Embryology ofKyllinga monocephala (Cyperaceae) and its systematic position

Aspects of the life history ofKyllinga monocephala are described. Anther wall development corresponds to the Monocot type. The endothecium shows spiral thickenings. The tapetum is glandular and has uninucleate cells. Ubisch granules are present. Mature pollen grains (pseudomonads) are 3-celled at maturity. Ovules are bitegmic, crassinucellate and develop a funicular obturator. The embryo development conforms to theJuncus-variation of the Onagrad type. Endosperm, seed coat and pericarp are described.     

The fine structure of the pollen wall inStrelitzia reginae (Musaceae)

The pollen wall ofStrelitzia reginae (Musaceae) consists of a nearly unsculptured, very thin, highly reduced, but coherent exine, and a thick intine (with an outer, channeled layer and an inner, largely homogeneous layer). After short, incomplete acetolysis the exine covers the remaining, severely shrinked protoplast as a folded, but unaltered “skin”, while the intine has totally disappeared. After extended acetolysis only the coherent, skin-like exine remains. Thus, the term “exine-less pollen” sometimes used for similar sporoderm structures in other genera ofZingiberales is misleading and should be substituted by the term “skin-like exine”. Surprisingly, the peculiar pollen wall ultrastructure ofStrelitzia and some otherZingiberales is very similar to that of some genera of theLaurales, an example for convergent evolution within the angiosperms.     

Distribution of the protein “phaseolin“ in some representatives ofViciaceae

Using immunochemical methods the authors investigated the evolutionary taxonomic distribution of the reserve seed protein “phaseolin” in cultivars ofPhaseolus vulgaris, in a series of species ofPhaseolus, and in representatives of some additional genera ofViciaceae. “Phaseolin” is typical of the seed ofPhaseolus vulgaris L.: it was detected in all 658 investigated cultivars — and also in species related toPhaseolus vulgaris L.(Ph. vulgaris L. ssp.aborigineus Burk.,Ph. polyanthus Green,Ph. dumosus Macf.,Ph. coccineus L., and in an undescribed species from the group ofPh. vulgaris L. -Ph. coccineus L.). A protein immunochemically somewhat similar to ?phaseolin“ occurs inPh. acufifolius A. Gray. In all other taxa“phaseolin” is absent.     

Anthoxanthum odoratum andA. alpinum: Life history parameters at two different altitudes

The closely related species, diploidAnthoxanthum alpinum Á. Löve etD. Löve and tetraploidAnthoxanthum odoratum L., have distinct distributions:A. alpinum is an arctic-alpine species, whileA. odoratum is a species of lower altitudes and more southerly latitudes. However, some authors suggest that both species are potentially able to maintain their populations in the distribution area of the other species. Reciprocal transplant experiments in two mountain localities (one withA. alpinum, the other withA. odoratum) were carried out to study the survival and vegetative and generative reproduction of tussocks of both species in the area of distribution of the other species. The mortality of tussocks ofA. alpinum was higher in the “alien” locality, the life span of tillers was greatly reduced and the size of tussocks decreased considerably during the experiment compared to its “native” locality. These results suggest that there was a lack of favourable microsites forA. alpinum in the “alien” locality probably caused by the presence of strong competitors.A. odoratum flowered far less in the “alien” locality (both on tussocks and tillers) compared to the “native” one. These results suggest that environmental conditions are not suitable for the flowering ofA. odoratum in the “alien” locality. We conclude thatA. alpinum could have been limited in extending its distribution into the area ofA. odoratum by the presence of strong competitors, whileA. odoratum could have been limited by its ability to reproduce by seed.     

