Comprehensive analysis of the ascidian genome reveals novel insights into the molecular evolution of ion channel genes

Okamura, Yasushi; Nishino, Atsuo; Murata, Yuzo; Nakajo, Koichi; Iwasaki, Hirohide; Ohtsuka, Yukio; Tanaka-Kunishima, Motoko; Takahashi, Nobuyuki; Hara, Yuji; Yoshida, Takashi; Nishida, Motohiro; Okado, Haruo; Watari, Hirofumi; Meinertzhagen, Ian A.; Satoh, Nori; Takahashi, Kunitaro; Satou, Yutaka; Okada, Yasunobu; Mori, Yasuo

doi:10.1152/physiolgenomics.00229.2004

Cited by 92 publications

(100 citation statements)

References 63 publications

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“…To determine the molecular basis for neuromuscular transmission, we characterized the nAChR subunits expressed in the larval muscle. In an earlier (13) and subsequent surveys of the Ciona genome, we identified 10 nAChR subunit genes and a rapsyn homolog gene ( Fig. 2A, Fig.…”

Section: Resultsmentioning

confidence: 98%

“…These cholinergic neurons project axons down the tail and innervate a part of the (mainly dorsal) muscle cells, whereas others receive excitation via gap junctions (8-11). Despite such knowledge, how the Ciona larva swims like fish using such simplified motor units remains unknown.Recent research on the Ciona genome provides an opportunity to examine the molecular mechanisms underlying the physiology of this animal (12,13). Given the correspondence between the body plans yet nevertheless the extreme contrast between their body complexities (minimal ascidian larva vs. much larger vertebrates), detailed comparison of their apparently similar swimming dynamics could uncover some novel control mechanisms.…”

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confidence: 99%

“…Recent research on the Ciona genome provides an opportunity to examine the molecular mechanisms underlying the physiology of this animal (12,13). Given the correspondence between the body plans yet nevertheless the extreme contrast between their body complexities (minimal ascidian larva vs. much larger vertebrates), detailed comparison of their apparently similar swimming dynamics could uncover some novel control mechanisms.…”

mentioning

confidence: 99%

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A mechanism for graded motor control encoded in the channel properties of the muscle ACh receptor

Nishino

Baba

Okamura

2011

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

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The larva of the invertebrate chordate Ciona intestinalis possesses only 36 striated muscle cells and lacks body segmentation. It can swim, however, like a vertebrate tadpole, and how its simple body achieves such sophisticated motor control remains puzzling. We found that muscle contractions in Ciona larvae are variable and can be changed by sensory stimuli, so that neuromuscular transmission can convert the variable neural inputs into graded muscle activity. We characterized the molecular nature of the nicotinic acetylcholine receptor (nAChR) at neuromuscular synapses. When heterologously expressed in Xenopus oocytes, this nAChR channel exhibited two biophysical features resembling vertebrate neuronal nAChRs rather than the muscle type: inward rectification and high Ca 2+ permeability. Both of these properties were abolished by a simple mutation at the channel pore in one of the non-α subunits, called BGDE3, so as to adopt the sequence of related subunits in vertebrates, γ and ε. In vivo exchange of native BGDE3 with this mutant severely disrupted graded motor control, producing instead sporadic all-or-none-like flexions. The graded nature of excitation-contraction (E-C) coupling in this organism is based on the traits of the nAChR channel pore, which confer fine controllability on such a coarse motor architecture.ascidian larva | muscle physiology | locomotion | neuromuscular junction I n tailed aquatic vertebrates such as fish and amphibian tadpoles, swimming undulations are generated by sequential activation of the myotomal segments. These segments contain multiple classes of muscle fibers, including slow, fast, and intermediate types, with distinct mechanical and metabolic properties that constitute a "gearing" system adjustable to a wide range of speeds. The activity of a given segment is mostly independent of the others, and when, which, and how many fibers will be activated are determined by a neural network in the spinal cord (1-3). This neural mechanism by which contraction magnitude is varied is based on the logic for recruiting motor neurons into the active population, called the size principle (1-4). This control system for compound muscle fibers is likely a key innovation in vertebrates, but how far this basis can be traced back in invertebrate systems is poorly understood.Ascidians are marine invertebrates that constitute a sister clade of the vertebrates (5, 6). The larva of the ascidian Ciona intestinalis (L) is tadpole shaped and possesses bilateral muscle bands, a dorsal neural tube supported by an axial notochord, and sensory organs including a photoreceptive ocellus (Fig. 1A and Fig. S1A). Despite this suite of organs, the body of the Ciona larva is quite simple. The muscle band on each side lacks a segmental plan and is composed of only 18 cells arranged in a single layer (Fig. 1A and Fig. S1). The 4-5 pairs of cholinergic motor neurons located in the motor ganglion (or the visceral ganglion) have accounted for the swimming behavior (Fig. S1) (7-10). These cholinergic neurons project axons...

