台闽苣苔（苦苣苔科）花部器官的形态发生

在扫描电镜下对台闽苣苔 (T .oldhamii (Hemsl.)Solereder)进行了花部器官形态发生的观察 ,为探索该类群的个体发育、类群间的系统发育关系和进化趋势提供依据。研究发现该属植物萼片、花冠和雄蕊发生式样均为五数花类型 ,它们各自来源于花原基上分化出来的萼片原基、花冠原基和雄蕊原基 ;花冠与雄蕊的两侧对称性与花冠上唇生长稍快和退化雄蕊原基发育迟滞相关 ;萼片原基的发生和发育的顺序是不一致的 :萼片原基发生的式样为近轴中原基—远轴 2原基— 2侧原基 ,发育式样则为近轴中萼片— 2侧萼片—远轴 2萼片 ,花蕾时为镊合状排列。花冠裂片原基的发生和发育式样是一致的 ,即远轴中裂原基 (下唇中裂片 )—远轴 2侧裂原基 (下唇 2侧裂片 )—近轴 2裂原基 (上唇 2裂片 )。花蕾期卷迭式为覆瓦状排列 ,从外向内 :下唇中裂片—下唇 2侧裂片—上唇 2裂片或下唇 2侧裂片—上唇 2裂片—下唇中裂片。雄蕊原基与花冠裂片原基互生 ,前方雄蕊原基在发生上稍迟于后方雄蕊原基 ,后者与退化雄蕊原基几乎同时发生 ,但较小 ,并与近轴心皮 (或柱头上唇 )对生。将该属与玄参科 (Scrophulari aceae)的地黄属 (Rehmannia)、苦苣苔科 (Gesneriaceae)的异叶苣苔属 (Whytockia)和尖舌苣苔属 (Rhynchoglossum)的花部器官比较发现     

韭兰的几种花形变异及初步分析

首次报道了韭兰的多种花被裂片数目、雄蕊数目及其它变异类型。花被裂片数目变异的频率明显高于雄蕊数目变异。花被筒基部弯曲变异也较常见,而且与花被裂片数目增多的变异存在相关性。跟踪观察结果表明:韭兰的花形变异是不稳定的,但是可以在同一植株中重复出现。分析认为:韭兰的花形变异发生在花亚区的形成期,不能用花器官发育的"ABC模型"以及由"ABC模型"为基础发展而来的"ABCD模型"和"AB-CDE模型"解释。其变异原因既与花器官亚区形成的早期调节有关,也与细胞分裂速度改变有关。韭兰的花形变异是相关基因受到体内某种因素的影响所致。花形变异的不稳定性可能与转座遗传因子有关。     

濒危植物秦岭石蝴蝶花瓣数量变异机理研究

为了探明秦岭石蝴蝶花瓣数量变异原因,该研究采用Illumina HiSeq 2500高通量测序技术对秦岭石蝴蝶两种花型发育的早期和晚期进行转录组测序,挖掘参与其花发育相关的差异基因,并探讨花器变异的可能机制。结果显示：(1)与NR数据库进行比对,共有52 677个Unigene注释到NR库,占Unigene总数的46.25%,与旋蒴苣苔(Dorcoceras hygrometricum)的序列同源性最高(54.29%)。(2)GO富集分析结果显示,正常2 3型和变异2 4型差异基因富集最显著的GO条目为：细胞组分类的细胞膜、分子功能类的反转运蛋白活性和酶抑制剂活性、生物过程类的跨膜转运和催化活性的负调控等;KEGG富集分析结果显示,正常2 3型和变异2 4型差异基因富集最显著的KEGG通路为：植物激素信号转导、脂肪酸延长、戊糖和葡萄糖醛酸酯的相互转化、苯丙烷生物合成、硫代谢、类黄酮生物合成、玉米素的生物合成等途径。(3)对表达差异基因进行筛选并进一步对4个比较组进行交叉比对分析,确定了6个可能与秦岭石蝴蝶花器官发育相关的基因,分别为PqMIF2、PqMYB340、PqMYB305、PqGATA12、PqCCD4和PqZBED;qRT PCR验证发现,其表达趋势和转录组测序分析结果一致。该研究结果为秦岭石蝴蝶的花器官发育和系统进化及其濒危机制方面研究提供了重要的信息。     

