MORPHOGENESIS OF THE SPORANGIUM OF COMATRICHA

Goodwin , Donna C. (State U. Iowa, Iowa City.) Morphogenesis of the sporangium of Comatricha. Amer. Jour. Bot. 48(2): 148–154. IIlus. 1961.—Three species of the myxomycete genus, Comatricha, were studied: Comatricha nigra, C. fimbriata, and C. elegans. The sporangia developed on living bark of Ulmus americana in moist chamber. The hypothallus is formed under the homogeneous protoplasmic mass of the sporangial initial. The fibrous threads of the hypothallus bend upward, lengthening at the apices to become the fibers of the stalk and columella. The undifferentiated protoplasm is carried upward as the stalk elongates. When the columella has attained its mature height, threads bend out from the columella and grow toward the periphery of the sporangium. These threads form the capillitium. Simultaneous with the appearance of the capillitial initials, the peridium, a delicate membrane, forms. After the capillitium is mature, the protoplast cleaves into many cells, the future spores. The peridium evanesces early in the stage of spore maturation. Cellulose is present in the stalk, capillitium, and spore walls but is not found in the peridium or hypothallus. The capillitium of these species follows a developmental pattern designated as the “Comatricha-type” by Ross (1957) from a study of Comatricha typhoides. The taxonomic implications of the sporangial developmental pattern are discussed.     

MORPHOLOGY AND LABORATORY CULTIVATION OF ECHINOSTELIUM MINUTUM

Alexopoulos , Constantine J. (State U. Iowa, Iowa City.) Morphology and laboratory cultivation of Echinostelium minutum. Amer. Jour. Bot. 47(1): 37—43. Illus. 1960.—The morphology of the sporangium, spores, swarm cells and Plasmodium of the white form of Echinostelium minutum is described. A peridium is present in the early stages of sporangial formation. It eventually disappears leaving only a small collar at the base of the columella. The structure of the spore wall is unique in this genus. The spore case may be described as consisting of a thin wall with several thickened portions distributed over its surface. These are particularly evident in germinated spores. Spore germination and swarm cells are described for the first time. Swarm cells are biflagellate with two long anterior flagella of nearly equal length. The Plasmodium remains microscopic until fruiting time, when it gives rise to but a single sporangium. The plasmodial protoplast never becomes differentiated into veins but remains more or less homogeneous. It exhibits almost imperceptibly slow, irregular streaming instead of the reversible, rapid, rhythmic motion characteristic of plasmodia of most other Myxomycetes which have been studied. It typifies, therefore, a third type of Plasmodium which may be placed alongside that of the Physarales, and that of Stemonitis flavogenita. The laboratory cultivation of E. minutum from spore to spore on agar media is reported here for the first time.     

SPORE ULTRASTRUCTURE OF THE MYXOMYCETE PHYSARUM POLYCEPHALUM

Spores of the true slime mold Physarum polycephalum were examined at several stages of their development by means of scanning and transmission electron microscopy. The spores were globose, spine-covered structures produced within a sporangium enclosed in a tough, noncellular peridium. Cytologically, the spore represented a typical eukaryotic cell, having discrete organelles similar to spores of other myxomycetes. The presence of dictyosomes, helical filaments, and microbodies in these cells, as well as the further elucidation of the cell wall and the “polysaccharide-containing” areas, represent new contributions to the ultrastructure of the myxomycete spore. Of special interest were observations of metaphase nuclei just prior to spore cleavage, interphase nuclei in young spores, and nuclei in mature spores containing synaptonemal complexes. These observations indicate that in Physarum polycephalum mitosis occurs just prior to spore cleavage, and meiosis takes place after spore cleavage.     

