Cytological Studies on the Embryogenesis of Hybrids between Oryza sativa L.(Pennisetum sp.

(1) The pollen grains of Pennisetum can germinate normally on the stigma of rice and the pollen tubes can grow into the style and enter the embryo sacs. However, the process of double fertilization is slow and more or less abnormal and phenomenon of simple fertilization often occurs. (2) It has been found that in the majority of cases the development of the embryos is slow and stays long in the stage of globular embryos, thus, the differentiation of the embryos is very difficult and degeneration of the embryos appears many times. Simple differentiation was observed only in some embryos during 16–24 days after pollination. Normal differenting and developing embryos were not observed. The cause of the degeneration of the embryos is related to the state of endosperm development and also to the non-coordination of the genomes of both parents. (3) The development of the endosperm is abnormal. The change from the free nuclei into the cells in the endosperm is delayed as late as the 8th day after pollination. The whole endosperm tissue is composed of the cell masses which are quite different both in shape and function, a part of these endospemn cells lacks the ability to synthesize starch. The disintegration of the endosperm could be frequently observed during their development. (4) A lots of starch are accumulated in the nucellar cells near the antipodals, It is shown that there was some metabolic confusion resulted from the crossing in the embryo sacs. Based on the above mentioued results the authers consider that the failure of producing seeds by crossing is at least related to the nutrient condition which are essential for the development of embryos. If embryo culture technique is employed at the early stage of the embryo development the hybrid seeds could be obtained.     

In vitro pollination of angiosperm ovules with gymnosperm pollen grains

Summary Pollen grains of the gymnosperm species Ephedra distachya and Pinus wallichiana germinated abundantly on the in vitro cultured placentae of the angiosperm species Nicotiana tabacum, Melandrium album and Allium moly. Some P. wallichiana pollen tubes entered the micropyles of M. album. Embryological observations of cross-pollinated M. album ovules 2 or 3 d after cross-pollination revealed the presence of pollen tube remnants within the embryo sacs. Karyological disturbances in the two- and three-celled proembryos and endosperm nuclei indicated their probable hybrid origin. In some crosses, gynogenetic haploid proembryos were also noticed.     

Direct somatic embryogenesis from <Emphasis Type="Italic">Coffea arabica</Emphasis> L. and <Emphasis Type="Italic">Coffea canephora</Emphasis> P ex Fr. under the influence of ethylene action inhibitor-silver nitrate

For the first time direct somatic embryogenesis from hypocotyl explants of in vitro regenerated plantlets of C. arabica and C. canephora was achieved on modified MS medium containing 10 – 70 μM silver nitrate supplemented with 1.1 μM N⁶ benzyladenine and 2.85 μM indole-3-acetic acid. A maximum of 144.1±7.3 and 68.7±3.3 embryos per explant were produced at 40 μM silver nitrate in C. canephora and C. arabica respectively. Only yellow friable embryogenic callus obtained from the cut edges of most of leaf explants of both C. arabica and C. canephora at all concentrations of silver nitrate were tried in this experiment. Formation of secondary embryos from stage I primary embryos (small yellow, round, globular embryos) was more (28.23±1.3) at 60 μM silver nitrate in C. canephora, while 40 μM silver nitrate supported more of secondary embryo formation in C. arabica (40.5±1.2). When stage II (green globular round matured embryos) and stage III primary embryos (tubular stage embryos) were used, secondary embryo formation was very small and many of these embryos developed into plantlets and some of them even rooted. By using these protocols within 45 – 60 days it is possible to get secondary embryos from primary embryos and direct somatic embryos from hypocotyls of in vitro plantlets in both these Coffea species.     

Abscisic acid and ancymidol promote conversion of somatic embryos to plantlets and secondary embryogenesis inAsparagus officinalis L.

Summary The effects of abscisic acid (ABA) (0, 0.09 μM, 0.19 μM, 0.28 μM, and 0.38 μM) or ancymidol (0, 0.98 μM, 1.95 μM, 2.93 μM, 3.90 μM) in embryo germination medium on the conversion of primary embryos to plantlets and secondary embryogenesis were evaluated for asparagus. ABA and ancymidol each significantly enhanced both responses. ABA was more effective than ancymidol in promoting the conversion of primary embryos to plantlets, while the converse was true for the production of secondary embryos. The most effective treatments for embryo conversion were 0.19 and 0.28 μM ABA; 75–77% bipolar and 55–57% globular embryos converted to plantlets. For secondary embryogenesis, the most effective treatments were 1.95 and 2.93 μM ancymidol; 99–101 and 84–86 somatic embryos were produced from 10 globular and 10 bipolar embryos, respectively. Bipolar embryos generally converted to plantlets better than globular embryos, but more secondary embryos were produced from globular embryos than from bipolar embryos in all treatments. ABA and ancymidol also affected the morphology of the plantlets produced. The plantlets from the embryos incubated on the medium with ancymidol had strong and thick shoots and roots, while those on the medium with ABA had long, thin shoots and short thin roots.     

