missing oocyte encodes a highly conserved nuclear protein required for the maintenance of the meiotic cycle and oocyte identity in Drosophila

In Drosophila, a single oocyte develops within a 16-cell germline cyst. Although all 16 cells initiate meiosis and undergo premeiotic S phase, only the oocyte retains its meiotic chromosome configuration and remains in the meiotic cycle. The other 15 cells in the cyst enter the endocycle and develop as polyploid nurse cells. A longstanding goal in the field has been to identify factors that are concentrated or activated in the oocyte, that promote meiotic progression and/or the establishment of the oocyte identity. We present the characterization of the missing oocyte gene, an excellent candidate for a gene directly involved in the differentiation of the oocyte nucleus. The missing oocyte gene encodes a highly conserved protein that preferentially accumulates in pro-oocyte nuclei in early prophase of meiosis I. In missing oocyte mutants, the oocyte enters the endocycle and develops as a polyploid nurse cell. Genetic interaction studies indicate that missing oocyte influences meiotic progression prior to pachytene and may interact with pathways that control DNA metabolism. Our data strongly suggest that the product of the missing oocyte gene acts in the oocyte nucleus to facilitate the execution of the unique cell cycle and developmental programs that produce the mature haploid gamete.     

The cytoskeleton organizes germ nuclei with divergent fates and asynchronous cycles in a common cytoplasm during oogenesis in the chordate Oikopleura

Germline cysts are conserved structures in which cells initiating meiosis are interconnected by ring canals. In many species, the cyst phase is of limited duration, but the chordate, Oikopleura, maintains it throughout prophase I as a unique cell, the coenocyst. We show that despite sharing one common cytoplasm with meiotic and nurse nuclei evenly distributed in a 1:1 ratio, both entry into meiosis and subsequent endocycles of nurse nuclei were asynchronous. Coenocyst cytoskeletal elements played central roles as oogenesis progressed from a syncytial state of indistinguishable germ nuclei, to a final arrangement where the common cytoplasm had been equally partitioned into resolved, mature oocytes. During chromosomal bouquet formation in zygotene, nuclear pore complexes clustered and anchored meiotic nuclei to the coenocyst F-actin network opposite ring canals, polarizing oocytes early in prophase I. F-actin synthesis was required for oocyte growth but movement of cytoplasmic organelles into oocytes did not require cargo transport along colchicine-sensitive microtubules. Instead, microtubules maintained nurse nuclei on the F-actin scaffold and prevented their entry into growing oocytes. Finally, it was possible to both decouple meiotic progression from cellular mechanisms governing oocyte growth, and to advance the timing of oocyte growth in response to external cues.     

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.     

Elimination of nurse cell nuclei that shuttle into oocytes during oogenesis

Drosophila oocytes develop together with 15 sister germline nurse cells (NCs), which pass products to the oocyte through intercellular bridges. The NCs are completely eliminated during stages 12–14, but we discovered that at stage 10B, two specific NCs fuse with the oocyte and extrude their nuclei through a channel that opens in the anterior face of the oocyte. These nuclei extinguish in the ooplasm, leaving 2 enucleated and 13 nucleated NCs. At stage 11, the cell boundaries of the oocyte are mostly restored. Oocytes in egg chambers that fail to eliminate NC nuclei at stage 10B develop with abnormal morphology. These findings show that stage 10B NCs are distinguished by position and identity, and that NC elimination proceeds in two stages: first at stage 10B and later at stages 12–14.     

Tracking nucleolar dynamics with GFP-Nopp140 during Drosophila oogenesis and embryogenesis

We expressed two green fluorescent protein (GFP)-tagged Nopp140 isoforms in transgenic Drosophila melanogaster to study nucleolar dynamics during oogenesis and early embryogenesis. Specifically, we wanted to test whether the quiescent oocyte nucleus stored maternal Nopp140 and then to determine precisely when nucleoli formed during embryogenesis. During oogenesis nurse cell nucleoli accumulated GFP-Nopp140 gradually such that posterior nurse cell nucleoli in egg chambers at stage 10 were usually brighter than the more anterior nurse cell nucleoli. Nucleoli within apoptotic nurse cells disassembled in stages 12 and 13, but not all GFP-Nopp140 entered the oocyte through inter-connecting cytoplasmic bridges. Oocytes, on the other hand, lost their nucleoli by stage 3, but GFP-Nopp140 gradually accumulated in oocyte nuclei during stages 8–13. Most oocyte nuclei at stage 10 stored GFP-Nopp140 uniformly, but many stage 10 oocytes accumulated GFP-Nopp140 in presumed endobodies or in multiple smaller spheres. All oocyte nuclei at stages 11-12 were uniformly labeled, and GFP-Nopp140 diffused to the cytoplasm upon nuclear disassembly in stage 13. GFP-Nopp140 reappeared during embryogenesis; initial nucleologenesis occurred in peripheral somatic nuclei during embryonic stage 13, one stage earlier than reported previously. These GFP-Nopp140-containing foci disassembled at the 13th syncytial mitosis, and a second nucleologenesis occurred in early stage 14. The resulting nucleoli occupied nuclear regions closest to the periphery of the embryos. Pole cells contained GFP-Nopp140 during the syncytial embryonic stages, but their nucleologenesis started at gastrulation. This work was supported by the National Science Foundation (grant MCB-0234245). O'Keith Dellafosse was supported by the Louisiana Alliance for Minority Participation (LAMP).     

