Mariusz K. Jaglarz

Mouse early oocytes are transiently polar: three-dimensional and ultrastructural analysis

The oocytes of many invertebrate and non-mammalian vertebrate species are not only asymmetrical but also polar in the distribution of organelles, localized RNAs and proteins, and the oocyte polarity dictates the patterning of the future embryo. Polarily located within the oocytes of many species is the Balbiani body (Bb), which in Xenopus is known to be associated with the germinal granules responsible for the determination of germ cell fate. In contrast, in mammals, it is widely believed that the patterning of the embryo does not occur before implantation, and that oocytes are non-polar and symmetrical. Although the oocytes of many mammals, including mice and humans, contain Bbs, it remains unknown how and if the presence of Bbs relates to mouse oocyte and egg polarity. Using three-dimensional reconstruction of mouse neonatal oocytes, we showed that mouse early oocytes are both asymmetrical and transiently polar. In addition, the specifics of polarity in mouse oocytes are highly reminiscent of those in Xenopus early oocytes. Based on these findings, we conclude that the polarity of early oocytes imposed by the position of the centrioles at the cytoplasmic bridges is a fundamental and ancestral feature across the animal kingdom.

Organization and possible functions of microtubule cytoskeleton in hymenopteran nurse cells.

The results of systematic cytochemical and EM studies on the distribution of actin filaments and microtubules in hymenopteran nurse cells are presented. We demonstrate that each nurse cell nucleus is surrounded by a thick three-dimensional cage of microtubules that is engaged in maintaining the position of the nuclei in the cell centers during the flow of the cytoplasm from nurse cells into the oocyte. Hence, the cages represent functional counterparts of actin bundles described in the Drosophila nurse cells. Furthermore, our data suggest that a subset of the microtubules is involved in transferring nuage aggregates from the vicinity of the nucleus towards the nurse cell periphery and the nearest intercellular bridge. A conclusion is reached that despite similar polytrophic organization of the ovaries in both hymenopterans and dipterans, the physiology of their nurse cell-oocyte syncytia appears distinctly different.

Structure of the ovaries and follicular epithelium morphogenesis in Drosophila and its kin

In insects, the ovarian follicular epithelium morphogenesis has been intensively studied and best characterized in the fruit fly, Drosophila melanogaster. It is well established that initially identical somatic follicular cells (FCs) form a simple epithelium overlying the germline cells, but during oogenesis, they diversify into a number of morphologically distinct subpopulations each responsible for creating specific eggshell structures. In addition, some FC subpopulations (e.g. polar cells) are indispensable in establishing antero-posterior and dorso-ventral ovarian follicle axes and patterning of the developing embryo. The morphological and molecular changes that occur during follicular epithelium morphogenesis in Drosophila are frequently considered as a paradigm of the FC diversification in all flies. However, recent comparative studies indicate that, in dipterans, the functioning of the ovarian follicles is diverse, group-specific and may significantly differ from the Drosophila model system. We discuss the similarities and differences of the ovary structure and follicular epithelium morphogenesis in different dipteran groups and put them into a phylognetic context. We suggest that the migratory activity of the FCs represents an evolutionary novelty that evolved in the ancestors of higher dipterans (Brachycera). Subsequently, during evolution of this subgroup, the number of migrating FC subpopulations has gradually increased from one (in Orthorrhapha) to four (in Cyclorrhapha).

