Pollen exine development precedes microtubule rearrangement inVigna unguiculata (Fabaceae): A model for pollen wall patterning

Summary Although patterns on pollen exines are highly conserved, heritable traits, there is no prevailing explanation for control of pattern development. InVigna unguiculata (Fabaceae), the exine reticulum is unusually coarse so that development of the reticulum can be followed by light microscopy. Developing exine patterns were compared with the arrangement of microtubules in the microspore using immunofluorescence labeling of microtubules. Exine pattern developed in microspores at stages with a regular microtubule pattern. At later stages of exine formation, microtubules were arranged in patches under the lumina of the reticulum. We conclude that microtubules do not determine exine pattern. The developing exine appears to rearrange microtubules. We interpret this as evidence for the selfpatterning of exine based on intrinsic properties of the matrix between the microspore and the callose wall.Abbreviations DIC differential interference contrast - ECM(s) extracellular matrix(ces) - MT(s) microtubule(s) - PBS phosphate buffered saline - SEM scanning electron microscopy     

Microspore and tapetal development in Echinodorus cordifolìus (Alismaceae)

In the microspore tetrad period the exine begins as rods that originate from the plasma membrane. These rods are exine units that on further development become columellae as well as part of the tectum, foot layer and “transitory endexine”. The primexine matrix is very thin in the future sites of the pores. At these sites the plasma membrane and its surface coating (glycocalyx) are without exine units and adjacent to the callose envelope. The exine around the aperture margin is characterized by units of reduced height. After the exine units and primexine matrix have become ca 0.2 μm in height a fibrillar zone forms under the aperture margin. It is the exine units around the aperture that are templates for exine processes on apertures of mature pollen. Oblique sections of the early exine show that the tectum consists of the distal portions of close-packed exine units. The exine enlarges in the free microspore period but initially its substructure (tectum, columellae, foot layer and transitory endexine) is not homogeneous and unit structures are visible until after the vacuolate microspore period. There are indications of a commissural line/plane (junction plane) which separates the foot layer from the endexine during early development. Our observations of development in Echinodorus pollen extend a growing number of reports of “transitory endexines” in monocot pollen. The exine unit-structures become 0.2 μm or more in diameter and many columellae are composed of only one exine unit. Spinules become exceptionally tall, many protruding ca 0.7 μm above the level of the tectum as units only ca 0.1 μm in diameter. The outer portion of the tectum fills in around spinules and by maturity they are microechinate with their bases spread out to ca 1 μm or more. Unit structures can be seen with SEM in mature pollen following oxidation by plasma ashing and in the tapetum these units are arranged both radially, as in spinules, and parallel with the tapetal surfaces. There are clear indications of such an arrangement of units in untreated fresh pollen. Units comprising the basal part of the exine are not completely fused by sporopollenin accumulated during development. This would seem to be a characteristic feature, based on published work, of the alismacean pollen. Our use of a tracer shows, however, that there is considerable space within or between exine structure of mature Echinodorus pollen. Based upon the ca 0.1 μm size of exine-units formed early in development and exine components seen after oxidative treatment it seems that the early (primary) accumulated sporopollenin has greater resistance to oxidation than sporopollenin added, secondarily, around and between units later in development. Both primarily and secondarily accumulated sporopollenin are resistant to acetolysis but published work indicates that acetolysis alters exine material. At the microspore tetrad time and until the vacuolate stages tapetal cells are arranged as in secretory tapetums. During early microspore stages there are orbicules at the inner surface of tapetal cells. At free microspore period tapetal cells greatly elongate into the loculus and surround the microspores. By the end of the microspore vacuolate period tapetal cells release their cellular contents and microspores are for a time enveloped by tapetal organelles and translocation material.     

