Structural and Cytochemical Characteristics of the Stigma and Style in Vitis vinifera L. var. Sangiovese (Vitaceae)

Studies were carried out on structural and cytochemical aspectsof the stigma and style ofVitis vinifera . The stigma is ofthe wet papillate type with a continuous cuticle and pellicle.During the development of the papillae, the cell walls increasein thickness and produce a secretion product constituted oflipids that pass through the wall forming the exudate. The styleis solid with a central core of transmitting tissue which hasconspicuous intercellular spaces that increase remarkably fromthe periphery to the centre where the cuticle is present. Theintercellular spaces, where the pollen tubes grow, contain amatrix that includes polysaccharides, pectic substances andscattered areas of lipidic nature. Cytochemistry; stigma; style; ultrastructure; Vitis vinifera     

Two novel reports of semidry stigmatic surface in Asteraceae

Research documents related to the morphology and function of style branches and stigmatic surface of Asteraceae are still rather few, and the literature reports are thus controversial. We report in the present study that the stigmatic surfaces of two non-related species of Asteraceae (Lessingianthus grandiflorus and Lucilia lycopodioides) have features of semidry stigmas. Sporodermis of both species was also analyzed so that we could understand how the stigmatic surface works during pollen deposition and rehydration. Stylar branches and pollen grains (sporodermis) were studied using scanning and transmission electron microscopy (SEM and TEM) and histochemistry techniques. The inner and marginal bands of stylar branches in these species display intermediary features between the dry and wet types of stigma: the cuticle characterizes the dry stigma and cells with secretory activity characterize the wet stigma; these showed differences from what has been described to the Asteraceae family, where stigmatic surface of species from several tribes is considered dry. Pollen grains are medium-size to large with exine ornamentation (echinate and echinolophate) and abundant secretion which latter characterizes pollenkitt. We can assume that two processes might help pollen grain hydration on stigmatic surface in Lessingianthus grandiflorus and Lucilia lycopodioides: (1) the presence of pollenkitt, as observed in the secretory content inside exine cavities and around pollen grains; and (2) the secretory activity of stigmatic surface cells, whose secretion accumulates among intercellular and subcuticular spaces and leads to cuticle disruption during the floral receptive phase. Our results suggest that ultrastructural and histochemical studies should be considered when describing stigmatic surface and that the “semidry” feature within Asteraceae should be investigated still more in detail, so that the taxonomic or adaptation value of this trait in the family can be verified.     

The dry and wet stigmas ofPrimula obconica: Ultrastructural and cytochemical dimorphisms

Summary The stigmatic papillae of the distylous speciesPrimula obconica are studied by means of cytochemical, light and electron microscopic techniques. The papillae on thrum stigmas are smaller than those on pin stigmas. At the bud stage, secretory vesicles are not a conspicious part of the cytoplasm, although certain signs of secretory activity are present. The young papillae bear the thin, superficial pellicle typical to dry stigmas. Small vesicles are numerous in mature papillae of both morphs, and seem to originate from the ER. A layer of closely packed, osmiophilic globuli is present in the outermost part of mature walls of pin papillae. At sites with cuticle disruption, the globuli seem to migrate outwards to be incorporated with the copious, blistery exudate. Due to this exudate the pin stigma is characterized as wet. Cytochemical tests suggest that the exudate contains mainly lipids, and different carbohydrates and protein are detected. It reacts positively in tests for peroxidase, acid phosphatase, and non-specific esterases. The thrum stigma remains dry at maturity, with a distinct pellicle also reacting positively to the enzyme tests. Only a few, scattered osmiophilic globuli, sized and situated as those in the pin papillae walls, are found in the thrum walls, and they do not form a proper layer.Thus the generally accepted correlation between dry stigmas and the sporophytic kind of self-incompatibility system is not substantiated withinP. obconica, and the possible influence of the dimorphisms to the pollen/stigma interaction is discussed.     

