海韭菜的花器官发生

运用扫描电镜（SEM）观察了海韭菜（Triglochin maritimum）的花器官发生发育过程。结果表明：海韭菜花发育是典型的单子叶植物发生模式,即两轮花被片、两轮雄蕊和两轮心皮以三基数轮状交替发生,花器官是以向心向顶的方式发生的,未发现“花被片—雄蕊复合原基”。 发育后期雄蕊和与之对生的花被片之间的共同基部可能是相继向上居间生长的结果。花被片轮和雄蕊轮二者之间在发育位置、时间和速率上存在差异,内轮花被片原基和外轮雄蕊原基的不同发育时间和发育速度使得在成熟花中内轮花被片位于外轮雄蕊的内方。观察结果不支持水麦冬属植物的花是退化（或压缩）的花序侧分枝等假花的观点。     

拟单性木兰属（木兰科）植物的分类学修订

根据标本研究和野外调查,对木兰科(Magnoliaceae)的拟单性木兰属(Parakmeria Hu &; Cheng)进行了分类学修订。回顾了此属的分类学简史,阐述了保留拟单性木兰属的理由,将Magnolia Linn. subgenus Gynopodium Figlar &; Noot. section Gynopodium 作为拟单性木兰属的新异名,将Magnolia yunnanensis (Hu) Noot. 和M. nitida W. W. Smith var. robusta B. L. Chen &; Noot.作为云南拟单性木兰(Parakmeria yunnanensis Hu)的新异名,将Magnolia omeiensis (Cheng) Dandy、M. lotungensis Chun &; C. H. Tsoong、M. nitida W. W. Smith var. lotungensis (Chun &; C. H. Tsoong) B. L. Chen &; Noot. 和Parakmeria lotungensis (Chun &; C. H. Tsoong) Law作为峨眉拟单性木兰(Parakmeria omeiensis Cheng)的新异名,确认拟单性木兰属含４种植物,列出了分种检索表,描述了各种的地理分布和生长环境。     

焕镛木属——中国木兰科一新属

焕镛木属(Woonyoungia Law)曾分布于广西西北部罗城县,现星散分布于广西北部环江县,贵州省东部荔坡县、云南西南部马关县、是珍稀濒危树种。焕镛木属的花单性异株,与木兰科其他各属均不同;雄花的花被片形态相似而雌花的花被片则明显异形,这也是与木兰科其他各属均不同。此外,焕镛木属的雄蕊两药室稍分开,内侧向开裂,药隔伸出成舌状尖;雌蕊6-9,心皮全部合生,仅露出柱关面;成熟心皮革质,沿背缝开裂,形成近球形的聚合果。与它近缘的单性木兰属(Kmeria Dandy)则雄蕊两药室紧贴,内向开裂,顶端钝,药隔不伸出;成熟心皮木质、沿腹缝全裂及顶端开裂,最后裂成两果瓣、形成各成熟心皮散开的聚合果等不同。依上述不相同特征,故成立焕镛木属属新属。     

单性木兰花部综合特征及其传粉适应性

对单性木兰花部综合特征和访花昆虫种类及访花行为进行了研究,结果表明,单性木兰花冠顶端呈半合拢状,花被片之间存在间隙,只有那些能够穿过这些间隙的昆虫才能到达花内为其采粉和授粉,对访花者的要求较为苛刻。于降雨前去掉雄花和雌花花被片,使雄花雄蕊群和雌花柱头充分暴露,另外选择雄花和雌花作对照,降雨后将花取回并测定雄花花粉生活力和雌花柱头上的花粉粒。结果表明,在雨天,单性木兰花冠顶端呈半合拢状的开放方式对雄花和雌花均起到了保护作用,这种花部结构的特化是对花期持续降雨的一种生态适应。从访花昆虫种类上看,单性木兰雄花的昆虫种类是雌花的两倍,显然雄花比雌花更能吸引昆虫。     

中国木兰科木兰属一新种

描述了中国木兰科木兰属一新种——红花玉兰(Magnolia wufengensis L. Y. Ma et L. R. Wang),并绘了模式图。本种的主要特点是：落叶乔木,花被片9,近相等,整个花被片内外为均匀的红色,叶柄较长,叶片下面沿主脉密被白色柔毛,这些特征与武当木兰(M. sprengeri Pamp.)和玉兰(M. denudata Desr.)存在明显区别。     

