[Lewy bodies in Parkinson's disease: histological, immunohistochemical, and interferometric examinations]. / Tel'tsa Levi pri bolezni Parkinsona (gistologicheskoe, immunogistokhimicheskoe i interferometricheskoe issledovanie).

OBJECTIVE: To quantify the morphochemical characteristics of Lewy bodies detected in the substantia nigra in patients with Parkinson's disease (PD). MATERIAL AND METHODS: The investigators studied the localization of alpha-synuclein (α-Syn) and the distribution of neurofilament protein and synaptophysin by immunohistochemical assas and compared with the results of interferometry and computer-assisted morphometry of Lewy bodies in the autopsy specimens of the substantia nigra from PD patients. RESULTS: Three groups of synuclein-positive aggregates differing in shape were identified. Mature Lewy bodies had a rounded shape, a concentric structure, a poorly stained core, and, as compared with neuropil, a high phase difference value. Comparison of the localization of α-Syn, neurofilaments, and synaptophysin showed that immunostaining of neurofilaments in the peripheral layer of Lewy bodies was shifted closer to the nucleus and the localization of synaptophysin and α-Syn coincided. CONCLUSION: Synuclein-positive protein aggregates showed heterogeneity in structure, shape, and protein composition in PD. The localization of neurofilament protein and synaptophysin in Lewy bodies attests that the cytoskeleton and neuronal synaptic vesicle trafficking in the substantia nigra are impaired in BP.

[Simultaneous demonstration of glutamate decarboxylase and synaptophysin in paraffin sections of rat cerebellum].

The article presents highly reproducible and inexpensive protocol for simultaneous demonstration of glutamate decarboxylase (GAD67), the key enzyme of gamma-aminobutyric acid (GABA) synthesis and synaptophysin (SYP), a marker protein of synaptic vesicles using confocal laser microscopy. In the cerebellar cortex, GAD labels Purkinje cells and pinceaux in their basal parts and is unevenly distributed in the neuropil of molecular and granular layers. SYP clearly marks the contours of large dendrites of Purkinje cells in molecular layer, while in the granular layers it labels parts of cerebellar glomeruli--the terminals of the mossy fibers. GAD-immunopositive structures (GABA-ergic axons of stellate cells--Golgi cells) are often located at periphery of the glomeruli. In the peripheral zone of the glomeruli, colocalization of GAD- and SYP-immunopositive structures was observed, suggesting the presence of GABA-ergic synapses in this zone.

Immunological identification of vesicular nucleotide transporter in intestinal L cells.

It is well established that vesicular nucleotide transporter (VNUT) is responsible for vesicular storage of nucleotides such as ATP, and that VNUT-expressing cells can secrete nucleotides upon exocytosis, playing an important role in purinergic chemical transmission. In the present study, we show that VNUT is expressed in intestinal L cells. Immunohistochemical evidence indicated that VNUT is present in glucagon-like peptide 1 (GLP-1) containing cells in rat intestine. VNUT immunoreactivity is not co-localized with GLP-1, a marker for secretory granules, and synaptophysin, a marker for synaptic-like microvesicles (SLMVs). Essentially the same results were obtained for GLUTag clonal L cells. Sucrose density gradient analysis confirmed that VNUT is present the light fraction, unlike secretory granules. These results demonstrate that intestinal L cells express VNUT in either the unidentified organelles at light density other than secretory granules and SLMVs or a subpopulation of SLMVs, and suggest that L cells are purinergic in nature and secrete nucleotides independent of GLP-1 secretion.

[Hippocampal and cognitive alterations precede amyloid deposition in a mouse model for Alzheimer's disease]. / Alteraciones hipocampales y cambios cognitivos preceden al depósito de placas amiloides en un modelo murino de la enfermedad de Alzheimer.

