The silkmoth chorion: Morphogenesis of surface structures and its relation to synthesis of specific proteins

The morphogenesis of four spatially differentiated surface regions of the silkmoth eggshell (chorion) has been documented and correlated with differing patterns of chorion protein synthesis within the corresponding secretory cells. During the first half of choriogenesis the polygonal pattern of ridges which cover the entire chorion appears. Regional differences in the morphology of developing ridges are not accompanied by significant protein differences, and thus presumably reflect differences in secretory cell behavior and shape. During the second half of choriogenesis expanding domes of the chorion located immediately beneath three-cell junctions of the overlying secretory surface become prominent surface features exclusively in the aeropyle crown region. Domes are composed of a thin lamellar skin and an inner buttressing “filler.” Continued filler deposition appears to cause a ripping of the lamellar skin, transforming the dome into a multiple-pronged crown that overflows with filler. Continued synthesis of lamellar chorion components elongates and strengthens the crowns until they can stand alone without the support of filler. In the aeropyle crown region, synthesis of regionally specific proteins begins in the second half of choriogenesis and accelerates until the final stages, in parallel with dome/crown formation. The more numerous proteins which are common to all regions are synthesized at approximately equal rates within all regions, and their synthesis decelerates toward the end of choriogenesis. Fifteen of the proteins (excluding filler) which are found predominantly in the aeropyle crown region may be necessary but not sufficient for crown formation, since they also occur in the stripe region (1); presumably the secretory cell surfaces mold the same components differently in the two regions. Filler appears to play an important scaffolding role in crown formation. A group of eight aeropyle crown region-specific chorion proteins which compose filler have been identified on two-dimensional gels and shown to be restricted to one of five previously described classes of chorion proteins.     

Heterochrony and the introduction of novel modes of morphogenesis during the evolution of moth choriogenesis

Summary Choriogenesis in silkmoths (superfamily Bombycoidea) and in a sphingid moth (super-family Sphingoidea) differ in major, but discrete, ways. In silkmoths, the predominant lamellar component assembles early in choriogenesis to form a thin framework. Subsequently, the lamellar framework is modified, first by expansion, and then by densification. Finally, ornate surface structures called aeropyle crowns form in some silkmoths, but they are absent in the species described here. In the sphingid, lamellar framework formation occurs throughout choriogenesis rather than largely during the early stages as in silkmoths. Lamellar densification occurs, but lamellar expansion and aeropyle crown formation do not. An evolutionary model is presented that accounts for the observed morphogenetic differences. Patterns of chorion protein synthesis in the sphingid differ from those in silkmoths in ways that are interpretable in light of the observed morphogenetic differences and the previously postulated functions of the proteins in silkmoths.     

Analysis of cell movements and fate mapping during early embryogenesis in Drosophila melanogaster

Four spatially differentiated surface regions, called aeropyle crown, flat, stripe, and micropyle, are found on the mature eggshell (chorion). Specializations of the apical surfaces of the secretory follicular epithelial cells are implicated in the formation of regional patterns on the chorion. Some of these specializations are restricted to cells overlying certain regions; others are shared by more than one region. Differences between regions are more apparent on the surface than within the bulk of the chorion. Evidence is presented that distinct cell populations, corresponding to the regions, are present long before the start of choriogenesis. One hundred eighty-six chorion-specific polypeptides have been resolved by two-dimensional gel electrophoresis. Fifteen of these are found entirely or predominantly in the aeropyle crown and stripe regions, while eight others are restricted to the aeropyle crown region. Certain of the spatially restricted components are quite unusual in their amino acid compositions when compared with previously analyzed chorion components. Others are closely related, although clearly distinct.     

