Adult stem cells and niche cells segregate gradually from common precursors that build the adult Drosophila ovary during pupal development

Production of proliferative Follicle Cells (FCs) and quiescent Escort Cells (ECs) by Follicle Stem Cells (FSCs) in adult Drosophila ovaries is regulated by niche signals from anterior (Cap Cells, ECs) and posterior (polar FCs) sources. Here we show that ECs, FSCs and FCs develop from common pupal precursors, with different fates acquired by progressive separation of cells along the AP axis and a graded decline in anterior cell proliferation. ECs, FSCs and most FCs derive from Intermingled Cell (IC) precursors interspersed with germline cells. Precursors also accumulate posterior to ICs before engulfing a naked germline cyst projected out of the germarium to form the first egg chamber and posterior polar FC signaling center. Thus, stem and niche cells develop in appropriate numbers and spatial organization through regulated proliferative expansion together with progressive establishment of spatial signaling cues that guide adult cell behavior, rather than through rigid early specification events.

Altered germline cyst formation and oogenesis in Tex14 mutant mice

ABSTRACT During oocyte differentiation in mouse fetal ovaries, sister germ cells are connected by intercellular bridges, forming germline cysts. Within the cyst, primary oocytes form via gaining cytoplasm and organelles from sister germ cells through germ cell connectivity. To uncover the role of intercellular bridges in oocyte differentiation, we analyzed mutant female mice lacking testis-expressed 14 (TEX14), a protein involved in intercellular bridge formation and stabilization. In Tex14 homozygous mutant fetal ovaries, germ cells divide to form a reduced number of cysts in which germ cells remained connected via syncytia or fragmented cell membranes, rather than normal intercellular bridges. Compared with wild-type cysts, homozygous mutant cysts fragmented at a higher frequency and produced a greatly reduced number of primary oocytes with precocious cytoplasmic enrichment and enlarged volume. By contrast, Tex14 heterozygous mutant germline cysts were less fragmented and generate primary oocytes at a reduced size. Moreover, enlarged primary oocytes in homozygous mutants were used more efficiently to sustain folliculogenesis than undersized heterozygous mutant primary oocytes. Our observations directly link the nature of fetal germline cysts to oocyte differentiation and development.

Acetylated microtubules are required for maintenance of the barrier between two adjacent tissues

Microtubule acetylation is found in populations of stable, long-lived microtubules, occurring on the conserved lysine 40 (K40) residue of α-tubulin, catalyzed by alpha-tubulin acetyltransferases (αTATs). K40 acetylation has been shown to stabilize microtubules via enhancing microtubule resilience against mechanical stress. Here we show that Drosophila CG17003/leaky (Lky), an αTAT, is required for proper oogenesis. We found that loss of lky disrupted the cell junction between germline cyst and follicle epithelial cells, adjacent cells that form an egg chamber. This resulted in leakage of germline contents into somatic follicle cells. The follicle cells that received germline-derived nanos gene product failed to maintain their cell fate, leading to an egg chamber fusion. The same phenotype was observed upon replacement of major α-tubulin84B K40 with α-tubulin84B K40A (non-acetylable tubulin), suggesting α-tubulin K40 acetylation is required for the boundary integrity of these two adjacent tissues. Taken together, this study provides the first in vivo function of tubulin acetylation in maintaining the integrity of a tissue barrier.

Symmetry breaking in the female germline cyst

In mammals and flies, only a limited number of cells in a multicellular female germline cyst become oocytes, but how the oocyte is selected is unknown. Here we show that the microtubule minus end-stabilizing protein, Patronin/CAMSAP marks the future Drosophila oocyte and is required for oocyte specification. The spectraplakin, Shot, recruits Patronin to the fusome, a branched structure extending into all cyst cells. Patronin stabilizes more microtubules in the cell with most fusome and this weak asymmetry is amplified by Dynein-dependent transport of Patronin-stabilized microtubules. This forms a polarized microtubule network, along which Dynein transports oocyte determinants into the presumptive oocyte. Thus, Patronin amplifies a weak fusome anisotropy to break cyst symmetry. These findings reveal a molecular mechanism of oocyte selection in the germline cyst.

