Structure of ovaries and oogenesis in Corydalidae and Chauliodidae (Insecta, Megaloptera). I. Architecture of adult ovarioles and previtellogenesis.

The results of histological and EM studies on the ovaries of three representatives of Megaloptera: Chauliodes pectinicornis, Nigronia fasciata (Chauliodidae), and Corydalus peruvianus Corydalidae) are presented. It is shown that the ovaries of all 3 investigated species are panoistic (secondary panoistic, = neopanoistic) and consist of numerous (more than a hundred) ovarioles that are differentiated into 3 well-defined regions: the terminal filament, the germarium, and the vitellarium. The germaria of adult females are apparently non-functional and contain germ and somatic cells in various stages of degeneration. The vitellaria are composed of 12-15 developing ovarian follicles (= oocytes surrounded by follicular cells) in a linear arrangement. In adult females these follicles can be classified into early previtellogenic, late previtellogenic, vitellogenic, and choriogenic. During early previtellogenesis oocyte nuclei (= germinal vesicles) contain single nucleolar masses. Histochemical analyses indicate that within the masses DNA as well as AgNOR proteins are present. During subsequent stages of the previtellogenic growth nucleolar masses gradually break down into smaller aggregations of coarse granular material, i.e. multiple nucleoli. In chauliodids the nucleoli are distributed evenly throughout the nucleoplasm while in the corydalid, C. peruvianus, they form a characteristic ring. The presented results are discussed in a phylogenetic context.

Intercellular cytoplasm transport during oogenesis of the moth midge, Tinearia alternata Say (Diptera: Psychodidae).

Polytrophic ovaries of the nematocerous dipteran, Tinearia alternata Say consists of several developmentally synchronized ovarioles each housing only one functional egg chamber with 15 nurse cells and an oocyte. At the early stages of previtellogenesis the nurse cells become polyploid and synthetically active. Their nuclei contain polytene chromosomes and prominent nucleoli. With the advance of previtellogenic growth the nurse cell cytoplasm is loaded with the growing number of ribosomes and contain perinuclear nuage material, mitochondria, electron dense bodies and aggregations of endoplasmic reticulum. All these organelles are transported into the oocyte thanks to the massive and rapid flow of the nurse cell cytoplasmic contents. Nurse cell-oocyte transport is mediated by actin cytoskeleton. Prior to the rapid cytoplasm transfer, F-actin network is associated with the nurse cell membranes while tiny bundles of microfilaments form actin baskets connected with ring canals. Nurse cells in Tinearia lack an extensive scaffold of radially oriented, F-actin bundles (cables) that would tether their nuclei in place, thus preventing ring canals from plugging. The way the nuclei are anchored to their central positions within the cells remains unclear. Towards the final stages of oogenesis nurse cells are almost devoid of cytoplasm and degenerate. Although their nuclei undergo dramatic morphological transformations, typical hallmarks of apoptotic pathway could not be clearly observed. Rapid ooplasmic streaming does not occur.

Neuropteroidea--different ovary structure in related groups.

Three different ovariole types have been described in the Neuropteroidea. In this review, comparative analysis of their structure and function is presented, and the results are used for phylogenetic considerations. Neuropteran polytrophic ovaries exhibit deviations from the basic polytrophic pattern found in other insects. Asynchronous divisions of germ cells result in a variable and unfixed number of cystocytes per cluster. In contrast to the typically branched system, spatial organization of the cystocyte connections in neuropteran egg chambers is almost linear. A more precise comparative study of ovariole structure and function within Neuroptera brings further support for the placement of Coniopterygidae as an early off-shoot from the main neuropteran phylogenetic lineage. Ovaries of Raphidioptera and Megaloptera: Sialidae represent a distinct type of telotrophic organization. Its almost identical character in both groups favours the concept on the origin of this telotrophy from the common ancestral polytrophic condition. Ovarioles of Megaloptera: Corydalidae are neopanoistic and it is emphasized here that this organization must have evolved independently from the polytrophic background. A hypothesis on paraphyletic origin of Megaloptera is thus supported.

Diptera--ovary structure and oogenesis in midges and flies.