Polyploidization in embryogenic microspore cultures ofBrassica napus L. cv. Topas enables the generation of doubled haploid clones by somatic embryogenesis

Summary Embryogenic microspore and pollen culture followed by subculture of microspore-derived plantlets enabled the production of clones ofBrassica napus cv. Topas. Flow-cytometric analysis revealed that most microspore- and pollen-derived embryos (pEMs) were haploid initially. Spontaneous diploidization occurred at the globular stage of the pEMs, and was expressed as the relative increase of the 2C and 4C nuclear DNA content. Diploidization occurred throughout various organs of the pEMs and resulted in the formation of haploid and doubled haploid chimerics. In some embryos, nearly all cells were doubled haploid. From early cotyledon stage onward, pure haploid embryos were not observed anymore. At late cotyledon and germination stages, pure doubled haploid embryos and plantlets increased in number. Tetraploid pEMs were found occasionally. A culture regime was established to induce somatic embryos on the pEM-derived young plantlets. The ploidy of the somatic embryos varied highly and tended to be the same as that of the tissue at the initiation site on the pEM-plant. The results show that during the embryogenic development ofB. napus microspores, spontaneous diploidization occurs at globular stage, and increases progressively, resulting in the formation of chimerical haploid and doubled haploid plants as well as pure doubled haploid plants; ploidy neither affects pEM development at embryo developmental stages nor somatic embryogenesis, that starts on young pEM-derived plantlets; doubled haploid somatic embryos can be cloned from single pEM-derived plantlets; and doubled haploid embryos develop to fertile plants.     

Polyamines and cytokinins in celery embryogenic cell cultures

The effect of inhibitors of polyamine biosynthesis on the development of embryogenic cell cultures of celery (Apium graveolus L.) was studied. Several developmental stages of somatic embryos were compared for differences in the content and biosynthesis of free polyamines and for cytokinin content. Cyclohexylamine and particularly methylglyoxal bis(guanylhydrazone), inhibited both cell division and the organization of polar embryos from globular embryos. Difluoromethylornithine slightly promoted embryo development, especially cell division.The free putrescine content of globular embryos was 6-fold that of fully differentiated plantlets, and that of spermidine 2-fold. Only a slight increase in the spermine content was found with embryo development. These differences were confirmed by data from polyamine biosynthesis. Incorporation of ¹⁴C-arginine into polyamines was slightly higher than that of ¹⁴C-ornithine. Over 96% of this incorporation was detected in the putrescine fraction. Incorporation of ¹⁴C into putrescine in globular embryos was 3 to 4-fold that in fully-differentiated plantlets. Incorporation into spermidine and spermine was, however, higher in plantlets than in globular embryos.Cytokinin analysis revealed considerable differences in the biological activity between the developmental stages of embryogenesis. This could be due to endogenous cytokinins and/or BA taken up from the maintenance medium. Cytokinin levels decreased with increased embryo development. Most of the detected cytokinin-like activity co-chromatographed with BA and its metabolites. Some as yet unidentified peaks of activity were recorded in the globular embryos.The results are considered with respect to the possible participation of polyamines and cytokinins in the development of embryogenic cell cultures of celery. It is suggested that the onset of embryogenesis is characterized by a high content of putrescine and cytokinins, while a decrease in putrescine synthesis and cytokinin content, and an increase in spermidine and spermine content, accompany further embryo development and plantlet formation.Abbreviation ADC arginine decarboxylase - ODC ornithine decarboxylase - 2,4-D dichlorophenoxyacetic acid - DFMA difluoromethylarginine - DFMO difluoromethylornithine - MGBG methylglyoxal bis(guanylhydrazone) - CHA cyclohexylamine - BA benzyladenine - BAR benzyladenine riboside     

Embryo rescue and plant regeneration in vitro of selfed chickpea (Cicer arietinum L.) and its wild annual relatives