The KASH domain protein MSP-300 plays an essential role in nuclear anchoring during Drosophila oogenesis

During late stages of Drosophila oogenesis, the cytoplasm of nurse cells in the egg chamber is rapidly transferred ("dumped") to oocytes, while the nurse cell nuclei are anchored by a mechanism that involves the actin cytoskeleton. The factors that mediate this interaction between nuclei and actin cytoskeleton are unknown. MSP-300 is the likely Drosophila ortholog of the mammalian Syne-1 and -2 and C. elegans ANC-1 proteins, contained both actin-binding and nuclear envelope localization domains. By using an antibody against C-terminus of MSP-300, we find that MSP-300 is distributed throughout the cytoplasm and accumulates at the nuclear envelope of nurse cells and the oocyte. A GFP fusion protein containing the C-terminal region of MSP-300 is also sufficient to localize protein on the nuclear envelope in oocytes. To eliminate the maternal gene activity during oogenesis, we generated homozygous germ-line clones of a loss-of-function mutation in msp-300 in otherwise heterozygous mothers. In the mutant egg chambers that develop from such clones, cytoplasmic dumping of nurse cells is severely disturbed. The nuclei of nurse cells and the oocyte are mislocalized and the usually well-organized actin structures are severely disrupted. These results indicate that maternal MSP-300 plays an important role in actin-dependent nuclear anchorage during cytoplasmic transport.     

Observations on the polarity of mutant Drosophila follicles lacking the oocyte

Summary Homozygous females of the mutantsegalitarian andBicaudal-D ^R26produce follicles in which the oocyte is replaced by an additional nurse cell. Normal morphological markers for polarity can be identified in mutant follicles but the normal spatial organization of these markers is disturbed. For example, nurse-cell nuclei of different ploidy classes are present but, contrary to wild-type follicles, the nuclei show no anteroposterior ploidy gradient. The two cells with four intercellular bridges, one of which should have developed into the oocyte rather than a nurse cell, are located at the posterior pole only in young follicles (up to about stage 5), whereas during later stages they are more often found at lateral or intermediate positions. This disturbed polarity correlates with a variable aberrant pattern of extracellular ionic currents. Moreover, in the mutant follicles patches of columnar follicular epithelium differentiate locally although this type of epithelium forms normally only around the oocyte. The follicle cells at both follicle poles possess anterior quality since they migrate from both poles towards the centre of the follicle, as do the border cells restricted to the anterior pole in wild-type follicles. Our analysis indicates that in the mutants the follicular polarity is normal at first but becomes disturbed during stages 5 to 6. The secondary breakdown of polarity is likely to follow on from the absence of the oocyte.     

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.     

Stage-specific apoptotic patterns during Drosophila oogenesis

In the present study we demonstrate the existence of two apoptotic patterns in Drosophila nurse cells during oogenesis. One is developmentally regulated and normally occurs at stage 12 and the other is stage-specific and is sporadically observed at stages 7 and 8 of abnormally developed follicles. The apoptotic manifestation of the first pattern begins at stage 11 and is marked by a perinuclear rearrangement of the actin cytoskeleton and the development of extensive lobes and engulfments of the nurse cell nuclei located proximal to the oocyte. Consequently, at late stage 12 (12C), half of the nurse cell nuclei exhibit condensed chromatin, while at late stage 13 all the nuclei have fragmented DNA, as it is clearly shown by TUNEL assay. Finally, the apoptotic vesicles that are formed during stage 13, are phagocytosed by the neighboring follicle cells and at stage 14 the nurse cell nuclear remnants can be easily detected within the adjacent follicle cell phagosomes. In the second sporadic apoptotic pattern, all the nurse cell nuclei are highly condensed with fragmented DNA, accompanied by a completely disorganized actin cytoskeleton. When we induced apoptosis in Drosophila follicles through an etoposide and staurosporine in vitro treatment, we observed a similar pattern of stage-specific cell death at stages 7 and 8. These observations suggest a possible protective mechanism throughout Drosophila oogenesis that results in apoptosis of abnormal, damaged or spontaneously mutated follicles before they reach maturity.     

