Phototactic personality in fruit flies and its suppression by serotonin and
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Kain, Jamey; Stokes, Chris R.; Bivort, Benjamin L. de

doi:10.1073/pnas.1211988109

Cited by 157 publications

(231 citation statements)

References 32 publications

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“…The pairwise transition rates between clusters appeared to be idiosyncratic as well. These findings are consistent with behavioral individuality in Drosophila phototaxis (Kain et al 2012), locomotor handedness (Buchanan et al 2015) and thermal preference . However, the clear evidence of individuality in PCA 20 -GMM-SW cluster abundance distributions is notable when compared to the lack of signal of such individuality in the supervised classification results of Kain et al (2013).…”

Section: Discussionsupporting

confidence: 85%

Systematic exploration of unsupervised methods for mapping behavior

Todd

Kain²,

Bivort

2017

Phys. Biol.

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To fully understand the mechanisms giving rise to behavior, we need to be able to precisely measure it. When coupled with large behavioral data sets, unsupervised clustering methods offer the potential of unbiased mapping of behavioral spaces. However, unsupervised techniques to map behavioral spaces are in their infancy, and there have been few systematic considerations of all the methodological options. We compared the performance of seven distinct mapping methods in clustering a wavelettransformed data set consisting of the x-and y-positions of the six legs of individual flies. Legs were automatically tracked by small pieces of fluorescent dye, while the fly was tethered and walking on an air-suspended ball. We find that there is considerable variation in the performance of these mapping methods, and that better performance is attained when clustering is done in higher dimensional spaces (which are otherwise less preferable because they are hard to visualize). High dimensionality means that some algorithms, including the non-parametric watershed cluster assignment algorithm, cannot be used. We developed an alternative watershed algorithm which can be used in high-dimensional spaces when a probability density estimate can be computed directly. With these tools in hand, we examined the behavioral space of fly leg postural dynamics and locomotion. We find a striking division of behavior into modes involving the fore legs and modes involving the hind legs, with few direct transitions between them. By computing behavioral clusters using the data from all flies simultaneously, we show that this division appears to be common to all flies. We also identify individual-to-individual differences in behavior and behavioral transitions. Lastly, we suggest a computational pipeline that can achieve satisfactory levels of performance without the taxing computational demands of a systematic combinatorial approach.

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Section: Discussionsupporting

confidence: 85%

Systematic exploration of unsupervised methods for mapping behavior

Todd

Kain²,

Bivort

2017

Phys. Biol.

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“…We measured the turn biases of hundreds of individual flies from seven different fly lines: Berlin-K (BK), Canton-S (CS), Cambridge-A (CA) (19), two lines of CS that were independently inbred for 10 generations, CA that was inbred for 10 generations (19), and w 1118 , the background line for many transgenic flies ( Fig. 1 E and F and Fig.…”

Section: Resultsmentioning

confidence: 99%

“…We examined whether disrupting the CC can alter a population's distribution of turn bias scores. First, we tested seven mutants that perturb central complex development and morphology (19). Of these, no-bridge, centralcomplex-deranged, and central-body-defect (cbd KS96 ) showed a significant increase in individual variation in turning compared with heterozygous controls (Fig.…”

