ULTRASTRUCTURE AND INITIATION OF WALL PATTERN IN PEDIASTRUM BORYANUM

The reticulate pattern in the wall of Pediastrum boryanum emerges rapidly during wall formation following aggregation of the swarming zoospores to form the coenobium. Electron micrographs during colony formation show that microtubules, present during the motile phase and aggregation, are gone prior to wall formation and probably do not participate in wall pattern regulation. A single dictyosome lies adjacent to the nucleus and from blebs of the nuclear membrane receives vesicles at its forming face. Vesicles formed at the maturing face have not been observed to contribute to the cell wall. Electron-lucent patches occur in the plasma membrane prior to wall formation. The first indication of a reticulate pattern in wall development is the deposition on the plasma membrane of interconnected plaques of outer wall material at the corners of hexagons. The sites of the plaques may correspond to clusters of ribosomes on endoplasmic reticulum underlying the plasmalemma. Following completion of the outer wall the thicker inner wall layer is deposited and within it the reticulate pattern of ridges is soon evident in tangential sections as strips of greater electron density. It is suggested that the pattern of the wall is templated by the plasma membrane.     

Pattern formation and the fine structure of the developing cell wall in colonies of Pediastrum boryanum

A single-layered disc of peripheral pronged cells and central prongless cells impart the typical gear shape to colonies of Pediastrum, while the walls of each cell have a characteristic reticulate triangular pattern. The two-layered wall forms in the cells during colony formation following zoospore aggregation and adhesion. The uniformly thin outer layer reflects contours resulting from differential thickening in the reticulate pattern of the inner, thicker, more fibrillar and granular wall layer. The reticulate pattern thus imparted to the outer wall layer persists in empty zoosporangia following the release of zoospores. Columns of electron-dense material extend through the outer wall layer except at the ridges and centers of the reticulum. Following mitosis and cleavage, the resulting zoospores are extruded within a vesicle membrane consisting of the inner wall layer. Separation of this membrane from the parent cell occurs in material of the inner layer adjacent to the outer wall. Vesicles containing swarming zoospores also contain a granular material which appears to become associated with the aggregating and adhering cells of new colonies. Microtubules occur in zoospores prior to adherence but are absent during wall deposition.     

MITOSIS,CYTOKINESIS, AND COLONY FORMATION IN THE GREEN ALGA SORASTRUM1

Synchronous mitotic divisions produce multi-nucleate cells of Sorastrum. Perinuclear envelopes of endoplasmic reticulum and a virtually intact nuclear envelope enclose mitotic nuclei. Cytoplasmic cleavage, which shirts before the last round of Synchronous mitoses, gives rise to uninucleate fragments which differentiate to form zoospores. These zoospores are released into a spherical vesicle, presumably derived from the inner layer of the parental cell wall, in which they swarm actively before aggregating as a spherical colony. The roughly conical shaped zoospores apparently adhere laterally before withdrawing their flagella and extending horns and a stipe, which, following wall deposition, interconnects the cells at the center of the colony. The probable role of the microtubules, which underlie the plasmalemma of aggregating cells, in determining the shape of both the cells and the colony itself is discussed.     

The Golgi apparatus,zoosporogenesis, and development of the zoospore discharge apparatus ofChytridium confervae

C. confervae is a eucarpic, monocentric chytrid that has been cultured synchronously (L. P. Gauriloff and M. S. Fuller, 1979,Exp. Mycol.3: 3–5). In this study we use light and electron microscopy to examine the development of zoospores and the discharge apparatus, focusing on the multiple roles of the Golgi apparatus. The Golgi apparatus produces, in succession, vesicles with electron-opaque cores that may function in cell wall formation, secretory vesicles that form the extracellular lenticular deposit of the discharge apparatus, cleavage vesicles that fuse to form the plasma membranes of the developing zoospores, and vesicles that contain cell coat material for the zoospores. The discharge apparatus consists of the operculum (a circle of sporangial wall delimited from the rest of the wall), the lenticular deposit, and an outer layer found between the lens and the operculum. At discharge, the operculum dehisces, the outer layer ruptures, and the lenticular deposit expands to form a vesicle that constrains the zoospores. The outer layer provides the mechanical connection between the wall and the vesicle. Comparison of discharge apparatus development with other Chytridiomycetes suggests that the order of the developmental steps leading to discharge may be as important to chytrid taxonomy as the steps themselves.     

