Formation of the zone of paratomy in freshwater oligochaetes

Oligochaetes Nais communis and Pristina longiseta are capable of paratomy, i.e., asexual reproduction of the cross division type, when division proceeds across the long body axis and daughter organisms retain the maternal axes. Paratomy is represented by two forms: slow and fast. Slow paratomy is accompanied by the formation of chains from no more than two zooids (N. communis), while fast paratomy leads to the formation of chains from many zooids (P. longiseta). Analysis of the appearance and development of the zone of paratomy (constriction) has shown that when its cephalogenic part is formed, only head segments appear and are formed simultaneously, while in the somatogenic part, body segments appears successively. Dedifferentiated cells of the covering epithelium appear to serve as a source of newly formed structures. It was shown using mathematical statistics that constriction is laid down in the zone defined by a system of coordinates formed by unknown factors. Although the constriction is laid down in the middle of a segment, its subsequent growth is not related to the transformation of adjacent areas of the segment.     

Quantitative observations on asexual reproduction of Aeolosoma viride (Annelida,Aphanoneura)

Agametic reproductive activity (via paratomy) of Aeolosoma viride was analyzed throughout the life cycle in individually reared specimens. Aeolosoma viride is organized in linear chains of 3–4 zooids; the main zooid is anterior, and the secondary zooids are positioned posterior to the main zooid in inverse order with respect to their degree of growth, the most advanced being at the posterior end, and those less advanced nearer the main zooid. On average, worms lived 66±10 d and produced 57±6 offspring. A budding area located in the sub‐terminal part of the main zooid produced chaetigers that formed the origin of the secondary zooids. A growth zone was located in the posterior end of each secondary zooids. Fission occurred between the penultimate and the last zooid of the chain. Just before fission, the growth zone of each secondary zooid became a budding area. Agametic reproduction was via multiple paratomy with linear succession of the secondary zooid and terminal fission. The structure of the chain was therefore modulated by the interaction of the processes of budding, growth, cephalic differentiation, and fission, which occurred continuously and on different timescales. Values of parameters describing paratomic activity (interval between origin of the zooids, time to produce a chaetiger, growth time of the zooids, and interval between the fission of the filial chains) are low early in an individual's life, but increase during senescence. Due to its relatively rapid lifecycle and high reproductive activity, A. viride is a convenient experimental organism for the study of agametic reproduction.     

Observations on the oviposition behaviour ofGoniozus sensorius [Hymenoptera: Bethylidae] a parasite ofDiaphania indica [Lepidoptera: Pyralidae]

Goniozus sensorius Gordh (Hymenoptera: Bethylidae) was recorded as a major parasite of the pumpkin caterpillar,Diaphania indica (Saunders) (Lepidoptera: Pyralidae). This paper provides detailed information on the oviposition behaviour ofG. sensorius. Prior to oviposition, the parasite temporarily paralyses the host larva. The paralysed condition lasts for about 2 h. The egg laying process on each larva requires 30 to 60 min. The maximum number of eggs are laid on the 6^th and 7^th segment, and none in the terminal segments. Generally, oviposition is restricted to 1 segment of the host larva and occasionally on 3 segments. The maximum number of eggs are laid on the 2^nd and 3^rd day after emergence and the mean number of eggs laid on each host larva was 7.1.     

Asexual reproduction in Microstomum lineare (Turbellaria). I. An autoradiographic and ultrastructural study

The distribution of cells preparing for proliferation during asexual reproduction by paratomy in Microstomum lineare (Turbellaria) was investigated using the technique of exogenous tritiated thymidine ([³H]T) labelling and routine electron microscopy. The subsequent fates of labelled cells in developing and mature zooids were followed by fixing tissues at various intervals. The only labelled cells are mesenchymal and gastrodermal neoblasts, occurring along the whole worm without any special growth zones or axial gradient. Organ primordia develop as a result of locally dividing as well as of migrating cells.     