Exine development: the importance of looking through a colloid chemistry ``window'

Most biological construction systems operate within the colloidal dimension. In view of this, it seems reasonable to reassess what is known of the early stages of exine development in the light of a brief excursion into colloid and micelle behaviour. The results of this analysis show remarkable similarity of structures and suggest that almost all of the features seen during early pollen wall development can be easily interpreted using simple, established colloidal principles. This study of exine framework and endexine development offers the possibility that growth of the early exine progresses by successive transitory mesophases of a constrained micellar system. The self-assembling micelle mesophases will all be clearly recognized as constituents of the developing exine. They include spherical, cylindrical, continuous layers of hexagonally-packed cylindrical units and lamellar mesophases which most probably correspond to future granules, columellae, complex columellar (and alveolar) microarchitecture and ``white-line-centred' lamellae. Furthermore, the various types of micelle involved have the potential to perform the functions previously loosely assigned to the exine.     

Low external pH replaces 2,4-D in maintaining and multiplying 2,4-D-initiated embryogenic cells of carrot

A mixed culture comprised of both embryonic globules and nonembryogenic callus. was derived from seedling hypocotyls of Daucus carota cv. Scarlet Nantes on 2,4-D-containing medium using well-established methods. Then the mixed cultures were transferred to, and serially subcultured on, a hormone-free medium near pH 4. The medium contained 1 m M NH+ as the sole nitrogen source. When cultured in this way, embryonic globules were able to multiply without development into later embryo stages Nonembryogenic callus did not survive. Continuous culture of embryonic globules on this low pH hormone-free medium yielded cultures consisting entirely of preglobular stage proembryos (PGSPs). PGSP cultures have been maintained as such with continuous multiplication for nearly 2 years without loss of embryogenic potential. These hormone-free-maintained PGSPs continue their development to later embryo stages when cultured on the same hormone-free medium buffered at pH 5.8. We show that hormone-free medium near pH 4 can replace 2.4-D in its ability to sustain multiplication of 2,4-D-initiated embryogenic cells of carrot at an acceptable growth rate without their development into later embryo stages. This procedure provides selective conditions that do not permit the growth of nonembryogenic cells while providing an adequate environment for embryogenic cell proliferation and should prove invaluable in studying habituation.     

Identification of embryogenic microspores of barley (Hordeum vulgare L.) by individual selection and culture and their potential for transformation by microinjection

Summary In order to identify microspores, suitable for transformation via microinjection of DNA, single microspores of barley (Hordeum vulgare L.) were selected after initial preculture of anthers floating on liquid media and analysed for their development in individual culture in microdroplets of culture medium. Conditions for microculture and plant regeneration from single selected embryogenie microspores were established. The technical feasability of intranuclear microinjection was demonstrated by injecting the fluorescent dye Lucifer Yellow. All essential procedures for a transformation system of barley based on microinjection into microspores have thus been performed successfully. Further efforts to increase efficiencies of culture and microinjection procedures are necessary, however, in order to improve the suitability of this approach towards transformation of barley.Abbreviations MES 2 (N-morpholino) ethanesulfonic acid - PEG polyethylene glycol     

Structural changes during early embryogenesis in wheat pollen

Summary We have made a detailed cytological examination of the development of wheat embryoids, monitoring their initial divisions from two to ten cells by both light and electron microscopy. According to our observations the first embryogenic division is symmetrical. After the androgenesis induction treatment, there is a decrease in ribosome population with cells that have inactive nucleoli made up almost exclusively of a dense fibrillar component. This population is restored after initial embryogenic divisions. During the initial divisions the embryogenic pollen grains do not appear to change in size and the pollen wall remains intact. The exine undergoes no modification but the intine thickens, and we have observed that the thickness of the intine can be used as a cytological marker of androgenesis. The walls separating the cells obtained after embryogenic division contained numerous plasmodesmata. The beginnings of embryo polarization and cell differentiation could be made out in the very early pollen embryoids.     

