Latrophilin 1 and its endogenous ligand Lasso/teneurin-2 form a high-affinity transsynaptic receptor pair with signaling capabilities

Silva, John-Paul; Lelianova, Vera G.; Ermolyuk, Yaroslav S.; Vysokov, Nickolai; Hitchen, Paul G.; Berninghausen, Otto; Rahman, MA; Zangrandi, Alice; Fidalgo, Sara; Tonevitsky, Alexander G.; Dell, Anne; Volynski, Kirill E.; Ushkaryov, Yuri A.

doi:10.1073/pnas.1019434108

Cited by 218 publications

(362 citation statements)

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“…Teneurins are required for transsynaptic signaling and organization of the synapse cytoskeleton in Drosophila neuromuscular synapses and olfactory receptor neurons (33,86). Recently, mammalian teneurins have been shown to be latrophilin (Lphn) receptors, which are known to mediate the massive synaptic exocytosis caused by the black widow spider venom α-latrotoxin and which also were identified as reduced in deprived synapses (48,87). Prickle2 has been shown to regulate neurite formation and outgrowth, but only in neuroblastoma cell lines (55).…”

Section: Discussionmentioning

confidence: 99%

In vivo quantitative proteomics of somatosensory cortical synapses shows which protein levels are modulated by sensory deprivation

Butko¹,

Savas

Friedman³

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

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Postnatal bilateral whisker trimming was used as a model system to test how synaptic proteomes are altered in barrel cortex by sensory deprivation during synaptogenesis. Using quantitative mass spectrometry, we quantified more than 7,000 synaptic proteins and identified 89 significantly reduced and 161 significantly elevated proteins in sensory-deprived synapses, 22 of which were validated by immunoblotting. More than 95% of quantified proteins, including abundant synaptic proteins such as PSD-95 and gephyrin, exhibited no significant difference under high-and low-activity rearing conditions, suggesting no tissue-wide changes in excitatory or inhibitory synaptic density. In contrast, several proteins that promote mature spine morphology and synaptic strength, such as excitatory glutamate receptors and known accessory factors, were reduced significantly in deprived synapses. Immunohistochemistry revealed that the reduction in SynGAP1, a postsynaptic scaffolding protein, was restricted largely to layer I of barrel cortex in sensorydeprived rats. In addition, protein-degradation machinery such as proteasome subunits, E2 ligases, and E3 ligases, accumulated significantly in deprived synapses, suggesting targeted synaptic protein degradation under sensory deprivation. Importantly, this screen identified synaptic proteins whose levels were affected by sensory deprivation but whose synaptic roles have not yet been characterized in mammalian neurons. These data demonstrate the feasibility of defining synaptic proteomes under different sensory rearing conditions and could be applied to elucidate further molecular mechanisms of sensory development. mass spectrometric proteomics | somatosensory cortex | experience-dependent plasticity | synaptic protein dynamics S ensory information is encoded in the brain by activation of specific neuronal circuits that operate via chemical synapses. Important sensory experiences are stored by strengthening activated synapses in the circuit, a process known as "experience-dependent plasticity" (1). When animals are deprived of sensory experience during development, for example, by trimming rodent whiskers from birth to 30 d after birth, synaptic strength and mature synaptic morphology are attenuated, suggesting that the low activity in the deprived circuits interferes with normal development (2-7). However, the molecular changes that alter these synaptic properties in response to experience remain unclear. Synaptic activation has been shown to promote regulated and highly localized effects on synaptic proteins such as local translation, recruitment, and targeted degradation (8-11), and this spatiotemporal control of protein availability is required for long-term plasticity and synaptic maturation, which are fundamental in memory formation and storage and ultimately for an organism's survival (12-14). The need for highly controlled protein availability is highlighted in studies of neurological diseases, which often result from the disruption of protein availability at the synapse (15-17). ...

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Section: Discussionmentioning

confidence: 99%

In vivo quantitative proteomics of somatosensory cortical synapses shows which protein levels are modulated by sensory deprivation

Butko¹,

Savas

Friedman³

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

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“…A further feature of the Adhesion GPCR binding profile seems to be a high promiscuity in ligand recognition, with one receptor binding to multiple partners. Lastly, the location of these partners is not always found on opposing cells or in the extracellular space (in trans: Hamann et al, 1996b;Park et al, 2007;Das et al, 2011;Silva et al, 2011); in some cases, receptor and ligand may reside on the surface of the same cell (in cis: Little et al, 2004;Nishimura et al, 2012;Prömel et al, 2012a).…”

