Callose pattern and polarization phenomena in the ovules in the F2-hybrids betweenOenothera hookeri andOe. suaveolens

The pattern of callose formation in meiotic cell walls and the order of megaspore degeneration and polarity during embryo sac development are investigated in F₂-plants ofOe. hookeri ×suaveolens and the reciprocal cross. All investigated characters are variable between the ovules in the same ovary. Plants differ in the frequency of the types of callose pattern and polarity of the embryo sacs. In segregating progenies different combinations of both characters are found. The genetic basis of the polarity phenomena during the embryo sac development is discussed. In our material no correlation can be seen between the callose pattern in the surrounding wall of the meiotic cell and the development of polarity in the later stages.     

Megasporogenesis and megagametogenesis in several Tripsacum species (Poaceae)

The Tripsacum agamic complex (x = 18) will provide valuable characters for maize breeding, provided that apomixis can be manipulated. Apomixis in Tripsacum was first reported 40 years ago, but its prevalence in the genus has not been established. Reproductive development was determined for eight Mexican and two South American Tripsacum species by microscopic analysis of ovaries cleared in a benzyl benzoate-dibutyl phthalate solution using interference contrast optics. The occurrence and distribution of callose deposition during megasporogenesis were determined by fluorescence microscopy of ovaries optically cleared in an aqueous sucrose solution containing aniline blue. Diploid genotypes were sexual. Polyploid forms reproduced apomictically following the Antennaria type (complete meiosis abortion) of diplospory. The Taraxacum type (unreduced megaspore production through meiotic restitution nuclei) of diplospory also occurred but rarely. The walls of diplosporic megasporocytes lacked callose whereas the walls of sexual megasporocytes contained a normal complement of callose. The absence of callose suggests that the diplosporic forms of reproduction result from mutations affecting the normal meiotic process. Apomixis in the Tripsacum genus is facultative, and the production of new polyploid genotypes through genetic exchanges involving both apomictic and sexual genotypes is possible.     

New facts about callose events in the young ovules of some sexual and apomictic species of the Asteraceae family

Callose (β-1,3-glucan) is one of the cell wall polymers that plays an important role in many biological processes in plants, including reproductive development. In angiosperms, timely deposition and degradation of callose during sporogenesis accompanies the transition of cells from somatic to generative identity. However, knowledge on the regulation of callose biosynthesis at specific sites of the megasporocyte wall remains limited and the data on its distribution are not conclusive. Establishing the callose deposition pattern in a large number of species can contribute to full understanding of its function in reproductive development. Previous studies focused on callose events in sexual species and only a few concerned apomicts. The main goal of our research was to establish and compare the pattern of callose deposition during early sexual and diplosporous processes in the ovules of some Hieracium, Pilosella and Taraxacum (Asteraceae) species; aniline blue staining technique was used for this purpose. Our findings indicate that callose deposition accompanies both meiotic and diplosporous development of the megaspore mother cell. This suggests that it has similar regulatory functions in intercellular communication regardless of the mode of reproduction. Interestingly, callose deposition followed a different pattern in the studied sexual and diplosporous species compared to most angiosperms as it usually began at the micropylar pole of the megasporocyte. Here, it was only in sexually reproducing H. transylvanicum that callose first appeared at the chalazal pole of the megasporocyte. The present paper additionally discusses the occurrence of aposporous initial cells with callose-rich walls in the ovules of diploid species.

     

A case of early dissolution of the microsporocyte callose wall in male-sterile (CMS) sweet pepper (Capsicum annuum L.)

On squash preparations of anthers from pollen fertile and sterile plants of sweet pepper (Capsicum annuum L. cv. Severka) callose envelopes of microsporocytes, stained specifically with resorcin blue, were investigated microscopically. During normal course of microsporogenesis in fertile plants the envelopes remained intact up to the stage of microspore tetrads. Then callose begins to dissolve, and that from individual microspores towards the envelope periphery. In sterile analogues of the same cultivar the callose breakdown occurred precociously, usually in the course of the second, but sometimes as early as the first meiotic division of PMCs. Having completed meiosis sporadic microsporocytes formed microspore tetrads. Most PMCs contained an undivided four-nucleate protoplast rimmed with a narrow or wider unstained zone of dissolved callose. In certain cases more condensed callose septa pointing to the furrows on the surface of the PMC protoplast were well-observable in this lytic zone, as a residuum of normal mechanism of tetradogenesis.     

