Anther ontogeny in Campsis radicans (L.) Seem. (Bignoniaceae)

In this study anther ontogeny of Campsis radicans (L.) Seem. was investigated by transmission electron microscopy and light microscopy with special reference to the development of the anther wall. The anther wall formation follows the dicotyledonous type. The differentiation in anther starts with the appearance of archesporial cells which undergo periclinal divisions to give primary parietal layer to the epidermal site and the primary sporogenous cells to the inside. The primary parietal layer also divides to form two secondary parietal layers. Later, the outer secondary parietal layer (spl1) forms the endothecium and the middle layer by periclinal division whereas the inner one (spl2) directly develops into the outer tapetum forming the inner most layer of the anther wall. The sporogenous tissue is generally organized in two rows of cells with a horseshoe-shaped outline. The remainder of the tapetum lining the sporogenous mass is derived from the connective tissue. The tapetum thus has dual origin and dimorphic. Anthers are tetrasporangiate. The wall of the anther consists of an epidermis, endothecium, middle layer, and the secretory type tapetum. Tapetal cells are usually binucleated. Epidermis and Endothecium layers of anther wall remain intact until the end of anther and pollen development; however, middle layer and tapetum disappear during development.     

A histochemical study of meiocytes, microspores, pollen and the tapetum in Kalanchoe

A histochemical study was made of developing sporogenous cells, meiocytes, microspores, pollen and the tapetum in anthers of Kalanchoë morlagei. Storage polysaccharides were seen only in mature pollen. Ascorbic acid was not found in the sporogenous cells, but in meiocytes a high quantity of this compound occurred in the cytoplasm. Spore tetrads, microspores and pollen also had a high ascorbic acid content. The amounts of RNA and proteins were high in the sporogenous cells and in meiocytes during meiosis–I, but a small reduction trend with respect to RNA content was noticed. Microspores in the tetrad showed high amounts of RNA and proteins. In the young microspores RNA and proteins declined. Later, as the microspores matured, an increase in content of RNA and proteins took place. The wall of the young microspores gave a faint green colour with azure B stain, the intensity of which increased and remained high in the exine of the mature pollen. The additional wall thickening around the meiocytes and tetrads gave a strong pink colour with PAS test. This thickening showed presence of silver granules when tested for ascorbic acid, the tapetum synthesized abundant quantities of PAS positive starch, ascorbic acid, RNA and proteins from its appearance in the anther wall until microspore formation. During meiocyte meiosis the tapetum became highly vesicular. Our results indicate that the tapetum constitutes a tissue specialized for storing and supplying basic nutritive substances for the developing pollen in the anther.     

Morphological development of anthers induced by the dimorphic smut fungus<Emphasis Type="Italic"> Microbotryum violaceum</Emphasis> in female flowers of the dioecious plant<Emphasis Type="Italic"> Silene latifolia</Emphasis>

When inoculated with the dimorphic smut fungus Microbotryum violaceum (Pers.) G. Deml and Oberwinkler, the female flower of the dioecious plant Silene latifolia (Miller) E.H.L. Krause develops anther-like structures filled with spores instead of pollen grains. Using natural scanning electron microscopy, Nomarski interference microscopy, and fluorescence microscopy, we investigated the morphological modifications of the host plant resulting from this parasitism and the localization of smut hyphae in the flower bud. Flowers of infected plants lasted significantly longer than those of healthy plants, probably because the infection strengthened floral organs, such as the flower base and the anther filaments. Smut hyphae were observed throughout all organs of the young flower buds of infected plants, including sepals, petals, stamens, and pistil primordia. In healthy female flowers, anthers initiated sporogenous cell formation, but lacked parietal cell layers. By contrast, the parietal cell layers of infected female flowers differentiated into tapetal tissue, middle cell layers, and endothecial layers, as in the anthers of healthy male flowers. Smut spore formation in the infected anther was initiated in intercellular regions between the sporogenous cells, resulting in degeneration of premature sporogenous cells, tapetal tissue, and middle cell layers. The development of the endothecial layers and epidermis in the infected anther were morphologically normal.Abbreviations DAPI 4,6-diamidino-2-phenylidole - i infected - PMC pollen mother cell     

