Structural changes during the first divisions of embryos resulting from anther and free microspore culture inBrassica napus

Summary Ultrastructural and cytochemical features of embryo development during anther and free microspore culture inBrassica napus have been followed from the late uninucleate microspore stage through the first embryonic division. On transfer to culture, the microspore cytoplasm possesses a large vacuole, often containing electron opaque aggregates, and a peripheral nucleus. Mitochondria, endoplasmic reticulum and starch-free plastids are distributed throughout the cytoplasm. The conditions of culture induce a number of major changes in the cytoplasmic organisation of the microspore. First, the central vacuole becomes fragmented allowing the nucleus to assume a central position within the cell. Secondly, starch synthesis commences in the plastids which, in turn, are seen to occupy a domain investing the nucleus. Thirdly, the cell develops a thick fibrillar wall, situated immediately adjacent to the intine of the immature pollen wall. Finally, the microspores develop large cytoplasmic aggregates of globular material. The nature of this substance remains unknown, but it remains present until the young embryos have reached the 30 cell stage. The first division of cultured microspores destined to become embryos is generally symmetrical, in contrast to the asymmetric division seen in normal development in vivo. Consideration is given to the differences observed between embryos developing from anthers and free microspores in culture.     

A high throughput <Emphasis Type="Italic">Brassica napus</Emphasis> microspore culture system: influence of percoll gradient separation and bud selection on embryogenesis

Microspore culture for the purpose of developing doubled haploid plants is routine for numerous plant species; however, the embryo yield is still very low compared with the total available microspore population. The ability to select and isolate highly embryogenic microspores would be desirable for high embryo yield in microspore culture. To maximize the efficiency of canola microspore culture, a combination of bud size selection and microspore fractionation using a Percoll gradient was followed. This approach has consistently given high embryo yields and uniform embryo development. Microspores isolated from buds 1.5 to 4.4 mm in length of Brassica napus genotypes Topas 4079, DH12075, Westar and 0025 formed embryos at different frequencies. The most embryogenic bud size range varied with each cultivar: Topas 4079 3.5–3.9 mm, DH12075 2.0–2.4 mm, and Westar and 0025 2.5–2.9 mm. When the microspores from 2.0 to 2.4 mm buds of DH12075 were carefully layered on top of a discontinuous Percoll gradient of 10, 20 and 40%, and subsequently spun through the Percoll layers by centrifugation, bands were formed containing populations of microspores of uniform developmental stage. The middle layer of the gradient contained the late uninucleate and early binucleate microspores that were the most embryogenic. In addition, the relationship between the bud size, developmental stage of isolated microspores, Percoll gradient concentration and the embryogenic frequency of each cultivar were studied. Optimization of these factors is required for each genotype evaluated.     

Colchicine, an efficient genome-doubling agent for maize (Zea mays L.) microspores cultured in anthero

The construction of maize genotypes with high haploid induction capacity made it possible to study the effect of colchicine on maize androgenesis in vitro. Anther cultures of three hybrids were treated with 0.02% and 0.03% colchicine for 3 days at the beginning of microspore induction. Colchicine added to the induction medium had no negative influence on the androgenic responses (anther induction, induction of structures of microspore origin and their regeneration ability) of the genotypes examined. However, significantly higher fertility was observed in plants originating from colchicine-treated microspores, especially at 0.03%. Cytological examinations showed that colchicine treatment before the first microspore division efficiently arrested mitosis and resulted in homozygous doubled-haploid microspores. Under the experimental conditions, the antimitotic drug had no later effect on the division symmetry of the microspore nucleus, and unequal divisions remained dominant. Callus formation from the induced microspores seemed to be more typical (ranging between 60–70%), but embryo frequency was increased by approximately 10%, especially at the higher colchicine concentration. These results suggest that the mechanism of colchicine action in premitotic maize microspores may differ from that previously observed in wheat. Received: 15 June 1998 / Revision received: 17 September 1998 / Accepted: 3 December 1998     

Isolated microspore culture of chickpea (<Emphasis Type="Italic">Cicer arietinum</Emphasis> L.): induction of androgenesis and cytological analysis of early haploid divisions

