Protecting and Diversifying the Germline

Gleason, Ryan J; Alladi, Anand; Kai, Toshie; Chen, Xin

doi:10.1534/genetics.117.300208

Cited by 37 publications

(34 citation statements)

References 432 publications

(595 reference statements)

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“…In the anterior half of the germarium, cysts arise from the mitotic expansion of GSCs and their differentiating daughters (Figures 2D, 3). GSCs divide mitotically with asymmetric division, giving rise to two cells of unequal fates: a new stem cell and a cystoblast destined for differentiation (Schüpbach et al, 1978;Wieschaus and Szabad, 1979;Lin and Spradling, 1993;reviewed in: Xie, 2013;Gleason et al, 2018;Drummond-Barbosa, 2019;Kahney et al, 2019). The cystoblast undergoes exactly four rounds of mitotic division with incomplete cytokinesis, creating interconnected 2, 4, 8, and 16 cell cysts (King, 1970;Spradling, 1993).…”

Section: Introductionmentioning

confidence: 99%

Coordinating Proliferation, Polarity, and Cell Fate in the Drosophila Female Germline

Hinnant

Merkle

Ables

2020

Front. Cell Dev. Biol.

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Gametes are highly specialized cell types produced by a complex differentiation process. Production of viable oocytes requires a series of precise and coordinated molecular events. Early in their development, germ cells are an interconnected group of mitotically dividing cells. Key regulatory events lead to the specification of mature oocytes and initiate a switch to the meiotic cell cycle program. Though the chromosomal events of meiosis have been extensively studied, it is unclear how other aspects of oocyte specification are temporally coordinated. The fruit fly, Drosophila melanogaster, has long been at the forefront as a model system for genetics and cell biology research. The adult Drosophila ovary continuously produces germ cells throughout the organism's lifetime, and many of the cellular processes that occur to establish oocyte fate are conserved with mammalian gamete development. Here, we review recent discoveries from Drosophila that advance our understanding of how early germ cells balance mitotic exit with meiotic initiation. We discuss cell cycle control and establishment of cell polarity as major themes in oocyte specification. We also highlight a germline-specific organelle, the fusome, as integral to the coordination of cell division, cell polarity, and cell fate in ovarian germ cells. Finally, we discuss how the molecular controls of the cell cycle might be integrated with cell polarity and cell fate to maintain oocyte production.

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Section: Introductionmentioning

confidence: 99%

Coordinating Proliferation, Polarity, and Cell Fate in the Drosophila Female Germline

Hinnant

Merkle

Ables

2020

Front. Cell Dev. Biol.

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“…Drosophila melanogaster is an ideal model organism for the detailed study of oogenesis. Drosophila females have one pair of ovaries that consist of 18-20 ovarioles (reviewed in [1][2][3]). In germarium-a structure at the anterior tip of the ovariole-two or three germline stem cells (GSCs) are maintained in the undifferentiated status in a niche environment.…”

Section: Introductionmentioning

confidence: 99%

Drosophila MARF1 ensures proper oocyte maturation by regulating nanos expression

Kawaguchi¹,

Ueki²,

Kai³

2020

PLoS ONE

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Meiosis and oocyte maturation are tightly regulated processes. The meiosis arrest female 1 (MARF1) gene is essential for meiotic progression in animals; however, its detailed function remains unclear. In this study, we examined the molecular mechanism of dMarf1, a Drosophila homolog of MARF1 encoding an OST and RNA Recognition Motif (RRM)-containing protein for meiotic progression and oocyte maturation. Although oogenesis progressed in females carrying a dMarf1 loss-of-function allele, the dMarf1 mutant oocytes were found to contain arrested meiotic spindles or disrupted microtubule structures, indicating that the transition from meiosis I to II was compromised in these oocytes. The expression of the full-length dMarf1 transgene, but none of the variants lacking the OST and RRM motifs or the 47 conserved C-terminal residues among insect groups, rescued the meiotic defect in dMarf1 mutant oocytes. Our results indicate that these conserved residues are important for dMarf1 function. Immunoprecipitation of Myc-dMarf1 revealed that several mRNAs are bound to dMarf1. Of those, the protein expression of nanos (nos), but not its mRNA, was affected in the absence of dMarf1. In the control, the expression of Nos protein became downregulated during the late stages of oogenesis, while it remained high in dMarf1 mutant oocytes. We propose that dMarf1 translationally represses nos by binding to its mRNA. Furthermore, the downregulation of Nos induces cycB expression, which in turn activates the CycB/Cdk1 complex at the onset of oocyte maturation.