Effects of kanamycin on tissue culture and somatic embryogenesis in cotton

The aminoglycoside antibiotic kanamycin was evaluated for its effects on callus initiation from hypocotyl and cotyledon explants, proliferation of non-embryogenic and embryogenic calli, initiation and development of somatic embryos in cotton (Gossypium hirsutum L.). On this basis, the potential use of kanamycin as a selective agent in genetic transformation with the neomycin phosphotransferase II gene as the selective marker gene was evaluated. Cotton cotyledon and hypocotyl explants, and embryogenic calluses were highly sensitive to kanamycin. Kanamycin at 10 mg/L or higher concentrations reduced callus formation, with complete inhibition at 60 mg/L. Kanamycin inhibited embryogenic callus growth and proliferation, as well as the initiation and development of cotton somatic embryos. The sensitivity of embryogenic callus and somatic embryos to kanamycin was different during the initiation and development stages. Kanamycin was considered as a suitable selective agent for transformed callus formation and growth of non-embryogenic callus. Forty to sixty mg/L was the optimal kanamycin concentration for the induction and proliferation of transformed callus. The concentration of kanamycin must be increased (from 50 to 200 mg/L) for the selection of transformation embryogenic callus and somatic embryos. A scheme for selection of transgenic cotton plants when kanamycin is used as the selection agent is discussed.     

Extracellular matrix surface network of embryogenic units of friable maize callus contains arabinogalactan-proteins recognized by monoclonal antibody JIM4

Embryogenic units of friable maize callus are formed as globular or oblong packets of tightly associated meristematic cells. These units are surrounded by conspicuous cell walls visible in light microscopy after staining with basic fuchsin. Transmission electron microscopy revealed that embryogenic cells are rich in endoplasmic reticulum, polysomes and small protein bodies, and that the outermost layer of their cell walls is composed of fibrillar material. Electron microscopy has also shown that this material covers the surface of embryogenic cells as a distinct layer which we denote as extracellular matrix surface network (ECMSN). Employing histochemical staining with β-glucosyl Yariv phenylglycoside, we localized arabinogalactan-proteins (AGPs) to the outer cell walls of embryogenic units including ECMSN. The most prominent staining was found in cell-cell junction domains. Large non-embryogenic callus cells were not stained with this AGP-specific dye. Immunofluorescence and silver-enhanced immunogold labelling using monoclonal antibody JIM4 has shown that the ECMSN of embryogenic cells is equipped with JIM4 epitope, while non-embryogenic callus cells are devoid of this epitope. We propose that some specific AGPs of the ECMSN might be relevant for cell-cell adhesion and recognition of embryogenic cells during early embryogenic stages, and that the JIM4 antibody can serve as an early marker of embryogenic competence in maize callus culture. Received: 13 March 1998 / Revision received: 6 June 1998 / Accepted: 1 July 1998     

Ultrastructure of embryogenic pollen ofNicotiana tabacum var. Badischer burley

Summary Pollen grains capable of embryogenesis were selectively isolated from (a) near-mature buds from plants induced to flower in short days and low temperature (8 hours light and 18 °C) and (b) young buds from these plants with an additional low temperature treatment (10 °C for 10 days) and fixed for electron microscopy. The pollen from the former formed embryos at a very low frequency in culture, and at the subcellular level showed different degrees of regression of cytoplasm and mitochondria. On the contrary, cold-treated pollen were characterized by a high frequency of embryogenesis, up to 25% of the cultured pollen. They did not show regression of cytoplasm or organelles but had an attenuated cytoplasm which was not rich in ribosomes. Another noteworthy feature of embryogenic grains was the condensed nature of mitochondria. These characteristics of embryogenic grains indicate that they are repressed for gametophytic differentiation. The embryogenic pollen did not differentiate from gametophytic pollen which were very distinctive, having a thick exine, and dense cytoplasm rich in ribosomes. The close similarity of embryogenic grains with young microspores in terms of thin exine and sparse cytoplasm is suggestive of an indeterminate state and that determination into gametophytic or sporophytic (embryogenic) type is probably the function of differential gene activity. Of interest, in this context, is the condensation of mitochondria in embryogenic grains. The relationship, if any, between mitochondrial condensation and embryogenesis remains to be resolved.     

