Identification of Embryoid-Abundant Genes That Are Temporally Expressed during Pollen Embryogenesis in Wheat Anther Cultures

Uninucleate microspores in anther cultures of bread wheat (Triticum aestivum cv Pavon) are capable of producing haploid pollen embryoids and plants. To gain an understanding of this alternate pathway of pollen development, we constructed a cDNA library to young pollen embryoids, isolated embryoid-specific genes, and analyzed their expression patterns during morphogenesis. Two embryoid-abundant clones, pEMB4 and 94, were expressed very early during culture, suggesting that these genes are associated with development and are not simply expressed as a consequence of differentiation. The accumulation patterns of five cloned mRNAs may indicate the activation of specific genes associated with the major morphological and physiological activities connected with the differentiation of embryoids in vitro. These results suggest that embryoid-abundant gene expression is causally related to this pathway because gene expression is spatially and temporally specific and is not observed when microspores are cultured under noninductive conditions.     

Ultrastructural studies on pollen embryogenesis in maize (Zea mays L.)

Maize anthers have been induced on modified N6 medium to produce embryoids. Different stages from the cultures were sampled and prepared for microscopical examination. The microspores at the onset of culture were in an early developmental stage, with the nucleus and numerous organelles centred in the middle, surrounded by many small vacuoles with a lipid content. The binuclear pollen grains contained small vesicles and much starch. The partially condensed vegetative nucleus indicated participation of the vegetative component in the formation of multicellular pollen grains (MPGs). Several MPGs have been observed which differed in morphology. We suggest, on the basis of these ultrastructural observations, that in maize mainly the vegetative cell contributes to the MPG which further develops directly into embryoids.     

甘蓝型油菜游离小孢子培养的胚胎发生

以生长在非控温控光下的４个冬性甘蓝型油菜（ＢｒａｓｓｉｃａｎａｐｕｓＬ．）品种为供体,进行游离小孢子培养。研究发现,多数品种在开花３－７天取材最为适宜。在甘蓝型油菜小孢子培养中只有单核晚期的小孢子才可能发育成胚状体,而花药培养时处于单核早期的小孢子易于发育成胚状体。在适当花期选取发育比较一致的单核晚期小孢子培养,经数小时后,部分小孢子便开始膨大,这是小孢子发育成胚的最早标志,膨大的小孢子中,有部分形成多细胞球并进一步发育成胚。用春性甘蓝型油菜为材料进行蔗糖浓度的实验结果表明：培养３天后,在１６％蔗糖培养基中存活的小孢子最多,达１６．１３％;培养３０天后,胚状体诱导频率则以１３％蔗糖浓度为最高,每花蕾可达１４４个胚状体。如果在１６％蔗糖培养基中培养３天后,添加等体积的１３％蔗糖培养基,能够大大提高胚状体的诱导频率,为仅用１３％蔗糖培养基培养的３．７倍。这一实验体系正在用于抗菌核病的诱变与筛选,并作为外源基因导入的实验体系。     

Control of abscisic acid catabolism and abscisic acid homeostasis is important for reproductive stage stress tolerance in cereals

Drought stress at the reproductive stage causes pollen sterility and grain loss in wheat (Triticum aestivum). Drought stress induces abscisic acid (ABA) biosynthesis genes in anthers and ABA accumulation in spikes of drought-sensitive wheat varieties. In contrast, drought-tolerant wheat accumulates lower ABA levels, which correlates with lower ABA biosynthesis and higher ABA catabolic gene expression (ABA 8'-hydroxylase). Wheat TaABA8'OH1 deletion lines accumulate higher spike ABA levels and are more drought sensitive. ABA treatment of the spike mimics the effect of drought, causing high levels of sterility. ABA treatment represses the anther cell wall invertase gene TaIVR1, and drought-tolerant lines appeared to be more sensitive to the effect of ABA. Drought-induced sterility shows similarity to cold-induced sterility in rice (Oryza sativa). In cold-stressed rice, the rate of ABA accumulation was similar in cold-sensitive and cold-tolerant lines during the first 8 h of cold treatment, but in the tolerant line, ABA catabolism reduced ABA levels between 8 and 16 h of cold treatment. The ABA biosynthesis gene encoding 9-cis-epoxycarotenoid dioxygenase in anthers is mainly expressed in parenchyma cells surrounding the vascular bundle of the anther. Transgenic rice lines expressing the wheat TaABA8'OH1 gene under the control of the OsG6B tapetum-specific promoter resulted in reduced anther ABA levels under cold conditions. The transgenic lines showed that anther sink strength (OsINV4) was maintained under cold conditions and that this correlated with improved cold stress tolerance. Our data indicate that ABA and ABA 8'-hydroxylase play an important role in controlling anther ABA homeostasis and reproductive stage abiotic stress tolerance in cereals.     