The main constraint to the transfer of desired traits into cultivated chickpea from wild Cicer relatives is the presence of post-zygotic barriers which result in abortion of the immature embryo following interspecific hybridisation. Rescue of hybrid embryos in vitro and regeneration of hybrid plantlets could allow chickpea breeders to transfer desirable traits from wild relatives of chickpea. The development of embryo rescue techniques using selfed chickpea and selfed wild relatives is being used as a first step to protocols for wide hybrids. Optical microscopy studies of embryogenesis, in both selfs and hybrids, identified deleterious changes in the fertilised hybrid seed as early as 2–4 days after pollination in some crosses. These observations suggest that the appropriate time to rescue chickpea × C. bijugum hybrids is at the early globular stage of embryogenesis (2–7 days old), which requires the development of a complex tissue culture medium. In contrast hybrids between chickpea × C. pinnatifidum abort later (up to 15–20 days old) at the heart-shaped or torpedo stages, and are easier to rescue in vitro. Genotype also plays a significant role in the ability of immature selfed ovules to germinate in vitro. In this paper we report on the optimisation of␣protocols for rescueing immature embryos using selfed chickpea and its wild relatives in ovule, and subsequently to regenerate plantlets.     

Plant regeneration via direct somatic embryogenesis in Panax japonicus

Panax japonicus is one of the important medicinal plants. Here, we established the protocol for plant regeneration of P. japonicus via direct somatic embryogenesis. Somatic embryos were directly obtained from the segments of zygotic embryos on MS medium with 4.4 μM 2,4-D. Thereafter, somatic embryos were produced by repetitive secondary somatic embryogenesis. The secondary somatic embryo formation was enhanced by plasmolyzing pretreatment (1.0 M mannitol for 10 h). Frequency of secondary somatic embryo formation from cotyledon segments was lowered by plasmolyzing pretreatment, but the number of somatic embryos per explants was greatly increased. Plasmolyzing pretreatment resulted in retardation of embryo growth and required subculture to fresh medium for further growth of embryos into cotyledonary stage. Without plasmolyzing pretreatment, cotyledonary embryos were obtained after 8 weeks of culture. All the cotyledonary somatic embryos germinated by 5 μM GA₃ treatment, but only 15.3% were germinated on hormone-free medium. After 2 months of culture on 1/2 strength WPM medium, plantlets produced flowers spontaneously. In the anthers of in vitro flowers, microsporogenesis occurred normally with low number of pollen grains.     

Gynogenetic haploids of Citrus after in vitro pollination with triploid pollen grains

This study reports haploid plantlet regeneration through gynogenesis in Citrus clementina Hort. ex Tan., cv. Nules, induced by in vitro pollination with pollen grains of Oroblanco, a triploid cultivar of grapefruit. It indicates that parthenogenesis induced in vitro by triploid pollen can be an alternative method to obtain haploids in monoembryonic cultivars of Citrus. Actually, despite considerable efforts, androgenesis has not been yet successful in many genotypes of Citrus. Pollination and mature stage of pistils was necessary for gynogenic embryo regeneration. Fourteen haploid gynogenic embryos of Nules clementine were obtained. Embryo conversion was high (85.7%) and embryos vigorously germinated producing twelve plantlets. Chromosome counting, performed in the roots of obtained embryos, showed the haploid level (n=x=9). Isozyme analyses confirmed the expected homozygous state of embryos and plantlets. This revised version was published online in June 2006 with corrections to the Cover Date.     

Differential development of plastids during microspore embryogenesis in barley

Summary In order to understand and limit albino plantlet formation during pollen embryogenesis in barley (Hordeum vulgare L. cv. Igri), plastid feature was followed during pollen embryogenesis under two anther culture conditions and compared to plastid development in the zygotic embryo. The first condition was characterized by cold pretreatment and maltose in the induction medium. Both embryos and calli were then obtained. During pollen embryo development, up to 30% of plastids had abnormal features. Disruptions mainly affected the plastid size, the feature of plastid envelopes, thylakoid and granum organization, as well as starch accumulation. In pollen calli, superficial cells had meristematic features. Up to 50% of plastids exhibited the above mentioned abnormalities. Internal cells were highly vacuolated with amyloplast-like plastids; envelopes had normal features but no internal membrane was detected. Pollen embryo-derived plantlets had a green-to-albino ratio (G/A) being equal to 1.0, whereas calli-derived embryos only formed albino plantlets. The second condition was characterized by mannitol pretreatment and the presence of both maltose and mannitol in the induction medium. No callus was formed but most of microspore-derived structures developed haploid embryos and then the green plantlets (200 plantlets per 100 responding anthers, G/A=9.4). In this case, plastid development in zygotic and pollen embryos were similar and almost no albino plantlets were formed.     