SPORE WALL DEVELOPMENT IN ANDREAEA (MUSCI: ANDREAEOPSIDA)

The spore wall of Andreaea rothii (Andreaeopsida) is unique among mosses studied by transmission electron microscopy. The exine of other mosses is typically initiated on trilaminar structures of near unit membrane dimensions just outside the plasma membrane. The exine of Andreaea is initiated in the absence of such structures as discrete globules within the coarsely fibrillar network of the sporocyte wall. The sequence of wall layer development, nevertheless, is essentially like that of other mosses. The intine is deposited within the exine and the perine accumulates on the surface of the exine during the latter stages of spore maturation. The mature spore is weakly trilete and inaperturate. The wall consists of three layers, the inner intine, the spongy exine consisting of loosely compacted irregular globules of sporopollenin, and an outer layer of perine. The perine differs ultrastructurally from the exine only in its greater degree of electron opacity. This ultrastructural evidence of departure from the fundamental pattern of exine development in mosses supports the taxonomic isolation of Andreaea from mosses of the Sphagnopsida and Bryopsida.     

Histological and Ultrastructural Observation Reveals Significant Cellular Differences between Agrobacterium Transformed Embryogenic and Non-embryogenic Calli of Cotton

Over the past few decades genetic engineering has been applied to improve cotton breeding. Agrobacterium medicated transformation is nowadays widely used as an efficient approach to introduce exogenous genes into cotton for genetically modified organisms. However, it still needs to be improved for better transformation efficiency and higher embryogenic callus induction ratios. To research further the difference of mechanisms for morphogenesis between embryogenic callus and non-embryogenic callus, we carried out a systematical study on the histological and cellular ultrastructure of Agrobacterium transformed calli. Results showed that the embryogenic callus developed nodule-like structures, which were formed by small, tightly packed, hemispherical cells. The surface of some embryogenic callus was covered with a flbrilar-like structure named extracellular matrix. The cells of embryogenic calli had similar morphological characteristics. Organelles of embryogenic callus cells were located near the nucleus, and chloroplasts degraded to proplastid-like structures with some starch grains, in contrast, the non-embryogenic calli were covered by oval or sphere cells or small clusters of cells. It was observed that cells had vacuolation of cytoplasm and plastids with a well organized endomembrane system. This study aims to understand the mechanisms of embryogenic callus morphogenesis and to improve the efficiency of cotton transformation in future.     

AN ULTRASTRUCTURAL AND STEREOLOGICAL ANALYSIS OF POLLEN GRAINS OF HYOSCYAMUS NIGER DURING NORMAL ONTOGENY AND INDUCED EMBRYOGENIC DEVELOPMENT

Selected nuclear and cytoplasmic changes of pollen grains of Hyoscyamus niger during normal gametophytic development and embryogenic development, induced by anther culture, were analyzed and compared ultrastructurally using stereological methods. Potentially embryogenic, uninucleate pollen could be identified within 6 hr of culture by an increased ratio of the volume density of the nucleolar granular zone to the volume density of the fibrillar zone and an increased ratio of dispersed to condensed chromatin in the nucleoplasm. Nonembryogenic pollen in vitro and in vivo possessed prominent nucleolar fibrillar zones and low ratios of dispersed to condensed chromatin. These differences may reflect changes in nuclear activity in potentially embryogenic pollen grains during early stages of culture. Following the first haploid mitosis, in potentially embryogenic pollen the generative cell maintained its large granular nucleolus and high ratio of dispersed to condensed chromatin through its first division to form a proembryoid. The volume fraction of the cytoplasm occupied by mitochondria and plastids and the area fraction occupied by RER and Golgi cisternae differed in the generative cells of potentially embryogenic and nonembryogenic pollen. Those changes only detected in generative cells of potentially embryogenic pollen include: increased area and complexity of cytoplasmic membranes, increased mitochondrial volume, and the presence of plastids at all stages of development. These results support the idea that embryogenic induction of H. niger takes place at the uninucleate stage of development and that subsequent nuclear and cytoplasmic changes are essential for continued sporophytic development.     

