Developmental expression of ASG- 1 during gametogenesis in apomictic guinea grass (Panicum maximum)

We have used Western blue-visualized in situ-hybridization (ISH) to monitor the expression of apomixis-specific gene-1 (ASG-1, GenBank accession number AB000809) during gametogenesis in obligate-sexual and facultative-apomictic (aposporic) genotypes of guinea grass (Panicum maximum). The in situ-analysis revealed that ASG-1 is not expressed in the ovule during early floral development in both, the facultative apomicts (A1 stage) and the obligate sexuals (S1 stage). With the appearance of the aposporous initial cell(s) in the ovule of the apomictic type (A2-1 stage), ASG-1 expression is strong and specific to this apomixis-specific cell. ASG-1 expression continued through different stages of aposporous embryo sac development (A2-2 stage), indicating that the gene may play a role in this developmental process. Regular embryo sacs in sexual types did not show hybridization signals (S2 stage). However, strong ASG-1 expression was detected in immature pollen grains and young embryos in both reproductive types, suggesting that ASG-1 may be an allele derived from the obligate-sexual wild type. Expression in pollen grains faded with maturation. In a heterologous system, using Paspalum notatum, a facultative-aposporic tropical grass (bahia grass), identical results were obtained. The results are discussed in view of the fact, that ASG-1 shows some homology to genes known to be seed- or embryo-specific or involved in processes related to cell growth.     

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.     

Ultrastructural changes in suspension culture cells of Panicum maximum during cryopreservation

A Panicum maximum cell suspension was used to study ultrastructural changes during cryopreservation. Pregrowing the cells in mannitol caused reduction in the vacuolar volume by redistribution of the large central vacuole into a number of smaller vesicles. Invaginations were formed in the plasma membrane of the cells, to accommodate the reduced cell volume. Swelling of organelles occurred during different stages of cryopreservation. The cisternae of the endoplasmic reticulum dilated and formed vesicles. Although some damage was apparent, organelles were still recognizable in cells frozen slowly and freeze-fixed at –10°C. The cells were able to repair such damage within two days in culture, and regained their normal appearance. Cells frozen slowly without any cryoprotection, and cells frozen rapidly by direct immersion into liquid nitrogen after cryoprotection, were lethally damaged by destruction of membranous structures. Osmiophilic granules were found along the plasma membrane of lethally damaged cells, indicating that their formation is a consequence of freeze damage, rather than a mechanism to prevent injury.Abbreviations 2,4-D 2,4-dichlorophenoxyacetic acid - DMSO dimethyl sulfoxide     

Rearrangements in the mitochondrial genome of somatic hybrid cell lines of Pennisetum americanum (L.) K. Schum. + Panicum maximum Jacq.

Summary Mitochondrial DNA from three somatic hybrid cell lines of Pennisetum americanum + Panicum maximum was compared with mitochondrial DNA of the parents. Gel electrophoresis of BamHI-restricted mitochondrial DNA indicated that extensive rearrangements had occurred in each of the three hybrid lines. The hybrid restriction patterns showed a combination of some bands from each parent plus novel fragments not present in either parent. Additional evidence for rearrangements was obtained by hybridization of eight DNA probes, carrying sequences of known coding regions, to Southern blots. Each of the somatic hybrids exhibited a partial combination of the parental mitochondrial genomes. These data suggest recombination or amplification of the mitochondrial genomes in the somatic hybrids.     

Molecular characterization of the genomic region linked with apomixis in<Emphasis Type="Italic"> Pennisetum/Cenchrus</Emphasis>

Apomixis is defined as asexual reproduction through seeds, although this outcome can be achieved by multiple pathways. Since little is known about the molecular control of these pathways, how they might intersect is also a mystery. Two of these pathways in the grass family, diplospory and apospory, are receiving attention from molecular biologists. Apospory in Pennisetum/Cenchrus, two genera of panicoid grasses, results in the formation of four-nucleate embryo sacs that lack antipodals. Sexual reproduction frequently aborts so that the resulting seed is composed of (1) a parthenogenetically derived embryo that is genetically identical to the mother and (2) endosperm formed through pseudogamy. The transmission of apomixis is associated with the transfer of a linkage block on a single chromosome. This linkage block contains repetitive sequences as well as hemizygous, low-copy DNA sequences. Fluorescence in situ hybridization has demonstrated that these DNA regions occur on only a single chromosome, but not its homologs, in the polyploid apomicts studied. Features of the apomixis-associated region resemble those of other chromosomal segments isolated from recombination and replete with "selfish" DNAs.     

