Category Archives: Retinal Circuitry

Uncovering the electrical synapse proteome in retinal neurons via in vivo proximity labeling

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We have a new paper out in eLife: Uncovering the electrical synapse proteome in retinal neurons via in vivo proximity labeling.

Authors: Stephan Tetenborg, Eyad Shihabeddin, Elizebeth Olive Akansha Manoj Kumar, Crystal Sigulinsky @csigulinsky.bsky.social, Karin Dedek, Ya-Ping Lin, Fabio Echeverry, Hannah Hoff, Alberto Pereda, Bryan William Jones @bwjones.bsky.social, Christophe Ribelayga, Klaus Ebnet, Ken Matsuura, John O’Brien

Abstract: Electrical synapses containing Connexin 36 (Cx36) represent the main means for direct electrical communication among neurons in the mammalian nervous system. However, little is known about the protein complexes that constitute these synapses. In the present study, we applied different BioID strategies to screen the interactomes of Connexin 36 and its zebrafish orthologue Cx35b in retinal neurons. For in vivo proximity labeling in mice, we took advantage of the Cx36-EGFP strain and expressed a GFP-nanobody-TurboID fusion construct selectively in AII amacrine cells. For in vivo BioID in zebrafish, we generated a transgenic line expressing a Cx35b-TurboID fusion under control of the Cx35b promoter. Both strategies allowed us to capture a plethora of molecules that were associated with electrical synapses and showed a high degree of evolutionary conservation in the proteomes of both species. Besides known interactors of Cx36 such as ZO-1 and ZO-2 we have identified more than 50 new proteins, such as scaffold proteins, adhesion molecules and regulators of the cytoskeleton. Moreover, we determined the subcellular localization of these proteins in mouse retina and tested potential binding interactions with Cx36. Amongst these new interactors, we identified signal induced proliferation associated 1 like 3 (Sipa1l3), a protein that has been implicated in cell junction formation and cell polarity, as a new scaffold of electrical synapses. Interestingly, Sipa1l3 was able to interact with ZO-1, ZO-2 and Cx36, suggesting a pivotal role in electrical synapse function. In summary, our study provides the first detailed view of the electrical synapse proteome in retinal neurons, which is likely to apply to electrical synapses elsewhere.

Uncovering The Electrical Synapse Proteome In Retinal Neurons Via In Vivo Proximity Labeling

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We have a new paper out In BioRxiv, Uncovering The Electrical Synapse Proteome In Retinal Neurons Via In Vivo Proximity Labeling.

Authors: Stephan Tetenborg, Eyad Shihabeddin, Elizebeth Olive Akansha Manoj Kumar, Crystal Sigulinsky @csigulinsky.bsky.social, Karin Dedek, Ya-Ping Lin, Fabio Echeverry, Hannah Hoff, Alberto Pereda, Bryan William Jones @bwjones.bsky.social, Christophe Ribelayga, Klaus Ebnet, Ken Matsuura, John O’Brien

Abstract: Through decades of research, we have gained a comprehensive understanding of the protein complexes underlying function and regulation of chemical synapses in the nervous system. Despite the identification of key molecules such as ZO-1 or CaMKII, we currently lack a similar level of insight into the electrical synapse proteome. With the advancement of BioID as a tool for in vivo proteomics, it has become possible to identify complex interactomes of a given protein of interest by combining enzymatic biotinylation with subsequent streptavidin affinity capture. In the present study, we applied different BioID strategies to screen the interactomes of Connexin 36 (mouse) the major neuronal connexin and its zebrafish orthologue Cx35b in retinal neurons. For in vivo proximity labeling in mice, we took advantage of the Cx36-EGFP strain and expressed a GFP-nanobody-TurboID fusion construct selectively in AII amacrine cells. For in vivo BioID in
zebrafish, we generated a transgenic line expressing a Cx35b-TurboID fusion under control of the Cx35b promoter. Both two strategies allowed us to capture a plethora of molecules that were associated with electrical synapses and showed a high degree of evolutionary conservation in the proteomes of both species. Besides known interactors of Cx36 such as ZO-1 and ZO-2 we have identified more than 50 new proteins, such as scaffold proteins, adhesion molecules and regulators of the cytoskeleton. We further determined the subcellular localization of these proteins in AII amacrine and tested potential binding interactions with Cx36. Of note, we identified signal induced proliferation associated 1 like 3 (SIPA1L3), a protein that has been implicated in cell junction formation and cell polarity as a new scaffold of electrical synapses. Interestingly, SIPA1L3 was able to interact with ZO-1, ZO-2 and Cx36, suggesting a pivotal role in electrical synapse function. In summary, our study provides a first detailed view of the electrical synapse proteome in retinal neurons.