Although there is strong evidence about neuronal and glial disturbances at advanced stages of Alzheimer's disease, less attention has been directed to early, preamyloid changes that could contribute to the progression of the disease. We evaluated neuronal and glial morphological changes and behavioral disturbances in PDAPP-J20 transgenic (Tg) mice, carrying mutated human APP gene (amyloid precursor protein), at 5 months of age, before brain amyloid deposition occurs. Using NeuN immunohistochemistry we found decreased numbers of pyramidal and granular neurons in the hippocampus associated with a reduction of hippocampal volume in Tg mice compared with controls. Neurogenesis was impaired, evidenced by means of DCX immunohistochemistry in the dentate gyrus. In the CA3 region we found a decreased density of synaptophysin, suggesting synaptic disturbance, but no changes were found in CA1 synaptic spine density. Using confocal microscopy we observed decreased number and cell complexity of GFAP+ astrocytes, indicating potential glial atrophy. Cognitive impairment (novel location recognition test) and increased anxiety (open field) were detected in Tg mice, associated with more c-Fos+ nuclei in the amygdala, possibly indicating a role for emotionality in early stages of the disease. The study of early alterations in the course of amyloid pathology could contribute to the development of diagnostic and preventive strategies.

Immunohistochemical evaluation of neuroreceptors in healthy and pathological temporo-mandibular joint.

AIM: A study was performed on the articular disk and periarticular tissues of the temporo-mandibular joint (TMJ) with immunohistochemical techniques to give evidence to the presence of neuroreceptors (NRec) in these sites. METHODS: The study was carried out on tissue samples obtained from 10 subjects without TMJ disease and from 7 patients with severe TMJ arthritis and arthrosis. We use antibodies directed against following antigens: Gliofibrillary Acidic Protein (GFAP), Leu-7, Myelin Basic Protein (MBP), Neurofilaments 68 kD (NF), Neuron Specific Enolase (NSE), S-100 protein (S-100) and Synaptophysin (SYN). RESULTS: This study revealed that Ruffini's-like, Pacini's-like and Golgi's-like receptors can be demonstrated in TMJ periarticular tissues and that free nervous endings are present in the subsynovial tissues but not within the articular disk. We observed elongated cytoplamic processes of chondrocytes that demonstrated strong S-100 immunoreactivity but they were unreactive with all other antibodies. These cytoplamic processes were more abundant and thicker in the samples obtained from patients with disease TMJ. CONCLUSION: The results of this study confirm that different Nrec are detectable in TMJ periarticular tissues but they are absent within the articular disk. In the latter site, only condrocytic processes are evident, especially in diseased TMJ, and they might have been confused with nervous endings in previous morphological studies. Nevertheless the absence of immunoreactivity for NF, NSE and SYN proves that they are not of neural origin.

Sorting of synaptophysin into special vesicles in nonneuroendocrine epithelial cells.

Synaptophysin is a major transmembrane glycoprotein of a type of small vesicle with an electron-translucent content (SET vesicles), including the approximately 50-nm presynaptic vesicles in neuronal cells, and of similar, somewhat larger (< or = approximately 90 nm) vesicles (SLMV) in neuroendocrine (NE) cells. When certain epithelial non-NE cells, such as human hepatocellular carcinoma PLC cells, were cDNA transfected to synthesize synaptophysin, the new molecules appeared in specific SET vesicles. As this was in contrast to other reports that only NE cells were able to sort synaptophysin away from other plasma membrane proteins into presynaptic- or SLMV-type vesicles, we have further characterized the vesicles containing synaptophysin in transfected PLC cells. Using fractionation and immunoisolation techniques, we have separated different kinds of vesicles, and we have identified a distinct type of synaptophysin-rich, small (30-90-nm) vesicle that contains little, if any, protein of the constitutive secretory pathway marker hepatitis B surface antigen, of the fluid phase endocytosis marker HRP, and of the plasma membrane recycling endosomal marker transferrin receptor. In addition, we have found variously sized vesicles that contained both synaptophysin and transferrin receptor. A corresponding result was also obtained by direct visualization, using double-label immunofluorescence microscopy for the endocytotic markers and synaptophysin in confocal laser scan microscopy and in double-immunogold label electron microscopy. We conclude that diverse non-NE cells of epithelial nature are able to enrich the "foreign" molecule synaptophysin in a category of SET vesicles that are morphologically indistinguishable from SLMV of NE cells, including one type of vesicle in which synaptophysin is sorted away from endosomal marker proteins. Possible mechanisms of this sorting are discussed.

The t-SNAREs syntaxin 1 and SNAP-25 are present on organelles that participate in synaptic vesicle recycling.

