The histogenesis of integuments in some species of menispermanceae

The mode of initiation and development of integuments was investigated in six species of five genera in Menispermanceae, which have bitegmic and unitegmic ovules. The species investigated have similar integumentary structures at maturity in each of the bitegmic and unitegmic ovules. In bitegmic ovules (e.g.Cocculus), both integuments are for the most part two-cell layered. The initiation of inner integument (ii) begins with divisions of dermal cells of the nucellar primordium. The initiation of the outer integument (oi) commences with divisions of subdermal cells. In unitegmic ovules (e.g.Stephania), the integument is initiated by periclinal divisions of dermal cells, and cells of subdermal origin (which may represent the oi in case of bitegmy) form a small swelling on the raphal side and, on the antiraphal side, are included in the base of the single integument. Unitegmy of Menispermanceae (at least in the case of the genera investigated) seems to have been derived through elimination of oi, rather than through “integumentary shifting” (Bouman and Calis, 1977), a process suggested for explanation of unitegmy as in Ranunculaceae.     

Postpollination-prezygotic ovular secretions into the micropylar canal inPseudotsuga menziesii (Pinaceae)

Ovular morphology was examined ultrastructurally inPseudotsuga menziesii to determine the effects of the ovule on pollen development. Vesicles containing lipid-like substances traverse cell walls of the inner epidemis of the integument and release their contents at the integument surface to form the integumentary membrane. A major aqueous secretion from the integument into the micropylar canal is proposed to occur by the movement of the integumentary membrane and its invaginations towards the center of the micropylar canal. The cellular degeneration of the nucellar apex results from the breakdown of vacuoles. After this degeneration, electron-dense substances move from the prothallial cells of the female gametophyte towards the nucellus, and many morphological changes in the nucellus, prothallial cells, and micropylar canal take place simultaneously. We interpret these changes to result from another major secretion from the prothallial cells. Egg cytoplasm appears to disorganize for a short time. Simultaneously, substantial amounts of electron dense-substances in the prothallial cells and lipid-like substances in surface cell walls of the female gametophyte move towards the nucellus as components of the third major secretion.     

A PERIODIC ACID-SCHIFF'S SUBSTANCE RELATED TO THE DIRECTIONAL GROWTH OF POLLEN TUBE INTO EMBRYO SAC IN PASPALUM OVULES

The presence of a periodic acid-Schiff's (PAS) substance at the micropylar portion of the ovules of Paspalum orbiculare and three other species of Paspalum has been revealed by improved cytological techniques. The substance is located in the distal portion of the outer integument, especially at its edges, and in the micropyle, which is formed by the inner integument. A study of the origin of this substance in P. orbiculare indicates that it is produced from the cellular material of the dissolved cells in situ. The PAS substance is highly water soluble and may contain some protein. The final directional growth of the pollen tube into the filiform apparatus of the degenerated synergid is related to this substance. The role of the synergids in its formation is discussed.     

SOME HISTOCHEMICAL,ULTRASTRUCTURAL, AND NUTRITIONAL ASPECTS OF THE OVULE OF QUERCUS GAMBELII

Histochemical analyses of the ovule of Quercus gambelii show that the major food reserves (starch grains and lipids) are located almost exclusively within the outer integument. Vascular traces are present only within this integument which contains numerous, well-developed plasmodesmata. The inner integument is virtually devoid of any food reserves and has very few plasmodesmata. The ovule has a persistent chalazal extension of residual nucellar cells (called the postament) which projects into the embryo sac. Due to the above information and the fact that the synergids rarely contain starch and no plasmodesmata are present in the walls of any of the cells of the egg apparatus (Mogensen, 1972), it is concluded that the synergids play little or no role in embryo sac nutrition. Rather, it is proposed that the pathway of available food materials in the young ovule is from the outer integument to the chalaza and through the postament into the embryo sac.     