台闽苣苔(苦苣苔科)花部器官的形态发生

在扫描电镜下对台闽苣苔 (T. oldhamii (Hemsl.) Solereder)进行了花部器官形态发生的观察,为探索该类群的个体发育、类群间的系统发育关系和进化趋势提供依据.研究发现该属植物萼片、花冠和雄蕊发生式样均为五数花类型,它们各自来源于花原基上分化出来的萼片原基、花冠原基和雄蕊原基;花冠与雄蕊的两侧对称性与花冠上唇生长稍快和退化雄蕊原基发育迟滞相关;萼片原基的发生和发育的顺序是不一致的:萼片原基发生的式样为近轴中原基-远轴2原基-2侧原基,发育式样则为近轴中萼片-2侧萼片-远轴2萼片,花蕾时为镊合状排列.花冠裂片原基的发生和发育式样是一致的,即远轴中裂原基(下唇中裂片)-远轴2侧裂原基(下唇2侧裂片)-近轴2裂原基(上唇2裂片).花蕾期卷迭式为覆瓦状排列,从外向内:下唇中裂片-下唇2侧裂片-上唇2裂片或下唇2侧裂片-上唇2裂片-下唇中裂片.雄蕊原基与花冠裂片原基互生,前方雄蕊原基在发生上稍迟于后方雄蕊原基,后者与退化雄蕊原基几乎同时发生,但较小,并与近轴心皮(或柱头上唇)对生.将该属与玄参科(Scrophulariaceae)的地黄属( Rehmannia )、苦苣苔科(Gesneriaceae)的异叶苣苔属( Whytockia)和尖舌苣苔属(Rhynchoglossum )的花部器官比较发现,这四个属在这方面呈现出多样性和交叉.过去一直按子房室数和胎座类型划分玄参科(子房2室、中轴胎座)和苦苣苔科(子房1室、侧膜胎座)这一做法受到了质疑.     

楸树不同单株花性状变异分析

楸树是我国中部地区重要的珍贵阔叶用材和著名的园林观赏树种,已有2 600多年的栽培历史。研究其花性状多样性与变异性旨在揭示花表型性状在楸树种内存在的巨大变异,为新花色育种和优良观花新品种的选育及新品种的鉴定和保护提供理论依据。以1985~1990年收集的优良单株和杂种F1共27株为材料,测定了花性状中的2个质量性状和7个数量性状,并采用方差分析、聚类分析等方法进行统计分析。①27株的开花物候期差异可达5 d,花大小、花序长短和单株花量均有较大差异,并且由于叶柄长度和花枝长度的差异导致不同单株表现出显花和隐花特征。②楸树为二强雄蕊,分为雄性可育和败育,调查的27株中有12株为雄性可育,且花粉量差异较大。③花冠檐部5裂,上唇3瓣,下唇2瓣,上唇瓣长度大于下唇瓣。27株的花枝长度、花序长度、单花枝花数、花上唇瓣长度、花下唇瓣长度和花冠直径均存在极显著差异,单株间的变幅分别为10.7~16.4 cm、5.6~9.6cm、2~13朵、3.8~5.2 cm、3.0~4.3 cm、3.9~5.4 cm,表型变异系数分别为12.8%、12.5%、36.7%、7.5%、9.1%和9.2%。④16株间花色L^*值(亮度值)、a^*值(红绿值)、b^*值(黄蓝值)、C^*值(彩度)和h值(色相)均存在极显著差异,a^*值、b^*值以及彩度C^*值的表型变异系数分别为35.1%、52.5%和29.8%;以L^*、a^*和b^*值度量花色,通过聚类分析将16株聚为3类,红色系、粉红色系和白色系。楸树27株的花枝长度、花序长度、花大小差异极显著,16株的花色也具有明显的差别,依据L^*、a^*和b^*值进行聚类分析,当欧氏距离为15时可将16株聚为3类:红色系、粉红色系和白色系。     

洋葱花器数目变异研究

以洋葱JQS-1、MST-140、Red beauty 3个常规栽培品种的鳞茎为试材,观察统计洋葱花器数目的变化,探讨花器数目的变异与植物花器多样性的关系,为植物花器发育模式以及植物分类和系统发育研究提供依据。结果表明:(1)洋葱花序中正常的洋葱小花含有6枚雄蕊,一些异常小花雄蕊的数目减少到5枚或增加到7~11枚;正常花药中的花粉粒数量大、形状规则、分散均匀,而异常花药中的花粉粒形状不规则。(2)雌蕊数目也发生变异,子房由正常的3室,变成了2室、4室或6室;花柱从正常1枚,增加到2枚或3枚。(3)正常小花含有6片花被片,异常小花的花被片数目从5片到10片。(4)花被片与雄蕊数目的变异有同步增减和非同步增加2种类型。     