Stigma-surface Esterase Activity and Stigma Receptivity in Some Taxa Characterized by Wet Stigmas

Stigma-surface esterase activity and stigma receptivity througha sequence of developmental stages of the pistil have been studiedin four taxa characterized by having wet stigmas — Petuniahybrida, Nicotiana tabacum, Crinum defixum and Amaryllis vittata.The style is solid in the first two and hollow in the lattertwo taxa. In all the taxa, stigma—surface esterase couldbe detected in a thin surface layer (pellicle) from a very earlystage of pistil development, irrespective of the presence orabsence of the exudate. However, the taxa showed variation instigma receptivity. In Petunia and Nicotiana, stigmas from pistilsof all the stages supported pollen germination and tube growth.In Amaryllis and Crinum, stigmas of only the mature pistils,when the exudate is present on the stigma, supported normalpollen germination and tube growth. It is inferred that in taxacharacterized by a wet stigma and solid style, the factors requiredfor pollen germination are present from an early stage of pistildevelopment and the exudate per se is not involved in pollengermination. In taxa characterized by a wet stigma and hollowstyle, however, the pellicle does not carry the factors requiredfor pollen germination and tube growth; they appear to be presentin the exudate. Petunia hybrida Vilm, Nicotiana tabacum L., Crinum defixum, Ker-Gawl, Amaryllis vittata Ait., tobacco, pollination, pollen germination, stigmatic exudate, stigma receptivity, stigma-surface esterase, esterase activity     

Structure of the style and wet non-papillate stigma of Colophospermum mopane, Caesalpinioideae: Detarieae

The capitate stigma of Colophospermum mopane (Kirk ex Benth.) Kirk ex J. Leonard is an intensely folded bilobed structure. The epidermal layer of the stigma consists of non-papillate cells. Before anthesis the epidermis is covered with a cuticle and thin proteinaceous layer. Elongated subepidermal cells constitute the secretory zone. Cell disintegration in the central region of each stigma lobe leads to cavities that become connected to the central cavity in the style. During early anthesis it appears as if the receptive surface of the stigma is confined to the depressions of the stigma surface and to the cleft between the two stigma lobes as the secretory product and pollen grains are mainly confined to these areas. The secretory products of the stigma and style are released during five different stages from prior to anthesis to late anthesis. The stigmatic exudate appears complex and consists of carbohydrates, proteins and lipids. The style has a hollow, lysigenous, fluid-filled canal that is not lined with an epidermal layer or cuticle. The stylar canal is continuous with the opening between the two stigma lobes and provides an open route for the passage of exudate. The stylar exudate is PAS-positive. The dorsal and ventral bundles that supply the style branch in such a way as to almost form a cylinder around the central transmitting tissue and stylar canal. New sieve elements proliferate before anthesis.  © 2002 The Linnean Society of London, Botanical Journal of the Linnean Society , 2002, 139 , 295–304.     

STIGMA,STYLE, AND OBTURATOR OF SOYBEAN,GLYCINE MAX (L.) MERR. (LEGUMINOSAE) AND THEIR FUNCTION IN THE REPRODUCTIVE PROCESS

Soybeans have a wet stigma overtopped by a pellicle that originates from the cuticle. There are numerous exudate-filled, axially oriented channels between cells of the transmitting tissue in the stigma and style. Pollen tubes grow in these channels and receive nutrition and mechanical guidance. Transmitting-tissue cells of the obturator are secretory also, but the obturator in soybean does not appear to control direction of pollen tube growth mechanically. The significant function of transmitting tissue in soybeans is to provide nutrition and to control direction of pollen tube growth.     