Syntaxin 1 and synaptosome-associated protein of 25 kD (SNAP-25) are neuronal plasmalemma proteins that appear to be essential for exocytosis of synaptic vesicles (SVs). Both proteins form a complex with synaptobrevin, an intrinsic membrane protein of SVs. This binding is thought to be responsible for vesicle docking and apparently precedes membrane fusion. According to the current concept, syntaxin 1 and SNAP-25 are members of larger protein families, collectively designated as target-SNAP receptors (t-SNAREs), whose specific localization to subcellular membranes define where transport vesicles bind and fuse. Here we demonstrate that major pools of syntaxin 1 and SNAP-25 recycle with SVs. Both proteins cofractionate with SVs and clathrin-coated vesicles upon subcellular fractionation. Using recombinant proteins as standards for quantitation, we found that syntaxin 1 and SNAP-25 each comprise approximately 3% of the total protein in highly purified SVs. Thus, both proteins are significant components of SVs although less abundant than synaptobrevin (8.7% of the total protein). Immunoisolation of vesicles using synaptophysin and syntaxin specific antibodies revealed that most SVs contain syntaxin 1. The widespread distribution of both syntaxin 1 and SNAP-25 on SVs was further confirmed by immunogold electron microscopy. Botulinum neurotoxin C1, a toxin that blocks exocytosis by proteolyzing syntaxin 1, preferentially cleaves vesicular syntaxin 1. We conclude that t-SNAREs participate in SV recycling in what may be functionally distinct forms.

Structure of synaptophysin: a hexameric MARVEL-domain channel protein.

Synaptophysin I (SypI) is an archetypal member of the MARVEL-domain family of integral membrane proteins and one of the first synaptic vesicle proteins to be identified and cloned. Most all MARVEL-domain proteins are involved in membrane apposition and vesicle-trafficking events, but their precise role in these processes is unclear. We have purified mammalian SypI and determined its three-dimensional (3D) structure by using electron microscopy and single-particle 3D reconstruction. The hexameric structure resembles an open basket with a large pore and tenuous interactions within the cytosolic domain. The structure suggests a model for Synaptophysin's role in fusion and recycling that is regulated by known interactions with the SNARE machinery. This 3D structure of a MARVEL-domain protein provides a structural foundation for understanding the role of these important proteins in a variety of biological processes.

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.

A novel enzyme-linked immunosorbent assay for determination of synaptophysin as compared with other quantification procedures.

A two-sided enzyme-linked immunosorbent assay (ELISA) has been established for reliable, specific and sensitive determination of synaptophysin (SYN), an intrinsic membrane protein of the small synaptic vesicles. This ELISA used a highly specific monoclonal antibody (SY 38) as capture reagent and a specific SYN antiserum in combination with a secondary peroxidase-conjugated antibody for detection. Calibration was carried out with immunoaffinity-purified SYN from porcine cortex. The sensitivity was found to be improved substantially when the ELISA was compared with previously used dot-immunobinding assays. This ELISA allowed rapid and reliable determination of SYN from detergent lysed homogenates, partially and highly purified preparations of rat, porcine and human brain. SYN was determined in highly purified small synaptic vesicles, and it was calculated to be 5.8% of total detergent solubilized protein.

Cortical cell loss in asymptomatic cats experimentally infected with feline immunodeficiency virus.

Specific pathogen-free cats experimentally infected with feline immunodeficiency virus (FIV) were used to evaluate the development of central nervous system changes during the asymptomatic stages of viral infection. The brains of asyptomatic cats were examined at postinoculation times ranging from 8 weeks to 3 years for changes in neuron density, glutamate receptor density, and synaptophysin immunoreactivity. At 2-3 years postinoculation a small decrease in neuronal density was found in layers 2-3 and layer 5 of the frontal cortex (-14.4%), parietal cortex (-18.1%), and striatum (-29.5%). The only other indications of pathology within these regions were a mild diffuse astrogliosis, occasional microglial nodules, and the accumulation of satellite cells around selected neurons. An average loss of large neurons of 56-68% was seen in the cortex of four random source cats euthanized with AIDS. These values contrasted with the absence of any significant cell loss in FIV-infected cats 18 weeks after inoculation or FIV-negative controls. The loss of neurons in the asymptomatic cats showed a significant positive correlation with a decrease in the blood CD4:CD8 ratios. Morphometric evaluation of synaptic terminal densities immunocytochemically stained with synaptophysin revealed a significant increase in the asymptomatic cats at 2-3 years postinoculation that correlated negatively with the CD4:CD8 ratios. Random source AIDS cats showed a 34% decrease in synaptophysin-immunoreactive profiles. Glutamate binding in the cortex did not change significantly in the asymptomatic cats (4-7% decline). Thus, experimentally infected specific pathogen-free cats show a loss of cortical neurons similar to what has been observed in postmortem studies of humans infected with HIV. The detection of neuronal loss during the asymptomatic stage of disease and the correlation with the peripheral CD4:CD8 cell ratios indicate that neurodegeneration may progress in parallel with peripheral disease.

