Robust discrimination between self and non-self neurites requires thousands of Dscam1 isoforms

Hattori, Daisuke; Che, Yi; Matthews, Benjamin J.; Salwiński, Łukasz; Sabatti, Chiara; Grueber, Wesley B.; Zipursky, S. Lawrence

doi:10.1038/nature08431

Cited by 155 publications

(227 citation statements)

References 28 publications

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“…Cite this article as Cold Spring Harb Perspect Biol 2010;2:a001776 whether the diversity of DSCAM isoforms instructs glomerular specificity of either or both cell types, although an instructional role for DSCAM has been shown at other fly synapses (Hattori et al 2009). …”

Section: Comparative Views On Olfactory Axon Guidancementioning

confidence: 99%

Topographic Mapping--The Olfactory System

Imai¹,

Sakano²,

Vosshall³

2010

Cold Spring Harbor Perspectives in Biology

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Sensory systems must map accurate representations of the external world in the brain. Although the physical senses of touch and vision build topographic representations of the spatial coordinates of the body and the field of view, the chemical sense of olfaction maps discontinuous features of chemical space, comprising an extremely large number of possible odor stimuli. In both mammals and insects, olfactory circuits are wired according to the convergence of axons from sensory neurons expressing the same odorant receptor. Synapses are organized into distinctive spherical neuropils-the olfactory glomeruli-that connect sensory input with output neurons and local modulatory interneurons. Although there is a strong conservation of form in the olfactory maps of mammals and insects, they arise using divergent mechanisms. Olfactory glomeruli provide a unique solution to the problem of mapping discontinuous chemical space onto the brain.T he olfactory system detects airborne organic and inorganic chemicals that originate from plant and animal metabolites and environmental and industrial sources. Odors mediate both innate and learned behaviors such as attraction and aversion, governing decisions to eat, mate, attack or flee from aggressors and predators. A remarkable feature of the olfactory system is the extraordinary diversity of possible odor molecules that exist. Although accurate measurements can be made of the detection range of visual wavelengths or auditory frequencies in humans, there are no reliable estimates of the number of odorous molecules that exist on earth or those that can be detected by a given animal species (Gilbert 2008). Nevertheless, the number of possible odorants is thought to be high, in the range of many thousands. Beyond odor detection lies the problem of odor discrimination: how can chemicals with slightly different physical properties be discriminated and associated with distinct odor percepts?Experiments investigating the molecular logic of olfaction over the last 20 years have led to major insights into how animals solve the problem of detecting and discriminating a vast number of different odor stimuli (Axel 1995). Four organizational principles have emerged from this work. First, large numbers of distinct odorant receptor (OR) genes are dedicated

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Section: Comparative Views On Olfactory Axon Guidancementioning

confidence: 99%

Topographic Mapping--The Olfactory System

Imai¹,

Sakano²,

Vosshall³

2010

Cold Spring Harbor Perspectives in Biology

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“…The genome size is insufficient to encode such diversity, but a mixture of combinatorial expression patterns that pair different synaptic cell-adhesion molecules with each other and of distinct alternative splicing patterns that amplify the number of cell-adhesion molecules into a large number of isoforms may generate the number of transsynaptic interactions needed to account for the enormous diversity of synaptic connections. In Drosophila melanogaster, alternative splicing of the mRNAs encoding the Down syndrome cell-adhesion molecule can generate nearly 20,000 protein isoforms whose structures specify axon bundling but not synapse formation (6). In mammals, alternative splicing of neurexin and some protocadherin mRNAs can also produce thousands of isoforms, which may at least in the case of neurexins be involved in synapse formation (7)(8)(9)(10).…”

mentioning

confidence: 99%

Cartography of neurexin alternative splicing mapped by single-molecule long-read mRNA sequencing