Maize csmd1 exhibits pre-meiotic somatic and post-meiotic microspore and somatic defects but sustains anther growth

Maize male reproductive development is complex and lengthy, and anther formation and pollen maturation are precisely and spatiotemporally regulated. Here, we document that callose, somatic, and microspore defect 1 (csmd1), a new male-sterile mutant, has both pre-meiotic somatic and post-meiotic gametophyte and somatic defects. Chromosome behavior and cell developmental events were monitored by nuclear staining viewed by bright field microscopy; cell dimensions were charted by Volocity analysis of confocal microscopy images. Aniline blue staining and quantitative assays were performed to record callose deposition, and expression of three callose synthase genes was measured by qRT-PCR. Despite numerous defects and unlike other maize male-sterile mutants that show growth arrest coincident with locular defects, csmd1 anther elongation is nearly normal. Pre-meiotically and during prophase I, there is excess callose surrounding the meiocytes. Post-meiotically csmd1 epidermal cells have impaired elongation but excess longitudinal divisions, and uninucleate microspores cease growth; the microspore nucleoli degrade followed by cytoplasmic vacuolization and haploid cell collapse. The single vascular bundle within csmd1 anthers senesces precociously, coordinate with microspore death. Although csmd1 anther locules contain only epidermal and endothecial cells at maturity, locules are oval rather than collapsed, indicating that these two cell types suffice to maintain an open channel within each locule. Our data indicate that csmd1 encodes a crucial factor important for normal anther development in both somatic and haploid cells, that excess callose deposition does not cause meiotic arrest, and that developing pollen is not required for continued maize anther growth.     

LP28, a lily pollen-specific LEA-like protein, is located in the callosic cell wall during male gametogenesis

. LP28, a pollen-specific LEA-like protein identified in Lilium longiflorum purportedly related to the desiccation tolerance of pollen, was localized during male gametogenesis using immuno-electron microscopy. At premeiotic interphase, LP28 label is absent from the microsporocyte. LP28 label was first detected in the cell wall of the microsporocyte at meiotic prophase I. LP28 gradually increased as the cell wall thickened. In the dyad, after the first meiotic division, LP28 label also appeared in the septum. In the tetrad, after the second meiotic division, LP28 was detected throughout the cell wall, including the septa. Immunolabeling of callose during meiosis indicated that the appearance and localization of LP28 was very similar to that of callose. After the microspores were released from the tetrad by digesting the callosic cell wall, LP28 was not found in the microspores. In bicellular pollen, just after microspore mitosis, LP28 appeared in the generative cell wall, which also consisted of callose. After pollen germination, LP28 also accumulated in the callosic layer of the elongated pollen tube wall and the callose plug. Thus, LP28 colocalized with the callosic cell wall during male gametogenesis. The possible role of LP28 with respect to wall formation during meiosis and pollen development is discussed.     

Callose in cell walls during megasporogenesis in angiosperms

Summary Callose was detected by fluorescence microscopy in megasporogenesis in all investigated species with mono- and bisporic embryo-sac development. Callose occurs first in the meiotic prophase in the chalazal part of the megasporocyte wall and by the first meiotic metaphase the whole cell is enveloped in a callose-containing wall. Later, there is a marked decrease of callose fluorescence, usually at the chalazal end of the megasporocyte. In Oenothera, where the micropylar megaspore is active, decrease of fluorescence takes place at the micropylar pole of the megasporocyte. Callose appears centrifugally in the cell plates forming eventually the walls dividing the megaspores. It disappears from the walls of the megaspores during degeneration and differentiation.     

Changes in intracellular localization of peroxidase during Microsporogenesis in Gymnosperms

Cytochemical investigations on peroxidase localization during microsporogenesis inLarix europaea D.C.,Taxus baccata L. andPinus sylvestris L. have revealed striking differences in the localization and activity level of this enzyme linked with the developmental stage. The localization and level of activity of peroxidase, typical of each stage, changed in the course of microsporogenesis in a strictly orderly way, giving a characteristic and stable pattern. The pattern of intracellular peroxidase localization proved to be the same for microsporogenesis of all the gymnosperms in question. It is suggested that the identity of that pattern in plants so phylogenetically distant asTaxus baccata L. andPinus sylvestris L. indicates that peroxidase activity in gymnosperms’ microsporogenesis is connected with the fundamental and genetically well stabilized processes of meiotic cytodifferentiation. Moreover, enhanced peroxidase activity has been found in the sites of callose walls synthesis of dyads and tetrads, which suggests the participation of this enzyme in callose synthesis.     

