Temperature-dependent stomatal movement in tulip petals controls water transpiration during flower opening and closing

Temperature‐dependent tulip petal opening and closing movement was previously suggested to be regulated by reversible phosphorylation of a plasma membrane aquaporin ( Azad et al., 2004a ). Stomatal apertures of petals were investigated during petal opening at 20°C and closing at 5°C. In completely open petals, the proportion of open stomata in outer and inner surfaces of the same petal was 27 ± 6% and 65 ± 3%, respectively. During the course of petal closing, stomatal apertures in both surfaces reversed, and in completely closed petals, the proportion of open stomata in outer and inner surfaces of the same petal was 74 ± 3% and 29 ± 6%, respectively, indicating an inverse relationship between stomatal aperture in outer and inner surfaces of the petal during petal opening and closing. Both petal opening and stomatal closure in the outer surface of the petal was inhibited by a Ca²⁺ channel blocker and a Ca²⁺ chelator, whereas the inner surface stomata remained unaffected. On the other hand, sodium nitroprusside, a nitric oxide donor, had no effect on stomatal aperture of the outer surface but influenced the inner surface stomatal aperture during petal opening and closing, suggesting different signalling pathways for regulation of temperature‐dependent stomatal changes in the two surfaces of tulip petals. Stomata were found to be differentially distributed in the bottom, middle and upper parts of tulip petals. During petal closing, water transpiration was observed by measuring the loss of ³H₂O. Transpiration of ³H₂O by petals was fivefold greater in the first 10 min than that found after 30 min, and the transpiration rate was shown to be associated with stomatal distribution and aperture. Thus, the stomata of outer and inner surfaces of the petal are involved in the accumulation and transpiration of water during petal opening.     

Relationship between petal abscission and programmed cell death in <Emphasis Type="Italic">Prunus yedoensis</Emphasis> and <Emphasis Type="Italic">Delphinium belladonna</Emphasis>

Depending on the species, the end of flower life span is characterized by petal wilting or by abscission of petals that are still fully turgid. Wilting at the end of petal life is due to programmed cell death (PCD). It is not known whether the abscission of turgid petals is preceded by PCD. We studied some parameters that indicate PCD: chromatin condensation, a decrease in nuclear diameter, DNA fragmentation, and DNA content per nucleus, using Prunus yedoensis and Delphinium belladonna which both show abscission of turgid petals at the end of floral life. No DNA degradation, no chromatin condensation, and no change in nuclear volume was observed in P. yedoensis petals, prior to abscission. In abscising D. belladonna petals, in contrast, considerable DNA degradation was found, chromatin was condensed and the nuclear volume considerably reduced. Following abscission, the nuclear area in both species drastically increased, and the chromatin became unevenly distributed. Similar chromatin changes were observed after dehydration (24 h at 60°C) of petals severed at the time of flower opening, and in dehydrated petals of Ipomoea nil and Petunia hybrida, severed at the time of flower opening. In these flowers the petal life span is terminated by wilting rather than abscission. It is concluded that the abscission of turgid petals in D. belladonna was preceded by a number of PCD indicators, whereas no such evidence for PCD was found at the time of P. yedoensis petal abscission. Dehydration of the petal cells, after abscission, was associated with a remarkable nuclear morphology which was also found in younger petals subjected to dehydration. This nuclear morphology has apparently not been described previously, for any organism.     

Floral ontogeny in Sophoreae (Leguminosae: Papilionoideae): II. Sophora sensu lato (Sophora group)

Floral ontogeny is described in eight species of Sophora sensu lato, representing the Sophora group, as part of a comparative ontogenetic analysis of Polhill's eight groups of tribe Sophoreae, subfamily Papilionoideae. This tribe includes taxa having relatively unspecialized floral structure. Flowers have a five-lobed calyx, a corolla of five free petals, ten mostly unfused, identical stamens, and a carpel. Order of initiation is predominantly acropetal (except for the carpel): sepals, petals, outer stamens plus carpel, inner stamens. Order of initiation within each whorl is unidirectional from the abaxial side. Overlapping initiation among whorls occurs only in S. chrysophylla. Keel petals are slightly fused in six species, and wing petals are fused in 5. tomentosa. Two bird-pollinated species (S. chrysophylla, S. microphylla) lack the papilionaceous corolla of other species, and their petals are unusually long and lack wing sculpturing found in the others. Other floral differences among species mostly involve flower color, differing absolute or relative sizes among organs, and degree of reflexing of vexillum. All but S. davidii have a hypanthium, which develops very late, starting when the bud is about 5 mm long. The distinctions among species (petal size, degree of reflexed position of vexillum, petal sculpturing, color, anther shape, filament hairs, hypanthium presence, calyx lobing) tend to be expressed late in ontogeny.     

