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Synapsin I, is the collective name for Synapsin Ia and Synapsin Ib, two nearly identical that in humans are encoded by the SYN1 gene. In its phosphorylation form, Synapsin I may also be referred to as phosphosynaspin I. Synapsin I is the first of the proteins in the synapsin family of phosphoproteins in the synaptic vesicles present in the central and peripheral nervous systems. Synapsin Ia and Ib are close in length and almost the same in make up, however, Synapsin Ib stops short of the last segment of the C-terminal in the amino acid sequence found in Synapsin Ia.
The phosphoprotein plays a role in regulation of Axon guidance and synaptogenesis. The protein serves as a substrate for several different and phosphorylation may function in the regulation of this protein in the nerve terminal.
Synapsin I is found in two isoforms of the protein, Synapsin Ia and Synapsin Ib, with Synapsin Ib being a slightly shorter version of the protein. Both Synapsin I proteins are highly basic with a pI in the range of 10.3 and 10.2, respectively. Both isoforms are phosphorylated at identical locations within their protein sequences at the same three serine residues.
Synapsin I phosphoproteins make up approximately 6% of the total protein in synaptic vesicles. Among bovine, rat, and human it has been shown to be 95% homologous, with the central 'C' domain evolutionarily conserved. This phosphoprotein is loosely associated with the vesicular membrance and is easily dissociated by treatment with a salt, versus a detergent being required for its removal from the membrane.
Rich in the amino acids proline and glycine, the compositional and structural natures of this protein are somewhat similar to collagen. This aided in the early determination of its structure using collagenase, which was later confirmed by amino acid sequencing and modern techniques. Cleavage of synapsin I by collagenase fragments the elongated C-terminal and leaves the globular N-terminal domain intact.
Amino acid sequencing has shown that synapsin I has common N-terminals across both isoforms and shares the same N-terminal as synapsin II. Synapsin I isoforms differ from synapsin II isoforms in their C-terminal domains as well. Further research has been done on the interactions of synapsin I, synapsin II, and synapsin III with each other to create heterodimers of the proteins in COS cells.
The N-terminal globular domain contains three sites: the cAMP-dependent protein kinase-mediated phosphorylation site near the end in domain A, and two sites further in, in domain B, mediated by mitogen-activated protein kinase (MAP kinase). The tail portion of the protein, the C-terminal end, bears three phosphorylation sites: two sites at which calcium/calmodulin dependent protein kinase II acts, and a third site at which MAP kinase and cyclin-dependent protein kinase (CDK) acts. Specificity for calcium/calmodulin dependent protein kinase binding to Synapsin I is very high in comparison to other substrate proteins. Cyclic AMP-dependent protein kinase is unique in its mechanism of activation. The protein kinase is composed of two regulatory (R) subunits and two catalytic (C) subunits, creating a tetrameric holoenzyme. Cyclic AMP binds to the regulatory subunits of cAMP-dependent protein kinase and causes the dissociation of its regulatory subunits from the catalytic subunits, generating the active form of the kinase. This active form of the protein kinase catalyses the phosphorylation of Synapsin I. The phosphorylated form of Synapsin I is referred to as phosphosynapsin I.
Depolarization of the presynaptic membrane induces a calcium ion influx into the axonal nerve terminal of neurons, and increases the intracellular concentration of calcium ions. Synapsin I was shown to be phosphorylated by this calcium influx. The calcium ion, Ca2+, binds to calmodulin to form a calcium/calmodulin complex which then activates the calcium/calmodulin-dependent protein kinase, in turn triggering phosphorylation. Calcium/calmodulin-dependent phosphorylation of synapsin I causes dissociation of synapsin I from the vesicular membrane.
In the nerve terminal ending, there are two pools of synaptic vesicles, the reserve pool and the ready-release pool. The reserve pool refers to the synaptic vesicles that are not ready to release neurotransmitters and the ready-release pool refers to the vesicles which are primed to release their neurotransmitters across the presynaptic cytoplasmic membrane and into the synaptic cleft. The removal of Synapsin I from synaptic vesicles is thought to mobilize synaptic vesicles from the reserve pool to the release-ready pool, thereby modulating neurotransmitter release. Since it is only present in the vesicles in the reserve pool, the non-phosphorylated form of Synapsin I is considered to be an inhibitory regulator of neurotransmission.
The novel techniques used to discover Synapsin I, were a combination of SDS gel electrophoresis and autoradiography developed by Tetsufumi Ueda in Greengard’s laboratory, that significantly enhanced the way proteins activated by phosphorylation could be observed. More specifically, this was accomplished by autoradiography measuring the radioactivity of the individual protein bands phosphorylated by radioactive adenosine triphosphate. Hiroo Maeno, a lab colleague, assisted with the sample preparations and radio-labelling ATP with P-32 at the gamma phosphate.
The discovery of the synaptic membrane protein and the methodology by which it was discovered, are considered both groundbreaking advancements in the analysis of phosphorylated proteins, and introduced the identification of specific proteins.
Synapsin I is also the first collagenous protein to be described in the nervous system.
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