An upright psaroniaceous stump and two surrounding pecopteroids from the early Permian Wuda Tuff Flora

An upright Psaronius stump was discovered in the upper part of Taiyuan Formation (Asselian) of Wuda Coalfield, Inner Mongolia, China. The stump is 47 cm high and truncated at the upper part of the ash layer in which it is preserved. At the height of 38 cm, the stem possesses a stelar configuration comprised of 3~4 cycles in 5 orthostichies. The Wuda Psaronius stump rapidly widens at the base until it attains a stable axial diameter; a root mantle is present in the proximal zone of primary body expansion, but not distal to that zone. This architecture is further demonstrated by a prostrate Psaronius trunk almost 7 m long with a stable stem diameter and two rows of frond scars visible over most of its length. This developmental mode is seen among extant leptosporangiate tree ferns but differs from that previously documented among North American Pennsylvanian marattialean tree ferns whereby the primary body of Psaronius stems increases continually in width towards the apex and is buttressed by a thick root mantle that compensates for the obconical nature of the stem. Two types of pecopteroid fronds associated with the Psaronius stump are identified as Pecopteris cf. polymorpha and Pecopteris orientalis based on their pinnule morphology. The Pecopteris orientalis frond possesses a penultimate rachis with stewartiopteroid anatomy and is more likely to be the leaf of the Psaronius stump based on a recently reported Psaronius specimen with stem and frond in connection from the same locality.     

BOTRYOPTERIS FORENSIS (BOTRYOPTERIDACEAE), A TRUNK EPIPHYTE OF THE TREE FERN PSARONIUS

Basal parts of Botryopteris forensis have been discovered rooted within the mantle of the tree fern Psaronius. Specimens occur in Upper Pennsylvanian coal balls from near Steubenville, Ohio, USA. The Botryopteris stems branch profusely, and these shoots are intertwined with the Psaronius roots near the surface of the mantle. They also produce adventitious roots that extend among the Psaronius roots. This material demonstrates that B. forensis was a trunk epiphyte, rather than a rhizomatous terrestrial fern. The B. forensis plant is interpreted to have branched continuously, to ramify, and to maintain itself at the periphery of the growing mantle of Psaronius roots. A new reconstruction of B. forensis is offered showing the large, globose fructifications hanging pendulously from horizontal fronds on emergent shoots. Epiphytes and lianas are common on the trunks of Psaronius, indicating that some Marattiales did not produce leaf skirts.     

PHLOEM STRUCTURE IN THE CARBONIFEROUS FERN PSARONIUS (MARATTIALES)

Phloem anatomy in stems of Psaronius is described from coal ball specimens collected at the Berryville, IL and Lewis Creek, KY localities. Phloem completely surrounds the C-shaped xylem segments, but is more extensively developed on the abaxial side of the trace. The phloem zone consists of a central band of large diameter (approximately 90–120 μm) sieve elements surrounded by a mixed zone of smaller sieve elements and phloem parenchyma. Phloem is separated from the xylem by a parenchymatous xylem sheath. On the abaxial side of the trace, a discontinuous arc of very small diameter cells (7.8 μm) is present between the xylem sheath and the metaxylem. These cells corrrespond in position and size to protophloem cells in living marattialeans. Metaphloem sieve elements exhibit discrete, circular-oval sieve areas on their side and end walls, some of which show evidence of sieve pores. Phloem structure in Psaronius is compared with that known for living members of the Marattiales.     