THE ULTRASTRUCTURE OF CARPOSPOROGENESIS IN CALOGLOSSA LEPRIEURII (DELESSERIACEAE,CERAMIALES)

Carposporogenesis in Caloglossa leprieurii is divided into three cytological stages. At stage I, the young spores have few plastids and little starch. Abundant dictyosomes secrete a gelatinous wall layer in scale-like units. At stage II, dictyosomes produce a second fibrillar wall component in addition to the gelatinous constituent. Large fibrillar vesicles accumulate in the cytoplasm. Production of gelatinous material decreases in this stage. By stage III, starch grains and fully developed plastids are abundant. Rough endoplasmic reticulum occupies much of the peripheral cytoplasm. A dense, granular proteinaceous component appears in the wall in association with the fibrillar layer. Arrays of randomly oriented tubules are scattered in the cytoplasm. The mature carpospore is surrounded by an outer gelatinous wall layer and an inner fibrillar layer. Few dictyosomes persist in the mature spore. Carposporogenesis in Caloglossa is compared with that in other red algae.     

AN ULTRASTRUCTURAL STUDY OF SPORE WALL MORPHOGENESIS IN EQUISETUM ARVENSE

Spore wall morphogenesis of Equisetum arvense was observed by transmission electron microscopy. The spore wall of E. arvense consists of four layers: intine, exine, middle layer, and elater. The exine is formed after meiosis and consists of two distinct layers. The inner portion of the exine is formed in advance of the outer layer of the exine. The middle layer is deposited after the exine. The elater can be subdivided into two distinct layers. The inner layer comprises longitudinal microfibrils that surround the spore in spiral fashion. The elater appears as thin beltlike structures at the beginning of development. Numerous microtubules were observed on the inner surface of the plasmodial plasma membrane opposite the inner layer of the elater, suggesting that these microtubules are involved with the synthesis of inner elater microfibrils. The matrix of the outer elater is formed by discharge of granules from the plasmodial cytoplasm. The intine is the last component of the sporoderm to be formed.     

TWO TYPES OF CYTOPLASMIC CLEAVAGE IN THE COENOCYTIC SOIL ALGA PROTOSIPHON BOTRYOIDES (CHLOROPHYCEAE)1

Cytokinesis in the coenocytic green alga Protosiphon botryoides (Kütz.) Klebs was studied with transmission electron microscopy. In vegetative cells, nuclei with associated basal bodies and dictyosomes are scattered throughout the cytoplasm. Mature cells may develop either multinucleate resting spores (coenocysts) or uninucleate zoospores. Cytokinesis may be preceded by contraction of the protoplast due to the disintegration of vacuoles that are present in larger, siphonous cells. The formation of coenocysts in ageing, siphonous cells, is signalled by cleavage of the chloroplast and the development of arrays of phycoplast microtubules in one or more transversely oriented planes through the cell. Nuclei with associated basal apparatuses stay dispersed throughout the cytoplasm; the basal bodies apparently are not involved in organization of the phycoplast. The plasma membrane invaginates, resulting in a centripetal cleavage of the protoplast into two or more multinucleate daughter protoplasts. Simultaneously, wall material is deposited along the outside of the daughter protoplasts by dictyosome-derived vesicles, and finally two or more thick-walled coenocysts are formed. The formation of zoospores, on the other hand, is signalled by clustering of the nuclei in one or more groups depending on the shape of the mother cell. The nuclei become arranged with the associated basal apparatuses facing toward the center of the cluster. Bundles of phycoplast microtubules develop between the nuclei, radiating from the center of a cluster toward the plasma membrane; basal apparatuses or associated structures apparently are involved in organization of the phycoplast. Cleavage furrows grow out centrifugally along these bundles of micro-tubules, fed by dictyosome-derived vesicles. No wall material is deposited. An additional mitotic division occurs during cleavage, and finally numerous uninucleate, wall-less, biflagellate zoospores are formed. The ultrastructural features of the two different types of cytoplasmic cleavage associated with two different types of daughter cells have not previously been reported for chlorophycean algae.     