八角目(Illiciales)植物花被片表皮比较形态

在光学显微镜和扫描电镜下,观察了八角科(Illiciaceae)八角属(Illicium Linn.)2组11种20个材料、五味子科(Schisandraceae)南五味子属(Kadsura Ksempf. ex Juss.)2亚属2组8种15个材料和五味子属(Schisandra Michx.)2亚属4组6种17个材料的花被片表皮形态特征。首次报道了八角目2个科（八角科和五味子科）3个属（八角属、南五味子属和五味子属）植物花被片表皮细胞的形状、分泌细胞的形状及分布、气孔器的形状及分布、花被片表面的纹饰。通过与八角目2个科3个属植物的叶表皮形态比较,发现花被片表皮气孔器外拱盖均为单层,与叶表皮气孔器外拱盖层数（常绿种类为双层和落叶种类为单层）之间没有相关性,还在五味子科中发现2个新的性状（气孔对和环列型气孔）。通过对两性花、雌花和雄花花被片表皮观察,发现花被片表皮形态与花的性别之间没有相关性。通过对八角属、南五味子属和五味子属花被片表皮比较,发现五味子属与南五味子属相比,其花被片表皮表现出更多的衍生性状;南五味子属与八角属相比,前者花被片表皮具有更多的衍生性状;而南五味子属花被片表皮形态与五味子属的相似性程度较大,支持五味子科包含南五味子属和五味子属、八角科包含八角属的观点。     

两种木莲属植物的花器官发生与发育

用扫描电镜观察桂南木莲(Manglietia chingii Dandy)和木莲(Manglietia fordiana Oliv.)两种木莲属植物的花器官发生及发育过程。结果显示,两种植物的花被片皆为向心发生,木莲的花被片3基数3轮,而桂南木莲的花被片4轮,前3轮3基数,第4轮普遍存在退化现象。雄蕊与心皮皆多枚,螺旋状向心发生。两种植物花发育的特殊之处在于花被片为轮状不同时发生,即从发生位置上看为3基数轮生,但同一轮花被片之间在发生时间上存在差异。这种花被片的轮状不同时发生可能是螺旋状发生向轮状发生演化的一个过渡阶段,这对探讨被子植物花器官发生与发育的演化具有重要意义。     

越南拟单性木兰属一新组合

粗壮光叶拟单性木兰(Magnolia nitida var. robusta)被转移到拟单性木兰属(Parakmeria),升级为种的等级。它与光叶拟单性木兰不同,特征是:长叶片,长叶柄,雌蕊短于雄蕊,花两性或雄性,被片乳白色,附属物尖 (3~3.5 mm)。     

青城细辛的花器官发生

利用扫描电镜观察了青城细辛（Asarum splendens）的花器官发生过程。青城细辛的花器官为轮状结构,向心发生,依次为两轮3基数的花被原基,两轮6基数的雄蕊原基和一轮6基数的心皮原基。两轮花被原基互生,只有外轮（先发生的一轮）花被原基完全发育,而内轮（后发生的一轮）花被原基在发育过程中逐渐退化。两轮雄蕊原基为离心发生：位于内侧的一轮雄蕊原基先发生,每两个原基正对第一轮发生的花被原基,外侧的一轮雄蕊原基后发生,与内轮雄蕊原基互生。心皮与内侧的一轮雄蕊互生。     

番荔枝科两种植物花器官形态发生

用扫描电镜观察了囊瓣木（Saccopetalum prolificum）和刺果番荔枝（Annona muricata）花器官的形态发生过程。刺果番荔枝和囊瓣木花被片均为3轮,其中刺果番荔枝内轮花被片数目为3枚、5枚或7枚。囊瓣木花原基最初为圆锥形,最外轮3枚花被片很快发生,之后中、内轮花被片原基连续发生,3轮花被片互生。此时花原基为六边形。花被片分化完成时,圆球形雄蕊原基沿六边形花原基的6个边螺旋向心发生,最终近轮状排列于花原基上。刺果番荔枝的雄蕊较多（约1000枚）,首先在中轮花被片所对的花原基边缘发生,之后大量雄蕊螺旋状发生。心皮分化的早期阶段,与雄蕊原基很相似,当心皮数目逐渐增多时,不能分辩出发生的顺序。成熟花中,心皮和雄蕊全都被毛覆盖,毛具有粘住传粉滴的作用。     

