Distinct regulation of atonal in a visual organ of Drosophila : Organ-specific enhancer and lack of autoregulation in the larval eye

Zhou, Qingxiang; Yu, Lingxue; Friedrich, Markus; Pignoni, Francesca

doi:10.1016/j.ydbio.2016.09.023

Cited by 5 publications

(9 citation statements)

References 46 publications

(83 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Could other mechanisms thus be used to replace autoregulation to maintain stable neural fate? Positive autoregulation has not been found in studies of some Drosophila neurons, indicating that although the segregation of initiation and autoregulation provides an important conceptual insight into mechanisms of fate specification, similar outcomes might also be achieved by other regulatory mechanisms (Holohan et al, 2006;Zhou et al, 2017). It is possible that transcription factors further downstream are responsible.…”

Section: Coding Mutationmentioning

confidence: 99%

All in the family: proneural bHLH genes and neuronal diversity

Baker

Brown

2018

Development

View full text Add to dashboard Cite

Proneural basic Helix-Loop-Helix (bHLH) proteins are required for neuronal determination and the differentiation of most neural precursor cells. These transcription factors are expressed in vastly divergent organisms, ranging from sponges to primates. Here, we review proneural bHLH gene evolution and function in the and vertebrate nervous systems, arguing that the gene provides a useful platform for understanding proneural gene structure and regulation. We also discuss how functional equivalency experiments using distinct proneural genes can reveal how proneural gene duplication and divergence are interwoven with neuronal complexity.

show abstract

Section: Coding Mutationmentioning

confidence: 99%

All in the family: proneural bHLH genes and neuronal diversity

Baker

Brown

2018

Development

View full text Add to dashboard Cite

show abstract

“…By contrast, BO PRCs, once segregated from the surface, turn down the expression of the apical/subapical protein complexes Crb and Arm/β-catenin. One might speculate that the disappearance of these proteins is controlled at the transcriptional level, by the emergence of larval-specific cis-regulatory elements, as shown recently shown for the proneural gene atonal (Zhou et al, 2017). In the absence of apical markers, like Crb, PLP or Asl, the polarity of BO PRCs is difficult to follow; using the fact that PRC axons mark the basal pole, and interpreting the opposite side of the cell as the apical pole, one can infer that cells rotate, so that the apical pole faces anteriorly during stage 14/15, and comes to point laterally (i.e., 180 deg rotated from the original orientation) by stage 16 (see Fig.…”

Section: Cells Of the Drosophila Larval Eye: Developmentally Truncatementioning

confidence: 70%

“…Drosophila larval vision, mediated by the BO, has been the focus of several recent functional studies, including (Essen et al, 2011;Humberg et al, 2018;Humberg and Sprecher, 2017;Justice et al, 2012;Kane et al, 2013;Keene et al, 2011). The BO, due to its simplicity in terms of cell types and rapid development during the embryonic period, has also a rich source for developmental genetic analysis (Sprecher et al, 2007;Sprecher and Desplan, 2008;Vasiliauskas et al, 2011;Mishra et al, 2013Mishra et al, , 2016Zhou et al, 2017). To further aid in these studies a more detailed understanding of the ultrastructural details of the BO photoreceptor membrane specializations is required.…”

Section: Introductionmentioning

confidence: 99%

Serial electron microscopic reconstruction of the drosophila larval eye: Photoreceptors with a rudimentary rhabdomere of microvillar-like processes