STUDIES OF PALEOZOIC MARATTIALEANS: THE MORPHOLOGY AND PROBABLE AFFINITIES OF TELANGIUM PYGMAEUM GRAHAM

Telangium pygmaeum Graham is known from Upper Pennsylvanian coal balls from the Calhoun coal mine (Illinois). The species was described as possessing radial synangia consisting of 3-5 sporangia fused laterally for about f13 their length. Synangia were believed to be sessile and borne terminally or laterally on a branching rachis without lamina. Examination of new coal ball material of the same age indicates that the synangia are borne abaxially on the pinnules of a compound frond with the anatomy of a Psaronius leaf (Marattiales). Synangia are sessile and borne in two rows, one on either side of the pinnule midrib, under the unbranched lateral veins. Synangia are radial, 0.6 mm in diam, and consist of a ring of thin-walled sporangia fused to near their apices prior to dehiscence, but separating on dehiscence to release spores along their inner midline. Spores are spherical, trilete, 30-48 μm in diam, with a granulate ornamentation. The new genus Araiangium is proposed for this material based on the organization of the sessile thin-walled synangia. Araiangium is compared with other marattialean genera with sessile synangia (Acaulangium, Acitheca), and with the pedicellate synangia of various species of Scolecopteris. Criteria used in the delimitation of genera in Paleozoic anatomically preserved marattialean fertile foliage are discussed.     

COMPARATIVE STUDIES OF THE NODAL AND VASCULAR ANATOMY IN THE NEOTROPICAL CYATHEACEAE. I. METAXYA AND LOPHOSORIA

Comparative studies of the nodal and vascular anatomy in the monotypic genera Metaxya and Lophosoria are discussed as they relate to the taxonomy and phylogeny of the Cyatheaceae. Both genera are distinctive and primitive with respect to habit, stem and petiole indument, stelar pattern, and nodal anatomy. Metaxya possesses a prostrate, dorsiventral rhizome, whereas a short, upright radial stem occurs in Lophosoria. Trichomes occur on the stems and leaf petioles of these genera. Both Metaxya and Lophosoria have a spiral phyllotaxy, and adventitious buds occur on the petiole bases. The stelar pattern is basically a siphonostele, although frequently a dictyostele is found in Lophosoria. Accessory bundles are lacking in both genera. A characteristic petiole pattern is found in these genera, with an increase in complexity from an undivided strand in Metaxya to the three-parted petiole pattern in Lophosoria. Data from nodal and vascular anatomy indicate that these taxa are distinct from the other genera in the Cyatheaceae and belong in an independent position at the base of the Cyatheoid line, although in some respects an affinity to members of the Dicksoniaceae is indicated.     

COMPARATIVE MORPHOLOGY OF THE COCHLOSPERMACEAE. II. ANATOMY OF THE YOUNG VEGETATIVE SHOOT

The generic scope and systematic position of the Cochlospermaceae were evaluated using observations from the anatomy of the stem, node, and leaf. There are few basic differences in vegetative anatomy between Amoreuxia and Cochlospermum. Secretory cells and canals, dilated phloem rays, and banded phloem are unifying features. Mature nodal anatomy is 3-trace, trilacunar, and the leaves of both genera have elongate, unicellular, branched idioblasts in the spongy mesophyll. Bixa has some features in common with Amoreuxia and Cochlospermum but is distinctive in vascularization of the petiole, leaf anatomy, and vestiture. Rhopalocarpus is quite different from the above genera, and its placement in a separate family is justified on anatomical grounds. The Cochlospermaceae, consisting of Amoreuxia and Cochlospermum, seem more closely related to the Sterculiaceae and Tiliaceae than to the Flacourtiaceae, Cistaceae, or Violaceae.     

Osservazioni Morfologiche Ed Anatomiche Sull' Apparato Sotterraneo Della Carlina Acaulis L.

Abstract

Orservation on the morphology and the anatomy on the subterranean organ of CARLINA ACAULIS L. — The morphology and the anatomy of the subterranean organ of Carlina acaulis L. have been studied in relation to the structure of the analogous organ in Atractylis gummifera L. (Maugini, 1960). It has been shown that the two organs differ markedly: in Carlina there is an evident flattening and dissociation of the stem and a dual anatomical structure, related both to stem and to root.     