Prey preferences of the polyclad flatworm Prostheceraeus roseus among Mediterranean species of the ascidian genus Pycnoclavella

In the present study we analyzed prey preferences of the polyclad flatworm Prostheceraeus roseus among three different species of colonial ascidians of the genus Pycnoclavella occurring sympatrically in the Northwestern Mediterranean (Spain). Palatability assays were conducted in laboratory conditions in order to test predator preferences in pairwise tests, and cycles of abundance of the predator and prey were monitored in the field. The results showed a clear preference of the predator for Pycnoclavella communis over Pycnoclavella nana and Pycnoclavella aurilucens. We suggest that chemical variation in defense compounds among species of this secondary metabolite-rich genus can drive the flatworm preferences. The ascidian had seasonal cycles in the area studied, with resting (aestivation) states in the summer months. The flatworm abundance showed no clear seasonal cycle, but it was less abundant in winter. The predator has been seen in the field feeding either on active zooids or on the reserve-laden basal mass of tunic during the aestivation phase of P. communis. Handling editor: I. Nagelkerken     

Formation of the insect head involves lateral contribution of the intercalary segment, which depends on Tc-labial function

The insect head is composed of several segments. During embryonic development, the segments fuse to form a rigid head capsule where obvious segmental boundaries are lacking. Hence, the assignment of regions of the insect head to specific segments is hampered, especially with respect to dorsal (vertex) and lateral (gena) parts. We show that upon Tribolium labial (Tc-lab) knock down, the intercalary segment is deleted but not transformed. Furthermore, we find that the intercalary segment contributes to lateral parts of the head cuticle in Tribolium. Based on several additional mutant and RNAi phenotypes that interfere with gnathal segment development, we show that these segments do not contribute to the dorsal head capsule apart from the dorsal ridge. Opposing the classical view but in line with findings in the vinegar fly Drosophila melanogaster and the milkweed bug Oncopeltus fasciatus, we propose a “bend and zipper” model for insect head capsule formation.     

Genetic analysis of pattern-formation in the embryo ofDrosophila melanogaster

Summary The mutationbicaudal (Bull, 1966) causes embryos to develop a longitudinal mirror image duplication of the posteriormost abdominal segments, while head and thorax are missing. These embryos occur with varying frequencies among eggs laid by mutant females, irrespective of the paternal genotype. Recombination and deletion mapping indicate thatbicaudal (bic) is a recessive, hypomorphic, maternal-effect mutation mapping at a single locus on the second chromosome ofDrosophila melanogaster close tovg (67.0±0.1). The frequency of bicaudal embryos depends on the age of the mother, her genetic constitution and the temperature at which she is raised. Best producers are very young females hemizygous forbic (bic/Df(2)vg ^B ) at 28° C. Under these conditions 80% to 90% of the eggs which differentiate can show the bicaudal embryo phenotype. Upon ageing of the mother the frequency of bicaudal embryos declines rapidly, and most of the eggs develop the normal body pattern. Temperature shift experiments suggest a temperature-sensitive period at the onset of vitellogenesis.The mutation causes several types of abnormalities in the segment pattern of theDrosophila embryo, which are interpreted as various degrees of expression of the mutant character. The most frequent abnormal phenotype is the symmetrical bicaudal embryo with one to five abdominal segments duplicated. Less frequent are asymmetrical types, in which the smaller number of segments is always in the anterior reversed part. Other phenotypes are embryos with missing or rudimentary heads, and embryos with irregular gaps in the segment pattern. In bicaudal embryos, the pole cells, formed at the posterior pole of the egg prior to blastoderm formation, are not duplicated at the anterior. The significance of thebicaudal phenotypes for embryonic pattern-formation inDrosophila is discussed.     

Ultrastructural organization of the transition from the distal nephron to the collecting duct in the desert rodent Psammomys obesus

Summary The transition from the nephron to the collecting duct is formed by three tubular segments (convoluted part of the distal tubule, connecting tubule, cortical collecting duct), which in the desert rodent, Psammomys obesus, transform gradually from one segment to the next, due to intermingling of their different cell types.The convoluted part of the distal tubule (DTC) starts abruptly, shortly beyond the macula densa and initially is homogeneously composed of characteristic DTC-cells. Subsequently, the DTC-cells intermingle with intercalated cells. The first appearance of the connecting-tubule cell, which gradually replaces the DTC-cell, is regarded as the beginning of the connecting tubule. The major portion of the connecting tubule is lined by connecting-tubule cells and intercalated cells. The first appearance of the principal cell between them defines the beginning of the cortical collecting duct, which in the medullary ray is lined by principal and intercalated cells only.Each cell type is described in detail and discussed in relation to the assumed function of the tubular segments.Interspecies differences in the cellular composition of the transitional zone from the nephron to the collecting duct are discussed in relation to the different organization of the collecting duct system.     