Flower structure and potential bisexuality in Freycinetia reineckei (Pandanaceae), a species of the Samoa Islands

In Freycinetia reineckei the staminate flower (on the staminate spikes) comprises 3 or 4 (sometimes 2) stamens and a pistillode with 2 (sometimes 4) carpellodes, and the pistillate flower (on the pistillate spikes) is formed of a pistil with 2 (sometimes 4) carpels and of 3 or 4 (sometimes 2) staminodes. This perfect floral homology, also observed in all the other species that were studied with both pistillate and staminate material, strongly suggests that the flower of Freycinetia is basically and potentially bisexual, and may explain the occasional sexual lability and bisexuality of that flower (occurrence of both pistillate and staminate inflorescences, and/or of bisexual inflorescences with bisexual flowers and/or unisexual flowers, on the same individuals) in some species, and also the frequent occurrence of bisexual spikes in this species. These may be partitioned into pistillate, staminate, mixed and sterile zones. In the pistillate zones the flowers have the same aspect and structure as the pistillate flowers. In the staminate zones the flowers generally comprise 3 or 4 (sometimes 2) stamens and a ‘semi-pistil’ some have both stamens and staminodes. The semi-pistils are intermediate between pistils and pistillodes in length, aspect and structure, but always have placentas and ovules. In the mixed zones the flowers are generally formed of a pistil and 3 or 4 (sometimes 2) stamens, and are therefore true hermaphrodite flowers; some have both stamens and staminodes. In the sterile zones the flowers comprise a semi-pistil and 3 or 4 (sometimes 2) staminodes. The staminodes are anatomically very similar to the stamens, especially in the staminate, mixed, and sterile zones, in which they exhibit a wide range of variation in length, aspect and structure. The perfect floral homology as generic character on one hand, and the occasional bisexuality both with and without bisexual flowers and other aspects of sex expression (e.g. occurrence of both pistillate and staminate shoots on the same individuals) in some species on the other hand, seem to indicate that Freycinetia is a basically monoecious, sex changing genus.     

Reproductive biology of Echinodorus longipetalus (Alismataceae): Sexual morphs,breeding system and pollinators

The floral biology, pollinators and breeding system of Echinodorus longipetalus Micheli were studied in a marshy area of the district of Taquaritinga (State of São Paulo), southeastern Brazil. E. longipetalus is gynodioecious and as far as is known, this is the first record of unisexual flowers, besides perfect flowers, in Echinodorus. Proportion of female individuals in the studied population is 50% and produces 31% more flowers than hermaphrodites. Perfect and pistillate flowers of E. longipetalus are similar in appearance and are pollinated by several species of Hymenoptera (mainly by Xylocopa (Neoxylocopa) suspecta Moure & Camargo). Perfect flowers offer pollen as a reward. Pistillate flowers attract floral visitors by deceit with their staminodes that resemble the stamens of the perfect flowers. Visits to pistillate flowers are quick (1–2 s), while visits to perfect flowers last up to 120 s. The perfect flowers are self-compatible and produce fruits through spontaneous self-pollination (control flowers), whereas the pistillate ones only set fruits through cross-pollinations. Perfect and pistillate flowers set more fruits under natural conditions than in manual treatments, respectively. Although the pistillate and perfect flowers bear a strong similarity, the selective pollinator behavior seems to be responsible for the increase of fruit set in perfect flowers.     

Reproductive biology of Echinodorus longipetalus (Alismataceae): Sexual morphs,breeding system and pollinators

The floral biology, pollinators and breeding system of Echinodorus longipetalus Micheli were studied in a marshy area of the district of Taquaritinga (State of São Paulo), southeastern Brazil. E. longipetalus is gynodioecious and as far as is known, this is the first record of unisexual flowers, besides perfect flowers, in Echinodorus. Proportion of female individuals in the studied population is 50% and produces 31% more flowers than hermaphrodites. Perfect and pistillate flowers of E. longipetalus are similar in appearance and are pollinated by several species of Hymenoptera (mainly by Xylocopa (Neoxylocopa) suspecta Moure & Camargo). Perfect flowers offer pollen as a reward. Pistillate flowers attract floral visitors by deceit with their staminodes that resemble the stamens of the perfect flowers. Visits to pistillate flowers are quick (1–2 s), while visits to perfect flowers last up to 120 s. The perfect flowers are self-compatible and produce fruits through spontaneous self-pollination (control flowers), whereas the pistillate ones only set fruits through cross-pollinations. Perfect and pistillate flowers set more fruits under natural conditions than in manual treatments, respectively. Although the pistillate and perfect flowers bear a strong similarity, the selective pollinator behavior seems to be responsible for the increase of fruit set in perfect flowers.     