FEEDING APPARATUS OF THE COLORLESS FLAGELLATE KATABLEPHARIS (CRYPTOPHYCEAE)1

The feeding apparatus of Kalablepharis ovalis (isolated from a freshwater impoundment in Colorado) and Katablepharis clone G-2 (isolated from the littoral of the Black Sea near Yalta in the Crimea) consists of inner and outer oval-shaped arrays of microtubules that begin at the anterior end of the cell and pass into the posterior of the cell. Each array of microtubules contains groups of microtubules with two to eight microtubules per group depending on the position of the array in the cell. A specialized area of the plasma membrane, the mouth, occurs at the anterior end of the cell. The mouth is oval with the long axis oriented dorsoventrally and consists of a raised ridge surrounding a central depression. The anterior end of the microtubules of the inner and outer arrays supports the raised ridge of the mouth. In freeze-fracture replicas, the protoplasmic face of the plasma membrane contains intramembrane particles on the raised ridge of the mouth. Three small membrane-cisternae occur on the protoplasmic side of the plasma membrane in the area of the mouth. Katablepharis clone G-2 also has five or six additional large membrane-cisternae associated with the inner microtubular array in the anterior portion of the cell. These larger membrane-cisternae do not occur in K. ovalis. Vesicles with electron-dense contents occur in association with the microtubular arrays. Katablepharis ovalis has a second type of vesicle containing a single-membrane profile associated with the microtubule arrays. The structure of the microtubular arrays in Katablepharis is compared with similar structures in suctorian ciliates and dinoflagellates.     

Surface architecture of the plant cell: Biogenesis of the cell wall,with special emphasis on the role of the plasma membrane in cellulose biosynthesis

Cell wall structure and biogenesis in the unicellular green alga, Oocystis apiculata, is described. The wall consists of an outer amourphous primary layer and an inner secondary layer of highly organized cellulosic microfibrils. The primary wall is deposited immediately after cytokinesis. Golgi-derived products contribute to this layer. Cortical microtubules underlie the plasma membrane immediately before and during primary wall formation. They function in maintaining the elliptical cell shape. Following primary wall synthesis, Golgi-derived materials accumulate on the cell surface to form the periplasmic layer. This layer functions in the deposition of coating and cross-linking substances which associate with cellulosic microfibrils of the incipient secondary wall. Secondary wall microfibrils are assembled in association with the plasma membrane. Freeze-etch preparations of untreated, living cells reveal linear terminal complexes in association with growing cellulosic microfibrils. These complexes are embedded in the EF fracture face of the plasma membrane. The newly synthesized microfibril lies in a groove of the outer leaflet of the plasma membrane. The groove is decorated on the EF fracture face by perpendicular structures termed “ridges.” The ridges interlink with definitive rows of particles associated with the PF fracture face of the inner leaflet of the plasma membrane. These particles are termed “granule bands,” and they function in the orientation of the newly synthesized microfibrils. Microfibril development in relation to a coordinated multienzyme complex is discussed. The process of cell wall biogenesis in Oocystis is compared to that in higher plants.     