Section: Resultsmentioning

confidence: 99%

Neuronal control of locomotor handedness in Drosophila

Buchanan¹,

Kain²,

Bivort

2015

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

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184

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Genetically identical individuals display variability in their physiology, morphology, and behaviors, even when reared in essentially identical environments, but there is little mechanistic understanding of the basis of such variation. Here, we investigated whether Drosophila melanogaster displays individual-toindividual variation in locomotor behaviors. We developed a new high-throughout platform capable of measuring the exploratory behavior of hundreds of individual flies simultaneously. With this approach, we find that, during exploratory walking, individual flies exhibit significant bias in their left vs. right locomotor choices, with some flies being strongly left biased or right biased. This idiosyncrasy was present in all genotypes examined, including wild-derived populations and inbred isogenic laboratory strains. The biases of individual flies persist for their lifetime and are nonheritable: i.e., mating two left-biased individuals does not yield left-biased progeny. This locomotor handedness is uncorrelated with other asymmetries, such as the handedness of gut twisting, leg-length asymmetry, and wing-folding preference. Using transgenics and mutants, we find that the magnitude of locomotor handedness is under the control of columnar neurons within the central complex, a brain region implicated in motor planning and execution. When these neurons are silenced, exploratory laterality increases, with more extreme leftiness and rightiness. This observation intriguingly implies that the brain may be able to dynamically regulate behavioral individuality.behavior | individuality | personality | circuit mapping | central complex H and dominance-better performance using either the left or right hand-is a familiar human trait, moderately heritable (1), and regulated by many genes (2), including those involved in general body symmetry (3). However, behavioral handedness in general, i.e., the preferential performance of a behavior on one side of the body or with a particular chiral twist, is a multifaceted phenomenon. For example, in the absence of visual feedback, people display clockwise or counterclockwise biases in their walking behavior (4). This "locomotor handedness" is uncorrelated to hand dominance or gross morphological asymmetry and instead may be due to asymmetries in the collection and processing of sensory information, resulting in individual locomotor biases with a neurological basis (4, 5).Handed behavioral tendencies specific to individuals are also prevalent throughout the animal kingdom and have been shown in species as disparate as mice (paw use) (6), octopi (eye use) (7), and tortoises (side rolled on during righting) (8). There is also evidence that, at the population mean level, some species of insects have handed behaviors and asymmetric neurophysiological patterns (9). However, there has been little investigation of the differences in handed behaviors among individuals of the same insect species, and the mechanisms by which asymmetries are instilled in behavior are unknown. Considering beha...

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“…In medical genetics, many diseased states emerge beyond a phenotypic threshold, and high variability genotypes will produce a larger proportion of individuals exceeding that threshold than low variability genotypes, even if each genotypic class has the same mean. Although intragenotypic variability has been discussed in animal behavior, particularly in the context of the emergence of personality (10,17),…”

mentioning

confidence: 99%

Behavioral idiosyncrasy reveals genetic control of phenotypic variability

Ayroles

Buchanan²,

O’Leary

et al. 2015

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

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178

207

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Quantitative genetics has primarily focused on describing genetic effects on trait means and largely ignored the effect of alternative alleles on trait variability, potentially missing an important axis of genetic variation contributing to phenotypic differences among individuals. To study the genetic effects on individual-to-individual phenotypic variability (or intragenotypic variability), we used Drosophila inbred lines and measured the spontaneous locomotor behavior of flies walking individually in Y-shaped mazes, focusing on variability in locomotor handedness, an assay optimized to measure variability. We discovered that some lines had consistently high levels of intragenotypic variability among individuals, whereas lines with low variability behaved as although they tossed a coin at each left/right turn decision. We demonstrate that the degree of variability is itself heritable. Using a genome-wide association study (GWAS) for the degree of intragenotypic variability as the phenotype across lines, we identified several genes expressed in the brain that affect variability in handedness without affecting the mean. One of these genes, Ten-a, implicates a neuropil in the central complex of the fly brain as influencing the magnitude of behavioral variability, a brain region involved in sensory integration and locomotor coordination. We validated these results using genetic deficiencies, null alleles, and inducible RNAi transgenes. Our study reveals the constellation of phenotypes that can arise from a single genotype and shows that different genetic backgrounds differ dramatically in their propensity for phenotypic variabililty. Because traditional mean-focused GWASs ignore the contribution of variability to overall phenotypic variation, current methods may miss important links between genotype and phenotype.variability | variance QTL | DGRP | ten-a | personality

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Phototactic personality in fruit flies and its suppression by serotonin and white

Cited by 157 publications

References 32 publications

Systematic exploration of unsupervised methods for mapping behavior

Systematic exploration of unsupervised methods for mapping behavior

Neuronal control of locomotor handedness in Drosophila

Behavioral idiosyncrasy reveals genetic control of phenotypic variability

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