Apomixis in <Emphasis Type="Italic">Eulaliopsis binata</Emphasis>: characterization of reproductive mode and endosperm development

Apomixis represents an alteration of classical sexual plant reproduction to produce seeds with essentially clonal embryos, stimulating wide interest from biologists and plant breeders for its ability to fix heterosis. Eulaliopsis binata (Poaceae), is identified here as a new apomictic species. Embryological investigation indicates that the developmental pattern of embryo sac formation in E. binata represents gametophytic apospory, the embryo originating from an unreduced cell, without fertilization and the mode of endosperm development was autonomous. Sexual embryo sacs were found with a frequency of 1–4% depending on the biotype. The DNA content of nuclei (C-value) in mature seeds was screened by flow cytometry (FCSS) and demonstrated that the endosperm was derived autonomously without fertilization and the three biotypes of E. binata showed varying degrees of apomixis. The Wide-leaf type showed obligate apomixis whereas the Slender-leaf and the Red-haulm type displayed facultative apomixis. In addition, adventitious embryos were observed on the wall of ovary, integument and nucellus cells, indicating that E. binata produces embryos via a mixture of apospory and adventitious embryony.     

Inorganic salts modify embryo sac development in sexual and aposporous Cenchrus ciliaris

Summary Sexual and aposporously apomictic plants of buffelgrass (Cenchrus ciliaris L.) form megaspore tetrads. In sexual plants the chalazal megaspore develops into a single Polygonum type embryo sac. In aposporous plants the megaspores degenerate, and one or more un-reduced nucellar cells form Panicum type embryo sacs. Apospory is conditioned by gene A; the dominant allele of gene B is epistatic to A and preserves sexual reproduction. We recently observed that heavy application of (NH₄)₂SO₄ to the soil induced multiple embryo sacs in a sexual line. Therefore we tested the effect of salt stress on embryo sac formation in sexual and aposporous genotypes. One molar solutions of CaCl₂, NaCl, (NH₄)₂SO₄, NH₄Cl, NaNO₃, or Na₂SO₄ were applied to the soil of greenhouse plants every day or two starting at the archespore stage. Some of the pistils in salt-treated plants of sexual genotypes AaBb, aaBb, and aabb showed features not seen in untreated controls: (1) multiple Polygonum type embryo sacs in 1%–7% of pistils depending upon the salt; (2) embryo sacs without antipodals (0%–7%); (3) embryo sacs protruding through the micropyle (1%–16%). Some pistils of salt-treated obligately aposporous lines, but not controls, developed Polygonum type embryo sacs (4%–13%) and protruding embryo sacs (0%–6%). There was no ion specificity for induction of abnormal features. We postulate that salt stress suppresses the developmental priority of nucellar embryo sacs over megaspores in aposporous lines and of the chalazal megaspore over other megaspores in all lines. This may permit megaspores of aposporous plants to form reduced Polygonum type gametophytes, and permit more than one megaspore to form reduced embryo sacs in all lines. Protrusion of sacs and failure of antipodal formation in reduced embryo sacs may be the consequence of uncoordinated expansion of the embryo sacs and surrounding tissue.Joint contribution of the Department of Biology, The Pennsylvania State University, and USDA-ARS, U.S. Regional Pasture Research Laboratory. Names of products are included for the benefit of the reader and do not imply endorsement or preferential treatment by USDA     

Effect of varying environments on photosynthetic parameters of C3, C3-C4 and C4 species of Panicum

Summary CO₂ exchange characteristics and the activity of the carboxylating enzymes phosphoenolpyruvate carboxylase (PEP-C, E.C. 4.1.1.31) and ribulose 1,5-bisphosphate carboxylase (RuBP-C, E.C. 4.1.1.39) during one year in the greenhouse and at two levels of light and temperature in growth chambers were determined in the C₃-C₄ intermediate species P. milioides Nees ex. Trin. These results were compared with those of P. bisulcatum Thumb. (C₃) and P. maximum Jacq. (C₄). Under all tested conditions, and even when the influence of leaf surface temperature on photosynthetic rates and CO₂ compensation points were measured, the biochemical and physiological behaviour of the C₃-C₄ intermediate was more similar to that of the C₃ plant than the C₄ species. The C₄ plant P. maximum, however, responded positively, mainly in terms of PEP-C activity and photosynthetic rate, to the regime of high light and temperature. The results presented indicate that in the C₃-C₄ Panicum grown in high light and temperature no direct relationships between a low CO₂ compesation point and superior growth are evident. It has still to be clarified why in nature a photosynthetic-photorespiratory pathway leading to an intermediate CO₂ compensation value has evolved in P. milioides.     

Detection of interspecific and intraspecific variation in Panicum millets through random amplified polymorphic DNA

The potential use of random amplified polymorphic DNA (RAPD) was evaluated as a source of genetic markers for studying variation among four species of Panicum and within the crop species P. miliaceum and P. sumatrense. Polymorphism in RAPD markers was observed across and within species. The four species were distinct in RAPD patterns and were separated at low correlation values even with small samples involving single genotypes per species. Accessions of P. miliaceum were grouped according to geographical regions of origin. The study demonstrated that unlike isozyme and protein electrophoresis patterns, RAPD markers can be applied to studying genetic diversity, defining gene pools, and identifying cultivars for this group of millets.     