Comparative study of ovary development and oogenesis in the dipterans revealed significant differences between the Nematocera (lower dipterans, midges) and the Brachycera (true flies). The occurrence of these differences emphasizes well the phylogenetic division of the Diptera into these major subgroups. Basic discrepancies were found in the course of ovary development and in the mode of follicular cell differentiation. In contrast to more advanced flies, in midges the initial stages of germ cell differentiation, i.e. divisions of gonial cells, germ cell cluster formation and diversification of cystocytes within clusters take place exclusively in the larval and early pupal stages. Moreover, the formation of cystocyte clusters precedes that of ovarioles. Differences in the behaviour of some follicular cells found between the ovarian follicles of midges and advanced flies suggest that both major dipteran subgroups may differ in the scenario and/or the mechanisms of terminal signalling leading to the determination of the anteriormost part of the body.

Germ cells cluster organization in polytrophic ovaries of neuroptera.

Histological and ultrastructural analysis of polytrophic ovary structure in Neuroptera revealed an unusual organization of their germ cell clusters. In all species under study (representing 5 families), clusters with variable and unfixed numbers of cystocytes are formed. Moreover, spatial organization of cystocyte connections within the cluster is linear rather than typically branched; only a few branching sites being observed. The oocyte is located in the central, always linear, part of the cluster and therefore is directly connected via intercellular bridges with only two nurse cells. It is postulated here that the linear character of germ cell clusters in Neuroptera may result from asynchrony of cystocyte divisions. Mechanisms of germ cell cluster formation and differentiation are discussed.

Extrachromosomal amplification of rDNA in oocytes of Hemerobius spp. (Insecta, Neuroptera).

In previtellogenic oocytes of the neuropteran, Hemerobius spp., two distinct, DNA-positive intranuclear structures have been observed. Chromosomes of meiotic prophase assemble in the center of the oocyte nucleus forming a highly polymorphic karyosphere, which persists in this position until the very late stages of vitellogenesis. The extrachromosomal DNA body, containing amplified ribosomal genes, undergoes fragmentation and dispersion in the nucleoplasm. At the onset of previtellogenic growth, transcription of extra rDNA starts, which is accompanied by the appearance of dense, granular material (multiple nucleoli). Arising nucleoli gradually fill the nucleoplasm. At the electron microscopic (EM) level two electron dense structural forms of the granular material have been described. Together with general histological and ultrastructural analysis the amplification of rDNA genes in Hemerobius spp. oocytes has been demonstrated by means of the spreading technique, which has shown that extra rDNA is organized in rings containing various numbers of active ribosomal genes. The transcription activity of amplified genes is manifested in the form of typical "Christmas tree" structures.

Egg envelopes in diplopods, a comparative ultrastructural study.

By means of electron microscopy two types of egg envelope have been described in representatives of two diplopod subclasses, the Chilognatha and the Pselaphognatha. The vitelline envelope appears on the oocyte surface in early previtellogenesis and persists till ovulation. In its thin and filamentous structure it resembles basement membranes. During vitellogenesis electron dense material is deposited on filamentous scaffolding which fills the space between the oolemma and the vitelline envelope. As a result, the thick and spongy or filamentous chorion is formed. In the present study it has been shown that regardless of the type of oogenesis (solitary-the Chilognatha, or follicular-the Pselaphognatha) both envelopes in diplopods are produced by the oocyte itself, and although completely different in structure and time of appearance, they must be both considered as primary.

Ultrastructural studies on accessory nuclei in developing oocytes of the crustacean, Siphonophanes grubei.

Numerous accessory nuclei (AN) occur within peripheral cytoplasm of Siphonophanes grubei oocytes. They exhibit typical nuclear structure, with double membrane envelope pierced by pore complexes. Although no explicit evidence was shown, indirect arguments exist indicating that AN originate from the oocyte nucleus. Presence of clumps of DNP material within AN suggests that AN might play some role in amplified DNA metabolism. Participation of AN in cellular membrane elaboration is also postulated.

Deposition of calcium salts in oocytes and ovarian somatic tissue of millipedes.

Until recently calcium concretions commonly encountered in the millipede ooplasm were considered as mineral store, incorporated in larva exoskeleton during embryogenesis. The presence of mineral bodies also in somatic tissues of millipedes (including ovarian epithelia) suggests that their appearance is mainly associated with detoxification of physiologically active mineral ions excess.