Ultrastructure of meiosis in the mossRhynchostegium serrulatum I. Prophasic microtubules and spindle dynamics

Summary An extensive system of microtubules develops during meiotic prophase in the mossRhynchostegium serrulatum (Hedw.)Jaeg. &Sauerb. Development of the cytoskeleton can be traced to early prophase when the nucleus is acentric and the single plastid divides into four plastids. The cytoskeletal microtubules are associated with equidistant positioning of the four plastids at the distal tetrad poles and with migration of the nucleus to a central position in the sporocyte. The cytoskeleton, which interconnects plastids and encloses the nucleus, contributes to the establishment of moss sporocyte polarity. Just prior to metaphase I evidence of the prophase cytoskeleton is lost as the bipolar metaphase I spindle develops in association with discrete polar organizers located in opposite cleavage furrows between plastids.     

Division polarity,development and configuration of microtubule arrays in bryophyte meiosis

Summary First and second division spindles and the three cell plates of moss meiosis are oriented in accordance with polarity established during meiotic prophase. Plastids are located at the second division poles and cytoplasmic infurrowing marks the planes along which the cytoplasm will cleave into four spores. Anaphase I spindles that terminate in two focal points of microtubules straddling opposite cleavage furrows reflect the unusual tetrahedral origin of the functionally bipolar spindle. The organelles (except for the plastids which remain in the four cytoplasmic lobes) are polarized in the first division equatorial region at the time of phragmoplast microtubule assembly and remain in a distinct band after microtubule disassembly. Prophasic spindles appear to be directly transformed into metaphase II spindles in the predetermined axes between mutually perpendicular pairs of plastids. Cell plates form by vesicle coalescence in the equatorial regions of the two sets of second division phragmoplasts at approximately the same time as a cell plate belatedly forms in the organelle band. The cytoplasmic markers (plastid migration, cytoplasmic lobing and infurrowing) that predict poles and cleavage planes in free cells lacking a preprophase band strongly strengthens the concept that division sites are capable of preserving preprogrammed signals that can be triggered later in the process of cell division.     

Division polarity,development and configuration of microtubule arrays in Bryophyte meiosis

Summary Immunofluorescence and TEM studies of meiosis in two mosses (Bryophyta) provide evidence that the prophasic tetrahedral system of microtubules contributes directly to the metaphase I spindle. Intense staining of tubulin, conspicuously absent around the nuclear envelope, is first seen associated with plastids. By mid-prophase, microtubules radiate from the plastids to the nuclear envelope and become organized into six bands that interconnect the four plastids, forming a tetrahedral cytoskeleton surrounding the nucleus. During transition of prophase to metaphase, the four poles of the tetrahedral microtubule system converge in pairs toward opposite cleavage furrows. Opposite furrows occupy mutually perpendicular planes and the pair of microtubule focal points straddling one furrow lies at right angles to the pair straddling the opposite furrow. Additional microtubules terminate in numerous small clusters in the concave polar regions arching over the cleavage furrows. By early anaphase, the microtubule focal points lie very close to the division axis. We conclude that microtubules recruited from the prophasic quadripolar system are incorporated into the mature metaphase I spindle and the two principal focal points at each pole are those derived from poles of the prophasic quadripolar system.     

Minispindles and cytoplasmic domains in microsporogenesis of orchids

Summary Changes in the microtubular cytoskeleton during meiosis and cytokinesis in hybrid moth orchids were studied by indirect immunofluorescence. Lagging chromosomes not incorporated into telophase nuclei after first meiotic division behave as small extra nuclei. Events in the microtubular cycle associated with these micronuclei are similar to and synchronous with those of the principal nuclei. During second meiotic division the micronuclei trigger formation of minispindles which are variously oriented with respect to the two principal spindles. After meiosis, radial systems of microtubules measure cytoplasmic domains around each nucleus in the coenocyte. Cleavage planes are established in regions where opposing radial arrays interact and the cytoplasm cleaved around micronuclei is proportionately smaller than that around the four principal nuclei. These observations clearly demonstrate that nuclei in plant cells are of fundamental importance in microtubule organization and provide strong evidence in support of our recently advanced hypothesis that division planes in simultaneous cytokinesis following meiosis are determined by establishment of cytoplasmic domains via radial systems of nuclear-based microtubules rather than by division sites established before nuclear division.Abbreviations DMSO dimethylsulfoxide - FITC fluorescein isothiocyanate - MTOC microtubule organizing center - PBS phosphate buffered saline - PPB preprophase band of microtubules     