Nucellar degeneration inCortaderia (Gramineae)

Summary Vigorous degradation of nucellar tissue in the apomictic grassCortaderia jubata is associated with early degeneration of the megaspore mother cell and the subsequent enlargement of several cells to form somatic embryo sacs. Nucellar degeneration is recognised by the separation of the nuclear membranes, at first along only small sectors of the nucleus, and the appearance within the enlarging perinuclear space of vesicles formed by blebbing of both the inner and outer membranes of the nuclear envelope. Invaginations of the bounding membrane of the dilating RER are responsible for many single-membrane-bound vesicles lying in cisternae throughout the cytoplasm. Eventually the nucleus, enclosed mainly in the inner nuclear membrane, and the cytoplasm, are subject to extensive vesicularization. An electron opaque substance is present in the perinuclear space, in the ER, in vacuoles, and outside the plasmalemma adjacent to the degenerating cell wall, and is similar to a substance which appears on the inner and outer membrane surfaces of mitochondria during later stages of cell degeneration. It is suggested that the genesis and growth of embryo sacs inC. jubata are linked with a programmed nucellar cell autolysis.     

非洲狼尾草胚珠(着重胚珠附器)发育的特点

用光学显微镜对非洲狼尾草胚珠发育做了进一步观察。结果表明有如下几个特点：（１）珠孔区域的珠心细胞发生特化,膨大１伸长并进入珠孔,形成胚珠附器。（２）珠心表皮平周分裂产生周缘珠心组织。（３）珠孔由内珠被和腹侧外珠被构成。     

Rice caryopsis development I: Dynamic changes in different cell layers

Rice caryopsis as one of the most important food sources for humans has a complex structure that is composed of maternal tissues including the pericarp and testa and filial tissues including the endosperm and embryo. Although rice caryopsis studies have been conducted previously, a systematic characterization throughout the entire developmental process is still lacking. In this study, detailed morphological examinations of caryopses were made during the entire 30‐day developmental process. We observed some rapid changes in cell differentiation events and cataloged how cellular degeneration processes occurred in maternal tissues. The differentiations of tube cells and cross cells were achieved by 9 days after pollination (DAP). In the testa, the outer integument was degenerated by 3 DAP, while the outer layer of the inner integument degenerated by 7 DAP. In the nucellus, all tissues with the exception of the nucellar projection and the nucellar epidermis degenerated in the first 5 DAP. By 21 DAP, all maternal tissues, including vascular bundles, the nucellar projection and the nucellar epidermal cells were degenerated. In summary, this study provides a complete atlas of the dynamic changes in cell differentiation and degeneration for individual maternal cell layers of rice caryopsis.     

