Ultrastructural characterization of apospory in Panicum maximum

The nucellar ultrastructure of apomictic Panicum maximum was analyzed during the meiocytic stage and during aposporous embryo sac formation. At pachytene the megameiocyte shows a random cell organelle distribution and sometimes only an incomplete micropylar callose wall. The chalazal nucellar cells are meristematic until the tetrad stage. They can turn into initial cells of aposporous embryo sacs. The aposporous initials can be recognized by their increased cell size, large nucleus, and the presence of many vesicles. The cell wall is thin with few plasmodesmata. If only a sexual embryo sac is formed, the nucellar cells retain their meristematic character. The aposporous initial cell is somewhat comparable to a vacuolated functional megaspore. It shows large vacuoles around the central nucleus and is surrounded by a thick cell wall without plasmodesmata. In the mature aposporous embryo sac the structure of the cells of the egg apparatus is similar to each other. In the chalazal part of the egg apparatus the cell walls are thin and do not hamper the transfer of sperm cells. Structural and functional aspects of nucellar cell differentiation and aposporous and sexual embryo sac development are discussed.     

水蔗草兼性无融合生殖胚胎学研究

对水蔗草 (ApludamuticaL .)的生殖方式进行研究 ,结果表明水蔗草进行兼性无融合生殖。胚囊发育分为两种类型 ,即有性生殖的蓼型和无孢子生殖的大黍型。无融合生殖胚囊频率为 6 0 .74%。在大孢子母细胞发育至四分体后 ,珠孔端的 3个大孢子解体。合点端的大孢子未解体时 ,邻近大孢子的 1个珠心细胞开始特化 ,形成无融合生殖的原始细胞 ,由该原始细胞发育形成有 1个卵细胞、1个助细胞和 2个极核的四核胚囊。     

Nuclear DNA amount during sporogenesis and gametogenesis in sexual and aposporous buffelgrass

Nuclear DNA amounts (C values) were measured in Feulgen-stained sections of anthers and ovules of sexual plant B-2s (genotype aaaa) and aposporous cultivar Higgins (genotype AAaa) of buffelgrass (Pennisetum ciliare). The mass of the unreplicated nuclear genome of a gamete equals 1C DNA. In both lines, pollen mother cell nuclei were 4C before leptotene; anther wall, dyad, 1-nucleate pollen, and generative cell nuclei were 2C; microspore tetrad, enlarging microspore, and sperm nuclei were 1C. The tapetum persisted as uninucleate cells with 4C DNA. Archespores (2-4C) of both lines initiated meiosis to form megaspore tetrad nuclei with 1-2C DNA. In B-2s, chalazal megaspores (2-4C) formed reduced 8-nucleate Polygonum type embryo sacs, and sacs at 2- and 4-nucleate stages showed distributions with peaks near C1 and C2, corresponding to G1 and G2 cell cycle phases; this is characteristic of active mitosis. Nuclei of 8-nucleate sacs and of eggs and polars were 1C, indicating chromosomes were not duplicated before fertilization. Antipodal nuclei had levels from 1 to 36C, possibly due to polyteny or endopolyploidy. In Higgins, aposporous initials and 2-nucleate embryo sacs showed bimodal distributions of 2n nuclei with peaks at 2C and 4C DNA. Nuclei of newly formed 4-nucleate Panicum type aposporous sacs and of polars were 2C; aposporous eggs stained too faintly for reliable measurement.Names of products are included for the benefit of the reader and do not imply endorsement or preferential treatment by USDA     

水蔗草兼性无融合生殖胚胎学研究

对水蔗草(Apluda mutica L.)的生殖方式进行研究,结果表明水蔗草进行兼性无融合生殖.胚囊发育分为两种类型,即有性生殖的蓼型和无孢子生殖的大黍型.无融合生殖胚囊频率为60.74%.在大孢子母细胞发育至四分体后,珠孔端的3个大孢子解体.合点端的大孢子未解体时,邻近大孢子的1个珠心细胞开始特化,形成无融合生殖的原始细胞,由该原始细胞发育形成有1个卵细胞、1个助细胞和2个极核的四核胚囊.     

