Native vitellins are modified during ovarian development in the stick insect Carausius morosus (Br.)

Vitellins from ovarian follicles and newly laid eggs of the stick insect Carausius morosus were examined by ion exchange chromatography on a HPLC Mono Q column. Under these conditions, vitellins from newly laid eggs resolved as two distinct peaks, referred to as VtA and VtB, that eluted at 8.5 and 12.0 min, respectively. On native gels, both VtA and VtB separated into two different variant forms (VtA′ and VtA′, VtB′ and VtB′). By two-dimensional gel electrophoresis, VtA′ and VtA′ were shown to contain polypeptides A₁, A₂ and A₃. On the other hand, VtB′ and VtB′ appeared to comprise polypeptides B₁ and B₂ and B₁, A₁, A₂, B₂ and A₃*, respectively. A similar Vt polypeptide composition was also observed by size-exclusion chromatography of vitellins from newly laid eggs. Vitellins from early vitellogenic ovarian follicles resolved into a single chromatographic peak at 7.5 min that coeluted with a major peak from the hemolymph of egg-laying females. Ovarian follicles progressively more advanced in development exhibited a more complex chromatographic profile, consisting of three separate peaks. By two-dimensional gel immunoelectrophoresis, vitellins from ovarian follicles appeared to consist of two closely related, immunologically cross-reacting antigens that gradually shifted apart as ovarian development proceeded to completion. By size-exclusion chromatography, each Vt from ovarian follicles was shown to consist of a unique set of polypeptides different from those listed above. Single ovarian follicles were fractionated into yolk granules and yolk fluid ooplasm and tested by immunoblotting against Mab 12. Under these conditions, VtA variant forms in yolk granules and yolk fluid ooplasm reacted differently. Sections from ovarian follicles in different developmental stages were exposed to Mab 12 and stained with a peroxidase-conjugated, goat anti-mouse antibody. Regardless of the developmental stage attained, staining for peroxidase was restricted to free yolk granules, suggesting that native vitellins in stick insects are structurally modified upon fusion into the yolk fluid ooplasm. Arch. Insect Biochem. Physiol. 36:335–348, 1997. © 1997 Wiley-Liss, Inc.     

Postendocytic vitellin processing in ovarian follicles of the stick insect Carausius morosus (Br.)

Newly laid eggs of the stick insect Carausius morosus contain two native vitellins (Vit A and Vit B). Under denaturing conditions, these vitellins resolved into 3 (A₁, A₂, and A₃) and 2 (B₁ and B₂) polypeptides. All of these polypeptides had counterparts in the female hemolymph from which they were shown to be derived by in vivo labelling. During ovarian development, the 2 vitellins changed both in charge and polypeptide composition. In EV and LV follicles, Vit A resolved into 4 distinct vitellin polypeptides (A₀, A₁, A₂ and A₃). Using a panel of monoclonal antibodies, polypeptide A₀ proved to be immunologically related to polypeptide A₂. In follicles about to begin choriongenesis, polypeptide A₃ was gradually replaced by a lower M_r polypeptide. Over the same time period, polypeptide B₁ changed in charge, but not in M_r. To confirm the existence of a polypeptide processing in C. morosus, ovarian follicles of different developmental stages were exposed in vivo to [³⁵S]-methionine from 6 to 72 h. Data showed that A₀ and B₁ were the polypeptides most heavily labelled after short time exposures to the radioisotope. Polypeptides B₂ and A₃ were also labelled to some extent. With progressively longer exposures, polypeptides A₁ and A₂ also became labelled. In vivo exposure to [³H]-GlcNAc caused all vitellin polypeptides to become heavily labelled. Autoradiographic analysis of ovarian follicles labelled this way showed that, during development, radioactivity was gradually transferred from newly formed yolk spheres in the cortical ooplasm to the central ooplasm. Data were interpreted as suggesting a causal relationship between polypeptide processing and progressive yolk sphere fusion to yield the central ooplasm. © 1993 Wiley-Liss, Inc.     