Polysaccharide Secretion by the Watermelon Stigma

Secretion of the galactose-containing polysaccharide componentof the watermelon stigma exudate was studied using electronmicroscopy cytochemistry and autoradiography. Polysaccharidelocalization using the thiosemicarbazide–silver proteinatemethod stained the Golgi apparatus and secretory vesicles, thecell wall, wall thickenings and extracellular secretion. Thesame result was obtained at anthesis and at 18 h prior to anthesis,which coincides with the period of maximum secretion. Labellingof stigmas in vivo with D-(1-³H) galactose at 20 h prior toanthesis resulted in different labelling patterns after 2 h(18 h prior to anthesis) and 20 h (anthesis). At 18 h priorto anthesis label was present in the Golgi apparatus and secretoryvesicles, the cell wall and wall thickenings. By anthesis labelhad accumulated in the extracellular secretion in addition tothe Golgi apparatus, secretory vesicles, cell wall and wallthickenings. The results suggest that the polysaccharide componentof the stigma exudate is produced in the Golgi apparatus andsecreted via the cell wall and wall thickenings. Citrullus lanatus Thumb., Matsum and Nakai, watermelon, autoradiography, stigma, secretion, cytochemistry, polysaccharide     

Developmental Aspects of Ultrastructure, Histochemistry and Receptivity of the Stigma of Nicotiana sylvestris

The bilobed papillate stigma of Nicotiana sylvestris Speg. andComes, is covered at maturity with a copious exudate containinglipid, protein and carbohydrate. The stigma is receptive fromthe very early stage of development and it also stains positivelyfor esterase activity. The stigma has three distinct zones:an epidermis with papillae; a subepidermal secretory zone; anda parenchymatous ground tissue. The behaviour of the cells ofthese three zones has been followed from 6 d before anthesisto one day after anthesis and pollination. The cells of theepidermis and the secretory zone stain intensively for lipids,proteins and carbohydrates in the initial stages. The secretoryzone develops large intercellular spaces containing heterogenoussecretory products which also stain positively for the aforesaidthree compounds. At maturity the secretory products are releasedto the surface through gaps formed in the epidermis by cellseparation. The main secretion of the stigma is produced bythe cells of the secretory zone. Less secretion is derived fromthe stigmatic papillae. Some amount of secretion is also releasedfrom the stylar transmitting tissue adjoining the stigma. Theglandular cells of the stigma contain numerous plastids, mitochondria,ribosomes, ER, cytoplasmic lipid droplets and some dictyosomes.The plastids and the vacuoles in the secretory cells of thestigma have a lot of electron dense (osmiophilic) inclusionsrespectively in the initial and later stages of development.The former are probably involved in the production of thesematerials. It is suggested that the proteins are directly secretedby rough ER compartments whereas smooth ER is involved in thesynthesis of lipidic materials. The carbohydrate moiety of theexudate is released by the eccrine mode (sugar mono- and dimers)with some addition of polymers by disintegration of the middlelamellae. The means by which the lipidic and osmiophilic materialis extruded remains unclear. Nicotiana sylvestris, stigma receptivity, organization, stigmatic secretory system, stigmatic exudate     

黄瓜雌花发育过程中柱头的腺特征(英文)

利用透射电镜技术研究了黄瓜（Ｃｕｃｕｍｉｓ　ｓａｔｉｖｕｓ　Ｌ．）雌花柱头发育过程中传递组织、分泌组织和乳突细胞的超微结构。在整个发育过程中,乳突细胞和分泌组织细胞的细胞质内密布很多管状及槽库膨大的内质网,产生很多分泌囊泡;在成熟柱头的传递组织和分泌组织细胞间观察到大量的胞间连丝;乳突细胞和分泌细胞高度液泡化,质膜内折;在柱头发育过程中分泌组织细胞的核周腔扩大形成裂瓣状核,到柱头成熟阶段裂瓣状核更加明显。进一步的研究显示,在成熟柱头的不同组织细胞中,　ＡＴＰａｓｅ的活性呈现在质膜和液泡膜上,随着柱头的发育,ＰＭ－Ｈ＋－ＡＴＰａｓｅ的比活性明显增强。结果表明,黄瓜雌花柱头的腺特征随发育进程而趋于显著。     

Pollen-Stigma Interaction in the Leguminosae: the Organization of the Stigma in Trifolium pratense L.