FLORAL DEVELOPMENT IN MYRISTICA (MYRISTICACEAE)

Myristica fragrans and M. malabarica are dioecious. Both staminate and pistillate plants produce axillary flowering structures. Each pistillate flower is solitary, borne terminally on a short, second-order shoot that bears a pair of ephemeral bracts. Each staminate inflorescence similarly produces a terminal flower and, usually, a third-order, racemose axis in the axil of each pair of bracts. Each flower on these indeterminate axes is in the axil of a bract. On the abaxial side immediately below the perianth, each flower has a bracteole, which is produced by the floral apex. Three tepal primordia are initiated on the margins of the floral apex in an acyclic pattern. Subsequent intercalary growth produces a perianth tube. Alternate with the tepals, three anther primordia arise on the margins of a broadened floral apex in an acyclic or helical pattern. Usually two more anther primordia arise adjacent to each of the first three primordia, producing a total of nine primordia. At this stage the floral apex begins to lose its meristematic appearance, but the residuum persists. Intercalary growth below the floral apex produces a columnar receptacle. The anther primordia remain adnate to the receptacle and grow longitudinally as the receptacle elongates. Each primordium develops into an anther with two pairs of septate, elongate microsporangia. In pistillate flowers, a carpel primordium encircles the floral apex eventually producing an ascidiate carpel with a cleft on the oblique apex and upper adaxial wall. The floral ontogeny supports the morphological interpretation of myristicaceous flowers as trimerous with either four-sporangiate anthers or monocarpellate pistils.     

Morphology, development and homologies of the perianth and floral nectaries in Croton and Astraea (Euphorbiaceae-Malpighiales)

New observations are presented on the ontogeny, vasculature and morphology of both staminate and pistillate flowers of Croton and Astraea. These data support earlier hypotheses that the filamentous structures in pistillate flowers represent reduced and transformed petals. Staminate flowers of both genera possess five free nectaries, which are vascularised by divergences of the sepal traces in Croton and unvascularised in Astraea. In pistillate flowers, there are five separate non-vascularised nectaries in Astraea, but in Croton there is a single nectariferous disk that is vascularised by divergences of the sepal traces. The nectaries are initiated late in floral development, but their location indicates that they could represent the outer stamen whorl transformed into secretory staminodes. Other glandular structures occur in pistillate flowers of most Croton species, resulting in flowers with two secretory organ whorls. In these cases, the inner whorl is formed by modified staminodes. Our observations support the recent segregation of Astraea species from the larger genus Croton. Despite strong similarities between the two genera, there are clear structural differences, including the presence of colleters in Astraea (absent in Croton), moniliform trichomes on petals (rather than simple trichomes in Croton), non-vascularised nectaries (vascularised in Croton) and reduced, non-secretory filamentous structures (well developed and secretory in Croton).     

A Matter of Contrast: Yellow Flower Colour Constrains Style Length in Crocus species

Most flowers display distinct colour patterns comprising two different areas. The peripheral large-area component of floral colour patterns attracts flower visitors from some distance and the central small-area component guides flower visitors towards landing sites. Whereas the peripheral colour is largely variable among species, the central colour, produced mostly by anthers and pollen or pollen mimicking floral guides, is predominantly yellow and UV-absorbing. This holds also for yellow flowers that regularly display a UV bull’s eye pattern. Here we show that yellow-flowering Crocus species are a noticeable exception, since yellow-flowering Crocus species–being entirely UV-absorbing–exhibit low colour contrast between yellow reproductive organs and yellow tepals. The elongated yellow or orange-yellow style of Crocus flowers is a stamen-mimicking structure promoting cross-pollination by facilitating flower visitors’ contact with the apical stigma before the flower visitors are touching the anthers. Since Crocus species possess either yellow, violet or white tepals, the colour contrast between the stamen-mimicking style and the tepals varies among species. In this study comprising 106 Crocus species, it was tested whether the style length of Crocus flowers is dependent on the corolla colour. The results show that members of the genus Crocus with yellow tepals have evolved independently up to twelve times in the genus Crocus and that yellow-flowering Crocus species possess shorter styles as compared to violet- and white-flowering ones. The manipulation of flower visitors by anther-mimicking elongated styles in Crocus flowers is discussed.     