Routine production of haploid plants has not been reported for any legume, despite the major role these species play in sustainable farming systems and human nutrition. It is within this context that we report a protocol for the induction of haploid development in chickpea (Cicer arietinum L.) using isolated microspore culture. The cultivars “Rupali”, “Narayen”, and “Kimberley Large” were identified as responsive to isolated microspore culture. Flower bud length and microspore developmental stage were correlated for these cultivars. Depending on the cultivar, buds 2.85–3.5 mm in length contained uninucleate microspores. Microspores from donor plants grown in winter and spring were more responsive than those grown in summer. A cold treatment (4°C) of between 24 and 48 h enhanced microspore response in winter- and spring-grown material but was not effective in summer-grown material. A medium developed by the authors was effective for microspore induction and early-stage embryo development. The addition of hormones to this medium was promotive of microspore induction in winter- and spring-grown material, but not in summer-grown material. The initial haploid division predominantly occurred via symmetrical division of the vegetative nucleus. Further research is under way to convert pro-embryos into plants.     

Tracking individual wheat microspores in vitro: identification of embryogenic microspores and body axis formation in the embryo

 The development of isolated, defined wheat microspores undergoing in vitro embryogenesis has been followed by cell tracking. Isolated wheat (Triticum aestivum L.). microspores were immobilized in Sea Plaque agarose supported by a polypropylene mesh at a low cell density and cultured in a hormone-free, maltose-containing medium in the presence of ovaries serving as a conditioning factor. Embryogenesis was followed in microspores isolated from immature anthers of freshly cut tillers or from heat- and starvation-treated, excised anthers. Three types of microspore were identified on the basis of their cytological features at the start of culture. Type-1 microspores had a big central vacuole and a nucleus close to the microspore wall, usually opposite to the germ pore. This type was identical to the late microspore stage in anthers developing in vivo. Microspores with a fragmented vacuole and a peripheral cytoplasmic pocket containing the nucleus were defined as type 2. In type-3 microspores the nucleus was positioned in a cytoplasmic pocket in the centre of the microspore. Tracking revealed that, irrespective of origin, type-1 microspores first developed into type 2 and then into type-3 microspores. After a few more days, type-3 microspores absorbed their vacuoles and differentiated into cytoplasm-rich and starch-accumulating cells, which then divided to form multicellular structures. Apparently the three types of microspore represent stages in a continuous process and not, as previously assumed, distinct classes of responding and non-responding microspores. The first cell division of the embryogenic microspores was always symmetric. Cell tracking also revealed that the original microspore wall opened opposite to a region in the multicellular microspore which consisted of cells containing starch grains while the remaining cells were starch grain-free. The starch-containing cells were located close to the germ pore of the microspore. In more advanced embryos the broken microspore wall was detected at the root pole of the embryo. Received: 27 December 1999 / Accepted: 11 May 2000     

Activated charcoal induced high frequency microspore embryogenesis and efficient doubled haploid production in Brassica juncea

Three Indian Brassica juncea cultivars were studied for embryogenic response of microspores, microspore embryo regeneration, ploidy assessment of microspore-derived plants and their diploidization. Genotype dependence for microspore totipotency was observed and a significant effect of genotype by bud size selection was established. The addition of activated charcoal in NLN medium containing 13% (w/v) sucrose and 10 μM silver nitrate resulted in a fourfold increase in microspore embryogenesis, ranging from 100 to 405 embryos per Petri dish corresponding to 2,700–10,935 embryos per 100 buds. Conversion/germination of embryos produced in presence or absence of activated charcoal was similar but air-drying of microspore embryos was essential. Incubation of microspore embryos at 4 ± 1°C for 10 days in dark resulted in 82.3% conversion. The majority of plants produced from these embryos was haploid. Treating microspore-derived plants at the 3–4 leaf growth stage with 0.34% colchicine for 2–3 h resulted in greatest survival (70%) and chromosome doubling (75%) frequencies. Doubled haploid plants were self-pollinated and grown to maturity under field conditions.     

Microspore development inBrassica napus and the effect of high temperature on division in vivo and in vitro

