濒危植物长柄双花木的花部综合特征与繁育系统

 通过野外观察,运用杂交指数、花粉-胚珠比、人工授粉和套袋实验及等位酶电泳等方法,对长柄双花木(Disanthus cercidifolius Maxim. var. longipes H. T. Chang)自然种群和人工种群的开花状态、繁育系统进行了研究。结果如下：该种单花花期一般6～7 d,开花过程中柱头始终高于花药的位置,花药散粉具有先后顺序,一般2花药先散粉,其余3花药滞后1～2 d。单花花期依其形态和散粉时间可分为5个时期：即散粉前期、散粉初期、散粉盛期、凋谢期。种群开花一般历时49～55 d,但不同地点、年份之间有所差异,推测开花持续时间不同主要是环境条件所致。由于其杂交指数大于4,花粉-胚珠比等于1 250,结合人工套袋和授粉实验以及等位酶电泳结果可以确定该种的繁育系统属于异交为主,部分自交亲和,传粉过程需要传粉者。花粉竞争可能是导致该种濒危的主要的生殖生物学原因。     

秦岭岩白菜的传粉生物学特性与繁育系统

对珍稀濒危植物秦岭岩白菜(Bergenia scopulosa T.P.Wang)的开花特性、传粉适应及繁育系统进行了分析研究。结果表明:(1)秦岭岩白菜为蝎尾状聚伞花序,具(29±10)朵单花,单花期约15d,遇低温雨雪天气花冠闭合,可延长3~5d,花序花期约30d,种群花期近4个月。(2)花粉活力在花药开裂后的12h内最高(约90%),维持单花平均花粉活力在30%以上约6d;柱头在第1~4天内保持很强的可授性,维持可授性的时间约为9d。(3)秦岭岩白菜主要有效传粉昆虫为中华蜜蜂,平均访花频率为6.5朵/min,单花停留时间为(11.0±4.8)s。(4)秦岭岩白菜的花粉胚珠比(P/O)为589.8,杂交指数(OCI)为3;人工授粉实验显示,秦岭岩白菜不存在无融合生殖,自交亲和,主动自交罕见,生殖成功主要依赖传粉者。研究认为,秦岭岩白菜是兼性异交的繁育系统,胚珠受精过程中可能存在自交衰退。     

两种广西特有报春苣苔属(苦苣苔科)植物传粉生物学研究

通过野外观察和室内试验,对两种广西特有的桂林小花苣苔和阳朔小花苣苔的传粉生物学进行比较研究。结果表明:两种报春苣苔属植物花期从7月底至8月初;单花花期内花粉具有较高的活性,最高可达92.6%和94.5%;柱头可授性最高时可达90%和95%;花粉/胚珠比率(P/O)分别为110.28±17.45和229.65±18.00;柱头与花药之间存在着空间隔离,可防止自花授粉;在单花花冠裂片张开后第3天,花药开始散粉,但雌蕊在花朵刚开始开放时已伸长,待第3天时柱头已伸长到位于花冠筒口部,高于花药,便于接受异花花粉;该两种植物均不存在无融合生殖现象;两种报春巨苔属植物均高度自交亲和,但很难发生自发的自花授粉,必须依靠外力,因此传粉媒介对于结实率有重要影响,自然条件下基本不发生自花授粉;在自然状态下结实率明显低于两种人工授粉的结实率;小蜂和淡脉隧蜂是目前已知仅见的两种传粉者。     

黄花牛耳朵(苦苣苔科)的传粉生物学

通过野外观察和繁育系统的实验,对黄花牛耳朵(Chirita lutea Yan Liu et Y.G.wei)的传粉生物学进行了研究.结果表明,黄花牛耳朵的花期从7月初至8月底,单株花期约35～47 d,单花化期约6～10 d,花的开放无固定的时间.在花期内花粉活性约80%,柱头可授性约75%～90%.花粉/胚珠比率(P/O)为1 215.73±266.13.柱头在花药散粉时已生长至花筒口部,明显高于花药,便于接受异花花粉.黄花牛耳朵不存在无融合生殖,高度白交亲和,但较难发生自动的白花授粉,产生种子主要依靠传粉媒介.自然授粉的结实率明显低于人工授粉的结实率,存在传粉限制,蜜蜂(Apidae sp.)、方头泥蜂(Crabro sp.)、无垫蜂(Ameglla sp.)是主要的传粉者.     