Morphogenesis of silkmoth chorion: sequential modification of an early helicoidal framework through expansion and densification

The silkmoth chorion is a helicoidally layered, fibrous structure which is constructed in four sequential morphogenetic modes, beginning with the assembly of a thin, low density lamellar framework. Subsequently, the framework expands in height by the insertion of additional fiber sheets into the preexisting lamellae. This expansion mode begins farthest from the follicular secretory cells and progresses in reverse. Individual fibers then grow in thickness, presumably through accretion of newly synthesized proteins, and eventually fuse. This third mode, which also begins in the most distant lamellae and proceeds in reverse, is called densification, as it results in an approximately two fold increase in overall chorion density without further lamellar expansion. Finally, lamellogenesis is recapitulated in miniature in a region of the chorion's surface, where very-late-forming lamellae are molded into prominent surface structures, the aeropyle crowns. The densification and especially the expansion modes suggest considerable fluidity in the developing chorion, consistent with its proposed cholesteric liquid crystalline structure. Such a structure is also consistent with numerous deviations from the ideal helicoidal array. These distortions and defects are described and discussed in terms of their possible origin and function.     

Specific protein synthesis in cellular differentiation: IV. The chorion proteins of Bombyx mori and their program of synthesis

Detailed analysis of the chorion proteins of Bombyx mori reveals more than 70 components, each distinguished by electrophoretic mobility, relative abundance, and kinetics of synthesis. Many proteins are strain specific. A protein numbering system is established, based on isoelectric point and molecular weight. As in Antheraea polyphemus, chorion proteins are produced asynchronously, individual proteins showing characteristic developmental kinetics. The synthetic program is analyzed in detail. Stages of choriogenesis are defined according to the pattern of protein synthesis, and their relative and absolute durations are determined. In a few stages, synthesis of numerous protein cohorts is coordinately initiated.     

Specific protein synthesis in cellular differentiation: II. The program of protein synthetic changes during chorion formation by silkmoth follicles,and its implementation in organ culture

During their differentiation, the follicular epithelial cells of the silkmoth, Antheraea polyphemus, produce the extracellular proteinaceous eggshell or chorion. Choriogenesis entails continuous changes in cell-specific protein synthesis; the various chorion proteins are synthesized with distinct kinetics. On the basis of protein synthetic profiles, 17 stages of choriogenesis are defined. The average duration of the stages is 3.0 hr, and thus choriogenesis lasts a total of approximately 51 hr. This program of protein synthetic changes is autonomous; i.e., it is implemented with normal kinetics by follicles cultured in isolation in a defined tissue culture medium.     

Variation, variability, and the origin of the avian endocranium: insights from the anatomy of Alioramus altai (Theropoda: Tyrannosauroidea)

The internal braincase anatomy of the holotype of Alioramus altai, a relatively small-bodied tyrannosauroid from the Late Cretaceous of Mongolia, was studied using high-resolution computed tomography. A number of derived characters strengthen the diagnosis of this taxon as both a tyrannosauroid and a unique, new species (e.g., endocranial position of the gasserian ganglion, internal ramification of the facial nerve). Also present are features intermediate between the basal theropod and avialan conditions that optimize as the ancestral condition for Coelurosauria--a diverse group of derived theropods that includes modern birds. The expression of several primitive theropod features as derived character states within Tyrannosauroidea establishes previously unrecognized evolutionary complexity and morphological plasticity at the base of Coelurosauria. It also demonstrates the critical role heterochrony may have played in driving patterns of endocranial variability within the group and potentially reveals stages in the evolution of neuroanatomical development that could not be inferred based solely on developmental observations of the major archosaurian crown clades. We discuss the integration of paleontology with variability studies, especially as applied to the nature of morphological transformations along the phylogenetically long branches that tend to separate the crown clades of major vertebrate groups.     

In vitro analysis of Bombyx mori early chorion gene regulation: stage specific expression involves interactions with C/EBP-like and GATA factors

This is the first attempt to identify regulatory elements that are involved in early choriogenesis of the silkworm Bombyx mori. A new cis element in the promoter region of five early chorion genes was identified. The consensus sequence of this element matches the consensus of the C/EBP DNA binding site. Moreover, this sequence interacts with a 70 kD protein (pX2) present in follicular nuclear extracts and complex formation exhibits early developmental specificity. There is strong evidence that this factor belongs to the C/EBP family. Surprisingly, the same protein binds with the same developmental specificity to a similar sequence of a late chorion gene promoter, which has been previously defined as the binding site for a putative late specific factor, BCFII. The possibility that pX2 and BCFII are isoforms or modifications of the same protein factor, which is presumably able to bind to the highly similar sequence elements of both early and late genes, is discussed. A hypothesis involving protein-protein interactions between C/EBP (pX2/BCFII) and GATA during choriogenesis is presented to explain the temporal specificity of chorion genes.     