The intact stigma of Trifolium pratense possesses a smooth receptivesurface fringed by a few ranks of brush hairs. This surfaceis ensheathed by a thin (75–100 nm) but highly impermeablecuticle, which encloses four to five ranks of secretory cellsimmersed in their secretory products. Experimental single-grainpollinations show that pollen cannot become hydrated or germinateon the intact surface. The cuticle is ruptured when the floweris tripped; the secretion is released, and captured pollen-selfor cross-can then germinate. As in other papilionoid Leguminosae,this mechanism provides a guard against premature selling. Thesecretory cells are elongated; they remain in communicationthrough persistent pit-fields as the intercellular spaces fillwith secretion product. The secretion forms a lipid-rich emulsion,with a mucilaginous aqueous phase which reacts cytochemicallyfor protein and carbohydrate and has esterase activity. Duringthe early development of the stigma head, the cells possessa fine-structure appropriate to their secretory function, withabundant ribosomal and smooth endoplasmic reticulum, stratifiedor in the form of ramifying and anastomosing tubules, numerousmitochondria and a well developed Golgi system. Lipid globuli,partly invested in endoplasmic reticulum, are abundant in theyoung cells, but there is as yet no indication of how the lipidis transferred to the intercellular spaces during the secretoryperiod. As the stigma matures, the secretory cells become moribund. Leguminosae, Trifolium pratenseL., pollen-stigma interaction, self-incompatibility, autofertility, stigma secretory system, lipid secretion, cuticle permeability     

黄瓜雌花发育过程中柱头的腺特征

利用透射电镜技术研究了黄瓜(Cucumis sativus L.)雌花柱头发育过程中传递组织、分泌组织和乳突细胞的超微结构.在整个发育过程中,乳突细胞和分泌组织细胞的细胞质内密布很多管状及槽库膨大的内质网,产生很多分泌囊泡;在成熟柱头的传递组织和分泌组织细胞间观察到大量的胞间连丝;乳突细胞和分泌细胞高度液泡化,质膜内折;在柱头发育过程中分泌组织细胞的核周腔扩大形成裂瓣状核,到柱头成熟阶段裂瓣状核更加明显.进一步的研究显示,在成熟柱头的不同组织细胞中,ATPase的活性呈现在质膜和液泡膜上,随着柱头的发育,PM-H -ATPase的比活性明显增强.结果表明,黄瓜雌花柱头的腺特征随发育进程而趋于显著.     

Pollen-Stigma Interaction in the Leguminosae: Stigma Organization and the Breeding System in Vicia faba L.

As in other papilionoid Leguminosae, the receptive surface ofthe stigma of Vicia faba L. is invested by a detached cuticle.This cuticle, the so-called ‘stigma membrane’ ofplant breeding literature, is lifted away from the epidermisduring development by the accumulation of a lipid-rich secretionreleased into the intercellular spaces of the stigma head bythe epidermal cells and the underlying three to four cell layers.The cuticle is thickened over the prominences left by the epidermalpapillae, thinning out between. Pollen, whether self or cross,cannot hydrate and germinate in contact with the intact stigmasurface, but must await the disruption of the cuticle and therelease of the retained secretion. In most genotypes this takesplace only when the flower is tripped by visiting pollinatorsor in consequence of severe agitation by wind. A comparison of lines differing in their degree of autofertilityin field conditions has revealed various differences in stigmastructure. A highly autofertile line had low papillae at thereceptive tip, with a relatively thin intervening cuticle, whilean autosterile line had longer papillae and a thicker cuticle.A line with partial autofertility was intermediate in thesecharacteristics. These properties of the stigma surface, togetherwith other differences in flower structure, are probably adequateto account for the variation in the degree of autosterility,since no evidence was obtained suggesting the presence of aneffective physiological self-incompatibility system in any ofthe lines studied. Since the rupturing of the stigma cuticle is affected by theturgor pressure of the cells of the stigma and style, some degreeof environmental interaction is to be expected: autofertilityshould be at the highest in conditions of adequate water supply,and lowest where there is water deprivation. Pollen-stigma interaction, Vicia faba L., Leguminosae, breeding system, self-incompatibility     