Effect of gibberellic acid on carnation flower senescence: evidence that the delay of carnation flower senescence by gibberellic acid depends on the stage of flower development

Gibberellic acid at concentrations of 10^–5 M and 10^–4 M delayed the senescence of cut carnation flowers, when applied continuously via the stem, to flowers between the closed brush and fully open stages of development. Older flowers with reflexed petals were unresponsive. Treatment with paclobutrazol, an inhibitor of GA biosynthesis, prevented tight buds from opening fully, reduced the longevity of partially open flowers, but was ineffective when applied continuously to fully open flowers. Gibberellic acid-treated flowers did not show simultaneous petal inrolling, a known indicator of senescence, and the time to complete petal drying was extended. Gibberellic acid modified the climacteric ethylene rise in a manner consistent with the extension of longevity. These results provide evidence for a correlative role of gibberellins in flower development.Abbreviations GA₃ gibberellin A₃ - GLC gas liquid chromatography     

A glutathione S-transferase GhTT19 determines flower petal pigmentation via regulating anthocyanin accumulation in cotton

Anthocyanin accumulations in the flowers can improve seed production of hybrid lines, and produce higher commodity value in cotton fibre. However, the genetic mechanism underlying the anthocyanin pigmentation in cotton petals is poorly understood. Here, we showed that the red petal phenotype was introgressed from Gossypium bickii through recombination with the segment containing the R₃ ^bic region in the A07 chromosome of Gossypium hirsutum variety LR compared with the near-isogenic line of LW with white flower petals. The cyanidin-3-O-glucoside (Cy3G) was the major anthocyanin in red petals of cotton. A GhTT19 encoding a TT19-like GST was mapped to the R₃^bic site associated with red petals via map-based cloning, but GhTT19 homologue gene from the D genome was not expressed in G. hirsutum. Intriguingly, allelic variations in the promoters between GhTT19^LW and GhTT19^LR, rather than genic regions, were found as genetic causal of petal colour variations. GhTT19-GFP was found localized in both the endoplasmic reticulum and tonoplast for facilitating anthocyanin transport. An additional MYB binding element found only in the promoter of GhTT19^LR, but not in that of GhTT19^LW, enhanced its transactivation by the MYB activator GhPAP1. The transgenic analysis confirmed the function of GhTT19 in regulating the red flower phenotype in cotton. The essential light signalling component GhHY5 bonded to and activated the promoter of GhPAP1, and the GhHY5-GhPAP1 module together regulated GhTT19 expression to mediate the light-activation of petal anthocyanin pigmentation in cotton. This study provides new insights into the molecular mechanisms for anthocyanin accumulation and may lay a foundation for faster genetic improvement of cotton.     

Light and scanning electron microscopic studies of flower development inLindenbergia macrostachya Benth. (Scrophulariaceae)

All the floral primordia are homologous to leaves in their development inLindenbergia macrostachya. The sepals follow an anterior to posterior sequence of initiation. The petals and stamens are initiated almost simultaneously but sequentially in order of petals followed by stamens. There is no sign of development of fifth posterior stamen. p ]The calyx tube is formed by interprimordial growth followed by zonal growth. The combined interprimordial growth between the petal primordia and growth on the abaxial side of stamen primordia results in the formation of upper corolla tube whereas lower corolla tube is formed only by zonal growth. The zonal growth extends below the bases of stamen primordia also due to which they become epipetalous. The placentae arise from the carpellary margins, move inwards and get fused in the lower half and remain free in the upper part of the ovary. Thus the ovary appears biloeular with axile plaeentation in the lower haler and unilocular with parietal placentation in the upper half.     