Recent advances in anther culture of Hevea brasiliensis (Muell.-Arg.)

Summary The yield of pollen embryoids from cultured Hevea anthers was increased 4 fold by optimizing the proportion of ammonium nitrate to potassium nitrate in the dedifferentiation medium. For optimal differentiation of pollen embryoids, kinetin, 2,4-D and -naphtalene acetic acid are required. Anther culture for 50 days on the dedifferentiation medium is a prerequisite for the selective development of calli and embryoids from microspores.The determination of chromosome numbers in embryoids, plantlets and regenerated trees reveals that they originate from (poly)haploid pollen grains (n=2x=18). Aneuploid, triploid (3x=27) and tetraploid (4x=36) cells were encountered in increasing frequencies as the embryoids and plants developed. A few haploid cells with 9 chromosomes were consistently observed. Buds from shoots with mixoploid chromosome numbers can be grafted and the change in the chromosome constitution of the developing new shoots followed.     

Phytohormone content in microstrobiles and androgenic callus of Siberian larch

Androgenesis in vitro in plants is a phenomenon of developmental switching of male generative cells, microspores, from their normal gametophytic to sporophytic pathway. We obtained androgenic callus and embryoids (embryo-like structures derived from microspores) of the conifer plant, Siberian larch (Larix sibirica Ledeb.) in the in vitro culture. The immune-enzyme analysis of the hormonal balance of larch androgenic cultures showed a substantial increase in the content of all phytohormones, especially cytokinins and ABA, as compared with initial explants (microstrobiles). This was evidently related to active cell divisions and embryoid formation. A comparison of androgenic cultures derived from trees nonifested and infested with larch gall midges (Dasineura rozhkovi Mam. et Nik.) revealed a cytokinin content increase (by two times) and an ABA content decrease (by two times), which indicates more intense growth of cultures derived from healthy trees. Phytohormone content in the androgenic callus was compared with their accumulation in the embryos of larch seeds harvested from noninfested trees. We concluded that successful growth of androgenic cultures and embryoid formation demand an additional medium supplement with auxins (not more than 0.5 mg/l).     

Observation of Androgenesis in Cultured Wheat Anthers at Meiosis,Tetrad, Early Uninucleate and Trinucleate Stage

The obtaining of calluses and plantlets from cultured wheat anthersat the stages from pollen mother cell to trinucleate microspore has been reported previously. Haploids as well as diploids existed among the regenerated plantlets derivedfrom anthers at these stages. Present paper reports the study on androgenesis patter-ns of cultured anthers at meiosis, tetrad, early mid- and late uninucleate and trinucleate stage. Cytological evidence of pollen-origin of calluses produced by anthers atthese stages was given. Observation showed that meiosis of wheat anthers was able tocomplete under culture conditions, resulting in releasing microspores, from which multinucleate and multicellular pollen grains formed. In meiosis anthers, abnormal cells,including syncytium and two kinds of binueleate calls were sometimes observed. Theymight be products of abnormal meiosis and abnormal development of tapetum cells. Itwas noted that failure and/or uncomplction of forming callus wall and/or pollen wallin in vitro anthers at meiosis, tetrad and early uninucleate stage occured often. Itmight lead to the low frequency of callus induction. Mature wheat anthers (trinucleate stage) contained both normal and abnormal pollen grains (pollen dimorphism); onlythe abnormal pollen grains developed into embryoids while all the normai trinucleatepollen grains degenerated rapidly. However, the date of the frequency of equal divisionof microspores suggested that abnormal pollen (N pollen, small pollen) could not be theonly source of androgenic pollens in cultured anthers at late uninucleate and other earlier stages.     

