B Chromosome Behavior in Maize Pollen as Determined by a Molecular Probe

The B chromosomes of maize typically undergo nondisjunction during the second microspore division (generative cell division). When the microspore nucleus contains only one B chromosome, two kinds of sperm result, one with two B chromosomes and one with no B chromosomes. The sperm with the B chromosomes preferentially fertilizes the egg cell. Previous studies of these phenomena have been limited to genetic analysis and chromosome spreads. In this study we show that a B chromosome-specific probe can be used with fluorescence in situ hybridization (FISH) analysis to detect the presence, location, and frequency of B chromosomes in intact interphase nuclei within mature pollen of maize. Using genetic line TB-10L18, our results indicate that nondisjunction of the B centromere occurs at an average frequency of 56.6%, based on four plants and 1306 pollen grains analyzed. This is consistent with the results of genetic studies using the same B-A translocation. In addition, our results suggest that B chromosome nondisjunction can occur during the first microspore division. Spatial distribution of the B chromosome-specific probe appears to be largely confined to one tip of the sperm nucleus, and a DNA fragment found outside the pollen nuclei often hybridizes to the B chromosome-specific probe.     

In vitro development of plants from microspores of rice

Summary Rice (Oryza sativa L., 2n=24) anthers containing microspores in the early-uninucleate to first-mitosis stages were induced successfully to develop into plants in vitro through an intermediary step of callus formation. Callus initiation occurred with highest frequency in anthers containing mid-uninucleate microspores. The callus derived from different stages of microspore development differed in the potential to differentiate into plants. The plants regenerated from pollen callus were predominantly haploid or diploid; polyploid and aneuploid plants were relatively infrequent. The first division of the uninucleate microspores was asymmetrical, resulting in the formation of large vegetative and small generative nuclei. The vegetative nucleus divided repeatedly and assumed the major role in the formation of callus, whereas the generative nucleus degenerated rapidly. Simultaneous division of the two nuclei was observed in a few pollen grains. Nuclear fusion during the very initial stages of pollen development was postulated to account for the occurrence of the diploid and polyploid plants. This work was supported by the National Science Council, Republic of China.     

An original mutation in soybean (Glycine max (L.) Merrill) involving degeneration of the generative cell and causing male sterility.

A spontaneous mutation causing male sterility has been detected in line BR97-17739 from the soybean breeding program conducted by Embrapa-National Soybean Research Center. Meiotic division and male gametophyte development were analyzed in 10 male-sterile, female-fertile plants. Meiotic process had few irregularities related to chromosome segregation and affected about 2% of tetrads. Despite the high frequency of normal microspores, pollen sterility was total. After callose dissolution, microspores were released into the anther loculle and interphase nucleus was displaced from the center to one side of the cell. Displacement continued throughout normal microspore mitosis (PMI). After telophase, the hemispherical phragmoplast marked the place of cytokinesis. A typical generative cell, adjacent to the plasma membrane, and the vegetative one, containing most of the cytoplasm, were formed. In spite of the well-formed generative cell, pollen mitosis (PMII) failed to occur. The generative cell degenerated and was completely destroyed. The 3:1 segregation for male sterility in this line and its progenies indicate that a single recessive gene controls mutation.     

Developmental staging of maize microspores reveals a transition in developing microspore proteins

A method for the preparation of developmentally staged microspores and young pollen from maize (Zea mays) has been devised. The preparations are of sufficient purity and quantity for biochemical analysis, including the analysis of steady-state protein and RNA populations associated with each stage. A major transition in protein populations occurs during the developmental period that encompasses microspore mitosis, the asymmetric nuclear division producing the vegetative and generative nuclei. Several differences between early and late stage proteins can be detected by one-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Two-dimensional gel electrophoresis of proteins reveals that over half of the steady-state proteins differ between the younger and older stages, either quantitative or qualitative. One protein that increases in relative abundance about fourfold is actin. In vitro translation of RNA isolated from staged microspores demonstrates changes in microspore gene expression during the same developmental period.     

Morphological events in cultures of mechanically isolated maize mcirospores

Summary In tis androgenic response, maize is considered to be a recalcitrant plant. We used mechanically isolated microspores of maize genotype A18 to establish a responsive microspore culture of maize. Morphological events occurring during the first days of maize androgenesis in a microspore culture were observed and described, and some morphological markers for distinguishing between embryogenic microspores and nonembryogenic microspores were identified. It was found that the enlargement of microspores during the first days in culture and the ‘star-like’ organization of the cytoplasm inside the microspore are connected with reprogramming of the developmental pathway in maize microspores. Some differences were also found in the surface wall architecture of embryogenic microspores. Fertile plants were successfully recovered from microspore-originated structures.     