Two discrete modes of histone gene expression during oogenesis in Drosophila melanogaster

We have used in situ hybridization to ovarian tissue sections to study the pattern of histone gene expression during oogenesis in Drosophila melanogaster. Our studies suggest that there are two distinct phases of histone gene expression during oogenesis. In the first phase, which occurs during early to middle oogenesis (stages 5-10A), we observe a mosaic pattern of histone mRNA in the 15 nurse cells of the egg chamber: some cells have very high levels of mRNA, while others have little or no mRNA. Our analysis suggests that there is a cyclic accumulation and subsequent degradation of histone mRNA in the egg chamber and that very little histone mRNA is transported into the growing oocyte. Moreover, since the endomitotic replication cycles of the nurse cells are asynchronous during this period, the mosaic distribution of histone message would suggest that the expression of the histone genes in each nurse cell nucleus is probably coupled to DNA replication as in most somatic cells. The second phase begins at stage 10B. During this period, histone gene expression appears to be "induced" in all 15 nurse cells of the egg chamber, and instead of a mosaic pattern, high levels of histone mRNA are found in all cells. Unlike the earlier phase, this expression is apparently uncoupled from the endomitotic replication of the nurse cells (which are completed by the end of stage 10A). Moreover, much of the newly synthesized histone mRNA is transported from the nurse cells into the oocyte where it accumulates and is stored for use during early embryogenesis. Finally, we have also observed tightly clustered grains within nurse cell nuclei in non-denatured tissue sections. As was the case with cytoplasmic histone mRNA, there is a mosaic distribution of nuclear grains from stages 5 to 10A, while at stage 10B, virtually all nurse cell nuclei have grain clusters. These grain clusters appear to be due to the hybridization of nurse cell histone gene DNA to our probe, and are localized in specific regions of the nucleus.     

Multiple effects of colchicine on oogenesis in Drosophila: Induced sterility and switch of potential oocyte to nurse-cell developmental pathway

Adult female fruitflies exposed to colchicine admixed to the culture medium show a series of dosage-related abnormalities that affect oogenesis and may induce sterility. Among the effects observed were decreased fecundity and hatchability of laid eggs, formation of oocytes lacking chorionic appendages, abnormal distribution and diminution in number of yolk spheres, inhibition of oocyte growth and abnormally located oocyte nuclei. Potentially the most significant effect was the development of egg chambers which contained the normal complement of 16 cells but in which all the cells had the nuclear morphology of nurse cells. The approach provides for the first time an experimental means to divert a potential oocyte into the developmental pathway of the nurse cell in a wild-type fly, and hence should be helpful in the elucidation of factors which control oocyte and nurse cell differentiation. In addition, the results serve to expand the usefulness of oogenesis in Drosophila as a model system for the evaluation of drug-induced metabolic-morphologic abnormalities.     

Regulation of growth of nurse nuclei in the development of egg follicles inCecidomyiidae (Diptera)

InCecidomyiidae the number of trophocytes derived from the somatic tissue of the ovary and forming nutritive chambers of egg follicles is variable. The regulation of growth of the whole nutritive chambers and of the nurse nuclei was investigated in two species of the gall midges,Mikiola fagi andBoucheella artemisiae, at two different stages of the egg follicle development during the second period of the oocyte growth. The volume of a nutritive chamber is correlated with the size of the egg follicle as a whole and is not dependent on the number of nurse nuclei it contains. The total volume of nurse nuclei at each stage under investigation was found to have a constant value which is independent of their number. It was established that the growth of the nurse nuclei takes place through endomitosis, and that at a given stage of the egg follicle development the constant value of the total volume of the nurse nuclei reflects the constancy of degree of their total polyploidy. The results obtained indicate that at the early stages of the egg follicle development the rates of growth of the nurse nuclei and of the whole nutritive chambers in the egg follicles differing with respect to the number of their nurse nuclei must be different; the greater the number of nurse nuclei in a given nutritive chamber the slower the rate of growth of the chamber and their nuclei. As a result of this differential rate of growth the volumes of the nutritive chambers and total volumes of nurse nuclei reach at a certain stage of the egg follicle development certain values common for all egg follicles, irrespective of the number of the nurse nuclei they contain. Beginning with this stage the dependence between the endomitotic activity of the nurse nuclei and the rate of growth of the whole nutritive chamber on the one hand, and the number of the nurse nuclei in the chamber on the other, evidently disappears. The available evidence supports the hypothesis that in the egg follicle ofCecidomyiidae the growth regulation of nurse nuclei and, indirectly, also of whole nutritive chambers results from developmental interrelationships between the oocyte and the nutritive chamber, and that the oocyte plays a leading role in this process. In view of a syncytial character of the nutritive chambers inCecidomyiidae and distinctly expressed asynchrony of the growth-duplication cycles of nurse nuclei belonging to a given chamber it is concluded that the control mechanism for DNA synthesis and endomitosis in nurse nuclei must possess the property of a rapid switch. Processes of the growth regulation of the nurse nuclei are discussed in connection with the role of the nutritive chamber in production of RNA and its supply to the growing oocyte. It is suggested that in the egg follicles ofCecidomyiidae there exists a complex interrelationship between the control mechanism for DNA synthesis and endomitosis in the nurse nuclei and the synthetic processes regulated by the supply of the growing oocyte with RNA produced by the nuclei of the nutritive chamber.     

