Genetic access to neurons in the accessory optic system reveals a role for Sema6A in midbrain circuitry mediating motion perception

Lilley, Brendan N.; Sabbah, Shai; Hunyara, John L.; Gribble, Katherine D.; Al-Khindi, Timour; Xiong, Jiali; Wu, Zhuhao; Berson, David M.; Kolodkin, Alex L.

doi:10.1002/cne.24507

Cited by 25 publications

(27 citation statements)

References 58 publications

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“…Another compelling example for this enrichment is the semaphorin-plexin pathway ( Figure S4 C), which is known to be essential for axon guidance along the visual pathway during development. 24 , 25 , 26 Furthermore, when comparing intrinsic host RGCs and donor RGCs at 1 week post-transplant to newly transplanted day 1 donor RGCs ( Figure S5 A), it is apparent how pathways involved in synaptic plasticity and transmission only become enriched after the initial survival phase and within 1 week of transplant closely match the host. When analyzing whole mounts this observation is matched, as most non-integrated donor cells are cleared or die off within the first week post-transplant, arguing that only donor cells that establish cell-surface signaling or synaptic contact with the host tissue can survive and ultimately integrate.…”

Section: Resultsmentioning

confidence: 99%

Transplantation of miPSC/mESC-derived retinal ganglion cells into healthy and glaucomatous retinas

Oswald

Kegeles

Minelli

et al. 2021

Molecular Therapy - Methods & Clinical Development

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Optic neuropathies, including glaucoma, are a group of neurodegenerative diseases, characterized by the progressive loss of retinal ganglion cells (RGCs), leading to irreversible vision loss. While previous studies demonstrated the potential to replace RGCs with primary neurons from developing mouse retinas, their use is limited clinically. We demonstrate successful transplantation of mouse induced pluripotent stem cell (miPSC)/mouse embryonic stem cell (mESC)-derived RGCs into healthy and glaucomatous mouse retinas, at a success rate exceeding 65% and a donor cell survival window of up to 12 months. Transplanted Thy1-GFP+ RGCs were able to polarize within the host retina and formed axonal processes that followed host axons along the retinal surface and entered the optic nerve head. RNA sequencing of donor RGCs re-isolated from host retinas at 24 h and 1 week post-transplantation showed upregulation of cellular pathways mediating axonal outgrowth, extension, and guidance. Additionally, we provide evidence of subtype-specific diversity within miPSC-derived RGCs prior to transplantation.

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Section: Resultsmentioning

confidence: 99%

Transplantation of miPSC/mESC-derived retinal ganglion cells into healthy and glaucomatous retinas

Oswald

Kegeles

Minelli

et al. 2021

Molecular Therapy - Methods & Clinical Development

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“…To test a potential role of presynaptic mechanisms, we monitored released glutamate using two-photon imaging [10, 12, 29]. We targeted the dendrites of genetically labeled ON DS cells in Pcdh9-Cre mice [30, 31] (Figure S1B) with the glutamate indicator iGluSnFr delivered by adeno-associated virus (AAV) (Figure 2). To estimate the temporal filtering property in the glutamate releases, we used a static flash stimulus that temporally modulates temporal frequency and contrast (“modulating flash”) [29, 32].…”

Section: Resultsmentioning

confidence: 99%

“…Wild-type mice (C57BL/6J) were obtained from Janvier labs. Hoxd10-EGFP [27] and Pcdh9-Cre [30, 31] mice were obtained from Mutant Mouse Research and Resource Centers (strains: STOCK Tg(Hoxd10-EGFP)LT174Gsat/Mmucd and STOCK Tg(Pcdh-9-cre)NP276Gsat/Mmucd) and backcrossed to C57BL/6J mice for more than 5 generations. We used 4- to 16-week-old mice of either sex.…”

Section: Methodsmentioning

confidence: 99%

Spatiotemporally Asymmetric Excitation Supports Mammalian Retinal Motion Sensitivity

