Basic aspects of ovarian development in <Emphasis Type="Italic">Drosophila melanogaster</Emphasis>

Modern views of the development and structural organization of the female reproductive system in Drosophila melanogaster are reviewed. Special emphasis is placed on the generation and development of follicles in the germarium and the interactions of germline and somatic cells in the egg chamber. Detailed consideration is given to the main events that ensure and regulate the transport of mRNA, proteins, and organelles from nurse cells to the oocyte in the germarium and at later stages of egg chamber development.     

Morphological Oogenesis in the out1 Mutant of Drosophila melanogaster Meigen (Diptera: Drosophilidae)

ABSTRACT The sex-linked, recessive otu¹ mutant of Drosophila melanogaster was studied cytologically to reveal the effect of the otu gene mutation on oogenesis. Consequently, the germarium of the otu¹ mutant was found to be larger as compared to the normal fertile one and contains many undifferentiated tumor cells resembling cystocytes. Each ovary consists of three types of ovarioles; ovarioles with only a germarium, ovarioles with a germarium and one tumor chamber, and ovarioles with a germarium and two tumor chambers. In the otu¹ germarium, the mesodermal follicle cells invade the clusters of different number of tumor cells at the posterior region of the germarium in order to make the tumor chamber and the dividing frequency of the tumor cells in the first tumor chamber was six times more than in the second tumor chamber. Follicle cells surrounding the tumor chamber are morphologically normal, but the number of the follicle cells becomes less as the tumor chambers move down contrary to the fertile one. The otu¹ mutant female never lays the egg and the formation of the vitelline membrane is incomplete. The otu¹ mutant tumor cells also showed characteristics of certain rapidly dividing cells and its nucleus is lobulated.     

Development of ovarioles and nurse-cell cytoskeleton in <Emphasis Type="Italic">Calliphora erythrocephala</Emphasis> Mg (Diptera: Calliphoridae)

We have examined ovariole morphology and their development in Calliphora erythrocephala Mg. (Diptera: Calliphoridae). It has been shown that several regions can be distinguished in C. erythrocephala germarium. In these regions, cyst morphogenesis subsequently continues until the separation of the formed egg chamber. The germarium has variously branching fusomes. Two egg chambers develop in the C. erythrocephala vitellarium. The distribution of actin filaments and the formation of ring canals was studied in C. erythrocephala nurse cells. The diameter of the ring canal increases in the germarium zone from 1.5 μm to 14.7 μm during the third and fourth studies of oogenesis. A scheme is presented that illustrates the irregular stretching of actin rollers, which are formed during middle and late oogenesis around ring canals, which joins the proximal and neighboring parts and dramatically increases the size of nurse cells.     

The origin and early differentiation of the egg chamber of Drosophila melanogaster

The egg chamber of Drosophila melanogaster consists of 16 interconnected cells surrounded by a monolayer of follicle cells. Each 16 cell cluster (from which the oocyte and 15 nurse cells differentiate) arises within the germarial region of an ovariole. To study the ultrastructure of the early stages in the formation and differentiation of egg chambers, a three dimensional reconstruction was made from serial thin sections through a germarium from a 24-hour old, virgin female. The germarium was found to be subdivided into three regions: (1) The mitotically active area where clusters of 16 cells originate from a series of cystocyte divisions, (2) the region where these cells interact with mesodermal cells, and (3) the region where the germarial cyst is transformed into the first egg chamber in the vitellarium. Since cystocytes were found to decrease in size with each division, the possibility exists that cell size may determine when the divisions cease. Models are presented which mimic with varying degrees of success the developmental changes the germarial cells undergo with time. Hypothesis are developed to explain why stem line oogonia are restricted to the anterior portion of the germarium, why mesodermal cells first interact with cystocytes in region 2, and why the oocyte is oriented posteriorly. The nuclear differentiations of the component cells of the chamber are described and correlated with observed differences in radiosensitivity. Symbionts were observed in the germaria of several strains of Drosophila, and the bearing of these findings upon nutritional studies is discussed.     