Genetic and embryological evidences of apomixis at the diploid level in <Emphasis Type="Italic">Paspalum rufum</Emphasis> support recurrent auto-polyploidization in the species

Gametophytic apomixis is an asexual mode of reproduction by seeds. This trait is present in several plant families and is strongly associated with polyploidy. Paspalum rufum is a forage grass with sexual self-incompatible diploids (2n = 2x = 20) and aposporous-apomictic pseudogamous tetraploids (2n = 4x = 40). In previous work embryological observations of the diploid genotype Q3754 showed 8.8–26.8% of the ovaries having one meiotic plus an aposporous-like embryo sac, suggesting some capability for apomictic reproduction. The objective of this work was to characterize progenies derived from Q3754 to determine if aposporous sacs were functional and generated progenies via apomixis at the diploid level. Re-examination of Q3754 ovaries showed that 12.5% of them contained one sexual plus an aposporous sac confirming previous results. Progeny tests were carried out on two experimental families (H₁ and S₁) employing heterozygous RAPD marker loci. Family H₁ was obtained crossing Q3754 with a natural diploid genotype (Q3861) and S₁ derived from the induced self-pollination of Q3754. Genetic analysis of H₁ showed that all individuals derived from sexual reproduction. However, 5 out of 95 plants from S₁ showed the same heterozygous state as the mother plant for 14 RAPD loci suggesting a clonal origin. Further experiments, designed to test the functionality of aposporous sacs by flow cytometric analyses, were carried out on a third family (M₁) obtained by crossing Q3754 with the tetraploid plant Q3785. Histograms of 20 M₁ plants showed 15 diploids (75%), 4 triploids (20%) and 1 tetraploid (5%). Triploids and the tetraploid may have originated from functional aposporous embryo sacs. Likewise, the reconstruction of the developmental route of 40 individual seeds demonstrated that 11 of them (27.5%) derived from fertilized aposporic sacs. The results presented in this work indicate that gametophytic apomixis is effectively expressed at the diploid level in Paspalum rufum and could be the foundation of a recurrent auto-polyploidization process in the species.     

四倍体双穗雀稗兼性无孢子生殖的研究

研究了四倍体双穗雀稗(Paspalum distichum L)无孢子生殖胚囊、胚胎发育以及假受精特点。当其大孢子母细胞发育至四分体阶段时,大多数情况下会发生四分体退化,同时有多个特化珠心细胞发育为1—3个无孢子生殖胚囊的现象。成熟无孢子生殖胚囊一般3核,包括1个卵细胞和2个极核。卵细胞在抽穗前就能自发分裂形成原胚团,而极核则在抽穗和传粉后参与假受精形成胚乳。当胚珠内存在多个无孢子生殖胚囊时,只是靠近珠孔端的1个无孢子生殖胚囊内的极核与精核结合,而其它的并不参与。种子成熟后出现很低频率的二胚苗。此外,还能观察到少量的有性生殖胚囊的发育以及有性生殖胚囊和无孢子生殖胚囊在同一胚珠中的发育现象,因此判断该类群为兼性无孢子生殖体。     

BIOSYSTEMATIC STUDIES IN THE BOUTELOUA CURTIPENDULA COMPLEX. V. MEGASPOROGENESIS AND EMBRYO SAC DEVELOPMENT

Megasporogenesis and embryo sac development in the sexually reproducing taxa Bouteloua warnockii (2n = 22), B. media (2n = 20), B. uniflora Vasey var. uniflora (2n = 20), B. uniflora var. coahuilensis Gould and Kapadia (2n = 20), and B. curtipendula var. curlipendula (2n = 40) all were found to be of the Adoxa type, in which all 4 megaspores persist and divide once to form an 8-nucleate embryo sac. On the other hand, evidence indicated that plants of B. curtipendula var. caespitosa with high ancuploid chromosome numbers reproduce by pseudogamous fertilization of an aposporous embryo sac. In this taxon the megaspore mother cell did not go beyond the first anaphase of meiosis and the functional embryo sac developed from a nucellar cell. Although the 8-nucleate embryo sac was typical, a 3-nucleate embryo sac was observed to develop in some cases.     

