Crustacean neuropeptides

Christie, Andrew E.; Stemmler, Elizabeth A.; Dickinson, Patsy S.

doi:10.1007/s00018-010-0482-8

Cited by 194 publications

(413 citation statements)

References 313 publications

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“…Invertebrate nervous systems, including the crustacean stomatogastric nervous system (STNS), with its small number of large, uniquely identifiable neurons (Nusbaum et al, 2001;Skiebe, 2001;Nusbaum and Beenhakker, 2002;Fénelon et al, 2003;Fénelon et al, 2004;Hooper and DiCaprio, 2004;Marder and Bucher, 2007;Stein, 2009), have for many years provided important insights into our understanding of co-transmission (Kupfermann, 1991;Nusbaum et al, 2001;Nässel, 2009;Christie et al, 2010). In the present study, we identified the peptide co-transmitter in a pair of modulatory histaminergic projection neurons of the lobster STNS, then examined the roles played by this peptide and histamine in simultaneously modulating three different rhythmic motor patterns.…”

Section: Introductionmentioning

confidence: 99%

Coordination of distinct but interacting rhythmic motor programs by a modulatory projection neuron using different co-transmitters in different ganglia

Kwiatkowski

Gabranski

Huber

et al. 2013

Journal of Experimental Biology

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SUMMARYWhile many neurons are known to contain multiple neurotransmitters, the specific roles played by each co-transmitter within a neuron are often poorly understood. Here, we investigated the roles of the co-transmitters of the pyloric suppressor (PS) neurons, which are located in the stomatogastric nervous system (STNS) of the lobster Homarus americanus. The PS neurons are known to contain histamine; using RT-PCR, we identified a second co-transmitter as the FMRFamide-like peptide crustacean myosuppressin (Crust-MS). The modulatory effects of Crust-MS application on the gastric mill and pyloric patterns, generated in the stomatogastric ganglion (STG), closely resembled those recorded following extracellular PS neuron stimulation. To determine whether histamine plays a role in mediating the effects of the PS neurons in the STG, we bath-applied histamine receptor antagonists to the ganglion. In the presence of the antagonists, the histamine response was blocked, but Crust-MS application and PS stimulation continued to modulate the gastric and pyloric patterns, suggesting that PS effects in the STG are mediated largely by Crust-MS. PS neuron stimulation also excited the oesophageal rhythm, produced in the commissural ganglia (CoGs) of the STNS. Application of histamine, but not Crust-MS, to the CoGs mimicked this effect. Histamine receptor antagonists blocked the ability of both histamine and PS stimulation to excite the oesophageal rhythm, providing strong evidence that the PS neurons use histamine in the CoGs to exert their effects. Overall, our data suggest that the PS neurons differentially utilize their cotransmitters in spatially distinct locations to coordinate the activity of three independent networks.

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Section: Introductionmentioning

confidence: 99%

Coordination of distinct but interacting rhythmic motor programs by a modulatory projection neuron using different co-transmitters in different ganglia

Kwiatkowski

Gabranski

Huber

et al. 2013

Journal of Experimental Biology

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“…Combined with molecular biology and electrophysiology, single-cell MS is effective for examining neuronal architecture, and for delineating neuronal circuits that regulate physiology and control of instinctive and learned behaviors (Jarecki et al, 2010;Jing et al, 2010;Vilim et al, 2010). Investigations of signaling peptides and their involvement in neural plasticity, learning, memory, complex behavior, and various physiological functions at the level of the individual cell have been successful in invertebrate models (Jimenez et al, 1994;Christie et al, 2010;Li and Smit, 2010;Neupert and Predel, 2010;. Given the simplicity of their nervous systems and the accessibility of identifiable neurons, invertebrates provide unsurpassed single-neuron resolution and coupling to molecular mechanisms.…”