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     

Unequal cell division and chromatin diffrentiation in pollen grain cells

The dynamics of the microtubule (MT) were studied by α-tubulin immunofluorescence methods during the polleng rain ontogeny inTradescantia paludosa. Before the microspore division, interphase nuclei of themicrospore cells were twice displaced from the center to one side (NM-1) and from the side to the center near the inner wall (NM-2). During NM-1, a few MTs appeared around the nucleus, but the movement was not interrupted by colchicine treatment. In NM-2, however, which was essential to the unequal division of microspores, many MTs and MT bundles became organized and shifted in a manner corresponding to the nuclear movement. This movement was inhibited by the colchicine treatment. It was concluded that NM-2 was dependent on the MT cytoskeleton, but NM-1 was independent. Througthout the microspore division, mitotic spindles were organized asymmetrically. From prophase to prometaphase, the spindle began to construct itself in the vegetative pole preceding the generative pole. The half-spindles were asymmetric at the metaphase and the phragmoplast developed curving toward the generative pole at the telophase. No pre-prophase band of MTs was observed throughout the cell cycle. The relationship between the characteristic MT dynamics and the nuclear movement, or unequal cell division, was revealed and is discussed here.     

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.     

Absence of microspore polarity, symmetric divisions and pollen cell fate in Brachiaria decumbens (Gramineae).

Meiotic division and male gametophyte development were analyzed in one tetraploid (2n = 4x = 36) accession of Brachiaria decumbens cv. Basilisk that showed some pollen sterility. Meiotic process was typical of polyploids in that it consisted of multiple chromosome associations. Precocious chromosome migration to the poles, laggards, and micronucleus formation were abundant in both meiosis I and II and resulted in tetrads with micronuclei. After callose dissolution, microspores were released into the anther locule and had the semblance of being normal. Although each microspore initiated its differentiation by pollen mitosis, in 43.24% of the microspores, nuclear polarization was not observed and the typical hemispherical cell plate was not detected. Division was symmetric and microspores lacked differentiation between the vegetative and the generative cell. Both nuclei were of equal size, presented equal chromatin condensation, and had a spherical shape. After the first pollen mitosis and cytokinesis, each cell underwent a new symmetric mitosis without nuclear polarization. At the end of the second pollen mitosis, four equal nuclei were observed in each pollen grain. After the second cytokinesis, the cells gave rise to four equal-sized pollen grains with a similar tetrad configuration that initially remained together. Sterile pollen grains resulted from abnormal pollen mitosis. This anomaly may be explained by a mutation, probably affecting microtubule cytoskeleton formation. The importance of this male-sterile mutation for Brachiaria breeding programs is discussed.     

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     

Genesis of microspore-derived triploid petunias

Summary A total of 61 microspore-derived plants of Petunia parodii were grown to maturity revealing a predominent population of triploids, 80.3%. Cytological investigations, together with the evidence from microfluorimetry, suggest that the origin of these triploids was due to the fusion of interphase nuclei in two different pathways. In the majority of embryogenic microspores, a vegetative nucleus of 1C DNA content fused with an endo-reduplicated 2C DNA generative nucleus at the binucleate stage and produced true triploid embryoids and plantlets (A pathway). Where this fusion failed, both the vegetative and the generative nuclei divided separately and in the multinucleate microspore two or more daughter nuclei fused to form a mixoploid embryoid. Such mixoploid embryoids produced a mixed population of plants with various ploidy levels as well as ploidy polymorphism within an individual. Since the triploids are morphologically superior with a faster growth rate than their diploids and related tetraploids, a predominent population of triploid plants was obtained from such mixoploid embryoids (B pathway). By low temperature treatment of the anther-donor buds, the embryogenic response of microspores was enhanced up to 5-fold.     