Hartenstein

Yuan

Younossi-Hartenstein

et al. 2019

Developmental Biology

View full text Add to dashboard Cite

Photoreceptor cells (PRCs) across the animal kingdom are characterized by a stacking of apical membranes to accommodate the high abundance of photopigment. In arthropods and many other invertebrate phyla PRC membrane stacks adopt the shape of densely packed microvilli that form a structure called rhabdomere. PRCs and surrounding accessory cells, including pigment cells and lens-forming cells, are grouped in stereotyped units, the ommatidia. In larvae of holometabolan insects, eyes (called stemmata) are reduced in terms of number and composition of ommatidia. The stemma of Drosophila (Bolwig organ) is reduced to a bilateral cluster of subepidermal PRCs, lacking all other cell types. In the present paper we have analyzed the development and fine structure of the Drosophila larval PRCs. Shortly after their appearance in the embryonic head ectoderm, PRC precursors delaminate and lose expression of apical markers of epithelial cells, including Crumbs and several centrosome-associated proteins. In the early first instar larva, PRCs show an expanded, irregularly shaped apical surface that is folded into multiple horizontal microvillar-like processes (MLPs). Apical PRC membranes and MLPs are covered with a layer of extracellular matrix. MLPs are predominantly aligned along an axis that extends ventro-anteriorly to dorso-posteriorly, but vary in length, diameter, and spacing. Individual MLPs present a "beaded" shape, with thick segments (0.2-0.3 μm diameter) alternating with thin segments (>0.1 μm). We show that loss of the glycoprotein Chaoptin, which is absolutely essential for rhabdomere formation in the adult PRCs, does not lead to severe abnormalities in larval PRCs.

show abstract

“…The ventroposterior domain gives rise to the primordium of the larval eye and consists of two photoreceptor (PR) precursor types (primary and secondary precursors), whereas the dorsal domain harbors neuroepithelial precursors that generate the optic lobe of the adult visual system [ 4 – 6 ]. The basic helix-loop-helix transcription factor Atonal (Ato) promotes PR precursor cell fate in the larval eye primordium [ 4 , 7 ]. The orphan nuclear receptor Tailless (Tll) is confined to the optic lobe primordium and maintains non-PR cell fate [ 4 ].…”

Section: Introductionmentioning

confidence: 99%

“…Notch delimits the number of PR precursors and maintains a pool of non-PR precursors [ 10 ]. Ato is initially expressed in all PR precursors in the placode and its expression gets progressively restricted to primary precursors [ 7 , 11 ]. In a second step, primary precursors recruit secondary precursors via EGFR signaling: primary precursors express the EGFR ligand Spitz, which is required in secondary precursors to promote their survival.…”

Section: Introductionmentioning

confidence: 99%

Patterning mechanisms diversify neuroepithelial domains in the Drosophila optic placode

et al. 2018

View full text Add to dashboard Cite

The central nervous system develops from monolayered neuroepithelial sheets. In a first step patterning mechanisms subdivide the seemingly uniform epithelia into domains allowing an increase of neuronal diversity in a tightly controlled spatial and temporal manner. In Drosophila, neuroepithelial patterning of the embryonic optic placode gives rise to the larval eye primordium, consisting of two photoreceptor (PR) precursor types (primary and secondary), as well as the optic lobe primordium, which during larval and pupal stages develops into the prominent optic ganglia. Here, we characterize a genetic network that regulates the balance between larval eye and optic lobe precursors, as well as between primary and secondary PR precursors. In a first step the proneural factor Atonal (Ato) specifies larval eye precursors, while the orphan nuclear receptor Tailless (Tll) is crucial for the specification of optic lobe precursors. The Hedgehog and Notch signaling pathways act upstream of Ato and Tll to coordinate neural precursor specification in a timely manner. The correct spatial placement of the boundary between Ato and Tll in turn is required to control the precise number of primary and secondary PR precursors. In a second step, Notch signaling also controls a binary cell fate decision, thus, acts at the top of a cascade of transcription factor interactions to define PR subtype identity. Our model serves as an example of how combinatorial action of cell extrinsic and cell intrinsic factors control neural tissue patterning.

show abstract

Distinct regulation of atonal in a visual organ of Drosophila : Organ-specific enhancer and lack of autoregulation in the larval eye

Cited by 5 publications

References 46 publications

All in the family: proneural bHLH genes and neuronal diversity

All in the family: proneural bHLH genes and neuronal diversity

Serial electron microscopic reconstruction of the drosophila larval eye: Photoreceptors with a rudimentary rhabdomere of microvillar-like processes

Patterning mechanisms diversify neuroepithelial domains in the Drosophila optic placode

Contact Info

Product

Resources

About