An integral insight into pollen wall development: involvement of physical processes in exine ontogeny in Calycanthus floridus L., with an experimental approach

We aimed to understand the underlying mechanisms of development in the sporopollenin-containing part of the pollen wall, the exine, one of the most complex cell walls in plants. Our hypothesis is that distinct physical processes, phase separation and micellar self-assembly, underpinexine development by taking the molecular building blocks, determined and synthesised by the genome, through several phase transitions. To test this hypothesis, we traced each stage of microspore development in Calycanthus floridus with transmission electron microscopy and then generated in vitro experimental simulations corresponding to every developmental stage. The sequence of structures observed within the periplasmic space around developing microspores starts with spherical units, which are rearranged into columns to then form rod-like units (the young columellae) and, finally, white line centred endexine lamellae. Phase separation precedes each developmental stage. The set of experimental simulations, obtained as self-assembled micellar mesophases formed at the interface between lipid and water compartments, was the same: spherical micelles; columns of spherical micelles; cylindrical micelles; and laminate micelles, separated by gaps, resembling white-lined lamellae. Thus, patterns simulating structures observed at the main stages of exine development in C. floridus were obtained from in vitro experiments, and hence purely physicochemical processes can construct exine-like patterns. This highlights the important part played by physical processes that are not under direct genomic control and share influence on the emerging ultrastructure with the genome during exine development. These findings suggest that a new approach to ontogenetic studies, including a consideration of physical factors, is required for a better understanding of developmental processes.     

Formation and development of the tapetal periplasmodium inTradescantia bracteata

Summary The formation of the tapetal periplasmodium inTradescantia bracteata is described at the electron microscope level and methods are given for the preparation of material. Evidence, both fine-structural and cytochemical, is presented in support of the view that the tapetal periplasmodium inTradescantia posesses an organized, functional ultrastructure. The changes which occur after dissolution of the tapetal walls appear to be a reorganization rather than a degeneration. The observation that tapetal membranes penetrate the exine during the later stages of pollen development suggests that a physical association may develop between the cytoplasm of the male gametophyte and that of the sporophyte.     

EXINE PATTERN FORMATION BY PLASMA MEMBRANE IN BOUGAINVILLEA SPECTABILIS WILLD. (NYCTAGINACEAE)

Transmission and scanning electron microscopy of exine development in Bougainvillea spectabilis (Nyctaginaceae) confirmed that the exine pattern is initiated by invagination of the microspore plasma membrane at the early tetrad stage. Invaginated plasma membranes take the form of a reticulate pattern that corresponds to the mature exine tectum. Protectum is the first exine layer to be deposited on the reticulate-patterned plasma membrane. Subsequently, probacules elongate basally on protruding sites of the plasma membrane under the protectum and in the lumina. These sites retreat as the probacules elongate. After the dissolution of the callose wall, a foot layer forms through the accumulation of lamellated structures. Clearly, the plasma membrane serves a determinative role in the initial pattern formation of exine.     

High efficiency germ-line transformation of mosquitoes

The ability to manipulate the mosquito genome through germ-line transformation provides us with a powerful tool for investigating gene structure and function. It is also a valuable method for the development of novel approaches to combating the spread of mosquito-vectored diseases. To date, germ-line transformation has been demonstrated in several mosquito species. Transgenes are introduced into pre-blastocyst mosquito embryos using microinjection techniques that take a few hours, and progeny are screened for the presence of a marker gene. The microinjection protocol presented here can be applied to most mosquitoes and contains several improvements over other published methods that increase the survival of injected embryos and, therefore, the number of transformants. Transgenic lines can be established in approximately 1 month using this technique.     