棉花变异体（CHV1）的花形态特征分析

棉花体细胞培养再生植株存在大量的生理变异和可遗传变异,从中分离到一个性状稳定的花器变异体(CHV1)。从花器官形态特征和表面显微特征分析,该变异体的所有花器官都变成了苞叶状器官,但中央数片叶状器官的基部有胎座和胚珠着生。变异体每朵花有苞叶3—7片,苞叶状器官19—41片。苞叶状器官在花梗上的排布介于“轮”与“螺旋”状之间。据花器发育理论和变异体花的生长特性推测,该变异体中控制花器发育的A、B和C功能皆失活。对造成该变异的可能机理和棉花花发育模式进行了分析。该变异材料对研究棉花花发育和体细胞无性系变异的机理有一定价值。     

濒危植物秦岭石蝴蝶的SCoT遗传多样性分析

利用筛选到的24条SCoT引物,分析秦岭石蝴蝶人工繁育和野生种群60份材料的遗传多样性和遗传结构,为秦岭石蝴蝶的濒危机制和制定种群保护与修复策略提供理论依据。结果显示:(1)60份秦岭石蝴蝶供试样品的观察等位基因数平均为1.51,有效等位基因数平均为1.31,Nei's基因多样性平均为0.2305,Shannon指数平均为0.3703,表明供试材料种群的遗传多样性较低。(2)种群间的遗传距离与遗传相似系数分析结果表明,3个种群60份供试材料间的遗传相似系数为0.9551~0.9705,平均相似系数0.9634,进一步表明供试材料之间的遗传相似性极高,遗传背景较为狭窄。(3)秦岭石蝴蝶种群分子方差分析结果显示15%的变异来自于种群间,而85%的变异来自于种群内部。综合分析表明,秦岭石蝴蝶各种群内和种群之间的遗传多样性较低,遗传背景狭窄,这可能是秦岭石蝴蝶适应环境能力差,从而导致其濒危的重要原因之一。     

棉花变异体(CHV1)的花形态特征分析

棉花体细胞培养再生植株存在大量的生理变异和可遗传变异,从中分离到一个性状稳定的花器变异体(CHV1)。从花器官形态特征和表面显微特征分析,该变异体的所有花器官都变成了苞叶状器官,但中央数片叶状器官的基部有胎座和胚珠着生。变异体每朵花有苞叶3-7片,苞叶状器官19-41片。苞叶状器官在花梗上的排布介于“轮”与“螺旋”状之间。据花器发育理论和变异体花的生长特性推测,该变异体中控制花器发育的A、B和C功能皆失活。对造成该变异的可能机理和棉花花发育模式进行了分析。该变异材料对研究棉花花发育和体细胞无性系变异的机理有一定价值。     

秦岭秀雅杜鹃7个野生群体形态性状的变异分析

对秦岭山区的7个秀雅杜鹃野生群体的表型变异情况进行分析。结果表明:秀雅杜鹃表型性状在种群间和种群内都存在一定程度的变异,但变异不大。各性状总的平均变异系数在0(雄蕊数目)~0.28(花梗长)之间,种群间总的平均变异系数在0.08(周至)~0.14(南郑),花色性状种群间变异大,种群内变异较小。秀雅杜鹃表型性状与地理生态因子的相关分析表明,各个性状的变异和地理生态因子并无显著的相关性,说明表型受环境影响的程度相对较小。利用群体间欧氏距离进行的UPGMA聚类分析结果表明,秀雅杜鹃野生群体可以划分为3类。     

浙江省野生蜡梅花部形态变异及其与环境因子的相关性

以浙江省蜡梅自然分布区的5个居群为研究对象,采用巢式方差分析、主成分分析、相关分析、聚类分析等多种分析方法,探究蜡梅花部的形态变异及其与环境因子相关性以及居群间和居群内的表型多样性。结果表明:蜡梅花部性状中除雄蕊长度、雌蕊数、雌蕊长度、内被片数以外,其他12个性状在居群间均有极显著差异。胚珠数的平均变异系数最大,花冠内径的平均变异系数最小,各性状的平均变异系数为15.03%(10.81%—23.38%)。五尖山的表型多样性最丰富,碧东山居群最小,种群间平均表型分化系数为44.38%(1.57%—89.62%),种群内变异大于种群间变异,种群内变异是花部变异的主要来源。主成分分析显示花冠直径、花冠内径、花筒深度和中被片长对种群变异起主要贡献作用。花部多数性状间存在显著或极显著的相关关系,生态因子中花部性状与土壤酸度相关性最大,土壤中花部性状与大量元素相关性最大,微量元素次之,中量元素最小。通过UPGMA聚类分析可以将5个种群分成两组。浙江省野生蜡梅花部形态存在丰富的变异和多样性,花部部分性状与土壤中钙、铁、铜含量和海拔有显著或极显著相关关系。     

