在神经干细胞向神经元定向分化的过程中,随着细胞分化的不断成熟,溶酶体的表达亦发生着变化。分化初期主要以核周附近表达明显,至神经元分化成熟则散在分布于胞质中及突起内,且表现有圆形、线状两种形态。结论在神经干细胞向神经元定向分化过程中溶酶体发生表达分布的变化,说明其参与了细胞的代谢和细胞内物质的运输。     

山鸡椒雄花花芽发育形态解剖特征观察

采用体视显微镜、扫描电镜和石蜡切片技术对山鸡椒（Litsea cubeba（Lour.） Pers.）雄花花芽分化发育的外部形态和内部解剖结构进行了观察研究。结果显示:（1）山鸡椒雄花花芽分化发生可分为5个时期,即未分化期、花序原基分化期、苞片原基分化期、花原基分化期和花器官分化期,其中花器官分化期又可细分为花被原基分化期、雄蕊原基分化期和雌蕊原基分化期;各相邻分化时期存在一定重叠现象;花期从翌年1月上旬至3月下旬。（2）雄花成熟结构中具有独特的雄蕊蜜腺,蜜腺绿色且形态不规则,着生于内轮雄蕊基部,分布于花丝两侧,夹在内外轮雄蕊的花丝之间,与内轮花丝紧密相连。（3）雄蕊花药四室,花药壁发育属于基本型;腺质绒毡层;小孢子母细胞减数分裂过程中胞质分裂属于连续型;成熟花粉为2-细胞花粉粒;成熟花粉粒外壁刺突较多,刺突基部膨大,外壁露出部分粗糙,无薄壁区,有少数小穿孔。（4）山鸡椒雄花中绝大多数雌蕊发育至腹缝线卷合形成子房室时停止,柱头发育不良或者败育,花柱缩短或缺失,不能受精,直到开花结束,即发生退化。本研究明确了山鸡椒雄花花芽发育发生各个阶段时间、形态变化特点及外部形态变化特征,山鸡椒小孢子发生、雄配子体发育至散粉期变化特点和规律以及雄花中退化雌蕊发育的进程,可为山鸡椒优良品种选育、调控花期和提高结实率提供一定的参考。     

新疆医科大学基础医学院组织胚胎学教研室

目的:观察国人胚胎三叉神经节细胞分化及发育过程。方法:取水囊引产18-36周国人胎儿三叉神经节,HE染色及透射电镜观察。结果:18-20周胎儿三叉神经节神经元排列紧密,胞质少,可见到数量不多的线粒体,且其内几乎看不到嵴,其它细胞器少。25周时,线粒体嵴变长,粗面内质网雏形出现,有纵形小管出现;27周时可观察到成熟的高尔基复合体,32周后,线粒体、粗面内质网等细胞器发育趋于成熟。到33周电镜下可见溶酶体;36周时细胞内各种细胞器结构和功能基本完善。结论:人胚胎三叉神经节细胞发育过程中随胎龄增加,其结构和功能逐步完善,32～36周(8～9月)是细胞的分化发育重要时期。     

枸杞体细胞胚发生中Ca2+和ATPase的超微结构定位研究

研究2,4-D诱导枸杞体细胞胚发生中的作用及其与Ca~(2+)含量和ATPase活性时空分布动态之间的关系,以探讨2,4-D诱导植物体细胞胚发生的作用机理。采用超微细胞化学定位的方法,跟踪分析了体细胞胚发生与发育的不同时期,Ca~(2+)和ATPase活性的时空分布动态。结果表明:2,4-D是诱导离体培养的枸杞体细胞进入胚胎状态的关键激素。在含有2,4-D和不含2,4-D的培养条件下,分别诱导枸杞体细胞脱分化后,再转入除去2,4-D的MS培养基上,进行分化培养,结果前者可分化形成体细胞胚,因而称为胚性愈伤组织。后者在相同条件却不能分化形成胚,故称为非胚性愈伤组织。在2,4-D诱导枸杞的胚性愈伤组织中,胚性细胞分化早期的细胞间隙和细胞壁上均有Ca~(2+)沉淀。随着胚性细胞的分化、分裂和多细胞原胚形成,这时Ca~(2+)在细胞内的分布主要集中在细胞膜和液泡膜上;球形胚期在细胞核中Ca~(2+)呈弥散性分布。在此过程中,ATPase活性时空分布与Ca~(2+)的定位变化具有高度一致性,仅仅稍滞后于Ca~(2+)出现的时间。而在胚性细胞分化早期,ATPase活性同样位于质膜上,随后在液泡和细胞核都可见ATPase活性分布。而在非胚性愈伤组织中,则未见Ca~(2+)和ATPase活性呈时空动态分布,而且随着非胚性细胞的液泡化,无论是Ca~(2+)含量,还是ATPase活性都呈逐渐降低的趋势。表明Ca~(2+)和ATPase活性变化与2,4-D诱导的胚性细胞分化和发育密切相关。并由此推测,Ca~(2+)和ATPase的时空分布对胚性细胞分化中的信息传递和调控相关基因表达起着关键性作用。     