THE ORGANIZATION OF THE VASCULAR SYSTEM IN THE STEMS OF THE NYMPHAEACEAE. II. NYMPHAEA SUBGENERA ANECPHYA,LOTOS, AND BRACHYCERAS

The anatomy and organization of the stem vascular system was analyzed in representative taxa of Nymphaea (subgenera Anecphya, Lotos, and Brachyceras). The stem vascular system consists of a series of concentric axial stem bundles from which traces to lateral organs depart. At the node each leaf is supplied with a median and two lateral leaf traces. At the same level a root trace supplies vascular tissue to adventitious roots borne on the leaf base. Flowers and vegetative buds occupy leaf sites in the genetic spiral and in the parastichies seen on the stem exterior. Certain leaves have flowers related to them spatially and by vascular association. Flowers (and similarly vegetative buds) are vascularized by a peduncle trace that arises from a peduncle fusion bundle located in the pith. The peduncle fusion bundle is formed by the fusion of vascular tissue derived from axial stem bundles that supply traces to certain leaves. The organization of the vascular system in the investigated taxa of Nymphaea is unique to angiosperms but similar to other subgenera of Nymphaea.     

Morphological and anatomical contributions to the taxonomical identification of two <Emphasis Type="Italic">Ornithogalum</Emphasis> taxa (<Emphasis Type="Italic">O. nutans and O. boucheanum</Emphasis>) from Flora of Turkey

In this study, morphological and anatomical features of Ornithogalum nutans and O. boucheanum, two relative and morphologically similar species growing in European Turkey, were investigated. These species showed some important anatomical differences with regard to leaf anatomy while they have identical features in stem. The stem anatomy of these two species displays the common properties of monocotyledons. The mesophyll is unifacial and contains monotypic chlorenchyma cells in the leaf of O. nutans. It has no lacunae. The mesophyll in O. boucheanum is equifacial and it has lacunae. This anatomical distinction may be useful for the identification of these similar-looking species.     

ARCHAEOPTERIS MACILENTA,ANATOMY AND MORPHOLOGY OF ITS FROND

The stem, rachides, and pinnae of Archaeopteris macilenta, formerly considered to be a fern of Devonian age, comprise a branch system in which the ultimate divisions heretofore referred to as pinnules are the leaves. The primary vascular system of the “frond” is a lobed siphonostele from which leaf traces arise in a spiral sequence. The anatomy of the “rachis” and of the “pinnae” is shown to be similar to that of the stem, Callixylon, which bore these “fronds.” Branching, epidermal pattern and stomates are described for the spirally arranged leaves (fertile pinnules). Attachment and dehiscence of sporangia as well as their stomates are reported. Archaeopteris is retained in the Class Progymnospermopsida which includes plants with gymnospermous anatomy and pteridophytic reproduction. It is suggested that Actinopodium, Svalbardia and Siderella are related closely to Archaeopteris and that this group of genera shows evolutionary stages in webbing of leaves and planation of branch systems. The opportunities for ontogenetic studies of the arborescent genus Archaeopteris are pointed out.     

Anatomical characterization of Strobilanthes (Acanthaceae) species from the northern Western Ghats of India and its implication for identification at vegetative state

A comprehensive study of stem, leaf and petiole anatomy of 10 species of Strobilanthes from northern Western Ghats of India was carried out to identify characteristics which would enable species identification when flowering material is unavailable. In Strobilanthes, some species bloom annually, others are plietesials, i.e. they grow without blooming for several years and then produce huge quantities of flowers, release seeds and die. Therefore, alternative methods, such as anatomical characters, are essential to distinguish Strobilanthes species in their vegetative stage. We collected ten species of Strobilanthes for anatomical characterization. Under the bright‐field microscope, stem cross‐sections of different species were found to be undulate, quadrangular, quadrangular‐winged or terete. Study of the stem revealed a distinct outer and inner cortex, the distribution of cystoliths (CaCO₃ crystals), raphides (CaC₂H₂O₅ crystals) and sclereids which varied from species to species. Study of leaf anatomy showed structural variation and vascular bundle shapes that differed between the species. Leaf epidermal characters under light and scanning electron microscopy exhibited variation in characters such as stomatal index, stomatal length and width, stomatal type and presence of glandular and non‐glandular trichomes. The petiole anatomy was species‐specific, especially with respect to vascular bundle structure and the distribution of structures such as sclereids, cystoliths, sphaeraphides and tannin cells varied. Hence, unique anatomical features of the stem, leaf and petiole could be used as taxonomic characters to identify Strobilanthes species in a vegetative state.     