Temperature and genotype affect asparagus somatic embryogenesis

Summary Calluses from five asparagus genotypes G14, G32, G171, G203, and G447 and hybrid Jersey Giant (JG) were incubated at three temperature regimes (24, 27, and 30°C) on embryo induction medium to assess somatic embryo development and conversion to plantlets. The calluses from three genotypes (G14, G32, and G171) were not responsive, failing to produce somatic embryos at any temperature regime. For three responsive genotypes (G203, G447, and JG), both incubation temperature and genotype significantly affected the numbers of somatic embryos produced. The calluses produced the most and the least numbers of total, bipolar, and globular embryos when incubated at 27°C and 24°C, respectively. When incubated at 27°C, G203 produced the highest numbers of total and globular embryos, 178 g⁻¹ callus and 142 g⁻¹ callus, respectively while G447 produced the highest number of bipolar embryos, 77 g⁻¹ callus. Incubation temperature but not genotype significantly affected the conversion of somatic embryos to plantlets. The somatic embryos recovered from the three responsive genotypes incubated at 27°C also converted to plantlets at the highest frequencies, 60–63% of the bipolar embryos and 42–43% of the globular embryos converted to plantlets, while the somatic embryos recovered from the calluses incubated at 24°C converted to plantlets at the lowest frequencies.     

Endosperm responses to irradiated pollen in apples

Summary The cytological effects of pollen -irradiation at 50 and 100 krad on both embryo and endosperm development were studied in Malus × domestica. Fruit and seed set were reduced by increasing doses of pollen irradiation, while embryo sacs resulting from the treatments differed in number and morphology of endosperm nuclei and in the presence or absence of an embryo. Nuclear abnormalities, distinguished from normal nuclear behaviour in embryo sacs derived from unirradiated pollen, included enhanced numbers of polyploid restitution nuclei, bridges between nuclei, excluded metaphase chromosome fragments and disrupted mitotic synchrony. Generally, a high dose of pollen irradiation (100 krad) generated an all-or-nothing response in the embryo sac, either creating highly abnormal embryos and/or endosperms which aborted, or showing relatively normal development. Callus produced from excised cellular endosperm differed in average genome size, that derived from 100 krad pollen being smaller than that from unirradiated pollen.     

Plantlet regeneration from a NaCl-selected salt-tolerant callus culture of Shamouti orange (Citrus sinensis L. Osbeck)

Plantlets were regenerated from a selected salt-tolerant cell line of Shamouti orange (Citrus sinensis L. Osbeck). Embryogenesis was carried out both in the presence and absence of NaCl, yielding green and white globular embryos, respectively. Greening could be induced subsequently and normal heart shape embryo development was obtained. Plantlet formation required exposure to kinetin prior to the introduction of the root-inducing hormone naphthalene acetic acid. This system differs from the designed protocol for plant regeneration from the salt-sensitive, i.e., unselected callus. It is concluded that NaCl interferes with the regeneration process, with embryogenesis and/or embryo development into plantlets. Its presence during callus growth probably changes the balance of the phytohormones which is later manifested in plant regeneration. Citrus salt-tolerant callus yields salt-tolerant embryos. Salt-tolerant calli derived from regenerated plantlets indicate acquisition of salt tolerance on the whole plant level.     

The embryogenic competency and morphological changes during somatic embryogenesis in Iris pseudacorus

Embryogenic callus was obtained from bulb segments of Iris pseudacorus on Murashige and Skoog (MS) medium with 2,4-dichlorophenoxyacetic acid (2,4-D) alone or in combination with kinetin. When early globular somatic embryos were subcultured onto MS medium with 4.52 μM 2,4-D, high frequency of somatic embryogenesis was obtained. Deprivation of 2,4-D was required for maturation. Mature somatic embryos had an elongated scutellum with a notch on the base of scutellum. Separation of embryos from embryo clusters was necessary to enhance the frequency of germination. Germination was stimulated by separation of embryos from embryo clusters and transfer onto fresh half-strength MS medium with 3% sucrose. After acclimation in artificial soil in greenhouse for 2 months, 96.4% of plantlets survived.     