Retinal Connectomics: A Review

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We have a new manuscript out of the lab in Volume 10 of the Annual Review of Vision Science titled Retinal Connectomics: A Review by Crystal L. Sigulinsky, Rebecca L. Pfeiffer, and Bryan William Jones. A .pdf is here.

Abstract
The retina is an ideal model for understanding the fundamental rules for
how neural networks are constructed. The compact neural networks of
the retina perform all of the initial processing of visual information be-
fore transmission to higher visual centers in the brain. The field of retinal
connectomics uses high-resolution electron microscopy datasets to map
the intricate organization of these networks and further our understand-
ing of how these computations are performed by revealing the fundamental
topologies and allowable networks behind retinal computations. In this ar-
ticle, we review some of the notable advances that retinal connectomics
has provided in our understanding of the specific cells and the organi-
zation of their connectivities within the retina, as well as how these are
shaped in development and break down in disease. Using these anatomi-
cal maps to inform modeling has been, and will continue to be, instrumental
in understanding how the retina processes visual signals.

Preprint: Neural Circuit Revision in Retinal Remodeling, A Pathoconnectomics Approach

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We have a new preprint out, Neural Circuit Revision in Retinal Remodeling, A Pathoconnectomics Approach.

Authors: Rebecca L Pfeiffer, Jeebika Dahal, Crystal L Sigulinsky, James R Anderson, Isabel A Barrera, Jia-Hui Yang, Olivia Haddadin, Alexis R Houser, Jessica C Garcia, Bryan William Jones

Abstract: The Aii glycinergic amacrine cell (Aii) plays a central role in bridging rod pathways with cone pathways, enabling an increased dynamic range of vision from scotopic to photopic ranges. The Aii integrates scotopic signals via chemical synapses from rod bipolar cells (RodBCs) onto the arboreal processes of Aii ACs, injecting signals into ON-cone bipolar cells (CBbs) via gap junctions with Aiis on the arboreal processes and the waist of the Aii ACs. The CBbs then carry this information to ON and OFF ganglion cell classes. In addition, the Aii is involved in the surround inhibition of OFF cone bipolar cells (CBas) through glycinergic chemical synapses from Aii ACs onto CBas. We have previously shown changes in RodBC connectivity as a consequence of rod photoreceptor degeneration in a pathoconnectome of early retinal degeneration: RPC1. Here, we evaluated the impact of rod photoreceptor degeneration on the connectivity of the Aii to determine the impacts of photoreceptor degeneration on the downstream network of the neural retina and its suitability for integrating therapeutic interventions as rod photoreceptors are lost. Previously, we reported that in early retinal degeneration, prior to photoreceptor cell loss, Rod BCs make pathological gap junctions with Aiis. Here, we further characterize this altered connectivity and additional shifts in both the excitatory drive and gap junctional coupling of Aiis in retinal degeneration, along with discussion of the broader impact of altered connectivity networks. New findings reported here demonstrate that Aiis make additional gap junctions with CBas increasing the number of BC classes that make pathological gap junctional connectivity with Aiis in degenerating retina. In this study, we also report that the Aii, a tertiary retinal neuron alters their synaptic contacts early in photoreceptor degeneration, indicating that rewiring occurs in more distant members of the retinal network earlier in degeneration than was previously predicted. This rewiring impacts retinal processing, presumably acuity, and ultimately its ability to support therapeutics designed to restore image-forming vision. Finally, these Aii alterations may be the cellular network level finding that explains one of the first clinical complaints from human patients with retinal degenerative disease, an inability to adapt back and forth from photopic to scotopic conditions.

UCI Center For Translational Vision Research Talk on Retinal Connectomics and Pathoconnectomics

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Impact of Retinal Degeneration on Response of ON and OFF Cone Bipolar Cells to Electrical Stimulation

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We have a new manuscript from the lab in IEEE, Impact of Retinal Degeneration on Response of ON and OFF Cone Bipolar Cells to Electrical Stimulation. This manuscript is in collaboration with the Lazzi lab out of USC.  The first author, Shayan Farzad, Pragya Kosta, Ege Iseri, Steven T Walston, Jean-Marie C. Bouteiller,  Rebecca L. Pfeiffer @BeccaPfeiffer19, Crystal L. Sigulinsky @CSigulinsky, Jia-Hui Yang, Jessica C. Garcia, James R. Anderson, Bryan W. Jones @BWJones, and Gianluca Lazzi. The PDF is here.

