Development of embryonic membranes in the silverfish Lepisma saccharina linnaeus (insecta: Zygentoma, Lepismatidae)

Development and fate of embryonic membranes in the silverfish Lepisma saccharina was examined throughout embryogenesis. The amnioserosal folds first arise as serosal folds that are completed by the later addition of the amnion from the embryo's margins as in archaeognaths. The close link between production of the amnion and formation of the folds should not be assigned to Dicondylia but to Pterygota as an autapomorphy. During fold formation, folding of embryonic membranes beneath the embryo is less extensive and the ventral cupping of the embryo plays a larger role comparable to that occurring in archaeognath embryos. In L. saccharina, the embryonic membrane pore (the amniopore) varies in its manner of closure, either by complete fusion of serosal folds or by formation of a serosal cuticular plug between them as in archaeognaths. Although, in many aspects of its embryogenesis, L. saccharina retains the primitiveness of archaeognaths, its amnioserosal folds persist and are well integrated into its embryogenesis as the amnioserosal fold-amniotic cavity system is established and as occurs in many pterygote embryos; this may be thus regarded as an autapomorphy of Dicondylia.     

Morphological effects of juvenile hormone mimics on embryonic development in the bug,Pyrrhocoris apterus

Summary Embryos ofPyrrhocoris apterus exposed to juvenile hormone mimics (JH) were examined throughout development to determine the progressive effects of treatment. Prior to blastokinesis whole experimental embryos did not differ morphologically from control embryos fixed at the same stage. Treated embryos failed to complete blastokinesis due to abnormal breakage of the extra-embryonic membranes.In the embryo-larva transition, JH exposure interfered with dorsal closure, with the consolidation of the nerve cord, and with the extension of appendages. Yet pigmentation and muscle differentiation occurred.These effects were interpreted and discussed with reference to the role of juvenile hormone in post-embryonic development.This is a portion of a dissertation submitted to the graduate school of Harvard University, in partial fulfillment of the requirements for the degree of Doctor of Philosophy (1973). It was previously reported in abstract (Enslee and Riddiford, 1970). This research was supported by NIGMS Training Grant T01 GM 00036-09, 11, 12, 13 to E.C.E. and NSF grants GB 6730, GB 7966 to L.M.R.     

Embryonic development of Eucorydia yasumatsui Asahina,with special reference to external morphology (Insecta: Blattodea,Corydiidae)

As the first step in the comparative embryological study of Blattodea, with the aim of reconstructing the groundplan and phylogeny of Dictyoptera and Polyneoptera, the embryonic development of a corydiid was examined and described in detail using Eucorydia yasumatsui . Ten to fifteen micropyles are localized on the ventral side of the egg, and aggregated symbiont bacterial “mycetomes” are found in the egg. The embryo is formed by the fusion of paired blastodermal regions, with higher cellular density on the ventral side of the egg. This type of embryo formation, regarded as one of the embryological autapomorphies of Polyneoptera, was first demonstrated for “Blattaria” in the present study. The embryo undergoes embryogenesis of the short germ band type, and elongates to its full length on the ventral side of the egg. The embryo undergoes katatrepsis and dorsal closure, and then finally, it acquires its definitive form, keeping its original position on the ventral side of the egg, with its anteroposterior axis never reversed throughout development. The information obtained was compared with that of previous studies on other insects. “Micropyles grouped on the ventral side of the egg” is thought to be a part of the groundplan of Dictyoptera, and “possession of bacteria in the form of mycetomes” to be an apomorphic groundplan of Blattodea. Corydiid embryos were revealed to perform blastokinesis of the “non‐reversion type (N)”, as reported in blaberoid cockroaches other than Corydiidae (“Ectobiidae,” Blaberidae, etc.) and in Mantodea; the embryos of blattoid cockroaches (Blattidae and Cryptocercidae) and Isoptera undergo blastokinesis of the “reversion type (R),” in which the anteroposterior axis of the embryo is reversed during blastokinesis. Dictyopteran blastokinesis types can be summarized as “Mantodea (N) + Blattodea [= Blaberoidea (N) + Blattoidea (R) + Isoptera (R)]”.     