Manipulation of division symmetry and developmental fate in cultures of potato microspores

The effect of media composition on microspore culture was investigated in one tetraploid and two diploid potatoes. The viability of microspores isolated from 4.5 to 5 mm buds was in the range of 33 to 52%. In media for anther culture, microspores showed no further development and lost viability within 2 days. In M1 medium containing mineral components, sucrose, uridine, cytidine, myo-inositol, glutamine and lactalbumin hydrolysate, 18 to 37% of microspores underwent mitosis within 14 days. Up to 95% of the divisions were symmetric and produced equal nuclei. Some symmetrically divided microspores eventually produced structures with 3 to 10 nuclei. The proportion of the total microspore population producing multinuclear structures reached 9% in diploid clones responsive to anther culture and 1 to 2% in recalcitrant cv. Borka. Symmetric mitoses in M1 medium were induced in the presence of glutamine and lactalbumin hydrolysate. Nucleosides and myo-inositol had no effect on microspore division. In the absence of all organic components except sucrose, most mitoses were asymmetric, formation of multinuclear structures was reduced and most pollen accumulated starch indicative of gametophytic fate. In complete M1 medium, starch accumulation was suppressed. Suppression also occurred in asymmetrically divided microspores, indicating a direct inhibition of pollen development independent of the mode of microspore division. This inhibitory effect of M1 medium might present a stress which triggers the induction of symmetric microspore division and subsequent formation of multinuclear structures. This revised version was published online in June 2006 with corrections to the Cover Date.     

Chromosome instabilities and programmed cell death in tapetal cells of maize with B chromosomes and effects on pollen viability

B chromosomes (B's), knobbed chromosomes, and chromosome 6 (NOR) of maize undergo nondisjunction and micronucleus formation in binucleate tapetal cells. These chromosome instabilities are regular events in the program of tapetal cell death, but the B's strongly increase A chromosome instability. We studied 1B and 0B plants belonging to selected lines for high or low B transmission rate and their F1 hybrids. These lines are characterized by meiotic conservation or loss of B chromosomes, respectively. The female B transmission (fBtl) allele(s) for low B transmission is dominant, inducing micronucleus formation and B nondisjunction. We hypothesize that the fBtl allele(s) induces knob instability. This instability would be sufficient to produce B loss in both meiocytes and binucleate tapetal cells. B instability could, in turn, produce instabilities in all chromosomes of maize complement. To establish whether the chromosomal instabilities are related to the tapetal programmed cell death (PCD) process, we applied the TUNEL technique. PCD, estimated as the frequency of binucleate tapetal cells with TUNEL label, was significantly correlated with the formation of micronuclei and the frequency of pollen abortion. It can be concluded that the observed chromosome instabilities are important to the PCD process and to the development of microspores to form viable pollen grains.     

Identification of potentially embryogenic microspores in Brassica napus

Studies were undertaken with Brassica napus L. cv. Topas to identify buds containing microspores predisposed to embryogenesis in vitro and to investigate bud and microspore development in relation to this process. No significant correlation was found between the final embryo number and bud components. There appears to be a developmental window of less than 8 h duration during which microspores are very likely to form embryos: over 70% of the microspores can undergo division and up to 70% of these can form embryos. Embryos were mainly obtained from late uninuucleate to early binucleate microspores: the former contained mainly a G2 or M phase nucleus located at the microspore periphery and the latter a generative nucleus (associated with the intine) and a vegetative nucleus. Observations indicated that only the vegetative nucleus contributed to embryo formation. The first embryogenic division occurred between 8 and 16 h for uninucleate- and between 8 and 48 h for binucleate-derived embryos.     

Nuclear fusion in cultured microspores of barley

Fusion of the generative and vegetative nuclei physically separated by a wall has been observed in cultured microspores of barley. The generative cell appears to play an active role in fusion as it elongates toward the vegetative nucleus, becomes detached from the microspore wall, and finally completely encloses the vegetative nucleus. The generative cell wall disappears before nuclear fusion takes place. Since these events have been known to occur during pollen development in vivo, it is hypothesized that the occurrence of nuclear fusion in cultured microspores is the result of continued expression of the genes for gametophytic development.     

