Variable brain wiring through scalable and relative synapse formation in<i>Drosophila</i>

Kiral, Ferdi Rıdvan; Sb, Dutta; Linneweber, Gerit Arne; Poppa, Caroline; Kleist, Max von; Hassan, Bassem A.; Pr, Hiesinger

doi:10.1101/2021.05.12.443860

Cited by 3 publications

(3 citation statements)

References 73 publications

(112 reference statements)

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“…Such variability in response is expected in animals, and is consistent with recent work on the visual response of flies, which demonstrates a link between stochastic (non-heritable) variation in brain wiring within the visual system and strength of visual orientation response to a vertical stripe target (37). Furthermore, flies that experience high temperatures during development appear to exhibit a particularly strong orientation tendency, exhibiting the most direct paths to targets while flies that experience low developmental temperatures exhibit wandering paths to targets (38). In our model such differences can be accounted for by variation in directional tuning of the neural groups, with high directional tuning (low 𝜈) being associated with a strong orientational response, and such individuals exhibiting direct tracks to targets from the outset (see Fig.…”

Section: Experimental Tests Of Our Predictionssupporting

confidence: 87%

The geometry of decision-making

Sridhar

Gorbonos

et al. 2021

Preprint

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Choosing among spatially-distributed options is a central challenge for animals, from deciding among alternative potential food sources or refuges, to choosing with whom to associate. Using an integrated theoretical and experimental approach (employing immersive virtual reality), we consider the interplay between movement and vectorial integration during decision-making regarding two, or more, options in space. In computational models of this process we reveal the occurrence of spontaneous and abrupt "critical" transitions (associated with specific geometrical relationships) whereby organisms spontaneously switch from averaging vectorial information among, to suddenly excluding one, among the remaining options. This bifurcation process repeats until only one option---the one ultimately selected---remains. Thus we predict that the brain repeatedly breaks multi-choice decisions into a series of binary decisions in space-time. Experiments with fruit flies, desert locusts, and larval zebrafish reveal that they exhibit these same bifurcations, demonstrating that across taxa and ecological context, we show that there exist fundamental geometric principles that are essential to explain how, and why, animals move the way they do.

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Section: Experimental Tests Of Our Predictionssupporting

confidence: 87%

The geometry of decision-making

Sridhar

Gorbonos

et al. 2021

Preprint

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“…This variation modifies the arborization of sensory neurons inducing interindividual variability perceiving temperature (Alpert et al, 2020 ; Huang et al, 2020 ). Those temperature changes affect synaptic connectivity in the D. melanogaster visual system, as flies grown at low temperatures (19°C) have more synapse numbers than the ones grown at higher temperatures (25°C) (Kiral et al, 2021 ). Furthermore, phenotypic plasticity in front of temperature variation is not exclusive of drosophilids as other social insects as honey bees show different learning abilities related to labors within the colony depending on the larvae developmental temperature (Tautz et al, 2003 ; Jeanson, 2019 ).…”

Section: Developmental and Growth Conditions Shape Animal Personalitymentioning

confidence: 99%

“…The genetic background of the organism and the developmental history of an individual dramatically affect how the animal will express this individuality (Dall et al, 2004 ; Sih et al, 2004 ; Wolf and Weissing, 2010 ). Although animals of the same species share the same genome, subtle changes during development (i.e., axon guidance) can have severe effects on the final connectivity of the neurons due to stochastic events altering specific behaviors (Linneweber et al, 2020 ; Kiral et al, 2021 ). In addition, environmental factors during growth and epigenetic changes will modify gene expression.…”

Section: Introductionmentioning

confidence: 99%

Behavior Individuality: A Focus on Drosophila melanogaster

Mollá-Albaladejo

Sánchez-Alcañiz

2021

Front. Physiol.

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Among individuals, behavioral differences result from the well-known interplay of nature and nurture. Minute differences in the genetic code can lead to differential gene expression and function, dramatically affecting developmental processes and adult behavior. Environmental factors, epigenetic modifications, and gene expression and function are responsible for generating stochastic behaviors. In the last decade, the advent of high-throughput sequencing has facilitated studying the genetic basis of behavior and individuality. We can now study the genomes of multiple individuals and infer which genetic variations might be responsible for the observed behavior. In addition, the development of high-throughput behavioral paradigms, where multiple isogenic animals can be analyzed in various environmental conditions, has again facilitated the study of the influence of genetic and environmental variations in animal personality. Mainly, Drosophila melanogaster has been the focus of a great effort to understand how inter-individual behavioral differences emerge. The possibility of using large numbers of animals, isogenic populations, and the possibility of modifying neuronal function has made it an ideal model to search for the origins of individuality. In the present review, we will focus on the recent findings that try to shed light on the emergence of individuality with a particular interest in D. melanogaster.

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The geometry of decision-making in individuals and collectives

Sridhar

Gorbonos

et al. 2021

Proc. Natl. Acad. Sci. U.S.A.

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Choosing among spatially distributed options is a central challenge for animals, from deciding among alternative potential food sources or refuges to choosing with whom to associate. Using an integrated theoretical and experimental approach (employing immersive virtual reality), we consider the interplay between movement and vectorial integration during decision-making regarding two, or more, options in space. In computational models of this process, we reveal the occurrence of spontaneous and abrupt “critical” transitions (associated with specific geometrical relationships) whereby organisms spontaneously switch from averaging vectorial information among, to suddenly excluding one among, the remaining options. This bifurcation process repeats until only one option—the one ultimately selected—remains. Thus, we predict that the brain repeatedly breaks multichoice decisions into a series of binary decisions in space–time. Experiments with fruit flies, desert locusts, and larval zebrafish reveal that they exhibit these same bifurcations, demonstrating that across taxa and ecological contexts, there exist fundamental geometric principles that are essential to explain how, and why, animals move the way they do.

show abstract

Variable brain wiring through scalable and relative synapse formation inDrosophila

Cited by 3 publications

References 73 publications

The geometry of decision-making

The geometry of decision-making

Behavior Individuality: A Focus on Drosophila melanogaster

The geometry of decision-making in individuals and collectives

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