Abstract: In retinal degenerative diseases, such as retinitis pigmentosa (RP) and age-related macular degeneration (AMD), the photoreceptors become stressed and start to degenerate in the early stages of the disease. Retinal prosthetic devices have been developed to restore vision in patients by applying electrical stimulation to the surviving retinal cells. However, these devices provide limited visual perception as the therapeutic interventions are generally considered in the later stages of the disease when only inner retinal layer cells are left. A potential treatment option for retinal degenerative diseases in the early stages can be stimulating bipolar cells, which receive presynaptic signals from photoreceptors. In this work, we constructed computational models of healthy and degenerated (both ON and OFF-type) cone bipolar cells (CBCs) with realistic morphologies extracted from connectomes of the healthy and early-stage degenerated rabbit retina. We examined these cells’ membrane potential and axon terminal calcium current differences when subjected to electrical stimulation. In addition, we investigated how differently healthy and degenerated cells behave with respect to various stimulation parameters, including pulse duration and cells’ distance from the stimulating electrode. The results suggested that regardless of the position of the OFF CBCs in the retina model, there is not a significant difference between the membrane potential of healthy and degenerate cells when electrically stimulated. However, the healthy ON CBC axon terminal membrane potential rising time-constant is shorter (0.29 ± 0.03 ms) than the degenerated cells (0.8 ± 0.07 ms). Moreover, the ionic calcium channels at the axon terminals of the cells have a higher concentration and higher current in degenerated cells (32.24 ± 6.12 pA) than the healthy cells (13.64 ± 2.88 pA) independently of the cell’s position.

Müller Cell Connectomics In Health And Disease

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This talk was presented today, April 25th at the 2023 Association for Research in Vision and Opthalmology (ARVO) meetings in New Orleans, Louisiana by Rebecca Pfeiffer as part of an ARVO Minisymposium Bryan William Jones organized.

Abstract: Muller cells are a critical component of retinal function and rapidly change metabolically and morphologically in retinal disease. Of Muller cell functions, many require close physical relationships between the Muller cell and the synapses of the neurons they support. Despite this required neuro-glial relationship, little is known about the direct contacts between Muller cells and synapses in healthy or diseased retinas. In order to address this, I use a connectomics/pathoconnectomics approach to reconstruct Muller cells and their neighboring synapses. The retinas evaluated are from a healthy rabbit, retinal connectome 1 (RC1), and from the P347L rabbit model of retinitis pigmentosa, retinal pathoconnectome 1 (RPC1). Preliminary data demonstrate an increase in endfoot entanglement in RPC1 when compared with RC1, and direct synaptic contact analysis of both connectomes is ongoing.

Species-Specific Connectivity In The Aii Connectome

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This talk was presented today, April 25th at the 2023 Association for Research in Vision and Opthalmology (ARVO) meetings in New Orleans, Louisiana by Crystal Sigulinsky as part of an ARVO Minisymposium organized by Bryan William Jones.

Abstract: Biomedical research relies heavily on animal models to study human disease and develop therapeutics. Understanding the architectural diversity in neural networks between humans and these model species is essential for choosing a relevant study model and interpreting conflicting results. Using comparative connectomics, we sought to map and compare the local neural network architecture of rabbit and mouse retinal Aii amacrine cells. This specialized narrow-field, multistratified, glycinergic interneuron has critical feedforward and feedback roles in both the photopic and scotopic retinal networks spanning the ON and OFF pathways, making it an ideal candidate for investigating species-specific differences in retinal networks. High-resolution, serial-section transmission electron microscopy (TEM) volumes of rabbit (RC1: female, 13- month, Dutch Belted) and mouse (RC2: female, 5-month, C57BL/6J) retinal tissue provided spatially-registered synaptic maps of Aii connectivity at directly comparable resolution and completeness. These reveal that despite species-specific morphologies, gross synaptology and compartmentalization appear conserved. Yet, rabbit and mouse Aii cells diverge in the weighting of their partnerships, most notably in their coupling profiles. Opposing biases in gap junction partnerships and their respective sizing rules indicate a greater relative output by mouse Aii cells to ON pathways than in rabbit. However, a unique topological conformation for a subset of conventional presynapses formed by Aii cell lobular dendrites with species-specific features and prevalence may influence signal output to specific partner classes within the OFF pathway and either nullify or exacerbate this difference in ON/OFF output. Additionally, rabbit Aii cells in RC1 showed greater Aii-Aii coupling than in mouse, which may suggest greater signal-to-noise compensation. Lastly, preliminary data suggest mouse Aii cells receive greater excitatory, but not inhibitory input/feedback from the OFF pathway than in rabbit. Together these data indicate that precise neural circuit architectures diverge between species and require detailed, comprehensive mapping to begin to dissect potential influence on signal flow.