毛竹种子形成过程中形态解剖学特征

为揭示毛竹(Phyllostachys edulis)种子生长过程中胚、胚乳、果皮及种皮的发育规律,以桂林海洋山一带的开花毛竹为材料,采集并固定不同时期的开花毛竹种子,使用石蜡制片法制片,显微镜观察胚、胚乳、果皮与种皮的结构变化。结果表明：(1)毛竹花后1 d完成受精并形成合子,合子休眠时长约为5 d。经过原胚阶段、胚芽鞘阶段、幼胚生长阶段及成熟胚阶段,花后40 d的胚发育基本成熟,其发育类型为禾本型。(2)胚乳发育早于胚的发育,其发育类型为核型胚乳,历经游离核、细胞化、细胞分化及成熟4个阶段。在细胞分化阶段胚乳细胞分化形成淀粉胚乳细胞以及糊粉层细胞,淀粉胚乳细胞主要积累淀粉粒,糊粉层细胞主要积累矿质元素、脂类及蛋白质等。(3)花后1 d的果皮细胞及珠被细胞形状规则、内含物丰富、结构完整;花后10～20 d,内、外果皮及珠被细胞层数递减,形状发生改变,中果皮细胞开始出现淀粉粒;花后20～60 d,随着胚乳细胞营养物质的积累及体积的增大,向外产生机械压力,中果皮细胞逐步消解仅剩残留的细胞壁;外果皮细胞呈长条形,细胞壁加厚,与残留的中果皮细胞壁组成保护结构;皮层在种子发育过程中主要起到合成...     

枸杞体细胞胚发生中Ca^2＋和ATPase的超微结构定位研究

研究2,4-D诱导枸杞体细胞胚发生中的作用及其与Ca^2 含量和ATPase活性时空分布动态之间的关系,以探讨2,4-D诱导植物体细胞胚发生的作用机理。采用超微细胞化学定位的方法,跟踪分析了体细胞胚发生与发育的不同时期,Ca^2 和ATPase活性的时空分布动态。结果表明：2,4-D是诱导离体培养的枸杞体细胞进入胚胎状态的关键激素。在含有2,4-D和不含2,4-D的培养条件下,分别诱导枸杞体细胞脱分化后,再转入除去2,4-D的MS培养基上,进行分化培养,结果前者可分化形成体细胞胚,因而称为胚性愈伤组织。后者在相同条件却不能分化形成胚,故称为非胚性愈伤组织。在2,4-D诱导枸杞的胚性愈伤组织中,胚性细胞分化早期的细胞间隙和细胞壁上均有Ca^2 沉淀。随着胚性细胞的分化、分裂和多细胞原胚形成,这时Ca^2 在细胞内的分布主要集中在细胞膜和液泡膜上;球形胚期在细胞核中Ca^2 呈弥散性分布。在此过程中,ATPase活性时空分布与Ca^2 的定位变化具有高度一致性,仅仅稍滞后于Ca^2 出现的时间。而在胚性细胞分化早期,ATPase活性同样位于质膜上,随后在液泡和细胞核都可见ATPase活性分布。而在非胚性愈伤组织中,则未见Ca^2 和ATPase活性呈时空动态分布,而且随着非胚性细胞的液泡化,无论是Ca^2 含量,还是ATPase活性都呈逐渐降低的趋势。表明Ca^2 和ATPase活性变化与2,4-D诱导的胚性细胞分化和发育密切相关。并由此推测,Ca^2 和ATPase的时空分布对胚性细胞分化中的信息传递和调控相关基因表达起着关键性作用。     