5-氟尿嘧啶对家蝇卵巢的影响及其诱变效应

5—氟尿嘧啶(5-FU)是家蝇的有效不育性药剂.采用饲食法用浓度0.5%处理家蝇成虫一天,能造成家蝇90%以上不育,连续处理4—5天,即可造成完全不育.但处理雄蝇×正常雌蝇表现无效.其次,处理后的卵巢形态及细胞学变化显示:处理后的卵巢第一天比对照体积有增加,以后则发育迟缓、卵巢的外形和颜色也有改变.处理后的卵原区首先发生破坏,第一卵室的变化最明显,第二、第三卵室畸形或不发育.滤泡细胞和营养细胞改变很大,卵母细胞相对地改变较小.处理家蝇的后代表现出突变和畸形现象.讨论了5—FU的作用机制.由药效测定和细胞病理改变提出了5—FU造成家蝇不育的可能作用方式.     

Fused-dependent Hedgehog signal transduction is required for somatic cell differentiation during Drosophila egg chamber formation

The fused gene encodes a serine/threonine kinase involved in Hedgehog signal transduction during Drosophila embryo and larval imaginal disc development. Additionally, fused mutant females exhibit reduced fecundity that we report here to be associated with defects in three aspects of egg chamber formation: encapsulation of germline cysts by prefollicular cells in the germarium, interfollicular stalk morphogenesis and oocyte posterior positioning. Using clonal analysis we show that fused is required cell autonomously in prefollicular and pre-stalk cells to control their participation in these aspects of egg chamber formation. In contrast to what has been found for Hedgehog and other known components of Hedgehog signal transduction, we show that fused does not play a role in the regulation of somatic stem cell proliferation. However, genetic interaction studies, as well as the analysis of the effects of a partial reduction in Hedgehog signaling in the ovary, indicate that fused acts in the classical genetic pathway for Hedgehog signal transduction which is necessary for somatic cell differentiation during egg chamber formation. Therefore, we propose a model in which Hedgehog signals at least twice in germarial somatic cells: first, through a fused-independent pathway to control somatic stem cell proliferation; and second, through a classical fused-dependent pathway to regulate prefollicular cell differentiation.     

Stage-specific localization of the small heat shock protein Hsp27 during oogenesis inDrosophila melanogaster

The developmental and heat shock-induced expression of the small heat shock protein Hsp27 was investigated by confocal microscopy of whole-mount immunostained preparations of ovarioles during oogenesis inDrosophila melanogaster. In unstressed flies, Hsp27 was mainly associated with germline nurse cells throughout egg development. A small group of somatic follicle cells also expressed Hsp27 specifically at stages 8 to 10 of oogenesis. Interestingly, this Hsp showed a different intracellular localization depending on the stages of egg chamber development. Thus Hsp27 was localized in the nucleus of nurse cells during the first stages of oogenesis (from germarium to stage 6) whereas it showed a perinuclear and cytoplasmic localization from stage 8. After a heat shock, Hsp27 accumulated in somatic follicle cells surrounding the egg chamber whereas the expression of this small Hsp did not seem to be enhanced in nurse cells. The stage-dependent pattern of intracellular localization of Hsp27 observed in nurse cells of unstressed flies was also observed following heat shock. At late stages of oogenesis, Hsp27 also showed a perinuclear distribution in follicle and nurse cells after heat stress. These observations suggest that different factors may modulate the expression and intracellular distribution of Hsp27. This modulation may be associated with the specific activities occurring in each particular cell type throughout oogenesis during both normal development and under heat shock conditions. Edited by: E.R. Schmidt     

A role for extra macrochaetae downstream of Notch in follicle cell differentiation