Structural Motifs Of Excitatory Synapses In The Mammalian Retina

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This abstract was presented today, April 24th at the 2023 Association for Research in Vision and Opthalmology (ARVO) meetings in New Orleans, Louisiana by Taylor Otterness, Crystal Sigulinsky, James Anderson, and Bryan William Jones.

Full resolution version here.

Purpose
Connectivity within the nervous system is precise and disruptions lead to degraded performance and disease, yet the rules that govern connectivity remain unknown. Recent efforts reveal that different types of cone bipolar cells in the neural retina show preferences in the selection and frequency of presynaptic structure types used for signal transmission. However, it is not yet known how these differences are related to the quantity or type of postsynaptic partner. We used Retinal Connectome 1 (RC1) to analyze the synaptic output of rabbit CBb6 cells, a type of ON cone bipolar cell that forms excitatory synapses via diverse presynaptic structure types, to identify patterns in how these cells interact with their postsynaptic partners.

Methods
RC1 is a 0.25 mm diameter volume sampled from mid-peripheral retina of a 13 month old female Dutch-Belted rabbit, serially sectioned at 70 nm, and imaged at ultrastructural resolution (2nm/px) using transmission electron microscopy. Postsynaptic partners of CBb6 cell 6156’s presynaptic structures were annotated using the Viking Viewer for Connectomics. Statistical analyses were conducted in Microsoft Excel and investigated further with 3D rendering and graph visualization of connectivity.

Results
The factors tracked for comparison included presynaptic structure type, target number, and postsynaptic partner type. Multiribbon synapses of CBb6 cell 6156 trended towards having a greater number of output partners, with a greater proportion of dyads than monads. Despite this, triads and quadrads were only found opposing single ribbon synapses. As the different presynaptic structure types may differ in the strength of neurotransmitter release (ribbonless < single ribbon < multiribbon), these findings are inconsistent with scaling of output to the number of postsynaptic targets. Both amacrine cells (AC) and ganglion cells (GC) are postsynaptic partners of 6156. However, single ribbon and ribbonless structures appear biased towards AC only targets, while multiribbon synapses appear biased toward mixed AC and GC targets.

Conclusions
Target type relationships appear more important than the number of targets in determining presynaptic structure type in CBb6. Future efforts will examine size differences of postsynaptic structures and presynaptic ribbon size, and even compare across bipolar cell classes, in order to provide further insight on the connectivity rules underlying excitatory synapses.

Distinctive Synaptic Structural Motifs Link Excitatory Retinal Interneurons To Diverse Postsynaptic Partner Types

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We have a new manuscript from the lab in Cell Reports, Distinctive Synaptic Structural Motifs Link Excitatory Retinal Interneurons To Diverse Postsynaptic Partner Types. This manuscript is in collaboration with the first author, Wan-Qing Yu @wanqing_yu, then co-authors Rachael Swanstrom, Crystal L. Sigulinsky @CSigulinsky, Richard M. Ahlquist, along with Sharm Knecht, myself Bryan W. Jones @BWJonesDavid M. Berson, and Rachel O. Wong. The PDF is here.

Abstract:
Neurons make converging and diverging synaptic connections with distinct partner types. Whether synapses involving separate partners demonstrate similar or distinct structural motifs is not yet well understood. We thus used serial electron microscopy in mouse retina to map output synapses of cone bipolar cells (CBCs) and compare their structural arrangements across bipolar types and postsynaptic partners. Three presynaptic configurations emerge—single-ribbon, ribbonless, and multiribbon synapses. Each CBC type exploits these arrangements in a unique combination, a feature also found among rabbit ON CBCs. Though most synapses are dyads, monads and triads are also seen. Altogether, mouse CBCs exhibit at least six motifs, and each CBC type uses these in a stereotypic pattern. Moreover, synapses between CBCs and particular partner types appear biased toward certain motifs. Our observations reveal synaptic strategies that diversify the output within and across CBC types, potentially shaping the distinct functions of retinal microcircuits.