A CYTOLOGICAL ANALYSIS OF MICROSPORES OF TRITICUM AESTIVUM (POACEAE) DURING NORMAL ONTOGENY AND INDUCED EMBRYOGENIC DEVELOPMENT

Uninucleate microspores of Triticum aestivum cv. Pavon can be induced in vitro to alter their development to produce embryoids rather than pollen. Microspores expressed their embryogenic capacity through one of two division pathways. In the more common route, the first sporophytic division was asymmetric and produced what appeared to be a typical bicellular pollen grain. Here the generative cell detached from the intine, migrated to a central position in the pollen grain, and underwent a second haploid mitosis as the vegetative cell divided to give rise to the embryoid. In the second pathway, the first division was symmetric and both nuclei divided repeatedly to form the embryoid. This comparative analysis of normal pollen ontogeny and induced embryogenesis provided no evidence for the existence of predetermined embryogenic microspores in vitro or in vivo. Instead, microspores are induced at the time of culture, and embryogenesis involves continued metabolic activity associated with the gradual cessation of the gametophytic pathway and a redifferentiation into the sporophytic pathway. In conjunction with a previous study, it appears that embryogenic induction of wheat microspores involves switching off gametophytic genes and derepressing sporophytic genes.     

Microspore culture in wheat (Triticum aestivum) – doubled haploid production via induced embryogenesis

The inherent potential to produce plants from microspores or immature pollen exists naturally in many plant species. Some genotypes in hexaploid wheat (Triticum aestivum L.) also exhibit the trait for androgenesis. Under most circumstances, however, an artificial manipulation, in the form of physical, physiological and/or chemical treatment, need to be employed to switch microspores from gametophytic development to a sporophytic pathway. Induced embryogenic microspores, characterized by unique morphological features, undergo organized cell divisions and differentiation that lead to a direct formation of embryoids. Embryoids `germinate' to give rise to haploid or doubled haploid plants. The switch from terminal differentiation of pollen grain formation to sporophytic development of embryoid production involves a treatment that halts gametogenesis and initiates sporogenesis showing predictable cellular and molecular events. In principle, the inductive treatments may act to release microspores from cell cycle control that ensures mature pollen formation hence overcome a developmental block to embryogenesis. Isolated microspore culture, genetic analyses, and studies of cellular and molecular mechanisms related to microspore embryogenesis have yielded useful information for both understanding androgenesis and improving the efficiency of doubled haploid production. The precise mechanisms for microspore embryogenesis, however, must await more research.     

The effect of ovary-conditioned medium on microspore embryogenesis in common wheat (Triticum aestivum L.)

Microspores were isolated from wheat (Triticum aestivum L.) spikes of various genotypes following an effective pretreatment that induced microspore embryogenesis. The isolated microspores were cultured with or without live ovaries, and with or without medium pre-conditioned by ovaries for varying periods of time. Live ovaries alone increased androgenic embryoid yields up to 4.5-fold over the control for microspores isolated from responsive genotypes. While live ovary co-culture alone was not effective for microspores isolated from recalcitrant genotypes, the addition of medium preconditioned by ovaries to microspore cultures increased embryoid yield by more than 100-fold. Without ovary-conditioned medium, no embryoids could be obtained from some recalcitrant genotypes. Ovary-conditioned medium apparently functions to increase embryoid yields by providing essential substance(s) for elaboration of the embryogenic program already triggered during pretreatment.     

Genotypic Differences in the In Vitro Formation of Embryoids from Rice Pollen

Twenty varieties of rice were assessed for the ability of theirpollen to give rise to ombryoids and haploid plantlets in antherculture. There were wide differences in response between thevarieties, a primitive cultivar from Assam being the most responsive.Only anthers containing uninucleate microspores showed differentiationof pollen embryoids. It appeared that during the initial stagesof development the embryoids were attached to the wall of theanthors by a suspensor-like attachment. Genotypic differences,besides several other factors, have a definite role in shiftingthe normal course of development of the pollen.     