The Drosophila ovary provides a model system for studying the mechanisms that regulate the differentiation of somatic stem cells into specific cell types. Ovarian somatic stem cells produce follicle cells, which undergo a binary choice during early differentiation. They can become either epithelial cells that surround the germline to form an egg chamber ('main body cells') or a specialized cell lineage found at the poles of egg chambers. This lineage goes on to make two cell types: polar cells and stalk cells. To better understand how this choice is made, we carried out a screen for genes that affect follicle cell fate specification or differentiation. We identified extra macrochaetae (emc), which encodes a helix-loop-helix protein, as a downstream effector of Notch signaling in the ovary. EMC is expressed in proliferating cells in the germarium, as well as in the main body follicle cells. EMC expression in the main body cells is Notch dependent, and emc mutant cells located on the main body failed to differentiate. EMC expression is reduced in the precursors of the polar and stalk cells, and overexpression of EMC caused dramatic egg chamber fusions, indicating that EMC is a negative regulator of polar and/or stalk cells. EMC and Notch were both required in the main body cells for expression of Eyes Absent (EYA), a negative regulator of polar and stalk cell fate. We propose that EMC functions downstream of Notch and upstream of EYA to regulate main body cell fate specification and differentiation.     

An EM autoradiographic study on ovarian follicle cells of Drosophila melanogaster with special reference to the formation of egg coverings.

Ovarian follicle cells of Drosophila melanogaster have been studied by ultrastructural and autoradiographic analyses. During their migration through the germarium, follicle cells undergo several structural changes and, of these, the most conspicuous one occurs at the level of the nucleolus. By the time the first ovarian chamber is formed, follicle cells have formed a layer of uniform thickness all around a cluster or nurse cells and the oocyte. Following the initiation of vitellogenesis, the follicle cells overlaying the oocyte become columnar while those over the nurse cells become very thin. During stages 9-10, the columnar follicle cells are involved in the formation of the vitelline membrane, while from stages 11 to 13 these cells produce the endochorion. An EM autoradiographic analysis has shown that the rate of 3H-uridine incorporation in follicle cells nuclei is low in previtellogenic chambers, while it becomes very high in nuclei of stage 9-10 chambers. After short exposure to uridine, silver grains are located predominantly over nucleoli. Evidence from incorporation studies with 3H-lysine indicates that the columnar follicle cells and the region of the various egg coverings are highly labelled within an hour of incubation in the tracer. The observations confirm that columnar follicle cells are the only cells in the chamber involved in the formation of materials which make up the egg coverings.     

Eyes absent,a key repressor of polar cell fate during Drosophila oogenesis

Throughout Drosophila oogenesis, specialized somatic follicle cells perform crucial functions in egg chamber formation and in signaling between somatic and germline cells. In the ovary, at least three types of somatic follicle cells, polar cells, stalk cells and main body epithelial follicle cells, can be distinguished when egg chambers bud from the germarium. Although specification of these three somatic cell types is important for normal oogenesis and subsequent embryogenesis, the molecular basis for establishment of their cell fates is not completely understood. Our studies reveal the gene eyes absent (eya) to be a key repressor of polar cell fate. EYA is a nuclear protein that is normally excluded from polar and stalk cells, and the absence of EYA is sufficient to cause epithelial follicle cells to develop as polar cells. Furthermore, ectopic expression of EYA is capable of suppressing normal polar cell fate and compromising the normal functions of polar cells, such as promotion of border cell migration. Finally, we show that ectopic Hedgehog signaling, which is known to cause ectopic polar cell formation, does so by repressing eya expression in epithelial follicle cells.     

Cyst geometry in the egg chambers of Calliphora erythrocephala Mg. (Diptera: Calliphoridae) ovaries

In the germarium of polytrophic ovarioles of Calliphora erythrocephala (Mg.) fly, four mitotic divisions of cystoblasts give rise to 16-cell germ-line cysts. One cell differentiates into an oocyte, while the remaining 15 cells become nurse cells. Concomitantly actin-rich ring canals are formed at the intercellular junctions. The present study considers a mutual arrangement of the ring canals formed after the second to fourth mitoses relative to the ring canal formed after the first mitotic division in different regions of the germarium and egg chambers. During the cyst formation and its movement to the posterior end of the germarium, the ring canals are displaced relative to one another, thereby giving different branching variants of the cyst. The pattern of cell interconnections becomes stable in germarium region 2b and does not change during the cyst movement along the ovariole despite the cyst polarizes and increases in size.     