AN AUTORADIOGRAPHIC AND HISTOCHEMICAL LOCALIZATION OF SULFATED POLYSACCHARIDES IN EUCHEUMA NUDUM (RHODOPHYTA)1

The predominant sulfated polysaccharide, ?-carrageenan, was localized in the middle lamella of epidermal, cortical and medullary cells of Eucheumanudum J. Agardh. Autoradiographic studies with ³⁵SO₄= indicated that the label was first incorporated in the inner wall and ultimately deposited in the middle lamella of all cells, and in an outer wall layer of the epidermal cells. There was no evidence for cytoplasmic incorporation of the label. The middle lamella stained with alcian blue, was γ-metachromatic with toluidina blue O and bound diaminobenzidine-osmium tetroxide. This region was also positive with periodic acid-Schiff's (PAS) ragent, possibly demonstrating cellulose and/or a nonsulfated precursor of ?-carrageenan. A proposed model for extracellular sulfation includes production and secretion of a nonsulfated polygalactan and sulfotransferase enzyme(s) by the golgi apparatus and endoplasmic reticulum, respectively. Free sulfate in the wall would be bound to the precursor polysaccharide, with much of the resulting carrageenan migrating to the middle lamella facilitating mutual cell growth.     

ROLE OF DICTYOSOMES IN WALL FORMATION DURING CELL DIVISION OF CHLORELLA VULGARIS

The behavior of dictyosomes in wall formation during cell division of Chlorella vulgaris follows a definite pattern. During formation of the partition membrane they migrate into the equatorial plane and pair. There is a close spatial relationship between the dictyosomes and the partition membrane which, itself, may be derived from the fusion of dictyosomal vesicles. Dictyosomes also may participate significantly in the deposition of new wall material.     

CYTOCHALASIN B INFLUENCES DICTYOSOMAL VESICLE PRODUCTION AND MORPHOGENESIS IN THE DESMID EUASTRUM1

Cytochalasin B (CB) applied to young developing cells of the desmid Euastrum oblongum Ralfs ex Ralfs, at concentrations that do not entirely inhibit cytoplasmic streaming, retarded cell growth and caused malformations of cell shape. While the basic symmetry of the cell was maintained, only the first indentations were formed and the cell body appeared to be swollen. Electron microscopic investigations revealed that vesicle production at the dictyosomes was disturbed by cytochalasin. In contrast to untreated control cells, where vesicles with electron-dense contents (“dark vesicles”) were formed during primary wall formation, vesicles pinched off by the dictyosomes during CB treatment exhibited an “empty” appearance. These vesicles, which correspond to the “dark vesicles” in size, were accumulated around the dictyosomes without being transported to the plasma membrane and were frequently connected to the trans-cisternae of the Golgi bodies. We speculate that CB may influence the transfer of products from the endoplasmic reticulum (ER) to the dictyosomes via transition vesicles, which results in a disturbed vesicle production at the Golgi bodies. CB also causes a shift in ER and dictyosome distribution. Moreover, a cortical actin system appears to be involved in the cell shaping of Euastrum. The arrangement of microtubules around the nucleus is not affected by the drug.     

Morphology of <Emphasis Type="Italic">Mastigamoeba aspera</Emphasis> schulze, 1875 (Archamoebae,Pelobiontida)

The morphology of Mastigamoeba aspera, a typical species of the genus Mastigamoeba Schulze, 1875, was studied at the optical and electron microscopy level. During movement, M. aspera has an oval or pyriformic shape, with the motile flagella being located at the anterior end of mononuclear forms. In the process of movement, the mastigamoeba surface forms numerous conical or finger-shaped hyaline pseudopodia, whereas thel caudal cell end is usually transformed into a bulboid uroid. In M. aspera micropopulations, there are noted both mononuclear cells with flagella and multinuclear flagella-free individuals. The M. aspera plasma membrane has at its outer surface a hypertrophied glycocalix layer inhabited by numerous rod-shaped bacteria-ectobionts. The M. aspera nucleus is of vesicular type, with a large central spherical nucleolus. The flagellar apparatus is closely connected morphologically with the M. aspera nucleus. The basal flagella part is represented by a single kinetosome, from which radial microtubules and a lateral rootlet pass out into the cytoplasm. At the base of the kinetosome, there is located a compact center of organization of microtubules (COMT), in which there are immersed bases of the nuclear cone microtubules participating in formation of karyomastigont. The structure of the flagella axoneme corresponds to the formula 9(2)+2. The main volume of the M. aspera cytoplasm is occupied with digestive vacuoles. In addition, the cells contain numerous light-reflecting granules, as well as glycogen granules. Mitochondria, dictyosomes of the Golgi apparatus, and microbodies in the M. aspera cell cytoplasm are not revealed.     

