Abstract
The ability of locusts to detect looming stimuli and avoid collisions or predators depends on a neuronal circuit in the locust's optic lobe. Although comprehensively studied for over three decades, there are still major questions about the computational steps of this circuit. We used fourth instar larvae of Locusta migratoria to describe the connection between the lobula giant movement detector 1 (LGMD1) neuron in the lobula complex and the upstream neuropil, the medulla. Serial block-face scanning electron microscopy (SBEM) was used to characterize the morphology of the connecting neurons termed trans-medullary afferent (TmA) neurons and their synaptic connectivity. This enabled us to trace neurons over several hundred micrometers between the medulla and the lobula complex while identifying their synapses. We traced two different TmA neurons, each from a different individual, from their synapses with the LGMD in the lobula complex up into the medulla and describe their synaptic relationships. There is not a simple downstream transmission of the signal from a lamina neuron onto these TmA neurons; there is also a feedback loop in place with TmA neurons making outputs as well as receiving inputs. More than one type of neuron shapes the signal of the TmA neurons in the medulla. We found both columnar and trans-columnar neurons connected with the traced TmA neurons in the medulla. These findings indicate that there are computational steps in the medulla that have not been included in models of the neuronal pathway for looming detection.
Highlights
The timely detection of an approaching predator can be critical for the survival of an animal
Identification of the lobula giant movement detector (LGMD) was possible because the lobula giant movement detector 1 (LGMD1) subfield A forms a dendritic arbor that can be clearly recognized in sections of the optic lobe where it appears as a crescent of lightly stained profiles (Figure 1c)
Profiles of trans-medullary afferent (TmA) neurons involved in looming detection are identified by their output synapses onto the LGMD1 (Figure 2a–d,f)
Summary
The timely detection of an approaching predator can be critical for the survival of an animal. There are two giant movement-detecting neurons located in the locust's lobula complex (LOX), the LGMD1, and LGMD2. For both neurons, it is characteristic that conspicuous dendritic arborizations are found in the LOX. Subfield A receives synaptic input from afferent neurons covering almost the visual field of the locust's compound eye (Krapp & Gabbiani, 2005). The inputs to the LGMD1's subfields B and C are both inhibitory and phasic in nature mediated by GABAA release (Gabbiani et al, 2004). The LGMD2 only has one dendritic field where it receives both excitatory and inhibitory input (Rind, 1987; Simmons & Rind, 1997)
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