CERCIDIUM FLORIDUM SEED COAT,LIGHT AND ELECTRON MICROSCOPIC STUDY

Scott , Flora Murray , B. G. Bystrom , and E. Bowler . (U. California, Los Angeles.) Cercidium floridum seed coat, light and electron microscopic study. Amer. Jour. Bot. 49(8): 821–833. Illus. 1962.—The structure of the seed coat of the desert tree Cercidium is typical of the family Leguminosae, but the inner integument is mucilaginous. The characteristic palisade cells of the epidermis and the many-armed cells of the mucilaginous zone are discussed in detail. The minute wax rodlets on the surface of the young seed fuse later into a film of wax. The epidermal palisade cells are polygonal in transection and the walls are strengthened by cellulose flanges. The palisade cells are enclosed in a thin suberin-like sheath which connects with the film which lines all air-filled intercellular spaces in the outer integument. Plasmodesmata extend from the protoplast through the subcuticular zone to the cuticle and also interconnect with adjacent cells through numerous pits in the interflange areas of the main wall. The cells of the inner integument are many-armed. Intercellular spaces at all stages of growth observed are occluded with mucilage; nevertheless, they are lined with a suberin-like film similar in reaction to that of the air-filled intercellular spaces of the outer integument. The distribution of wall materials and ergastic substances was determined by microchemical tests. For electron microscopic study, the epidermis and the mucilaginous zone were fragmented ultrasonically, after chemical treatment when necessary. Cuticular fragments, frequently polygonal in outline, are dense to the electron beam at photographic illumination. When exposed to the electron beam, full-strength, volatile components are driven off and condense on other wall fragments or on substrate. Unique structures occur in the subcuticular zone, termed here, collar, cone and paddle structure. The basic material of the cell wall as a whole is cellulose impregnated with matrix materials, mainly non-cellulosic polysaccharides. In addition, lipid-like substances are conspicuous particularly in the flanges of the palisade cells. Under the electron beam, full-strength, these substances volatilize and leave the flanges with a blistered outline except in the region of the light line. The volatile substances may be absent from this zone or the microfibrillar structure may prevent distortion. The microfibrillar pattern throughout the length of the flanges is dominantly parallel, but a change to reticulate arrangement occurs in the light-line region. Numerous pits mark the paths of the plasmodesmata in the subcuticular zone and also through flange and interflange areas of the wall. The dominant microfibrillar pattern in the mucilage cells is reticulate in young and old cells, except for helical orientation in extending arms. Pits occur on arm ends but are infrequent elsewhere. The loose microfibrillar structure presumably allows continuous secretion of mucilage.     

Embryological studies inGlaucidium palmatum Sieb. et Zucc. with a discussion on the taxonomy of the genus

Embryological features ofGlaucidium palmatum are as follows: the ovule is anatropous and bitegmic; the archesporium is hypodermal and multicelled, consisting of about 10 to 15 cells; all the archesporial, cells develop directly into megaspore mother cells, only three or four of which, however, generally complete meiotic divisions; before and during meiosis, dermal cells of the nucellar apical part undergo successive periclinal divisions forming a thick nucellar cap of as many as 20 cell-layers; embryo sac formation is of the Polygonum type; multiple embryo sacs occur frequently; antipodal cells are small in size and ephemeral or persistent; the inner integument is 3 to 5 cell-layers thick, and the outer integument 7 to 13 cell-layers thick; the outer integument is vascularized; a micropyle is formed by the inner integument alone; the endosperm is of the Nuclear type; embryogeny is of a type similar to the Onagrad type. In light of evidence from embryology and other sources it seems that there is ample reason for recognizing the family Glaucidiaceae which is distinct from the Ranunculaceae and its related families. Several common embryological features suggest an affinity between the Glaucidiaceae and the Paeoniaceae.     

Transfer Cells in Suspensur and Endosperm during Early Embryogeny of Vigna sinensis

During early embryogeny, structural differentiation of the suspensor and endosperm can be observed with the formation of cells with wall ingrowths. In the early proembryo stage, wall ingrowths are seen only on the boundary walls of the embryo sac around the proembryo and at the chalazal end. Later, ingrowths appear in the outer walls of the basal suspensor cells and some wall ingrowths also begin to develop in the outer walls of cellular endospermic cells adjacent to the nucellar cap and the inner integumentary tissues. The suspensor appears to remain active throughout the differentiation stages. Two regions can be clearly distinguished in the suspensor: a basal region and a neck region. Wall ingrowths appear to form only in the cells of the basal region. During the development of the cellular endospermic sheath, its cell number and size both increase slightly. Later, these cells rapidly become separated from each other. Those endospermic cells that abut directly onto the integumentary tissues also develop wall ingrowths. In the region of the fluid endosperm, wall ingrowths are especially abundant in the boundary walls on the ventral side of the embryo sac. The possible pathway of nutrient flow to the developing embryo is discussed.     