The virulent <Emphasis Type="Italic">Wolbachia</Emphasis> strain wMelPop increases the frequency of apoptosis in the female germline cells of <Emphasis Type="Italic">Drosophila melanogaster</Emphasis>

BACKGROUND: Wolbachia are bacterial endosymbionts of many arthropod species in which they manipulate reproductive functions. The distribution of these bacteria in the Drosophila ovarian cells at different stages of oogenesis has been amply described. The pathways along which Wolbachia influences Drosophila oogenesis have been, so far, little studied. It is known that Wolbachia are abundant in the somatic stem cell niche of the Drosophila germarium. A checkpoint, where programmed cell death, or apoptosis, can occur, is located in region 2a/2b of the germarium, which comprises niche cells. Here we address the question whether or not the presence of Wolbachia in germarium cells can affect the frequency of cyst apoptosis in the checkpoint. RESULTS: Our current fluorescent microscopic observations showed that the wMel and wMelPop strains had different effects on female germline cells of D. melanogaster. The Wolbachia strain wMel did not affect the frequency of apoptosis in cells of the germarium. The presence of the Wolbachia strain wMelPop in the D. melanogasterw1118 ovaries increased the number of germaria where cells underwent apoptosis in the checkpoint. Based on the appearance in the electron microscope, there was no difference in morphological features of apoptotic cystocytes between Wolbachia-infected and uninfected flies. Bacteria with normal ultrastructure and large numbers of degenerating bacteria were found in the dying cyst cells. CONCLUSIONS: Our current study demonstrated that the Wolbachia strain wMelPop affects the egg chamber formation in the D. melanogaster ovaries. This led to an increase in the number of germaria containing apoptotic cells. It is suggested that Wolbachia can adversely interfere either with the cystocyte differentiation into the oocyte or with the division of somatic stem cells giving rise to follicle cells and, as a consequence, to improper ratio of germline cells to follicle cells and, ultimately, to apoptosis of cysts. There was no similar adverse effect in D. melanogaster Canton S infected with the Wolbachia strain wMel. This was taken to mean that the observed increase in frequency of apoptosis was not the general effect of Wolbachia on germline cells of D. melanogaster, it was rather induced by the virulent Wolbachia strain wMelPop.     

Ultrastructural features of egg development in oviparae of the vetch aphid, Megoura viciae buckton

In the ovaries of the oviparous morph of the aphid, Megoura viciae, resting oocytes are located in the basal region of each germarium. During previtellogenic egg development, electron-dense spheres appear in the ooplasm. During vitellogenesis a brush border develops at the oolemma, and numerous protein and lipid-like spheres accumulate in the egg cytoplasm. Follicle cells are of two morphologically distinct types, termed 'type 1' and 'type 2' follicle cells. Unlike the more numerous 'type 1' cell, 'type 2' cells do not become patent. The acellular tunica propria exterior to follicle cell apices remains intact throughout egg development. During late vitellogenesis symbiont invasion of eggs takes place via 'receptor' cells encircling the pedicel at the posterior egg pole. These cells shrink and/or degenerate to create intercellular spaces that facilitate symbiont transmission. The end of vitellogenesis is marked by vitelline membrane formation and secretion of the chorionic layers, at which time the next egg in the ovariole undergoes final stages of previtellogenic growth and enters vitellogenesis.     

Drosophila follicle cells are patterned by multiple levels of Notch signaling and antagonism between the Notch and JAK/STAT pathways

