Cotton embryogenesis: The pollen cytoplasm

Summary The ultrastructure and composition of cotton (Gossypium hirsutum) pollen, exclusive of the wall, was examined immediately before and after germination. The pollen grain before germination consists of two parts: the outer layer and a central core. The outer layer contains large numbers of mitochondria and dictyosomes as well as endoplasmic reticulum (ER). The core contains units made of spherical pockets of ER which are lined with lipid droplets and filled with small vesicles; the ER is rich in protein and may contain carbohydrate while the vesicles are filled with carbohydrate. Starch-containing plastids are also present in the core as are small vacuoles. The cytoplasm of the pore regions contains many 0.5 spherical bodies containing carbohydrate. After germination the ER pockets open and the lipid droplets and small vesicles mix with the other portions of the cytoplasm. With germination the pore region becomes filled with mitochondria and small vesicles. The vegetative nucleus is large, extremely dense and contains invaginations filled with coils of ER. A greatly reduced nucleolus is present in the generative cell which is surrounded by a carbohydrate wall. The cytoplasm of the generative cell is dense and contains many ribosomes, a few dictyosomes and mitochondria, many vesicles of several sizes, and some ER. No plastids were identified. The generative nucleus is also dense with masses of DNA clumped near the nuclear membrane. An unusual tubular structure of unknown origin or function was observed in the generative cell.     

Cotton embryogenesis: The pollen tube in the stigma and style

Summary The ultrastructure and composition of the pollen tube of cotton (Gossypium hirsutum) growing in the tissues of the stigma and style of the flower were examined. The distal portion of the tube is densely cytoplasmic and contains the vegetative nucleus and the two sperms. The vegetative nucleus is highly convoluted and the membrane contains many pores and connections with the ER. No organized nucleolus is present but 4–6 membrane-bound, protein containing bodies are found in the nucleus. Mitochondria containing numerous cristae are abundant in the cytoplasm. Dictyosomes are also plentiful and are engaged in the production of many large vesicles. Rough ER is conspicuous and polysomes are found in the cytoplasm. Plastids are few in number, poorly developed, and contain little starch. Many uniform, small vesicles are found throughout the cytoplasm. Lipid bodies frequently with small vesicles associated with them are found in the tube. In the proximal region vacuoles form and the cytoplasm becomes pressed against the wall. In the transition zone the ER frequently becomes distended and filled with protein. The wall has two distinct layers: one strongly PAS positive, the other faintly PAS positive. The inner wall is apparently formed by the deposition of large dictyosome vesicles. Plug structure and development were studied.     

Cotton embryogenesis: The tissues of the stigma and style and their relation to the pollen tube

Summary The stigma of cotton (Gossypium hirsutum) is covered by unicellular hairs. The cytoplasm of these hairs degenerates before the stigma becomes receptive. The vacuole remains intact, but the hair cytoplasm becomes a mass of dark, amorphous material with only a few organelles still being visible. The rest of the stigma consists of thin-walled parenchyma cells with large vacuoles and large amounts of starch. The cells of the style are differentiated into a uniseriate epidermis, vascular tissue, a cortex of thin-walled, vacuolate parenchyma cells, and the transmitting tissue. This latter tissue occupies the center of the style and consists of thick-walled cells with few vacuoles. The cells are rich in starch, ribosomes, endoplasmic reticulum and dictyosomes. They also contain deposits of calcium salts in the form of druses. The pollen germinates on the stigmatic hairs, grows down the outside of the hair and between the cells of the stigma to the transmitting tissue of the style. There the tubes grow between the walls of the cells but do not enter the cells themselves. Some transmitting cells adjacent to the pollen tube degenerate after the tip of the pollen tube has grown past them. However, not all degenerate, and those that do show no fixed spatial relationship to one another. The cells which do degenerate follow a characteristic pattern of breakdown. No ultrastructural evidence was found for the secretion of hydrolytic enzymes by the pollen tube.     