THE SYSTEMATICS AND ANATOMY OF GONGYLOCARPUS (ONAGRACEAE)

The unique fruiting structures of the closely related, principally Mexican, monotypic genera Gongylocarpus and Burragea (Onagraceae) compelled a detailed anatomical and cytological investigation of these plants which led to the conclusion that they should be included in a single genus, Gongylocarpus. Gongylocarpus fruticulosus (Burragea), endemic to two adjacent islands off the west coast of Baja California, is divided into two subspecies, subsp. fruticulosus and subsp. glaber. The vegetative and floral anatomy, including wood anatomy, of both species is described. The fruits of these two species grow into the stem by meristematic activity during the course of ontogeny, the ovaries in the mature flower being superficial and sessile in the leaf axil. There is no pedicel associated with the flower, but only a branch gap. Meristematic tissue at the base of the locules divides rapidly at a relatively late ontogenetic stage, the ovaries growing downward into the stem and crushing the pith. The mature, heavily sclerenchymatous fruits are located wholly within the stem, and in G. fruticulosus they are aggregated into long chains. Both species have a gametic chromosome number of n = 11, a characteristic otherwise unknown in the tribe Onagreae but shared with other generalized groups in the family. Taken together with other features, this suggests a primitive position within the tribe for Gongylocarpus.     

Functional anatomy and xylem cavitation resistance of three species of monocotyledons grown on flooded substrates

There are few investigations that analyze the xylem functional anatomy of monocotyledons, as the methods have been developed for woody plants. This study describes the root, rhizome and aerial stem xylem anatomy and functional anatomy of Canna indica, Cyperus papyrus and Phragmites communis grown on flooded substrates; and it aims to evaluate the relationship between the xylem anatomy and its cavitation resistance. To calculate the indexes of vulnerability, mesomorphy, collapse and relative hydraulic conductivity in the three organs mentioned, the diameter, number of vessels per mm², thickness of the walls and the length of the tracheal elements were recorded. In addition, the xylem specific conductivity of the aerial stem was measured with the pipette method, and its resistance to cavitation was determined experimentally by the air injection technique. The protoxylem is xeromorphic, it has longer vessel elements, smaller diameters, thin walls and scalariform perforation plates, whereas the metaxylem is mesomorphic, with shorter vessel elements, larger diameters, thicker walls and simple perforation plates. Both present low collapse resistance but have a high relative hydraulic conductivity. P. communis recorded the highest cavitation resistance, and the number of vessels per mm² was related to xylem cavitation resistance in Canna indica and Cyperus papyrus. The experimental results of this investigation match partially the anatomical indexes and showed that the xylem of these species has a low specific conductivity and is more vulnerable to cavitation than that of other monocots.     

Comparative vegetative anatomy and classification of Diseae (Orchidaceae)

The leaf, stem, root, tuber and dropper anatomy of the orchid tribe Diseae (including the subtribes Satyriinae, Disinae, Brownlecinac, Huttonaeinae and Coryciinae) is reviewed. The study is largely based on investigations of 123 species, and data from several previous publications have also been incorporated. Two characters were identified as being taxonomically valuable: (1) the presence of sclerenchyma caps associated with leaf vascular bundles, and (2) the degree of dissection of the siphonostele of the tuber (‘polystelic’ or ‘monostelic’). The phylogenetic analysis shows that anatomical characters do not change the basic structure of a cladogram that is based on morphological characters. The taxa of Diseae are discussed on the basis of anatomical data. Subtribes Satyriinae (excluding the anatomically unusual genus Pachites), Brownleeinae, Huttonaeinae, and Coryciinae are uniform in. critical anatomical characters. However, subtribe Disinae is rather diverse in vegetative anatomy. Disa sect. Micranthae differs from the rest of the genus in its leaf anatomy. The occurrence of foliar sclerenchyma bundle caps and ‘polystelic’ tubers supports the incorporation of Herschelianthe in Disa sect. Stenocarpa.     

