S. A. Fedorova

Basic Aspects of Ovarian Development in Drosophila melanogaster

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.

The role of Drosophila hyperplastic discs gene in spermatogenesis

In Drosophila, the ubiquitin ligase Hyd (hyperplastic disc) is required for regulation of cell proliferation during development [ Martin et al. (1977) Dev Biol 55, 213–232; Mansfield et al. (1994) Dev Biol 165, 507–526]. Earlier, we demonstrated that the Drosophila tumour suppressor Merlin participates not only in imaginal discs proliferation control, but also performs a separate Nebenkern structural function in Drosophila spermatogenesis [ Dorogova et al. (2008) BMC Cell Biol 9, 1. Here, we show that the hyd mutants also have spermatogenesis defects: chromosome condensation and attachment to the spindle, centrosome behaviour and cytokinesis in meiosis. The process of spermatid elongation was also greatly affected: nuclei were scattered along the cyst and had an abnormal shape, Nebenkern–axoneme angular relation and attachment was distorted, axonemes themselves lost correct structure. Since Hyd and pAbp protein families share a common PABC [poly(A)‐binding protein C‐terminal] protein domain, we also studied spermatogenesis in pAbp homozygotes and found defects in cytokinesis and spermatid elongation. However, our study of hyd and pAbp genetic interaction revealed only the phenotype of defective nuclei shape at the final stage of spermatid differentiation. So, the PABC domain is unlikely to be responsible for meiotic defects. Thus, our data document that, in addition to the tumour suppressor Merlin, another tumour suppressor, Hyd, also has a function in spermatogenesis.

Key Events of the Cell Cycle: Regulation and Organization

The review surveys the studies of molecular genetic mechanisms of the cell cycle control on various eukaryotic models. The major cell cycle phenomena are considered: (1) checkpoints and their role in preserving DNA integrity and fidelity of mitosis, (2) the cell oscillator model, and (3) the role of cyclins in timing of cell division and coordination of mitotic events. The main classes of regulatory proteins involved in the cell cycle are discussed in detail.

Drosophila male-sterile mutation emmenthal specifically affects the mitochondrial morphogenesis

Proper mitochondrial morphogenesis is crucial for successful development of motile sperm. It was known that recessive Drosophila melanogaster mutation emm caused anomalies in the formation of a mitochondrial derivative—nebenkern and led to male sterility. Here we identified primary mutation effect and showed that emm is required for the formation and maintenance of inner mitochondrial structure starting from early spermatocytes. Abnormal mitochondria structure affects subsequent cellular processes in spermatogenesis such as meiotic cytokinesis and spermatid elongation.

Genetic Control of Mitosis: Is Protein MASTν40 an Element of the Checkpoint System?

The effect of the mastv40 mutation was studied using neural ganglion cells of third-instar larvae of Drosophila melanogaster. The distributions of the cells by the interphase nucleus diameter and by the distance between the sister chromosome sets in anaphase were analyzed. Three following types of defects induced by the mutation were described: (1) Monopolar mitosis or, in the case of bipolar mitosis, an abnormally short distance between the sister chromosome sets in anaphase and early telophase. We suppose that these abnormalities are caused by damage of the start and (or) motor mechanisms of centrosome separation at the beginning and in the end of mitosis. (2) Lagging and bridging of chromosomes in anaphase and early telophase. These defects seem to be related to the disruption of functioning of mitotic spindle microtubules and (or) their defective attachment to the appropriate kinetochores. (3) Unlimited division of aneuploid and polyploid cells, which may be explained either by inactivation of the checkpoint system controlling the genome ploidy or by checkpoint adaptation. Taken collectively, our results and literature data suggest that the MAST protein is an element of the checkpoint system and that division of aneuploid and polyploid cells results from inactivation of the checkpoints.

Mitosis: Regulation and organization of cell division

Modern views on genetic, cytological and molecular bases of the structure and regulation of preparing and implementing mitotic chromosome segregation are discussed.

