Synapsin I phosphorylated by Ca2+, calmodulin-dependent protein kinase II is able to self-degrade

Determination of synapsin I and synaptophysin in body fluids by two-site enzyme-linked immunosorbent assays

Two-site enzyme-linked immunosorbent assays (ELISA) have been established for the specific and sensitive determination of two membrane proteins of the small synaptic vesicles (SSV), namely: peripheral synapsin I and integral synaptophysin. The ELISA used highly specific capture monoclonal antibodies (mAB) and polyclonal antibodies (pAB) as detectors. For synapsin I, the mAB were newly generated, whereas for synaptophysin, the commercially available mAB SY38 was applied. In order to calibrate the ELISA and to raise pAB, both proteins were purified in the mg-range. Synapsin I was purified by conventional means from human and porcine brain and synaptophysin was purified by immunoaffinity chromatography from porcine brain. Using the ELISA, neither synapsin I nor synaptophysin could be determined in serum or cerebrospinal fluid (CSF) from healthy donors or patients suffering various neurological disorders or pheochromocytomas. For this reason, the degradation of both proteins in serum and CSF was investigated. With the exception of synaptophysin measured in serum, both proteins exhibited fast rates of degradation. Despite the negative results in human body fluids, the two ELISA are appropriate for the quantification of these membrane proteins in neuronal or neuroendocrine cell extracts or preparations of SSV.

Vesicle-associated proteins and calcium in nerve terminals of chick ciliary ganglia during development of facilitation

1. The developmental appearance of synaptic vesicle-associated proteins and nerve terminal calcium ([Ca2+]i) sequestering processes were determined for the chick ciliary ganglia in relation to the maturation of the different phase of increased efficacy of transmitter release following nerve impulses. The maturation phases studied were from stages 34-35, at the time of synapse formation, to stage 46 at hatching. 2. Western blots and immunohistochemical localization indicated that synaptotagmin 1 and synapsin IIa were detectable at stages 34-35 and were clearly localized at the nerve terminals by stage 37. Syntaxin was clearly localized at the nerve terminals at stage 34. 3. The relative size of the postganglionic compound action potential, used to measure the transmission efficacy through the ganglion, showed that the slope of the relationship between log efficacy and log extracellular calcium concentration ([Ca2+]o) in low [Ca2+]o was about 4 by stage 46. 4. A mature facilitatory mechanism for transmission was not present at stage 34 and did not emerge until stage 38. A mature augmentation was not present at stages 34 or 38 and was not established until stages 41-42. Post-tetanic potentiation (PTP) was not present at stage 34; it was evident at stages 37-38 and only reached maturity by stages 41-42. 5. The time course of calcium changes in the nerve terminals following trains of impulses that give rise to facilitation, augmentation and PTP was determined for different stages of development using the indicator Calcium Green-1 in the nerve terminal. The mature time course of the phases of calcium decline in the nerve terminal associated with facilitation and augmentation was observed as early as stage 38, whereas that of the PTP phase did not mature until after stage 42. 6. These results are discussed in terms of the maturation of the vesicle-associated proteins and calcium influx into the terminal following trains of impulses that give rise to the different components of increased synaptic efficacy.

The synaptic vesicle and its targets

Synaptic vesicles play the central role in synaptic transmission. They are regarded as key organelles involved in synaptic functions such as uptake, storage and stimulus-dependent release of neurotransmitter. In the last few years our knowledge concerning the molecular components involved in the functioning of synaptic vesicles has grown impressively. Combined biochemical and molecular genetic approaches characterize many constituents of synaptic vesicles in molecular detail and contribute to an elaborate understanding of the organelle responsible for fast neuronal signalling. By studying synaptic vesicles from the electric organ of electric rays and from the mammalian cerebral cortex several proteins have been characterized as functional carriers of vesicle function, including proteins involved in the molecular cascade of exocytosis. The synaptic vesicle specific proteins, their presumptive function and targets of synaptic vesicle proteins will be discussed. This paper focuses on the small synaptic vesicles responsible for fast neuronal transmission. Comparing synaptic vesicles from the peripheral and central nervous systems strengthens the view of a high conservation in the overall composition of synaptic vesicles with a unique set of proteins attributed to this cellular compartment. Synaptic vesicle proteins belong to gene families encoding multiple isoforms present in subpopulations of neurons. The overall architecture of synaptic vesicle proteins is highly conserved during evolution and homologues of these proteins govern the constitutive secretion in yeast. Neurotoxins from different sources helped to identify target proteins of synaptic vesicles and to elucidate the molecular machinery of docking and fusion. Synaptic vesicle proteins and their markers are useful tools for the understanding of the complex life cycle of synaptic vesicles.

Simultaneous purification of the neuroproteins synapsin I and synaptophysin

A procedure for the simultaneous purification of synapsin I and synaptophysin from calf brain was developed. Demyelinated membranes were extracted with 2% Triton X-100 and 2 M KCl. The extracted proteins were separated by weak cation-exchange chromatography on carboxymethyl-Sepharose Fast Flow. Synaptophysin was finally purified by preparative sodium dodecyl sulphate-polyacrylamine gel electrophoresis and synapsin I by affinity chromatography using a calmodulin-Sepharose column. The recovery obtained was 40 micrograms/g in brain for synaptophysin and 25 micrograms/g in brain for synapsin I.