Section: Power Of One: Single-cell Analysis For Circuit and Pathway Cmentioning

confidence: 99%

Small-Volume Analysis of Cell–Cell Signaling Molecules in the Brain

Romanova

Aerts

Croushore

et al. 2013

Neuropsychopharmacol

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Modern science is characterized by integration and synergy between research fields. Accordingly, as technological advances allow new and more ambitious quests in scientific inquiry, numerous analytical and engineering techniques have become useful tools in biological research. The focus of this review is on cutting edge technologies that aid direct measurement of bioactive compounds in the nervous system to facilitate fundamental research, diagnostics, and drug discovery. We discuss challenges associated with measurement of cell-to-cell signaling molecules in the nervous system, and advocate for a decrease of sample volumes to the nanoliter volume regimen for improved analysis outcomes. We highlight effective approaches for the collection, separation, and detection of such small-volume samples, present strategies for targeted and discovery-oriented research, and describe the required technology advances that will empower future translational science.

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“…In fact, little was known about the molecular machinery necessary for the establishment and proper functioning of neurochemical pathways in any crustacean. Although the molecules used for chemical communication are diverse in all multicellular organisms, peptides are by far the largest class used by nervous systems (Christie et al, 2010;Christie, 2011), and it is this group of compounds that was the first to be investigated via genome and/or transcriptome mining in Daphnia.…”

Section: Peptidergic Systemsmentioning

confidence: 99%

“…One factor that has surely contributed to this lack of neurochemical knowledge is its size; adults are typically just a few millimeters in overall length. This is surely true for the identification of its neuropeptides, as the standard method for peptide discovery until ~2005 was to isolate individual peptides chromatographically and/or biochemically from large pools of starting tissue and, upon their purification, assess their structures using a combination of proteolytic cleavage, Edman analysis and mass spectrometry (Christie et al, 2010). Given its minute size and the need to manually dissect a sufficient amount of starting material, the identification of even a single Daphnia neuropeptide via this strategy would surely have been daunting, as hundreds, and in some cases thousands, of central nervous systems (CNSs) were needed for the biochemical isolation and characterization of individual native peptides from much larger crustaceans (e.g.…”

Section: Introductionmentioning

confidence: 99%

From genes to behavior: investigations of neurochemical signaling come of age for the model crustacean Daphnia pulex

Christie

McCoole

2012

Journal of Experimental Biology

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SummaryThe cladoceran crustacean Daphnia pulex has served as a standard organism for aquatic toxicity testing for decades. The model organism status of D. pulex rests largely on its remarkable ability to rapidly adapt morphologically, physiologically and behaviorally to a wide range of environmental challenges, as well as on its parthenogenetic reproduction and ease of laboratory culture. As in all multicellular organisms, neurochemical control systems are undoubtedly major contributors to the functional flexibility of Daphnia. Surprisingly, little work has focused on understanding its neurochemistry at any level. Recently, D. pulex has been the subject of extensive genome and transcriptome sequencing, and it is currently the only crustacean with a fully sequenced, publicly accessible genome. Although the molecular work was initiated for gene-based investigations of ecotoxicology and toxicogenomics, the data generated have allowed for investigations into numerous aspects of Daphnia biology, including its neurochemical signaling. This Commentary summarizes our knowledge of D. pulex neurochemistry obtained from recent genomic and transcriptomic studies, and places these data in context with other anatomical, biochemical and physiological experiments using D. pulex and its sister species Daphnia magna. Suggestions as to how the Daphnia molecular data may be useful for future investigations of crustacean neurochemical signaling are also provided.

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Crustacean neuropeptides

Cited by 194 publications

References 313 publications

Coordination of distinct but interacting rhythmic motor programs by a modulatory projection neuron using different co-transmitters in different ganglia

Coordination of distinct but interacting rhythmic motor programs by a modulatory projection neuron using different co-transmitters in different ganglia

Small-Volume Analysis of Cell–Cell Signaling Molecules in the Brain

From genes to behavior: investigations of neurochemical signaling come of age for the model crustacean Daphnia pulex

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