Development of polarity in the ovules of the F2-progeny of theOenothera hybridalbicans · hhookeri

In the F₂-progeny of hybrids from crosses betweenOenothera biennis orsuaveolens andOe. hookeri with theRenner-complexesalbicans and^hhookeri, the development of callose pattern in meiocytes and megaspore tetrads is the same as in the F₁ and the parentOe. hookeri. During the development of the megaspore tetrads and the embryo sacs primary and secondary heteropolarity as well as homopolarity is observed. Estimates for the initial frequency of homo- and heteropolar tetrads at the end of the degeneration of megaspores in the tetrads immediately before the start of embryo sac development could be calculated. The F₂-plants can be arranged in three groups, distinguished by the frequency of the two polarity types. One of these groups behaves similar to the parentOe. hookeri, the two others have more homopolar tetrads. The segregation can be interpreted as recombination of genes, which influence the development of the polarity in the ovules. This is possible by crossing-over of genes between the twoRenner-complexes of the hybrid.     

水蔗草胚珠附器的研究

本文对水蔗草的胚珠附器进行研究,结果表明：在功能大孢子时期,珠孔端的1～3个珠心细胞开始特化,发育成胚珠附器;胚珠附器发生时,有些胚珠同时出现无孢子生殖原始细 胞;有性生殖和无孢子生殖的胚囊中均有胚珠附器存在;但在无孢子生殖的胚囊中,胚珠附器一般很大,长约是宽的1～３倍;而有性生殖胚囊的胚珠附器的长约是宽的1～２倍;和有性生殖胚囊相比,无孢子生殖胚囊的胚珠附器更加发达;存在发达的胚珠附器是水蔗草无孢子生殖胚囊的特点之一。     

Embryological Studies on Apomixis in Pennisetum squamulatum

Studies on the formation and development of the embryo sac of the apomictic material of Pennisetum squamulatum Fresen indicated that normal archesporial cell did form with consequent development of a megaspore mother cell and later meiotic division to give rise to a triad. But invariably the megaspore mother cell and the triad underwent degeneration after formation. During the period of formation or degeneration of the megaspore or the triad a number of nucellar cells around the degenerated sexual cell became much enlarged. Frequently, one of the enlarging nucellar cells near the micropylar end became vacuolated and then developed into an aposporous uninucleate embryo sac, which underwent two further mitotic divisions to form an aposporous four-nucleate embryo sac, where the four nuclei remained in the micropylar end. Thus in the mature aposporous embryo sac there were one egg cell, one synergid and one central cell (containing two polar nuclei). Antipodal cells were completely lacking. The pattern of development of the aposporous embryo sac resembles the panicum type. There were two types of embryo formed during apomictic development namely ( 1 ) The pre-genesis embryo--embryo formed without fertilization, 1 to 2 days before anthesis, and (2) The late-genesis embryo--derived from the unfertilized egg cells, 3 to 4 days after anthesis. In the late-genesis embryo type, the egg cell divided after the secondary nucleus has undergone division to form the endosperm nuclei. All egg cells developed vacuoles before they differentiated into embryos. The development of the aposporous embryo followed the sequence of the formation of globular, pearshaped embryo and full stages of differentiation. The unfertilized secondary nucleus divides to form free endosperm nuclei after being stimulated by pollination. The development of the endosperm belongs to the nuclear-type.     