Mutations associated with floral organ number in rice

How floral organ number is specified is an interesting subject and has been intensively studied in Arabidopsis thaliana. In rice (Oryza sativa L.), mutations associated with floral organ number have been identified. In three mutants of rice, floral organ number 1 (fon1) and the two alleles, floral organ number 2-1 (fon2-1) and floral organ number 2-2 (fon2-2), the floral organs were increased in number centripetally. Lodicules, homologous to petals, were rarely affected, and stamens were frequently increased from six to seven or eight. Of all the floral organs the number of pistils was the most frequently increased. Among the mutants, fon1 showed a different spectrum of organ number from fon2 -1 and fon2 -2. Lodicules were the most frequently affected in fon1, but pistils of more than half of fon1 flowers were unaffected; in contrast, the pistils of most flowers were increased in fon2 -1 and fon2-2. Homeotic conversion of organ identity was also detected at a low frequency in ectopically formed lodicules and stamens. Lodicules and stamens were partially converted into anthers and stigmas, respectively. Concomitant with the increased number of floral organs, each mutant had an enlarged apical meristem. Although meristem size was comparable among the three mutants and wild type in the early phase of flower development, a significant difference became apparent after the lemma primordium had differentiated. In these mutants, the size of the shoot apical meristem in the embryo and in the vegetative phase was not affected, and no phenotypic abnormalities were detected. These results do not coincide with those for Arabidopsis in which clavatal affects the sizes of both shoot and floral meristems, leading to abnormal phyllotaxis, inflorescence fasciation and increased floral organs. Accordingly, it is considered that FON1 and FON2 function exclusively in the regulation of the floral meristem, not of the vegetative meristem.Abbreviation DIC differential interference contrast This work was supported in part by Grant-in-Aid for Scientific Research on Priority Areas from the Ministry of Education, Science and Culture of Japan.     

单瓣与重瓣垂丝海棠花器官形态发育比较观察

为探究垂丝海棠重瓣花成花原因,该研究以单瓣垂丝海棠和重瓣垂丝海棠为实验材料,应用体式显微镜和扫描电镜观察垂丝海棠单瓣、重瓣品种花器官分化过程;解剖观察重瓣垂丝海棠大蕾期的花与盛开的花,统计其花器官的形态与数目;应用R语言对重瓣垂丝海棠的花瓣数目与其余各轮花器官数目进行相关性分析。结果显示：(1)单瓣和重瓣垂丝海棠的花器官分化均分为萼片原基分化期、花瓣原基分化期、雄蕊原基分化期、雌蕊原基分化期,且各轮花器官按照向心顺序依次分化发育。(2)在花瓣原基分化期,单瓣垂丝海棠仅分化出一轮(5枚)均匀分布于两枚萼片交汇处的花瓣原基,而重瓣垂丝海棠分化出两轮分布散列的花瓣原基,第一轮为5~7枚,第二轮为7~10枚。(3)在重瓣垂丝海棠各轮花器官中存在较多萼片瓣化、雄蕊瓣化、雌雄蕊异常发育的情况。(4)重瓣垂丝海棠各轮花器官数目间相关性分析结果显示,其花瓣数目与雄蕊数目以及瓣化中的雄蕊数目间存在明显的正相关关系,该现象与常规雄蕊瓣化植物表现的雄蕊数目减少、花瓣数目增多的现象不同。研究表明,重瓣垂丝海棠花瓣数目的增多并不完全依赖于雄蕊变瓣,暗示垂丝海棠重瓣花成花原因的多元性与复杂性。     

Morph-specific variation of floral traits associated with reciprocal herkogamy in natural populations of Primula vulgaris and Primula veris

Documenting the morph-specific variation of floral traits associated with reciprocal herkogamy is of special importance for revealing the functional significance of traits in the evolution and maintenance of the heterostylous syndrome. In order to describe the extent and specificity of variation, stigma height, anther height, stigma-anther separation and corolla tube length were measured on 800 flowers collected in two natural populations of Primula vulgaris and P. veris. Beside the almost complete separation of stigma heights between the two morphs, we found appreciable intermorph overlap in anther height and relatively broad range of stigma-anther separation so far reported for heterostylous species. The corolla tube length–stigma-anther separation relationship showed striking difference between the two floral morphs, which supports the hypothesis that length of the corolla tube plays a more important role in positioning the sex-organs in the appropriate distance in the short-styled than in the long-styled morph.     