Extraembryonic development in insects and the acrobatics of blastokinesis

Extraembryonic development is familiar to mouse researchers, but the term is largely unknown among insect developmental geneticists. This is not surprising, as the model system Drosophila melanogaster has an extremely reduced extraembryonic component, the amnioserosa. In contrast, most insects retain the ancestral complement of two distinct extraembryonic membranes, amnion and serosa. These membranes are involved in several key morphogenetic events at specific developmental stages. The events of anatrepsis and katatrepsis-collectively referred to as blastokinesis-are specific to hemimetabolous insects. Corresponding events in holometabolous insects are simplified and lack formal names. All insects retain dorsal closure, which has been well studied in Drosophila. This review aims to resurrect both the terminology and awareness of insect extraembryonic development-which were last common currency in the late nineteenth and early twentieth centuries-as a number of recent studies have identified essential components of these events, through RNA interference of developmental genes and ectopic hormonal treatments. As much remains unknown, this topic offers opportunities for research on tissue specification, the regulation of cell shape changes and tissue interactions during morphogenesis, tracing the origins and final fates of cell and tissue lineages, and ascertaining the membranes' functions between morphogenetic events.     

Oncopeltus fasciatus zen is essential for serosal tissue function in katatrepsis

Unlike most Hox cluster genes, with their canonical role in anterior-posterior patterning of the embryo, the Hox3 orthologue of insects has diverged. Here, we investigate the zen orthologue in Oncopeltus fasciatus (Hemiptera:Heteroptera). As in other insects, the Of-zen gene is expressed extraembryonically, and RNA interference (RNAi) experiments demonstrate that it is functionally required in this domain for the proper occurrence of katatrepsis, the phase of embryonic movements by which the embryo emerges from the yolk and adjusts its orientation within the egg. After RNAi knockdown of Of-zen, katatrepsis does not occur, causing embryos to complete development inside out. However, not all aspects of expression and function are conserved compared to grasshopper, beetle, and fly orthologues. Of-zen is not expressed in the extraembryonic tissue until relatively late, suggesting it is not involved in tissue specification. Within the extraembryonic domain, Of-zen is expressed in the outer serosal membrane, but unlike orthologues, it is not detectable in the inner extraembryonic membrane, the amnion. Thus, the role of zen in the interaction of serosa, amnion, and embryo may differ between species. Of-zen is also expressed in the blastoderm, although this early expression shows no apparent correlation with defects seen by RNAi knockdown.     

Egg structure and outline of embryonic development of the basal mantodean, Metallyticus splendidus Westwood, 1835 (Insecta,Mantodea, Metallyticidae)

The egg structure and outline of the embryonic development of Metallyticus splendidus of one of the basal Mantodea representatives, Metallyticidae, were described in the present study. The results obtained were compared with those from the previous studies, to reconstruct and discuss the groundplan of Mantodea and Dictyoptera. In M. splendidus, the egg is spheroidal, it has a convex ventral side at the center in which numerous micropyles are grouped, and it possesses a conspicuous hatching line in its anterior half. These are the groundplan features of mantodean eggs and the “grouped micropyles in the ventral side of the egg” are regarded as an apomorphic groundplan feature of Dictyoptera. A small circular embryo is formed by a simple concentration of blastoderm cells, which then undergoes embryogenesis of the typical short germ band type. Blastokinesis is of the “non-reversion type” and the embryo keeps its original superficial position and original orientation throughout embryonic development. During the middle stages of development, the embryo undergoes rotation around the egg's anteroposterior axis. These features are a part of the groundplan of Mantodea. It is uncertain whether sharing of the “non-reversion type” of blastokinesis by Mantodea and blaberoidean Blattodea can be regarded as homology or homoplasy.