Ontogeny of intruding non-periplasmodial tapetum in the wild chicory,Cichorium intybus (Compositae)

The tapetal development ofCichorium intybus L. is investigated using LM and TEM and discussed in relation to the development in other species. During the second meiotic division the tapetal cells become binucleate and lose their cell walls. They intrude the loculus at the time of microspore release from the meiotic callose walls, which means that a locular cavity is never present in this species. During pollen development they tightly junct the exine, especially near the tips of the spines. During the two-celled pollen grain stage they degenerate and most of their content turns into pollenkitt. Until anther dehiscence they keep their individuality, which means that these intruding tapetal cells never fuse to form a periplasmodium. The ultrastructural cytoplasmatic changes during this development are discussed in relation to possible functions.     

Megasporogenesis and programmed cell death in <Emphasis Type="Italic">Tillandsia</Emphasis> (Bromeliaceae)

The degeneration of three of four meiotic products is a very common process in the female gender of oogamous eukaryotes. In Tillandsia (and many other angiosperms), the surviving megaspore has a callose-free wall in chalazal position while the other three megaspores are completely embedded in callose. Therefore, nutrients and signals can reach more easily the functional megaspore from the nucellus through the chalazal pole with respect to the other megaspores. The abortion of three of four megaspores was already recognized as the result of a programmed cell death (PCD) process. We investigated the process to understand the modality of this specific type of PCD and its relationship to the asymmetric callose deposition around the tetrad. The decision on which of the four megaspores will be the supernumerary megaspores in angiosperms, and hence destined to undergo programmed cell death, appears to be linked to the callose layer deposition around the tetrad. During supernumerary megaspores degeneration, events leading to the deletion of the cells do not appear to belong to a single type of cell death. The first morphological signs are typical of autophagy, including the formation of autophagosomes. The TUNEL positivity and a change in morphology of mitochondria and chloroplasts indicate the passage to an apoptotic-like PCD phase, while the cellular remnants undergo a final process resembling at least partially (ER swelling) necrotic morphological syndromes, eventually leading to a mainly lipidic cell corpse still separated from the functional megaspore by a callose layer.     

Efficiency of the induction of cytomixis in the microsporogenesis of dicotyledonous (<Emphasis Type="Italic">N. tabacum</Emphasis> L.) and monocotyledonous (<Emphasis Type="Italic">H. distichum</Emphasis> L.) plants by thermal stress

The efficiencies of the induction of cytomixis in microsporogenesis by thermal stress are compared in tobacco (N. tabacum L.) and barley (H. distichum L.) It has been shown that different thermal treatment schedules (budding tobacco plants at 50°C and air-dried barley grains at 48°C) produce similar results in the species: the frequency of cytomixis increases, and its maximum shifts to later stages of meiosis. However, the species show differences in response. The cytomixis frequency increase in tobacco is more pronounced, and its maximum shifts from the zygotene–pachytene stages of meiotic prophase I to prometaphase–metaphase I. Later in the meiosis, aberrations in chromosome structure and meiotic apparatus formation typical of cytomixis are noted, as well as cytomixis activation in tapetum cells. Thermal stress disturbs the integration of callose-bearing vesicles into the callose wall. Cold treatment at 7°C does not affect cytomixis frequency in tobacco microsporogenesis. Incubation of barley seeds at 48°C activates cytomixis in comparison to the control, shifts its maximum from the premeiotic interphase to zygotene, and changes the habit of cytomictic interactions from pairwise contacts to the formation of multicellular clusters. Thermal treatment induces cytomictic interactions within the tapetum and between microsporocytes and the tapetum. However, later meiotic phases show no adverse consequences of active cytomixis in barley. It is conjectured that heat stress affects callose metabolism and integration into the forming callose wall, thereby causing incomplete closure of cytomictic channels and favoring intercellular chromosome migration at advanced meiotic stages.     