凤仙花花药发育中多糖和脂滴组织化学研究

以不同发育时期的凤仙花花药为实验材料,采用组织化学方法,对花药发育中的结构变化及多糖和脂滴物质分布进行观察。结果表明:(1)凤仙花的花药壁由6层细胞组成,包括1层表皮细胞,2层药室内壁细胞,2层中层细胞和1层绒毡层细胞。其中绒毡层细胞的形态不明显,很难与造孢细胞区分,且在小孢子母细胞时期退化。(2)在小孢子母细胞中出现了一些淀粉粒,但减数分裂后,早期小孢子中的淀粉粒消失,又出现了一些小的脂滴;随着花粉的发育,小孢子形成大液泡,晚期小孢子中的脂滴也消失;小孢子分裂形成二胞花粉后,营养细胞中的大液泡降解、消失,二胞花粉中又开始积累淀粉;接近开花时,成熟花粉中充满细胞质,其中包含了较多的淀粉粒和脂滴。(3)在凤仙花的花药发育中,绒毡层细胞很早退化,为小孢子母细胞和四分体小孢子提供了营养物质;其后的中层细胞退化则为后期花粉发育提供了营养物质。     

STUDIES IN THE BIGNONIACEAE. II. ONTOGENY OF DIMORPHIC ANTHER TAPETUM IN TECOMA

A developmental study of anther tapetum in Tecoma stans has shown that the hypodermal archesporial layer differentiates in each microsporangium by cutting off a primary parietal layer to the outside (epidermal) and a primary sporogenous layer to the inside (connective). The primary parietal layer divides periclinally, producing the outer secondary parietal layer, which by further divisions, forms the future endothecium and the middle layer. On epidermal side, the inner secondary parietal layer gives rise to tapetum. The remainder of the tapetum on the inside (connective) is contributed by the parenchymatous connective cells lying just outside the sporogenous cells. The tapetum thus follows the dicotyledonous type of ontogeny. It also shows a distinct dual origin and is structurally dimorphic.     

STUDIES IN THE BIGNONIACEAE. I. ONTOGENY OF DIMORPHIC ANTHER TAPETUM IN PYROSTEGIA

Development of the anther wall was studied with special reference to the tapetum in Pyrostegia ignea. The archesporium in each microsporangium is horseshoe-shaped. The inner tapetum develops earlier from the vegetative cells of the connective region while the outer differentiates a little later from the parietal layers. Thus, the tapetum has a distinct dual origin. The two tapetal layers exhibit a pronounced structural dimorphism. Sometimes, sterile septae, partitioning the sporogenous tissue, develop in microsporangia. A prominent membrane with Ubisch granules (orbicules) is organised on the inner tangential surface of the tapetal protoplasts facing the uninucleate microspores.     

ANTHER AND POLLEN DEVELOPMENT IN RICE (ORYZA SATIVA)

Investigations of the growth of anthers and ontogeny of pollen grains of Oryza sativa (rice) IR-30 were undertaken for the purpose of 1) providing a set of growth measurements and 2) describing stable cytological features of anther and pollen development. Correlations exist between elongation of the floret and growth parameters of the anther such as its length, width, fresh and dry weights and cytological stage of pollen development. In the early ontogeny of the anther, hypodermal archesporial initials divide periclinally to form primary parietal cells and primary sporogenous cells. Each of the latter divides twice mitotically to generate four microspore mother cells, which undergo meiosis. The anther wall is formed by anticlinal and periclinal divisions of the primary parietal cells as well as of cells surrounding the primary sporogenous cells. Subsequent cytological features in the development of anther and pollen grains of rice have much in common with anther and pollen developmental biology of other members of Gramineae.     

Anther diversity and function inVerticordia DC. (Myrtaceae)

Anther form and structure across the taxonomic groups inVerticordia were examined. The three anther types which were recognised — rectangular, oblong and saccate, accord well with the three subgenera into which the genus has been divided. The sporogenous part of the anther has a fairly typical angiosperm anatomy. However in many species there is a small or large gland in the upper filament/connective which contains lipidic contents. The anatomy of this structure is based on that of the oil glands which are ubiquitous in Myrtaceae primary tissues. However the gland is usually much larger than these and is schizolysigenous in origin. Evolutionary development of the anthers in the genus is related to pollination systems and the development of secondary pollen presentation from the upper style in some groups. Anther glands may have originally had a protective function for the sporogenous tissue. However in different groups the function has changed or the gland has disappeared. In some species in subgenusChrysoma (which does not have secondary pollen presentation) the gland contents seem to be an additional food source for pollinators. In other groups, with the development of secondary pollen presentation the protective function has become redundant and anther glands have either disappeared or produce contents which have become part of the process of pollen dispersal.     