Summary Brassica napus cv. Topas microspores isolated and cultured near the first pollen mitosis and subjected to a heat treatment develop into haploid embryos at a frequency of about 20%. In order to obtain a greater understanding of the induction process and embryogenesis, transmission electron microscopy was used to study the development of pollen from the mid-uninucleate to the bicellular microspore stage. The effect of 24 h of high temperature (32.5 °C) on microspore development was examined by heat treating microspore cultures or entire plants. Mid-uninucleate microspores contained small vacuoles. Late-uninucleate vacuolate microspores contained a large vacuole. The large vacuole of the vacuolate stage was fragmented into numerous small vacuoles in the late-uninucleate stage. The late-uninucleate stage contained an increased number of ribosomes, a pollen coat covering the exine and a laterally positioned nucleus. Prior to the first pollen mitosis the nucleus of the lateuninucleate microspore appeared to be appressed to the plasma membrane; numerous perinuclear microtubules were observed. Microspores developing into pollen divided asymmetrically to form a large vegetative cell with amyloplasts and a small generative cell without plastids. The cells were separated by a lens-shaped cell wall which later diminished. At the late-bicellular stage the generative cell was observed within the vegetative cell. Starch and lipid reserves were present in the vegetative cell and the rough endoplasmic reticulum and Golgi were abundant. The microspore isolation procedure removed the pollen coat, but did not redistribute or alter the morphology of the organelles. Microspores cultured at 25 °C for 24 h resembled late-bicellular microspores except more starch and a thicker intine were present. A more equal division of microspores occurred during the 24 h heat treatment (32.5 °C) of the entire plant or of cultures. A planar wall separated the cells of the bicellular microspores. Both daughter cells contained plastids and the nuclei were of similar size. Cultured embryogenie microspores contained electron-dense deposits at the plasma membrane/cell wall interface, vesicle-like structures in the cell walls and organelle-free regions in the cytoplasm. The results are related to embryogenesis and a possible mechanism of induction is discussed.Abbreviations B binucleate - LU late uninucleate - LUV late uninucleate vacuolate - M mitotic - MU mid-uninucleate - RER rough endoplasmic reticulum - TEM transmission electron micrograph     

秋水仙碱对甘蓝型油菜离体小孢子胚胎发生的影响

研究了秋水仙碱不同浓度和处理时间对甘蓝型油菜23个基因型离体小孢子胚胎发生的影响.3个基因型的小孢子被10、50和100mg/L秋水仙碱处理24h或48h,胚产量是2.55～14.75胚/蕾,10～50mg/L处理72h则是0.94～2.43胚/蕾.这表明处理72h对小孢子胚发生有抑制作用.用200、400、500和800mg/L处理2个基因型小孢子16～48h,胚产量为0.6～1.33胚/蕾,未处理对照是6.25和9.36胚/蕾.可见200～800mg/L浓度对胚再生有不同程度的阻碍效应.结果还证明,小孢子对秋水仙碱的反应与其基因型有关.当用10、20、50和100mg/L处理48h时,22B5-6和903-3小孢子的胚产量为37.09～69.47胚/蕾,而F1-29、W592和SF10-12是0.28～1.45胚/蕾,相互之间差异很大.秋水仙碱处理小孢子的目的是使其再生植株的染色体高频率加倍,因此应根据胚产量和染色体加倍率来确定秋水仙碱浓度和处理时间.本试验中,采用10～50mg/L处理48h或者用100mg/L处理24h,约80%基因型的小孢子胚产量在5胚/蕾以上,约70%基因型的再生植株加倍率达60%以上,可有效地用于油菜遗传和育种研究等领域.     

Development of microsporesin vivo andin vitro inBrassica napus L.

Summary Populations of highly homogeneous uninucleate and binucleate microspores ofBrassica napus cv. Topas were obtained by bud selection and percoll fractionation. The development of the uninucleate and the binucleate microspores in culture was compared to thosein vivo using the fluorochrome DAPI to stain DNA. The major developmental pathway of the uninucleate microsporesin vitro resulted in embryo formation. The characteristic of this pathway was that the first division produced two diffusely stained nuclei and subsequent divisions gave rise to a multinucleate embryoid. The second pathway which occurred in a small number of the uninucleate microspores led to callus formation. The majority of the binucleate microsporesin vitro followed the developmental pattern of their counterpartsin vivo and were not embryogenic. The embryogenic binucleate microspores produced embryos through the divisions of the vegetative nucleus.Plant Research Centre Contribution # 1147     

Origin of Multicellular Pollen and Pollen Embryos in Cultured Anthers of Pepper (Capsicum Annuum)