The specification of polar, main-body and stalk follicle cells in the germarium of the Drosophila ovary plays a key role in the formation of the egg chamber and polarisation of its anterior-posterior axis. High levels of Notch pathway activation, resulting from a germline Delta ligand signal, induce polar cells. Here we show that low Notch activation levels, originating from Delta expressed in the polar follicle cells, are required for stalk formation. The metalloprotease Kuzbanian-like, which cleaves and inactivates Delta, reduces the level of Delta signaling between follicle cells, thereby limiting the size of the stalk. We find that Notch activation is required in a continuous fashion to maintain the polar and stalk cell fates. We further demonstrate that mutual antagonism between the Notch and JAK/STAT signaling pathways provides a crucial facet of follicle cell patterning. Notch signaling in polar and main-body follicle cells inhibits JAK/STAT signaling by preventing STAT nuclear translocation, thereby restricting the influence of this pathway to stalk cells. Conversely, signaling by JAK/STAT reduces Notch signaling in the stalk. Thus, variations in the levels of Notch pathway activation, coupled with a continuous balance between the Notch and JAK/STAT pathways, specify the identity of the different follicle cell types and help establish the polarity of the egg chamber.     

The rôle of juvenile hormone in housefly ovarian follicle morphogenesis

Oögenesis in the housefly, Musca domestica, was divided into a series of 10 stages where stage 1 was the germarium, stage 4 was the beginning of yolk deposition, stage 7 was characterized by maximal nurse cell development, stage 9 by the degeneration of the nurse cells and chorion formation, and stage 10 was the mature egg. It required 69 hr from eclosion at 27°C to develop mature eggs. This represented an oöcyte volume increase of 3700-fold, a seventeenfold increase in follicle length, and a sevenfold increase in weight. The application of 2 μg of isopropyl (E,E)-11-methoxy-3,7,11-trimethyldodeca-2,4-dienoate (ZR-515) to allatectomized (-CA) flies stimulated egg development, which progressed at the same rate as the controls. The -CA flies did not develop eggs past stage 4, which represented a cessation of development at a volume of 1·4 per cent that of a mature egg and an ovarian dry weight of 11 per cent that of a mature ovary. The follicle cells from -CA flies did not differentiate into the squamous condition over the nurse chamber, did not become columnar over the oöcyte, did not produce the chorion or vitelline membrane, and did not decrease in number as they did on the stage 10 follicles. Endomitosis in the nurse cell nuclei of -CA flies stopped development at 290 c, but maximum development of 2400 c occurred in stage 7 follicles from controls, and then the nurse cells began to disintegrate.     

ELECTRON MICROSCOPIC STUDIES ON THE OOGENESIS OF DRAGONFLY AND CRICKET WITH SPECIAL REFERENCE TO THE PANOISTIC OVARIES

The successive ultrastructural changes during oogenesis in Sympetrum frequens (Odonata, Libellulidae) and Gryllus yemma (Orthoptera, Gryllidae) were studied.
The structures of the terminal filament and boundary between the terminal filament and the germarium differed from each other in these 2 species; in Sympetrum the boundary between the terminal filament and the germarium was a special acellular transverse septum, whereas that in Gryllus was composed of several flattened cells which seemed to be similar to the prefollicular cells in the germarium.
During the previtellogenesis, the nucleolar extrusions and emissions of the outer nuclear envelope were observed frequently in young oocytes. In Sympetrum , electron dense masses were observed in the oocyte cytoplasm, which seemed to be "yolk nuclei" or "Balbiani bodies" and were composed of aggregated small particles (about 200 A in diameter). They were gradually dispersed in the cytoplasm until the onset of vitellogenesis.
In both Sympetrum and Gryllus , yolk precursors seemed to be incorporated into oocytes by micropinocytosis as observed in various animals.
The egg membranes, viz. , the vitelline membrane and the chorion, seemed to be formed by products from follicle cells which developed rough-surfaced endoplasmic reticulum and Golgi bodies. Thus, both of these egg membranes were assumed to be the secondary egg membranes.     

The receptor-like tyrosine phosphatase lar is required for epithelial planar polarity and for axis determination within drosophila ovarian follicles.