Anther ontogeny in <Emphasis Type="Italic">Brachypodium distachyon</Emphasis>

Brachypodium distachyon has emerged as a model plant for the improvement of grain crops such as wheat, barley and oats and for understanding basic biological processes to facilitate the development of grasses as superior energy crops. Brachypodium is also the first species of the grass subfamily Pooideae with a sequenced genome. For obtaining a better understanding of the mechanisms controlling male gametophyte development in B. distachyon, here we report the cellular changes during the stages of anther development, with special reference to the development of the anther wall. Brachypodium anthers are tetrasporangiate and follow the typical monocotyledonous-type anther wall formation pattern. Anther differentiation starts with the appearance of archesporial cells, which divide to generate primary parietal and primary sporogenous cells. The primary parietal cells form two secondary parietal layers. Later, the outer secondary parietal layer directly develops into the endothecium and the inner secondary parietal layer forms an outer middle layer and inner tapetum by periclinal division. The anther wall comprises an epidermis, endothecium, middle layer and the secretory-type tapetum. Major documented events of anther development include the degradation of a secretory-type tapetum and middle layer during the course of development and the rapid formation of U-shaped endothecial thickenings in the mature pollen grain stage. The tapetum undergoes degeneration at the tetrad stage and disintegrates completely at the bicellular stage of pollen development. The distribution of insoluble polysaccharides in the anther layers and connective tissue through progressive developmental stages suggests their role in the development of male gametophytes. Until sporogenous cell stage, the amount of insoluble polysaccharides in the anther wall was negligible. However, abundant levels of insoluble polysaccharides were observed during microspore mother cell and tetrad stages and gradually declined during the free microspore and vacuolated microspore stages to undetectable level at the mature stage. Thus, the cellular features in the development of anthers in B. distachyon share similarities with anther and pollen development of other members of Poaceae.     

Comparative development of aseptate and septate anthers of Annonaceae

We compared anther development in 13 genera and 15 species of Annonaceae to document the nature and development of anther septa. In aseptate anthers, all sporogenous initials proceed to sporogenesis and meiosis. In septate anthers, a small number of sporogenous initials, in a discontinuous distribution pattern, differentiate into sporogenous cells; the remaining initials become sterile and form cellular septa that partition each anther lobe into multiple sporangial chambers. In species where the septum is 1-2 cell layers thick, the entire septum becomes tapetal (T-type septa) and breaks down before anther dehiscence. In species in which the septum is three or more cell layers thick, only the layer in direct contact with the sporogenous cells becomes tapetal, and the remaining cells become parenchymatous (P-type septa). These thicker P-type septa are sometimes visible in dehisced anthers. Both types are homologous in ontogeny and are highly associated with the production of compound pollen. We propose that the evolution of anther septation in Annonaceae was mainly driven by the requirement for highly efficient nutrient and physical support to the development of large, compound pollen units.     

Comparative microsporogenesis and anther development of selected species from Magnoliaceae

Stamen development and microsporogenesis of four species from Magnoliaceae was investigated in order to provide additional data from this family. Stamen bases were found to be wide and short, without morphological differentiation in Magnolia moto, M. paenetalauma and Woonyoungia septentrionalis. In contrast, stamens are distinctly differentiated into anther and filament regions in Michelia crassipes. The orientation of dehiscence is introrse, introrse‐latrorse and latrorse in M. moto, M. paenetalauma and M. crassipes, respectively. The vascular bundles range from three to five (M. moto, M. paenetalauma) to one (M. crassipes). The amount of the connective tissue has been reduced from three to two times of the sporogenous tissue in M. moto and M. paenetalauma. The two parts are nearly equal in M. crassipess. In W. septentrionalis, the orientation of dehiscence, the vascular bundles and the size of the connective tissue vary in different parts of the floral receptacle. The endothecium and endothecial‐like cells form a ring that encloses the entire anther. The middle layer cells originate from both the outer and inner secondary parietal layers, and start to degenerate gradually at the microspore interphase stage or meiosis stage. The tapetum is of the secretory type, derived from the inner secondary parietal cells. The mature anther wall is composed of one epidermal, one endothecial, three to four middle layer(s) and one glandular tapetum. Only one epidermis, one endothecium, and the remnants of the middle layer and tapetum are left before anther dehiscence. Microspore tetrads appear as isobilateral, tetrahedral, decussate and T‐shaped, produced by a modified simultaneous microsporogenesis, which have evolved from the common ancestor of all Magnoliaceae. Our results support an ancestral state with stamens with non‐marginal sporangia and the amount of sterile tissue exceeding the amount of sporogenous tissue, and evolutionary trends toward equalization of the amount of fertile and sterile tissue on the stamen.     