Anthers of Capsicum annuum L. were cultured on Murashige and Skoog (MS) medium containing 0.1 mg l⁻¹ NAA and 0.1 mg l⁻¹ kinetin. Inoculated anthers were subjected to 31 °C and development of microspores in anthers of varying stages was observed cytologically using 4′-6-diamidino-2-phenylindol-2HCl (DAPI). Pepper was characterized by a strong asynchrony of pollen development within a single anther. Percentage of pollen at different stages changed with the culture period, and the proportion of dead pollen increased drastically from day 2 after culture. Microspores that were cultured at the late-uninucleate stage followed one of two developmental pathways. In the more common route, the first sporophytic division was asymmetric and produced what appeared to be a typical bicellular pollen. Embryogenic pollen was formed by repeated divisions of the vegetative nucleus. In the second pathway, which occurred in fewer microspores, the first division was symmetric and both nuclei divided repeatedly to form embryogenic pollen. In early-bicellular pollen, sporophytic pollen was produced through division of the vegetative nucleus. In mid-bicellular pollen, the generative nucleus may undergo division to produce two or more sperm-like nuclei. However, division of the generative nucleus alone to form the embryo was never observed. The anther stage optimal for embryo production contained a large proportion (>75%) of early-binucleate pollen. Associations were found among the percentage of early-binucleate pollen, the frequency of embryogenic multinucleate pollen, and the yield of pollen embryos.     

Nuclear DNA synthesis during the induction of embryogenesis in cultured microspores and pollen of Brassica napus L.

The dynamics of nuclear DNA synthesis were analysed in isolated microspores and pollen of Brassica napus that were induced to form embryos. DNA synthesis was visualized by the immunocytochemical labelling of incorporated Bromodeoxyuridine (BrdU), applied continuously or as a pulse during the first 24 h of culture under embryogenic (32 °C) and non-embryogenic (18 °C) conditions. Total DNA content of the nuclei was determined by microspectrophotometry. At the moment of isolation, microspore nuclei and nuclei of generative cells were at the G1, S or G2 phase. Vegetative nuclei of pollen were always in G1 at the onset of culture. When microspores were cultured at 18 °C, they followed the normal gametophytic development; when cultured at 32 °C, they divided symmetrically and became embryogenic or continued gametophytic development. Because the two nuclei of the symmetrically divided microspores were either both labelled with BrdU or not labelled at all, we concluded that microspores are inducible to form embryos from the G1 until the G2 phase. When bicellular pollen were cultured at 18 °C, they exhibited labelling exclusively in generative nuclei. This is comparable to the gametophytic development that occurs in vivo. Early bicellular pollen cultured at 32 °C, however, also exhibited replication in vegetative nuclei. The majority of vegetative nuclei re-entered the cell cycle after 12 h of culture. Replication in the vegetative cells preceded division of the vegetative cell, a prerequisite for pollen-derived embryogenesis.     

Microspore culture of radish (Raphanus sativus L.): influence of genotype and culture conditions on embryogenesis

A number of factors influencing embryogenesis from isolated microspores of radish (Raphanus sativus) were examined. Of 11 genotypes evaluated, six produced embryos ranging from 8.3 embryos per 10⁵ microspores for Chugoku-ao to 0.2 for Tenshun, but five genotypes were not responsive. An initial culture period at elevated temperature before incubation at 25°C was essential for induction of microspore embryogenesis. However, the optimum period of the treatment varied among genotypes and/or experiments. Bud size also influenced microspore embryogenesis. Though optimum bud size was different between genotypes, the microspore populations represented in these buds contained uninucleate and binucleate microspores. Selection of embryogenic microspores using percoll density gradient resulted in up to 1.3-fold increase of embryo yield. Though almost all embryos failed to develop directly into plantlets, plants were obtained by multiple subcultures. The regenerated plants had hyperploid chromosome numbers.     

Effects of aluminum on DNA synthesis, cellular polyamines, polyamine biosynthetic enzymes and inorganic ions in cell suspension cultures of a woody plant, Catharanthus roseus

Individual buds of Brassica napus cv. Topas, near the first pollen mitosis, were used for microspore culture. Bud and petal lengths were recorded. Microspores isolated from the individual buds were plated and small samples were fixed for cytology. Following embryo induction and three weeks of culturing, numbers of embryos were scored. Bud and petal lengths did not accurately indicate which buds would supply microspores that would form embryos at high frequencies. Fluorescence microscopy was used to examine nuclei stained with Hoechst 33258 and vacuolar morphology of microspores was revealed by the weaker fluorescence due to glutaraldehyde fixation. Following isolation, nuclear and vacuolar characteristics were used to stage the microspores as miduninucleate, late uninucleate vacuolate, late uninucleate, mitotic, or binucleate. The relationship of developmental stage to the frequency of microspore-derived embryos was evaluated. A classification scheme was developed which uses the relative proportions of microspores at each of the stages to identify microspore isolations that would form embryos at high frequencies. It was found that when 1 to 87% of the isolated microspores were binucleate, 21.4 ± 3.0% of the viable microspores developed into embryos. This was a significant ( P < 0.001) increase over the other 3 classes. The ability to select highly embryogenic microspore isolations is of great advantage for developmental cell biology studies.     