Floral ontogeny inMazus pumilus (Scrophulariaceae)

InMazus pumilus, all the floral appendages are initiated in acropetal sequence in the second cell layer (except stamens) of the floral primordium by periclinal divisions. The actinomorphic calyx tube is formed due to zonal growth. The zygomorphy in corolla is evident from the inception of petal primordia which arise sequentially as independent units in order of one anterior, a pair of anterio-lateral followed by a pair of posterio-lateral. Later these primordia exhibit differential growth because of which zygomorphy becomes more pronounced. The upper corolla tube is formed by interprimordial growth and lower corolla tube by zonal growth. Stamens are initiated in the third layer of the floral apex. Unlike sepals and petals, in the development of stamens (4) underlying cells of corpus also contribute. Posterior stamen is absent. The stamens become epipetalous because of interprimordial and zonal growth in the common region below the bases of petals as well as stamens. The two carpel primordia arise as crescent shaped structures which become continuous due to interprimordial growth. The ovary is formed by a ring of zonal meristem. The style develops later between stigma and ovary because of intercalary growth. The residual apex grows vertically along with the ovary and forms the septum of the ovary. All the floral appendages exhibit similar pattern of histogenesis and early growth suggesting thereby the appendicular nature of these appendages.     

Expression of nuclear-cytoplasmic genomic incompatibility in interspecific Petunia somatic hybrid plants

Summary Somatic hybrid plants were regenerated following calcium-high pH fusion of the unidirectional, sexually incompatible cross of Petunia parodii wild-type leaf mesophyll protoplasts with protoplasts from a cytoplasmic determined chlorophyll-deficient mutant of P. inflata. Genic complementation to chlorophyll synthesis and sustained growth in the selective medium was used to visually identify hybrid calluses. Hybrid calluses were subsequently regenerated to shoots, rooted, and confirmed as somatic hybrids by their intermediate floral and leaf morphology based on comparison to the 2 _n = 4 _x = 28 sexual counterpart, dominant anthocyanin expression in the corolla, chromosome number, and peroxidase and maleic dehydrogenase isozyme patterns. Certain cytologically stable somatic hybrids displayed aberrant reproductive and floral morphologies including subtle to moderate corolla and leaf pigment variegation, floral dimension changes and reduced pollen viability. In contrast, cytologically unstable somatic hybrids showed various degrees of aneuploidy coupled with corolla splitting, and irregularities in reproductive organs such as double stigmas and styles in addition to reduced pollen viability. Postulated mechanisms to account for these phenotypic changes in stable and unstable somatic hybrids include nuclear-cytoplasmic genomic incompatibility, chromosome loss in a biparental cytoplasm, or a phenomenon similar to hybrid dysgenesis occurring as a result of somatic fusion.Michigan Agricultural Experiment Station Journal Article No. 11376. Supported by Grant No. I-134-79 from BARD — The United States — Israel Binational Agricultural Research and Development Fund, and by grant 11-77-4 from American Florists Endowment     

Separation of AG function in floral meristem determinacy from that in reproductive organ identity by expressing antisense AG RNA

The Arabidopsis floral homeotic gene AGAMOUS (AG) is a regulator of early flower development. The ag mutant phenotypes suggest that AG has two functions in flower development: (1) specifying the identity of stamens and carpels, and (2) controlling floral meristem determinacy. To dissect these two AG functions, we have generated transgenic Arabidopsis plants carrying an antisense AG construct. We found that all of the transgenic plants produced abnormal flowers, which can be classified into three types. Type I transgenic flowers are phenocopies of the ag-1 mutant flowers, with both floral meristem indeterminacy and floral organ conversion; type II flowers are indeterminate and have partial conversion of the reproductive organs; and type III flowers have normal stamens and carpels, but still have an indeterminate floral meristem inside the fourth whorl of fused carpels. The existence of type III flowers indicates that AG function can be perturbed to affect only floral meristem determinacy, but not floral organ identity. Furthermore, the fact that floral meristem determinacy is affected in all transformants, but floral organ identity only in a subset of them, suggests that the former may required a higher level of AG activity than the latter. This hypothesis is supported by the levels of AG'mRNA detected in different transformants with different frequencies of distinct types of abnormal antisense AG transgenic flowers. Finally, since AG inhibits the expression of another floral regulatory gene AP1, we examined AP1 expression in antisense AG flowers, and found that AP1 is expressed at a relatively high level in the center of type II flowers, but very little or below detectable levels in the inner whorls of type III flowers. These results provide further insights into the interaction of AG and AP1 and how such an interaction may control both organ identity and floral meristem determinacy.