Behavior of plastid nucleoids during male gametogenesis inPlumbago auriculata

Summary We characterized the behavior of plastid (pt) and mitochondrial (mt) nucleoids during malegametogenesis inPlumbago auriculata in three dimensions. The behavior of pt-nucleoids and mt-nucleoids differed throughout male gametogenesis.Pt-nucleoids were distibuted in a characteristic manner in three stages: in the early microspore, pt-nucleoids assemble around cell nucleus: in the mid-generative cell,pt-nucleoids gather at the internal side of the pollen: in the late-generative cell, pt-nucleoids aggregation turns its pole to the external side of the pollen. We also studied organelle nucleoids in the egg and the central cell by a method in which semi-thick sections of resin-embedded anthers and ovaries were observed by confocal laser scanning microscopy. The number of pt-nucleoids in the sperm cell did not differ significantly from that the behavior of DNA-containing organelles is regulated strictly during male gametogenes inP. auriculata, and that a biparental inheritance of plastids in the Plumbago embryo is more favored than was previously thought.     

Megagametophyte abnormalities of near-isogenic female partial-sterile soybean mutants (Glycine max; Leguminosae)

Megagametogenesis of soybean, Glycine max (L.) Merr., cultivars Clark and Clark k2, and F1 hybrid of Clark (female parent) crossed with Clark k2 (male parent) were studied using stereo light microscopy and confocal scanning laser microscopy. Reproductive development in Clark and Clark k2 plants was compared to F1 hybrid plants. In mature pods, 6.4% of the ovules of Clark, 8.1% of the ovules of Clark k2, and 41.4% of the ovules of F1 hybrid plants were aborted. This female partial sterility was due to incomplete megagametophyte development: undeveloped polar nuclei—or developed but not in a position for fertilization; increased megagametophyte wall thickness; abnormal shape and/or premature degeneration of synergids and intact synergids throughout the life of the ovule; egg cell not well-developed or absent; and megagametophyte remaining uninucleate. Each of these abnormalities contributed to either lack of double fertilization or early megagametophyte abortion. Electronic Publication     

Carbendazim (MBC) disrupts oocyte spindle function and induces aneuploidy in hamsters exposed during fertilization (meiosis II)

Peri-fertilization exposure to Carbendazim (MBC; a microtubule poison) induces infertility and early pregnancy loss in hamsters. Presently, both in vivo and in vitro techniques were employed to characterize the effects of MBC on cellular aspects of fertilization in hamsters. Exposure to MBC during either in vivo or in vitro fertilization (IVF) induced identical morphological abnormalities in the maternal chromatin of zygotes and embryos. These abnormalities included either multiple second polar bodies (PB₂), and/or multiple small female pronuclei (PN), or meiotic arrest. Multiple PB₂, multiple female PN, multiple PB₂ with multiple female PN, or meiotic arrest were exhibited by approximately 31%, 15%, 12%, and 2% of the in vivo zygotes; and 3%, 16%, 36%, and 20% of IVF zygotes, respectively. The effects of MBC persisted to day 2 of pregnancy as indicated by decreased (P ≤ 0.05) embryo development to the two-cell stage and the presence of micronuclei in 6% of two-cell embryos from MBC-treated females. Immunofluorescence analysis of microtubules (MTs) confirmed that MBC disrupted spindle MTs during IVF. Numerical chromosome analysis revealed that a single dose of MBC administered during in vivo fertilization induced aneuploidy in the resulting pronuclear-stage zygotes. The present data point to two mechanisms by which peri-fertilization MBC exposure may induce early pregnancy loss: 1) arrested meiosis with no zygotic cleavage; or 2) induction of zygotic aneuploidy with subsequent developmental arrest. © 1995 wiley-Liss, Inc.     

The somatic musculature of Bryceella stylata (Milne, 1886) (Rotifera: Proalidae) as revealed by confocal laser scanning microscopy with additional new data on its trophi and overall morphology

The monogonont rotifer Bryceella stylata was investigated with light, electron and confocal laser scanning (CLSM) microscopy to provide detailed insights into its anatomy and new information for future phylogenetic analyses of the group. Results from CLSM and phalloidin staining revealed a total of six paired longitudinal muscles (musculi longitudinales I-VI) and eight circular muscles (musculi circulares I-VIII) as well a complex network of mostly fine visceral muscles. In comparison with other rotifer species that have been investigated so far, B. stylata shares the presence of the circular and longitudinal muscles: musculus longitudinalis ventralis, musculus longitudinalis lateralis inferior, musculus longitudinalis dorsalis, musculus longitudinalis capitis and musculus circumpedalis. However, the species lacks lateral and dorsolateral longitudinal muscles and some circular muscles (e.g., corona sphincter, musculus pars coronalis). With light and electron microscopy, we were able to document the precise number of pseudosegments and the arrangement of the chambers comprising the trophi elements. Furthermore, our observations revealed several new morphological characteristics, including a shield-like epidermal projection covering the dorsal antenna, an epidermal projection restricting the corona caudally and an unpaired hypopharynx with distinct shovel-like structures.     