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     

MECHANISMS OF APOMIXIS IN ELYMUS RECTISETUS FROM EASTERN AUSTRALIA AND NEW ZEALAND

Megasporogenesis was examined in cleared ovaries of 23 accessions of hexaploid Elymus from southeastern Queensland, northeastern New South Wales, the Australian Capital Territory, and the South Island of New Zealand. Apomixis was confined to the 17 accessions that morphologically corresponded to E. rectisetus (Nees in Lehm.) Löve et Connor. Female meiotic development followed the Polygonum type. Apomeiotic development was delayed relative to meiotic development because of a lengthy period of MMC vacuolation and nuclear stretching that occurred in place of meiosis I. Amitosis was evident in up to possibly five percent of the MMC's during nuclear stretching. A subsequent mitotic division facultatively functioned as meiosis II or the first embryo-sac mitosis to yield a 2n megaspore dyad, a hemidyad with an incomplete crosswall, or a directly binucleate embryo sac. Nuclear stretching generally resumed in the chalazal daughter nucleus from the apomeiotic division, but was not seen later in embryo sac development. When a dyad formed, its chalazal member would enlarge and develop into the embryo sac. The organized embryo sac was of the conventional eight-nucleate, seven-celled structure prior to antipodal proliferation, regardless of meiotic or apomeiotic origin. Microsporocyte meiosis was normal in both sexuals and apomicts. Deposition of a slightly birefringent substance, possibly callose, was deficient around megasporocytes, megaspores, and microsporocytes in the apomicts.     

Fluorochromes for Detection of Callose in Meiocytes of Olive (Olea europaea L)

The callosic wall which covers microsporocyte mother cells during meiotic division has been studied using different fluorochromes as alternatives to the widely used aniline blue. We have confirmed that both acridine orange and 4', 6' diamidino-2-phenylindole (DAPI) produce a fluorescent response to callose which is comparable in specificity and intensity to that of aniline blue: therefore, they can be used to study callose wall formation. Staining properties of these fluorochromes, as well of those of curcumin and sirofluor, reported earlier as fluorescent stains for callose, are discussed. We also discuss the efficacy of the combined use of sirofluor and DAPI to study particular aspects of the deposition of callose.     

铝胁迫下胡枝子根尖胼胝质形成规律及影响因素

采用水培试验,研究了铝胁迫下两个胡枝子品种根尖产生胼胝质的变化规律及影响因素。结果表明,两个品种的根尖铝吸收量与胼胝质形成量呈正比例关系。品种间差异主要是在根尖0—0.5 cm处。敏感品种胼胝质形成量同铝吸收量的变化趋势相一致,而耐性品种则在铝处理6 h时出现一个高峰值后下降。去除铝胁迫后,耐性品种胼胝质形成量并不显著减少。与单独铝处理相比,阴离子通道抑制剂苯甲酰甲醛加铝处理对两个品种胼胝质形成无影响;尼氟灭酸加铝处理抑制敏感品种胼胝质的形成,对耐性品种无影响;蒽-9-羧酸加铝处理显著抑制两个品种的胼胝质形成。另外,抑制剂2-去氧-D-葡萄糖加铝共同处理与单独铝处理相比,敏感品种的胼胝质形成量显著降低,耐性品种无影响。甘露醇对两个品种胼胝质形成的影响无显著差别。镧处理下胼胝质的形成量是耐性品种显著高于敏感品种,铝、镧同时处理胼胝质的形成量最高。敏感品种胼胝质形成处理间无差别。总之,耐性品种在铝胁迫下胼胝质形成与有机酸分泌可能存在一定的协调关系;铝胁迫下胼胝质形成是敏感指标;在一定条件下,特别是有机酸分泌前胼胝质的形成可能具有一定抗性意义;铝诱导胼胝质的形成受多种外界因素(浓度、时间、有机酸分泌,渗透压等)的影响。     

Localization of Callose during the Occurrence of Megasporocyte in Gastrodia elata Blume

The structure of ovule in Gastrodia elata Blume was very simple. Functional megaspore occurred at the chalazal end. Callose was absent at megasporocyte stage. It first appeared at the chalazal wall during the first meiotic prophase and exhibited continuous fluorescence. Soon later callose fluorescence disappeared in some part of the chalazal wall and many noncallosic dark areas took place, subsequently these nonfluorescence areas became larger and the callose fluorescence appeared discontinuous granulose distribution. This fluorescence maintained until the megaspore formed. The callose of micropylar wall appeared later and usually disappeared before megaspore formation. In the cross walls between the functional and the two degenarated megaspore callose fluorescence was very strong, continued and kept for a long time. But the side walls usually lacked callose. Accoding to the morphological character of simple ovule in G. eiata and the localization of acid phosphatase and polysaecharide grains, the transfer of vegetative materials from surrounding tissues into megasporocyte mainly passing through the chalazal end of megasporocyte. Thus a continuous callose wall deposited at the ehalazal end of megasporocyte, and it in reality caused the “isolation” of meiocyte. It was possible that a reduced form of callose disposition existed in parasetic orchids.     