Fate of sperm organelles during early embryogenesis in the rat

The report is part of a continuing study in which we employ monoclonal antibodies to membrane domains and internal organelles of rat spermatozoa in order to trace events during maturation, capacitation, fertilization, and early development. In the present study, we have used immunocytochemistry at the light and EM levels to localize one antibody, 5A5, to the fibrous sheath and a second, 3D5, to the outer mitochondrial membrane. Antibody 5A5 does not stain the fibrous sheath of spermatozoa of rodents other than the rat, while 3D5 can be localized to the outer mitochondrial membrane of rat, hamster, and mouse spermatozoa. In order to follow these antibodies during fertilization and early embryogenesis, we developed a method to stain internal components of zygotes and early embryos. Our findings suggests that the fibrous sheath disappears prior to the first cleavage and that mitochondria can be detected up to the 2-cell stage in mouse and the 4-cell stage in rat. © 1994 Wiley-Liss, Inc.     

Further evidence that sperm nuclear proteins are necessary for embryogenesis

We have recently presented evidence that the structural integrity of the mouse sperm nuclear matrix may be necessary for the proper unpackaging of sperm DNA for participation in embryogenesis. It is likely that the sperm nuclear matrix contributes to the organisation of the sperm DNA and its disturbance can seriously damage the paternal genome or its expression. In this work, we confirm our previous data and further suggest that even very subtle changes in the sperm nuclear structure may have a significant impact on embryo development. As reported previously, dithiothreitol (DTT) in the presence of an ionic detergent, ATAB, destabilized the nuclear matrix as measured by the halo assay, and oocytes injected with these nuclei failed to develop. We also discovered that omitting the protease inhibitor PMSF from the buffers used to extract spermatozoa prevented sperm injected into oocytes from participating in development. The organization of DNA into loop domains by the nuclear matrix in these nuclei appeared normal, as measured by the halo assay. Oocytes injected with sperm nuclei that had been washed with ATAB in the presence of phenylmethylsulphonyl fluoride (PMSF) but in the absence of DTT resulted in live births. Neither DTT treatment nor the absence of PMSF would be expected to disrupt the integrity of the paternal DNA. The data therefore suggest that even very subtle alterations in the structural proteins of the nucleus are enough to deprive sperm DNA of the ability to contribute to embryonic development.     

REVIEW ARTICLE: Zygotic embryogenesis versus somatic embryogenesis

This review will summarize molecular and genetic analyses aimedat identifying the mechanisms underlying the sequence of eventsduring plant zygotic embryogenesis. These events are being studiedin parallel with the histotogical and morphological analysesof somatic embryogenesis. The strength and limitations of somaticembryogenesis as a model system will be discussed briefly. Theformation of the zygotic embryo has been described in some detail,but the molecular mechanisms controlling the differentiationof the various cell types are not understood. In recent yearsplant molecular and genetic studies have led to the identificationand characterization of genes controlling the establishmentof polarity, tissue differentiation and elaboration of patternsduring embryo development. An investigation of the developmentalbasis of a number of mutant phenotypes has enabled the identificationof gene activities promoting (1) asymmetric cell division andpolarization leading to heterogeneous partitioning of the cytoplasmicdeterminants necessary for the initiation of embryogenesis (e.g.GNOM),(2) the determination of the apical-basal organization whichis established independently of the differentiation of the tissuesof the radial pattern elements (e.g.KNOLLE, FACKEL, ZWILLE),(3) the differentiation of meristems (e.g.SHOOT-MERISTEMLESS),and (4) the formation of a mature embryo characterized by theaccumulation of LEA and storage proteins. The accumulation ofthese two types of proteins is controlled by ABA-dependent regulatorymechanisms as shown using both ABA-deficient and ABA-insensitivemutants (e.g.ABA, ABI3). Both types of embryogenesis have beenstudied by different techniques and common features have beenidentified between them. In spite of the relative difficultyof identifying the original cells involved in the developmentalprocesses of somatic embryogenesis, common regulatory mechanismsare probably involved in the first stages up to the globularform. Signal molecules, such as growth regulators, have beenshown to play a role during development of both types of embryos.The most promising method for identifying regulatory mechanismsresponsible for the key events of embryogenesis willcome frommolecular and genetic analyses. The mutations already identifiedwill shed light on the nature of the genes that affect developmentalprocesses as well as elucidating the role of the various regulatorygenes that control plant embryogenesis. Key words: Development, marker, mutant, somatic embryogenesis, zygotic embryogenesis     