Homeogenetic inductive mechanism of segmentation in polychaete tail regeneration

Segmentation is a body-patterning strategy in which new segments are specified from a segment-addition zone containing uncommitted cells. However, the cell-recruitment process is poorly understood. Here we investigated in detail the segmentation in a polychaete annelid, Perinereis nuntia (Lophotrochozoa), in which new segments emerge at the boundary between the posterior end of the segmented region and the terminal pygidium. Cells at this border synchronously remodel their chromatin, enter the cell cycle, and undergo oriented cell division, before being added to new segments. wingless is expressed at the posterior edge of the pre-existing segment, abutted by hedgehog in the first row of the new segment. Overstimulation of Wingless signaling caused excess cells to enter the cell cycle, prolonging segmentation and widening the new segment. Thus, segment addition may occur by a homeogenetic mechanism, in which Wingless expressed in the differentiated segment coordinates the stepwise recruitment of undifferentiated cells from the segment/pygidium boundary.     

Obligatory female philopatry affects genetic population structure in the ant Proformica longiseta

Evolution of sociality has instigated many changes in the biology of social insects. Particularly, evolution towards complex social systems in ants affects how individuals move in space, usually by making females philopatric. Proformica longisetais well-suited for studying the effects of female philopatry, because female sexuals are wingless and do not actively disperse. We studied genetic population structure in P. longiseta in local scale both as genetic viscosity within one subpopulation, and as differentiation between closely (0.1–1.5 km) located subpopulations, by using nuclear (microsatellites) and mitochondrial (SSCP) markers. Dependent colony founding by splitting old nests is the only known nest founding strategy in P. longiseta. However, no genetic viscosity was detected at the nuclear markers within the subpopulation studied, possibly due to the dynamic nature of P. longiseta populations. The extreme female philopatry showed as strong structure between closely located subpopulations in the mitochondrial genome, but there was no isolation by distance showing that the differentiation pattern was random. Genetic structure in the nuclear genome was much weaker, and there was an indication of isolation by distance. This suggests that male dispersal is strong but not totally free across the area. Finally, non-dispersing P. longiseta females necessarily mate locally raising the possibility of inbreeding, but inbreeding coefficients showed that mating is random. Received 10 January 2006; revised 13 April 2006; accepted 20 April 2006.     

Gene expression suggests conserved mechanisms patterning the heads of insects and myriapods

Segmentation, i.e. the subdivision of the body into serially homologous units, is one of the hallmarks of the arthropods. Arthropod segmentation is best understood in the fly Drosophila melanogaster. But different from the situation in most arthropods in this species all segments are formed from the early blastoderm (so called long-germ developmental mode). In most other arthropods only the anterior segments are formed in a similar way (so called short-germ developmental mode). Posterior segments are added one at a time or in pairs of two from a posterior segment addition zone. The segmentation mechanisms are not universally conserved among arthropods and only little is known about the genetic patterning of the anterior segments. Here we present the expression patterns of the insect head patterning gene orthologs hunchback (hb), orthodenticle (otd), buttonhead-like (btdl), collier (col), cap-n-collar (cnc) and crocodile (croc), and the trunk gap gene Krüppel (Kr) in the myriapod Glomeris marginata. Conserved expression of these genes in insects and a myriapod suggests that the anterior segmentation system may be conserved in at least these two classes of arthropods. This finding implies that the anterior patterning mechanism already existed in the last common ancestor of insects and myriapods.     