Reproduction in Seagrasses: Nature of the Pollen and Receptive Surface of the Stigma in the Hydrocharitaceae

This paper describes the characteristics of the pollen and thereceptive surfaces of the stigmas in the three marine angiospermsincluded in the Hydrocharitaceae. The pollen in Enhalus acoroidesand Thalassia hemprichii is spherical and has an ornamentedexine. An exine layer is not found in Halophila stipulacea wherereniform pollen grains are contained within transparent moniliformtubes. Cytochemical tests show that the pollen wall in the threespecies contains acidic and neutral polysaccharides and acidhydrolase acitivity is detected in the intine of H. stipulaceaand T. hemprichii. In Thalassia, one of the intine enzymes,acid phosphatase, is unambiguously associated with cytoplasmicinclusions. Flowering in Thalassia is coincident with the spring tides andthe pollen is released as a mass suspended in a thecal slimewhich contains approximately 5 per cent by weight carbohydrate,the principal mono-saccharide being mannose. Electrophoreticanalysis of the pollen-free slime shows a single glycoproteincomponent. The stigmas of the three seagrasses are papillate and of the‘dry’ type possessing a continuous protein-aceouspellicle subtended by a cuticle. The stigma pellicle exhibitscytochemically detectable esterase activity and binds the lectinconcanavalin A. Acid phosphatase activity is localized beneaththe cuticle at the tips of the stigma papillae. The discoveries show that the characteristics of the pollenand stigmas in the seagrasses are comparable with those foundin terrestrial flowering plants. The similarity in enzymaticproperites of the pollen wall and stigma pellicle suggests that,intriguingly, a similar mechanism of cuticle erosion might wellfollow compatible pollination both on land and in the sea. Enhalus acoroides, Thalassia hemprichii, Halophila stipulacea, Halophila decipiens, seagrasses pollen wall, stigma surface, hydrolytic enzymes     

GYNOECIAL DEVELOPMENT,POLLINATION, AND THE PATH OF POLLEN TUBE GROWTH IN THE TEPARY BEAN,PHASEOLUS ACUTIFOLIUS

The gynoecium of Phaseolus acutifolius var. latifolius, a self-compatible legume, is characterized by a wet non-papillate stigma, an intermeditae hollow/solid style type, and secretory cells on the ventral surface of the ovary which direct pollen tube growth. The stigma is initially receptive 5–6 days prior to anthesis. Production of stigmatic secretions, composed primarily of carbohydrates and lipids, fragment the cuticle covering epidermal cells of the stigma early in ontogeny; the lipidic aspect of the copious secretions apparently serves to inhibit desiccation after the cuticle is ruptured. Stylar canal development occurs as a combination of elongation of a basal canal present early in development, and dissolution of part of a solid transmitting tract tissue just below the stigma. Anthers dehisce and the tricolporate pollen is released onto the receptive stigma one day before anthesis. Following initial growth in intercellular spaces in the transmitting tract of the stigma, pollen tubes adhere to epidermal secretory cells along the ventral side of the stylar canal and upper ovary; here the transmitting tract is apparently limited in the number of tubes it can accommodate, providing a possible site of selection of male gametes.     

