Aspects of amino acid requirements for in vitro evagination of imaginal leg discs inDrosophila melanogaster

Summary A method of staging late third instar larvae on the basis of salivary gland morphology is described. Using this technique, we investigated stage related amino acid requirements forDrosophila leg disc evagination in vitro. It was found that the requirement for glutamine lasted longer than that of proline. The staging technique should help in the detailed exploration of the late 3rd instar time period in order to bridge the gap between biochemistry and morphogenesis in the initiation of disc evagination.     

Identification of newly synthesized wing imaginal disc proteins induced by 20-hydroxyecdysone inGalleria mellonella

Summary Wing imaginal discs from 7th instarGalleria mellonella L. larvae evaginate and exhibit tracheolar elongation when exposed to 20-hydroxyecdysone in vitro. This response was elicited within 24 h of treatment as was a greater than fourfold stimulation of the incorporation of [³H]leucine into disc proteins. Autoradiographic analyses of [³⁵S]methionine labeled polypeptides separated on two-dimensional gels, however, revealed no differences in protein profiles between control and treated discs until 48 h following exposure to molting hormone. At this time, wing imaginal discs exposed to 1 μg/ml 20-hydroxyecdysone synthesized four unique polypeptides not detected either in controls or in discs treated for 24 h. These four new proteins were also found to be synthesized by imaginal discs that had evaginated in vivo. These results suggest that these proteins are normally synthesized subsequent to evagination and do not play a role in the morphological events necessary for evagination. Mention of a commercial or proprietary product in this paper does not constitute an endorsement of that product by the USDA. S. G. M. is employed through a cooperative agreement between the Insect Attractants, Behavior and Basic Biology Laboratory and the Department of Entomology, University of Florida.     

Light microscopy and scanning electron microscopy of the In vitro evagination process of Echinococcus multilocularis protoscolices

Marchiondo A. A. and Andersen F. L. 1984. Light microscopy and scanning electron microscopy of the in vitro evagination process of Echinococcus multilocularis protoscolices. International Journal for Parasitotogy14:151–157. During histogenesis of the protoscolices of Echinococcus multilocularis, the apical portion of the protoscolex consisting of the suckers, rostellum and hook region develops as an introversion and invagination within the tissue of the basal portion. In vitro incubation of protoscolices in evagination fluid stimulates the emergence of the apical portion. The initiation of evagination is first detected by a surface change in the basal portion. The smooth contour of this surface which lacks microtriches becomes transformed into tegumental indentations that form transverse and longitudinal furrows within the basal tegument as the protoscolices contract and expand, respectively. An orifice formed at the site or junction where the apical portion is invaginated begins to expand laterally in order to allow emergence of the suckers. The hooks are arranged within the invaginated protoscolex with blades directed towards the basal orifice, the handles directed towards the peduncle and the guards directed laterally. This arrangement persists throughout the evagination of the suckers and rostellum until the apical dome of the hook region emerges, thereby rotating the blades laterally in the direction of the peduncle and rotating the handles and guards medially to assume a coronal arrangement. Evagination is an asynchronous event and therefore allows observation of individual protoscolices in various stages of emergence.     

Significance of absorption, oxidation, and binding to toxicity of four ecdysone agonists in multi-resistant cotton leafworm

Treatment of last-instar larvae of multi-resistant cotton leafworm Spodoptera littoralis with four dibenzoylhydrazines, methoxyfenozide (RH-2485), tebufenozide (RH-5992), halofenozide (RH-0345), and RH-5849, resulted in premature molting leading to death. Methoxyfenozide was the most toxic followed by tebufenozide, halofenozide, and RH-5849. To explain differences in toxicity, especially between multi-resistant and laboratory strains, absorption in the body tissues and oxidative metabolism were tested with 14C-labeled ecdysone agonist and a Lineweaver-Burk assay, respectively. Then to address different compound potencies in multi-resistant strains, the potency of the four ecdysone agonists was measured based on their ability to mimic the natural insect molting hormone, 20-hydroxyecdysone (20E) by inducing evagination in isolated imaginal wing discs. Using monoclonal antibody 9B9, the presence of ecdysteroid receptors in imaginal discs in vitro was confirmed. In parallel, Scatchard plot analysis with whole imaginal wing discs cultured with different concentrations of 3H-labeled ponasterone A indicated no significant difference in affinity and in number of target sites for binding between multi-resistant and susceptible laboratory strains. The four compounds tested caused the effect as agonists of 20E in vitro, and typically the order of their toxicities (LC50s) corresponded with that for evagination-induction with whole imaginal discs.     

Invagination and Evagination: A Hydromechanical Model

It has been proposed that processes of invagination and evagination be considered in the context of a single, hydromechanical, model. The model is based on the assumption that the structures demonstrating invaginations and evaginations are closed systems capable of changing their intracavitary pressure in an autonomous regime. The mass, which occupies the cavity, should overcome the resistance of the surrounding membrane during its growth. In places of the weakest resistance, the inner mass expands especially quickly: it bulges out. If the pressure under the membrane is less than the exterior one, the process goes in the opposite direction: the outer mass intrudes (invaginates) into the cavity, causing its wall to sag in the weakest regions.     

Taenia hydatigena. II. Evagination of cysticerci and establishment in dogs

Conditions in vitro producing high rates of evagination of the cysticercus of Taenia hydatigena were obtained with an enzyme mixture of either 100 nig trypsin or 100 mg pancreatin and 5 ml whole dog bile made up to 100 ml with Hanks' balanced salt solution (BSS). Single enzyme solutions, or whole bile, in Hanks' BSS were not efficient. A pretreatment with an acid pepsin solution had little effect, on the rate of evagination. Evagination in vivo took place in the small intestine where a large portion of the larval tissue was shed almost immediately. There was no significant relationship between the mean weight of cysticerci fed to dogs AND the mean weight of scoleces recovered after 24 hr or 20 days.     

Polarity and morphogenesis of the eye epithelium requires the adhesion junction associated adaptor protein Traf4

ABSTRACT

During development, neuroepithelial progenitors acquire apico-basal polarity and adhere to one another via apically located tight and adherens junction complexes. This polarized neuroepithelium must continue to integrate cells arising through cell divisions and intercalation, and allow for cell movements, at the same time as undergoing morphogenesis. Cell proliferation, migration and intercalation all occur in the morphing embryonic eye. To understand how eye development might depend on dynamic epithelial adhesion, we investigated the function of a known regulator of junctional plasticity, Tumour necrosis factor receptor-associated factor 4 (Traf4). traf4a mRNA is expressed in the developing eye vesicle over the period of optic cup morphogenesis, and Traf4a loss leads to disrupted evagination and elongation of the eye vesicles, and aberrant organization and apico-basal polarity of the eye epithelium. We propose a model whereby Traf4a regulates apical junction plasticity in nascent eye epithelium, allowing for its polarization and morphogenesis.

Symbols and Abbreviations: AB: apico-basal; aPKC: atypical protein kinase-C; CRISPR: clustered regularly-interspaced short palindromic repeats; GFP: green fluorescent protein; hpf: hours post-fertilization; MO: antisense morpholino oligonucleotide; pHH3: phospho histone H3; ss: somite stage; Traf4: Tumour necrosis factor receptor-associated factor 4; ZO-1: zona occludens-1