Morphological and molecular (RAPD) analyses confirm the hybrid origin of the diploid grassCalamagrostis longiseta var.longe-aristata (Gramineae)

To examine the hybrid origin of the diploid grassCalamagrostis longiseta var.longe-aristata, we performed morphometric and genetic analyses of this taxon and its putative parental taxa. The morphometric analyses revealed that, in general,C. longiseta var.longe-aristata is morphologically intermediate betweenC. longiseta var.longiseta andC. fauriei. Previous studies have reported that some hybrids exhibit transgressive characters but others do not; the latter is the case forC. longiseta var.longe-aristata. Their absence may be due to the ecological adaptation to environments intermediate between those inhabited by the putative parental taxa, and therefore the transgressive characters have not been selected. Nevertheless, there is no direct evidence for adaptive value of the characters examined in this study and only a small part of all characters potentially responsible for adaptation was investigated. An alternative hypothesis about the absence of transgressive characters inC. longiseta var.longe-aristata is that it is at an early stage of hybrid speciation. Random amplified polymorphic DNA (RAPD) analyses showed that individuals ofC. longiseta var.longe-aristata were placed in both of the clusters formed by each putative parental taxon. Greater genetic diversity was observed inC. longiseta var.longe-aristata than in its putative parental taxa. All here reported findings support the scenario thatC. longiseta var.longe-aristata is of hybrid origin, having evolved fromC. longiseta var.longiseta andC. fauriei.     

Inhibition of stomatal opening during uptake of carbohydrates by guard cells in isolated epidermal tissues

The uptake of glucose and other carbohydrates into the guard cells of Commelina communis L. was found to inhibit the opening of the stomata. The concentration of glucose necessary to achieve about 50% inhibition was of the same order of magnitude as the potassium concentration required for opening; the uptake systems for potassium and glucose appear to be competitive and to exhibit the same degree of affinity. It is suggested that the uptake of glucose occurs via a proton cotransport, which, depolarizing the membrane potential, slows down the electrogenic import of potassium ions. The process of stomatal closure, in contrast, appears not to be affected by carbohydrate uptake. In guard cells of Tulipa gesneriana L. and Vicia faba L., which do not possess subsidiary cells, import of glucose or other carbohydrates did not interfere with the regulation of stomatal movements.     

Pollination by ants: consequences of the quantitative effects on a mutualistic system

Summary We have analysed the importance of worker ants (Proformica longiseta, Formicidae) as pollinators of a mass-flowering woody plant (Hormathophylla spinosa, Cruciferae) in the high-mountain area of the Sierra Nevada (southern Spain). We have quantified the abundance and foraging behavior of P. longiseta in comparison with winged flower visitors. We have also examined, by means of selective exclusion experiments, the role of ants as true pollinators, comparing them with the winged flower visitors. A total of 39 species belonging to 18 families visited the flowers of H. spinosa. All the visitors were winged insects, except P. longiseta, a species which alone made up more than 80% of the total number of insects found on the flowers. All pollinators of H. spinosa had similar foraging patterns, with 98% of total movements made between flowers within the same plant. Ants always made contact with the plant reproductive organs when foraging for nectar, and transferred large numbers of pollen grains. However, pollen exposed to ants for brief periods exhibited reduced percentage of germination. P. longiseta is both the most abundant and spatio-temporally predictable flower visitor of H. spinosa. These characteristics, weighted by their flower visitation rate, make worker ants the pollinator that maintains the strongest mutualistic interaction with H. spinosa. The exclusion experiments show that workers behave as true pollinators, since they contribute to increase the number of viable seeds produced by H. spinosa. The key factor of this interaction is mainly the great density of workers throughout the flowering period. In short, the H. spinosa-P. longiseta mutualistic interaction mainly depends on its high probability of occurrence.     

<Emphasis Type="Italic">Tubulideres seminoli</Emphasis> gen. et sp. nov. and <Emphasis Type="Italic">Zelinkaderes brightae</Emphasis> sp. nov. (Kinorhyncha,Cyclorhagida) from Florida