Section: Extracellular Interaction Partnersmentioning

confidence: 99%

“…ADGRLs (latrophilins) are well studied with regard to interacting partner binding, and recently, teneurin-2 (also known as Lasso) was suggested to be an endogenous binding partner for ADGRL1 (latrophilin-1) (Silva et al, 2011). In rats, teneurin-2 interacts strongly and specifically with ADGRL1 (latrophilin-1) in trans (Silva et al, 2011) (Fig.…”

mentioning

confidence: 99%

International Union of Basic and Clinical Pharmacology. XCIV. Adhesion G Protein–Coupled Receptors

et al. 2015

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“…2), subfamily I latrophilins are well known for their roles in synapse development and triggering neurotransmitter release. The presynaptic latrophilin 1 (LPHN1) interacts with the postsynaptic teneurin-2 (also known as Lasso, an endogenous ligand of latrophilin 1), forming a trans-synaptic complex and thus affecting synaptic development (Boucard et al, 2014;Silva et al, 2011). And, latrophilins interact with the postsynaptic fibronectin leucine-rich transmembrane (FLRT) family members.…”

Section: The Journal Of Experimental Biologymentioning

confidence: 99%

The role of G protein-coupled receptors in the early evolution of neurotransmission and the nervous system

Krishnan

Schiöth

2015

Journal of Experimental Biology

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The origin and evolution of the nervous system is one of the most intriguing and enigmatic events in biology. The recent sequencing of complete genomes from early metazoan organisms provides a new platform to study the origins of neuronal gene families. This review explores the early metazoan expansion of the largest integral transmembrane protein family, the G protein-coupled receptors (GPCRs), which serve as molecular targets for a large subset of neurotransmitters and neuropeptides in higher animals. GPCR repertories from four pre-bilaterian metazoan genomes were compared. This includes the cnidarian Nematostella vectensis and the ctenophore Mnemiopsis leidyi, which have primitive nervous systems (nerve nets), the demosponge Amphimedon queenslandica and the placozoan Trichoplax adhaerens, which lack nerve and muscle cells. Comparative genomics demonstrate that the rhodopsin and glutamate receptor families, known to be involved in neurotransmission in higher animals are also widely found in prebilaterian metazoans and possess substantial expansions of rhodopsin-family-like GPCRs. Furthermore, the emerging knowledge on the functions of adhesion GPCRs in the vertebrate nervous system provides a platform to examine possible analogous roles of their closest homologues in pre-bilaterians. Intriguingly, the presence of molecular components required for GPCR-mediated neurotransmission in pre-bilaterians reveals that they exist in both primitive nervous systems and nerve-cell-free environments, providing essential comparative models to better understand the origins of the nervous system and neurotransmission. KEY WORDS: Neuron, GPCR, Nerve net, Synapse, EvolutionIntroduction G protein-coupled receptors (GPCRs) constitute the largest superfamily among membrane bound proteins that control key physiological functions, such as, neurotransmission, hormone releases, and immune responses among others (Katritch et al., 2013; Lagerström and Schiöth, 2008;Rosenbaum et al., 2009). As such, the large range of integral transmembrane proteins in this family respond to subsequent, diverse array of ligands: including neurotransmitters, hormones, lipids, and odorants (Civelli et al., 2013;Shoichet and Kobilka, 2012). GPCRs in mammals are classified into the five main families according to the GRAFS classification: glutamate, rhodopsin, adhesion, frizzled and secretin (Fredriksson et al., 2003). These five GPCR families are associated with various physiological functions, but the roles of the glutamate and the rhodopsin families are particularly well documented for REVIEW Department of Neuroscience, Functional Pharmacology, Uppsala University, BMC, Box 593,751 24, Uppsala, Sweden.*Authors for correspondence (arunkumar.krishnan@neuro.uu.se; helgi.schioth@neuro.uu.se) neurotransmission and regulation of the nervous system (Niswender and Conn, 2010;Schoepp, 2001). Some functions include synaptic transmission, synapse formation, axon guidance and development of neuronal circuits (Collingridge et al., 2004;Hnasko and Edwards, 2012)...

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Latrophilin 1 and its endogenous ligand Lasso/teneurin-2 form a high-affinity transsynaptic receptor pair with signaling capabilities

Cited by 218 publications

References 41 publications

In vivo quantitative proteomics of somatosensory cortical synapses shows which protein levels are modulated by sensory deprivation

In vivo quantitative proteomics of somatosensory cortical synapses shows which protein levels are modulated by sensory deprivation

International Union of Basic and Clinical Pharmacology. XCIV. Adhesion G Protein–Coupled Receptors

The role of G protein-coupled receptors in the early evolution of neurotransmission and the nervous system

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