ZEA MAYS EMBRYO SACS IN CULTURE. I. PLANT REGENERATION FROM 1 DAY AFTER POLLINATION EMBRYOS

One day after pollination, embryo sacs of Zea mays, containing zygotes and a few endosperm nuclei, were partially isolated and grown in culture. The zygotes underwent normal embryo development, and 40% germinated on a modified Murashige and Skoog medium with 0.1 mg/liter 6-benzylaminopurine. After the appearance of a root and a shoot, individual plantlets were transferred to soil and grown to sexual maturity. The techniques for partial mechanical isolation and successful growth to maturity of such young embryos provide the tools necessary for the recovery of plants from in vitro-fertilìzed embryo sacs.     

In Vitro Embryogenesis in Unfertilized Embryo Sacs of Oryza sativa L.

Haploid rice plantlets were induced from cultured ovaries in our previously reported experiment. The present paper is an embryological study on this subject. Young flowers of two japonica cultivars were excised and cultured just in the same manner as before. Liquid medium used for float culture was N6+3% sucrose+0.125 ppm MCPA. The inoculated materials were checked to be at late uninuclcate pollen stage which corresponded mainly to the uuinuelcate embryo sac stage, but as well as some 2- or 4-nucleate embryo sacs. Samples were fixed at 23 days intervals in acetomethanol (1:3), stained in toto with diluted Ehrlich's hematoxylin and sectioned by paraffin method for microscopical observation. 4 days after inoculation most of the embryo sacs developed up to 8-nucleate stage with polarized differentiation of the egg apparatus, central cell and antipodals. From 7th day on, proembryos of various sizes and shapes appeared in the micropylar region of some embryo sacs; some consisted of meristcmatic ceils, others were highly vacuo]ated. One-celled as well as linear multicellular suspensors atypical of in vivo zygote proembryos were observed, ttowever, it was uncertain whether the proembryos originated from the egg cell, the synergids, or the differentiating egg apparatus as a whole. Another peculiar event occured during culture was the formation of endosperm-like free nuclei from the unfertilized polar nuclei in some embryo sacs. Sometimes the free nuclei were numerous and showed a tendency of cell formation in localized areas. 12–15 days after inoculation, the proembryos developed into mieroseopieal ealli with globular or pearlike shape, wbieh continued enlarging to visible size with naked eyes at about 18–24 th day. Further growth eventually led the ealli protruding out the ovary wall beyond 32–35 the day. These observations indicate that the embryo sue, similarly as the pollen, can be induced to embryogenesis in vitro. This may open a new way to study the mechanism controlling gametophytie and sporophytie developmental pathways of embryo sac and provide means for large-scale production of "embryo sac plants" in future.     

Fertilization in maize indeterminate gametophyte1 mutant

Summary. Mature embryo sacs of the maize mutant indeterminate gametophyte1 displayed different cellular patterns compared to those of the wild type. About 40% of the ig1 embryo sacs contained three or more synergids and two or more egg cells at the micropylar end. During fertilization in embryo sacs with two synergids, both of them frequently degenerated and were penetrated by two pollen tubes. 75% of the embryo sacs containing three or more synergid cells were penetrated by two or more pollen tubes, although most of them had only one degenerated synergid. Multiple fusions between the sperm cells and eggs frequently occurred in the same embryo sac, which subsequently generated multiple embryos. There were two or more central cells in about 33% of ig1 embryo sacs. The largest central cell was usually adjacent to the egg apparatus and contained two unfused polar nuclei, while those extra central cells located at the chalazal end usually had a single nucleus. Fertilization occurred only between the male gamete and the largest binucleate central cell. The extra central cells eventually degenerated after fertilization.Present address: GI Basic Research Center, Mayo Clinic, Rochester, Minnesota, U.S.A.Correspondence and reprints: State Key Laboratory of Plant Physiology and Biochemistry, College of Biological Science, China Agricultural University, Beijing 100094, Peoples Republic of China.     

Apomixis in plants: structural and functional aspects of diplospory inPoa nemoralis andP. palustris