One new kinorhynch genus and species and one new species from the genus Zelinkaderes are described from sandy sediment off Fort Pierce, Florida. The new genus and species, Tubulideres seminoli gen. et sp. nov. is characterized by the presence of the first trunk segment consisting of a closed ring, the second segment of a bent tergal plate with a midventral articulation and the following nine segments consisting of a tergal and two sternal plates. Cuspidate spines are not present, but flexible tubules are located on several segments, and in particular concentrated on the ventral side of the second segment. Middorsal spines are present on all trunk segments and are alternatingly offset to a position slightly lateral to the middorsal line. Zelinkaderes brightae nov. sp. is characterized by its spine formula in having middorsal spines on trunk segments 4, 6 and 8–11, lateroventral acicular spines on segment 2, lateral accessory cuspidate spines on segments 2 and 8, ventrolateral cuspidate spines on segments 4–6 and 9, lateroventral acicular spines present on segments 8 and 9, and midterminal, lateral terminal and lateral terminal accessory spines on segment 11. The spine formula of Z. brightae nov. sp. places it in a position in between Z. submersus and a clade consisting of Z. klepali and Z. floridensis. The new findings on Z. brightae nov. sp. have led us to propose an emended diagnosis for the genus.     

Über den Teilungsverlauf des Chloroplasten beiChlamydomonas

Zusammenfassung Die Teilung des Chloroplasten wurde bei zweiChlamydomonas-Arten mit topfförmigem Chloroplasten,Chlamydomonas parallestriata Korschikoff undChlamydomonas cribrum Ettl, an lebenden Zellen laufend verfolgt. Im Unterschied zu den Angaben anderer Autoren kommt der Teilungsbeginn des Chloroplasten der Kernteilung deutlich zuvor. Bei den teilungsbereiten Zellen werden am Vorderrand des Chloroplasten zwei Teilungsfurchen angelegt, die einander gegenüberliegen und den Chloroplasten vom Vorderrand aus zur Basis teilen. In der ersten Phase wird der Randbereich geteilt, wobei sich der Zellkern noch in der Interphase befindet. Erst nach der Teilung des Randbereiches setzt die Mitose ein, und die Teilung des Chloroplasten wird am Basalstück vollendet. Der Chloroplast wächst während der Entwicklung des Tochterprotoplasten erneut zu seiner topfförmigen Gestalt heran. Der beschriebene Teilungsmodus des Chloroplasten wurde auch bei anderenChlamydomonas-Arten beobachtet. Das Vorausgehen des Teilungsbeginns des Chloroplasten vor der Mitose wird diskutiert. Es wird für möglich gehalten, daß die Chloroplastenteilung während der Zellteilung semiautonom verläuft. Der Widerspruch zwischen meinen Untersuchungen und denen anderer Autoren wird geklärt, und es wird betont, daß die morphologische Untersuchung des ganzen Chloroplasten für diese Zwecke nötig ist.

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About the progress of chloroplast division inChlamydomonas

Summary The progress of chloroplast division in twoChlamydomonas species with cup-shaped chloroplasts—Chlamydomonas parallestriata Korschikoff andChlamydomonas cribrum Ettl—is continuously followed with the light microscope in living cells. In contradistinction to the results given by other authors the chloroplast division is starting sooner than the mitosis. Two dividing furrows face each other and appear on the frontal margin of the chloroplast dividing it in direction towards its basal part. During the first stage the lateral part of the chloroplast is divided while the nucleus stays in interphase. Afterwards the mitosis is starting and the division of the basal part of the chloroplast together with the pyrenoid will be finished. The new cup-shaped chloroplast is formed during the development of the young daughter protoplast. The mode of chloroplast division described here has been observed also in otherChlamydomonas species. The preceding of the beginning of chloroplast division with regard to the mitosis is discussed. It is considered that the chloroplast division may be a semiautonomous act in the course of cell division. The differences in my studies and those of other authors are explained and the necessity of the morphological study of the whole chloroplast is stressed.

     

Kinetics of polyglucose breakdown in Chlorobium

Washed cells of Chlorobium limicola f. thiosulfatophilum photoassimilate CO₂ and acetate into polyglucose, which is laid down within the cells as rosette-like granules. When the cells are incubated in the dark, the polyglucose is broken down. Experiments using electron microscopy and labelling with ¹⁴C-acetate have revealed that degradation of polyglucose occurs in such a way that all the granules are subject to degradation simultaneously and the polyglucose which has been formed most recently in the light, becomes metabolized in the dark first.