Anther wall layers control pollen sugar nutrition inLilium

Summary Anthers ofLilium were for the first time investigated at the ultrastructural level in order to appreciate the possible ways of sugar transport in the microsporangium. Our results have shown that the cells of the outer anther wall layers and the cell of the connective were interconnected by plasmodesmata, thus allowing assimilates to travel through the symplasmic pathway from the vascular bundle to the most internal middle layer (ML 1). ML 1 was devoid of cell communication throughout pollen development. Tapetal cells were also lacking plasmodesmata on their external face towards ML 1, but adjacent tapetal cells developed lateral junctions: the tapetum could represent a syncytium. Sugars destinated to pollen in the loculus have then to cross the ML 1 and the tapetal layers by the apoplasmic pathway; it is suggested that these two envelopes could be involved in the control of sugar transport from the outer anther wall layers to the locular fluid. Before microspore mitosis, the tapetum degenerated but ML 1 remained structurally unchanged. During pollen development, the guard cells of stomata were lacking cell communication, and preserved their starch content, which could be the sign of photosynthesis within the anther wall. In order to check whether these structural disconnections in anther tissues corresponded to physiological barriers, isolated pollen and stamens were cultivated during the anther maturation phase, on a medium containing increasing concentrations of sucrose (0 M, 1/6 M, 1/2 M, 1 M). After 7 days of culture, isolated pollen was engorged with starch grains and was unable to germinate, whereas in cultivated stamens, pollen did not contain any starch grain: sporophytic tissues, however, accumulated abnormal amylaceous reserves. These results strongly suggest that the anther wall layers, in particular ML 1, starve pollen with sugars during its maturation. They are acting as a physiological buffer storing nutriment surplus in starch grains.Abbreviations ML 1 middle layer 1 - ML 2 middle layer 2 - PAS periodic acid Schiff - PATAg periodic acid thiosemicarbazide silver nitrate     

开口箭大小孢子发生及雌雄配子体发育

利用石蜡切片技术,对百合科植物开口箭(Tupistra chinensis Baker)大小孢子发生及雌雄配子体发育进程进行胚胎学观察分析,以明确开口箭胚胎发育的特征,为百合科植物的研究提供生殖生物学依据。结果表明:(1)开口箭花药具有4个药室,花药壁的发育方式为基本型,由表皮、药室内壁、中层及绒毡层组成;绒毡层发育类型为分泌型,到四分体花药阶段绒毡层细胞开始解体退化,花药成熟时完全消失。(2)花粉母细胞减数分裂为连续型,依次形成二分体、四分体,四分体为左右对称形;成熟花粉为2-细胞花粉,具单萌发沟。(3)子房3室,倒生型胚珠6枚,双珠被,薄珠心;在花部的分化早期,由珠心顶端表皮下方分化出雌性孢原细胞,孢原细胞经过一次平周分裂形成周缘细胞和造孢细胞,造孢细胞发育为大孢子母细胞;大孢子母细胞第一次减数分裂后形成二分体,珠孔端的二分体孢子退化,合点端的二分体孢子继续第二次分裂,形成两个子细胞依次发育为二核胚囊、四核胚囊和八核胚囊;开口箭的胚囊发育类型为葱型。     

凤仙花花药发育特征

凤仙花花药发育比较特殊: 在造孢细胞时期,花药横切面中央是体积较大、细胞内含物较多的细胞团、包括造孢细胞和绒毡层细胞。花药药壁细胞的细胞质较稀少,与中部细胞界限明晰。花粉母细胞时期的花药药壁由约6层细胞组成,但细胞的界限不明显;绒毡层细胞显示变形流入药室中。到四分体时期,绒毡层细胞进一步退化。开花时,成熟花药的药壁细胞由一层表皮细胞、两层药室内壁细胞和一层中层细胞组成。对凤仙花花药绒毡层的特殊性质进行了讨论。     