Paclitaxel and vinorelbine cause synergistic increases in apoptosis but not in microtubular disruption in human lung adenocarcinoma cells (A-549)

Concurrent administration of paclitaxel and vinorelbine results in cytotoxicity in vivo and in vitro in a number of tumor cell lines, yet the mechanisms of enhanced cell killing are undefined. In studies here, we show that low concentrations (1 nM) of paclitaxel and vinorelbine in combination result in enhanced cell killing by apoptosis (P<0.05) in the human lung adenocarcinoma cell line, A-549. In contrast, necrotic cell death and formation of multinucleated cells, which were significantly increased by paclitaxel (P<0.05) alone, but not vinorelbine, were not increased synergistically by both drugs. Paclitaxel also caused microtubular disruption which was not observed with vinorelbine. These data provide further rationale for the combined use of paclitaxel and vinorelbine in clinical trials, and suggest that the cooperative effects of drugs on apoptosis are not mediated through similar disruptional effects on microtubules.     

Preprophasic microtubule systems and development of the mitotic spindle in hornworts (Bryophyta)

Summary Studies of monoplastidic mitosis in hornworts (Bryophyta) using transmission electron microscopy and indirect immunofluorescence staining of microtubules have revealed that two mutually perpendicular microtubule systems predict division polarity in preprophase. Events of cytoplasmic reorganization in preparation for division occur in the following order: migration of the single plastid to a position perpendicular to the division site, constriction of the plastid where its midpoint intersects the division site, development of an axial system of microtubules parallel to the elongating plastid isthmus, and appearance of an atypical preprophase band of microtubules (PPB). The PPB is asymmetrical with a tight band of microtubules on the side over the plastid isthmus and a broad band of widely spaced microtubules over the nucleus. The axial system contributes directly to development of the spindle. In prometaphase, the axial system separates at the equator and additional microtubule bundles project from polar regions, creating two opposing halfspindles. The PPB is still present during asymmetrical organization of the spindle and microtubules extending from the broad portion of the PPB to poles appear to be incorporated into the developing spindle. Dynamic changes in the microtubular cytoskeleton demonstrate (1) intimate relationship of plastid and nuclear division, (2) contribution of preprophase/prophase microtubule systems to spindle development in monoplastidic cells, and (3) dynamic reorientation of microtubules from one system to another.     

Use of confocal laser scanning microscopy on soil thin-sections for improved characterization of microbial growth in unconsolidated soils and aquifer materials

Confocal laser scanning microscopy (CLSM) was utilized to examine samples from an aquifer microcosm that was used to investigate microbially mediated losses in hydraulic conductivity. Samples were fixed, dehydrated and dried to prepare the biological material in a fashion similar to that used previously for viewing under the scanning electron microscope. Then, samples were prepared as thin-sections by employing soil micromorphological techniques. Serial images generated by the CLSM technique were visualized using computer three-dimensional rendering software. Results from the CLSM technique were compared with simple fluorescence microscopy of thin-sections and scanning electron microscopy (SEM) of samples from the microcosm. Computer visualization of serial sections with the CLSM technique provided images on a submicron scale in three dimensions. SEM has a much higher resolution, on a nanometer scale, but the results are not three dimensional. Artifacts associated with thin-section preparation are minimal for natural porous media composed mostly of sand, such as aquifer materials. Also, CLSM images are affected minimally by changes to biological material due to sample preparation, whereas artifacts associated with SEM images are very prominent, due to the higher magnification and resolution. CLSM of thin-sections and SEM are very powerful methods for viewing microbial growth in natural porous media, but CLSM is preferable because it allows three-dimensional visualization and measurements of cells and aggregates with few artifacts.     