Microtubular configurations during meiosis and megasporogenesis in Gasteria verrucosa and Chamaenerion angustifolium

Summary In Gasteria and Chamaenerion, microtubular configurations were visualized immunocytochemically during meiosis and megasporogenesis in order to study their relationship to cell development, meiotic divisions and selection of the functional megaspore. In Chamaenerion, the intensity of the fluorescence found in megaspores was weaker than that found in Gasteria. Both plants exhibited concentrations of microtubules around the meiocyte nuclei during pachytene-diplotene. Preprophase bands were not observed. In Chamaenerion, cytoplasmic microtubules radiating from meiocyte nuclei were found at late prophase, the dyad stage and in the functional megaspore; in Gasteria, they were observed only at the dyad stage and in the functional megaspore. During the second meiotic division of Gasteria, dividing cells and their nuclei exhibited differences in volumes. Also, the two microtubular spindles of the dyad cells had different widths. Fluorescence indicating the presence of the cytoskeleton diminished during maturation of the large functional megaspores in both plants, whereas in the three degenerating smaller megaspores, fluorescence intensity persisted. Our conclusion is that only an indirect relationship exists between the organization of the microtubular cytoskeleton and selection of the functional megaspore.     

水蔗草胚珠附器的研究

本文对水蔗草的胚珠附器进行研究,结果表明：在功能大孢子时期,珠孔端的1—3个珠心细胞开始特化,发育成胚珠附器;胚珠附器发生时,有些胚珠同时出现无孢子生殖原始细胞;有性生殖和无孢子生殖的胚囊中均有胚珠附器存在;但在无孢子生殖的胚囊中,胚珠附器一般很大,长约是宽的1—3倍;而有性生殖胚囊的胚珠附器的长约是宽的1—2倍;和有性生殖胚囊相比,无孢子生殖胚囊的胚珠附器更加发达;存在发达的胚珠附器是水蔗草无孢子生殖胚囊的特点之一。     

Genetic characterization of apospory in tetraploid Paspalum notatum based on the identification of linked molecular markers

Tetraploid Paspalum notatum (bahiagrass) is a valuable forage grass with aposporous apomictic reproduction. In a previous study, we showed that apospory in bahiagrass is under the control of a single dominant gene with a distorted segregation ratio. The objective of this work was to identify molecular markers linked to apospory in tetraploid P. notatum and establish a preliminary syntenic relationship with the genomic region associated with apospory in P. simplex. A F₁ population of 290 individuals, segregating for apospory, was generated after crossing a completely sexual plant (Q4188) with a natural aposporous apomictic plant (Q4117). The whole progeny was classified as sexual or aposporous by embryo sacs analysis. A bulked segregant analysis was carried out to identify molecular markers co-segregating with apospory. Four hundred RAPD primers, 30 AFLP primers combinations and 85 RFLP clones were screened using DNA from both parental genotypes and aposporous and sexual bulks. Linkage analysis was performed with cytological and genetic information from the complete progeny. Cytoembryological analysis showed 219 sexual and 71 aposporous F₁ individuals. Seven different molecular markers (2 RAPD, 4 AFLP and 1 RFLP) were found to be completely linked to apospory. The RFLP probe C1069, mapping to the telomeric region of the long arm of rice chromosome 12, was one of the molecular markers completely linked to apospory in P. notatum. This marker had been previously associated with apospory in P. simplex. A preliminary map of the chromosome region carrying the apospory locus was constructed.     

An <Emphasis Type="Italic">Hieracium</Emphasis> mutant, <Emphasis Type="Italic">loss of</Emphasis><Emphasis Type="Italic">apomeiosis 1</Emphasis> (<Emphasis Type="Italic">loa1</Emphasis>) is defective in the initiation of apomixis