Ultrastructure of the dimorphic pollen and stigmas of the cleistogamous species,Collomia grandiflora (Polemoniaceae)

Summary An ultrastructural study of the pollen and stigma of the dimorphic flowers in the cleistogamous speciesCollomia grandiflora reveals significant differences in cytoplasmic features in the pollen and wall features in the papillae. Both pollen types contain lipid and starch reserves, but the smaller CL (cleistogamous) pollen shows a much greater abundance of starch compared to the CH (chasmogamous) pollen. In addition to the papular size and shape differences between the two stigma types, there is a more extensive cuticular stretching and wall microfibrillar loosening over the CH papillar tip. There is no apparent pellicle on the cuticle surface of either type of papilla, only scattered lipidic deposits. It is proposed that these structural differences may contribute to the cross incompatibility between the two floral morphs.     

POLLINATION IN LUPINUS NANUS SUBSP. LATIFOLIUS (LEGUMINOSAE)

Floral morphology and phenology and the timing of stigmatic receptivity and pollen viability were studied to elucidate the mechanisms by which self-pollination in Lupinus nanus subsp. latifolius is minimized under natural conditions. Pollen germination and pollen tube growth suggest that a physiological self-incompatibility system does not exist. Instead, self-pollination is minimized by protandry and by a collar of peristigmatic hairs, which initially inhibit access of autologous pollen to the stigma. These hairs subsequently wilt, permitting self-pollination of unvisited flowers. Pollen germinates in vivo one day before substantial metabolic enzyme activity can be detected. Citric acid cycle enzymes are not detectable in pollen, but those of anaerobic metabolism are. Beginning on the second day postanthesis, stigmatic secretions exude from weak areas on lateral walls of the elongate epidermal papillae, welling up in the interstices between these cells. This contrasts with the stigmas of other papilionoid legumes, in which secretions accumulate beneath the cuticle covering the stigmatic cells, and the often-thin cuticle must be ruptured before pollen and exudate can come into contact.     

Fine Structure and Cytochemistry of the Stigma Surface and Incompatibility in some Distylous Linum Species

The receptive surface of the stigma in distylous Linum grandiflorumand L. pubescens was studied by electron microscopy and cytochemicaltechniques. In both floral morphs a proteinaceous-lipoidal coatingis present on the papilla surface. In thrum stigmas the cuticleis highly irregular and pitted at the papilla tip. The cuticleis dislodged and torn at anthesis and an osmiophilic secretionproduct is released within a pectinaceous matrix. The secretionproduct stains for proteins and lipids and contributes to adhesionof pollen. In the larger pin papillae the cuticle is wavy, continuous,thicker than in thrum papillae and adjoins the cell wall. Inboth species the surface of the two types of pollen grains iscoated with lipids and protein. A similar behaviour of the male gametophyte is observed in incompatiblepollinations of L. pubescens, L. mucronatum and L. grandiflorum.In intramorph thrum pollinations pollen tubes are arrested withinthe stigma. In intramorph pin pollinations the majority of pollengrains fail to adhere to the stigma. Low permeability to waterin pin papillae, as determined by the neutral red test, maybe a factor preventing imbibition of the few adhering grains.Tubes of the few germinated grains are inhibited inside thestigma. On the part of the stigma, the difference in the major siteof inhibition in the two intramorph incompatible combinationsmay be accounted for by the dissimilar properties of the papillae,i.e. the occurrence of wet thrum stigmas and dry pin stigmas.Functionally, the unusual association of sporophytic incompatibilitywith wet thrum stigmas is attributed to retention of the secretorymaterial on individual papillae. Stigmatic papillae, cuticle, pollen coat, distyly, incompatibility, Linum grandiflorum, L. pubescens, L. mucronatum     

Pistil Exudate Production and Pollen Tube Growth in Lilium longiflorum Thunb.