Ciliary control of meiotic chromosomal pairing mechanics and germ cell morphogenesis

Meiosis is a cellular program essential for the production of haploid gametes. A hallmark of meiosis is chromosomal pairing via synaptonemal complexes, and a major focus traditionally has been to understand synaptonemal complex formation. However, chromosomal pairing also depends on cytoplasmic counterparts that tether and rotate telomeres on the nuclear envelope, shuffling chromosomes and mechanically driving their homology searches1–8. Rotating telomeres slide on perinuclear microtubules and are ultimately pulled towards the centrosome7,9,10, forming the “zygotene chromosomal bouquet configuration”11. The bouquet is universally conserved and is essential for pairing and fertility1–8,12. However, despite its discovery in 190011, how the cytoplasmic counterparts of bouquet formation are mechanically regulated has remained enigmatic. Here, by studying zebrafish oogenesis, we report and comprehensively characterize the “zygotene cilium” - a previously unrecognized cilium in oocytes. We show that the zygotene cilium specifically connects to the bouquet centrosome and constitutes a cable system of the cytoplasmic bouquet machinery. Farther, zygotene cilia extend throughout the germline cyst, a conserved cellular organization of germ cells. By analyzing multiple ciliary mutants, we demonstrate that the zygotene cilium is essential for chromosomal pairing, germ cell morphogenesis, ovarian development and fertility. We further show that the zygotene cilium is conserved in both male meiosis in zebrafish, as well as in mammalian oogenesis. Our work uncovers the novel concept of a cilium as a critical player in meiosis and sheds new light on reproduction phenotypes in ciliopathies. Furthermore, most cells in metazoans are ciliated and exhibit specific nuclear dynamics. We propose a cellular paradigm that cilia can control chromosomal dynamics.

Hormone receptor 4 is required in muscles and distinct ovarian cell types to regulate specific steps of Drosophila oogenesis

The conserved nuclear receptor superfamily has critical roles in many processes, including reproduction. Nuclear receptors with known roles in oogenesis have been studied mostly in the context of their ovary-intrinsic requirement. Recent studies in Drosophila, however, have begun to reveal new roles of nuclear receptor signaling in peripheral tissues in controlling reproduction. Here, we identified Hormone receptor 4 (Hr4) as an oogenesis regulator required in the ovary and muscles. Global Hr4 knockdown leads to increased germline stem cell (GSC) loss, reduced GSC proliferation, early germline cyst death, slowed follicle growth, and vitellogenic follicle degeneration. Tissue-specific knockdown experiments uncovered ovary-intrinsic and peripheral tissue requirements for Hr4. In the ovary, Hr4 is required in the niche for GSC proliferation and in the germline for GSC maintenance. Hr4 functions in muscles to promote GSC maintenance and follicle growth. The specific tissues that require Hr4 for survival of early germline cysts and vitellogenic follicles remain unidentified. These results add to the few examples of muscles controlling gametogenesis and expand our understanding of the complexity of nuclear receptor regulation of various aspects of oogenesis.

Zebrafish dazl regulates cystogenesis upstream of the meiotic transition and germline stem cell specification and independent of meiotic checkpoints

Fertility and gamete reserves are maintained by asymmetric divisions of the germline stem cells to produce new stem cells or daughters that differentiate as gametes. Before entering meiosis, differentiating germ cells (GCs) of sexual animals typically undergo cystogenesis. This evolutionary conserved process involves synchronous and incomplete mitotic divisions of a germ cell daughter (cystoblast) to generate sister cells connected by stable intercellular bridges that facilitate exchange of materials to support a large synchronous population of gamete progenitors. Here we investigate cystogenesis in zebrafish and identified Deleted in azoospermia (Dazl), a conserved vertebrate RNA binding protein as a regulator of this process. Analysis of dazl mutants revealed an essential role for Dazl in regulating incomplete cytokinesis and germline cyst formation before the meiotic transition. Accordingly, dazl mutant GCs form defective ring canals, and ultimately remain as individual cells that fail to differentiate as meiocytes. In addition to promoting cystoblast divisions and meiotic entry, dazl function is required upstream of germline stem cell establishment and fertility.Summary StatementWe show that zebrafish dazl is required for incomplete cytokinesis to generate germline cysts during cystogenesis, acts upstream of germline stem cell establishment, and is required for meiosis, and fertility.