Interdependent regulation of stereotyped and stochastic photoreceptor fates in the fly eye

Miller, Adam C.; Urban, Elizabeth; Lyons, Eric L.; Herman, Tory; Johnston, Robert J.

doi:10.1016/j.ydbio.2020.12.008

Cited by 6 publications

(6 citation statements)

References 36 publications

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“…In vertebrates, crx , otx2 , and rax are expressed in all PRCs, but different factors control the opsins expressed in rods (nrl, nr2e3, nr1d1, pias 3, and fiz1) compared with cones (thbr and rxrg for Lws opsin; tbx2 for Sws1) [ 26 ]. In insects, a set of genes ( senseless , prospero , spalt , and spineless ) is used for PRC specification, but variation in gene regulatory networks drive differences across a compound eye and between species [ 27 , 28 , 29 ].…”

Section: Evolution Of Eyes and Photoreceptor Cell Typesmentioning

confidence: 99%

Deep Diversity: Extensive Variation in the Components of Complex Visual Systems across Animals

Vöcking

Macias-Muñoz

Jaeger

et al. 2022

Cells

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Understanding the molecular underpinnings of the evolution of complex (multi-part) systems is a fundamental topic in biology. One unanswered question is to what the extent do similar or different genes and regulatory interactions underlie similar complex systems across species? Animal eyes and phototransduction (light detection) are outstanding systems to investigate this question because some of the genetics underlying these traits are well characterized in model organisms. However, comparative studies using non-model organisms are also necessary to understand the diversity and evolution of these traits. Here, we compare the characteristics of photoreceptor cells, opsins, and phototransduction cascades in diverse taxa, with a particular focus on cnidarians. In contrast to the common theme of deep homology, whereby similar traits develop mainly using homologous genes, comparisons of visual systems, especially in non-model organisms, are beginning to highlight a “deep diversity” of underlying components, illustrating how variation can underlie similar complex systems across taxa. Although using candidate genes from model organisms across diversity was a good starting point to understand the evolution of complex systems, unbiased genome-wide comparisons and subsequent functional validation will be necessary to uncover unique genes that comprise the complex systems of non-model groups to better understand biodiversity and its evolution.

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Section: Evolution Of Eyes and Photoreceptor Cell Typesmentioning

confidence: 99%

Deep Diversity: Extensive Variation in the Components of Complex Visual Systems across Animals

Vöcking

Macias-Muñoz

Jaeger

et al. 2022

Cells

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“…In the dorsal third retina, lower Dve expression and Iroquois complex expression activate Rh3 coexpression with Rh4 in dorsal yellow ommatidia [16,37,38]. Recently, another feedback loop was discovered, showing that interaction with stereotyped upstream Runt expression contributes to the stochastic Spineless expression that determines pale or yellow ommatidial types [39] (figure 1c). Feedforward, feedback and bistable loops build redundancy and modularity into this system and have become hallmarks of robust developmental processes in other complex traits.…”

Section: What Have We Learned About Opsin Regulationmentioning

confidence: 99%

Insect opsins and evo-devo: what have we learned in 25 years?

McCulloch

Macias-Muñoz

Briscoe

2022

Phil. Trans. R. Soc. B

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The visual pigments known as opsins are the primary molecular basis for colour vision in animals. Insects are among the most diverse of animal groups and their visual systems reflect a variety of life histories. The study of insect opsins in the fruit fly Drosophila melanogaster has led to major advances in the fields of neuroscience, development and evolution. In the last 25 years, research in D. melanogaster has improved our understanding of opsin genotype–phenotype relationships while comparative work in other insects has expanded our understanding of the evolution of insect eyes via gene duplication, coexpression and homologue switching. Even so, until recently, technology and sampling have limited our understanding of the fundamental mechanisms that evolution uses to shape the diversity of insect eyes. With the advent of genome editing and in vitro expression assays, the study of insect opsins is poised to reveal new frontiers in evolutionary biology, visual neuroscience, and animal behaviour. This article is part of the theme issue ‘Understanding colour vision: molecular, physiological, neuronal and behavioural studies in arthropods’.

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“…Ss is expressed in yR7s where it promotes Rh4 expression and yR7 fate, while suppressing Rh3 expression and pR7 fate [30] (figure 1a,c). Ss interacts with a network of transcription factors to regulate R7 subtype fate [31][32][33][34][35][36]. As Ss ON/OFF expression defines R7 subtype fate, we will refer to Rh3-expressing pR7s as Ss OFF R7s and Rh4-expressing yR7s as Ss ON R7s (figure 1a).…”

Section: (A) Regulation Of the Pr7 Versus Yr7 Decisionmentioning

confidence: 99%

“…Key differences lie in the roles of protein-mediated feedback in the final step of fate stabilization. While stochastic ss gene regulation is independent of protein feedback in the fly, transcription network feedback ensures proper expression of Rh4 in ss -expressing R7s [ 14 , 32 ]. In mice, OR feedback is a vital mechanism for OR fate maintenance and OSN maturation, preventing co-expression or fate switching of multiple ORs [ 55 , 70 , 79 , 80 ].…”

Section: A Mechanism For Stochastic Cell Fate Specificationmentioning

confidence: 99%

Transcriptional priming and chromatin regulation during stochastic cell fate specification

Ordway,

Helt,

Johnston

2024

Phil. Trans. R. Soc. B

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Stochastic cell fate specification, in which a cell chooses between two or more fates with a set probability, diversifies cell subtypes in development. Although this is a vital process across species, a common mechanism for these cell fate decisions remains elusive. This review examines two well-characterized stochastic cell fate decisions to identify commonalities between their developmental programmes. In the fly eye, two subtypes of R7 photoreceptors are specified by the stochastic ON/OFF expression of a transcription factor, spineless . In the mouse olfactory system, olfactory sensory neurons (OSNs) randomly select to express one copy of an olfactory receptor (OR) gene out of a pool of 2800 alleles. Despite the differences in these sensory systems, both stochastic fate choices rely on the dynamic interplay between transcriptional priming, chromatin regulation and terminal gene expression. The coupling of transcription and chromatin modifications primes gene loci in undifferentiated neurons, enabling later expression during terminal differentiation. Here, we compare these mechanisms, examine broader implications for gene regulation during development and posit key challenges moving forward. This article is part of a discussion meeting issue ‘Causes and consequences of stochastic processes in development and disease’.

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Interdependent regulation of stereotyped and stochastic photoreceptor fates in the fly eye

Cited by 6 publications

References 36 publications

Deep Diversity: Extensive Variation in the Components of Complex Visual Systems across Animals

Deep Diversity: Extensive Variation in the Components of Complex Visual Systems across Animals

Insect opsins and evo-devo: what have we learned in 25 years?

Transcriptional priming and chromatin regulation during stochastic cell fate specification

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