淡黄绒泡菌和全白绒泡菌孢囊形成过程显微观察的染色差异

为了研究黏菌孢囊形成过程中显微结构的变化,文中探讨了番红-固绿和铁帆-苏木精染色条件下淡黄绒泡菌和全白绒泡菌孢囊不同发育阶段显微结构的差异显示效果。结果表明：在幼孢囊中原质团有种水平的割裂,大割裂和微割裂,这些割裂和孢丝及孢子的形成有关;全白绒泡菌囊轴表现了和孢囊柄不一致的状态和染色结果;番红-固绿染色下,淡黄绒泡菌在孢囊形成前期原质团被染成淡红色,可以分辨出大量游离存在的细胞核;孢囊壁及囊轴被染成绿色,孢子灰绿色;全白绒泡菌原质团被染成绿色,初期可见较厚孢囊壁,囊轴绿色。铁帆-苏木精染色下,淡黄绒泡菌和全白绒泡菌原质团均被染成灰色,囊壁不明显,成熟孢子发生皱缩。     

Electron Microscope Observations on Spore Formation in the True Slime Mold Didymium nigripes

SYNOPSIS. Developing and mature sporangia of the true slime mold Didymium nigripes were studied with the electron microscope to follow the course of spore formation. The sporangium forms from the plasmodium as a protoplasmic bleb which differentiates into a stalk and an apical sphere containing a mass of protoplasm. Nuclei within this protoplasmic mass undergo synchronous division (presumably meiosis). The division spindle forms within the nuclear membrane which is retained intact throughout the division; centrioles have not been observed at the spindle poles. At the same time the nuclei are dividing, the protoplasm cleaves to give ultimately uninucleate spheres—the incipient spores. Capillitial threads come to lie in the furrows created by the cleaving protoplasm. A wall consisting of an inner thick component and an outer thin component forms about each sphere. Cyto-chemical tests suggest that the inner wall of the spore is cellulose-containing and that the outer component might contain chitin.     

Development of the Mycetozoan Echinosteliopsis oligospora*

SYNOPSIS. The mycetozoan genus Echinosteliopsis, resembling the myxomycete Echinostelium in some of its features, is described. The single species, E. oligospora Reinhardt & Olive, forms small sporocarps which consist of a basal disk, stalk and a sporangium with only 1–8 spores. Spores form progressively, not simultaneously, by segmentation. The spores germinate to release non-flagellate amebae which, in liquid, assume a characteristic broad, fan shape. Each ameba has one or more nuclei. The nucleus is distinctive because of refractile, globular to elongate peripheral bodies which cytochemical tests indicate to be primarily RNA. At the time of nuclear division the characteristic RNA bodies disappear and, as observed with the phase microscope and in stained preparations, optically dense material accumulates in the middle area of the nucleus. Threads, either a spindle or actual chromatin, can be seen attached to the nuclear membrane. The threads separate to opposite poles as the nucleus elongates. During this division process the nuclear membrane apparently remains intact. Synchronous binucleate divisions, as well as a tripolar nuclear division, have been observed. Uninucleate and synchronous binucleate divisions may or may not be followed by cytokinesis. The absence of cell division after nuclear division leads to the production of cells with varying numbers of nuclei. Nuclear divisions in early sporangial stages and in spores have not been observed. The spores are uni- to multinucleate. In 8-spored sporangia and in most 4-spored sporangia there is a characteristic small “stalk spore” at the apex of the stalk. The stalk spore germinates slowly, if at all, but the larger spores germinate readily. No evidence of a sexual process has been found.     

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.     

Ultrastructural Changes Associated with Spore Formation in Sporangia and Sporangiola of Thamnidium elegans Link