小麦根尖细胞分化过程中DNA,RNA和蛋白质含量变化的研究

小麦(Triticum aestivum L.)种子在25℃条件下萌发3d,根生长至1～2cm长时,于双筒解剖镜下严格切取根分生区、伸长区和成熟区。用专一性荧光染料Hochest33258、Pyronin G和FITC分别染细胞核DNA、RNA和蛋白质,并用自动图像分析技术和细胞荧光测定术分别测定三个区中各125个细胞核DNA的相对含量和各100个细胞中RNA和蛋白质的相对含量。核DNA相对含量随着根尖细胞分化的进程,DNA含量递增,成熟区细胞中含量最高。RNA的相对含量则与之相反,在分生区细胞中含量最高,成熟区细胞中含量最低。蛋白质的相对含量则在伸长区细胞中最高,分生区细胞中最低。讨论了根尖细胞分化过程中DNA、RNA和蛋白质三者之间变化的一些内在联系。     

猫视网膜多巴胺能无长突细胞发育的中央—周边梯度

本文报道用酪氨酸羟化酶(TH)免疫细胞化学方法标记猫视网膜多巴胺(DA)能无长突细胞发育的中央—周边梯度。TH阳性反应的I型DA能无长突细胞在发育成熟过程中呈现时空顺序的中央—周边梯度:(1)P_1时期分化较高的细胞,即染色深,胞体大,具有2—4支树突,分枝分布于内网状层(IPL),最外缘的星状Ⅰ_1类细胞大都集中于视网膜的中央部位;而分化较低的细胞,即染色淡,胞体小,具有1—2支树突,分枝分布于IPL外层和中层的不规则形Ⅰ_3类细胞大都集中于视网膜的周边部位;介于两者之间的Ⅰ_2类细胞散在分布于整个视网膜。它们形成了空间分布上的中央—周边分化成熟梯度。(2)随着发育进程,Ⅰ_1类细胞数增多,分布区逐渐从中央向四周扩展,由占视网膜总面积的30%(P_1时)增至65%(P_6时),P_(13)时达97%。开眼后P_(13)时,由于Ⅰ_1类细胞分布已扩展至周边,中央区和周边区间细胞平均直径和树突发育成熟程度的差别逐渐缩小,Ⅰ型DA能无长突细胞发育成熟的中央—周边梯度明显减弱。至P_(23)时,周边区细胞对TH抗体免疫反应强度以及形态学上成熟程度均相似中央区者,上述中央—周边梯度特征则完全消失。I型DA能无长突细胞发育成熟过程中呈现时空顺序的中央—周边梯度特征是视网膜个体发育过程中的暂时现象,它与视网膜中一些神经发生过程存在平行关系。它在视网膜神经发生中的作用,文中进行了讨论。     

珍稀濒危植物巴东木莲胚胎学研究

对巴东木莲(Manglietia patungensis Hu)的花发育以及胚胎发育过程进行了系统研究。巴东木莲花顶生,花器官头年年底开始分化到第二年3月分化出花被、雌雄蕊群直至6月发育成熟。雌蕊成熟时胚珠倒生,双珠被,厚珠心,大孢子四分体线形排列,合点端发育成功能大孢子,珠孔端的3个退化,大孢子为单孢子发生型,胚囊发育方式属蓼型;雄蕊花药外侧壁玫瑰红色,内侧有4个白色花粉囊,绒毡层有1层多核细胞,小孢子四分体排列方式多为左右对称形和交叉形,四面体形,偶为T字形和线形,成熟花粉粒为二细胞型。在巴东木莲花发育和大、小孢子发生以及雌、雄配子体形成过程中未见异常现象,因此笔者认为该物种的花器官发育以及雌、雄配子体发育并不构成导致该物种濒危的因素。     

细胞终末分化过程中三维基因组结构与功能调控的分子机制

真核细胞中的染色质DNA高度折叠形成复杂的三维结构,其空间组织方式对精准调控基因的表达和细胞发挥正常功能都起着重要的作用。细胞终末分化成熟过程中形态及基因表达谱常发生显著改变,同时伴随着明显的基因组三维结构变化。本文在简单介绍三维基因组多层次组织结构(染色质领域、A/B区室、拓扑相关结构域和成环构象等)基础上,重点综述了细胞终末分化过程中三维基因组结构变化与功能调控方面的研究进展,并探讨了当前三维基因组研究在解析细胞分化成熟过程时存在的问题和前景。     