Nuage morphogenesis becomes more complex: two translocation pathways and two forms of nuage coexist in Drosophila germline syncytia

We have developed a simple and reliable method of preserving antigen immunoreactivity with concomitant excellent retention of the cell ultrastructure. Using this method, we have been able to follow the origin and developmental stages of nuage accumulations within the nurse cell/oocyte syncytium in the ovary of the fruit fly, Drosophila melanogaster, at the ultrastructural level. We have found two morphologically and biochemically distinct forms of nuage material in the nurse cell cytoplasm: translocating accumulations of nuage containing the Vasa protein, termed sponge bodies and stationary polymorphic accumulations of nuage enriched in Argonaute and Survival of motor neuron proteins. Immunogold labeling combined with confocal fluorescent and ultrastructural analyses have revealed that the Vasa-containing nuage accumulations remain closely associated with the cisternae of the endoplasmic reticulum throughout their lifetimes. The migration mechanism of the Vasa-positive nuage appears distinct from the microtubule-dependent translocation of oskar ribonucleoprotein complexes. We postulate that these two distinct nuage translocation pathways converge in the formation of the polar granules within the polar/germ plasm of the oocyte posterior pole. We also provide morphological and immunocytochemical evidence that these polymorphic nuage accumulations correspond to the recently described cytoplasmic domains termed U body-P body complexes.

Electron microscopy, immunostaining, cytoskeleton visualization, in situ hybridization, and three-dimensional reconstruction of Xenopus oocytes

Although the overwhelming development of molecular techniques in recent decades has made ultrastructural studies less popular, to the point that ultrastructural interpretation is becoming a dying art, it still remains an indispensable tool for cell and developmental biologists. The introduction of EM-immunocytochemistry and three-dimensional visualization methods allows us to complement the knowledge gained from ultrastructural and molecular approaches. Because the first clues about the functions of newly discovered genes often come from the subcellular localization patterns of their proteins or RNAs, in this chapter we describe the methods that allow for precise ultrastructural localization and visualization of protein and RNA molecules within the compartments, organelles, and cytoskeleton of Xenopus oocytes.

Peculiarities of the organization of egg chambers in carabid ground beetles and their phylogenetic implications

The ovaries of 31 species of the coleopteran familyCarabidae have been studied by light and electron microscopy. Ovarioles of all the examined insects are of the polytrophic type. In the majority of the species a constant number of nurse cells per egg chamber has been observed. However, several species do not obey the 2(n) rule and the number of nurse cells varies considerably even in the consecutive egg chambers of the same ovariole. In spite of the differences, the number of intercellular bridges connecting nurse cells to the oocyte is fixed and species specific. InCarabidae seven types of egg chambers have been characterized regarding the number of divisions, the number of nurse cells and the way the nurse cells are bridged to the oocyte. Some phylogenetic implications are considered.

Ovary structure and early oogenesis in the remipede, Godzilliognomus frondosus (Crustacea, Remipedia): phylogenetic implications.

Remipedia are enigmatic crustaceans of uncertain phylogenetic position with the general consensus that they are crucial for understanding the crustacean/arthropod evolution. It has been demonstrated previously that the features of the ovary organization and subcellular aspects of oogenesis are useful in resolving phylogenetic relationships in arthropods such as hexapods and onychophorans. The structure of the female gonads in Remipedia remains largely unknown; therefore, we examined the gross morphology and ultrastructural details of the ovary in a remipede, Godzilliognomus frondosus, with special emphasis on characters relevant to phylogenetic reconstructions. The ovaries of G. frondosus are located in the anterior part of the body and are composed of a single anterior proliferative zone (the germarium) and paired ovarian tubes (the vitellarium). The oocytes undergo subsequent stages of development within the lumen of the ovarian tubes, hence the remipede ovaries can be classified as endogenous. During oogenesis, each oocyte is enveloped by a set of characteristic somatic follicular cells, which results in the formation of distinct ovarian follicles. Here, we demonstrate that Remipedia share significant similarities in the ovary organization with Cephalocarida, including the anterior location of the ovary, the anterior-most position of the germarium and the endogenous type of oocyte development. Phylogenetic implications of our findings are discussed.