Fully formed pre-cleavage sporangia and sporangiola of Thamnidiumelegans Link were bounded by a primary wall plus a thick, internalsecondary wall layer. In sporangia in late pre-cleavage, Golgi-likecisternae were associated with groups of cytoplasmic vesiclesof characteristic size and appearance which were not found insporangia containing large cleavage vesicles. In both sporangia and sporangiola, protoplast cleavage was effectedby enlargement of endogenous cleavage vesicles each containinga lining layer of variable appearance, mutual fusion of cleavagevesicle membranes and fusion of cleavage vesicle membranes withthe plasmalemma. Golgi-like cisternae and small vesicular profileswere present in sporangium protoplasts at all stages of cleavagevesicle enlargement. In sporangia, the columella zone was delimitedby cleavage vesicles and separated from the sporogenous zoneby a fibrillar wall. A similar wall, which sometimes protrudedto form a small columella, was formed in sporangiola. Recently delimited spore protoplasts were bounded by plasmalemmamembrane derived from cleavage vesicle bounding membrane andsporangium or sporangiolum plasmalemma and surrounded by aninvesting layer derived from cleavage vesicle lining material.The investing layer at first appeared single, but later twoelectron opaque profiles were discernible. The spore wall wasformed between the investing layer and the plasmalemma. Wallsof sporangia and sporangiola which contained fully formed sporesconsisted of the primary layers only.     

The anterior-like cells in Dictyostelium are required for the elevation of the spores during culmination

 Shortly after initiation of Dictyostelium fruiting body formation, prespore cells begin to differentiate into non-motile spores. Although these cells lose their ability to move, they are, nevertheless, elevated to the tip of the stalk. Removal of the amoeboid anterior-like cells, located above the differentiating spores in the developing fruiting body, prevents further spore elevation although the stalk continues to elongate. Furthermore, replacement of the anterior-like cells with anterior-like cells from another fruiting body largely restores the ability to lift the spores to the top of the stalk. However, if amoeboid prestalk cells are used to replace the anterior-like cells, there is no restoration of spore elevation. Finally, when a droplet of mineral oil replaces differentiating spores, it is treated as are the spores: the mineral oil is elevated in the presence of anterior-like cells and becomes arrested on the stalk in the absence of anterior-like cells. Because a similar droplet of mineral oil is totally ignored by slug tissue, it appears that there is a dramatic transformation in the treatment of non-motile matter at this point in Dictyostelium development. Received: 26 January 1998 / Accepted: 27 May 1998     

THE EFFECTS OF CYCLIC AMP ON DIFFERENTIATION OF A MUTANT DICTYOSTELIUM DISCOIDEUM CAPABLE OF DEVELOPING WITHOUT MORPHOGENESIS

The dev 1510 mutant of Dictyostelium discoideum differs from the wild type in that unaggregated cells are capable of differentiating into either spores or stalk cells depending on the culture conditions (12). Taking advantage of this fact, the effects of cyclic AMP (cAMP) on differentiation of the mutant cells were examined under conditions that prevent normal morphogenesis. In the presence of low concentrations of exogenous cAMP, the cells differentiated into only stalk cells, whereas in the presence of high concentrations they differentiated into only spores. Untreated cells formed stalk cells, but this was inhibited by addition of phosphodiesterase, indicating that it was induced by a low concentration of cAMP which they produced themselves. Cyclic GMP and dibutyryl cAMP also induced spore formation though less effectively, while 5'AMP, ADP and ATP had no effect. During development, the cells increased in sensitivity to cAMP in that spore formation was induced at lower concentration of cAMP after 4 hr of starvation. Treatment of cells that had been starved for 6hr with 10⁻⁴M cAMP for as short a time as 30 min was enough to induce 8% of the cells to form spores.
The effects on cAMP-induced differentiation of chemicals that are known to influence development of the wild type were also examined. Both NH₄Cl and KCl inhibited cAMP-induced stalk formation, but had no effect on spore formation. In the presence of arginine, spore formation was induced at a lower concentration of cAMP with higher efficiency. CaCl₂, LiCl and KF had no effect on cAMP-induced differentiation.     