Analysis of Nondisjunction Induced by the R-X1 Deficiency during Microsporogenesis in Zea Mays L

The r-X1 deficiency in maize induces nondisjunction at the second mitotic division during embryo sac formation. However, it was not known if this deficiency also induces nondisjunction during the microspore divisions. Microsporogenesis in plants lacking or containing this deficiency was compared using two approaches. First, chromosome numbers were determined in generative nuclei. Many (8.3%) of the generative nuclei in r-X1-containing plants were aneuploid; however, those from control plants were all haploid. Thus, this deficiency induces nondisjunction during the first microspore division. Second, nucleoli were analyzed in microspores. The only nucleolar organizing region in maize is on chromosome 6. If chromosome 6 underwent nondisjunction during the first microspore division, one nucleus in binucleate microspores would contain no nucleolus and the other would contain two nucleoli (or one nucleolus if the nucleoli fused). Only one (0.03%) microspore of this type was observed in control plants while 1.12% were found in r-X1-containing plants. Thus, the r-X1 deficiency induces nondisjunction of chromosome 6 during the first microspore division. However, both of the sperm nuclei in trinucleate microspores contained one nucleolus in r-X1-containing and control plants; thus, this deficiency does not induce nondisjunction of chromosome 6 (and presumably other chromosomes) during the second microspore division.     

Effect of various exogenous and endogenous factors on microspore embryogenesis in Indian mustard (<Emphasis Type="Italic">Brassica juncea</Emphasis> (L.) Czern and Coss)

Summary The influence of donor plant growth environment, microspore development stage, culture media and incubation conditions on microspore embryogenesis was studied in three Indian B. juncea varieties. The donor plants were grown under varying environments: field conditions, controlled conditions, or a combination of the two. The correlation analysis between the bud size and microspore development stage revealed that the bud size is an accurate marker for donor plants grown under controlled conditions, however, the same does not hold true for the field-grown plants. The buds containing late uninucleate microspores collected from plants grown under normal field conditions up to bolting stage and then transferred to controlled environment were observed to be most responsive with genotypic variability ranging from 10 to 35 embryos per Petri dish, irrespective of the other factors. NLN medium containing 13% sucrose was found to be most suitable for induction of embryogenesis The fortification of this medium with activated charcoal, polyvinylpyrrolidone, colchicine, or growth regulators (6-benzylaminopurine and 1-naphthaleneacetic acid) was observed to be antagonistic for microspore embryogenesis, while silver nitrate (10 μM) had a significant synergistic effect. A post-culture high-temperature incubation of microspores at 32.5±1°C for 10–15 d was found most suitable for high-frequency production of microspore embryos. The highest frequency of microspore embryogenesis (78 embryos per Petri dish) was observed from the late uninucleate microspores (contained in bud sizes 3.1–3.5 nm irrespective of genotype) cultured on NLN medium containing 13% sucrose and silver nitrate (10 μM), and incubated at 32.5°C for 10–15 d.     

Hsp70 and Hsp90 change their expression and subcellular localization after microspore embryogenesis induction in Brassica napus L

A stress treatment of 32 degrees C for at least 8h was able to change the gametophytic program of the microspore, switching it to embryogenesis in Brassica napus, an interesting model for studying this process in vitro. After induction, some microspores started symmetric divisions and became haploid embryos after a few days, whereas other microspores, not sensitive to induction, followed their original gametophytic development. In this work the distribution and ultrastructural localization of two heat-shock proteins (Hsp70 and Hsp90) throughout key stages before and after embryogenesis induction were studied. Both Hsp proteins are rapidly induced, localizing in the nucleus and the cytoplasm. Immunogold labeling showed changes in the distribution patterns of these proteins, these changes being assessed by a quantitative analysis. Inside the nucleus, Hsp70 was found in association with RNP structures in the interchromatin region and in the nucleolus, whereas nuclear Hsp90 was mostly found in the interchromatin region. For Hsp70, the accumulation after the inductive treatment was accompanied by a reversible translocation from the cytoplasm to the nucleus, in both induced (embryogenic) and noninduced (gametophytic) microspores. However, the translocation was higher in embryogenic microspores, suggesting a possible additional role for Hsp70 in the switch to embryogenesis. In contrast, Hsp90 increase was similar in all microspores, occurring faster than for Hsp70 and suggesting a more specific role for Hsp90 in the stress response. Hsp70 and Hsp90 colocalized in clusters in the cytoplasm and the nucleus, but not in the nucleolus. Results indicated that stress proteins are involved in the process of microspore embryogenesis induction. The differential appearance and distribution of the two proteins and their association at specific stages have been determined between the two systems coexisting in the same culture: embryogenic development (induced cells) and development of gametes (noninduced cells).     