Regulation of intestinal stem cells in mammals and Drosophila

The digestive systems in mammals and Drosophila are quite different in terms of their complexity and organization, but their biological functions are similar. The Drosophila midgut is a functional equivalent of the mouse small intestine. Adult intestinal stem cells (ISCs) have been identified in both the mouse small intestine and Drosophila midgut. The anatomy and cell renewal in the Drosophila midgut are similar to those in the mouse small intestine: the intestinal epithelium in both systems is a tube composed of epithelial cells with absorptive and secretory functions; the Notch signaling controls absorptive versus secretory fate decisions in the intestinal epithelium; cell renewal in both systems starts from stem cells in the basal cell layer, and the differentiated cells then move toward the lumen. However, it is clear that the stem cells in the two systems are regulated in different ways. In this review, we will compare cell renewal and stem cell regulation in the two systems. J. Cell. Physiol. 222:33–37, 2010. © 2009 Wiley‐Liss, Inc.     

Stem Anatomy of Uebelmannia (Cactaceae) — with Special Reference to Uebelmannia gummifera

The three species of Uebelmannia (Cactaceae: Cactoideae; endemic to Minas Cerais, Brazil) are noteworthy for their tough, bumpy stem surface and the presence of conspicuous mucilage cavities restricted to the outer part of the stems. The anatomy of the mature structures and their ontogeny was investigated from microtome sections. The uncommon surface relief is caused by groups of unequally elongated hypodermis cells. The mucilage cavities consist of solitary and considerably enlarged mucilage cells (U.buiningii and U. pectinifera). In U.gummifera groups of mucilage cells disintegrate and form large cavities which are finally united into longitudinal ducts. A comparison of these stem features with species of the superficially similar genera Islaya and Wigginsia (representing tribe Notocacteae), does not indicate a close phylogenetic relationship between Uebelmannia and members of tribe Notocacteae. Finally, some short comments touch on the adaptational aspect of the characteristic stem features of Uebelmannia.     

Osteology and relationships of Thaiichthys nov. gen.: a Ginglymodi from the Late Jurassic – Early Cretaceous of Thailand

Abstract: The osteology of Thaiichthys buddhabutrensis, nov. gen., from the Late Jurassic – Early Cretaceous of Thailand is described on the basis of a collection of well‐preserved specimens. The mode of preservation of the material allows describing the external anatomy, as well as some elements of the internal anatomy (braincase, elements of the vertebral column). Most of the cranial and postcranial skeleton shows a rather conservative anatomy for ‘semionotiformes’, but the jaw apparatus displays specializations. Variations observed in the ossification pattern of the skull roof and of the cheek, in the morphology of the median dorsal scales and in fin rays’ count indicate that caution should be applied when these characters are used in diagnoses and in phylogenetic analyses. A phylogenetic analysis including a set of gars, of ‘semionotiformes’, of Macrosemiiformes and of Halecomorphi shows the following features: (1) the monophyly of Holostei; (2) sister‐pair relationships between Tlayuamichin/Semiolepis, Isanichthys/’Lepidotes’ latifrons and Araripelepidotes/Pliodetes; (3) the latter pair, together with Thaiichthys and possibly ‘Lepidotes’ mantelli, are resolved as stem Lepisosteiformes; and (4) the ‘semionotiformes’ (a group gathering species of Semionotus and Lepidotes) do not form a clade.     