Chloroplast division polarity,a marker of cell division planes during morphogenesis inBangia vermicularis Harvey (Rhodophyceae)

Summary Ultrastructural observations of dividing cells inBangia vermicularis revealed a type of chloroplast division (plastokinesis) not previously reported in the red algae. The polarity of this prekaryokinetic process serves as a reliable marker of the plane of cytokinesis, a key factor in establishing thallus morphology. At the onset of division one or more invaginations develop in the envelope of the large, lobed chloroplast and proceed centripetally through the stroma in the plane of the thylakoids, forming narrow cytoplasmic channels (CCs). The thylakoids are realigned somewhat, but are not constricted as the chloroplast is divided into two or more units. The number of resulting chloroplasts and the orientation of the CCs are dependent on cell type. Distinctive cylindrical cells at the base of the filamentous region, immediately distal to the holdfast, are shorter than broad and contain a central nucleus surrounded by a doughnutshaped chloroplast. The cylindrical morphology of the thallus is established early in the first periclinal division as multiple plastokinesis commences, generating several radially-arranged daughter chloroplasts. Cleavage of the original chloroplast is completed during subsequent cell divisions in the initial developmental stage, finally resulting in eight chloroplasts that are distributed to an equal number of wedge-shaped radial cells. Cells distal to the actively dividing basal cells are cuboidal and have a peripheral nucleus. Division of the single chloroplast prior to karyokinesis in these cells results in two or four daughter chloroplasts according to cell type. During or following plastokinesis, multilamellar bodies derived from the CE appear to serve as the source of membranes for the developing septum in the channels. Septa link to proliferations of the plasmalemma in areas of slight cell wall (CW) indentations, and are completed between daughter nuclei after karyokinesis, producing a cleavage channel. Subsequently, primary CW material is deposited between the two septal membranes. The shape and arrangement of daughter cells in each of the developmental stages in the thallus are defined by the planes of cell division. These are indicated by both the orientation of CCs and the polar orientation of nuclear division which is always at right angles to the CC.Abbreviations CC cytoplasmic channel - CE chloroplast envelope - CW cell wall - ER endoplasmic reticulum - MLB multilamellar body     

Changes in the Pattern of Organization of Microtubules During Microspore Formation in Rice (Oryza sativa L.)

Changes in the pattern of organization of microtubules in the developing microspore of rice ( Oryza sativa L. ) have been followed using immunofluorescence confocal microscopy. At the microsporocyte stage of development the cell possessed a network of highly branched and thickened microtubule bundles. In the central cytoplasm numerous bundles mn circumferentially around the nucleus. From the circumferentially distributed microtubule bundle network some microtubule bundles radiated towards the conical region of the cell. The microsporocyte after Meiosis Ⅰ became a dyad. In the dyad cell microtubule bundles emanated radially from the nucleus. In the cortex of the dyad cell some of the microtubule bundles became randomly oriented. The dyad then underwent Meiosis Ⅱ to become tetrad. Microtubule bundles in the tetrad cell radiated from the nucleus. No randomly oriented microtubule bundles were present in the cortical region of the tetrad cell. Mter- wards the four cells that made up the tetrad dissociated from each other and each became a microspore. At the early stage of the microspore development most of the microtubule bundles were randomly distributed. Later, some of the microtubules converged towards a bud-like cytoplasmic protrusion. This bud-like protrusion later developed into a germ pore (or pollen pore). At the late stage of microspore formation, microtubule bundles became thinner and reticulately oriented to form a tightly knitted network.     

四唑盐减低法结合激光共聚焦显微镜定量分析表皮葡萄球菌生物被膜体外模型

目的建立体外表皮葡萄球菌(Staphylococcus epidermidis)生物膜(biofilm,BF)模型,观察和定量分析表皮葡萄球菌BF的动态形成过程。方法采用可形成BF的表皮葡萄球菌RP62A,平板法建立体外BF模型,四唑盐(tetrazolium salt,XTT)减低法定量检测BF形成过程中细菌活力的变化,激光共聚焦显微镜(confocal laser scan-ning microscopy,CLSM)结合图像结构分析软件(image structure analyer,ISA)对BF形成过程结构参数进行动态分析,扫描电镜(scanning electron microscope,SEM)观察BF形成过程中的形态结构。结果在12、24和48 h时,XTT减低法A450的值分别为2.39±0.48、3.41±0.18和3.92±0.27,P0.05;ISA软件定量分析显示在区域孔径(AP)的值分别为0.84±0.08、0.68±0.01和0.59±0.13,P0.05,平均扩散距离(ADD)的值分别为1.34±0.24、1.49±0.09和1.89±0.39,P0.05,结构熵(TE)的值分别为4.71±0.82、8.69±0.68和8.94±0.28,24 h、48 h与12 h相比,P0.05。结论表皮葡萄球菌BF的形成是个动态的过程,24 h时BF基本形成,48 h BF结构更加复杂。XTT减低法,CLSM结合ISA软件,SEM三种方法联合使用是观察和定量分析体外BF模型较理想的方法。     

Confocal Microscopic Observations on Microtubular Cytoskeleton Changes During Megasporogenesis and Megagametogenesis in Phaius tankervilliae (Aiton) Bl.