Asexual seed formation (apomixis) in Hieracium aurantiacum occurs by mitotic embryo sac formation without prior meiosis in ovules (apomeiosis), followed by fertilization-independent embryo and endosperm development. Sexual reproduction begins first in Hieracium ovules with megaspore mother cell (MMC) formation. Apomixis initiates with the enlargement of somatic cells, termed aposporous initial (AI) cells, near sexual cells. AI cells grow towards sexually programmed cells undergoing meiosis, which degrade as the dividing nuclei of AIs obscure and displace them. Following Agrobacterium-mediated transformation of an aneuploid Hieracium aurantiacum apomict, a somaclonal mutant designated “loss of apomeiosis 1” (loa1) was recovered, which had significantly lost the ability to form apomictic seed. Maternal apomictic progeny were rare and low levels of germinable seedlings were primarily derived from meiotically derived eggs. Cytological analysis revealed defects in AI formation and function in loa1. Somatic cells enlarged some distance away from sexual cells and unlike AI cells, these expanded away from sexual cells without nuclear division. Surprisingly, many accumulated callose in the walls, a marker associated with meiotically specified cells. These defective AI (DAI) cells only had partial sexual identity as they failed to express a marker reflecting entry to meiosis that was easily detected in MMCs and they ultimately degraded. DAI cell formation did not lead to a compensatory increase in functional sexual embryo sacs, as collapse of meiotic embryo sacs was prevalent in the aneuploid somaclonal mutant. Positional cues that are important for AI cell differentiation, growth and fate may have been disrupted in the loa1 mutant and this is discussed. The authors Takashi Okada, Andrew S. Catanach and Susan D. Johnson made equal contributions to the data.     

Embryological studies inGlaucidium palmatum Sieb. et Zucc. with a discussion on the taxonomy of the genus

Embryological features ofGlaucidium palmatum are as follows: the ovule is anatropous and bitegmic; the archesporium is hypodermal and multicelled, consisting of about 10 to 15 cells; all the archesporial, cells develop directly into megaspore mother cells, only three or four of which, however, generally complete meiotic divisions; before and during meiosis, dermal cells of the nucellar apical part undergo successive periclinal divisions forming a thick nucellar cap of as many as 20 cell-layers; embryo sac formation is of the Polygonum type; multiple embryo sacs occur frequently; antipodal cells are small in size and ephemeral or persistent; the inner integument is 3 to 5 cell-layers thick, and the outer integument 7 to 13 cell-layers thick; the outer integument is vascularized; a micropyle is formed by the inner integument alone; the endosperm is of the Nuclear type; embryogeny is of a type similar to the Onagrad type. In light of evidence from embryology and other sources it seems that there is ample reason for recognizing the family Glaucidiaceae which is distinct from the Ranunculaceae and its related families. Several common embryological features suggest an affinity between the Glaucidiaceae and the Paeoniaceae.     

Development of Ovules and Embryo sacs in Ostrya virginiana (Betulaceae) and Its Systematic Significance

The development of ovules and embryo sacs in Ostrya virginiana was studied for the first time. Most ovaries had two ovules which were anatropous, unitegmic and crassinucellate. The ovule usually possessed several archesporial ceils which divided periclinally into the upper parietal cell and the lower sporogenous cell. The sporogenous cell functioned directly as megaspore mother cell. The tetrad of megaspores was linear in arrangement, and every megaspore might be functional. One ovule often contained 2- 6 embryo sacs and the embryo sac belongs to Polygonum type. It can be concluded from the present data that all ovules among the genera of the Betulaceae are unitegrnic. There are more groups with the phenomenon of multiple embryo sacs in anemophic plants such as Betulaceae, Casuarinaceae, Graminae, Jnglandaceae, Myricaceae, Simaroubaceae, Ulmaceae, than in entomophilous plants. Multiple embryo sacs also occur among some parasitic plants and saprophytes, e.g. Orobanchaceae, Cassytha in Lauraceae, Cuscuta in Convolvulaceae and Utricularia in Lentibulariaceae. It may be inferred that the characteristic of multiple embryo sacs be an evolutionary adaptation of those plants with lower pollination rate to increase the rate of fertilization. Finally, a comparison of embryological characters among the genera of the Betulaceae shows that the family is of a number of common embryological characters, such as multicellular archesporium, multiple embryo sacs in one ovule, and a long interval between pollination and fertilization. The diversity and systematic significance of several embryological characters among the “higher” hamamelid families are also discussed. It is still hard to explain the phy-logenetic relationships among those families clearly only with.     