2019

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Graphical Abstract Highlights d Space-time wiring between ON DS cells and bipolar cell types was identified d Presynaptic inhibition and Na V channels set the glutamate release dynamics d Preferred direction enhancement supports the tuning to direction and slow speed d Global dendritic summation is involved in computing image motion Authors Akihiro Matsumoto, Kevin L. Briggman, Keisuke Yonehara Correspondence keisuke.yonehara@dandrite.au.dk In BriefMatsumoto et al. find the space-time wiring between the dendrites of ON direction-selective cells and bipolar cell types in the mouse retina. Temporally diverse glutamatergic inputs, which are asymmetrically organized across the dendrites, are globally summated by a preferred direction enhancement mechanism for computing motion speed and direction. SUMMARYThe detection of visual motion is a fundamental function of the visual system. How motion speed and direction are computed together at the cellular level, however, remains largely unknown. Here, we suggest a circuit mechanism by which excitatory inputs to direction-selective ganglion cells in the mouse retina become sensitive to the motion speed and direction of image motion. Electrophysiological, imaging, and connectomic analyses provide evidence that the dendrites of ON direction-selective cells receive spatially offset and asymmetrically filtered glutamatergic inputs along motion-preference axis from asymmetrically wired bipolar and amacrine cell types with distinct release dynamics. A computational model shows that, with this spatiotemporal structure, the input amplitude becomes sensitive to speed and direction by a preferred direction enhancement mechanism. Our results highlight the role of an excitatory mechanism in retinal motion computation by which feature selectivity emerges from non-selective inputs.

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“…Mixed libraries of AAV cap variants were injected into discreet regions of the mouse CNS and variants were selected if they efficiently transported to neuronal cell bodies sending long-range projections to the site of AAV injection 31 . Since its creation, AAV2.retro has been used in mouse and rat models to target a multitude of CNS pathways including the amygdala via the ventral medial hypothalamus 32 , the thalamus via the anterior cingulate cortex 33 , the claustrum via the prefrontal cortex 34 , and more [35][36][37] . Taken together, these studies demonstrate that AAV2.retro is a powerful molecular tool capable of robust retrograde transport enabling the manipulation of neuronal pathways and circuits.…”

Section: Introductionmentioning

confidence: 99%

Intra-striatal AAV2.retro administration leads to extensive retrograde transport in the rhesus macaque brain: implications for disease modeling and therapeutic development

Weiss

Liguore

Domire

et al. 2020

Preprint

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ABSTRACTRecently, AAV2.retro, a new capsid variant capable of efficient retrograde transport in brain, was generated in mice using a directed evolution approach. However, it remains unclear to what degree transport will be recapitulated in the substantially larger and more complex nonhuman primate (NHP) brain. Here, we compared the biodistribution of AAV2.retro with its parent serotype, AAV2, in adult macaques following delivery into the caudate and putamen, brain regions which comprise the striatum. While AAV2 transduction was primarily limited to the injected brain regions, AAV2.retro transduced cells in the striatum and in dozens of cortical and subcortical regions with known striatal afferents. We then evaluated the capability of AAV2.retro to deliver disease-related gene cargo to biologically-relevant NHP brain circuits by packaging a fragment of human mutant HTT, the causative gene mutation in Huntington’s disease. Following intra-striatal delivery, pathological mHTT-positive protein aggregates were distributed widely among cognitive, motor, and limbic cortico-basal ganglia circuits. Together, these studies demonstrate strong retrograde transport of AAV2.retro in NHP brain, highlight its utility in developing novel NHP models of brain disease and suggest its potential for querying circuit function and delivering therapeutic genes in the brain, particularly where treating dysfunctional circuits, versus single brain regions, is warranted.

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Genetic access to neurons in the accessory optic system reveals a role for Sema6A in midbrain circuitry mediating motion perception

Cited by 25 publications

References 58 publications

Transplantation of miPSC/mESC-derived retinal ganglion cells into healthy and glaucomatous retinas

Transplantation of miPSC/mESC-derived retinal ganglion cells into healthy and glaucomatous retinas

Spatiotemporally Asymmetric Excitation Supports Mammalian Retinal Motion Sensitivity

Intra-striatal AAV2.retro administration leads to extensive retrograde transport in the rhesus macaque brain: implications for disease modeling and therapeutic development

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