In nun orchid (Phaius tankervilliae (Alton) B1. ) embryo sac development follows the monosporic pattern. Changes in the pattern of organization of the microtubular cytoskeleton during megasporogenesis and megagametogenesis in this orchid were studied using the immunofluorescence technique and eonfocal microscopy. At the initial stage of development the microtubules in the arehesporium were randomly oriented into a network. Later the archesporial cell elongated to form the megasporocyte. The cytoskeleton in the elongated megasporoeyte was radially organized in which microtubules extending from the nuclear envelope to the peripheral region of the cell. The megasporoeyte then underwent meiosis 1 to form a dyad. The dyad cell at the chalazal end was larger than the cell at the micropylar end. Microtubules in the dyad cell were radially oriented. The dyad underwent meiosis to give rise to a linear array of four megaspores (i. e. tetrad formation). The chalazal-far most megaspore survived and became the functional megaspore, which contained a set of randomly oriented microtubules. The microtubules in the other 3 megaspore disappeared as the cells degenerated. The functional megaspore then underwent mitotic division giveing rise to a 2 nucleate embryo sac. The nuclei of the 2-nucleate embryo sac were separated by a set of longitudinally oriented microtubules which ran parallel to the long axis of the embryo sac. Each nucleus in the embryo sac was surrounded by a set of perinuelear microtubules. The gnucleate embryo sac again underwent mitotic division to form a 4-nucleate embryo sac. The division of the two nuclei was synchronous. But the orientation of the division plan of the two spindles was different (i. e. the spindle microtubules at the chalazal end ran parallel with the long axis of the embryo sac and those at the mieropylar end ran at right angle to the axis of the embryo sac). The 4 nuclei of the 4-nucleate embryo sac were all tightly surrounded by randomly oriented microtubules. Later the paired nuclei at the micropylr end and at the chalazal end as well underwent mitotic division in seguence. At this time when the embryo sac had reached the 8-nucleate embryo sac stage. The pattern of organization of the microtubules was very complex. Initially the nuclei were surrounded by a set of randomly oriented microtubules, but after the two polar nuclei had moved to the central region of the embryo sac, three different organizational zones of microtubules appeared, viz: a randomly oriented set of microtubules surrounding each nucleus in the chalazal zone: a set (in the form of a basket) of cortical microtubules which surrounded the vacuoles and the two polar nuclei in the central zone and a loosely knitted network of microtubules surrounding the nucleus that later became the egg cell nucleus in the micropylar zone. The two nuclei that would become the nuclei of the synergids were surrounded by a set of more densely packed mierotubules. Towards far the most micropylar end some microtubules formed thick bundles. The site of appearance of these thick bundles coincided with the site of development of the filiform apparatus. The pattern of microtubule organization after cellularization (i. e. at the beginning of embryo sac maturation) did not change much. The author's results indicated that various patterns of microtubule organization observed in the developing embryo sac of nun orchid reflected the complexity and dynamism of the embryo sac.     

Directional cell-to-cell communication in theArabidopsis root apical meristem I. An ultrastructural and functional analysis

Summary As a foundation for studies on directional intercellular communication and its regulation in apical development, the network of plasmodesmata inArabidopsis root apical meristems was characterized by quantitative electron microscopy and dye-coupling analysis, using symplasmic probes, and real-time imaging in confocal laser scanning microscopy. A tissue-specific plasmodesmatal network, which interconnected the cells in the root apical meristem, was characterized by the following features, (a) Plasmodesmatal distribution and density were found to be tissue-specific, (b) Primary and secondary plasmodesmata were differentially grouped and regulated. Primary plasmodesmata were formed in large numbers in the transverse walls of each tissue, and were subject to deletion during cell differentiation. Secondary plasmodesmata were mostly distributed in longitudinal walls between cell files and common walls between neighboring tissues; they also provided a symplasmic path between different initial tiers in the meristem. Small fluorescent tracers moved through the plasmodesmatal network of the root apical meristem in two distinct phases. At low concentrations molecules trafficked in a non-tissue-specific manner, whereas at higher concentrations, their distribution reflected the presence of tissue-specific movement consistent with plasmodesmatal distribution. These findings are discussed in terms of the role of tissue-specific plasmodesmatal domains in the control of root development.     