Anatomical and nutlet differentiation between <Emphasis Type="Italic">Teucrium montanum</Emphasis> and <Emphasis Type="Italic">T. polium</Emphasis> from Turkey

Teucrium montanum L. and T. polium L. are the two closest Teucrium L. species from sect. Polium (Mill.) Schreb in Turkey. In addition, they are sympatric for some part of their range in Turkey. In this study, comparative anatomical and micromorphological studies of the two species are carried out. They have been investigated by their leaf and stem anatomical features, as well as nutlet micromorphological characteristics. The results of anatomical studies show that the anatomical characters of both taxa are observed to be similar to the general features of the family Lamiaceae anatomy, except for lacking rich collenchyma at the corners. Both taxa are similar in stem anatomy and their leaves exhibit xeromorphy. However, trichome morphology on the stems and the leaves appear to have a taxonomic value in segregation of the two taxa. Light and scanning electron microscope studies on the nutlets also show that nutlet shapes, measures and surface micromorphologies are different in the two species. Whereas nutlet surfaces are bireticulate in both species, the nutlets are larger and primary sculpturing is more distinct in T. polium than in T. montanum. Moreover, the nutlets are oblong to oblong-ovoid and larger in T. polium, but ovoid and smaller in T. montanum.     

VASCULAR PATTERNS IN STEMS OF ARACEAE: SUBFAMILIES COLOCASIOIDEAE,AROIDEAE AND PISTIOIDEAE

The stem vasculature of ten genera of Colocasioideae and three genera of Aroideae was analyzed by films of series of cross sections. The technique was unsuited for the numerous tuberous genera of Aroideae (and Pistia), which have shortened internodes. The Colocasioideae has long been recognized as one of the most natural large assemblages in the Araceae, a concept further supported by information from stem anatomy and vasculature. All species examined have amphivasal axial bundles that undergo frequent anastomosis and bifurcation of a seemingly irregular kind. Syngonium is the only viny genus and is exceptional in a number of anatomical features which are associated with its unusual morphology. One of the principle points of diversity in the Colocasioideae is the presence or absence of a permanent cortical vascular system. All four genera with a permanent cortical system (Caladiopsis, Caladium, Xanthosoma, and Syngonium) are neotropical. In the Aroideae (and Pistioideae) all of the tuberous genera have a highly condensed vascular system. Genera with elongated internodes (Stylochiton, Lagenandra, Cryptocoryne) also have a similar pattern, which makes taxonomic comparisons based on stem vasculature in the Aroideae of little value. Branch trace insertion is much less well developed in Colocasioideae and Aroideae than in most other subfamilies.     

Structural and ultrastructural differences between field,micropropagated and acclimated leaves and stems of two Leucospermum cultivars (Proteaceae)

The anatomy of field, in vitro and acclimatized shoots (leaves and stems) of two cultivars of Leucospermum (L. cordifolium ‘Flame Spike’ and L. ‘Tango’) was compared using light, scanning and transmission electron microscopy. Field plants showed several scleromorphic anatomical structures related to excess solar radiation such as: cuticle thickness, subepidermal collenchyma and sclerenchyma. Furthermore, a large quantity of phenolic deposits present in the cell lumen of various tissues is also a scleromorphic feature. The special conditions during in vitro culture result in plantlets with abnormal morphology and anatomy. These disorders are associated with the gaseous environment in the culture vessels, low irradiance in the incubation chamber and the addition of sucrose, nutrients and growth regulators to the culture medium. After transfer from in vitro to ex vitro conditions, substantial changes in leaf and stem anatomy were observed, above all in cuticle thickness, epidermal characteristics (stomatal and trichome index, and stomatal and pore size), differentiation of leaf mesophyll, chloroplast structure, and amount and localization of phenolic deposits. These changes allowed the plants to adapt to the new environmental conditions. The study of anatomical features of in vitro shoots facilitated adapting the acclimation protocol to predict which plantlet would survive the critical acclimation stage.