Treutlein¹,

Gökçe

Quake

et al. 2014

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

277

252

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Neurexins are evolutionarily conserved presynaptic cell-adhesion molecules that are essential for normal synapse formation and synaptic transmission. Indirect evidence has indicated that extensive alternative splicing of neurexin mRNAs may produce hundreds if not thousands of neurexin isoforms, but no direct evidence for such diversity has been available. Here we use unbiased long-read sequencing of full-length neurexin (Nrxn)1α, Nrxn1β, Nrxn2β, Nrxn3α, and Nrxn3β mRNAs to systematically assess how many sites of alternative splicing are used in neurexins with a significant frequency, and whether alternative splicing events at these sites are independent of each other. In sequencing more than 25,000 full-length mRNAs, we identified a novel, abundantly used alternatively spliced exon of Nrxn1α and Nrxn3α (referred to as alternatively spliced sequence 6) that encodes a 9-residue insertion in the flexible hinge region between the fifth LNS (laminin-α, neurexin, sex hormone-binding globulin) domain and the third EGF-like sequence. In addition, we observed several larger-scale events of alternative splicing that deleted multiple domains and were much less frequent than the canonical six sites of alternative splicing in neurexins. All of the six canonical events of alternative splicing appear to be independent of each other, suggesting that neurexins may exhibit an even larger isoform diversity than previously envisioned and comprise thousands of variants. Our data are consistent with the notion that α-neurexins represent extracellular protein-interaction scaffolds in which different LNS and EGF domains mediate distinct interactions that affect diverse functions and are independently regulated by independent events of alternative splicing.N eurons form highly specific and complex patterns of synaptic connections that underlie all brain function (1-5). Such specific connections require trillions of chemically differentiated synapses whose identity may be shaped by interactions of specific pre-and postsynaptic signaling molecules, especially cell-adhesion molecules. The genome size is insufficient to encode such diversity, but a mixture of combinatorial expression patterns that pair different synaptic cell-adhesion molecules with each other and of distinct alternative splicing patterns that amplify the number of cell-adhesion molecules into a large number of isoforms may generate the number of transsynaptic interactions needed to account for the enormous diversity of synaptic connections. In Drosophila melanogaster, alternative splicing of the mRNAs encoding the Down syndrome cell-adhesion molecule can generate nearly 20,000 protein isoforms whose structures specify axon bundling but not synapse formation (6). In mammals, alternative splicing of neurexin and some protocadherin mRNAs can also produce thousands of isoforms, which may at least in the case of neurexins be involved in synapse formation (7-10).Neurexins are type I membrane proteins that were discovered as presynaptic receptors for α-latrotoxin (8, 9). Six prin...

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“…When their neurites contact, they undergo homophilic binding, which generates repulsion, whereas when other neurons, which have a different set of isoforms, are encountered, homophilic binding and repulsion do not occur (see Figure 1). The number of Dscam1 isoforms expressed by each neuron is believed to be in the range 10 to 50, and it has been proposed that this set of isoforms is chosen stochastically from the set of all possible isoforms (Hattori et al, 2009). Although little is known biologically about how this might occur, understanding the consequences of this assumption reduces to a problem in combinatorics.…”

Section: Introductionmentioning

confidence: 99%

The Combinatorics of Neurite Self-Avoidance

2011

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During neural development in Drosophila, the ability of neurite branches to recognize whether they are from the same or different neurons depends crucially on the molecule Dscam1. In particular, this recognition depends on the stochastic acquisition of a unique combination of Dscam1 isoforms out of a large set of possible isoforms. To properly interpret these findings, it is crucial to understand the combinatorics involved, which has previously been attempted only using stochastic simulations for some specific parameter combinations. Here we present closed-form solutions for the general case. These reveal the relationships among the key variables and how these constrain possible biological scenarios.

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Robust discrimination between self and non-self neurites requires thousands of Dscam1 isoforms

Cited by 155 publications

References 28 publications

Topographic Mapping--The Olfactory System

Topographic Mapping--The Olfactory System

Cartography of neurexin alternative splicing mapped by single-molecule long-read mRNA sequencing

The Combinatorics of Neurite Self-Avoidance

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