Three-dimensional reconstruction of mushroom body neuropils in the polychaete species <Emphasis Type="Italic">Nereis diversicolor</Emphasis> and <Emphasis Type="Italic">Harmothoe areolata</Emphasis> (Phyllodocida,Annelida)

Mushroom bodies are prominent brain neuropils present in most arthropod representatives. Similar structures in the brain of certain polychaete species are possibly homologous to these structures. Using three-dimensional reconstruction techniques, we investigated the structural composition of the mushroom body neuropils in the polychaete species Nereis diversicolor and Harmothoe areolata. Comparative analysis revealed a common organization of neuropil substructures in both species that closely matches the basic assembly of arthropod mushroom bodies. Concurring with earlier homology assessments, these neuroarchitectural similarities provide support for a common origin of mushroom body neuropils in polychaetes and arthropods. Beyond that, differences in the morphological differentiation of neuropil substructures indicate polychaete mushroom bodies to show a high degree of morphological variability, thus impeding the quest for a common ground pattern of these brain centers.     

Pseudopollen and food-hair diversity in Polystachya Hook. (Orchidaceae)

Labellar food-hairs in Polystachya Hook. exhibit considerable morphological diversity. The commonest type of trichome is uniseriate, two to four-celled, with a clavate or subclavate terminal cell. This type occurs amongst representatives of most sections examined. Other trichomes are bristle-like with tapering or fusiform terminal cells, whereas representatives of section Polystachya have uniseriate, moniliform trichomes that fragment with the formation of rounded or elliptical component cells. Most contain protein and, while some contain starch, lipid is invariably absent. The presence of particular types of labellar trichomes does not coincide with variations in vegetative morphology. Thus, current taxonomic treatment of the genus indicates that trichome types, with perhaps the sole exception of moniliform, pseudopollen-forming hairs found in section Polystachya only, have limited taxonomic value. However, the remarkable similarity between pseudopollen-forming hairs of Polystachya and those of the Neotropical genus Maxillaria in terms of morphology, cellular dimensions and food content indicates that pseudopollen may have arisen several times and evolved in response to similar pollinator pressures.     

The legs of “spider associated” parasitic primary larvae of Mantispa aphavexelte (Mantispidae,Neuroptera) – Attachment devices and phylogenetic implications

The legs of the primary larva of Mantispa aphavexelte, parasite in egg sacks of spiders, were examined using scanning electron microscopy (SEM), histology and confocal laser scanning microscopy (CLSM). The leg morphology is described in detail, including intrinsic muscles. Functional adaptations of the leg attachment devices are discussed, especially regarding the material composition. For example, a sole-like flexible ventral tarsal surface containing resilin is combined with sclerotized pseudo-claws. This likely enables the larvae to cope with surface structures on the spider's body, with substrates on the ground, and also with various structural elements in the spider's nest. The leg morphology is evaluated with respect to phylogenetic affinities. A trumpet-shaped, elongated empodium has likely evolved early in the evolution of Neuroptera and may consequently belong to the groundplan of a large subgroup of the order. It characterizes most groups of the hemerobiform lineage and is also present in the myrmeleontiform Psychopsidae. The presence of a tarsal protrusion resembling a pretarsus confirms the monophyletic origin of Mantispoidea. A single fixed tooth and a specific surface structure are potential autapomorphies of Mantispidae. A distal tibial subunit partly separated from the main part of the leg segment is an apomorphy only described for larvae of M. aphavexelte.     

Seed micromorphology in the genus Neotinea Rchb.f. (Orchidaceae, Orchidinae)

The ultrastructure of testa seed in the genus Neotinea (Orchidaceae, Orchidinae) was examined for the first time. The morphology of the seed and of the anticlinal and periclinal walls was analysed by scanning electron microscopy. Quantitative data concerning the length and width of the seed and embryo, seed and embryo volume, free air space, and number of cells along the longitudinal axis are presented. In all species, the seeds are fusiform in shape with transverse ridges on the inner periclinal walls. This ornamentation pattern is characteristic for the genus Neotinea . It is a good diagnostic value supporting the monophyly of this genus, which has recently been proposed by several authors.  © 2007 The Linnean Society of London, Botanical Journal of the Linnean Society , 2007, 153 , 133–140.