Lithium treatment of Nicotiana tabacum microspores blocks polar nuclear migration,disrupts the partitioning of membrane-associated Ca2+, and induces symmetrical mitosis

We have found that the normal developmental pathway of Nicotiana tabacum microspores is blocked or switched when microspores are exposed to lithium, and these effects are reversible with Ca²⁺ and myo-inositol. Normal development was defined by the following characteristics: changes in microspore shape from spherical to oval and then ellipsoid; two nuclear displacements, first from a central location to the cell periphery, and then from the periphery to the generative pole; a localization of membrane-associated Ca²⁺ at the generative pole preceding nuclear division; and, finally, an asymmetrical mitosis that results in a two-celled pollen grain with well-differentiated generative and vegetative nuclei. Lithium treatment blocked the localization of membrane-associated Ca²⁺ at the generative pole, and instead it was evenly distributed at both poles. Lithium treatment also blocked the asymmetrical positioning of the microspore nucleus at the generative pole and resulted in an approximately four-fold increase in the frequency of symmetrical mitosis. When Ca²⁺ and myo-inositol were added along with lithium, the effects were substantially decreased, and there was only a small increase in the frequency of symmetrical mitosis compared with controls. The timing of treatment was important; microspores isolated before the first nuclear displacement had a low frequency of further development, while microspores isolated immediately preceding the onset of mitosis were much less sensitive to lithium, and the result was only a small increase in the frequency of symmetrical mitosis. In microspores isolated after the first nuclear displacement, a 1-day exposure to lithium was sufficient to switch the developmental pathway from an asymmetrical to a symmetrical mitosis while still allowing limited further development. However, we have not optimized culturing conditions for embryogenesis and the furthest development observed after a 1-week culture was to four- or five-celled proembryo-like structures.     

Electroporation and PEG delivery of DNA into maize microspores

Summary The ability to deliver and detect reporter gene activity in maize microspores was tested. Tested expression vectors contained the chloramphenicol acetyl transferase (CAT) gene and one of the following promoter-intron combinations: 1) cauliflower mosaic virus (CaMV 35S), 2) CaMV 35S + maize alcohol dehydrogenase 1 intron 6 (Adh1-I6), 3) maize alcohol dehydrogenase 1 + intron 1 (Adh1-I1), or 4) maize ubiquitin 1 + intron 1 (Ubiq 1-I1) promoter + intron. The expression vectors were delivered into maize microspores using electroporation or polyethylene glycol (PEG). Both methods were effective for delivering free DNA into microspores. Although all four promoters were active in maize protoplasts, only two promoters were active in maize microspores. The CaMV 35S and the Adh1 promoters did not promote gene expression in maize microspore. The CaMV 35S + Adh1-I6 and Ubiq1-I1 promoters produced high levels of CAT activity in maize microspores.     

The mitotic apparatus during unequal microspore division observed by a confocal laser scanning microscope

Summary The structure of the mitotic apparatus during the microspore division ofTradescantia paludosa, which has a distinctively unequal division of large vegetative and small generative cells, was studied using -tubulin immunofluorescence methods and confocal laser scanning microscopy. Mitotic apparatuses began to develop asynchronously during early prophase at the vegetative pole (VP) and during prometaphase at the generative pole (GP). Both, however, reached completion together at the same time during metaphase. At the VP from prophase to prometaphase, microtubules (MTs) did not converge on the pole, and there was a circular area containing only a few MTs. The prophase spindles on the VP side were in the form of domes or cones that lacked the top. In the metaphase, however, the MTs concentrated at the pole to form a representative cone-shaped half-spindle. At the GP from prometaphase to metaphase, the MTs did not concentrate, and a circular area existed that lacked MTs. The half-spindles formed truncated cones. When the phragmoplast developed and curved around the generative nucleus during the telophase. it first grew toward the long axis of the ellipsoidal-shaped microspore; and after it arrived at the inner membrane of the microspore, it again curved past the generative nucleus toward the short axis. In conclusion, it was found that the mitotic apparatus ofT. paludosa microspores with its asynchronous growth and asymmetrical spindle structure and with its three dimensional growth of phragmoplasts had a peculiar developmental manner related to unequal division.     

Electron Microscope Observation of Microspore Division of Wheat in Vitro

First mitosis of wheat microspores in anther culture was studied by electron microscope. The division types of the most pollen grains were unequal (A pathway) and that of others were equal (B pathway). The characteristics of unequal division of microspores in vitro in contrast with in Vivo were as follows: (1) Phragmoplast and “phragmoplast-pla- smalemma complex” were of occurrence after nucleus division but new cell wall could not form between two daughter nuclei. (2) Generative cells were various in size, shape and amount of cytoplasmic organelles. (3) Generative cell could attach to intine at all times and underwent sporophyte division there. "Phragmoplast-plasmalemma complex" surrounding generative cell did not disappear even after generative cell detached from the intine, so that there was always an obvious demarcation line between derivative nuclei of generative and vegetative nucleus.