LABORATORY CULTIVATION OF CLASTODERMA DEBARYANUM

Mc Manus , Sister Mary Annunciata , R.S.M. (Mount Mercy Coll., Cedar Rapids, Iowa.) Laboratory cultivation of Clastoderma debaryanum. Amer. Jour. Bot. 48(10): 884–888. Illus. 1961.—Clastoderma debaryanum has been cultivated on laboratory media for the first time and its life cycle studied. Spores germinate to produce a single protoplast which may remain a myxamoeba or may become a swarm cell. The swarm cells fuse in pairs to form a zygote, which grows into a microscopic, spherical plasmodium. The plasmodium never develops a network of veins and shows only irregular streaming. At maturity each plasmodium gives rise to 1 sporangium. There is always a sphere of gelatinous material about 4/5 the distance up the stalk, which appears late in the development of the sporangium, and which dries to become a wrinkled enlargement. The peridium dehisces early, leaving only a few plates attached to some of the peripheral tips of the capillitial twigs, and a peridial collar. The solid capillitium branches from the tip of a very short columella.     

Tetrads in sporangia and spore masses from the Upper Silurian and Lower Devonian of the Welsh Borderland

Prior to the mid-Silurian, evidence for the earliest embryophytes comes from dispersed spores, particularly permanent tetrads, there being no fossils showing gross morphology or anatomy of the producers. The fragmentary coalified mesofossils described here from the uppermost Silurian (Pridoli) and basal Devonian (Lochkovian) of the Welsh Borderland contain tetrads assigned to Tetrahedraletes, Velatitetras and Cheilotetras. These spores together with examples from spore masses have been examined by scanning and transmission electron microscopy and display diversity in ultrastructure of the exospore and envelope. Tetrads have been found, together with a putative elater, in the forking apex of an axial Lochkovian fossil, named Grisellatheca salopensis gen. et sp. nov., that anatomically, apart from spore characters, reveals no unequivocal evidence for hepatic affinity. The remaining fossils are equally as uninformative as regards affinity. Tetrads with ornamented envelopes are recorded in an isolated discoidal sporangium and in the bases of incomplete sporangia borne terminally on a bifurcating axis. Both ornament and ultrastructure suggest that the spores belong to quite distinct species within Velatitetras. Tetrahedraletes is recorded in an incomplete sporangium subtended by a forking axis, in which no cellular detail is preserved. Naked unfused tetrads also assigned to Tetrahedraletes are recorded in spore masses from both localities and again exospore ultrastructure demonstrates diversity. A final Lochkovian sporangium contains naked tetrads with sporadic Papiculate ornament and shows a unique trilayered exospore. Comparisons of exospore ultrastructure in these tetrads, which it is argued are mature and dispersed as such, provide no unequivocal evidence for affinities, be they tracheophyte or bryophyte. The bifurcating sporophytes are evidence against similarities with extant bryophytes. It is concluded that these very fragmentary fossils derive from small plants comprising relict populations of the vegetation that flourished on land in turfs through the greater part of the Ordovician and early Silurian, but that was gradually replaced by the tracheophytes.     

SPORE MORPHOLOGY IN THE CYATHEACEAE. I. THE PERINE AND SPORANGIAL CAPACITY: GENERAL CONSIDERATIONS

The literature on cyatheaceous spore morphology relative to the presence of a perine layer is reviewed, and evidence based on a sodium-hydroxide assay is presented indicating that the outer scultpine layer in certain cyatheaceous spores is perine. Perine so defined characterizes Metaxya, paleotropical and certain neotropical species of Sphaeropteris, nearly all species of Alsophila, all species of Nephelea, and certain species of Trichipteris and Cyathea. It is lacking in Lophosoria, many species of Trichipteris and Cyathea, and all species of Cnemidaria. Two major patterns of spore number per sporangium in the family are reported. Lophosoria, Sphaeropteris, Trichipteris, Cyathea, Cnemidaria, and probably Metaxya are characterized by 64-spored sporangia, whereas most species of Alsophila and all species of Nephelea are characterized by 16-spored sporangia. The congruence of this generic distribution of sporangial-capacity types with Tryon's phyletic arrangement of cyatheaceous genera supports the naturalness of his system. The intrasporangial germination of spores retained in dehisced and dispersed sporangia supports the suggestion that decreased spore number per sporangium in Alsophila and Nephelea may relate to the role of the sporangia as dispersal units. The decreased number of spores per sporangium is associated with a trend toward increase in the number of sporangia per sores, with the highest known count approaching 1000 sporangia per sorus. The Alsophila-Nephelea evolutionary line has probably not been ancestral in the phylogeny of the more advanced groups of ferns.     