Capsella embryogenesis: The suspensor and the basal cell

Summary The suspensor and basal cell ofCapsella were examined with the electron microscope and analyzed by histochemical procedures. The suspensor cells are more vacuolate and contain more ER and dictyosomes, but fewer ribosomes and stain less intensely for protein and nucleic acids than the cells of the embryo. The end walls of the suspensor cells contain numerous plasmodesmata but there are no plasmodesmata in the walls separating the suspensor from the embryo sac. The lower suspensor cells fuse with the embryo sac wall and the lateral walls of the lower and middle suspensor cells produce finger-like projections into the endosperm. At the heart stage the suspensor cells begin to degenerate and gradually lose their ability to stain for protein and nucleic acids.The basal cell is highly vacuolate and enlarges to a size of 150 X 70. An extensive network of wall projections develops on the micropylar end wall and adjacent lateral wall. The nucleus becomes deeply lobed and suspended in a strand of cytoplasm traversing the large vacuole. The cytoplasmic matrix darkens at the late globular stage and histochemical staining for protein becomes very intense. The basal cell remains active after the suspensor cytoplasm has degenerated. It is proposed that the suspensor and basal cell function as an embryonic root in the absorption and translocation of nutriments from the integuments to the developing embryo.Research supported by NSF grant GB 3460 and NIH grant 5-RO 1-CA-03656-09.     

The diffuse endocrine system: from embryogenesis to carcinogenesis

In the present review we will summarise the current knowledge about the cells comprising the Diffuse Endocrine System (DES) in mammalian organs. We will describe the morphological, histochemical and functional traits of these cells in three major systems gastrointestinal, respiratory and prostatic. We will also focus on some aspects of their ontogeny and differentiation, as well as to their relevance in carcinogenesis, especially in neuroendocrine tumors. The first chapter describes the characteristics of DES cells and some of their specific biological and biochemical traits. The second chapter deals with DES in the gastrointestinal organs, with special reference to the new data on the differentiation mechanisms that leads to the appearance of endocrine cells from an undifferentiated stem cell. The third chapter is devoted to DES of the respiratory system and some aspects of its biological role, both, during development and adulthood. Neuroendocrine hyperplasia and neuroendocrine lung tumors are also addressed. Finally, the last chapter deals with the prostatic DES, discussing its probable functional role and its relevance in hormone-resistant prostatic carcinomas.     

Alisma embryogenesis: The development and ultrastructure of the suspensor

Summary The development of the suspensor (consisting of a basal cell and a few chalazal cells) inAlisma plantagoaquatica andA. lanceolatum was investigated using cytochemical methods, light and electron microscopy. The basal cell becomes differentiated during the first three days of embryo development. As a result of endopolyploidization the volume of the nucleus rapidly increases, as does the quantity of chromatin it contains and the size of the nucleolus. As basal cell grows, its cytoplasm increases in volume and the number of organelles increase, and wall ingrowths begin to form on the walls at the micropylar pole of the cell. The full development and functioning of the suspensor occurs during the next three days. The enormous basal cell then attains its maximum degree of differentiation: its nucleus reaches a ploidy of 256n or 512n, the micropylar transfer wall is fully developed, as is the cytoplasm, rich in proteins, ribonucleic acids (RNA) and organelles, particularly dictyosomes and long cisternae of the rough endoplasmic reticulum. The chalazal suspensor cells joining the embryo proper to the basal cell also become differentiated. In the seven-day embryo the suspensor begins to degenerate which coincides with the cellularization of the endosperm at the micropylar pole of the embryo sac. The senescence of the suspensor involves the degradation of the nucleus, increasing cytoplasmic vacuolization, and a distinct decrease in protein and RNA content, first in the basal cell, then in the chalazal suspensor cells. Analysis of the development and ultrastructure of the basal suspensor cell suggests that it plays the role of an active metabolic transfer cell, translocating nutrients from the maternal tissues via the chalazal suspensor cells to the growing embryo proper.     

