Difference between revisions of "On-Off Direction-Selective Ganglion Cell"

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[[File:vaney2.png|thumb|right|600px|Diagram showing the response of ON/OFF DSGC to stimulus in the null and preferred direction.  Inputs are multiplied in the preferred direction, and suppressed in the null direction.<ref name = "vaney2011" />]]
 
[[File:vaney2.png|thumb|right|600px|Diagram showing the response of ON/OFF DSGC to stimulus in the null and preferred direction.  Inputs are multiplied in the preferred direction, and suppressed in the null direction.<ref name = "vaney2011" />]]
 
ON/OFF DSGCs act as local motion detectors. If a bright stimulus (e.g., a light) is moving in the direction of the cell's preference, the cell will fire at both the leading and trailing edge. An important contrast is that bright stimuli moving opposite the preferred direction (called the null direction), elicit little or no response <ref name="wiki" />.  The response to stimulus is independent of many stimulus properties, including size, shape, color, and speed.
 
ON/OFF DSGCs act as local motion detectors. If a bright stimulus (e.g., a light) is moving in the direction of the cell's preference, the cell will fire at both the leading and trailing edge. An important contrast is that bright stimuli moving opposite the preferred direction (called the null direction), elicit little or no response <ref name="wiki" />.  The response to stimulus is independent of many stimulus properties, including size, shape, color, and speed.
These cells have a center-surround structure, and the size of the dendrite correlates with the size of the center receptive field <ref name="levick1965" />.   
+
These cells have a center-surround structure, and the size of the dendrite correlates with the size of the center receptive field <ref name="barlow1965" />.   
 
ON/OFF DSGCs can be divided into 4 subtypes differing in their directional preference, ventral, dorsal, nasal, or temporal. The cells of different subtypes also differ in their dendritic structure and synaptic targets in the brain <ref name="kay2011" />.
 
ON/OFF DSGCs can be divided into 4 subtypes differing in their directional preference, ventral, dorsal, nasal, or temporal. The cells of different subtypes also differ in their dendritic structure and synaptic targets in the brain <ref name="kay2011" />.
From the early experiments in the 1960s, it was shown that receptive fields are fairly large, sensitive to small changes, and direction-selective subunits are repeated many times throughout the retina <ref name="levick1965" />.
+
From the early experiments in the 1960s, it was shown that receptive fields are fairly large, sensitive to small changes, and direction-selective subunits are repeated many times throughout the retina <ref name="barlow1965" />.
  
 
[[Image:DSGC_orientation.jpg|thumb|none|300px|Illustration of direction selectivity of four cell subtypes <ref name="Borst2011" />]]
 
[[Image:DSGC_orientation.jpg|thumb|none|300px|Illustration of direction selectivity of four cell subtypes <ref name="Borst2011" />]]

Revision as of 15:05, 1 May 2012

File:Onoffdsgc.png
Reconstructed by Omni Desktop from Helmstaedter's skeleton[1]

Direction selective (DS) cells in the retina are neurons that respond differentially to the direction of a visual stimulus. The term is used to describe a group of neurons that preferrentially "gives a vigorous discharge of impulses when a (bright) stimulus object is moved through its receptive field in one direction" [2]. There are three known types of DS cells in the vertebrate retina of the mouse, ON/OFF DS ganglion cells, ON DS Ganglion Cells (which respond to the leading edge of a bright stimulus) and OFF DS Ganglion Cells (which respond only to the trailing edge of a bright stimulus). Each has a distinctive physiology and anatomy[3]. The rest of this page will only apply to ON/OFF DS Ganglion Cells.

Physiology

File:Vaney2.png
Diagram showing the response of ON/OFF DSGC to stimulus in the null and preferred direction. Inputs are multiplied in the preferred direction, and suppressed in the null direction.[4]

ON/OFF DSGCs act as local motion detectors. If a bright stimulus (e.g., a light) is moving in the direction of the cell's preference, the cell will fire at both the leading and trailing edge. An important contrast is that bright stimuli moving opposite the preferred direction (called the null direction), elicit little or no response [3]. The response to stimulus is independent of many stimulus properties, including size, shape, color, and speed. These cells have a center-surround structure, and the size of the dendrite correlates with the size of the center receptive field [2]. ON/OFF DSGCs can be divided into 4 subtypes differing in their directional preference, ventral, dorsal, nasal, or temporal. The cells of different subtypes also differ in their dendritic structure and synaptic targets in the brain [5]. From the early experiments in the 1960s, it was shown that receptive fields are fairly large, sensitive to small changes, and direction-selective subunits are repeated many times throughout the retina [2].

File:DSGC orientation.jpg
Illustration of direction selectivity of four cell subtypes [6]

Anatomy

The anatomy of ON/OFF cells is such that the dendrites extend to two sublaminae of the inner plexiform layer and make synapses with bipolar and amacrine cells. They have four subtypes, each with own preference for direction. Each subtype of ON/OFF DSGCs has differences in dendritic patterns and axonal projections to the brain. These differences indicate that outputs from different subtypes may wire to different parts of the brain [5].

