Transcriptome Analysis of the Central and Peripheral Nervous Systems of the Spider Cupiennius salei Reveals Multiple Putative Cys-Loop Ligand Gated Ion Channel Subunits and an Acetylcholine Binding Protein

Protein-engineering methods have been exploited to produce a surrogate system for the extracellular neurotransmitter-binding site of a heteromeric human ligand-gated ion channel, the glycine receptor. This approach circumvents two major issues: the inherent experimental difficulties in working with a membrane-bound ion channel and the complication that a heteromeric assembly is necessary to create a key, physiologically relevant binding site. Residues that form the orthosteric site in a highly stable ortholog, acetylcholine-binding protein, were selected for substitution. Recombinant proteins were prepared and characterized in stepwise fashion exploiting a range of biophysical techniques, including X-ray crystallography, married to the use of selected chemical probes. The decision making and development of the surrogate, which is termed a glycine-binding protein, are described, and comparisons are provided with wild-type and homomeric systems that establish features of molecular recognition in the binding site and the confidence that the system is suited for use in early-stage drug discovery targeting a heteromeric α/β glycine receptor.

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Ultrastructural localization of hyaluronan in myelin sheaths of the rat central and rat and human peripheral nervous systems using hyaluronan-binding protein-gold and link protein-gold

Neuroscience ◽

10.1016/0306-4522(92)90417-z ◽

1992 ◽

Vol 48 (3) ◽

pp. 737-744 ◽

Cited By ~ 30

Author(s):

P.S. Eggli ◽

J. Lucocq ◽

P. Ott ◽

W. Graber ◽

E. van der Zypen

Keyword(s):

Binding Protein ◽

Ultrastructural Localization ◽

Nervous Systems ◽

Link Protein ◽

Myelin Sheaths ◽

Peripheral Nervous Systems ◽

Hyaluronan Binding

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In silico Screening and Molecular Interaction Studies of Tetrahydrocannabinol and its Derivatives with Acetylcholine Binding Protein

Current Chemical Biology ◽

10.2174/2212796812666180416145232 ◽

2018 ◽

Vol 12 (2) ◽

pp. 181-190 ◽

Cited By ~ 5

Author(s):

Priya P. Panigrahi ◽

Ramit Singla ◽

Ankush Bansal ◽

Moacyr Comar Junior ◽

Vikas Jaitak ◽

...

Keyword(s):

Molecular Interaction ◽

In Silico ◽

Binding Protein ◽

In Silico Screening ◽

Acetylcholine Binding Protein ◽

Interaction Studies

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Section Review: Central & Peripheral Nervous Systems: Disorders of sexual response: Pioneering new pharmaceutical and therapeutic opportunities

Expert Opinion on Investigational Drugs ◽

10.1517/13543784.4.7.621 ◽

1995 ◽

Vol 4 (7) ◽

pp. 621-636 ◽

Cited By ~ 2

Author(s):

Mark M. Foreman

Keyword(s):

Sexual Response ◽

Nervous Systems ◽

Peripheral Nervous Systems

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Synapsin I (protein I), a nerve terminal-specific phosphoprotein. I. Its general distribution in synapses of the central and peripheral nervous system demonstrated by immunofluorescence in frozen and plastic sections.

The Journal of Cell Biology ◽

10.1083/jcb.96.5.1337 ◽

1983 ◽

Vol 96 (5) ◽

pp. 1337-1354 ◽

Cited By ~ 345

Author(s):

P De Camilli ◽

R Cameron ◽

P Greengard

Keyword(s):

Nervous System ◽

Detailed Examination ◽

Specific Protein ◽

Nerve Cells ◽

General Distribution ◽

Synapsin I ◽

Nervous Systems ◽

Synaptic Region ◽

Specific Localization ◽

Peripheral Nervous Systems

Synapsin I (formerly referred to as protein I) is the collective name for two almost identical phosphoproteins, synapsin Ia and synapsin Ib (protein Ia and protein Ib), present in the nervous system. Synapsin I has previously been shown by immunoperoxidase studies (De Camilli, P., T. Ueda, F. E. Bloom, E. Battenberg, and P. Greengard, 1979, Proc. Natl. Acad. Sci. USA, 76:5977-5981; Bloom, F. E., T. Ueda, E. Battenberg, and P. Greengard, 1979, Proc. Natl. Acad. Sci. USA 76:5982-5986) to be a neuron-specific protein, present in both the central and peripheral nervous systems and concentrated in the synaptic region of nerve cells. In those preliminary studies, the occurrence of synapsin I could be demonstrated in only a portion of synapses. We have now carried out a detailed examination of the distribution of synapsin I immunoreactivity in the central and peripheral nervous systems. In this study we have attempted to maximize the level of resolution of immunohistochemical light microscopy images in order to estimate the proportion of immunoreactive synapses and to establish their precise distribution. Optimal results were obtained by the use of immunofluorescence in semithin sections (approximately 1 micron) prepared from Epon-embedded nonosmicated tissues after the Epon had been removed. Our results confirm the previous observations on the specific localization of synapsin I in nerve cells and synapses. In addition, the results strongly suggest that, with a few possible exceptions involving highly specialized neurons, all synapses contain synapsin I. Finally, immunocytochemical experiments indicate that synapsin I appearance in the various regions of the developing nervous system correlates topographically and temporally with the appearance of synapses. In two accompanying papers (De Camilli, P., S. M. Harris, Jr., W. B. Huttner, and P. Greengard, and Huttner, W. B., W. Schiebler, P. Greengard, and P. De Camilli, 1983, J. Cell Biol. 96:1355-1373 and 1374-1388, respectively), evidence is presented that synapsin I is specifically associated with synaptic vesicles in nerve endings.

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