Pollen movement in the micropylar canal ofLarix and its simulation

InLarix pollen captured by the ovule and rested at the distal end of the micropylar canal is transferred upward to the nucellus before it develops a pollen tube. This upward movement occurs after the canal is filled with secreted fluid, despite the fact that the pollen sinks in the fluid. We examined the mechanism of the movement based on the morphology of the canal and its simulation using pipettes. When a water column moves upward in a waxed pipette, suspended particles also move upward carried by the meniscus. InL. x eurolepis the inner surface of the integument lining the micropylar canal is coated by a cuticle layer. This layer is further coated by an integumentary membrane before the fluid is secreted. This membrane, however, becomes distorted or disappears during fluid secretion. The exposed cuticle and the degenerated hydrophilic nucellar apex may facilitate the movement of the meniscus toward the nucellus as in the simulated pipette. Pollen is interpreted to move by being carried by the meniscus when the fluid recedes.     

甘蔗雌雄蕊的解剖学研究

甘蔗雄蕊花药的壁由四层细胞构成,药室内壁在花药成熟时才发育。花粉母细胞减数分裂属连续型,四分体正常发育为小孢子,但当开花时,只有少数进一步发育为成熟的花粉粒。甘蔗雌蕊柱头是分枝的,每一柱头毛是由数个细胞质浓密的细胞,呈不规则的纵列而组成。倒生胚珠一个,着生于子房室的内侧;内、外珠被均由两层细胞构成,外珠被上侧未能生长到珠孔,内珠被的内层细胞在胚珠发育中不断增大体积。石蜡制片是以樟油为透明剂的。     

Embryology of tribeDrypeteae, an enigmatic taxon ofEuphorbiaceae

The tribeDrypeteae, whose traditional assignment inPhyllanthoideae ofEuphorbiaceae is now doubtful, is studied embryologically on the basis of a literature survey and examination of six additional species in two of the four constituent genera.Drypeteae are characterized by having several embryological features that are unknown in otherPhyllanthoideae, such as a two- or three-celled ovule archesporium; a thin, two cell-layered parietal layer in the nucellus; no nucellar beak or cap; an early disintegrating nucellar tissue; thick, multiplicative, inner and outer integuments; an endothelium; a few discrete vascular bundles in the outer integument; and a fibrous exotegmen (or its derived state). EmbryologicallyDrypeteae do not fit within thePhyllanthoideae and, as available nucleotide sequence data from therbcL gene suggest, are rather placed nearErythroxylaceae, Rhizophoraceae, Chrysobalanaceae, andLinaceae. Drypeteae share with those families a combination of the fibrous exotegmen, the endothelium, and the thick, multiplicative inner integument.     

Ultrastructure of the “fringe-layer”, the innermost epidermis of cotton seed coats

Summary The inner epidermis of the inner integument of cotton seed coats (fringe-layer) and the cuticles between this cell layer and the nucellus were examined in the light and electron microscope at different times of their development. The cells of the fringe-layer contain only small vacuoles and their cytoplasm is densely packed with organelles and free and membrane-bound polysomes. The lateral walls contain many plasmodesmata. At the time when the fruit capsules stop growing, the fringe-cells produce a cell wall labyrinth, resembling that of transfer cells. The cell wall labyrinth is restricted to the lateral walls. The differentiated state of the fringe-cells is short-lived. At about the time of elaboration of the cell wall labyrinth most of them become progressively vacuolated, lignify, and lose their cytoplasmic constituents. The development of the fringe-layer is well correlated with other developmental events in the inner integument, but not with the filling of embryo and endosperm with reserve substances.At anthesis, the fringe-layer and nucellus are covered by a thin cuticle proper of about 20 nm. After anthesis, the nucellar cells start to produce a cuticular layer of considerable, but variable, thickness (0.25–2.5 m), containing a polysaccharide network.In drying seeds the cells of the fringe-layer disrupt. The thin outer tangential wall remains attached to the seed coat. The rest of the cell, together with the cuticles and the collapsed cells of the nucellus, form a protective layer around embryo and endosperm, remaining attached to the seed coat at the chalazal end.     