ULTRASTRUCTURE OF TETRASPOROGENESIS IN THE PARASITIC RED ALGA LEVRINGIELLA GARDNERI (SETCHELL) KYLIN12

Ultrastructural studies on tetraspore formation in Levringiella gardneri revealed that 3 stages may be recognized during their formation. The youngest stage consists of a uninucleate tetraspore mother cell with synaptonemal complexes present during early prophase of meiosis I. Mitochondria are aggregated around the nucleus, dictyosome activity is low, and chloroplasts occur in the peripheral cytoplasm. A 4-nucleate tetraspore mother cell is formed prior to tetrahedral cell cleavage, and an increase in the number of chloroplasts and mitochondria occurs. Small straight-profiled dictyosomes secrete vesicles into larger fibrous vesicles or contribute material to the developing tetraspore wall. During the second stage of tetraspore formation, striated vesicles form within endoplasmic reticulum, semicircular profiled dictyosomes secrete vesicles for fibrous vesicles or wall material, and starch formation increases. The final stage is characterized by the disappearance of striated vesicles, presence of straight, large dictyosomes which secrete cored vesicles, and an abundance of starch grains. Cleavage is usually complete at this stage and the tetraspore wall consists of a narrow outer layer of fibrillar material and an inner, electron transparent layer. These spores are surrounded by a tetrasporangial wall which was the original wall surrounding the tetraspore mother cell.     

FINE STRUCTURE OF ZOOSPOROGENESIS, ZOOSPORE GERMINATION, AND EARLY GAMETOPHYTE DEVELOPMENT IN CLADOPHORA SURERA (CLADOPHORALES, CHLOROPHYTA)

The fine structure of zoosporogenesis, zoospore germination, and early gametophyte development in Cladophora surera Parodi et Cáceres were studied. Zoosporogenesis started with simultaneous meiosis in all nuclei of apical initial cells. The resulting haploid nuclei duplicated in turn by successive centric, closed mitoses. Then, each initial cell divided into two short zoosporangia. Numerous vacuoles appeared around each sporic nucleus. The delimitation of uninucleate zoosporocytes occurred by cytokinetic furrows produced by the coalescence of tiny, clear vesicles, without microtubules. Final shape of the zoospore resulted from gradual expulsion of vacuoles from the cell body. Mature biflagellate zoospores exhibited a conspicuous apical papilla containing fine granular globules, the basal apparatus, and a microtubular "umbrella" formed by numerous cortical microtubules that ran backward the length of the cell body. The chloroplast showed a conspicuous eyespot. The zoosporangial wall disorganized at the pore through which the zoospores were liberated. Zoospores settled on a substrate by their anterior papilla secreting an adhesive. Germination involved retraction of the apical papilla, loss of the "umbrella" microtubules and eyespot, and the lateral absorption of the entire flagellar apparatus, i.e. basal apparatus plus axoneme, into the cytoplasm. Early gametophyte development involved the synthesis of a thin, young cell wall, the development of outer peripheral vacuoles, the appearance of the marginal reticulate chloroplast, and the formation of the first central vacuoles derived from abundant endoplasmic reticulum. Close to the plasmalemma ran longitudinally oriented cortical microtubules. Eventually, the germling developed an achlorophylic, elongated rhizoidal portion.     