THE MISSING PETAL CHARACTER IN OENOTHERA AND ITS RELATION TO THE CRUCIATE CHARACTER

Two characters are known in Oenothera which show inconstancy of behavior resulting in phenotypic mosaicism. These are absence of petals mp and cruciate petals cr. The latter character has been studied intensively by Oehlkers and Renner. The former is discussed here for the first time. The missing petal character exhibits mosaicism in essentially all cases. Flowers with four, three, two, one, or no petals may appear on the same plant on the same day. Where petals are present, they occupy normal positions and are usually normal in size and shape; where absent, no primordia are produced. It is suggested that the cr character is not based on a highly mutable locus (Oehlkers) or on one in which gene conversion occurs (Renner), but is the result of a mutant gene at a locus basic to the development of sepals which is. capable, under certain conditions, of functioning not only in the sepals, but also in cells of petal primordia, thereby suppressing genes for petal development. The sepaloid tissue which it produces in the petal is much more complex than, the petaloid tissue which it suppresses. The mp locus is basic to the initiation of petals; mp is a mutant gene with reduced potency. Whether it is able to function depends upon the cellular environment in which it finds itself. In both cases mosaicism is the result, not of frequently recurring alteration in genic structure, but of regulation of gene action based on variations in the cellular milieu.     

A comparison of venation pattern development in wild type and a homeotic sepaloid petal mutant of Clarkia tembloriensis (Onagraceae)

Vascular system development in sepals, petals, and sepaloid petals was compared in wild-type and crinkled petal mutant plants of Clarkia tembloriensis. Patterns of vascularization in cleared whole mounts were visualized and traced under both brightfield and polarizing illumination. Wild-type sepals exhibited a basipetal pattern of maturation, with tracheary elements maturing relatively rapidly. Mature sepals had three primary veins with numerous secondary veins. In contrast, wild-type petals exhibited an acropetal pattern of maturation, with tracheary elements maturing relatively slowly. The mature petals had only one primary vein with numerous secondary veins. Sepaloid (crinkled) petals combined characteristics of both wild-type sepals and wild-type petals. They exhibited a basipetal pattern of development and a relatively rapid maturation of the tracheary elements characteristic of wild-type sepals. Venation architecture in crinkled petal mutants showed a single primary vein with numerous secondary veins, similar to wild-type petals. The crinkled petal mutant fits the definition of a homeotic mutant in that the petal has assumed characteristics of the sepal. However, homeotic transformation from petal to sepal is incomplete since the crinkled petal still retains many of the characteristics of wild-type petals.     

全缘叶绿绒蒿的花内热量来源和温度调节功能

为探究全缘叶绿绒蒿( Meconopsis integrifolia )的花内热量来源和温度调节功能,该研究选择在全缘叶绿绒蒿的巴朗山居群,对其进行遮阴及去瓣处理,并采用红外热像仪监测全缘叶绿绒蒿的花内微环境温度日变化及花器官温度,用环境温度计监测环境温度。结果表明:(1)太阳照射显著提高全缘叶绿绒蒿花内微环境温度和花器官温度,全缘叶绿绒蒿的热量主要来源于太阳辐射。花内微环境昼夜温差显著低于环境昼夜温差,全缘叶绿绒蒿的花具有温度调节功能。(2)白天环境温度较高时,太阳照射显著提高全缘叶绿绒蒿花内微环境温度,花瓣会降低花内微环境温度; 夜间环境温度较低时,花瓣闭合会提高花内微环境温度; 花瓣闭合运动降低了花内微环境昼夜温差,产生了保温效果。(3)在太阳照射下,花器官温度差异显著,雌雄蕊温度显著高于花瓣温度,且花器官温度由雌蕊柱头中心点向外递减,全缘叶绿绒蒿能有效调控花器官各部位的温度。综上认为,全缘叶绿绒蒿的花内热量来源于太阳辐射,主要通过花瓣闭合运动降低花内微环境昼夜温差并能在太阳照射下调节各花器官的温度实现温度调节功能。     