Evolution and higher-order structure of architectural proteins in silkmoth chorion.

Genomic and cDNA clones have been sequenced that encode the E2 silkmoth chorion protein. E2 assembles with E1 [Regier, J.C. and Pacholski, P. (1985) Proc. Natl. Acad. Sci. USA, 82, 6035-6039] to form the 'filler' that helps mold prominent chorion surface structures called aeropyle crowns. E2 has two distinct domains. The amino terminal domain consists of four alternating stretches of hydrophobic and hydrophilic residues, the first three of which are homologous in sequence to about half of the E1 protein. Comparison of predicted secondary structures provides further support for the localized homology of E2 and E1. The carboxy terminal domain of E2 is much longer, is hydrophilic and consists entirely of multiple tandem copies of a single, variant hexapeptide repeat sequence that is absent from E1. Numbers of hexapeptide repeat sequences differed dramatically in two animals. The types of events required for such variation are discussed. Finally, we have elaborated our earlier model for how E proteins may assemble in vivo to form filler.     

Phylogeny of Steinernema travassos, 1927 (Cephalobina: Steinernematidae) inferred from ribosomal DNA sequences and morphological characters

Entomopathogenic nematodes in Steinernema, together with their symbiont bacteria Xenorhabdus, are obligate and lethal parasites of insects that can provide effective biological control of some important lepidopteran, dipteran, and coleopteran pests of commercial crops. Phylogenetic relationships among 21 Steinernema species were estimated using 28S ribosomal DNA (rDNA) sequences and morphological characters. Sequences of the rDNA internal transcribed spacers were obtained to provide additional molecular characters to resolve relationships among Steinernema carpocapsae, Steinernema scapterisci, Steinernema siamkavai, and Steinernema monticolum. Four equally parsimonious trees resulted from combined analysis of 28S sequences and 22 morphological characters. Clades inferred from analyses of molecular sequences and combined datasets were primarily reliably supported as assessed by bootstrap resampling, whereas those inferred from morphological data alone were not. Although partially consistent with some traditional expectations and previous phylogenetic studies, the hypotheses inferred from molecular evidence, and those from combined analysis of morphological and molecular data, provide a new and comprehensive framework for evaluating character evolution of steinernematids. Interpretation of morphological character evolution on 6 trees inferred from sequence data and combined evidence suggests that many structural features of these nematodes are highly homoplastic, and that some structures previously used to hypothesize relationships represent ancestral character states.     

Ootaxonomy and eggshell ultrastructure of Phlebotomus sandflies

The eggshell structure of four sandfly species: Phlebotomus perniciosus Newstead, P.perfiliewi Parrot, P.papatasi Scopoli and P.duboscqi Neveu-Lemaire, was examined by scanning and transmission electron microscopy (SEM and TEM). At the TEM level, the eggshell appears to have a homogeneous vitelline envelope and a thick chorion. At SEM level, the eggshell of all species is characterized by the outer chorion forming a series of fifteen to twenty longitudinal sinuous ridges, cross-linked in places to form a pattern of polygons, each line of the chorion consisting of columns arranged in a palisade. The aeropyle region of the egg is described for the first time in phlebotomine sandflies. Specific characters of the eggshell topography are described for distinguishing between these and other species of Phlebotomus.     