The follicle cell monolayer that encircles each developing Drosophila oocyte contributes actively to egg development and patterning, and also represents a model stem cell-derived epithelium. We have identified mutations in the receptor-like transmembrane tyrosine phosphatase Lar that disorganize follicle formation, block egg chamber elongation and disrupt Oskar localization, which is an indicator of oocyte anterior-posterior polarity. Alterations in actin filament organization correlate with these defects. Actin filaments in the basal follicle cell domain normally become polarized during stage 6 around the anterior-posterior axis defined by the polar cells, but mutations in Lar frequently disrupt polar cell differentiation and actin polarization. Lar function is only needed in somatic cells, and (for Oskar localization) its action is autonomous to posterior follicle cells. Polarity signals may be laid down by these cells within the extracellular matrix (ECM), possibly in the distribution of the candidate Lar ligand Laminin A, and read out at the time Oskar is localized in a Lar-dependent manner. Lar is not required autonomously to polarize somatic cell actin during stages 6. We show that Lar acts somatically early in oogenesis, during follicle formation, and postulate that it functions in germarium intercyst cells that are required for polar cell specification and differentiation. Our studies suggest that positional information can be stored transiently in the ECM. A major function of Lar may be to transduce such signals.     

Ultrastructure of the female gonad of two temnocephalids (Platyhelminthes,Rhabdocoela)

The female gonad of Temnocephala dendyi and T. minor consists of a single germarium and two rows of vitellaria. It is enveloped by an extracellular lamina and accessory cells. Accessory cells are only peripherally located in the germarium while their cytoplasmic projections also fill the spaces between vitellocytes in the vitellarium. The main feature of oocyte maturation is the appearance of chromatoid bodies and the development of rough endoplasmic reticulum (R.E.R.) and Golgi complexes which appear to be correlated with the production of double-structured egg granules. The egg granules, which are localized in the cortical cytoplasm of mature oocytes, contain glycoproteins, are devoid of polyphenols and are similar in structure and composition to the cortical granules observed in some Digenea and Monogenea. Vitellocytes are typical secretory cells with well-developed R.E.R. and Golgi complexes which are involved in the production of shell globules and yolk. The multigranular pattern and the polyphenolic composition of the shell globules of the temnocephalids investigated are similar to those observed in other rhabdocoels, and in some Prolecithophora and Neodermata. This feature may represent a synapomorphy shared by these taxa. This revised version was published online in July 2006 with corrections to the Cover Date.     

F-actin distribution in the ovaries of pre-vitellogenic and vitellogenic black blowflies,Phormia regina (Meigen) (Diptera : Calliphoridae)

The spatial distribution of F-actin microfilaments in the ovaries of previtellogenic and vitellogenic female black blowflies, Phormia regina (Diptera : Calliphoridae), as the females shift from a sugar to a liver diet, is determined using rhodamine-labelled phalloidin (rh-phalloidin). During the pre-vitellogenic stages of ovarian development (i.e. corresponding to a sugar diet) a single bright fluorescent layer marks the interface between follicle cells and the oocyte. Fluorescence is also most evident at the inner surface of the ring canals of the nurse cells. This is observed in the nurse cells both in the distal part of the germarium, and in the vitellogenic growing oocyte. However, when liver-fed (i.e. necessary for vitellogenesis), 2 bright fluorescent layers are observed at the follicle cell-oocyte interface. In addition, the cytoplasm of the nurse cells during vitellogenesis appears full of fluorescent microfilaments and the actin rings are found to increase in size and thickness. The changing organization of the F-actin microfilaments in the follicles during the process of both egg chamber and oocyte formation is discussed and possible functions considered.     

The abnormal spindle protein is required for germ cell mitosis and oocyte differentiation during Drosophila oogenesis

In this study, we present evidence that the asp function is required in oogenesis for germline cell divisions as well as for cyst polarity and oocyte differentiation. Consistent with previously described roles in spindle organization during Drosophila meiosis and mitosis, asp mutation leads to severe defects in spindle microtubule organization within the germarium. The mitotic spindles of the mutant cystocytes are composed by wavy microtubules and have abnormal poles that often lack gamma-tubulin. The fusome structure is also compromised. In the absence of asp function, the cystocyte divisions fail resulting in egg chamber with fewer than 16 germ cells. Moreover, the microtubule network within the developing germline cysts may assemble incorrectly in turn affecting the microtubule based transport of the specific determinants that is required during mid-oogenesis for the oocyte differentiation program.