Genetic Control of Mitosis: Features of Anaphase Separation of Sister Chromatid Sets in Mutant Strain aarV158 in Drosophila melanogaster

The effect of mutation aarV158 on anaphase separation of chromatids was studied on fixed cells of neural ganglia of Drosophila melanogaster larvae. It was shown that mutation aarV158 causes three types of defective chromosome segregation manifested as (1) monopolar anaphase, (2) separation of chromatids to an abnormally short distance in anaphase, and (3) bridging and lagging of some chromatids or prolonged asynchronous separation of sister chromatid sets to the poles in anaphase. We believe that the former two types of defective segregation are caused by disturbed centrosome separation at the beginning of mitosis and the third type, by defects in chromatid separation during anaphase. During the two-year maintenance of the mutation in a heterozygous state, partial correction (adaptive modification) of the defects of type 1 and type 2 (but not type 3) occurred. The correction of type 1 and type 2 defects during adaptogenesis depended on the genotype: in heterozygotes and homozygotes, respectively type 1 and type 2 were preferentially corrected. The frequency of type 3 defects remained constant during the two-year period of maintenance of the mutation in a heterozygous state. However, in all variants of the experiment, their frequency decreased with increasing distance between the sister chromatid sets. In the cells that completed the previous division with abnormalities, the checkpoint system is supposed to effectively arrest the cell cycle in the subsequent division.

Genetic Control of Mitosis: Mutation ff3Causes Premature Beginning of Telophase Chromatin Reorganization in Drosophila melanogaster

The effect of cell cycle mutation ff3 on chromosome segregation was studied on fixed cells of neural ganglia of Drosophila melanogasterlarvae. The cell distributions by diameter of interphase nuclei and by distance between sister chromatid sets were compared at anaphase and telophase. In the control wild-type strain Lausenne, the cell distribution by distance between sister chromatids in anaphase was similar to their distribution by nuclear size. The mean distance between segregating chromatids at anaphase (lav) coincided with the mean diameter of interphase nuclei (dav) and was 8.3 μm. Cells passed to telophase when chromatids were at least 10 μm apart. The mutant ff3 strain differed from the control strain Lausenne in cell distribution by interphase nuclear diameter and distance between sister chromatids in anaphase; the mean nuclear diameter and mean distance between segregating chromatids similarly increased to 9.3 μm. A specific feature of mitosis in mutant strain ff3 was a premature beginning of telophase chromatin reorganization. This caused the occurrence of cells with abnormally short (less then the interphase nuclear diameter) distance between sister chromatid sets in telophase but not in anaphase, as if these cells had passed from anaphase to telophase prematurely, during the chromatid movement toward poles in anaphase A.

Analysis of peanut gene RNAi in drosophila oogenesis

The peanut gene functions in Drosophila melanogaster oogenesis were studied. It was demonstrated that the suppression of peanut expression by RNA interference in follicle cells led to oocyte polarization defects, anomalous cytokinesis in the chorion cells, and aberrant chromatin condensation in follicle cells. No oogenesis abnormalities were observed in females with decreased peanut gene expression in ovarian germline cells. However, embryos produced by such females had a decreased survival rate caused by two peaks of embryonic death.

Specifics of anaphase chromatid segregation in Drosophila melanogaster mitotic mutants

Anaphase chromatid segregation defects (CSDs) were quantitatively and qualitatively studied in neural ganglion cells of third-instar larvae of several control wild type Drosophila melanogaster strains and four strains with mutations of the aarv158, ff3, mastv40, and CycB2g cell cycle genes. A linear specificity was observed for the CSD frequency, type, determination, and correction probability. The probability of anaphase CSD correction was close to unity in the control strains and lower in the mutant strains. The lower correction probability in the mutant strains was explained in the context of two findings, that the mutations induced the CSDs that were atypical of the wild type strains and were potentially uncorrectable in anaphase and that the mutations negatively affected the relative anaphase time in mitosis.