中华水韭孢子囊发育研究

采用半薄切片法,连续观察了极度濒危级(CR)植物中华水韭大小孢子囊的发育过程,以期从无性生殖的角度,为探讨其濒危原因提供直观可靠的理论根据。结果显示:(1)中华水韭的大小孢子叶相间排列,无混生孢子囊。(2)隔丝为孢子供给营养,其体积直接影响孢子的大小、产量和育性。(3)大小孢子囊都近半数败育,小孢子囊为整齐发育,大孢子囊为不整齐发育。(4)大小孢子囊均无柄,且都不存在开裂结构,只有孢子囊壁腐烂后才能散播孢子。研究认为,中华水韭的濒危与孢子囊的发育特征密切相关,孢子囊的高频率败育、没有开裂结构以及对环境的依赖,是造成中华水韭濒危的重要因素之一;通过与近缘类群孢子囊的比较,发现仅水韭孢子的散播借助外力,对生境要求较高,即验证了水韭古老的系统学地位,同时说明水韭更具有监测生境地区环境指标的能力。     

ULTRASTRUCTURAL ASPECTS OF CELL ELONGATION,CELLULOSE SYNTHESIS,AND SPORE DIFFERENTIATION IN ACYTOSTELIUM LEPTOSOMUM,A CELLULAR SLIME MOLD

Vegetative myxamoebae of Acytostelium leptosomum, a cellular slime mold, have the appearance of typical eucaryotic cells. The presence of dictyosomes has been established. Elongation of the cells during aggregation and culmination appears to be mediated by dense bundles of microfibrils traversing the cells longitudinally. Microtubules are present; however, they are randomly oriented and no correlation can be made with cell elongation or with the direction of the cellulose microfibrils within the stalk. A variety of vesicles, multivesicular bodies, and lysosome-like vacuoles seems to be involved in producing and transporting stalk material to the vicinity of the stalk. However, only rarely do the vesicles empty their contents directly to the outside of the cells. It seems rather that the fibrillar material of the stalk is assembled near or directly at the plasmalemma, and can then be seen to stream away and become an integral part of the stalk. An unusual structure, the H-body, is formed in great abundance during culmination indicating its possible involvement in stalk synthesis. The H-bodies are removed from the cells prior to spore formation together with other portions of the cytoplasm at least partly by a process involving autophagic vacuoles. These vacuoles, which are also present in the spores, appear to be part of a rather complex and extensive vacuolar apparatus including the food vacuoles, contractile vacuoles, lysosome-like structures, and possibly the H-bodies. The spore coat consists of a heavy outer wall with a fibrillar substructure and two thin, dense bands lining the inside of the plasmalemma. The fibrillar nature of both the outer spore wall and the stalk was accentuated by using barium permanganate to stain sectioned material.     

Differentiation of Various Cell Types during Fruiting Body Formation of Dictyostelium Discoideum*

The processes of differentiation of the presumptive cells (prespore and prestalk cens) into mature spores, stalk and basal-disc cells in Dictyotelium discoideum was investigated. The number of stalk and disc cells in pre-labeled culminating cell masses was estimated by determining the radioactivity of the undissociable fraction separated by filtration from the dissociable fraction containing presumptive cells and spores. Changes in the proportion of amoeboid cells stainable with fluorescein-conjugated antispore serum and encapsulated spores were also followed in the dissociable fraction. Formation of stalk and disc cells began at 17 hr of development and was completed at 26 hr, while formation of morphologically identifiable spores began at 18 hr and was completed at 20 hr, long before completion of stalk formation. At the onset of culmination, unstained cells abruptly increased with an accompanying decrease of stained cells, when unstained rear-guard cells appeared in the hind region. Although some of the rear-guard cells soon differentiated into basal-disc cells, the rest remained amoeboid in the upper part of the spore mass (sorus) after complete formation of a fruiting body. Despite the presence of the amoeboid cells in mature sori, the proportion of the sorus to the stalk and disc of a fruiting body was approximately equal to that of stained (prespore) to unstained (prestalk) cells in a migrating slug.     

