RIM1α forms a protein scaffold for regulating neurotransmitter release at the active zone

Schoch, Susanne; Castillo, Pablo E.; Jo, Tobias; Mukherjee, Konark; Geppert, Martin; Wang, Yun; Schmitz, Frank; Malenka, Robert C.; Südhof, Thomas C.

doi:10.1038/415321a

Cited by 564 publications

(748 citation statements)

References 25 publications

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“…However, genetic deletion of such pan-synaptic scaVolding proteins often has diVerent eVects on excitatory than on inhibitory presynaptic terminals. This holds true, e.g., for Munc13s (Schoch et al 2002;Varoqueaux et al 2002), RIM1 (Schoch et al 2002), and CASK ). Likewise, triple knockout of the synaptic vesicle associated cytomatrix proteins Synapsin 1, 2 and 3 changes the kinetics of synaptic depression, but not basal transmission, at excitatory synapses, whereas the kinetics of depression are unchanged, but basal transmission is reduced, at inhibitory synapses (Gitler et al 2004).…”

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confidence: 83%

Molecular architecture of glycinergic synapses

Dresbach

Nawrotzki

Kremer

et al. 2008

Histochem Cell Biol

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Synapses can be considered chemical machines, which are optimized for fast and repeated exocytosis of neurotransmitters from presynaptic nerve terminals and the reliable electrical or chemical transduction of neurotransmitter binding to the appropriate receptors in the postsynaptic membrane. Therefore, synapses share a common repertoire of proteins like, e.g., the release machinery and certain cell adhesion molecules. This basic repertoire must be extended in order to generate speciWcity of neurotransmission and allow plastic changes, which are considered the basis of developmental and/or learning processes. Here, we focus on these complementary molecules located in the presynaptic terminal and postsynaptic membrane specializations of glycinergic synapses. Moreover, as speciWcity of neurotransmission in this system is established by the speciWc binding of the neurotransmitter to its receptor, we review the molecular properties of glycine receptor subunits and their assembly into functional glycine receptors with diVerent functional characteristics. The past years have revealed that the molecular machinery underlying inhibitory and especially glycinergic postsynaptic membrane specializations is more complex and dynamic than previously anticipated from morphological studies. The emerging features include structural components as well as signaling modules, which could confer the plasticity required for the proper function of distinct motor and sensory functions.

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mentioning

confidence: 83%

Molecular architecture of glycinergic synapses

Dresbach

Nawrotzki

Kremer

et al. 2008

Histochem Cell Biol

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“…RIM1-alpha, the best studied isoform, is located at the active zone of the presynaptic terminals and forms a protein scaffold interacting with key presynaptic molecules. In addition to Rab3a, RIM1-alpha binds active zone proteins Munc13-1 147,148 and ERCs, 149,150 the synaptic vesicle protein synaptotagmin1, a calcium sensor for fast synchronous release, 151,152 and other synaptic proteins as alpha-liprins. 152 Indirectly, RIM1-alpha binds to L-type calcium channels 153 through the so-called RIM-BPs (RIM binding proteins).…”

Section: Rim1-alphamentioning

confidence: 99%

“…In addition to Rab3a, RIM1-alpha binds active zone proteins Munc13-1 147,148 and ERCs, 149,150 the synaptic vesicle protein synaptotagmin1, a calcium sensor for fast synchronous release, 151,152 and other synaptic proteins as alpha-liprins. 152 Indirectly, RIM1-alpha binds to L-type calcium channels 153 through the so-called RIM-BPs (RIM binding proteins). 150 Insightful functional studies of RIM have been recently performed in C. elegans 154 and in knockout mice.…”

Section: Rim1-alphamentioning

confidence: 99%

“…150 Insightful functional studies of RIM have been recently performed in C. elegans 154 and in knockout mice. 152,155,156,126 Schoch et al 152 have shown that mice lacking RIM1-alpha survived to adulthood with slighter high mortality compared to wild-type littermates and displayed a poor maternal and nurturing behavior. They did not show any structural abnormalities in the brain and did not have significant changes in the levels of synaptic proteins, except for the active zone protein Munc13-1 which was decreased by B60% probably because, since Munc-13 binds to RIM1-alpha, it degrades when RIM1-alpha is absent.…”

Section: Rim1-alphamentioning

confidence: 99%

“…Since Munc13-1 is a key priming factor, 124,125,130 they concluded that the missing 50% of the RRP could be explained because in RIM1-alpha knockout mice, there is a substantial reduction in Munc13-1 levels. 152 That implies that there are probably two different subpools of synaptic vesicles within the RRP. The missing subpool of the RRP in RIM1-alpha KO mice probably corresponds in normal conditions to a pool of synaptic vesicles activated by a priming reaction where the interaction between Munc13-1 and RIM1-alpha is required.…”

Section: Rim1-alphamentioning

confidence: 99%

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Active zones for presynaptic plasticity in the brain

García-Junco-Clemente

Linares-Clemente

Fernández‐Chacón

2005

Mol Psychiatry

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Some of the most abundant synapses in the brain such as the synapses formed by the hippocampal mossy fibers, cerebellar parallel fibers and several types of cortical afferents express presynaptic forms of long-term potentiation (LTP), a putative cellular model for spatial, motor and fear learning. Those synapses often display presynaptic mechanisms of LTP induction, which are either NMDA receptor independent of dependent of presynaptic NMDA receptors. Recent investigations on the molecular mechanisms of neurotransmitter release modulation in short-and long-term synaptic plasticity in central synapses give a preponderant role to active zone proteins as Munc-13 and RIM1-alpha, and point toward the maturation process of synaptic vesicles prior to Ca 2 þ -dependent fusion as a key regulatory step of presynaptic plasticity.

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Regulation of synaptic release‐site Ca²⁺ channel coupling as a mechanism to control release probability and short‐term plasticity

2018

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Synaptic transmission relies on the rapid fusion of neurotransmitter-containing synaptic vesicles (SVs), which happens in response to action potential (AP)-induced Ca influx at active zones (AZs). A highly conserved molecular machinery cooperates at SV-release sites to mediate SV plasma membrane attachment and maturation, Ca sensing, and membrane fusion. Despite this high degree of conservation, synapses - even within the same organism, organ or neuron - are highly diverse regarding the probability of APs to trigger SV fusion. Additionally, repetitive activation can lead to either strengthening or weakening of transmission. In this review, we discuss mechanisms controlling release probability and this short-term plasticity. We argue that an important layer of control is exerted by evolutionarily conserved AZ scaffolding proteins, which determine the coupling distance between SV fusion sites and voltage-gated Ca channels (VGCC) and, thereby, shape synapse-specific input/output behaviors. We propose that AZ-scaffold modifications may occur to adapt the coupling distance during synapse maturation and plastic regulation of synapse strength.

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RIM1α forms a protein scaffold for regulating neurotransmitter release at the active zone

Cited by 564 publications

References 25 publications

Molecular architecture of glycinergic synapses

Molecular architecture of glycinergic synapses

Active zones for presynaptic plasticity in the brain

Regulation of synaptic release‐site Ca²⁺ channel coupling as a mechanism to control release probability and short‐term plasticity

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RIM1α forms a protein scaffold for regulating neurotransmitter release at the active zone

Cited by 564 publications

References 25 publications

Molecular architecture of glycinergic synapses

Molecular architecture of glycinergic synapses

Active zones for presynaptic plasticity in the brain

Regulation of synaptic release‐site Ca2+ channel coupling as a mechanism to control release probability and short‐term plasticity

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Regulation of synaptic release‐site Ca²⁺ channel coupling as a mechanism to control release probability and short‐term plasticity