Tryptophan 2,3-dioxygenase in the development of the stick insect,Carausius morosus Br

Summary A detailed kinematical analysis of oscillating fly wings using high speed cine films in three-table projection and model reconstructions show a variety of quick changes in beating and rotating movements. There are especially quick changes in the geometrical angle of attack during the upper and lower reversal phases and quick twisting movements and bending oscillations during some of the beating phases. A dozen possibilities for instationary aerodynamic effects are discussed, including quick oscillations in angle of attack, quick turning movements in the reversal points, circulation possibly induced by a quick supination during the beginning of upstroke (fast supination effect), oblique attack by the fluid, circulation possibly induced by a forced oscillation of the trailing edge during the beginning of downstroke (swinging edge effect), tangential transport of the boundary layer by undulatory movements, rolling movements during the turning phases, high-frequency small oscillations of the wing surface, and a quick oscillation during late upstroke. Weis-Fogh's clap and fling mechanism and flip mechanism could not be detected in Calliphorid flies.

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Mit Unterstützung der Deutschen Forschungsgemeinschaft     

Fine structure of the abdominal neural fat-body sheath in the stick insect (Carausius morosus,Br.)

The neural fat-body sheath surrounding the abdominal ventral nerve cord of Carausius morosus has been examined by light and electron microscopy. A perineural chamber between the ventral nerve cord and the sheath is present in the ganglionic regions, but in the interconnective regions the sheath directly covers the neural lamella. The sheath is differentiated into secretory cells with abundant granular endoplasmic reticulum and many mitochondria and storage cells with lipid droplets and granules presumed to be glycogen. The whole sheath is pervaded with tracheoblast cells and associated tracheal and tracheolar tubules. Recent evidence suggests that this sheath may have little power of ionic regulation. The function of the sheath, deduced from the fine structure described here, appears to be to serve the nutritional needs of the central nervous system. Why a sheath of this type appears to be confined to herbivorous insects with unusual haemolymph cationic balance is still unexplained.     

Immunohistological studies on the distribution of yolk proteins in the stick insect (Carausius morosus)

The path of yolk proteins through stick insect embryos at two developmental levels was studied immunologically. In 18-day-old embryos, all the blastema takes up the yolk proteins directly. In 30-day-old embryos, two transport systems are developed: embryonic contraction moves the yolk particles throughout the embryonic cavities, and amoeboid cells complete the yolk transport to its destination.     

The maturation divisions of the parthenogenetic stick insect Carausius morosus Br. (Orthoptera,Phasmidae)

The meiotic stages in the maturation of the egg of the parthenogenetic stick insect Carausius morosus Br. is described. The meiosis consists of two equational divisions and parthenogenesis is thus apomictic. The first prometaphase is formed between 5.8–5.5 days before oviposition; the first metaphase lasts until oviposition; the meiosis ends between 14 and 24 hours after oviposition. An extra chromosome doubling occurs before first anaphase, causing the first metaphase chromosomes to resemble bivalents and requiring that meiosis consists of two divisions instead of one. A terminal affinity between the daughter chromosomes influences chromosome movement during first and second metaphase and anaphase. The first and second polar bodies degenerate. The first polar body divides amitotically during pycnosis. Meiosis takes place ventrally in the egg, the germ anlage development dorsally. The pronucleus divides mitotically in the ventral part of the egg during its migration from ventral to dorsal, enabling blastoderm development to take place both ventrally and dorsally.     

Cells released in vitro from the embryonic yolk sac of the stick insect carausius morosus (BR.) (PHASMATODEA : HETERONEMIIDAE) may include embryonic hemocytes

The embryonic yolk sac and the adult dorsal vessel of the stick insect Carausius morosus (Br.) (Phasmatodea : Heteronemiidae) were shown to release a number of cells that appear morphologically similar to circulating adult hemocytes. Like adult hemocytes, these cells reacted positively when tested for both phenoloxidase activity and a monoclonal antibody specifically raised against a vitellin polypeptide. Based on this evidence, it is suggested that yolk sac-released cells behave as potential embryonic hemocytes. A model is thus proposed whereby the yolk sac might host a number of hemopoietic stem cells on their way to the dorsal vessel, and in so doing, it may temporally act as an embryonic hemopoietic organ.     