Membrane-bound choline-O-acetyltransferase in rat hippocampal tissue is associated with synaptic vesicles.

Some of the choline-O-acetyltransferase (EC 2.3.1.6; ChAT) in rat hippocampal nerve terminals is non-ionically associated with membranes. The intent of the present report was to ascertain whether any of this membrane-bound ChAT might be associated with synaptic vesicles. To test this possibility, synaptosomal (P2) fractions were hypo-osmotically shocked in water, salt washed to remove ionically-bound ChAT, subjected to sucrose density gradient centrifugation, and the activity of ChAT compared with the amount of occluded ACh in the various subcellular fractions. A peak of ChAT and occluded ACh occurred in that fraction of the gradient (0.4 M sucrose) acknowledged to be enriched in synaptic vesicles. In other experiments, Immunobeads coated with an antibody directed against the synaptic vesicle specific SV2 protein immunoprecipitated both ChAT and occluded ACh from the 0.4 M sucrose fraction, but no other fraction. Immunobeads coated with an anti-ChAT antiserum immunoprecipitated synaptophysin from the 0.4 M sucrose fraction, an effect which was blocked by pretreatment of the anti-ChAT Immunobeads with purified ChAT. These results suggest that some of the membrane-bound ChAT in rat hippocampal nerve terminals is associated with cholinergic synaptic vesicles.

Alteraciones hipocampales y cambios cognitivos preceden al deposito de placas amiloides en un modelo murino de la enfermedad de Alzheimer

Existen múltiples evidencias de alteraciones neuronales y gliales en etapas avanzadas de la enfemedad de Alzheimer con abundantes depósitos cerebrales de beta amiloide, aunque hay pocos datos de cambios tempranos que podrían contribuir al desarrollo de la enfermedad. Evaluamos alteraciones morfológicas neuronales y gliales, y cambios cognitivos y emocionales tempranos en ratones transgénicos PDAPP-J20 (Tg), portadores del gen humano de APP (amyloid precursor protein) mutado, a los 5 meses de edad, aún sin depósitos amiloides en el hipocampo y con niveles bajos de péptidos amiloides cerebrales. Mediante inmunohistoquímica para NeuN, los Tg presentaron menor número de neuronas piramidales y granulares en el hipocampo, junto con un menor volumen de la estructura, en comparación con los controles no transgénicos. La neurogénesis se encontró afectada, evidenciada por reducido número de neuronas DCX+ en el giro dentado. En la región CA3, hubo una menor densidad de sinaptofisina sugiriendo alteraciones sinápticas entre neuronas granulares y piramidales, sin cambios en la densidad de espinas dendríticas en CA1. Utilizando microscopía confocal, observamos una disminución del número de astrocitos GFAP+ con una reducción de la complejidad celular, sugiriendo atrofia glial. Se detectó un déficit cognitivo (reconocimiento de localización novedosa de un objeto) y un aumento de la ansiedad (campo abierto) en los Tg, con aumento en los núcleos c-Fos+ en amígdala, evidenciando el papel de la emocionalidad en los inicios de la enfermedad. El estudio de las alteraciones iniciales en la enfermedad amiloide podría contribuir al desarrollo de métodos de diagnóstico temprano y de terapéutica preventiva.

Although there is strong evidence about neuronal and glial disturbances at advanced stages of Alzheimer’s disease, less attention has been directed to early, pre-amyloid changes that could contribute to the progression of the disease. We evaluated neuronal and glial morphological changes and behavioral disturbances in PDAPP-J20 transgenic (Tg) mice, carrying mutated human APP gene (amyloid precursor protein), at 5 months of age, before brain amyloid deposition occurs. Using NeuN immunohistochemistry we found decreased numbers of pyramidal and granular neurons in the hippocampus associated with a reduction of hippocampal volume in Tg mice compared with controls. Neurogenesis was impaired, evidenced by means of DCX immunohistochemistry in the dentate gyrus. In the CA3 region we found a decreased density of synaptophysin, suggesting synaptic disturbance, but no changes were found in CA1 synaptic spine density. Using confocal microscopy we observed decreased number and cell complexity of GFAP+ astrocytes, indicating potential glial atrophy. Cognitive impairment (novel location recognition test) and increased anxiety (open field) were detected in Tg mice, associated with more c-Fos+ nuclei in the amygdala, possibly indicating a role for emotionality in early stages of the disease. The study of early alterations in the course of amyloid pathology could contribute to the development of diagnostic and preventive strategies.