紫茉莉的花部综合特征与繁育系统

采用定株观察,运用花粉-胚珠比、联苯胺-过氧化氢法、杂交指数和套袋实验等方法,对紫茉莉(Mirabilis jalapa L.)的开花状态及繁育系统进行了研究.结果表明:种群花期一般为6-10月,单花花期一般为2～3 d;单花花期依其形态和散粉时间可分为散粉前期、散粉初期、散粉盛期、花闭合期、凋谢期5个时期;在花闭合时期,晴天有66.80%的花的柱头在闭合花冠内,阴天时有81.65%的花的柱头在闭合花冠内,雨天柱头在闭合花冠内的花可达99.22%;按照杂交指数,其繁育系统属于自交亲和,有时需要传粉者;P/O值约为269,判断繁育系统类型属于兼性自交;开花6 h左右,柱头的可授性最强,此时花粉活力、置落在柱头上的花粉数及其在柱头上的萌发率都达到最高.套袋实验显示,紫茉莉自然条件下没有无融合现象,繁育系统为自交、异交亲和,以自交为主,但有时也需要传粉者;在长期的环境选择压力下,紫茉莉选择将更多的柱头留在闭合花冠内,是其对不利环境条件的一种适应进化策略.     

紫荣莉的花部综合特征与繁育系统

采用定株观察,运用花粉-胚珠比、联苯胺-过氧化氢法、杂交指数和套袋实验等方法,对紫茉莉（Mirabilis jalapa L．）的开花状态及繁育系统进行了研究。结果表明：种群花期一般为6—10月,单花花期一般为2—3d;单花花期依其形态和散粉时间可分为散粉前期、散粉初期、散粉盛期、花闭合期、凋谢期5个时期;在花闭合时期,晴天有66．80％的花的柱头在闭合花冠内,阴天时有81．65％的花的柱头在闭合花冠内,雨天柱头在闭合花冠内的花可达99．22％;按照杂交指数,其繁育系统属于自交亲和,有时需要传粉者;P／O值约为269,判断繁育系统类型属于兼性自交;开花6h左右,柱头的可授性最强,此时花粉活力、置落在柱头上的花粉数及其在柱头上的萌发率都达到最高。套袋实验显示,紫茉莉自然条件下没有无融合现象,繁育系统为自交、异交亲和,以自交为主,但有时也需要传粉者;在长期的环境选择压力下,紫荣莉选择将更多的柱头留在闭合花冠内,是其对不利环境条件的一种适应进化策略。     

濒危植物丰都车前的繁育系统与传粉生物学研究

丰都车前为三峡库区特有珍稀濒危植物,目前仅在重庆市江津支坪镇涂家村附近大中坝上有一小种群分布。以野生种群和移栽种群为对象,通过野外观察和人工授粉实验对丰都车前传粉生物学及繁育系统进行研究。结果表明:(1)丰都车前单花花期约4 d,花序花期约8 d,种群花期约3个月;单花开花进程可分为6个时期:花蕾期、雌蕊伸长期、雄蕊初露期、花瓣展开期、花瓣反折期、枯萎凋谢期。(2)花瓣展开前,柱头先伸出花冠,达最高可受性,之后花瓣展开雄蕊才露出,而此时大部分柱头已枯萎失活丧失可受性,只有少部分具可受性。表现出雌雄异熟的特征,一定程度避免了自交的发生。(3)花粉活力始于雄蕊初露期,花瓣展开、花药开裂时花粉活力最高,至枯萎凋谢前均具有活力。花粉活力最高期避开了柱头可受性最佳期,仅有少部分重叠。(4)繁育系统检测显示,花粉/胚珠比为15373.29,杂交指数为3。结合套袋实验表明,丰都车前可能同时具有风媒和虫媒传粉机制,传粉昆虫为中华蜜蜂、食蚜蝇,但数量偏少,不存在无融合生殖,异交为主,部分自交亲和,有时需要传粉者。(5)开花时期避开了其分布地洪水淹没期,能够顺利完成开花授粉及座果。综上所述,丰都车前的花部特征、开花物候和繁育系统为适应分布地夏季洪水水淹胁迫提供了一定的生殖保障,促进了该种群的续存。     

稀有植物小丛红景天花部综合特征与繁育系统

对稀有物种生物学特征及繁育系统的研究将有利于我们对稀有物种的保育。该文通过野外定位观测稀有植物小丛红景天(Rhodiola dumulosa)的花部综合特征,并运用杂交指数、花粉-胚珠比的方法首次对其繁育系统进行初步测定。结果表明:该物种单花花期一般为5~6 d,开花过程中花柱逐渐伸长并向外弯曲,子房开裂并逐渐伸长,花药散粉具有先后顺序,一般外轮对萼花药先散粉,其后1 d左右对瓣花药开始散粉。单花花期依照其形态和散粉时间可分为6个阶段:花蕾期、内轮散粉期、内轮散粉末期、外轮散粉期、外轮散粉末期和凋谢期。而种群花期一般可持续30 d以上,不同海拔观测地点有所不同,海拔2 202 m处的观测地点B开花物候最为滞后。由于其杂交指数不小于4,花粉-胚珠比在700~1 000之间, 根据Dafni(1992)和Cruden(1977)的标准,初步判定该物种的繁育系统属于异交为主,部分自交亲和,传粉过程需要传粉者。     