Apoptosis of nurse cells at the late stages of oogenesis of Drosophila melanogaster

 In Drosophila a remarkable feature of oogenesis is the regression of the nurse cells after dumping their cytoplasmic contents into the oocyte. We have studied the nature of this process at the late stages of egg chamber development. In egg chambers DAPI staining shows highly condensed chromatin from stage 12 and TUNEL labelling shows DNA fragmentation up to stage 14. Gel electrophoresis of the end-labelled DNA, extracted from isolated egg chambers at the same stages of development, shows a ladder typical of apoptotic nuclei. This provides evidence that, during Drosophila oogenesis, the nurse cells undergo apoptosis. Apoptotic nuclei have also been detected in dumping-defective egg chambers, indicating that the cytoplasmic depletion of nurse cells is concurrent with but apparently not the cause of the process. Received: 12 December 1997 / Accepted: 6 January 1998     

Ultrastructure and function of nurse cells in phthirapterans. Possible function of ramified nurse cell nuclei in the cytoplasm transfer

The structure of nurse cells as well as the distribution of cytoskeletal elements (actin filaments, microtubules) in three representatives of phthirapterans: the pig louse, Haematopinus suis (Anoplura) and bird lice, Eomenacanthus stramineus, Columbicola columbae (Mallophaga) were investigated. All three species have polytrophic-meroistic ovaries which means that each oocyte remains connected with a group of nurse cells via specialized cytoplasmic canals-intercellular bridges (ring canals). Throughout vitellogenesis, various macromolecules as well as organelles (mitochondria, endoplasmic reticulum vesicles, ribosomes) are transferred from the nurse cells to the oocyte. During this flow, the nurse cell nuclei do not enter the oocyte and are retained in the cell centers. In holometabolous insects (e.g. Drosophila, hymenopterans), the central position of nurse cell nuclei is maintained by cytoskeletal elements (actin filaments or microtubules). In the investigated species, the nurse cells are equipped with large, highly extended (irregularly lobed) nuclei. The inner nuclear membrane is lined with a relatively thick layer of nuclear lamina. Ultrastructural analysis and staining with rhodamine-labeled phalloidin revealed that the nurse cell cytoskeleton is poorly developed and represented only by: (1) single microtubules in the perinuclear cytoplasm; and (2) the F-actin layer in the cortical cytoplasm. In the light of this, we postulate that in phthirapterans the position of nurse cell nuclei during the cytoplasm transfer is maintained not by the cytoskeletal elements, but by a largely extended shape of the nuclei (i.e. their elongated extensions).     

Cell fusions during formation of the oocyte-nurse chamber complex in the ovary of the dipteran insectMycophila speyeri

Summary Formation of the oocyte-nurse chamber complex in the cecidomyid insectMycophila speyeri was studied in situ and in vitro by electron microscopy and time-lapse cinemicrography. At the end of the oogonial divisions each oogonium passes through a mitotic division with incomplete cytokinesis. This division gives rise to two sister cells, a prospective nurse cell and the oocyte, which remain connected by an intercellular bridge. In two phases of nurse chamber formation, first four and then (usually) one or two ovarian cells of mesodermal origin fuse with the prospective nurse cell. This results in a syncytial nurse chamber containing one germ-cell-derived nucleus and a varying number of mesoderm-cell-derived nuclei. In two subsequent fusion steps, two mesodermal cells fuse with the oocyte, giving rise to an oocyte containing one large and two small nuclei. Thus, four fusion steps lead to the formation of the complete oocyte-nurse chamber complex. Characteristics of the cell fusions are: (1) in each case one or more somatic cell(s) fuse with a germ-line cell and (2) cell contact between the fusing cells is established by the somatic cell, which approaches the germ-line cells.     