C-mannosylation in the hypertrehalosaemic hormone from the stick insect Carausius morosus

The hypertrehalosaemic hormone from the stick insect Carausius morosus (Cam-HrTH) contains a hexose covalently bound to the ring of the tryptophan, which is in the eighth position in the molecule. We show by solution NMR spectroscopy that the tryptophan is modified at its C(delta1)(C2) by an alpha-mannopyranose. It is the first insect hormone to exhibit C-glycosylation whose exact nature has been determined experimentally. Chemical shift analysis reveals that the unmodified as well as the mannosylated Cam-HrTH are not completely random-coil in aqueous solution. Most prominently, C-mannosylation strongly influences the average orientation of the tryptophan ring in solution and stabilizes it in a position clearly different from that found in the unmodified peptide. NMR diffusion measurements indicate that mannosylation reduces the effective hydrodynamic radius. It induces a change of the average peptide conformation that also diminishes the propensity for aggregation of the peptide.     

Sensory control of leg movement in the stick insect Carausius morosus

Hind legs with crossed receptor-apodemes of the femoral chordotonal organ when making a step during walking often do not release the ground after reaching the extreme posterior position. After putting a clamp on the trochanter (stimulation of the campaniform sensilla) the leg is no longer protracted during walking. However, during searching-movements the same leg is moved very far forwards. The anatomical situation of the campaniform sensilla on the trochanter and the sensory innervation of the trochanter is described. After removal of the hair-rows and continuously stimulating the hair-plate at the thorax-coxa-joint the extreme anterior and posterior positions of the leg in walking are displaced in the posterior direction. Front and middle legs operated in this way sometimes do not release the ground at the end of retraction. In searching-movements the same leg is moved in a normal way. If only one side of a decerebrated animal goes over a step, then on the other side a compensatory effect is observed. The main source of this compensatory information appears to be the BF1-hair-plates. If the animal has to drag a weight the extreme anterior and posterior positions of the middle and hind legs are displaced in the anterior direction. Crossing the receptor-apodeme of the femoral chordotonal organ, when it causes the leg to remain in the protraction phase, displaces the extreme posterior position of the ipsilateral leg in front of the operated one in the posterior direction. Influences of different sources on the extreme posterior position can superimpose. A model is presented which combines both a central programme and peripheral sensory influence. The word programme used here means that it does not only determine the motor output but also determines the reactions to particular afferences. The fact that the reaction to a stimulus depends on the internal state of the CNS is also represented by the model.Supported by Deutsche Forschungsgemeinschaft     

Yolk granules are differentially acidified during embryo development in the stick insect Carausius morosus

Newly laid eggs of stick insects comprise a unique fluid ooplasm that is gradually partitioned into a number of yolk granules by invasion of secondary vitellophages. This study aimed at establishing how yolk granules become acidified in the course of embryonic development. Data show that acidified yolk granules are rather scarce and randomly distributed in vitellophages of early embryos, while they tend to increase gradually in number as development proceeds to completion. Yolk granule acidification is progressively more inhibited in the presence of increasing concentrations of chloroquine, monensin and bafilomycin. A pro-protease was identified cytochemically and by immunoblotting in yolk extracts of progressively more advanced embryos. A specific monoclonal antibody raised against this pro-protease helped to demonstrate that it is gradually processed to yield a lower molecular weight polypeptide as development proceeds to completion. This latter polypeptide was identified as a protease using electrophoresis in polyacrylamide gels containing yolk extracts. Simultaneous administration of a fluorescent substrate for cysteine protease and an acidotropic probe produced superimposable labelling patterns, suggesting that only acidified yolk granules possess a proteolytic activity. On the other hand, yolk granules probed simultaneously for acidification and latent pro-protease yielded labelling patterns partially superimposed. Pro-protease labelling is gradually lost as yolk granules are progressively more acidified during development. Distinct labelling patterns were also obtained in vitellophages processed for the simultaneous detection of pro-protease and protease, suggesting that the two activities are expressed by different yolk granule populations, and that one is gradually converted into the other as time goes by.     

Structural heterozygosity and aneuploidy in the parthenogenetic stick insect Carausius morosus Br. (Phasmatodea: Phasmatidae)

The female chromosome complement of the thelytokous stick insect Carausius morosus Br. consists of three metacentric sex chromosomes, four metacentric and 57 acrocentric autosomes. The rare impaternate males have two sex chromosomes. The spermatogenesis is highly aberrant which is evident from the various numbers of univalents, homomorphic and unequal bivalents, and multivalents during first metaphase, and from abnormal segregation patterns during first and second anaphase. The abnormalities are due to aneuploidy and structural heterozygosity. The heterozygosity is maintained by the endomeiotic chromosome duplication in females. Translocations resulting from chiasmata in unequal associations are not formed during female meiosis. It has been discussed that the heterozygosity in males, and consequently in females, is caused by either chromosomal mutations, as indicated by at least ten interchanges and three inversions, or hybridization, indicated by allotriploidy.     