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Section: Resultsmentioning

confidence: 98%

mentioning

confidence: 99%

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confidence: 99%

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A mechanism for graded motor control encoded in the channel properties of the muscle ACh receptor

Nishino

Baba

Okamura

2011

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

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“…Several lines of evidence have suggested that whole genome duplications occurred before the vertebrate/ascidian divergence [39] and, later on, in the lineage of teleostheus after tetrapod divergence where only one set of these duplicated genes were maintained [40]- [43]. This is supported by the existence of several duplicated segments in zebrafish chromosomes [44].…”

Section: Genomic Organization Of P2x Orthologous Genesmentioning

confidence: 99%

Genomic Organization of Purinergic P2X Receptors

Loera-Valencia¹,

Jaramillo-Polanco²,

Liñán-Rico³

et al. 2015

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Purinergic P2X receptors are a family of ligand-gated cationic channels activated by extracellular ATP. P2X subunit protein sequences are highly conserved between vertebrate species. However, they can generate a great diversity of coding splicing variants to fulfill several roles in mammalian physiology. Despite intensive research in P2X expression in both central and peripheral nervous system, there is little information about their homology, genomic structure and other key features that can help to develop selective drugs or regulatory strategies of pharmacological value which are lacking today. In order to obtain clues on mammalian P2X diversity, we have performed a bioinformatics analysis of the coding regions and introns of the seven P2X subunits present in human, simian, dog, mouse, rat and zebrafish. Here we report the arrangements of exon and intron sequences, considering its number, size, phase and placement; proposing some ideas about the gain and loss of exons and retention of introns. Taken together, these evidences show traits that can be used to gain insight into the evolutionary history of vertebrate P2X receptors and better understand the diversity of subunits coding the purinergic signaling in mammals.

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“…Here, we instead used the ascidian chordate Ciona intestinalis, the closest living relative to vertebrates (16), which is thought to have just a single gluA gene (17). Ciona larvae are transparent, enabling easy identification of cells expressing a target gene and detection of morphological phenotypes in the tissues and organs.…”

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AMPA glutamate receptors are required for sensory-organ formation and morphogenesis in the basal chordate

Hirai

Hotta

Kubo

et al. 2017

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

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AMPA-type glutamate receptors (GluAs) mediate fast excitatory transmission in the vertebrate central nervous system (CNS), and their function has been extensively studied in the mature mammalian brain. However, GluA expression begins very early in developing embryos, suggesting that they may also have unidentified developmental roles. Here, we identify developmental roles for GluAs in the ascidian Ciona intestinalis. Mammals express Ca2+-permeable GluAs (Ca-P GluAs) and Ca2+-impermeable GluAs (Ca-I GluAs) by combining subunits derived from four genes. In contrast, ascidians have a single gluA gene. Taking advantage of the simple genomic GluA organization in ascidians, we knocked down (KD) GluAs in Ciona and observed severe impairments in formation of the ocellus, a photoreceptive organ used during the swimming stage, and in resorption of the tail and body axis rotation during metamorphosis to the adult stage. These defects could be rescued by injection of KD-resistant GluAs. GluA KD phenotypes could also be reproduced by expressing a GluA mutant that dominantly inhibits glutamate-evoked currents. These results suggest that, in addition to their role in synaptic communication in mature animals, GluAs also have critical developmental functions.

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Comprehensive analysis of the ascidian genome reveals novel insights into the molecular evolution of ion channel genes

Cited by 92 publications

References 63 publications

A mechanism for graded motor control encoded in the channel properties of the muscle ACh receptor

A mechanism for graded motor control encoded in the channel properties of the muscle ACh receptor

Genomic Organization of Purinergic P2X Receptors

AMPA glutamate receptors are required for sensory-organ formation and morphogenesis in the basal chordate

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