Transcellular ion currents during sporangium development in the water mould Achlya bisexualis

Changes in the pattern of electric currents that accompany the transformation of growing hyphae of Achlya bisexualis into sporangia have been examined. When hyphae were transferred to a non-nutrient buffer, they continued to extend for several hours and then gave rise to sporangia. Throughout this process, current (positive charge) flowed into the apical region that corresponds approximately to the future sporangium. The current ceased after the crosswall appeared. The sporangium then remained electrically quiescent, except for a brief intense burst of outward current at the 'homogeneous' stage of spore cleavage. The inward current during sporangium formation largely represents an influx of protons. Addition of nitrate abolished the flow of electric current with little effect on sporulation. The late burst of outward current is most probably an artefact, generated by the discharge of salts from the sporangial vacuole. The transcellular electric current apparently plays no role in sporangium formation or in spore cleavage. Calcium ions, however, are required and may traverse the plasma membrane.     

红盖鳞毛蕨孢子囊早期发育与质体分化的研究

利用光学显微镜和透射电子显微镜观察了红盖鳞毛蕨(Dryopteris erythrosora(Eaton)O.Ktze.)孢子囊的发育及在此期间质体的分化过程。研究表明:(1)红盖鳞毛蕨孢子囊的发育类型属于薄囊蕨型;(2)绒毡层为混合型,即内层绒毡层为原生质团型,外层绒毡层为腺质型;(3)孢子囊原始细胞中的质体通过3条路径分化,其一,原始细胞中含淀粉粒的质体通过分裂分配到下方细胞,继而进入孢子囊柄;其二,原始细胞分裂产生的新生质体被分配到上方细胞,进而被分配到除顶细胞外的原基细胞中,顶细胞将含淀粉粒的质体通过分裂分配到外套层原始细胞中;其三,顶细胞也将具淀粉粒的质体通过分裂分配到内部细胞,使分裂产生的孢原细胞和绒毡层原始细胞具新生质体;造孢细胞和孢子母细胞的质体具淀粉粒,孢子母细胞还具油体,新生孢子中具造粉体和油体;两层绒毡层具新生质体,随着退化外层绒毡层出现造粉体,内层绒毡层出现油体;(4)红盖鳞毛蕨与少数被子植物小孢子发育阶段质体分化模式类似,由前质体分化为造粉体再到油体。研究结果为蕨类植物质体在孢子囊发育过程不同组织细胞中的差异分化提供了新观察资料,为蕨类植物发育生物学和系统演化研究提供科学依据。     

TETRAXYLOPTERIS SCHMIDTII: ITS FERTILE PARTS AND ITS RELATIONSHIPS WITHIN THE ANEUROPHYTALES

The fertile branching system of Tetraxylopteris is composed of successive “nodes” bearing opposite and decussately arranged, upcurved sporangial complexes. By means of the transfer technique the morphology of the sporangial complex was revealed. It consists of a main stalk which dichotomizes twice producing four major branches. Each of the four branches is further subdivided three times, the subdivisions being arranged alternately and pinnately. The ultimate divisions bear the sporangia singly and terminally. The sporangial complexes decrease in size distally and are more tightly curved at the apex. The sporangia are oblong-oval with an acute apex. The spores are identical to the dispersed spore taxon Rhabdosporites langii, Richardson. They are spherical, trilete and pseudosaccate with a fine granular ornament on the pseudosaccus. They are 75–176 μ in diameter and show developmental stages from young tetrads to separated, fully mature spores depending on the age of the sporangium from which they were obtained. This is the first account of spores in sporangia of Tetraxylopteris. The diagnosis of the genus and species are emended to include the new information and the order Aneurophytales is redefined.