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.

Large-scale purification of synaptophysin and quantification with a newly established enzyme-linked immunosorbent assay.

Synaptophysin (SYP I), an integral membrane protein, was purified on a large scale (0.55 - 2.7 mg) from isolated small synaptic vesicles (SSV) of porcine cortex. In order to achieve this, a conventional purification procedure which consists of size exlusion chromatography, hydrophobic interaction chromatography and chromatofocusing has been developed. This procedure was compared with purification of SYP I by immunoaffinity chromatography. The elution patterns of both procedures were monitored using sodium dodecylsulfate gel electrophoresis (SDS-PAGE) with subsequent Coomassie blue staining of proteins and simultaneous immunoblotting with SYP I-specific antibody. Contaminating proteins with relative molecular masses (M(r)) very similar to SYP I could be removed during the process of purification, demonstrating that the 38 kDa protein found after Triton X-100 lysis of enriched SSV does not exclusively represent SYP I. A specific antiserum was raised in rabbits using a highly purified preparation of SYP I. This antiserum was used in combination with a monoclonal antibody to establish a specific and sensitive enzyme-linked immunosorbent assay (ELISA) which allowed rapid and reliable quantification of this hydrophobic membrane protein in all purification steps, starting with Triton X-100-lysed brain homogenates. Using this ELISA, the concentration of SYP I in highly purified SSV was determined to be 5.8% of solubilized protein.

Differential extraction of proteins from paraformaldehyde-fixed cells: lessons from synaptophysin and other membrane proteins.

While investigating the localization of synaptophysin in PC12 cells using immunofluorescence microscopy, we noticed a striking difference in its apparent subcellular distribution depending on whether digitonin or Triton X-100 was used as permeabilization agent of paraformaldehyde (PFA)-fixed cells. We found that this difference was due to epitope inaccessibility in the digitonin-treated cells combined with an almost quantitative extraction of the antigen on Triton X-100 permeabilization. Both phenomena were differential with respect to the various synaptophysin-containing compartments. The extraction of antigen from PFA-fixed cells was also seen with other membrane proteins but not with cytosolic proteins and proteins in the lumen of the secretory pathway. Significantly, some of the membrane proteins were extracted from the PFA-fixed cells in higher-molecular-weight forms which we believe represent their in vivo oligomeric states. The implications of our observations are discussed with respect to the method of immunofluorescence microscopy and also to the possible use of paraformaldehyde as an in vivo crosslinker for the study of membrane protein quaternary structure.

Synaptobrevin binding to synaptophysin: a potential mechanism for controlling the exocytotic fusion machine.

The synaptic vesicle protein synaptobrevin (VAMP) has recently been implicated as one of the key proteins involved in exocytotic membrane fusion. It interacts with the synaptic membrane proteins syntaxin I and synaptosome-associated protein (SNAP)-25 to form a complex which precedes exocytosis [Söllner et al. (1993b) Cell, 75, 409-418]. Here we demonstrate that the majority of synaptobrevin is bound to the vesicle protein synaptophysin in detergent extracts. No syntaxin I was found in this complex when synaptophysin-specific antibodies were used for immunoprecipitation. Conversely, no synaptophysin was associated with the synaptobrevin-syntaxin I complex when syntaxin-specific antibodies were used for immunoprecipitation. Thus, the synaptobrevin pool bound to synaptophysin is not available for binding to syntaxin I and SNAP-25, and vice versa. Synaptobrevin-synaptophysin binding was also demonstrated by chemical cross-linking in isolated nerve terminals. Furthermore, recombinant synaptobrevin II efficiently bound synaptophysin and its isoform synaptoporin, but not the more distantly related synaptic vesicle protein p29. Recombinant synaptobrevin I bound with similar efficiency, whereas the non-neuronal isoform cellubrevin displayed a lower affinity towards synaptophysin. Treatment with high NaCl concentrations resulted in a dissociation of the synaptobrevin-synaptophysin complex. In addition, the interaction of synaptobrevin with synaptophysin was irreversibly abolished by low amounts of SDS, while the interaction with syntaxin I was enhanced. We conclude that synaptophysin selectively interacts with synaptobrevin in a complex which excludes the t-SNAP receptors syntaxin I and SNAP-25, suggesting a role for synaptophysin in the control of exocytosis.