Exudate production in the pistil of Lilium longiflorum was studiedin relation to pollen tube growth, using scanning electron microscopy(SEM), transmission electron microscopy and light microscopy.In contrast with conventional fixation for SEM, during whichthe exudate of L. longiflorum largely washes away, the exudateremains present through freezing in case of cryo-SEM. Usingthe latter method we observed that exudate production on thestigma and in the style started before anthesis. Just underneaththe stigma the exudate was first accumulated at the top of eachsecretory cell, followed by a merging of those accumulationsas exudate production proceeded. Exudate is also produced bythe placenta. It was however not possible to determine whetherany of this fluid originated from the micropyle. Apart fromthe cell shape and the cuticle present in between the secretorycells, the ultrastructure of the secretory cells covering theplacenta was comparable to those of the stylar canal. The transferwall of the secretory cells of the placenta originated fromfusing Golgi vesicles but the endoplasmic reticulum seemed tohave an important role as well. After pollination the pollen tubes grew across the stigma andentered the style through one of the slits in the three stigmalobes. The pollen tubes grew straight downward through the styleand were covered by exudate. As the pollen tubes approachedthe ovary their growth was restricted to the areas with secretorycells. In the cavity the pollen tubes formed a bundle and theybent from this bundle in between the ovules towards the micropylarside. There they bent again to stay close to the secretory cells.After bud pollination the pollen tube growth was retarded. Laterarriving pollen tubes had a tendency to grow close to the secretorycells of the style, which resulted in a growth between thesecells and preceding pollen tubes. If there was still a littleexudate produced, it resulted in a lifting up of the pollentubes, out of the exudate. The relationship between exudateproduction and pollen tube growth is discussed. Both the speedand the guidance of the pollen tube seemed determined by theproperties of the exudate.Copyright 1994, 1999 Academic Press Cryo-scanning electron microscopy, exudate, Lilium longiflorum, lily, ovary, pollination, pollen tube growth, secretory cell, stigma, style     

Pollen and stigma morphology of some Phaseoleae species (Leguminosae) with different pollinators

Pollen transport to a receptive stigma can be facilitated through different pollinators, which submits the pollen to different selection pressures. This study aimed to associate pollen and stigma morphology with zoophily in species of the tribe Phaseoleae. Species of the genera Erythrina, Macroptilium and Mucuna with different pollinators were chosen. Pollen grains and stigmas were examined under light microscopy (anatomy), scanning electronic microscopy (surface analyses) and transmission electronic microscopy (ultrastructure). The three genera differ in terms of pollen wall ornamentation, pollen size, pollen aperture, thickness of the pollen wall, amount of pollenkitt, pollen hydration status and dominant reserves within the pollen grain, while species within each genus are very similar in most studied characteristics. Most of these features lack relationships to pollinator type, especially in Erythrina and Mucuna. Pollen reserves are discussed on a broad scale, according to the occurrence of protein in the pollen of invertebrate- or vertebrate-pollinated species. Some pollen characteristics are more associated to semi-dry stigma requirements. This apical, compact, cuticularised and secretory stigma occurs in all species investigated. We conclude that data on pollen and stigma structure should be included together with those on floral morphology and pollinator behaviour for the establishment of functional pollination classes.     

The transmitting tract in Trimezia fosteriana (Iridaceae). 1. Ultrastructure in the stigma, style and ovary

An ultrastructural investigation of the entire transmitting tract in Trimezia fosteriana (Iridaceae) was undertaken. The transmitting tissue is secretory but transfer cells do not occur at any level. With exception for the stigma papillae, the cells are covered with large amounts of secretory products. The papillae have a thick and ridged cuticle. The cuticle in the rest of the transmitting tract is thin and detached from the cell wall by the secretory products. It is more or less ruptured in the secretory parts of the stigma and ovary. In the stylar canal the major part of the cuticle is continuous and covers the secretory products. The occurence of a large amount of vesicles in the stigma transmitting tissue cells is interpreted as a result of high dictyosome activity. An electron opaque material is produced in the dictyosomes and appears in vesicles and vacuoles but also between the plasma membrane and the cell walls in the stigma. A small amount of such material is present in the cell walls. Corresponding material is also present in the style and the ovary but declines basipetally. Plastids with strongly electron opaque plastoglobules are present at all levels in the transmitting tract.