Biochemical and molecular markers for investigating the mode of reproduction in the facultative apomict Poa pratensis L.

Isozymes and random amplified polymorphic DNA (RAPD) markers were used for precocious identification of non-maternal plants in progenies of the facultative apomict Poa pratensis. Four progenies obtained from controlled crosses that showed different degrees of apomixis on isozyme analysis of phospho-gluco-isomerases, esterases and peroxidases were chosen for RAPD analysis to generate genomic fingerprints using species-specific primers. At an advanced vegetative stage, a morphological analysis was also performed and characteristics related to growth habit and leaf morphology were observed and recorded. On the basis of the isozyme and RAPD electrophoretic pattern and the morphological appearance, each plant was classified as maternal or aberrant. All three classes of genetic markers employed were able to identify plants that exhibited aberrant traits in the four progenies. Overall, the results of RAPD analysis supported those of isozyme and morphology studies. However, in each progeny, some plants which both isozyme and morphological analyses distinguished as of maternal origin were aberrant according to RAPD analysis. Therefore, the RAPD method proved the most precise screening technique. The greater cost of the molecular approach was offset by its higher accuracy. The use of either three isozyme systems or six primers for PCR amplification seems to be sufficient for reliable estimation of the degree of apomixis. Histological analyses were carried out and the aposporic development of the plant material studied.     

Ultrastructural characterization of somatic embryos regenerated from NaCl selected and nonselected calli ofDactylis glomerata

Summary Calli were induced from leaf expiants of aDactylis glomerata L. (orchardgrass) genotype which has a high capacity for somatic embryogenesis. After 7 months culture on SH medium containing NaCl, a line was selected which was tolerant to 200 mM NaCl. When both selected and nonselected calli were maintained for 56 days on media containing 0 to 300 mM NaCl, the selected line showed significantly higher regeneration capacity than nonselected calli when placed on media containing more than 50 mM NaCl. Ultrastructural features of control somatic embryos not exposed to the salt were compared to those from nonselected and selected embryos cultured on 200 mM NaCl medium. In the presence of NaCl there were changes in the appearance of cell walls and mitochondria, accumulation of lipids and a higher degree of vacuolation in cells of nonselected embryos compared to control and selected embryos.     

大黍无融合生殖研究概况

从胚胎学和遗传学角度论述了大黍（Panicum maximum Jacq)的无融合生殖研究进展和存在的问题,展望了大黍作为无融合生殖基因供体。在无融合生殖研究上的利用前景。     

Efficient induction of apospory and apogamy in vitro in silver fern (Pityrogramma calomelanos L.)

Silver fern (Pityrogramma calomelanos L.) is a terrestrial or lithophytic herbaceous fern used for ornamental and medicinal purposes. In its farina it produces the cytotoxic and anticancer compound dihydrochalcone. In vitro induction of apospory and apogamy, and direct field establishment of aposporous gametophytes and subsequent sporophyte development has been accomplished. Half-strength Murashige and Skoog (MS) medium with 3.33 μM N⁶-benzyladenine (BA) and 2.32 μM kinetin (Kn) showed earlier development and produced higher numbers of aposporous gametophytes than half-strength MS basal medium. Crozier explants developed higher numbers (mean value 29.2) of gametophytes, but were slower than frond explants (mean value 23.2). The gametophytes originated from the epidermal hairs progressed from uniseriate filamentous to cordate through bi-, tri- and multiseriate and spatulate stage with the development of antheridia. Reduction in the nutrient and sucrose concentrations in the media favoured apogamy. Sucrose-free 1/10 strength MS medium and agar plates developed a mean of 30.4 and 29.9 sporophytes, respectively in the light. The greenhouse-established gametophytes developed sporophytes. The established sporophytes ex vitro showed 95% survival rate. Apogamous sporophytes and the source plant showed the same chromosome numbers (2n=116). The established protocol accomplishes apogamy and apospory in silver fern, and the aposporous gametophytes can be used for genetic transformation and development of transgenic silver fern.     

Gibberellic-acid causes flowering in the short-day plants Panicum miliaceum L., P. miliare lamk., and Setaria italica (L.) P. Beauv.

Treatment with gibberellic acid (GA₃) causes formation of flowers in Panicum ciliaceum and Panicum miliare, two short-day plants, under long days (continuous light), and hastens the emergence of ears in Setaria italica, a quantitative short-day plant, under both inductive and non-inductive photoperiods. The GA₃-induced inflorescences, however, remain short and bear only few spikelets; in the two Panicum species, the spikelets also remain sterile.     

