Nuclei-specific differences in nerve terminal distribution, morphology, and development in mouse visual thalamus

Hammer, Sarah; Carrillo, Gabriela L.; Govindaiah, Gubbi; Monavarfeshani, Aboozar; Bircher, Joseph S; Su, Jianmin; Guido, William; Fox, Michael A.

doi:10.1186/1749-8104-9-16

Cited by 42 publications

(87 citation statements)

References 78 publications

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“…Examination of VGLUT2 immunoreactivity within dLGN allowed for identification of the retinogeniculate axon terminals downstream of the injured optic nerve. Assessment of this immunoreactivity in our sham-injured animals was consistent with previous reports of normal VGLUT2 immunoreactivity by others (El-Danaf et al, 2015; Hammer et al, 2015, 2014). Within sham animals, the distribution of VGLUT2 immunoreactivity occurred in large clusters of variable size, likely composed of multiple axon terminals as they synapse on proximal dendrites of relay neurons.…”

Section: Resultssupporting

confidence: 91%

“…Within sham animals, the distribution of VGLUT2 immunoreactivity occurred in large clusters of variable size, likely composed of multiple axon terminals as they synapse on proximal dendrites of relay neurons. These axon terminal clusters appeared evenly distributed throughout dLGN, a finding consistent with reports on the normal ultrastructure of retinogeniculate synapses upon relay neurons within dLGN (Bickford et al, 2015, 2010; Guido, 2008; Hammer et al, 2015, 2014; Morgan et al, 2016). Comparison of VGLUT2 immunoreactivity in mTBI animals 4 days post-injury to sham demonstrated the persistence of clusters (Figure 1B & D), however, the clusters in dLGN were more widely separated from each other, suggestive of axon terminal loss.…”

Section: Resultssupporting

confidence: 90%

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Adaptive reorganization of retinogeniculate axon terminals in dorsal lateral geniculate nucleus following experimental mild traumatic brain injury

Patel

Jurgens

Krahe

et al. 2017

Experimental Neurology

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The pathologic process in traumatic brain injury marked by delayed axonal loss, known as diffuse axonal injury (DAI), leads to partial deafferentation of neurons downstream of injured axons. This process is linked to persistent visual dysfunction following mild traumatic brain injury (mTBI), however, examination of deafferentation in humans is impossible with current technology. To investigate potential reorganization in the visual system following mTBI, we utilized the central fluid percussion injury (cFPI) mouse model of mTBI. We report that in the optic nerve of adult male C57BL/6J mice, axonal projections of retinal ganglion cells (RGC) to their downstream thalamic target, dorsal lateral geniculate nucleus (dLGN), undergo DAI followed by scattered, widespread axon terminals loss within the dLGN at 4 days post-injury. However, at 10 days post-injury, significant reorganization of RGC axon terminals was found, suggestive of an adaptive neuroplastic response. While these changes persisted at 20 days post-injury, the RGC axon terminal distribution did not recovery fully to sham-injury levels. Our studies also revealed that following DAI, the segregation of axon terminals from ipsilateral and contralateral eye projections remained consistent with normal adult mouse distribution. Lastly, our examination of the shell and core of dLGN suggested that different RGC subpopulations may vary in their susceptibility to injury or in their contribution to reorganization following injury. Collectively, these findings support the premise that subcortical axon terminal reorganization may contribute to recovery following mTBI, and that different neural phenotypes may vary in their contribution to this reorganization despite exposure to the same injury.

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Section: Resultssupporting

confidence: 91%

Section: Resultssupporting

confidence: 90%

Adaptive reorganization of retinogeniculate axon terminals in dorsal lateral geniculate nucleus following experimental mild traumatic brain injury

Patel

Jurgens

Krahe

et al. 2017

Experimental Neurology

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“…Complex RG synapses have been reported in both rodents and higher mammals (Lund and Cunningham, 1972, Jones and Powell, 1969, So et al, 1985, Campbell and Frost, 1987, Guillery and Scott, 1971, Wilson et al, 1984. Similar to the more classical simple RG synapses (which contain a single retinal terminal on a given portion of a relay cell dendrite), these complex RG synapses are absent from other retinorecipient regions of brain (Hammer et al, 2014) ( Figure S1). Since branches of dLGN-projecting RGCs also innervate other retinorecipient nuclei (Dhande et al, 2015), we interpret this to suggest that targetderived signals must be generated in dLGN to pattern the unique transformation of retinal axons into simple and complex RG synapses.…”