忍冬属植物开花过程中绿原酸类化合物含量的变化

忍冬是中国传统中药材金银花的药源植物。采用高效液相色谱—光电二极管阵列检测器联用技术(HPLC-PAD)和高效液相色谱—电喷雾离子化—多级质谱联用技术(HPLC-ESI-MSn)对忍冬和4种同属植物在开花不同阶段中绿原酸类化合物进行了定性和定量分析,以明确忍冬属植物花的利用价值及其最佳采收期。结果发现:4种忍冬属植物花蕾及开放花朵中均含有新绿原酸、绿原酸、绿原酸甲酯、异绿原酸A和一种异绿原酸的异构体;绿原酸和总绿原酸在花蕾中的含量高于开放花朵,但贯月忍冬变化不显著;火焰忍冬、贯月忍冬、台尔曼忍冬中绿原酸和总绿原酸的含量在花蕾膨大期(大白期)和初花期(银花期)都高于忍冬,而格雷姆忍冬和忍冬差异不显著,研究表明,4种忍冬属植物花及花蕾都具有较高的开发利用价值。     

Variation of Bioactive Compounds in Hypericum perforatum Growing in Turkey During Its Phenological Cycle

The present study was conducted to determine phenologic and morphogeneUc variation of hyperlcln, chlorogenlc acid and flavonoids, as rutin, hyperoside, apigenin-7-O-glucoside, quercitrin, quercetin content of Hypericum perforatum L. growing in Turkey. Wild growing plants were harvested at vegetative, floral budding, full flowering, fresh frulUng and mature fruiting stages and dissected into stem, leaf and reproductive tissues and assayed for bioacUve compounds by the High performance liquid chromatography （HPLC） method. Hypericin concentration ranged between 0 and 2.73 mg/g DW, chlorogenic acid 0.00-3.64 mg/g DW, rutin 0.00-3.36 mg/g DW, hyperoside 0.04- 22.42 mg/g DW, quercitrin 0.03-3.46 mg/g DW and quercetin 0.04-1.02 mg/g DW depending on ontogenetic and morphogenetic sampling. Leaves were found to be superior to stems and reproductive parts with regard to phenolic accumulation for all compounds tested while flowers accumulated the highest levels of hypericln. Quercltrln, quercetln and hypericin content in all tissues increased with advancing of developmental stages and reached their highest level during flower ontogenesis. Similarly, chlorogenic acid, hyperoside and apigenin-7-O-glucoside content in different plant parts increased during plant development, however, the highest level was observed at different stages of plant phenology for each tissue. Chlorogenic acid was not detected in stems, leaves and reproductive parts in several stages of plant phenology and its variation during plant growth showed inconsistent manner. In contrast to the other compounds examined, rutin content of stems and leaves decreased with advanc- ing of plant development and the highest level for both tissues was observed at the vegetative stage. However, content of the same compound in reproductive parts was the highest at mature fruiting. The present findings might be useful to obtain increased concentration of these natural compounds.     

穗花牡荆花芽分化过程中形态和生理指标变化

以穗花牡荆为研究材料,通过探究其花芽分化进程和生理特性,为花期调控技术提供成花机理。采用物候期观察和石蜡切片相结合的方法并测定花芽分化过程中相关生理指标,研究花发育过程中的形态和生理变化。结果表明,穗花牡荆花芽分化为一年多次分化型,其进程可划分为七个时期：未分化期、总轴花序原基分化期、初级分轴花序原基分化期、次级分轴花序原基分化期、小花原基分化期、花器官分化前期和花器官分化后期。同一植株不同位置花芽及同一花序中不同单花分化的进程不同,第一季花期后各阶段的花芽分化形态常存在重叠。花芽分化过程中不同时期叶片和花芽的可溶性糖和可溶性蛋白质含量均有上升下降的变化,总体上叶片中营养物质含量高于花芽保证营养供应。花芽分化过程中,IAA、ABA、CTK和GA3整体水平上先升后降有利于花芽分化进行。研究认为,花芽中大量的可溶性糖和蛋白质积累及较高的碳氮比,有利于穗花牡荆花芽形态分化顺利完成。低水平的GA3/ABA和IAA/CTK有利于花序的形成,ABA/CTK和ABA/IAA比值升高促进小花原基和小花萼片原基的分化, GA3/CTK、GA3/ABA和GA3/IAA比值升高促进花瓣原基、雄雌蕊原基发育。     

Cellular and subcellular localization of S-adenosyl-L-methionine:benzoic acid carboxyl methyltransferase, the enzyme responsible for biosynthesis of the volatile ester methylbenzoate in snapdragon flowers.