Isozyme polymorphism and organization of the agamic complex of the Maximae (Panicum maximum Jacq., P. infestum Anders,and P. trichocladum K. Schum.) in Tanzania

The tribe Maximae (Panicum maximum Jacq., P. infestum Anders., P. trichocladum K. Schum.) includes two sympatric pools with different modes of reproduction and ploidy levels: an apomictic and tetraploid pool on the one hand, and a smaller, sexual and diploid pool on the other. From an analysis of isozyme polymorphism five main results were evident. First, overall polymorphism is considerable showing that apomixis does not lead to a reduction in diversity. Second, the isozyme polymorphism of the two pools is similar, and this may be explained by reciprocal gene flow (low, but continuous) between these two pools. Third, maximum local polymorphism is due to the simultaneous presence of P. maximum sexuals and P. infestum apomicts. A continuum exists between the two species. Fourth, a high proportion of rare alleles, arising from introgression from P. infestum, characterized the isozyme polymorphism. These rare alleles, strongly counter-selected at the diploid level, are maintained by apomixis; the frequency of triplex or quadruplex genotypes was nevertheless low. Fifth, the heterozygosity level within apomicts is not higher than that of sexuals, showing that the apomixis-polyploidy combination does not lead to a higher frequency of very heterozygous individuals.     

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.     

Ultrastructural characterization of fresh and cryopreserved in vivo produced ovine embryos

Controlled slow freezing and vitrification have been successfully used for ovine embryo cryopreservation. Selection of embryos for transfer is based on stereomicroscopical embryo scoring after thawing, but the subjectivity inherent to this selection step has been demonstrated by ultrastructural studies of controlled slow frozen, in vivo produced ovine morulae and blastocysts. These studies have shown that certain abnormalities remain undetected by stereomicroscopy only. In the present study, using ovine in vivo produced morulae and blastocysts, we have studied the ultrastructural alterations induced by open pulled straw vitrification (OPS) and controlled slow freezing, compared stereomicroscopical embryo scoring with light microscopy evaluation of embryo's semithin sections, and related the ultrastructural cellular damage with the embryo classification by stereomicroscopical embryo scoring of embryos’ and semithin section evaluation by light microscopy. The ultrastructural lesions found for OPS-vitrified and controlled slow frozen embryos were similar, independently of embryo stage. A significant higher number of grade 3 embryos was found at stereomicroscopical scoring after controlled slow freezing (P = 0.02), and a significant higher number of grade 3 blastocysts was found at semithin sectioning after OPS vitrification (P = 0.037). The extension of ultrastructural damage, especially of mitochondria and cytoskeleton, was related to the semithin classification but not to stereomicroscopical scoring at thawing. This suggests that semithin scoring is a useful tool for predicting ultrastructural lesions and new improvements in cryopreservation and thawing methods of ovine embryos are still warranted, including in the case of blastocysts cryopreserved by OPS vitrification.     

Ultrastructural changes in corpora allata during a cycle of juvenile hormone biosynthesis in embryos of the viviparous cockroach, Diploptera punctata

We have observed changes with time in the fine structure of corpora allata (CA) during a known cycle of increasing and decreasing juvenile hormone (JH) synthesis in late embryos of Diploptera punctata. A previous report showed that rates of JH release were relatively low in 28-day-old embryos, but CA activity subsequently rose linearly to a peak on about day 42, and thereafter steadily declined to a low level on day 64 just before birth (Holbrook et al., 1997). We now show that, regardless of rate of JH synthesis, CA cells are large and replete with organelles which nevertheless exhibit variable morphology in embryos of different age. Highly active CA cells on day 40 contain abundant ring-form mitochondria, whereas CA cells of low activity on days 28 and 64 contain mitochondria that are rod-shaped or globular. Mitochondrial cristae were scarce and indistinct on day 28 but numerous and well developed on day 64. Endoplasmic reticula (ER) are rare on day 28 and appear in increasing numbers when CA activity rises. On day 40, ER are abundant and often exhibit a whorl-like appearance which is not observed on day 28. After day 44, when biosynthetic activity is declining, whorls of ER gradually decrease in number and are ultimately replaced by vesicular smooth ER on day 64. Neurosecretions are found only after day 38, by which time rates of JH synthesis have increased substantially from those of day 28. Except for membranous autophagic vacuoles, which are frequently found when ER whorls disintegrate as rates of JH synthesis decline toward birth, most autophagic vesicles such as multivesicular vesicles and dense bodies occur only sporadically among CA cells at all examined ages. We conclude that synchronous autophagy of exhausted organelles, which results in atrophy of CA cells and long-term arrest of JH synthesis in adult females of D. punctata, does not occur in embryos. The slow cyclic change in rate of JH synthesis in embryonic CA is most likely due to asynchronous autophagic activity and to alterations in certain unique features of intracellular organelles.