Floral ontogeny of Aeschynomene falcata and A. sensitiva (Leguminosae: Papilionoideae) supports molecular phylogenetic data

Floral ontogeny and morphology of the Leguminosae are of interest because of their potential to provide characteristics useful for phylogeny. To determine if these features corroborate the phylogenetic segregation of the section Ochopodium from Aeschynomene, this study used comparative analysis between Aeschynomene falcata and A. sensitiva, which are within the sections Ochopodium and Aeschynomene, respectively. Flower buds were analysed by use of scanning electron microscopy. Aeschynomene falcata has a unidirectional initiation of sepals from the abaxial side, and a tendency toward whorled initiation for petals and stamens. At maturity, it has a calyx tube with five lobes, a pubescent standard petal, keel petals with coherent (but not fused) margins above and below the stamens, and a carpel with a long hairy stipe. Aeschynomene sensitiva has a distinct initiation pattern of petals (1st abaxial, 2nd adaxial, and 3rd lateral) and a tendency toward whorled initiation of sepals and stamens. Overlap between sepals, petals, and antesepalous stamens initiation was observed. At maturity, A. sensitiva has a glabrous bilobed calyx and a glabrous standard petal, keel petals postgenitally fused above the stamens, and a carpel with a short and glabrous stipe. Floral ontogeny and morphology of A. falcata are very similar to those of Machaerium and Dalbergia species so far studied, corroborating the phylogenetic proximity of section Ochopodium to these genera. Important features of the floral ontogeny of A. sensitiva seem to be related to the origin of the bilobed calyx, which is shared with the rest of Aeschynomeninae except section Ochopodium, suggesting they are synapomorphies for those species.     

Effects of pollination on floral attraction and longevity

The end of a flower's attraction to pollinators may be due toa range of visible cues such as permanent flower closure, acolour change, and withering or abscission of the petals. Floralattraction may be reduced by pollination. Pollination-inducedconclusion of floral attraction is often due to a colour changeor to flower closure. This may or may not be followed by a reductionin floral longevity, defined as the time to petal withering,wilting or shattering. In a few species floral longevity isincreased following pollination-induced flower closure or apollination-induced change in colour. Floral attraction, therefore,has to be disting uished from floral longevity. A literature survey shows that pollination rapidly reduces floralattraction in numerous orchids, but among other plant familiesonly about 60 genera have been found to show pollination-inducedshortening of floral attraction. Although only a few specieshave been investigated, it was invariably established that theeffect of pollination is blocked by inhibitors of ethylene synthesisor ethylene perception, hence is mediated by ethylene. The flowersthat cease to be attractive to pollinators, shortly followingpollination, tend to be from families that are known mainlyto comprise species in which flower longevity, petal colour,or flower closure, is sensitive to exogenous ethylene. Thisindicates that the effect of pollination on floral attractionis generally mediated by endogenous ethylene. Numerous species reportedly show a decrease in the period offloral attraction after exposure to ethylene, whereas only fora small number of species a decrease in the period of floralattraction induced by pollination has been observed. This discrepancymay be due to the greater attention that has been paid to theeffects of ethylene. Nonetheless, the possibility remains thatendogenous ethylene has a role in changing perianth form andcolour in addition to signalling the occurrence of pollination. Key words: Ethylene sensitivity, flower closure, flower longevity, pollination, petal colour, petal wilting, petal withering, petal abscission     

A new species of <Emphasis Type="Italic">Dalea</Emphasis> ser. <Emphasis Type="Italic">Versicolores</Emphasis> (Leguminosae: Amorpheae) from Durango,Mexico

Dalea conetensis, a new species from the central part of the State of Durango, Mexico, is described and illustrated. It is referred to Dalea subgenus Parosela sect. Parosela series Versicolores. It is morphologically similar to D. pinetorum var. pinetorum but can be distinguished by its shorter stipules, leaves, bracts, calyx teeth, petals, androecium, fewer and shorter leaflets, and the calyx pubescence.     