Ultrastructural analysis of the behavior of the dimorphic fungus Microbotryum violaceum in fungus-induced anthers of female Silene latifolia flowers

Summary. The development of male organs is induced in female flowers of the dioecious plant Silene latifolia by infection with the fungus Microbotryum violaceum. Stamens in a healthy female flower grow only to stage 6, whereas those in an infected female flower develop to the mature stage (stage 12), at which the stamens are filled with fungal teliospores instead of pollen grains. To investigate these host–parasite interactions, young floral buds and fungus-induced anthers of infected female flowers were examined by electron microscopy following fixation by a high-pressure freezing method. Using this approach, we found that parasitic hyphae of this fungus contain several extracellular vesicles and have a consistent appearance up to stage 8. At that stage, parasitic hyphae are observed adjacent to dying sporogenous cells in the infected female anther. At stage 9, an increased number of dead and dying sporogenous cells is observed, among which the sporogenous hyphae of the fungus develop and form initial teliospores. Several types of electron-dense material are present in proximity to some fungi at this stage. The initial teliospores contain two types of vacuoles, and the fungus cell wall contains abundant carbohydrate, as revealed by silver protein staining. The sporogenous cell is probably sensitive to infection by the fungus, resulting in disruption. In addition, the fungus accelerates cell death in the anther and utilizes constituents of the dead host cell to form the mature teliospore. Correspondence and reprints (present address): Molecular Membrane Biology Laboratory, RIKEN, 2-1, Hirosawa, Wako, Saitama 351-0198, Japan.     

A novel extinction screen in Arabidopsis thaliana identifies mutant plants defective in early microsporangial development

Few Arabidopsis mutants defective in early male or female germline development have been reported. A novel extinction screen has been devised which permits the identification of mutants deficient in the earliest stages of anther development. Using mutagenized plants carrying GUS reporter constructs driven by tapetal-specific promoters originally derived from Brassica genes, a wide spectrum of mutants have been identified in Arabidopsis, ranging from those defective in archesporial cell differentiation to others expressed later in development. Crosses between these lines and known anther development mutants have enabled the identification of lines carrying mutations in genes expressed during very early anther formation. Initial characterization reveals these early mutants fall into two classes, gne (GUS-negative) 1-like, and gne2-like. Members of the gne1 mutant class initiate all four layers of the anther wall and an appropriate number of sporogenous cells; however, as development proceeds the tapetal and middle-layer cells enlarge, eventually crushing the sporogenous cells. The gne2 class anthers are disrupted at an earlier stage, with the middle and tapetal layers failing to form, and an excess of sporogenous cells developing until the germline aborts late in meiosis II. Analysis of these mutants has already raised questions about the accuracy of current models of angiosperm anther development.     

Embryology of theaceae — Anther and ovule development ofAdinandra,Cleyera andEurya

Anther and ovule development of the theaceous Ternstroemioideae is reported for the first time on the basis of eight specles of three generaAdinandra, Cleyera andEurya. Anthers of these three genera are similar and can be characterized by the following traits: tapetum of glandular type, anther dehiscing latrorse-introrse, both connective and anther epidermis heavily tanniniferous, and connective and even anther wall layers having abundant druses. Their ovules are also very similar in being bitegmic and tenuinucellate, and in having a micropyle formed by the inner integument only, three cell-layered integuments, a raphe bundle terminating at chalaza, usually amphitropous or less often campylotropous ovule, embryo sac formation of Polygonum type, ephemeral antipodal cells, and tanniniferous ovule epidermis. Such ovules are readily distinguishable from those of Camellioideae and all other families. It is suggested that the three genera studied are closely related, and that the degree of embryological specialization is highest inAdinandra and lowest inEurya. On the basis of the significant embryological discrepacies, the Ternstroemioideae seem to have diverged rather distantly from the other core-subfamily Camellioideae of the Theaceae.     