Biogenesis and function of the lipidic structures of pollen grains

 Pollen grains contain several lipidic structures, which play a key role in their development as male gametophytes. The elaborate extracellular pollen wall, the exine, is largely formed from acyl lipid and phenylpropanoid precursors, which together form the exceptionally stable biopolymer sporopollenin. An additional extracellular lipidic matrix, the pollen coat, which is particularly prominent in entomophilous plants, covers the interstices of the exine and has many important functions in pollen dispersal and pollen-stigma recognition. The sporopollenin and pollen coat precursors are both synthesised in the tapetum under the control of the sporophytic genome, but at different stages of development. Pollen grains also contain two major intracellular lipidic structures, namely storage oil bodies and an extensive membrane network. These intracellular lipids are synthesised in the vegetative cell of the pollen grain under the control of the gametophytic genome. Over the past few years there has been significant progress in elucidating the composition, biogenesis and function of these important pollen structures. The purpose of this review is to describe these recent advances within the historical context of research into pollen development. Received: 1 November 1997 / Revision accepted: 3 February 1998     

The expression of tissue inhibitor of metalloproteinase 2 (TIMP-2) is required for normal development of zebrafish embryos

MMP activities are controlled by a combination of proteolytic pro-enzyme activation steps and inhibition by endogenous inhibitors like alpha2-macroglobulin and the tissue inhibitors of metalloproteinases (TIMPs). TIMPs are the key inhibitors in tissue. The expression of both MMPs and TIMPs is controlled during tissue remodeling to maintain a balance in the turnover of extracellular matrix. Disruption of this balance may result in a broad spectrum of diseases. Additionally, TIMP-2 has been reported to have growth factor activities. To further study the function of TIMP-2 in development, we utilized zebrafish as an experimental model system. We have successfully isolated a TIMP-2 homologue from zebrafish (zTIMP-2). This zebrafish TIMP-2 showed high similarity to human TIMP-2 with all critical features conserved. Whole-mount in situ analysis showed that zTIMP-2 was expressed as early as the one-cell stage indicating a maternal origin. This expression continued through later stages of development. RT-PCR analysis confirmed the early expression pattern from the 16-cell stage through blastula, gastrula and 24-h stages. In addition, at the protein level, immunoreactive zTIMP-2 was detected using antibody against recombinant human TIMP-2. RFP-reporter analysis indicated that TIMP-2 can be secreted into the extracellular space where ECM is forming. Functional studies showed that the balance of TIMP-2 expression is important to normal development as reflected by the fact that both blockage of TIMP-2 translation using antisense morpholino oligonculeotides or increased translation of TIMP-2 using a mRNA microinjection approach resulted in abnormal zebrafish development. This is in contrast to murine knockout studies that indicate that TIMP-2 does not have a major role in mouse embryogenesis.     

Quantitative determination of gap junction intercellular communication using flow cytometric measurement of fluorescent dye transfer

Gap junction intercellular communication (GJIC) is involved in several aspects of normal cell behaviour, and disturbances in this type of communication have been associated with many pathological conditions. Reliable and accurate methods for the determination of GJIC are therefore important in studies of cell biology. (Tomasetto, C., Neveu, M.J., Daley, J., Horan, P.K. and Sager, R. (1993) Journal of Cell Biology, 122, 157-167) reported some years ago the use of flow cytometer to determine transfer between cells of a mobile dye, calcein, as a measure of cell communication through gap junctions. In spite of this being a method with potential for quantitative and reliable determination of GJIC, it has been modestly used, possibly due to technical difficulties. In the present work we have illustrated several ways to use flow cytometric data to express cell communication through gap junctions. The recipient cells were pre-stained with the permanent lipophilic dye PKH26, and the donor cell population were loaded with the gap junction permeable dye, calcein. We show that the method may be used to measure the effect of chemicals on GJIC, and that the information is reliable, objective and reproducible due to the large number of cells studied. The data may give additional information to that obtained with other methods, since the effect observed will be on the establishment of cell communication as compared to what is observed for microinjection or scrape loading, where the effect is on already established communication. This is probably the reason for the more potent effects of DMSO on GJIC measured by the present method than on already existing GJIC measured by microinjection or quantitative scrape loading. We also show that the problem related to the mobile dye calcein not being fixable with aldehydes will not affect the results as long as the cells are kept on ice in the dark and analysed by flow cytometer within the first hours after formalin cell fixation.