The other two contrast combinations, where the two points in space change their contrast in opposite directions with one point becoming darker and the other point becoming lighter in either temporal order, are called “reverse-phi” stimuli. Intriguingly, such signals caused the animal to turn in the opposite direction to that predicted by the spatial sequence of contrast change. This 5-FU research buy core result is captured by the sign-correct arithmetic multiplication embedded in the HRC, representing increases in brightness as positive numbers and decreases in brightness as negative
numbers. Multiplying either two positive or two negative numbers produces positively signed outputs and hence the same turning direction, while multiplying numbers of opposite sign produces negatively signed outputs and a turn in the opposite direction ( Figure S1A). Sign-correct multiplication in a single neural computation has long seemed implausible. It has thus been speculated, but never shown, that each sign pairing in the multiplication step might be implemented in a distinct computation
( Hassenstein and Reichardt, 1956 and Reiff et al., 2010). Motion-evoked behaviors BI 2536 datasheet in Drosophila depend on R1–R6 photoreceptors as well as their immediate postsynaptic targets, the lamina monopolar cells L1 and L2 ( Heisenberg and Buchner, 1977, Katsov and Clandinin, 2008, Rister et al., 2007 and Zhu et al., 2009). Recent electrophysiological studies have proposed that changes in contrast polarity are processed through two pathways, one devoted to detecting increases GPX6 in brightness (an “ON” pathway) and the other devoted to detecting decreases in brightness (an “OFF” pathway) ( Joesch et al., 2010 and Reiff et al., 2010). In these studies, blocking synaptic output from L1 or L2 caused the reciprocal loss of responses in a subset of lobula plate tangential
cells (LPTCs) to either light or dark moving edges, respectively ( Joesch et al., 2010). However, the computational mechanism by which this selectivity emerges is unclear. Here we use minimal motion signals in combination with genetic manipulations of the input pathways to the HRC, in vivo calcium imaging, and numerical modeling to examine the computational structure of the HRC with respect to its inputs from L1 and L2. To examine the inputs to the HRC, we constructed an apparatus that would allow us to easily display complex visual stimuli to a stationary fly while monitoring the circuit’s output, the fly’s turning behavior. We allowed the fly to walk in place on a spherical treadmill while its thorax was held in place. We presented each fly with broad-field visual stimuli (Figure S1C) and used the motion of the ball as a measure of the animal’s turning (Figures 1A and 1B; Buchner, 1976 and Seelig et al., 2010).