Embryo sac, endosperm, and seed of Nemophila (Boraginaceae) relative to taxonomy, with a remark on embryogeny in Pholistoma

Studies on embryology and seed morphology are complementary to molecular phylogenetics and of special value at the genus level. This paper discusses the delimitation and evolutionary relationships of genera within the tribe Hydrophylleae of the Boraginaceae. The seven Nemophila species characterized by a conspicuous seed appendage are similar in embryology and seed structure. The ovule is tenuinucellate and unitegmic with a meristematic tapetum. The embryo sac penetrating the nucellar apex is of the Polygonum type, has short-lived antipodal cells, and an embryo sac haustorium. The endosperm is cellular, producing two terminal endosperm haustoria, of which the chalazal has a lateral branch. Embryogeny is of the Chenopodiad type (as in Pholistoma). The seed coat is formed from the small-celled inner epidermis of the integument. The large-celled outer epidermis of the integument disintegrates into scattered cells. Seed pits evolve from irregularly placed inner epidermal cells of the integument. The chalazal part of the ovule produces a cucullus, that functions as an ant-attracting elaiosome. Those species of Nemophila with a conspicuous cucullus form a natural genus. Nemophila is most closely related to Pholistoma. The integumentary seed pits of Nemophila might have evolved from ovular seed pits similar to those in Pholistoma.     

Rice caryopsis development Ⅰ: Dynamic changes in different cell layers

Rice caryopsis as one of the most important food sources for humans has a complex structure that is composed of maternal tissues including the pericarp and testa and filial tissues including the endosperm and embryo. Although rice caryopsis studies have been conducted previously, a systematic characterization throughout the entire developmental process is still lacking. In this study, detailed morphological examinations of caryopses were made during the entire 30-day developmental process. We observed some rapid changes in cell differentiation events and cataloged how cellular degeneration processes occurred in maternal tissues. The differentiations of tube cells and cross cells were achieved by 9 days after pollination(DAP). In the testa, the outer integument was degenerated by 3 DAP, while the outer layer of the inner integument degenerated by 7 DAP. In the nucellus, all tissues with the exception of the nucellar projection and the nucellar epidermis degenerated in the first 5 DAP. By 21 DAP, all maternal tissues, including vascular bundles, the nucellar projection and the nucellar epidermal cells were degenerated. In summary, this study provides a complete atlas of the dynamic changes in cell differentiation and degeneration for individual maternal cell layers of rice caryopsis.     

Histochemical study of the development of the phytomelan layer in the seed coat ofGasteria verrucosa (Mill.) H. Duval

Summary In this study we document the development of the phytomelan layer in the outer epidermis of the outer integument ofGasteria verrucosa. Phytomelan has been described as a black, melanin-like substance which is chemically very inert. Using histochemical techniques we show that phytomelan development in the cell wall can be divided into three stages. The first stage is deposition of a callosic layer against the tangential wall, with simultaneous thickening of the adjacent parts of the radial walls. The second stage is the conversion of this callosic wall, which we call a tertiary wall, into a noncallosic inner and outer layer. The inner layer stains predominantly for cellulose and a little for pectin. The outer layer is of unknown composition, since it did not react with the stains that were used. In the third stage the outer tertiary layer becomes black, the phytomelan. The callosic wall deposited in the first developmental stage seems to function as a carbohydrate source and as a mould for the tertiary cell wall. The conversion of the callose in the second stage might be the result of penetration of substances which react with callose. All the components for phytomelan seem to be present in the outer layer before the conversion. Phenolics might be involved in this second conversion.Abbreviations DAP days after pollination - PAS periodic acid Schiff's reagent - PEG polyethylene glycol     

PETRIFIED PLANTS FROM THE UPPER MISSISSIPPIAN OF NORTH AMERICA. I: THE SEED RHYNCHOSPERMA GEN. N.