A model of leg coordination in the stick insect,Carausius morosus

A model of interleg coordination presented in a separate report is evaluated here by perturbing the step pattern in three ways. First, when the initial leg configuration is varied, the simulated leg movements assume a stable coordination from natural starting configurations in a natural way (Fig. 1a). They also rapidly re-establish the normal coordination when started from unnatural configurations (Fig. 1b-d). An explicit hierarchy of natural frequencies for the legs of the three thoracic segments is not required. Second, when the coordination is perturbed by assigning one or more legs a retraction velocity different from the rest, gliding coordination or various integer step ratios can be produced (Figs. 2–4). Third, when the swing of one leg is obstructed, characteristic changes in the stepping of other legs occur (Fig. 5). Overall differences between the step patterns of the model and those of the stick insect are related to the form of the coordinating mechanisms. Errors made by the model, such as overlapping swings by adjacent legs or discrepancies in step timing and step end-points, point out the limitations of a model restricted to kinematic parameters.     

A model of leg coordination in the stick insect,Carausius morosus

Mechanisms dependent upon leg position coordinate the alternate stepping of adjacent ipsilateral and contralateral legs in the stick insect. In this insect, swing duration and step amplitude are independent of walking speed. A simple geometrical model of the leg controller is used here to test different mechanisms for compatibility with these two invariant features. Leg position is the state variable of a relaxation oscillator and position thresholds determine the transitions between swing and stance. The coordination mechanisms alter these thresholds. The position-dependent mechanisms considered differ either in the form or the speed-dependence of the function relating the shift in the posterior threshold of the receiving leg to the position of the sending leg. The results identify parameter combinations leading to alternate stepping with symmetric or asymmetric phase distributions, to shifts in the posterior extreme position as a function of speed, to double stepping or to in-phase stepping. An optimal position-dependent excitatory mechanism is described. Finally the consequences of adding either inhibitory influences or time-dependent excitatory influences are analyzed.     

Sex chromosomes and origin of males and sex mosaics of the parthenogenetic stick insect Carausius morosus Br.

The chromosome complements of sporadic males and masculinized females of the thelytokous phasmid Carausius morosus Br. could be analysed in spermatogonia and ovarian follicle cells. Masculinized females with ovaries, ovotestes or testes have the female chromosome number, i.e., 61 autosomes and three sex chromosomes. The sex chromosomes, one being longer than the other two, are metacentric. In one masculinized female with testes the three sex chromosomes were different, apparently through a reciprocal translocation. The masculinized females are considered to be intersexes (phenotypic sex determination). The chromosome complement of males differs from that of females by lacking either one of the sex chromosomes or only a segment of one of these chromosomes (genotypic sex determination). The deleted sex chromosomes appear as acrocentrics and may have arisen through a chiasma between a translocated segment in one sex chromosome and its untransposed homologous region in another sex chromosome. One apparently telocentric sex chromosome may have originated from centric fission together with loss of the other arm. The sex chromosomes are positively heteropycntoic in the psermatogonia, also in those of masculinized females. En bloc heterochromatinization of the sex chromosomes, which seems to be under the direct or indirect control of one or more sites on the sex chromosomes themselves, functions in sex determination. The sex determination does not give a decisive answer to the question whether di-, tri-, or tetraploidy is involved.     

Effects of circum-oesophageal lesion on the behaviour of the stick insect Carausius morosus

The co-ordination of the walking behaviour of decerebrate stick insects is examined and compared with normal behaviour. The walks are fully coordinated but undergo subtle changes in timing, have a longer average step period and show momentary pauses of 50 ms during the time course of protraction movements. In addition a new intersegmental reflex has been discovered. This tactile reflex is used to avoid errors in co-ordination that would be produced by posterior legs stepping onto the tarsi of the legs in front. The reflex has a latency of 100 ms and is easily observed in lesioned animals but is also active, although seldom seen, in slowly walking intact animals.