Enhanced post-germinative growth of encapsulated somatic embryos of Siberian ginseng by carbohydrate addition to the encapsulation matrix

Based on a protocol for microspore culture in apple (Malus domestica Borkh.), the embryo induction phase has been improved with regard to pretreatment of microspores for initiation of microspore embryogenesis, the concentration of carbon source in the induction medium and the microspore density in the suspension. Furthermore, the effect of the genotype was studied. To determine the efficiency of in vitro androgenesis, both methods, via anther and microspore culture, were investigated using the same bud material. A comparison of the efficiency of embryo induction in anther and microspore cultures showed that microspore culture resulted in an increase up to 10 times, depending on the genotype. The regeneration route in microspore culture is similar to that of androgenic embryos via anther culture and showed adventitious shoot formation in most cases after a long period of secondary embryogenesis.Communicated by H. Lörz     

Effects of pH, MES, arabinogalactan-proteins on microspore cultures in white cabbage

The objective of this study was to improve induction of embryogenesis in white cabbage (Brassica oleracea var. capitata) microspore cultures. The effect of NLN-13 liquid medium pH on isolated microspore embryogenesis was investigated in five white cabbage genotypes. Relatively high pH (6.2 or 6.4) was more effective on microspore embryogenesis in most of the white cabbage genotypes than the pH of 5.8, especially for inducing microspore-derived embryos in recalcitrant genotype ??Zhonggan No. 8??. Based on this, 2??(N-Morpholino) ethanesulfonic acid (MES) and the arabinogalactan-protein from gum arabic were tested on four out of five genotypes to see if they could increase embryo yield in microspore cultures. Adding MES or gum arabic alone was effective for these four genotypes, but the frequency of embryos derived from microspores was still low. However, the combination of 10?mg?l^?1 gum arabic and 3?mM MES in NLN-13 at pH 6.4 significantly enhanced microspore embryogenesis efficiency (with embryo production of 4.57?C222.97 embryos per bud), especially with recalcitrant genotype ??Zhonggan No. 8?? for which it was increased by about 35-fold.     

Effects of High Temperature on the Cultures of Isolated Microspores in Brassica campestris ssp. pekinensis

The influence of high temperature (33℃) on embryogenesis in isolated microspore culture of Chinese cabbage (Brassica campestris spp. pekinensis ) was investigated by microscpopy of FDA and DAPI. The microspores cultured at constant temperature of 25 ℃ lost their viability quickly and only few viable microspores were found after 7 days of culture. The morphology of the cultured microspores became as turgescent as the "rugby" which was similar to the mature pollen of the Chinese cabbage. The first nuclear division of the microspores was asymmetric. The microspores lost their capacity of embryogenesis under such condition. In contrast, when the microspores were cultured at 33℃ for 24 h before they were transfered to the culture condition of 25 ℃, their developmental pattern was changed. Some of the microspores could remain viable even for 7 days in culture, they became rounded off. The symmetric nuclear division pattern was induced. The frequency of such division was about 40%. Of the several new cell division types observed, the symmetric type was more frequent (55%) than others. The microspores treated under 33℃ were able to form embryoids via embryogenesis. The critical period of high temperature treatment on microspore culture of Chinese cabbage was about the initial 12 h, if the cell division index of microspore was concerned, but the period was the initial 24 h if the frequency of embryogenesis was considered.     

Microspore development in cultured maize anthers

The present study follows in vivo and in vitro microspore development utilizing an anther culture-responsive maize genotype (Pa91×FR16) and a DNA-specific fluorescent dye (mithramycin). Cultured anthers were sampled at various times and scored for abnormal microspore divisions, multicellular masses, and embryo-like structures. The frequency of abnormal microspore divisions reached a peak during the first 7 days in culture and then declined. The vegetative nucleus was mitotically active in culture with over 50% of the induced microspores exhibiting this type of division. Multicellular masses and embryo-like structures first appeared in the 14 and 25 day samples, respectively. Most of the microspores did not reach the multicellular stage and an even greater mortality occurred during the formation of embryo-like structures.