Seed coat development, anatomy and scanning electron microscopy of Harpagophytum procumbens (Devil's Claw), Pedaliaceae

Seed coat development of Harpagophytum procumbens (Devil's Claw) and the possible role of the mature seed coat in seed dormancy were studied by light microscopy (LM), transmission electron microscopy (TEM) and environmental scanning electron microscopy (ESEM). Very young ovules of H. procumbens have a single thick integument consisting of densely packed thin-walled parenchyma cells that are uniform in shape and size. During later developmental stages the parenchyma cells differentiate into 4 different zones. Zone 1 is the multi-layered inner epidermis of the single integument that eventually develops into a tough impenetrable covering that tightly encloses the embryo. The inner epidermis is delineated on the inside by a few layers of collapsed remnant endosperm cell wall layers and on the outside by remnant cell wall layers of zone 2, also called the middle layer. Together with the inner epidermis these remnant cell wall layers from collapsed cells may contribute towards seed coat impermeability. Zone 2 underneath the inner epidermis consists of large thin-walled parenchyma cells. Zone 3 is the sub-epidermal layers underneath the outer epidermis referred to as a hypodermis and zone 4 is the single outer seed coat epidermal layer. Both zones 3 and 4 develop unusual secondary wall thickenings. The primary cell walls of the outer epidermis and hypodermis disintegrated during the final stages of seed maturation, leaving only a scaffold of these secondary cell wall thickenings. In the mature seed coat the outer fibrillar seed coat consists of the outer epidermis and hypodermis and separates easily to reveal the dense, smooth inner epidermis of the seed coat. Outer epidermal and hypodermal wall thickenings develop over primary pit fields and arise from the deposition of secondary cell wall material in the form of alternative electron dense and electron lucent layers. ESEM studies showed that the outer epidermal and hypodermal seed coat layers are exceptionally hygroscopic. At 100% relative humidity within the ESEM chamber, drops of water readily condense on the seed surface and react in various ways with the seed coat components, resulting in the swelling and expansion of the wall thickenings. The flexible fibrous outer seed coat epidermis and hypodermis may enhance soil seed contact and retention of water, while the inner seed coat epidermis maintains structural and perhaps chemical seed dormancy due to the possible presence of inhibitors.     

Seed coat variation in Glycine Willd. subgenus Glycine (Leguminosae) by SEM

Seed of the genusGlycine Willd. typically exhibits a muriculate appearance resulting from adherence to the true seed coat of the perisperm or inner pod wall layer. Thickened cell walls of the perisperm superimpose a reticulate network on the seed coat, the type of network ranging from alveolate to stellate depending on the shape of the perisperm cells. Tubercles distributed at intervals give the seed its roughened appearance. Seed lacking an attached perisperm appears smooth and shiny. Seed morphology of 62 collections representing the six species of the subgenusGlycine is examined in detail to elucidate inter-and intraspecific variability. Seed perisperm pattern appears to be characteristic for each species, but there are exceptions.Glycine canescens F. J. Herrn. andG. clandestina Willd. seeds possess a reticulate network and tubercles of irregular shape, the perisperm appearing granular inG. clandestina. Seeds ofG. latrobeana (Meissn.) Benth. andG. tabacina (Labill.) Benth. lack a distinct network and have stellate tubercles; the perisperm is granular inG. latrobeana and some plants ofG. tabacina. A few collections ofG. clandestina approachG. tabacina in seed appearance.Glycine tomentella Hayata seeds exhibit a regularly alveolate arrangement, while those ofG. falcata Benth. lack a perisperm layer altogether. Variation in seed coat within a species can usually be linked to differences in chromosome number or some aspect of gross morphology. Diploid collections ofG. tomentella (2n = 40) exhibit recognizable differences in seed morphology compared with tetraploids (2n = 80), coincident with other striking dissimilarities in gross morphology. An incompletely attached perisperm is accompanied by aneuploidy in severalG. tomentella accessions, while other 78 and 38 chromosome aneuploids produce normal seeds.     

Foliar appendages in certain species ofSalvia (studies inLamiaceae VI)

Foliar appendages of eight species ofSalvia L. have been studied. Eleven types of non glandular and five types of glandular appendages have been observed. They have been classified under three major categories: (1) glandular capitate; (2) non glandular filiform and (3) non glandular capitate. Five new types of trichomes have been reported fromLamiaceae for the first time. On the basis of trichome types different species ofSalvia can be identified. A tentative key has been presented.     