The colored objects in panel a are six DSGCs reconstructed by the researchers. The circles are representations of the cell bodies, and the lines are "skeletons" of the dendrites. Each DSGC is said to be "bistratified," which means that its dendrites branch out in two sublayers ("strata") of the IPL. The total number of strata in the IPL is estimated to be around ten. A view of the bottom of the sandwich (panel b) shows the branching of the DSGC dendrites.

Reconstructed ganglion and amacrine cells.

Location

Shape

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Image of an On-Off Direction-Selective Ganglion Cell[7].

Connections

File:DSGC Brigmann.jpg
Cells and synapses reconstructed from serial block face electron microscopy data. A single starburst amacrine cell (yellow, note synaptic varicosities) and two direction-selective ganglion cells (green). Even though there is substantial dendritic overlap with both cells, all connections (magenta) go to the right ganglion cell. ©Kevin Briggman. New microscope decodes complex eye circuitry: Retinal ganglion cells can recognise directions thanks to amacrine cells[1]


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Connections to SAC

Molecules

As described above, ON/OFF DS ganglion cells can be divided into 4 subtypes differing in their directional preference, ventral, dorsal, nasal, or temporal. Recent research has identified markers for distinguishing between the different subtypes, and for separating ON/OFF DSGCs from other retinal ganglion cells. These markers are independent of experience, and suggest a method for how these cells obtain different inputs [5].


Recent research has lead to the development of transgenic mouse lines that selectively mark ON/OFF DSGCs that prefer ventral or nasal motion and another line that marks ventral and dorsal preferring DSGCs. These lines were used to identify cell surface molecules (including Cadherin 6, CollagenXXV1, and Matrix metalloprotease 17), that allow each of the four types of ON/OFF DSGCs to be differentiated. A neuropeptide, CART (cocaine and amphetamine regulated transcript) has been found to differentiate ON/OFF DSGCs from all other retinal ganglion cells. Strikingly, these patterns of molecular differentiation occur before animal eye-opening, and demonstrate that these differences are experience-independent. Therefore, the molecular differences may help to explain the differing functionality between subtypes [5].

Figure showing how ON/OFF DSGCs can be distinguished from other RGCs. As described in the text, this is accomplished using CART; a careful morphological analysis confirms that this marker correctly identifies the ON/OFF DSGCs with no false positives. [5]

Models

The firing pattern of On-Off Direction-Selective Ganglion cells is time-dependent and is supported by the Reichardt- Hassenstain model, which detects spatiotemporal correlation between two adjacent cells [3].

File:Reichardt model.png
Graphic explaining the Reichardt-Hassenstain model [3]

As applied to the visual system, this model considers the processed stimulus(i.e., light) inputs to two adjacent cells. After a time delay, each delayed input is multiplied by the original signal from the other cell. The resulting signals are subtracted, and the positive outcome indicates the preferred direction [3].

This behavior was validated in the visual system using calcium imaging in the fly [8]. However, this model correspondence has only been completed at a high-level (input-output), rather than at an anatomical or physiological level (Borst, Alexander, and Thomas Euler. “Seeing Things in Motion: Models, Circuits, and Mechanisms.” Neuron 71.6 (2011) : 974-994.).

History

Direction Selective units were first explored in cats by Hubel and Wiesel in 1959. Levick and Barlow performed many of the seminal early experiments related to direction selectivity during the 1960s using rabbit retina [2]. In these experiments, they measured action potentials generated from a black-white grating with a small slit [3]. Many additional experiments have been performed during the past fifty years in organisms as diverse as the turtle (e.g., Marchiafava 1979) and the mouse (Briggman 2011).

Open questions / status / relevance to eyewire

Cells will be available for tracing in Eyewire, although these cells are not currently available (March 2012). See http://wiki.eyewire.org/wiki/E2198

Reading List

K. L. Briggman, M. Helmstaedter, and W. Denk, €œWiring specificity in the direction-selectivity circuit of the retina., Nature, vol. 471, no. 7337, pp. 183-8, Mar. 2011.

A. Borst and T. Euler, €œReview Seeing Things in Motion : Models, Circuits and Mechanisms,€ Neuron, vol. 71, no. 6, pp. 974-994, 2011.

D. I. Vaney, B. Sivyer, and W. R. Taylor, Direction selectivity in the retina: symmetry and asymmetry in structure and function,€ Nature reviews. Neuroscience, vol. 13, no. 3, pp. 194-208, Jan. 2012.

W. R. Levick and H. B. Barlow, €œThe Mechanism of Directionally Selective Units in Rabbit's Retina, pp. 477-504, 1965.

References

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  3. 3.0 3.1 3.2 3.3 3.4 3.5 "Motion Sensing in Vision." Wikipedia, The Free Encyclopedia, http://en.wikipedia.org/wiki/Motion_Sensing_in_Vision (Accessed April 02, 2012).
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