Sushi domain-containing protein 4 controls synaptic plasticity and motor learning

González-Calvo, Inés; Iyer, Keerthana; Carquin, Mélanie; Khayachi, Anouar; Giuliani, Fernando; Sigoillot, Séverine M.; Vincent, J.D.; Séveno, Martial; Veleanu, Maxime; Tahraoui, Sylvana; Albert, Mélanie; Vigy, Oana; Bosso-Lefèvre, Célia; Nadjar, Yann; Dumoulin, Andréa; Triller, Antoine; Bessereau, Jean-Louis; Rondi-Reig, Laure; Isope, Philippe; Selimi, Fekrije

doi:10.7554/elife.65712

Cited by 15 publications

(18 citation statements)

References 105 publications

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“…Most of the constructs, including Igsf9, Pdx1 and Susd4 (that have previously been shown to drive IO-specific transgene expression when used in cre-transgenic animals) drove stronger overall expression in the regions surrounding the IO ( Figure 1C , datapoints to the right of the vertical dashed line). Notably, GFP-expressing IO cells were seen densely labeled in limited region of the dorsomedial IO (2 out of 4 mice, subnucleus IO-Be, see arrow in Figure 1A2 ) with the Susd4-promoter (González-Calvo et al, 2021 ), but the expression was seen only sparsely within the other IO subnuclei.…”

Section: Resultsmentioning

confidence: 99%

“…The longest version of the Htr5b-promoter that we previously judged as having the strongest tropism for IO over the surrounding structures ( Figure 1 ) also resulted in the cleanest neuron-specificity (neuron/astrocyte ratio for Htr5b(3.7) promoter: +40 ± 9.8%, n = 79 cells; for all values, see Table 1 ). Notably, even though Susd4, Pdx1 and Igsf9-promoters have been shown to preferentially label IO neurons when used in the form of a transgenic animal (Hansen and Walmod, 2013 ; González-Calvo et al, 2021 ), this was not observed using AAV9-based transfection. Susd4 and Pdx1-controlled expression was only weakly biased toward neurons, and the neuronal expression obtained with various clones of Igsf9 promoter were same or less than that in astrocytes in the same slices.…”

Section: Resultsmentioning

confidence: 99%

“…Susd4 (Sushi Domain Containing 4; González-Calvo et al, 2021 ) gene promoter is driving expression of adhesion molecules in the axons of IO neurons.…”

Section: Resultsmentioning

confidence: 99%

“…Despite several works having employed a generic targeting approach for IO (White and Sillitoe, 2017 ; Rowan et al, 2018 ; Gaffield et al, 2019 ; González-Calvo et al, 2021 ), no systematic effort has been made to create a more specific targeting tool. Instead, experimenters have resorted to indirect methods, such as imaging IO-axon-evoked spikes in the cerebellum (Ju et al, 2019 ; Hoang et al, 2020 ; Roh et al, 2020 ; Michikawa et al, 2021 ), optogenetic modulation of IO afferents instead of IO neurons (Kim et al, 2020 ), limiting experimentation to cerebellar cortical regions where off-target transfection of axons with, e.g., the CamKII promoter is not problematic (Mathews et al, 2012 ; Gaffield et al, 2019 ) or morphological analysis (Nishiyama et al, 2007 ; Pätz et al, 2018 ; Vrieler et al, 2019 ; González-Calvo et al, 2021 ). To our knowledge, there have been no published reports of in situ, in vivo multi-cell IO network activity besides our recently-published preliminary observations (Guo et al, 2021 ).…”

Section: Introductionmentioning

confidence: 99%

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Designing AAV Vectors for Monitoring the Subtle Calcium Fluctuations of Inferior Olive Network in vivo

Dorgans

Guo

Kurima

et al. 2022

Front. Cell. Neurosci.

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Adeno-associated viral (AAV) vectors, used as vehicles for gene transfer into the brain, are a versatile and powerful tool of modern neuroscience that allow identifying specific neuronal populations, monitoring and modulating their activity. For consistent and reproducible results, the AAV vectors must be engineered so that they reliably and accurately target cell populations. Furthermore, transgene expression must be adjusted to sufficient and safe levels compatible with the physiology of studied cells. We undertook the effort to identify and validate an AAV vector that could be utilized for researching the inferior olivary (IO) nucleus, a structure gating critical timing-related signals to the cerebellum. By means of systematic construct generation and quantitative expression profiling, we succeeded in creating a viral tool for specific and strong transfection of the IO neurons without adverse effects on their physiology. The potential of these tools is demonstrated by expressing the calcium sensor GCaMP6s in adult mouse IO neurons. We could monitor subtle calcium fluctuations underlying two signatures of intrinsic IO activity: the subthreshold oscillations (STOs) and the variable-duration action potential waveforms both in-vitro and in-vivo. Further, we show that the expression levels of GCaMP6s allowing such recordings are compatible with the delicate calcium-based dynamics of IO neurons, inviting future work into the network dynamics of the olivo-cerebellar system in behaving animals.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

“…Susd4 (Sushi Domain Containing 4; González-Calvo et al, 2021 ) gene promoter is driving expression of adhesion molecules in the axons of IO neurons.…”

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Designing AAV Vectors for Monitoring the Subtle Calcium Fluctuations of Inferior Olive Network in vivo

Dorgans

Guo

Kurima

et al. 2022

Front. Cell. Neurosci.

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“…( Boulanger, 2009 )). One particular category of immune-related proteins with neuronal function are the proteins of the complement system implicated in innate immunity or their regulators: the complement proteins C1q and C3 contribute to synaptic pruning in the developing brain ( Stephan et al, 2012 ) and the complement inhibitor SUSD4 (Sushi domain-containing protein 4) regulates synaptic plasticity ( González-Calvo et al, 2021 ). Invertebrates do not have a complement system or an adaptative immune system.…”

Section: Introductionmentioning

confidence: 99%

Synapse Formation and Function Across Species: Ancient Roles for CCP, CUB, and TSP-1 Structural Domains

et al. 2022

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The appearance of synapses was a crucial step in the creation of the variety of nervous systems that are found in the animal kingdom. With increased complexity of the organisms came a greater number of synaptic proteins. In this review we describe synaptic proteins that contain the structural domains CUB, CCP, or TSP-1. These domains are found in invertebrates and vertebrates, and CUB and CCP domains were initially described in proteins belonging to the complement system of innate immunity. Interestingly, they are found in synapses of the nematode C. elegans, which does not have a complement system, suggesting an ancient function. Comparison of the roles of CUB-, CCP-, and TSP-1 containing synaptic proteins in various species shows that in more complex nervous systems, these structural domains are combined with other domains and that there is partial conservation of their function. These three domains are thus basic building blocks of the synaptic architecture. Further studies of structural domains characteristic of synaptic proteins in invertebrates such as C. elegans and comparison of their role in mammals will help identify other conserved synaptic molecular building blocks. Furthermore, this type of functional comparison across species will also identify structural domains added during evolution in correlation with increased complexity, shedding light on mechanisms underlying cognition and brain diseases.

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Purkinje Cells

Rossi

Isope

2023

Essentials of Cerebellum and Cerebellar Disorders

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Sushi domain-containing protein 4 controls synaptic plasticity and motor learning

Cited by 15 publications

References 105 publications

Designing AAV Vectors for Monitoring the Subtle Calcium Fluctuations of Inferior Olive Network in vivo

Designing AAV Vectors for Monitoring the Subtle Calcium Fluctuations of Inferior Olive Network in vivo

Synapse Formation and Function Across Species: Ancient Roles for CCP, CUB, and TSP-1 Structural Domains

Purkinje Cells

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