东北桤木叶表皮盾状腺毛的形态及其变化过程

利用电镜扫描技术,观察东北桤木叶片表面,发现其远轴面表皮上具有盾状腺毛。其由2个基细胞、4个柄细胞和20～25个头部细胞组成,随着分泌物质的积累,细胞逐渐破裂。幼叶远轴面表皮无盾状腺毛,仅有气孔分布。观察东北桤木叶片横切面,发现其为异面叶,远轴面表皮上的盾状腺毛细胞与叶脉维管组织相连。外文资料显示用于表述桤木属表皮上的盾状腺毛的名词较多,该毛状体应为“Peltate glandular hairs”。同时建议对“Glandular scales”、“Peltate gland”、“Peltate scale”、“Peltate glandular hairs”等名词进行规范统一。另外有关东北桤木叶表皮上毛状体从原表皮细胞的发生过程及其分泌物的成份,需进一步研究。     

Anatomical studies on seeds and seedlings of some Utricularia (Lentibulariaceae)

The undifferentiated mature embryos of someUtricularia studied consist of large polygonal cells which contain many starch grains. Later, they consist mostly of large polygonal cells with some small cells in one or more regions adjacent to the seed coat, which lack starch grains but have rather easily visible nuclei. After these small cells divide and produce more cells of the same type toward the midcenter of the embryo, they form one or more primordia which grow into the primary structures of the seedling. The primordia of the embryo seem to have no pattern as to which primary vegetative structure they will develop into. However, the terrestrial species ofUtricularia studied showed some non-cotyledonous, primary differences in germination patterns; some form primary foliar units, some form stolons, and some form bladders. The first and second primary foliar units of aquaticUtricularia radiata andV. gibba subsp.gibba do not follow in the same manner as cotyledons. No cotyledon could be distinguished in any of theUtricularia seedlings studied. In the seedlings ofU. gibba subsp.gibba andU. radiata, appearance and differentiation of the vascular elements occur simultaneously in more than one direction, toward the meristematic tissues of primary vegetative structures and toward the midcenter of the embryos. Lloyd’s proposed term: “cotyledonoids” (1942) and that of Kumazawa: “cotyledons” (1967) should not be used for the first and second primary foliar units in either aquatic or terrestrial to terrestrial-epiphyticUtricularia, unless further supportive evidence is accumulated.     

Isolation and Characterization of Mutants Defective in Seed Coat Mucilage Secretory Cell Development in Arabidopsis

In Arabidopsis, fertilization induces the epidermal cells of the outer ovule integument to differentiate into a specialized seed coat cell type producing extracellular pectinaceous mucilage and a volcano-shaped secondary cell wall. Differentiation involves a regulated series of cytological events including growth, cytoplasmic rearrangement, mucilage synthesis, and secondary cell wall production. We have tested the potential of Arabidopsis seed coat epidermal cells as a model system for the genetic analysis of these processes. A screen for mutants defective in seed mucilage identified five novel genes (MUCILAGE-MODIFIED [MUM]1–5). The seed coat development of these mutants, and that of three previously identified ones (TRANSPARENT TESTA GLABRA1, GLABRA2, and APETALA2) were characterized. Our results show that the genes identified define several events in seed coat differentiation. Although APETALA2 is needed for differentiation of both outer layers of the seed coat, TRANSPARENT TESTA GLABRA1, GLABRA2, and MUM4 are required for complete mucilage synthesis and cytoplasmic rearrangement. MUM3 and MUM5 may be involved in the regulation of mucilage composition, whereas MUM1 and MUM2 appear to play novel roles in post-synthesis cell wall modifications necessary for mucilage extrusion.     