Summary Data on structural and functional aspects of mitotic diplospory and later stages of apomictic seed formation are reported forPoa palustris andP. nemoralis. In this study, the plant material of two Russian populations ofP. nemoralis andP. palustris were used for transmission electron microscope observations. Seed formation was investigated by phase contrast microscopy in two populations ofP. nemoralis collected in The Netherlands. The processes of transformation of the megasporocytes to the megaspore mother cells of diplosporous embryo sacs, and thereafter to one- and two-nucleate diplosporous embryo sacs (Antennaria type) were characterized by an increase of cell size, structural and functional reorganization of the nucleus, nucleolus, and cytoplasm, and cell isolation as a result of thickening of the cell wall. These were accompanied by an increase in the cell metabolic activity inferred from visual evidence of the activation of nucleus, nucleolus, endoplasmic reticulum, dictyosomes, mitochondria, and from the appearance of a dense population of ribosomes and polysomes. The diplosporous embryo sac of the Antennaria type was characteristic for bothP. nemoralis andP. palustris. No signs of the presence of synaptonemal complexes were observed during the process of diplosporous-embryo-sac megaspore mother cell differentiation and division. About 90–95% of the diploid egg cells of diplosporous embryo sacs were able to produce apomictic embryos. These embryos developed before anthesis. However, many of them degenerated at the globular stage because of lack of endosperm. The ultrastructural events occurring during the process of diplospory of apomictic species, and meiosis and megagametogenesis of sexually reproduced plants are discussed.Abbreviations DMC megaspore mother cell of diplosporous embryo sac - TEM transmission electron microscopy - ER endoplasmic reticulum     

Interspecific hybridization of <Emphasis Type="Italic">Prunus persica</Emphasis> with <Emphasis Type="Italic">P. armeniaca</Emphasis> and <Emphasis Type="Italic">P. salicina</Emphasis> using embryo rescue

Embryo rescue technique was used successfully to produce interspecific hybrids by crossing peach (P. persica) as a female parent with apricot (P. armeniaca) and plum (P. salicica). In those crosses that had ‘Yuhualu’ or ‘Zhonghuashoutao’ as female parents, hybrid embryos aborted from the 7th or 8th week after pollination mainly due to post-pollination incompatibility. An embryo rescue protocol was established to rescue such embryos and recover hybrid plants. Modified half-strength MS medium containing 4 mg l⁻¹ 6-BA and 0.5 mg l⁻¹ IBA produced up to 90% germination in the embryos. Modified MS medium with 1.0 mg l⁻¹ 6-BA and 1.0 mg l⁻¹ IBA gave the highest bud induction and multiplication whereas modified MS medium containing 0.5 mg l⁻¹ IAA and 0.2 mg l⁻¹ NAA gave the best rooting percentage. All the hybrids obtained using this embryo rescue technique were verified using simple sequence repeat (SSR) markers. A series of pollen treatments were carried out to partially overcome pre-pollination incompatibility, and it was found accidentally that pollen treatment with electrostatic field not only improved pollen germination but also increased the multiplication coefficient of embryo-induced shoots.     

The progamic phase, embryo and endosperm development in an intraspecific Tulipa gesneriana L. cross and in the incongruent interspecific cross T. gesneriana × T. agenensis DC.

 The development of the embryo and endosperm has been investigated in an intraspecific Tulipa gesneriana cross and in the incongruent cross T. gesneriana ×T. agenensis at intervals of 10 days, from 12 to 82 days after pollination (DAP). In both tulip crosses, the zygote gives rise to an apparently undifferentiated cell mass, the proembryonal cell mass, on which a suspensor then develops. Subsequently, a globular embryo is formed on top of the suspensor. This embryo finally elongates, giving rise to a spindle-shaped embryo. The cellular endosperm fills the whole embryo sac in mature seeds, except for a region immediately around the embryo. In both crosses, aberrant developments were found. In the intraspecific T. gesneriana cross, the pollen tubes did not open in a number of ovules. In other ovules, the pollen tubes seemed to have opened, but an embryo or endosperm was not found or only endosperm was observed. In the cross T. gesneriana ×T. agenensis, fewer pollen tubes entered the ovules than in the intraspecific T. gesneriana cross. The ovules with embryo and endosperm formation of the incongruent interspecific cross showed, in general, retarded development in comparison with the intraspecific T. gesneriana cross. The first globular embryos and spindle-shaped embryos were found at the later fixation dates and the relatively lower number of spindle-shaped embryos at 82 DAP had a shorter average length. The number of ovules with deformations in embryo and/or endosperm development was also higher in the cross T. gesneriana × T. agenensis in comparison with the intraspecific T. gesneriana cross. Between 87% and 100% of the ovules with embryo and endosperm development showed normal development in the intraspecific T. gesneriana cross, while in the incongruent interspecific cross, from 22 DAP, between 17% and 56% of the ovules showed normal development. Of those ovules with aberrations in embryo and/or endosperm formation, about 80% had a deformed endosperm, of which more than 50% also contained a deformed embryo. Embryos of the incongruent cross might be saved by the application of embryo rescue techniques. Received: 10 December 1996 / Revision accepted: 23 April 1997