Petrified seeds of Upper Mississippian age (Chester Series) are described from sediments from northwestern Arkansas. Specimens of Rhynchosperma quinnii gen. et sp. n. are radially symmetrical and range in length from 1.2 to 2.2 cm and 1.0 to 1.3 cm at the greatest diameter. The seeds are ovate with a tapered apex having 8–10 integumentary ribs and a broadly rounded chalaza. The integument is two-parted, consisting of an outer presumably soft tissue with secretory canals and an inner layer constructed of longitudinally oriented thick-walled cells. Nucellus and integument are confluent, but they diverge near the seed midlevel with the free portion of the nucellus forming a dome-shaped pollen-receiving structure. Additional features such as vasculature and the structure of well-preserved megagametophytes are described. The petrified specimens are compared with taxa instituted for casts and impressions which include Rhynchogonium and Boroviczia. The ovulate versus cupulate nature of these genera which has remained uncertain until now appears to be settled in favor of an ovular identity.     

MITROSPERMUM VINCULUM SP. NOV., A CARDIOCARPALEAN OVULE FROM THE UPPER PENNSYLVANIAN OF OHIO

Numerous anatomically preserved ovules assignable to the genus Mitrospermum have been discovered in Upper Pennsylvanian sediments of Eastern Ohio. Although basically similar to Mitrospermum compressum, the newly discovered specimens exhibit several consistent differences. Ovules are strongly platyspermic, up to 4.2 mm long, 4.0 mm wide, and 0.6 mm thick. In the minor plane, ovules are broadest at the base and taper toward the micropyle. The integument exhibits three topographic regions: endotesta, sclerotesta, and sarcotesta. The sarcotesta is extremely broad in the major plane, where it forms two membranous wings. A single terete vascular bundle enters the base of the ovule, traverses the integument, and divides to form two integumentary bundles and a conspicuous nucellar platform. Integumentary bundles extend toward the tip of the ovule at the margin of the sarcotesta and sclerotesta. A pollen chamber with a prominent nucellar beak is delimited at the tip of the nucellus. Consistent differences in vascularization, size, nature of the seed base, features of the pollen chamber, and the Late Pennsylvanian age demonstrate that the specimens represent a distinct species. The discovery of these ovules extends the stratigraphic range of Mitrospermum to the Upper Pennsylvanian of Ohio.     

ULTRASTRUCTURE OF THE TRANSFER TISSUES DURING VIVIPAROUS SEEDLING DEVELOPMENT IN RHIZOPHORA MANGLE (RHIZOPHORACEAE)

All water and nutrients required for the growth of the huge viviparous seedlings of Rhizophora mangle must be transported from the inner surface of the integument (maternal tissue), across a layer of persistent endosperm cells (seedling tissue), and to the surface of the cylindrical cotyledonary body. We describe the ultrastructure of these tissues at two functionally different stages of embryo and seedling development (i.e., 2–3 wk and 2–3 mo postgermination, respectively). Integumentary cells adjacent to the endosperm have unique plastids and divide more frequently than cells further away from the endosperm/integument interface. Later, fibrillar inclusions develop in vacuoles of the integument cells. The outermost layer of endosperm cells differentiates into transfer cells with wall ingrowths on the external walls, and the remainder of the endosperm degenerates during the embryo to seedling transition. The wall ingrowths gradually occlude the lumena of the transfer cells, a process which is complete long before the seedling abscises; therefore, the seedling may be photosynthetically independent throughout most of its development. The outer surface of the seedling cotyledonary body is minimally papillate and exhibits several ultrastructural specializations: centripetal degeneration of external walls which are bounded by electron-dense deposits; numerous mitochondria; and plastids of unusual structure with many plastoglobuli, and which contain unique yellow pigments having absorption spectra characteristic of carotenoids. HPLC residence times of these pigments are unlike those of β-carotene or other common carotenoids. Transfer tissues of Rhizophora may have functions not found in other plants, such as salt exclusion and facilitating viviparous germination, but the ultrastuctural correlates of these functions remain uncertain.