Section: Introductionmentioning

confidence: 81%

“…In addition to being segregated based on class, retinal projections in dLGN are unique in that they form structurally and functionally distinct synapses compared to their counterparts in other retinorecipient nuclei (Hammer et al, 2014). Retinal terminals in dLGN are prototypic "driver" inputs which are dramatically large (compared to adjacent non-retinal inputs) and are capable of generating strong excitatory postsynaptic responses in thalamic relay cells.…”

Section: Introductionmentioning

confidence: 99%

LRRTM1 underlies synaptic convergence in visual thalamus

Monavarfeshani

Stanton

Name

et al. 2017

Preprint

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It has long been thought that the mammalian visual system is organized into parallel pathways, with incoming visual signals being parsed in the retina based on feature (e.g. color, contrast and motion) and then transmitted to the brain in unmixed, feature-specific channels. To faithfully convey feature-specific information from retina to cortex, thalamic relay cells must receive inputs from only a small number of functionally similar retinal ganglion cells. However, recent studies challenged this by revealing substantial levels of retinal convergence onto relay cells. Here, we sought to identify mechanisms responsible for the assembly of such convergence. Using an unbiased transcriptomics approach and targeted mutant mice, we discovered a critical role for the synaptic adhesion molecule Leucine Rich Repeat Transmembrane Neuronal 1 (LRRTM1) in the emergence of retinothalamic convergence. Importantly, LRRTM1 mutant mice display impairment in visual behaviors, suggesting a functional role of retinothalamic convergence in vision.

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“…Serial block face scanning electron microscopy. SBFSEM was performed as described previously (Hammer et al 2014;Monavarfeshani et al 2018). Briefly, mice were perfused with 0.1M sodium cacodylate buffer containing 4% PFA and 2.5% glutaraldehyde and immediately 300 µm vibratomed coronal sections were collected.…”

Section: Methodsmentioning

confidence: 99%

Toxoplasmainduces stripping of perisomatic inhibitory synapses

Carrillo

Ballard

Glausen

et al. 2019

Preprint

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words)Infection and inflammation within the brain induces changes in neuronal connectivity and function. The intracellular protozoan parasite, Toxoplasma gondii, is one pathogen that infects the brain and can cause encephalitis and seizures. Persistent infection by this parasite is also associated with behavioral alterations and an increased risk for developing psychiatric illness, including schizophrenia. Current evidence from studies in humans and mouse models suggest that both seizures and schizophrenia result from a loss or dysfunction of inhibitory synapses. In line with this, we recently reported that persistent Toxoplasma gondii infection alters the distribution of glutamic acid decarboxylase 67 (GAD67), an enzyme that catalyzes GABA synthesis in inhibitory synapses. These changes could reflect a redistribution of presynaptic machinery in inhibitory neurons or a loss of inhibitory nerve terminals. To directly assess the latter possibility, we employed serial block face scanning electron microscopy (SBFSEM) and quantified inhibitory perisomatic synapses in neocortex and hippocampus following parasitic infection. Not only did persistent infection lead to a significant loss of perisomatic synapses, it induced the ensheathment of neuronal somata by phagocytic cells. Immunohistochemical, genetic, and ultrastructural analyses revealed that these phagocytic cells included reactive microglia. Finally, ultrastructural analysis identified phagocytic cells enveloping perisomatic nerve terminals, suggesting they may participate in synaptic stripping. Thus, these results suggest that microglia contribute to perisomatic inhibitory synapse loss following parasitic infection and offer a novel mechanism as to how persistent Toxoplasma gondii infection may contribute to both seizures and psychiatric illness.

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Nuclei-specific differences in nerve terminal distribution, morphology, and development in mouse visual thalamus

Cited by 42 publications

References 78 publications

Adaptive reorganization of retinogeniculate axon terminals in dorsal lateral geniculate nucleus following experimental mild traumatic brain injury

Adaptive reorganization of retinogeniculate axon terminals in dorsal lateral geniculate nucleus following experimental mild traumatic brain injury

LRRTM1 underlies synaptic convergence in visual thalamus

Toxoplasmainduces stripping of perisomatic inhibitory synapses

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