PHOSPHATIDYLSERINE SYNTHASE1 is required for microspore development in Arabidopsis thaliana

Phosphatidylserine (PS) has many important biological roles, but little is known about its role in plants, partly because of its low abundance. We show here that PS is enriched in Arabidopsis floral tissues and that genetic disruption of PS biosynthesis decreased heterozygote fertility due to inhibition of pollen maturation. At1g15110, designated PSS1, encodes a base-exchange-type PS synthase. Escherichia coli cells expressing PSS1 accumulated PS in the presence of l-serine at 23°C. Promoter-GUS assays showed PSS1 expression in developing anther pollen and tapetum. A few seeds with pss1-1 and pss1-2 knockout alleles escaped embryonic lethality but developed into sterile dwarf mutant plants. These plants contained no PS, verifying that PSS1 is essential for PS biosynthesis. Reciprocal crossing revealed reduced pss1 transmission via male gametophytes, predicting a rate of 61.6%pss1-1 pollen defects in PSS1/pss1-1 plants. Alexander's staining of inseparable qrt1-1 PSS1/pss1-1 quartets revealed a rate of 42% having three or four dead pollen grains, suggesting sporophytic pss1-1 cell death effects. Analysis with the nuclear stain 4',6-diamidino-2-phenylindole (DAPI) showed that all tetrads from PSS1/pss1-1 anthers retain their nuclei, whereas unicellular microspores were sometimes anucleate. Transgenic Arabidopsis expressing a GFP-LactC2 construct that binds PS revealed vesicular staining in tetrads and bicellular microspores and nuclear membrane staining in unicellular microspores. Hence, distribution and/or transport of PS across membranes were dynamically regulated in pollen microspores. However, among unicellular microspores from PSS1/pss1-2 GFP-LactC2 plants, all anucleate microspores showed little GFP-LactC2 fluorescence, suggesting that pss1-2 microspores are more sensitive to sporophytic defects or show partial gametophytic defects.     

Regulation of hormone metabolism in Arabidopsis seeds: phytochrome regulation of abscisic acid metabolism and abscisic acid regulation of gibberellin metabolism

In a wide range of plant species, seed germination is regulated antagonistically by two plant hormones, abscisic acid (ABA) and gibberellin (GA). In the present study, we have revealed that ABA metabolism (both biosynthesis and inactivation) was phytochrome-regulated in an opposite fashion to GA metabolism during photoreversible seed germination in Arabidopsis. Endogenous ABA levels were decreased by irradiation with a red (R) light pulse in dark-imbibed seeds pre-treated with a far-red (FR) light pulse, and the reduction in ABA levels in response to R light was inhibited in a phytochrome B (PHYB)-deficient mutant. Expression of an ABA biosynthesis gene, AtNCED6, and the inactivation gene, CYP707A2, was regulated in a photoreversible manner, suggesting a key role for the genes in PHYB-mediated regulation of ABA metabolism. Abscisic acid-deficient mutants such as nced6-1, aba2-2 and aao3-4 exhibited an enhanced ability to germinate relative to wild type when imbibed in the dark after irradiation with an FR light pulse. In addition, the ability to synthesize GA was improved in the aba2-2 mutant compared with wild type during dark-imbibition after an FR light pulse. Activation of GA biosynthesis in the aba2-2 mutant was also observed during seed development. These data indicate that ABA is involved in the suppression of GA biosynthesis in both imbibed and developing seeds. Spatial expression patterns of the AtABA2 and AAO3 genes, responsible for last two steps of ABA biosynthesis, were distinct from that of the GA biosynthesis gene, AtGA3ox2, in both imbibed and developing seeds, suggesting that biosynthesis of ABA and GA in seeds occurs in different cell types.     

WBC27, an adenosine tri-phosphate-binding cassette protein, controls pollen wall formation and patterning in Arabidopsis

In flowering plants, the exine components are derived from tapetum. Despite its importance to sexual plant reproduction, little is known about the translocation of exine materials from tapetum to developing microspores. Here we report functional characterization of the arabidopsis WBC27 gene. WBC27 encodes an adenosine tri-phosphate binding cassette (ABC) transporter and is expressed preferentially in tapetum. Mutation of WBC27 disrupted the exine formation. The wbc27 mutant microspores began to degenerate once released from tetrads and most of the microspores collapsed at the uninucleate stage. Only a small number of wbc27-1 microspores could develop into tricellular pollen grains. These survival pollen grains lacked exine and germinated in the anther before anthesis. All of these results suggest that the ABC transporter, WBC27 plays important roles in the formation of arabidopsis exine, possibly by translocation of lipidic precursors of sporopollenin from tapetum to developing microspores.