Identification of genome regions controlling cotyledon,pod wall/seed coat and pod wall resistance to pea weevil through QTL mapping

Pea weevil, Bruchus pisorum, is one of the limiting factors for field pea (Pisum sativum) cultivation in the world with pesticide application the only available method for its control. Resistance to pea weevil has been found in an accession of Pisum fulvum but transfer of this resistance to cultivated pea (P. sativum) is limited due to a lack of easy-to-use techniques for screening interspecific breeding populations. To address this problem, an interspecific population was created from a cross between cultivated field pea and P. fulvum (resistance source). Quantitative trait locus (QTL) mapping was performed to discover the regions associated with resistance to cotyledon, pod wall/seed coat and pod wall resistance. Three major QTLs, located on linkage groups LG2, LG4 and LG5 were found for cotyledon resistance explaining approximately 80 % of the phenotypic variation. Two major QTLs were found for pod wall/seed coat resistance on LG2 and LG5 explaining approximately 70 % of the phenotypic variation. Co-linearity of QTLs for cotyledon and pod wall/seed coat resistance suggested that the mechanism of resistance for these two traits might act through the same pathways. Only one QTL was found for pod wall resistance on LG7 explaining approximately 9 % of the phenotypic variation. This is the first report on the development of QTL markers to probe Pisum germplasm for pea weevil resistance genes. These flanking markers will be useful in accelerating the process of screening when breeding for pea weevil resistance.     

Revision of Limonium (Plumbaginaceae) in eastern North America

The number of species ofLimonium in eastern North America has long been a matter of taxonomic concern. The complex of six to seven “species” is better treated as a single, highly variable species,Limonium carolinianum (Walter) Britton.     

Mikromorphologie der Samenschalen und Taxonomie derCactaceae: Ein raster-elektronenmikroskopischer Überblick

Micromorphology and surface sculpture of seed-coats of about 900 species ofCactaceae out of 120 genera (sensuBackeberg 1976) were examined by light and scanning electron microscopy. A survey of the seed coat characteristics (forms of testa cells, wall sculpturings, cuticular fold patterns etc.) is given. A terminology for the taxonomic application of these microstructures is proposed and their taxonomic significance is discussed.

     

New names inPhanerogamae 6

94 new nomenclatural combinations are proposed, resulting mostly from the study of taxonomic problems on the generic level. The reasons for the acceptance of the generic rank are given in the case ofAcetosa, Pulegium and of some sections ofOrobanche s. l. andSilene s. l. The taxonomic rank ofGentiana blepharophora Bordzi?. from the Caucasus has been revised and the taxon is classified as a subspecies ofGentianopsis ciliata. Nomenclatural problems of not numbered “species” inHoffmann's “Flora Deutschlands” from 1800 are demonstrated on the example ofArmeria elongata.     

Zur vergleichenden Morphologie der CyanophyceeClastidium setigerum und verwandter Gattungen

InClastidium setigerum the mature plant consists of the contents of the endosporangium, the sporangium itself is represented only by a basal cup-shaped cell wall. This cup-shaped wall originates, while the sporangium contents grow out during a very juvenile stage. The spores are homologous to the endospores of related genera but they are not “endo” spores in the literal sense, because they are never surrounded by a common wall. Sporogenesis occurs belated, that is only after the emergence of the sporangium contents, and is effected by centripetally growing-in of the delicate special wall (Eigenwand) of the sporangium contents.Clastidium therefore represents a very remarkable derived member ofDermocarpaceae, but also shows close relationship toCyanophanon. In this connection the systematic position ofGeitleribactron is thoroughly discussed: The morphological peculiarities of this genus, newly created as aChroococcacea byKomárek, are better understood, if the genus is considered as an extremely derived member ofDermocarpaceae with total suppression of a sporangium in the strict sense.     