Somatic embryogenesis in conifers: The role of carbohydrate metabolism

Summary Somatic embryogenesis represents a promising tool for mass propagation of elite genotypes of conifers. The efficiency of the technique strongly depends on cultivation conditions, with the exogenous saccharide supply being one of the most important factors. Different types and concentrations of saccharides have been empirically evaluated with respect to production of acceptable numbers and quality of somatic embryos for particular conifer species. Only a few recently published papers have focused on deeper studies of carbohydrate metabolism, enabling insight into the physiological background of the crucial effects of carbohydrates. Generally, saccharides are known to serve as carbon and energy sources, osmotic agents, stress protectants, and signal molecules in plants. This review collects and critically discusses the experimental data on exogenous saccharide supplies, resulting endogenous levels, and key enzyme activities obtained from the most thoroughly described genus Picea. In conclusion, it stresses the necessily to broaden the studies and consider the unltiple roles of saccharides during conifer somatic embryogenesis.     

Integrins: regulators of embryogenesis

Integrins are heterodimeric transmembrane glycoproteins involved in cell-cell and cell-extracellular matrix adhesion. They also participate in cytoskeletal rearrangements, co-regulation of growth factor activities and activation of signal transductions. This review describes experimental approaches that have given new insights into the integrin functions during embryogenesis. Using anti-functional antibodies, peptide inhibitors of integrin-ligand interactions and genetic ablation of integrins results, this review will show that integrins are key molecules during early development of both invertebrates and vertebrates.     

The sperm, a neuron with a tail: 'neuronal' receptors in mammalian sperm

A number of plasma membrane receptor types originally thought to be specific to neurons have been found in other somatic cells. More surprisingly, the mammalian sperm and neuron appear to share many of these 'neuronal' receptors. The morphology, chromosome number, genomic activity, and functions of those two cell types are as unlike as any two cells in the body, but they both achieve their highly disparate goals with the aid of a number of the same receptors. Exocytosis in neurons and sperm is essential to the functions of these cells and is strongly influenced by similar receptors. 'Neuronal' receptor types in sperm may also play a role in the control of sperm motility (a function of course not shared by neurons). This review will consider the evidence for the presence of sperm plasma membrane 'neuronal' receptors and for their significance to mammalian sperm function. The persuasiveness of the evidence varies depending on the receptor being considered, but there is strong experimental support for the presence and importance of a number of 'neuronal' receptors in sperm.     

Gamete evolution and sperm numbers: sperm competition versus sperm limitation

Both gamete competition and gamete limitation can generate anisogamy from ancestral isogamy, and both sperm competition (SC) and sperm limitation (SL) can increase sperm numbers. Here, we compare the marginal benefits due to these two components at any given population level of sperm production using the risk and intensity models in sperm economics. We show quite generally for the intensity model (where N males compete for each set of eggs) that however severe the degree of SL, if there is at least one competitor for fertilization (N − 1 ≥ 1), the marginal gains through SC exceed those for SL, provided that the relationship between the probability of fertilization (F) and increasing sperm numbers (x) is a concave function. In the risk model, as fertility F increases from 0 to 1.0, the threshold SC risk (the probability q that two males compete for fertilization) for SC to be the dominant force drops from 1.0 to 0. The gamete competition and gamete limitation theories for the evolution of anisogamy rely on very similar considerations: our results imply that gamete limitation could dominate only if ancestral reproduction took place in highly isolated, small spawning groups.