Changes in calcium and calmodulin levels during microsporogenesis,pollen development and germination in Gasteria verrucosa (Mill.) H. Duval

Summary The distribution of membrane calcium and calmodulin (CaM) has been fluorimetrically determined in the anther of Gasteria verrucosa with particular attention to sporogenous cells, meiocytes, microspores, pollen and stages of pollen germination and tube growth using chlortetracycline (CTC) and fluphenazine (FPZ). CTC and FPZ fluorescence in sporogenous cells is relatively higher than in the adjacent tapetal cells, indicating higher membrane calcium and CaM levels in the former cell type. However, during meiosis there is a significant increase in membrane calcium and CaM levels in the meiocytes compared to that found in the young microspores. CTC and FPZ fluorescence in the sporogenous cells, meiocytes and young microspores is punctate and slightly diffused throughout the cytoplasm. In the microspores of the tetrad and the young released microspores CTC fluorescence (CTCf) is polarized and mainly associated with the area opposite the future colporal region. FPZ fluorescence (FPZf) becomes polarized in the young microspore. Subsequently, there is a shift in the polarity, and most of the CTCf and FPZf in the old microspores and pollen is regionalized towards the colporal region, and the fluorescence is more diffused, indicating a change in the organellar-bound calcium and CaM. This final graded distribution of CTCf is maintained during pollen germination in that the growing pollen tubes invariably show a tip to base membrane-calcium gradient. In the tapetal cells a high level of Ca²⁺ is present during the microspore stage. During the preparation for anthesis the endothecium differentiation is marked by the presence of Ca²⁺. Post-treatment of labelled cells with a Ca²⁺ chelator such as EGTA resulted in a substantial decrease in diffuse and punctate CTCf. Alternatively, treatment of cells with non-ionic detergent Nonidet P-40 resulted in the total elimination of CTCf, suggesting that the observed CTC fluorescence was due to membrane-associated calcium. The cytological specification of CTC as a probe for calcium is discussed. From cytofluorometric measurements and atomic absorption, it became clear that the level of Ca²⁺ in the anther is high during the sporogenous and meiotic phases. An increase in CTCf and FPZf occurred after microspore mitosis. An interaction of Ca²⁺ transport from tapetum to the young pollen is postulated. These findings suggest that the level of Ca²⁺ in the anther during meiosis is generally relatively higher than at the sporogenous or young microspore stage. These findings are discussed in the light of available information on the role of Ca²⁺ and CaM-mediated processes such as cell division, callose synthesis and pollen-tube tip growth.     

The mac1 mutation alters the developmental fate of the hypodermal cells and their cellular progeny in the maize anther.

In angiosperm ovules and anthers, the hypodermal cell layer provides the progenitors of meiocytes. We have previously reported that the multiple archesporial cells1 (mac1) mutation identifies a gene that plays an important role in the switch of the hypodermal cells from the vegetative pathway to the meiotic (sporogenous) pathway in maize ovules. Here we report that the mac1 mutation alters the developmental fate of the hypodermal cells of the maize anther. In a normal anther a hypodermal cell divides periclinally with the inner cell giving rise to the sporogenous archesporial cells while the outer cell, together with adjacent cells, forms the primary parietal layer. The cells of the parietal layer then undergo two cycles of periclinal divisions to give rise to three wall layers. In mac1 anthers the primary parietal layer usually fails to divide periclinally so that the three wall layers do not form, while the archesporial cells divide excessively and most fail to form microsporocytes. The centrally located mutant microsporocytes are abnormal in appearance and in callose distribution and they fail to proceed through meiosis. These failures in development and function appear to reflect the failure of mac1 gene function in the hypodermal cells and their cellular progeny.     

Effects of light conditions and 2,4-D concentration in soybean anther culture

The morphogenic response of anther walls and connective tissue is the greatest obstacle to androgenesis in soybean anther culture. Whereas induction to microspore embryogenesis occurs in the dark in almost all plant species, soybean anthers have been cultured under light. In an attempt to establish culture conditions that simultaneously stimulate microspore embryogenesis and inhibit epidermal and connective cell proliferation, the effect of light and two 2,4-dichlorophenoxyacetic acid (2,4-D) concentrations (2 and 10 mg l^–1) on the induction process was investigated. Higher 2,4-D concentration speeded up microspore plasmolysis and did not improve androgenesis. Callogenesis and embryogenesis induction from sporophytic cells were significantly lower in the dark, and some microspores showed major alterations in the sporoderm. Auxin 2,4-D and induction under light contributed to the morphogenic response of the anther walls and connective tissue under the conditions previously recommended to trigger microspore embryogenesis.