ANALYSIS OF PETAL VENATION IN RANUNCULUS. I. ANASTOMOSES IN R. REPENS V. PLENIFLORUS

Arnott , Howard J., and Shirley C. Tucker . (Northwestern U., Evanston, Ill.) Analysis of petal venation in Ranunculus. I. Anastomoses in R. repens v. pleniflorus. Amer. Jour. Bot. 50(8): 821–830. Illus. 1963.—The venation patterns of 1218 petals of Ranunculus repens v. pleniflorus were analyzed, with particular attention to the number and position of vein anastomoses. The essentially open dichotomous vascular pattern is complicated by the presence of vein fusions in 69.4% of the petals. The anastomosis ratio (number of anastomoses/number of appendages) is, therefore, high (1.37), compared to a maximal 0.61 for Ginkgo leaves. Of the petals having such fusions, 55.3% have more than 1 anastomosis; the maximal number of fusions found per petal is 8. The presence of anastomoses shows a high degree of correlation with petal size and petal lobing. The types of fusions (types A, B, C, D) are identical with those found in Ginkgo leaves, with the addition of 2 modifications of type C. Curiously, types C and D account for 98.7% of the total anastomoses, while types A and B are rare. An analysis of the location of each type within the petal shows that type C's are disproportionately numerous along the distal periphery, and that type-D fusions are unusually numerous in the central and basal regions. Such evidence suggests that the occurrence of a vein fusion is no “accident,” but rather that it is one manifestation of morphogenetic control.     

Developmental anatomy of foliage leaves,bracts, calyx and corolla inPharbitis nil

The structure and ontogeny of the foliage leaves, bracts, bracteoles, calyx and corolla ofPharbitis nil were investigated, with special reference to the development of the lamina and the procambium. Reproductive organs used are those of a terminal inflorescence and axillary flowers induced by a single 16 hr dark period given to the seedling. The foliage leaf consists of the petiole and the broad lamina. Bracts show various forms and structures, which fluctuate from a lower leafy bract to an upper scaly one in a terminal inflorescence. The sepal is scaly. The corolla is funnel-shaped, and composed of five wedge-shaped petals. In the lamina of the foliage leaf primordium, marginal growth is followed by active growth by the plate meristem, and procambial strands of lateral veins differentiate from the residual meristem. The primordium of the lowest bract of the terminal inflorescence has already been initiated before the dark period, and develops into the bract, the residual meristem disappearing after the treatment. The leafy bract shows marginal growth and growth by the plate meristem similar to that of the foliage leaf, but of short duration. The activity of marginal growth of the scaly bract and the sepal decreases rapidly and procambial strands of lateral veins differentiate acropetally from highly vacuolated cells. The activity of marginal growth of the petal decreases gradually, and derivatives of the marginal meristem divide as a plate meristem. The corolla tube is initiated by co-operation of interprimordial growth and marginal growth of petal primordia.     

Homeosis in floral development of Sanguinaria canadensis and S. canadensis ‘Multiplex’ (Papaveraceae)

Sanguinaria canadensis is a member of the Papaveraceae that normally has eight petals rather than four as is usual in the family. Using epi-illumination microscopy to study floral development, we show that the four additional petal primordia are initiated in positions that correspond to the first four stamen positions in species of the Papaveraceae with four petals. Also, these additional petal primordia share early developmental features with stamen primordia: at inception they are circular in outline, and the relationship between organ length and width while very young is similar. The developmental pathway of the additional petals combines both stamen and petal features: initially stamenlike in appearance, they develop into typical petals. The additional petals of S. canadensis can therefore be interpreted as homeotic because petal features are expressed in stamen positions. Organogenesis in the ‘Multiplex’ cultivar is similar to that of its wild progenitor, but during development all primordia in the androecial region become petals. This cultivar, as well as variants within natural populations, show that replacement of stamens with petals occurs within the species.     