Purification and cDNA cloning of mouse BM89 antigen shows that it is identical with the synaptic vesicle protein synaptophysin.

The BM89 antigen, first identified in porcine brain by means of a monoclonal antibody, is a neuron-specific molecule widely distributed in the mammalian central and peripheral nervous system (Merkouri and Matsas: Neuroscience 50:53-68, 1992). Here we describe the purification of BM89 antigen from porcine and mouse brain by immunoaffinity chromatography using, respectively, the previously described BM89 monoclonal antibody which belongs to the IgM class and a specific polyclonal antibody generated in the present study. This antibody was also used for the cDNA cloning of the BM89 antigen from mouse brain. cDNA sequencing revealed that the mouse BM89 antigen is identical with the synaptic vesicle protein synaptophysin which is implicated in the control of regulated exocytosis and neurotransmitter release. Mouse BM89 antigen/synaptophysin exhibits, except for one extra amino acid, 100% identity with rat synaptophysin and substantial sequence identity with bovine (92.5% identity) and human (94.8% identity) synaptophysin, but only 59.8% identity with Torpedo synaptophysin. Northern and Western blot analyses confirmed that the mouse BM89 antigen/synaptophysin is expressed only in neural tissues.

Increase of synaptic density and memory retention by a peptide representing the trophic domain of the amyloid beta/A4 protein precursor.

The secreted form (sAPP) of the Alzheimer amyloid beta/A4 protein precursor (APP) has been shown to be involved in the in vitro regulation of fibroblast growth and neurite extension from neuronal cells. The active site of sAPP responsible for these functions is within a small domain just C-terminal to the Kunitz-type protease inhibitor (KPI) insertion site. We report here that a 17-mer peptide, containing this active domain of sAPP, can induce cellular and behavioral changes when infused into rat brains. After 2 weeks of APP 17-mer peptide infusion, the animals were tested for reversal learning and memory retention and were sacrificed for morphological examination of brains. We found that administration of the APP 17-mer peptide resulted in an 18% increase in the number of presynaptic terminals in the frontoparietal cortex. At the behavioral level, 17-mer-infused animals with nonimpaired learning capability showed an increased memory retention that seemed to interfere with reversal learning performance. This APP 17-mer effect on memory retention was not observed in animals with impaired initial learning capacity. These results suggest that APP is involved in memory retention through its effect on synaptic structure.

Neuronotypic differentiation results in reduced levels and altered distribution of synaptophysin in PC12 cells.

Several synaptic vesicle proteins including synaptophysin and p65/synaptotagmin are expressed by the pheochromocytoma cell line PC12. Stimulation of these cells with nerve growth factor for 7 days induces morphologic neuronotypic differentiation, but the levels of synaptophysin are markedly reduced. Stimulation with cyclic AMP analogs also produces neuronotypic differentiation of PC12 cells, and the degree of morphologic differentiation induced by these agents parallels their ability to effect reduction in synaptophysin levels. By contrast, levels of p65/synaptotagmin are increased following neuronotypic differentiation. The contrasting effects of neuronotypic differentiation on levels of synaptophysin and p65/synaptotagmin indicate potential differences in the regulation of these proteins in PC12 cells. Immunocytochemical labeling of undifferentiated PC12 cells reveals concentrations of synaptophysin in the perinuclear region. After neuronotypic differentiation, there is reduction in perinuclear labeling and concentration of label in swellings along PC12 cell processes. At the ultrastructural level, synaptophysin labeling is found on similar organelles in both undifferentiated and nerve growth factor-stimulated PC12 cells. Although the highest labeling densities were seen on small clear vesicles, specific labeling was also seen on dense core vesicles. The presence of synaptophysin on both small clear vesicles and dense core vesicles indicates potential functional similarities in these vesicle types. The changes in the levels and immunocytochemical distribution of synaptophysin after neuronotypic differentiation suggest possible functional heterogeneity among morphologically similar populations of small clear vesicles.