STRUCTURE AND COMPOSITION OF THE RESISTANT SPORANGIAL WALL IN THE FUNGUS ALLOMYCES

The fine structure and chemical composition of the wall of resistant sporangia of Allomyces neo-moniliformis were investigated. Studies with the electron microscope showed that the wall is approximately 1.3 μ in thickness and is of complex construction. It consists essentially of three parts: a five-layered outer wall, two layers of “cementing substances,” and a single-layered inner wall. The presence of a highly convoluted cell membrane was also demonstrated. Six structural components were found to make up the walls of the resistant sporangia: glucose, glucosamine, chitin, melanin, protein, and lipids. Comparison of the structure and composition of the walls of resistant sporangia with the walls of hyphae and zoospores of Allomyces as reported by other investigators showed that, while the structure is very different, the composition is quite similar with only melanin and lipids apparently being absent from the zoospore and hyphal walls.     

KATABLEPHARIS OVALIS,A COLORLESS FLAGELLATE WITH INTERESTING CYTOLOGICAL CHARACTERISTICS1

Katablepharis ovalis Skuja, isolated from an impoundment in Colorado, has a cell covering composed of two layers over the cell body and flagella. The outer component of the cell covering contains 25-nm-diameter hexagonal scales arranged in rows. The inner component of the cell covering is composed of a layer of interwoven microfibrils. The inner component of the cell covering is joined to the plasma membrane by one or more attachment strips that always occur outside, and along, one of the microtubular groups of the outer array. The attachment strips resemble hemidesmosomes and are composed of rows of electron-dense material, 12 nm apart, that protrude through the plasma membrane into the extracellular space, to attach to the inner wall. The two flagella are inserted subapically into a raised area of the cell. The flagella do not have any fibrillar or tubular hairs and are covered only by the two-layered cell covering. The cell has an inner and outer array of microtubules, both of which are spindle-shaped, arising at the anterior end of the cell and continuing into the posterior end of the cell. A single large Golgi apparatus occurs in the anterior cytoplasm. The nucleus is in the center of the cell. Two rows of large ejectisomes occur posterior to the area of flagellar attachment. Smaller ejectisomes occur under the plasma membrane in the posterior and medial areas of the cell. Each ejectisome is composed of a single body containing a spirally wound, tapered ribbon. On discharge, the ejectisome ribbon rolls inward, creating a tubular structure. The possible relationship between Katablepharis, the green algae, and the cryptophytes is discussed.     

The Structure of the Canal Cell in the Style of Lilium regale

The fine structure of canal cell in the style of Lilium regale has been observed under light and electron microscopes by OMA thin section method and ultra-thin section method respectively. The ultrastructural specialization of the canal cells during their functional stages may be characterized as follows: 1. The cell wall on the secretory face of the canal cell has numerous branched ingrowths extending into the cytoplasm, and the plasmalemma closely follows the contours of the ingrowths to form the wall-membrane apparatus. This pattern of distribution of plasmalemma increases the surface-volume ratio of the cell to facilitate the secretion of solutes out of the cell. 2. The cell wall under the thin layer of cuticle on the outside of the secretory face is digested starting from the outer part and gradually extending to the inner part to form a large space, the temporary secretory layer. During the secretion of products by the cell, the thin layer of cuticle becomes ruptured in many places and finally disappeared. Therefore the cell wall of the secretory face remains a thin layer only at that time. The change of the layers of the cell wall is involved in the mechanism of cell secretion. 3. The ultrastructural characteristics of the canal cell indicate that this cell is active in synthesis, intercellular transport and energyn metabolism. Some of the major facts seen in all cases included the highly lobing of nucleus, abundance of endoplasmie reticulum throughout the cytoplasm and well developed mitochondria, dictyosomes and polysomes. During the secretory stage of the cell, mitochondria apparently concentrate near the wall-membrane apparatus. 4. There are numerous granular and vesicular structures near the wall-membrane apparatus on the secretory face, especially at the space between wall ingrowths and plasmalemma. The presence of these granular and vesicular structures is thought to be related to the secretory function of the cell. According to the specialized characteristics the canal cell is evidently a typical transfer cell of the secretory type.     

