Neural circuit control of innate behaviors

AbstractIndividuals vary in their innate behaviors, even when they have the same genome and have been reared in the same environment. The extent of individuality in plastic behaviors, like learning, is less well characterized. Also unknown is the extent to which intragenotypic differences in learning generalize: if an individual performs well in one assay, will it perform well in other assays? We investigated this using the fruit fly Drosophila melanogaster, an organism long-used to study the mechanistic basis of learning and memory. We found that isogenic flies, reared in identical lab conditions, and subject to classical conditioning that associated odorants with electric shock, exhibit clear individuality in their learning responses. Flies that performed well when an odor was paired with shock tended to perform well when other odors were paired with shock, or when the original odor was paired with bitter taste. Thus, individuality in learning performance appears to be prominent in isogenic animals reared identically, and individual differences in learning performance generalize across stimulus modalities. Establishing these results in flies opens up the possibility of studying the genetic and neural circuit basis of individual differences in learning in a highly suitable model organism.

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A neural circuit basis for context-modulation of individual locomotor behavior

10.1101/797126 ◽

2019 ◽

Cited By ~ 1

Author(s):

Kyobi Skutt-Kakaria ◽

Pablo Reimers ◽

Timothy A. Currier ◽

Zach Werkhoven ◽

Benjamin L. de Bivort

Keyword(s):

Neural Circuit ◽

Locomotor Behavior ◽

Context Dependence ◽

Central Complex ◽

Ambient Illumination ◽

Behavioral Characteristic ◽

Illumination Changes ◽

Output Neurons ◽

Context Specific ◽

Innate Behaviors

AbstractDefying the cliche that biological variation arises from differences in nature or nurture, genetically identical animals reared in the same environment exhibit striking differences in their behaviors. Innate behaviors can be surprisingly flexible, for example by exhibiting context-dependence. The intersection of behavioral individuality and context-dependence is largely unexplored, particularly at the neural circuit level. Here, we show that individual flies’ tendencies to turn left or right (locomotor handedness) changes when ambient illumination changes. This change is itself a stable individual behavioral characteristic. Silencing output neurons of the central complex (a premotor area that mediates goal-directed navigation) blocks this change. These neurons respond to light with idiosyncratic changes to their baseline calcium levels, and idiosyncratic morphological variation in their presynaptic arbors correlates with idiosyncratic sensory-context-specific turn biases. These findings provide a circuit mechanism by which individual locomotor biases arise and are modulated by sensory context.

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The neuropeptide tachykinin is essential for pheromone detection in a gustatory neural circuit

eLife ◽

10.7554/elife.06914 ◽

2015 ◽

Vol 4 ◽

Cited By ~ 28

Author(s):

Shruti Shankar ◽

Jia Yi Chua ◽

Kah Junn Tan ◽

Meredith EK Calvert ◽

Ruifen Weng ◽

...

Keyword(s):

Neural Circuit ◽

Genetic Manipulation ◽

Physiological State ◽

Sexually Dimorphic ◽

Peptidergic Neurons ◽

Central Brain ◽

Brain Circuit ◽

Male Specific ◽

Innate Behaviors ◽

Aphrodisiac Pheromone

Gustatory pheromones play an essential role in shaping the behavior of many organisms. However, little is known about the processing of taste pheromones in higher order brain centers. Here, we describe a male-specific gustatory circuit in Drosophila that underlies the detection of the anti-aphrodisiac pheromone (3R,11Z,19Z)-3-acetoxy-11,19-octacosadien-1-ol (CH503). Using behavioral analysis, genetic manipulation, and live calcium imaging, we show that Gr68a-expressing neurons on the forelegs of male flies exhibit a sexually dimorphic physiological response to the pheromone and relay information to the central brain via peptidergic neurons. The release of tachykinin from 8 to 10 cells within the subesophageal zone is required for the pheromone-triggered courtship suppression. Taken together, this work describes a neuropeptide-modulated central brain circuit that underlies the programmed behavioral response to a gustatory sex pheromone. These results will allow further examination of the molecular basis by which innate behaviors are modulated by gustatory cues and physiological state.

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