Association of TCTP with Centrosome and Microtubules

Translationally Controlled Tumour Protein (TCTP) associates with microtubules (MT), however, the details of this association are unknown. Here we analyze the relationship of TCTP with MTs and centrosomes in Xenopus laevis and mammalian cells using immunofluorescence, tagged TCTP expression and immunoelectron microscopy. We show that TCTP associates both with MTs and centrosomes at spindle poles when detected by species-specific antibodies and by Myc-XlTCTP expression in Xenopus and mammalian cells. However, when the antibodies against XlTCTP were used in mammalian cells, TCTP was detected exclusively in the centrosomes. These results suggest that a distinct pool of TCTP may be specific for, and associate with, the centrosomes. Double labelling for TCTP and γ-tubulin with immuno-gold electron microscopy in Xenopus laevis oogonia shows localization of TCTP at the periphery of the γ-tubulin-containing pericentriolar material (PCM) enveloping the centriole. TCTP localizes in the close vicinity of, but not directly on the MTs in Xenopus ovary suggesting that this association requires unidentified linker proteins. Thus, we show for the first time: (1) the association of TCTP with centrosomes, (2) peripheral localization of TCTP in relation to the centriole and the γ-tubulin-containing PCM within the centrosome, and (3) the indirect association of TCTP with MTs.

Accessory nuclei in insect oogenesis: in search of the function of enigmatic organelles.

This review compiles present knowledge of the structure and molecular composition of the enigmatic cytoplasmic organelles called accessory nuclei. Most typically, they are found in the perinuclear cytoplasm in oocytes of insects and several other invertebrates. Accessory nuclei originate by budding of the oocyte nucleus (germinal vesicle) and are surrounded by an envelope identical to the nuclear envelope. They contain one or several dense inclusions called pseudonucleoli immersed in a translucent ground substance or matrix. Comparative analysis of the morphology, molecular composition and the ultimate fate of accessory nuclei and their inclusions revealed that there are two basic types of these organelles in insect oocytes. In mallophagans, accessory nuclei are associated with the oocyte nucleus throughout entire oogenesis and at least some of them are connected to the germinal vesicle by slender stems. Each accessory nucleus contains a single, dense, RNA-positive inclusion which is likely to correspond to a nucleolus. In hymenopterans, accessory nuclei initially surround the germinal vesicle but during oogenesis they separate from it and migrate toward the peripheral ooplasm. Within the accessory nucleus matrix usually two distinct inclusions develop. One of these is perfectly spherical, contains coilin and small nuclear ribonucleoproteins and is homologous to the Cajal body. In the light of recent discoveries, we discuss the role accessory nuclei play in insect oogenesis and early embryogenesis.

A novel pattern of follicular epithelium morphogenesis in higher dipterans.

In fly ovaries, the follicular epithelium surrounding germline cells diversifies into several morphologically distinct cell subpopulations. This complex process is crucial for the formation of a regionally complex eggshell and establishment of polarity of the future embryo. Morphogenetic changes accompanying patterning of the follicular epithelium have been best characterized in the model fly, Drosophila melanogaster. Here, we analyze follicular epithelium diversification in the ovaries of Tachypeza nubila, a brachyceran fly closely related to the group Cyclorrhapha, which also includes Drosophila. We provide morphological evidence that in Tachypeza, the diversification process differs from that described in the Drosophila model system in several important respects: (i) follicle cells differentiate into five subpopulations (versus eight in Drosophila); (ii) only one of these subpopulations (i.e. border cells) is migratory (versus four in Drosophila); (iii) the main body follicle cells form a uniform epithelium with no distinct border between follicle cells covering the nurse cell compartment and the oocyte; (iv) chorionic material is deposited not only on the surface of the oocyte but also on the nurse cells; (v) there is no centripetal migration of the follicle cells; (vi) the resulting eggshell is morphologically simple with no regional specializations except for the micropylar apparatus at the anterior pole of the oocyte. Our findings provide novel insights into the evolution of the follicle cell patterning and functioning in dipterans. A critical analysis of these processes in different dipteran groups strongly indicates that in Tachypeza, follicular epithelium diversification follows a distinct pattern, novel for higher dipterans.