ULTRASTRUCTURE OF DISPERSED AND IN SITU SPECIMENS OF THE DEVONIAN SPORE RHABDOSPORITES LANGII: EVIDENCE FOR THE EVOLUTIONARY RELATIONSHIPS OF PROGYMNOSPERMS

Abstract: The spore Rhabdosporites (Triletes) langii (Eisenack) Richardson, 1960 is abundant and well preserved in Middle Devonian (Eifelian) ‘Middle Old Red Sandstone’ deposits from the Orcadian Basin, Scotland. Here it occurs as dispersed individual spores and in situ in isolated sporangia. This paper reports on a detailed light microscope (LM), scanning electron microscope (SEM) and transmission electron microscope (TEM) analysis of both dispersed and in situ spores. The dispersed spores are pseudosaccate with a thick walled inner body enclosed within an outer layer that was originally attached only over the proximal face. The inner body has lamellate/laminate ultrastructure consisting of fine lamellae that are continuous around the spore and parallel stacked. Towards the outer part of the inner body these group to form thicker laminate structures that are also continuous and parallel stacked. The outer layer has spongy ultrastructure. In situ spores preserved in the isolated sporangia are identical to the dispersed forms in terms of morphology, gross structure and wall ultrastructure. The sporangium wall is two‐layered. A thick coalified outer layer is cellular and represents the main sporangium wall. This layer is readily lost if oxidation is applied during processing. A thin inner layer is interpreted as a peritapetal membrane. This layer survives oxidation as a tightly adherent membranous covering of the spore mass. Ultrastructurally it consists of three layers, with the innermost layer composed of material similar to that comprising the outer layer of the spores. Based on the new LM, SEM and TEM information, consideration is given to spore wall formation. The inner body of the spores is interpreted as developing by centripetal accumulation of lamellae at the plasma membrane. The outer layer is interpreted as forming by accretion of sporopollenin units derived from a tapetum. The inner layer of the sporangium wall is considered to represent a peritapetal membrane formed from the remnants of this tapetum. The spore R. langii derives from aneurophytalean progymnosperms. In light of the new evidence on spore/sporangium characters, and hypotheses of spore wall development based on interpretation of these, the evolutionary relationships of the progymnosperms are considered in terms of their origins and relationship to the seed plants. It is concluded that there is a smooth evolutionary transition between Apiculiretusispora‐type spores of certain basal euphyllophytes, Rhabdosporites‐type spores of aneurophytalean progymnosperms and Geminospora‐/Contagisporites‐type spores of heterosporous archaeopteridalean progymnosperms. Prepollen of basal seed plants (hydrasperman, medullosan and callistophytalean pteridosperms) are easily derived from the spores of either homosporous or heterosporous progymnosperms. The proposed evolutionary transition was sequential with increasing complexity of the spore/pollen wall probably reflecting increasing sophistication of reproductive strategy. The pollen wall of crown group seed plants appears to incorporate a completely new developmental mechanism: tectum and infratectum initiation within a glycocalyx‐like Microspore Surface Coat. It is unclear when this feature evolved, but it appears likely that it was not present in the most basal stem group seed plants.     

Cell shape in the algaPediastrum (Hydrodictyaceae; Chlorophyta)

Summary Species ofPediastrum, a genus in which the colonies assemble from aggregating zoospores, differ in the number and form of prongs on peripheral cells and the amount of space between cells of the colony; cell shape appears to be genetically based. Peripheral cells of theP. boryanum colony, for example, have two prongs per cell;P. simplex has one prong per cell. Prong extension is suppressed in the interior cells ofP. boryanum, but prong sites have been reported in scanning electron micrographs of the cell walls. A mutant unicellular strain in which cells of the colony separate after attaining typical form reveals several prong sites (6 or more) in each cell. Multiple suppressed prong sites are evident inP. simplex cells as well. Polyeders, 4- and 5-pronged unicells, occur in the life cycle ofP. simplex. Based on these observations and a recent report byMarchant (1979) of a microtubule organizing center associated with the prongs, it is suggested that several microtubule organizing centers are to be found in zoospores ofPediastrum species and may be related to species differences in cell shape.Research supported in part by Argonne Center for Educational Affairs, U.S. Department of Energy, under contract No. W-31-109-ENG-38.