贯叶连翘的开花动态与繁育系统研究

野外观察贯叶连翘的开花进程和花部形态特征,运用花粉萌发、杂交指数、花粉-胚珠比等方法测定其繁育系统。结果显示:贯叶连翘雌雄异熟,柱头先花药成熟,雌雄蕊无明显异位。单花花期4～5d。仅在开花当日有昆虫传粉,蜜蜂为主要传粉者。花粉在花药开裂1h后活力最大,萌发率达40.10%,花粉在柱头萌发3h后接近子房。根据杂交指数(OCI)推测其繁育系统属于异交,部分自交亲和,有时需要传粉者。花粉-胚珠比(P/O)则表明贯叶连翘的繁育系统为兼性异交。贯叶连翘结实率低,可能与花粉活力,花粉管的生长速度及花粉在柱头的竞争有关。     

多伞阿魏的繁育系统及其生态适应性

多伞阿魏（Ferula ferulaeoides）是新疆特有的类短命植物,具有巨大的生态作用和潜在的经济价值。实验通过研究多伞阿魏的花部形态特征、繁殖系统及传粉昆虫,来阐明其对生态环境的响应。结果表明：（1）多伞阿魏花序花期一般持续10~15 d,单花花期为7~10 d,两性花呈现雌雄异位和雌雄异熟的现象;（2）其繁育系统类型为兼性异交,存在自交部分亲和,自然结果率较高,为72.24%;（3）传粉昆虫多种多样,其中以双翅目和膜翅目昆虫居多;（4）开花当天的花粉活力呈单峰曲线,在12：00时活力最高,柱头可授性在花药完全散粉后第2天最强。     

Cytotoxic and antiviral activities of Colombian medicinal plant extracts of the Euphorbia genus

Forty-seven plant extracts of 10 species of the genus Euphorbia (Euphorbiaceae) used by Colombian traditional healers for the treatment of ulcers, cancers, tumors, warts, and other diseases, were tested in vitro for their potential antitumour (antiproliferative and cytotoxic) and antiherpetic activity. To evaluate the capacity of the extracts to inhibit the lytic activity of herpes simplex virus type 2 (HSV-2) and the reduction of viability of infected or uninfected cell cultures, the end-point titration technique (EPTT) and the MTT [3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide] colorimetric assay were used, respectively. The therapeutic index of the positive extracts for the antiviral activity was determined by calculating the ratio CC50 (50% cytotoxic concentration) over IC50 (50% inhibitory concentration of the viral effect). Five of the 47 extracts (11%) representing 3 out of 10 Euphorbia species (30%) exhibited antiherpetic action; the highest activity was found in the leaf/stem water-methanol extracts from E. cotinifolia and E. tirucalli. The therapeutic indexes of these two plant species were > 7.1; these extracts exhibited no cytotoxicity. Six extracts (13%) representing 4 plant species (40%) showed cytotoxic activity. The highest cytotoxicity was found in the dichloromethane extract obtained from E. cotinifolia leaves and the CC50 values for the most susceptible cell lines, HEp-2 and CHO, were 35.1 and 18.1 microgram/ml, respectively.     

濒危植物瑶山苣苔的大小孢子发生和雌雄配子体发育研究

利用石蜡切片技术对瑶山苣苔大小孢子发生、雌雄配子体发育及胚胎发育进行了细胞学观察,结果表明:瑶山苣苔胚珠倒生,单珠被,薄珠心,具珠被绒毡层。大孢子母细胞减数分裂形成的四分体呈直线排列,合点端的大孢子发育为功能大孢子,其余3个大孢子退化,胚囊为单孢子发生的蓼型胚囊发育方式。花药为四囊形,花药壁由外到内依次为表皮、药室内壁、中层和腺质绒毡层,小孢子形成时胞质分裂为修饰性同时型,小孢子四分体排列方式为四面体形,成熟花粉为2核细胞。胚乳发育为细胞型,在胚的发育过程中被吸收耗尽。瑶山苣苔大小孢子发生和雌雄配子体发育基本正常,不是导致其濒危的原因。但瑶山苣苔果实成熟时,胚仅发育至球形胚时期,需要经过一定时间休眠才能完成形态后熟,表明胚未发育完全可能是该物种天然更新困难的原因之一。     

Selection on flowering time and floral display in an alpine and a lowland population of Arabidopsis lyrata