FLORAL ONTOGENY IN SOPHOREAE (LEGUMINOSAE: PAPILIONOIDEAE). I. MYROXYLON (MYROXYLON GROUP) AND CASTANOSPERMUM (ANGYLOCALYX GROUP)

Floral ontogeny is described and documented using scanning electron microscopy in Myroxylon balsamum and Castanospermum australe, representatives respectively of Polhill's Myroxylon and Angylocalyx groups (Leguminosae: Papilionoideae), groups exhibiting relatively unspecialized flower structure for the tribe Sophoreae. Both are woody tropical trees with axillary or terminal racemes or panicles. Bracteoles are present in both Myroxylon and Castanospermum. Flowers are initiated singly in bract axils, which are produced in acropetal order by the inflorescence apical meristem. The flower structure of both includes a broad calyx tube, five petals lacking any fusion (only the vexillary distinctive), ten free homogeneous stamens in two whorls, and a long-stipitate carpel. The two taxa are alike in early organogenetic stages with essentially acropetal order of initiation: sepals, petals, outer stamens plus carpel, inner stamens. Within each whorl the order is unidirectional from the abaxial side. They are alike through middevelopment with one exception. There is accelerated vexillar enlargement in Castanospermum by middevelopment, not found in Myroxylon. Both have a hypanthium, which forms late in development. In both, large flower size, exserted stamens, and hypanthium are adaptations to bird-pollination. Differences between the two that are manifested in late development include strongly zygomorphic calyx and petal color change over time (Castanospermum), stamens sagittate and apiculate with some basal filament fusion (Myroxylon), stigma form differences, and fruit form.     

酢浆草叶片及花朵感夜运动的结构机制

为了解酢浆草(Oxalis corniculata)叶片和花朵的感夜性,采用半薄切片方法对其叶枕和花托进行形态解剖学观察。结果表明,黑暗处理酢浆草后叶片完全闭合,3枚叶片以叶轴为轴线向下紧贴闭合。黑暗处理8 h花瓣完全闭合并螺旋成束状,花萼紧贴螺旋的花瓣但不发生螺旋。叶片张开时屈肌侧皮层薄壁细胞收缩,伸肌侧皮层薄壁细胞膨大。叶片闭合时屈肌侧皮层细胞膨胀,伸肌侧表皮细胞和3～5层外皮层薄壁细胞收缩。花朵闭合时,花托基部的5个维管束收缩合并成2束明显分离的维管束群,且存在细胞壁加厚的现象;花托角隅处细胞膨胀。叶枕中的屈肌和伸肌细胞的收缩或膨胀控制酢浆草叶片的感夜运动,酢浆草花朵的感夜运动主要与花托基部的维管束群和花托角隅处细胞的膨大和收缩有关。     

金花茶组植物花色与细胞内重要环境因子的关系

为研究金花茶组植物花色与细胞内重要环境因子的关系,该研究以花色不同的8个金花茶组物种的9个居群为材料,测定了其花瓣的颜色、总黄酮含量、含水量、细胞pH、7种金属离子浓度。结果表明:所测金花茶组植物的花色平均明度L~*为80.82、色相a~*为-2.88、色相b~*为53.97、彩度C~*为54.10、色相角h为93.19°,故金花茶花色为明度较亮的黄色,其中色相b~*为描述黄色的主要指标,据此可将所测植物分为金黄、黄、浅黄3类。花瓣总黄酮含量为20.17%,花瓣含水量为88.14%,物种间均达到差异显著,且均与花色呈弱相关,对黄色呈现影响较小。花瓣细胞偏弱酸性,pH平均值为6.19,不同物种间差异显著,细胞pH与花色呈显著正相关,即中偏弱酸性细胞环境有利于金花茶花瓣黄色的呈现。金属离子浓度中,K~+含量最高(12.61 mg·g~(-1)),其他依次为Ca2+(3.91 mg·g~(-1))、Mg~(2+)(1.28 mg·g~(-1))、Al~(3+)(0.98 mg·g~(-1))、Na~+(0.17mg·g~(-1))、Fe~(3+)(0.07 mg·g~(-1)),Cu~(2+)含量最低(0.003 8 mg·g~(-1)),7种金属离子在所测植物间均存在显著差异,其中Al~(3+)、Fe~(3+)和Ca~(2+)对金花茶黄色花的形成具有不同程度的干扰作用,随着这3种金属离子浓度升高,黄度降低,花色变淡。因此,较低浓度的Al~(3+)、Fe~(3+)、Ca~(2+)可能更有利于金花茶黄色花的呈现。