Morphogenesis of silkmoth chorion: Initial framework formation and its relation to synthesis of specific proteins

Morphogenesis of the silkmoth eggshell is described at the ultrastructural level. Four zones are each assembled in a distinct manner and during a distinct developmental period: the innermost vitelline membrane and the adjacent trabecular layer appear consecutively, followed by a thin sieve layer, and a thick, lamellate chorion. Once formed, the sieve layer remains attached to microvilli, and thus all components which assemble into lamellae must pass through the sieve layer. Initially, lamellogenesis (and sieve layer formation) occurs in patches overlying trabeculae. Lamellae quickly fuse and new ones are added, presumably by apposition. Distinct types of lamellae seen in the mature chorion are already distinguishable in early lamellogenesis. The final lamellar number is attained before the developing chorion is one-half its final thickness or one-fifth its final dry weight. The early lamellae constitute a framework which is subsequently modified through expansion and densification. Proteins which may represent components of various parts of the eggshell have been identified on the basis of their timing of synthesis, relative amino acid compositions, and spatial distributions within the chorion.     

Walk it off: predictive power of appendicular characters toward inference of higher‐level relationships in Laniatores (Arachnida: Opiliones)

Morphological characters are essential for establishing phylogenetic relationships, delimiting higher‐level taxa, and testing phylogenetic relationships inferred from molecular sequence data. In cases where relationships between large clades remain unresolved, it becomes imperative to establish which character systems are sound predictors of phylogenetic signal. In the case of Laniatores, the largest suborder of Opiliones, some superfamilial relationships remain unresolved or unsupported, and traditionally employed phenotypic characters are typically of utility only at the family level. Here we investigated a promising set of morphological characters that can be discretized and scored in all Opiliones: cuticular structures of the distal podomeres (metatarsi and tarsi). We intensively sampled members of all known families of Laniatores, and define here three new, discrete appendicular characters toward refinement of Laniatores superfamilial systematics: metatarsal paired slits (MPS; occurring in all Laniatores except Sandokanidae), proximal tarsomeric gland (PTG; in Icaleptidae, Fissiphalliidae, and Zalmoxidae), and tarsal aggregate pores (TAP; found in Gonyleptoidea, Epedanoidea, and Pyramidopidae). We conducted statistical tests on each character to characterize the strength of phylogenetic signal and assess character independence, based on alternative tree topologies of Laniatores. All three characters had high retention indices and bore significantly strong phylogenetic signal. Excepting one pairwise comparison, morphological characters did not evolve in a correlated manner, indicating that appendicular morphology does not constitute a single character system. Our results demonstrate the predictive power and utility of appendicular characters in Opiliones phylogeny, and proffer a promising source of diagnostic synapomorphies for delimiting superfamilies.     

Evolution of male tail development in rhabditid nematodes related to Caenorhabditis elegans

The evolutionary pathway that has led to male tails of diverse morphology among species of the nematode family Rhabditidae was reconstructed. This family includes the well-studied model species Caenorhabditis elegans. By relating the steps of male tail morphological evolution to the phenotypic changes brought about by developmental mutations induced experimentally in C. elegans, the goal is to identify genes responsible for morphological evolution. The varying morphological characters of the male tails of several rhabiditid species have been described previously (Fitch and Emmons, 1995, Dev. Biol. 170:564-582). The developmental events preceding differentiation of the adult structures have also been analyzed; in many cases the origins of varying adult morphological characters were traced to differences during ontogeny. In the present work, the evolutionary changes producing these differences were reconstructed in the context of the four possible phylogenies supported independently by sequences of 18S ribosomal RNA genes (rDNA). Two or more alternative states were defined for 36 developmental and adult morphological characters. These characters alone do not provide sufficient data to resolve most species relationships; however, when combined with the rDNA characters, they provide stronger support for one of the four rDNA phylogenies. Assuming a model of ordered transformations for multistate developmental characters generally results in greater resolution. Transformations between character states can be assigned unequivocally by parsimony to unambiguous branches for most of the characters. Correlations are thereby revealed for some of the developmental characters, indicating a probability of a shared developmental or genetic regulatory pathway. Four of the unequivocal character state changes on unambiguously supported branches closely resemble the phenotypic changes brought about by known mutations in C. elegans. These mutations define genes that are known to act in genetic regulatory hierarchies controlling pattern formation, differentiation, and morphogenesis. Although these studies are still at an early stage, these results strongly suggest that parallel studies of developmental mutants in C. elegans and of morphological and developmental evolution among related nematodes will help define genetic changes underlying the evolution of form.