Occurrence and phylogenetic significance of cytokinesis-related callose in green algae, bryophytes, ferns and seed plants

 In order to investigate the occurrence of callose in dividing cells, we cultivated a selection of 30 organisms (the prokaryotic cyanobacterium Anabaena and eukaryotic green algae, bryophytes, ferns and seed plants) under defined conditions in the laboratory. Samples from these photoautotrophs, which are members of the evolutionary 'green lineage' leading from freshwater algae to land plants, were analysed by fluorescence microscopy. The β-1,3-glucan callose was identified by its staining properties with aniline blue and sirofluor. With the exception of the prokaryotic cyanobacterium, all of the eukaryotic organisms studied were capable of producing wound-induced callose. No callose was detected during cytokinesis of dividing cells of unicellular green algae (and Anabaena). However, in all of the multicellular green algae and land plants (embryophytes) investigated, callose was identified in newly made septae by an intense yellow fluorescence. The formation of wound callose was never detected in cells with callose in the newly formed septae. Additional experiments verified that no fixation-induced artefacts occurred. Our results show that callose is a regular component of developing septae in juvenile cells during cytokinesis in multicellular green algae and embryophytes. The implications of our results with respect to the evolutionary relationships between extant charophytes and land plants are discussed. Received: 15 September 2000 / Revision received: 23 October 2000 / Accepted: 23 October 2000     

The formation of cytoplasmic channels between tapetal cells inZea mays

Summary In this report we show that large cytoplasmic channels form between the tapetal cells ofZea mays (maize) during the period of tapetal cell differentiation. Tapetal cells are connected by plasmodesmata through their cellulosic cell walls prior to the first meiotic division of the meiocytes. As the tapetal cellulose wall is degraded at the onset of meiosis, both plasmodesmata and cytoplasmic channels measuring 50–200 nm are detectable between tapetal cells. By the time the meiotic tetrad is formed, the cytoplasmic channels are well-established and vary in size from 100–400 nm. The channels, with an average diameter of 200–300 nm, persist after the microspores are released from the callose wall and throughout the period of exine development in microsporogenesis. The channels could potentially allow for free exchange of cytoplasm and organelles. As the tapetal cells begin to pull apart and become vacuolate prior to microspore mitosis, the connecting channels are no longer detectable.     

Location of cellulose and callose in pollen tubes and grains of Nicotiana tabacum

The distribution of cellulose and callose in the walls of pollen tubes and grains of Nicotiana tabacum L. was examined by electron microscopy using gold-labelled cellobiohydrolase for cellulose and a (1,3)-β-D-glucan-specific monoclonal antibody for callose. These probes provided the first direct evidence that cellulose co-locates with callose in the inner, electron-lucent layer of the pollen-tube wall, while both polymers are absent from the outer, fibrillar layer. Neither cellulose nor callose are present in the wall at the pollen-tube tip or in cytoplasmic vesicles. Cellulose is first detected approximately 5–15 μm behind the growing tube tip, just before a visible inner wall layer commences, whereas callose is first observed in the inner wall layer approximately 30 μm behind the tip. Callose was present throughout transverse plugs, whereas cellulose was most abundant towards the outer regions of these plugs. This same distribution of cellulose and callose was also observed in pollen-tube walls of N. alata Link et Otto, Brassica campestris L. and Lilium longiflorum Thunb. In pollen grains of N. tabacum, cellulose is present in the intine layer of the wall throughout germination, but no callose is present. Callose appears in grains by 4 h after germination, increasing in amount over at least the first 18 h, and is located at the interface between the intine and the plasma membrane. This differential distribution of cellulose and callose in both pollen tubes and grains has implications for the nature of the β-glucan biosynthetic machinery. Received: 20 February 1988 / Accepted: 25 March 1998