Apomixis and sexuality in diploid and tetraploid accessions of Brachiaria decumbens

 Meiotic and aposporous embryo sacs and the initial steps of parthenogenetic embryogenesis and endosperm formation were investigated in diploid and tetraploid accessions of Brachiaria decumbens in two environments, differing mainly in day length: early summer and late autumn. Both diploid and tetraploid accessions were facultative apomicts. Di(ha)ploids showed a much lower level of apomixis (10% to15%) than tetraploids (80% to 95%). No obligate sexual diploids were found; thus, their occurrence in natural populations is obscure. It is suggested that reproduction in B. decumbens, as in other agamic complexes of the Paniceae tribe, in general, approximates a diploid-tetraploid-(di)haploid reproductive cycle which does not involve triploids. The dihaploids were fertile and survived in nature. Development of the reproductive structures depended on the environment. In autumn, in contrast to early summer, many meiotic and aposporous embryo sacs degenerated during development, leading to a significant reduction in the proportion of parthenogenetic embryos. Whether this effect can be attributed to day length or simply to age remains to be investigated. The ratio of aposporous to sexual embryo sacs was relatively stable over the two seasons. Received: 15 April 1998 / Revision accepted: 13 October 1998     

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     

EMBRYOLOGY OF CALYPSO BULBOSA. I. OVULE DEVELOPMENT

Calypso bulbosa is a terrestrial orchid that grows in north temperate regions. Like many orchids, the Calypso has ovules that are not fully developed at anthesis. After pollination, the ovule primordia divide several times to produce a nucellar filament which consists of five to six cells. The subterminal cell of the nucellar filament enlarges to become the archesporial cell. Through further enlargement and elongation, the archesporial cell becomes the megasporocyte. An unequal dyad results from the first meiotic division. A triad of one active chalazal megaspore and two inactive micropylar megaspores are the end products of meiotic division. Callose is present in the cell wall of the megaspore destined to degenerate. In the mature embryo sac the number of nuclei is reduced to six when the chalazal nuclei fail to divide after the first mitotic division. The chalazal nuclei join the polar nucleus and the male nucleus near the center of the embryo sac subsequent to fertilization.     

Dynamics of callose deposition and beta-1,3-glucanase expression during reproductive events in sexual and apomictic Hieracium

Callose accumulates in the walls of cells undergoing megasporogenesis during embryo sac formation in angiosperm ovules. Deficiencies in callose deposition have been observed in apomictic plants and causal linkages between altered callose deposition and apomictic initiation proposed. In apomictic Hieracium, embryo sacs initiate by sexual and apomictic processes within an ovule, but sexual development terminates in successful apomicts. Callose deposition and the events that lead to sexual termination were examined in different Hieracium apomicts that form initials pre- and post-meiosis. In apomictic plants, callose was not detected in initial cell walls and deficiencies in callose deposition were not observed in cells undergoing megasporogenesis. Multiple initial formation pre-meiosis resulted in physical distortion of cells undergoing megasporogenesis, persistence of callose and termination of the sexual pathway. In apomictic plants, callose persistence did not correlate with altered spatial or temporal expression of a β-1,3-glucanase gene (HpGluc) encoding a putative callose-degrading enzyme. Expression analysis indicated HpGluc might function during ovule growth and embryo sac expansion in addition to callose dissolution in sexual and apomictic plants. Initial formation pre-meiosis might therefore limit the access of HpGluc protein to callose substrate while the expansion of aposporous embryo sacs is promoted. Callose deposition and dissolution during megasporogenesis were unaffected when initials formed post-meiosis, indicating other events cause sexual termination. Apomixis in Hieracium is not caused by changes in callose distribution but by events that lead to initial cell formation. The timing of initial formation can in turn influence callose dissolution. Received: 18 April 2000 / Accepted: 10 July 2000