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“…The RNAi system of the insect last common ancestor diversified and expanded through time across the different insect lineages (Dowling et al., ). Although the canonical functions of piRNAs are associated with genome protection from transposon activity during embryogenesis, evidences of additional roles (like regulation of gene expression) are growing (Gebert, Ketting, Zischler, & Rosenkranz, ; Gleason et al., ; Le Thomas et al., ; Lewis et al., ; Peng & Lin, ; Pritykin, Brito, Schupbach, Singh, & Pane, ; Sarkar, Volff, & Vaury, ). As the taxonomic spectrum of studied species broadens, the complexity of the piRNA system appears to expand.…”

Section: Discussionmentioning

confidence: 99%

“…The piRNA transcription does not seem to occur through canonical promoters. It has been proposed that the Rhino‐Deadlock‐Cutoff (RDC) complex would participate in regulating the transcription of piRNA clusters in germ cells, inhibiting the transcription of adjacent genes in the cluster or allowing the functionality of noncanonical promoters (Gleason, Anand, Kai, & Chen, ). Moreover, the localization of some piRNA clusters in heterochromatic regions led to the study of them in relation to histone modifications, which has revealed an important role of H3K9me3 on cluster transcription (Mohn, Sienski, Handler, & Brennecke, ; Molla‐Herman, Vallés, Ganem‐Elbaz, Antoniewski, & Huynh, ).…”

Section: Introductionmentioning

confidence: 99%

“…Moreover, the localization of some piRNA clusters in heterochromatic regions led to the study of them in relation to histone modifications, which has revealed an important role of H3K9me3 on cluster transcription (Mohn, Sienski, Handler, & Brennecke, ; Molla‐Herman, Vallés, Ganem‐Elbaz, Antoniewski, & Huynh, ). In somatic cells, the mechanisms regulating piRNA transcription are less known, but it has been suggested that the control exerted by the RDC complex would not be necessary in these cells (see Gleason et al, ).…”

Section: Introductionmentioning

confidence: 99%

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Diversity of piRNA expression patterns during the ontogeny of the German cockroach

et al. 2018

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The Piwi-interacting RNA (piRNA) system is an evolutionarily conserved mechanism involved in the control of transposable elements and maintenance of genomic stability, especially in germ line cells and in early embryo stages. However, relevant particularities, both in mechanism and function, exist across species among metazoans and even within the insect class. As a member of the scarcely studied hemimetabolan group, Blattella germanica can be a suitable reference model to study insect evolution. We present the results of a stringent process of identification and study of expressed piRNAs for B. germanica across 11 developmental stages, ranging from unfertilized egg to nymphs and adult female. Our results confirm the dual origin of piRNA in this species, with a majority of them being generated from the primary pathway, and a smaller but highly expressed set of sequences participating in the secondary ("ping-pong") reamplification pathway. An intriguing partial complementarity in expression is observed between the piRNA of the two biogenesis pathways, with those generated in the secondary pathway being quite restricted to early embryo stages. In addition, many piRNAs are exclusively expressed in late embryo and nymphal stages. These observations point at piRNA functions beyond the role of transposon control in early embryogenesis. Our work supports the view of a more complex scenario, with different sets of piRNAs acting in different times and having a range of functions wider than previously thought.

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Protecting and Diversifying the Germline

Cited by 37 publications

References 432 publications

Coordinating Proliferation, Polarity, and Cell Fate in the Drosophila Female Germline

Coordinating Proliferation, Polarity, and Cell Fate in the Drosophila Female Germline

Drosophila MARF1 ensures proper oocyte maturation by regulating nanos expression

Diversity of piRNA expression patterns during the ontogeny of the German cockroach

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