Functional Monoecy Due to Delayed Anther Dehiscence: A Novel Mechanism in Pseuduvaria mulgraveana (Annonaceae)

Unlike most genera in the early-divergent angiosperm family Annonaceae, Pseuduvaria exhibits a diversity of floral sex expression. Most species are structurally andromonoecious (or possibly androdioecious), although the hermaphroditic flowers have been inferred to be functionally pistillate, with sterile staminodes. Pseuduvaria presents an ideal model for investigating the evolution of floral sex in early-divergent angiosperms, although detailed empirical studies are currently lacking. The phenology and pollination ecology of the Australian endemic species Pseuduvaria mulgraveana are studied in detail, including evaluations of floral scent chemistry, pollen viability, and floral visitors. Results showed that the flowers are pollinated by small diurnal nitidulid beetles and are protogynous. Pollen from both hermaphroditic and staminate flowers are shown to be equally viable. The structurally hermaphroditic flowers are nevertheless functionally pistillate as anther dehiscence is delayed until after petal abscission and hence after the departure of pollinators. This mechanism to achieve functional unisexuality of flowers has not previously been reported in angiosperms. It is known that protogyny is widespread amongst early-divergent angiosperms, including the Annonaceae, and is effective in preventing autogamy. Delayed anther dehiscence represents a further elaboration of this, and is effective in preventing geitonogamy since very few sexually mature flowers occur simultaneously in an individual. We highlight the necessity for field-based empirical interpretations of functional floral sex expression prior to evaluations of evolutionary processes.     

Floral anatomy of Paepalanthoideae (Eriocaulaceae, Poales) and their Nectariferous structures

BACKGROUND AND AIMS: Eriocaulaceae (Poales) is currently divided in two subfamilies: Eriocauloideae, which comprises two genera and Paepalanthoideae, with nine genera. The floral anatomy of Actinocephalus polyanthus, Leiothrix fluitans, Paepalanthus chlorocephalus, P. flaccidus and Rondonanthus roraimae was studied here. The flowers of these species of Paepalanthoideae are unisexual, and form capitulum-type inflorescences. Staminate and pistillate flowers are randomly distributed in the capitulum and develop centripetally. This work aims to establish a floral nomenclature for the Eriocaulaceae to provide more information about the taxonomy and phylogeny of the family. METHODS: Light microscopy, scanning electron microscopy and chemical tests were used to investigate the floral structures. KEY RESULTS: Staminate and pistillate flowers are trimerous (except in P. flaccidus, which presents dimerous flowers), and the perianth of all species is differentiated into sepals and petals. Staminate flowers present an androecium with scale-like staminodes (not in R. roraimae) and fertile stamens, and nectariferous pistillodes. Pistillate flowers present scale-like staminodes (except for R. roraimae, which presents elongated and vascularized staminodes), and a gynoecium with a hollow style, ramified in stigmatic and nectariferous portions. CONCLUSIONS: The scale-like staminodes present in the species of Paepalanthoideae indicate a probable reduction of the outer whorl of stamens present in species of Eriocauloideae. Among the Paepalanthoideae genera, Rondonanthus, which is probably basal, shows vascularized staminodes in their pistillate flowers. The occurrence of nectariferous pistillodes in staminate flowers and that of nectariferous portions of the style in pistillate flowers of Paepalanthoideae are emphasized as nectariferous structures in Eriocaulaceae.     

Evidence of trimonoecy in Phyllanthaceae: Phyllanthus acidus

Pollen from staminate flowers and pistillate flowers with ??staminodes?? of Phyllanthus acidus Skeels were analyzed under scanning electron microscopy, and tests of pollen viability and in?vitro germination were carried out to verify possible similarities between the three types of flowers. The results show that pistillate flowers with ??staminodes?? are bisexual, indicating the occurrence of trimonoecy in this species.