The benzenoid ester, methylbenzoate is one of the most abundant scent compounds detected in the majority of snapdragon (Antirrhinum majus) varieties. It is produced in upper and lower lobes of petals by enzymatic methylation of benzoic acid in the reaction catalyzed by S-adenosyl-L-methionine:benzoic acid carboxyl methyltransferase (BAMT). To identify the location of methylbenzoate biosynthesis, we conducted an extensive immunolocalization study by light and electron microscopy at cellular and subcellular levels using antibodies against BAMT protein. BAMT was immunolocalized predominantly in the conical cells of the inner epidermal layer and, to a much lesser extent, in the cells of the outer epidermis of snapdragon flower petal lobes. It was also located in the inner epidermis of the corolla tube with little BAMT protein detected in the outer epidermis and in the yellow hairs within the tube on the bee's way to the nectar. These results strongly suggest that scent biosynthetic genes are expressed almost exclusively in the epidermal cells of floral organs. Immunogold labeling studies reveal that BAMT is a cytosolic enzyme, suggesting cytosolic location of methylbenzoate biosynthesis. The concentration of scent production on flower surfaces that face the pollinators during landing may increase pollination efficiency and also help to minimize the biosynthetic cost of advertising for pollinators.     

A floral third whorl-specific marker gene in the dioecious species white campion is differentially expressed in mutants defective in stamen development

The CCLS4 gene of white campion is specifically expressed in anther epidermis and endothecium from pre- to post-meiotic stages. We report on a detailed in situ analysis of the gene's expression and show that it is a marker of the floral third whorl. The gene is expressed (1) in the anther (epidermis, parietal cells and the derived endothecium) in normally developing stamens and (2) in distinct sub-domains of third-whorl epidermis in mutants exhibiting aberrant states of parietal differentiation. Our results suggest that CCLS4 may fulfil different functions during pre- and post-meiotic anther development and reveal the complex role parietal cells may play during early stamen formation.     

Developmental and Anatomical Studies on the Floral Nectaries of Capsella bursa-pastoris

The development and structure of the floral nectaries of Capsella bursa-pastoris (L.) Medic. were examined. The nectaries consisted of four separated parts which were semiorbicular and were morphologically and anatomically similar to one another. They were located at the receptacle between stamens, and each part was composed of secretory epidermis, nectariferous tissue and vascular bundles, belonging to structural nectary. When the various floral organs were developed, 2--3 superficial layer cells of the receptacle between stamens became meristemoid and contributed to primordia the formation of nectary. By intercalary meristematic activity, the four nectaries formed synchronously. During the different stages of nectary differentiation, the content of starch gra ins and vacuolation in the cells of epidermis and nectariferous tissue changed regularly. According to the structural and histochemical changes the pre-nectar might be supplied by phloem. The nectar formed in nectariferous tissue was then secreted to the sub-stomatal chamber and where it was finally excreted from the stoma.     

Hormonal changes during flower development in floral tissues of Lilium

Much effort has been focussed on better understanding the key signals that modulate floral senescence. Although ethylene is one of the most important regulators of floral senescence in several species, Lilium flowers show low sensitivity to ethylene; thus their senescence may be regulated by other hormones. In this study we have examined how (1) endogenous levels of hormones in various floral tissues (outer and inner tepals, androecium and gynoecium) vary throughout flower development, (2) endogenous levels of hormones in such tissues change in cut versus intact flowers at anthesis, and (3) spray applications of abscisic acid and pyrabactin alter flower longevity. Results show that floral tissues behave differently in their hormonal changes during flower development. Cytokinin and auxin levels mostly increased in tepals prior to anthesis and decreased later during senescence. In contrast, levels of abscisic acid increased during senescence, but only in outer tepals and the gynoecium, and during the latest stages. In addition, cut flowers at anthesis differed from intact flowers in the levels of abscisic acid and auxins in outer tepals, salicylic acid in inner tepals, cytokinins, gibberellins and jasmonic acid in the androecium, and abscisic acid and salicylic acid in the gynoecium, thus showing a clear differential response between floral tissues. Furthermore, spray applications of abscisic acid and pyrabactin in combination accelerated the latest stages of tepal senescence, yet only when flower senescence was delayed with Promalin. It is concluded that (1) floral tissues differentially respond in their endogenous variations of hormones during flower development, (2) cut flowers have drastic changes in the hormonal balance not only of outer and inner tepals but also of androecium and gynoecium, and (3) abscisic acid may accelerate the progression of tepal senescence in Lilium.     