Glandular Epithelium as a Possible Source of a Fertility Signal in Ectatomma tuberculatum (Hymenoptera: Formicidae) Queens

The wax layer covering the insect''s cuticle plays an important protective role, as for example, uncontrolled water loss. In social insects, wax production is well-known in some bees that use it for nest building. Curiously, mated-fertile queens of the ant Ectatomma tuberculatum produce an uncommon extra-wax coat and, consequently queens (mated-fertile females) are matte due to such extra cuticular hydrocarbon (CHC) coat that covers the cuticle and masks the brightness of the queens'' cuticle while gynes (virgin-infertile queens) are shiny. In this study, histological analysis showed differences in the epidermis between fertile (i.e., queens or gynes with highly ovarian activity) and infertile females (gynes or workers with non developed ovaries). In fertile females the epidermis is a single layer of cubic cells found in all body segments whereas in infertile females it is a thin layer of flattened cells. Ultrastructural features showed active secretory tissue from fertile females similar to the glandular epithelium of wax-producing bees (type I gland). Different hypotheses related to the functions of the glandular epithelium exclusive to the E. tuberculatum fertile queens are discussed.     

Chemical investigation of different extracts and essential oil from the tubers of (Tunisian)Cyperus rotundus. Correlation with their antiradical and antimutagenic properties

The mutagenic potential of aqueous, Total Oligomers Flavonoids (TOF), ethyl acetate, and methanol extracts as well as essential oil (EO) obtained from tubers ofCyperus rotundus L. was assessed by “Ames assay”, usingSalmonella tester strains TA98 and TA100, and “SOS chromotest” usingEscherichia coli PQ37 strain with and without an exogenous metabolic activation system (S9). None of the different extracts showed a mutagenic effect. Likewise, the antimutagenicity of the same extracts was tested using the “Ames test” and the “SOS chromotest”. Our results showed thatC. rotundus extracts have antimutagenic effects withSalmonella typhimurium TA98 and TA100 strains towards the mutagen Aflatoxin B1 (AFB1), as well as withE. coli PQ37 strain against AFB1 and nifuroxazide mutagens. A free radical scavenging test was used in order to explore the antioxidant capacity of the extracts obtained from the tubers ofC. rotundus. TOF, ethyl acetate and methanol extracts showed an important free radical scavenging activity towards the 1,1-diphenyl-2-picrylhydrazyl (DPPH) free radical. These extracts showed IC50 values of respectively 5, 20 and 65 μg/ml. The beneficial effects of TOF, ethyl acetate, methanol and essential oil extracts ofC. rotundus have been assessed by antioxidant and antimutagenic activities.     

The systematic significance of seed morphology in Sagina (Caryophyllaceae) under scanning electron microscopy

The seed morphology of 15 species ofSagina from North America, Europe, and eastern Asia was studied, utilizing the scanning electron microscope, to determine the significance of seed coat features as taxonomic characters. There is variation in particular surface features within some members of the genus. However, superficial ridges and tubercules exhibit patterns very helpful in determining relationships among some species. Two basic seed types occur in the genus and are diagnostic at the sectional level. The saginoid seed, characteristic of sectionSagina, is obliquely triangular in outline, is grooved along the two dorsal ridges, and has slightly concave lateral surfaces. The crassuloid seed, characteristic of sectionMaxima, is obliquely reniform in outline, lacks dorsal grooves, and has shallowly convex lateral surfaces.     

Callose in the walls of mature embryo sac ofTorenia fournieri

Summary During the course of a fluorescence microscopic investigation on the extra-ovular micropylar portion of the embryo sacs ofTorenia fournieri Lind. (Scrophulariaceae) a callosic wall was found which surrounded it almost completely until the time of anthesis. In addition, the walls of young synergids and the filiform apparatus also showed callosic fluorescence. Treatments with PAS reaction revealed a PAS-positive substance filling up the locular cavity. Our attempts to induce fluorochromasia by employing fluorescein diacetate failed, indicating the low permeability of the callosic wall around the embryo sac. It is assumed that the callose wall around the embryo sac isolates the latter from the contents of the locular cavity whereas the callose in the synergid walls may represent an intermediate stage in the maturation of these walls; the filiform apparatus is mainly composed of callose.