Oogenesis in Hydra carnea: A new model based on light and electron microscopic analyses of oocyte and nurse cell differentiation

Oogenesis in Hydra carnea starts with an accumulation of a great number of I-cells in the interstitial spaces of the ectoderm of the body column. One centrally located I-cell becomes the future oocyte, the others differentiate into nurse cells. Presumptive oocyte and nurse cells are not easily distinguishable at that time. The earliest stage of an oocyte we could identify on ultrastructural criteria was in prophase of its first meiotic division. Only at this stage autosynthesis of nutritive substances predominates, the following rapid increase of the oocyte volume relies on the successive adoption of cytoplasmic fragments from nurse cells. Extending fingerlike processes between the epitheliomuscular cells, the oocyte then starts to phagocytose apoptotic nurse cells. Nurse cell differentiation is indicated by the appearance of lipid vesicles in I-cells. As differentiation proceeds glycogen, rEr and Golgi complexes appear and the cells increase due to a continuous production and accumulation of lipid, glycogen and yolk-like electron dense material. Then the loss of cytoplasmic fragments and degenerative changes typical of apoptosis, a morphologically defined form of cell death, converts the nurse cells into apoptotic bodies. The bulk of nurse cells becomes phagocytosed by the oocyte at late stages of their transformation into apoptotic bodies. At the end of oogenesis which in Hydra carnea takes about 4 days, the egg consists for the largest part of apoptotic nurse cells which persist in the developing embryo until hatching.     

Programmed cell death of the ovarian nurse cells during oogenesis of the silkmoth Bombyx mori

In the present study, we describe the features of programmed cell death of the ovarian nurse cells occurring during vitellogenesis of the silkmoth Bombyx mori. At developmental stage 5, the nurse cells occupy one-half of the follicular volume and obtain a rather spherical shape, while the nurse cell nuclei appear large and elongated, forming impressive projections. At the following stage, stage 6, the nurse cells decrease in size and their shape becomes elliptic. The nuclei remain elongated, being also characterized by large lobes. The lobes of the ramified nurse cell nuclei seem to retain the nucleus in the center of the cell during the dumping of the nurse cell cytoplasm into the growing oocyte. At stage 7, membrane enclosed vacuoles can be easily detected into the nurse cells cytoplasm. Ultrastructural analysis and fluorescent microscopy using mono-dansyl-cadaverine staining of these vacuoles also reveal that they represent autolysosomes. Caspase activity is detected during stage 7, as it is demonstrated by using the Red-VAD-FMK staining reagent. At developmental stages 8 and 9, the nurse cells exhibit chromatin condensation, DNA fragmentation and caspase activity. Finally, during the following stage 10, the nuclear remnants are assembled into apoptotic vesicles, which, after being phagocytosed, are observed in the cytoplasm of adjacent follicle cells. We propose that apoptosis and autophagy operate synergistically during vitellogenesis of B. mori, in order to achieve an efficient and rapid clearance of the degenerated nurse cell cluster.     

Cytochemical studies of developmental stages during oogenesis in Culex pipiens molestus (Forsk?l). I. Lipids and carbohydrates

Lipids and carbohydrates were studied in the polytrophic ovaries of Culex pipiens molestus during oogenesis. The cytoplasm of both the oocyte and the nurse cells contains lipid structures at all stages of development--granules in the early stages and spheres in the later stages. Intranuclear lipid bodies can be demonstrated in the oocyte and in the nurse cells. After leaving the nucleus, lipids are deposited in the peripheral cytoplasm. From the third to the seventh adult phase, lipid granules are concentrated in the area of the nurse cell and oocyte junction, indicating that lipids originate in the nurse cells and are transported from these to the oocyte. The follicular epithelial cells provide the oocyte with lipid material for fatty yolk synthesis and formation of the egg envelopes. Lipids are distributed similarly to the Golgi apparatus, indicating that there is a relationship between this organelle and fat formation. In the early stages, the cytoplasm of the oocyte, the nurse cells and the follicular epithelium contains glycogen granules. In the later stages these cells also contain mucopolysaccharides. The mucopolysaccharide yolk spheres are enclosed in vacuoles, while the chorion is composed of acid mucopolysaccharides. The follicular epithelium and vitelline membrane are of a mucopolysaccharide nature. A topographical relationship exists between the Golgi apparatus and the glycogen granules, indicating that this organelle also plays a role in glycogen synthesis.