THE DEVELOPMENTAL BASIS OF TRISTYLY IN EICHHORNIA PANICULATA (PONTEDERIACEAE)

Eichhornia paniculata is a tristylous, self-compatible, emergent aquatic. A given plant produces flowers with either long, mid or short styles and two levels of stamens equal in length to the styles not found in that flower. Flowers of each morph have two whorls of three tepals, six stamens and three fused carpels. The six stamens differentiate into two sets of three stamens each. A relatively short set, having either short- or mid-level stamens, occurs on the upper side of the flower, while a relatively long set, having either mid- or long-level stamens, occurs on the lower side. Stamen level depends on differences among stamens in filament length and position of insertion on the floral tube. Floral parts arise in whorls of three, but the two stamen whorls do not form the two sets of stamens found in each mature flower. Instead, stamens from both whorls make up a given set. Floral differences among morphs are not present at flower origin or floral organ initiation. Morphological differences arise first among stamen sets. The two sets within a flower differ prior to meiosis in the size, number, and timing of comparable developmental events in the sporogenous cells. After these initial differences arise, anther size diverges. In later developmental stages differences in filament and floral tube length, cell size, and cell number, as well as differences in the length, cell size, and cell number of styles, develop among morphs. This sequence of developmental events suggests that the genes controlling development in different morphs do not control flower and floral organ initiation but are first morphologically visible in sporogenous cell differentiation.     

Variability of flavonol contents during floral morphogenesis in Papaver somniferum L

We studied the contents of flavonols (kaempferol and quercetin) in the meristem of vegetative and generative apices of the main plant shoot in floral Papaver somniferum mutants, as well as in the normal plants at successive stages of flower development. Five stages of flower development were distinguished. Flavonols (kaempferol and quercetin) were present in all flower organs at all stages of floral morphogenesis we studied. However, their contents and distribution in different organs and at different stages of flower development markedly varied. No significant differences were found in the contents of flavonols in the meristems of vegetative and generative apices of the main shoot in the lines of floral mutants, as well as between the lines with different amounts of vegetative phytomeres. In the plants with normal flower structure, the contents of flavonols (kaempferol + quercetin) sharply increased with the beginning of differentiation of flower organs, i.e. from stage 3, to reach a maximum in the open flower, when gametogenesis is terminated and fertilization takes place. The level of flavonol contents in the petals (upper part) and stamen was at a maximum at all stages of flower development, while that in the gynaecium was at a minimum. The kaempferol: quercetin ratio shifted towards quercetin at successive stages of flower development, most significantly in the stamens. The involvement of flavonols in the regulation of floral morphogenesis at stages of flower organs differentiation and functioning is discussed.     

Variability of Flavonol Contents during Floral Morphogenesis in the Poppy Papaver somniferum L.

We studied the contents of flavonols (kaempferol and quercetin) in the meristem of vegetative and generative apices of the main plant shoot in floral Papaver somniferum L. mutants, as well as in the normal plants at successive stages of flower development. Five stages of flower development were distinguished. Flavonols (kaempferol and quercetin) were present in all flower organs at all stages of floral morphogenesis we studied. However, their contents and distribution in different organs and at different stages of flower development markedly varied. No significant differences were found in the contents of flavonols in the meristems of vegetative and generative apices of the main shoot in the lines of floral mutants, as well as between the lines with different amounts of vegetative phytomeres. In the plants with normal flower structure, the contents of flavonols (kaempferol + quercetin) sharply increased with the beginning of differentiation of flower organs, i.e. from stage 3, to reach a maximum in the open flower, when gametogenesis is terminated and fertilization takes place. The level of flavonol contents in the petals (upper part) and stamen was at a maximum at all stages of flower development, while that in the gynaecium was at a minimum. The kaempferol : quercetin ratio was shifted towards quercetin at successive stages of flower development, most significantly in the stamens. The involvement of flavonols in the regulation of floral morphogenesis at stages of flower organs differentiation and functioning is discussed.