To determine whether population differentiation in flowering time is consistent with differences in current selection, we quantified phenotypic selection acting through female reproductive success on flowering phenology and floral display in two Scandinavian populations of the outcrossing, perennial herb Arabidopsis lyrata in two years. One population was located in an alpine environment strongly affected by grazing, whereas the other was close to sea level and only moderately affected by herbivory. Multiple regression models indicated directional selection for early end of flowering in one year in the lowland population, and directional selection for early start of flowering in one year in the alpine population. As expected, there was selection for more inflorescences in the lowland population. However, in the alpine population, plants with many inflorescences were selectively grazed and the number of inflorescences produced was negatively related to female fitness in one year and not significantly related to female fitness in the second year. The results are consistent with the hypothesis that genetic differentiation in flowering phenology between the study populations is adaptive, and indicate that interactions with selective grazers may strongly influence selection on floral display in A. lyrata.     

Comparison of Flowering Time Genes in Brassica Rapa, B. Napus and Arabidopsis Thaliana

The major difference between annual and biennial cultivars of oilseed Brassica napus and B. rapa is conferred by genes controlling vernalization-responsive flowering time. These genes were compared between the species by aligning the map positions of flowering time quantitative trait loci (QTLs) detected in a segregating population of each species. The results suggest that two major QTLs identified in B. rapa correspond to two major QTLs identified in B. napus. Since B. rapa is one of the hypothesized diploid parents of the amphidiploid B. napus, the vernalization requirement of B. napus probably originated from B. rapa. Brassica genes also were compared to flowering time genes in Arabidopsis thaliana by mapping RFLP loci with the same probes in both B. napus and Arabidopsis. The region containing one pair of Brassica QTLs was collinear with the top of chromosome 5 in A. thaliana where flowering time genes FLC, FY and CO are located. The region containing the second pair of QTLs showed fractured collinearity with several regions of the Arabidopsis genome, including the top of chromosome 4 where FRI is located. Thus, these Brassica genes may correspond to two genes (FLC and FRI) that regulate flowering time in the latest flowering ecotypes of Arabidopsis.     

Hybrids and fruit set in a mixed flowering-time population of Gymnadenia conopsea (Orchidaceae)

We have recently found that the morphologically determined subspecies Gymnadenia conopsea ssp conopsea in Sweden includes early and late flowering individuals. We were interested in the interactions between the flowering time groups; if there were gene flow between them and if so this was detrimental or advantageous. A spatially mixed population of early and late flowering individuals was studied using three microsatellite loci. We measured patterns in genetic differentiation and inferred occurrence of hybridisation and introgression. Variation in flowering time, fertility and relative and absolute fruit set was measured. The pattern of introgression between flowering-time groups differed between loci. In two of the three investigated loci, allele separation was distinct between early and late flowering plants and one genetically obvious hybrid was infertile. In the third locus, several alleles were shared between the two flowering time variants. The degree of introgression was associated to fruit set failure, which was higher in the late flowering plants and lower in early flowering plants. A small group of early flowering individuals with somewhat delayed flowering compared to the main group was genetically distinct and had lower relative and absolute fruit set. This group was not genetically intermediate, but rather constituting an independent group, with lower fruit set possibly caused by absence of pollinators. There seem to be a strong barrier against introgression into the late flowering group which is kept genetically distinct and less diverse. The early flowering group is diverse, includes two subgroups and seems to benefit from gene flow.     

香紫苏开花期蒸腾和光合作用日变化特征及其影响因子研究

对开花期香紫苏功能叶片的蒸腾作用、光合作用日变化规律以及二者与环境因子之间的相互作用进行了研究.结果表明:处于花期的香紫苏蒸腾速率和气孔导度的日变化总体趋势是先升高后降低;不同花期净光合速率的日变化之间则存在明显的差别,初花期的净光合速率明显高于盛花期和终花期;湿度和光合有效辐射是影响香紫苏蒸腾作用的最主要因素,而光合有效辐射和CO2浓度变化则对香紫苏的净光合速率影响最大.     

Unique and conserved features of floral evocation in legumes

Legumes, with their unique ability to fix atmospheric nitrogen, play a vital role in ensuring future food security and mitigating the effects of climate change because they use less fossil energy and produce less greenhouse gases compared with N-fertilized systems. Grain legumes are second only to cereal crops as a source of human and animal food, and they contribute approximately one third of the protein consumed by the human population. The productivity of seed crops, such as grain legumes, is dependent on flowering. Despite the genetic variation and importance of flowering in legume production, studies of the molecular pathways that control flowering in legumes are limited.Recent advances in genomics have revealed that legume flowering pathways are divergent from those of such model species as Arabidopsis thaliana. Here, we discuss the current understanding of flowering time regulation in legumes and highlight the unique and conserved features of floral evocation in legumes.