Gradients of protein kinase C substrate phosphorylation in primate visual system peak in visual memory storage areas

Spinogenesis and Pruning in the Anterior Ventral Inferotemporal Cortex of the Macaque Monkey: An Intracellular Injection Study of Layer III Pyramidal Cells

Pyramidal cells grow and mature at different rates among different cortical areas in the macaque monkey. In particular, differences across the areas have been reported in both the timing and magnitude of growth, branching, spinogenesis, and pruning in the basal dendritic trees of cells in layer III. Presently available data suggest that these different growth profiles reflect the type of functions performed by these cells in the adult brain. However, to date, studies have focused on only a relatively few cortical areas. In the present investigation we quantified the growth of the dendritic trees of layer III pyramidal cells in the anterior ventral portion of cytoarchitectonic area TE (TEav) to better comprehend developmental trends in the cerebral cortex. We quantified the growth and branching of the dendrities, and spinogenesis and pruning of spines, from post-natal day 2 (PND2) to four and a half years of age. We found that the dendritic trees increase in size from PND2 to 7 months of age and thereafter became smaller. The dendritic trees became increasingly more branched from PND2 into adulthood. There was a two-fold increase in the number of spines in the basal dendritic trees of pyramidal cells from PND2 to 3.5 months of age and then a 10% net decrease in spine number into adulthood. Thus, the growth profile of layer III pyramidal cells in the anterior ventral portion of the inferotemporal cortex differs to that in other cortical areas associated with visual processing.

Early stages of memory formation in filial imprinting: Fos-like immunoreactivity and behavior in the domestic chick

Early stages of memory formation in filial imprinting were studied in domestic chicks. Chicks trained for 15 min showed strong imprinting, demonstrated by a strong preference for their training stimulus, and the time course of this preference over 2 days after training was similar to that of chicks trained for 60 min. The chicks therefore learned characteristics of the training stimulus very early during training. The intermediate and medial hyperstriatum ventrale (IMHV) is a part of the chick forebrain that is crucial for imprinting. Previous experiments have shown a learning-specific increase in Fos-like immunoreactivity, used as a marker of neuronal activity, in the IMHV after training for 60 min. The time course of Fos expression in the IMHV was measured after training for 15 min and 60 min. The same pattern of expression was found for both training times, showing a peak 120 min after the start of training. The time course of expression was stimulus-dependent. Fos expression in the IMHV, but not the hippocampus, was significantly correlated with strength of imprinting. It is concluded that the learning-specific change in Fos expression in the IMHV is associated with very early components of memory formation.

Altered expression and phosphorylation of myristoylated alanine-rich C kinase substrate (MARCKS) in postmortem brain of suicide victims with or without depression

Myristoylated alanine-rich C kinase substrate (MARCKS), an acidic, heat-stable protein, is involved in important physiological functions such as neurotransmitter release and re-uptake. It is also a substrate for phosphorylation by protein kinase C (PKC) and has been shown to play a role in the pathophysiology of mood disorders. In this study, protein and mRNA expression of MARCKS as well as phosphorylation of MARCKS were determined in the prefrontal cortex (PFC) and hippocampus of postmortem brain obtained from suicide victims, with or without depression, and normal control subjects. There were no significant differences in mRNA and protein levels of MARCKS between suicide subjects and controls. However, protein levels of MARCKS were significantly increased in the membrane but not in cytosol fraction of PFC and hippocampus obtained from depressed suicide subjects as compared to normal controls. When PKC-mediated MARCKS phosphorylation was determined, it was observed that MARCKS phosphorylation was significantly decreased in the membrane fraction of PFC and hippocampus obtained from total suicide subjects as well as depressed and non-depressed suicide subjects compared with control population. Although the mechanism of such alterations in MARCKS in depressed and non-depressed suicide subjects is not clear, results of the present study indicate that an increase in membrane MARCKS is associated with depressed suicide victims and a decrease in MARCKS phosphorylation may be a common feature of suicide victims independent of diagnosis.

Differential expression and regulation of myristoylated alanine-rich C kinase substrate (MARCKS) in the hippocampus of C57/BL6J and DBA/2J mice

The myristoylated alanine-rich C kinase substrate (MARCKS) is a major protein kinase C (PKC) substrate in brain that binds the inner surface of the plasma membrane, calmodulin, and cross-links filamentous actin, all in a PKC phosphorylation-reversible manner. MARCKS has been implicated in hippocampal-dependent learning and long-term potentiation (LTP). Previous studies have shown DBA/2 mice to exhibit poor spatial/contextual learning, impaired hippocampal LTP, and hippocampal mossy fiber hypoplasia, as well as reduced hippocampal PKC activity and expression relative to C57BL/6 mice. In the present study, we assessed the expression (mRNA and protein) and subcellular distribution (membrane and cytolsol) of MARCKS in the hippocampus and frontal cortex of C57BL/6 and DBA/2 mice using quantitative western blotting. In the hippocampus, total MARCKS mRNA and protein levels in C57BL/6J mice were significantly lower ( approximately 45%) compared with DBA/2J mice, and MARCKS protein was observed predominantly in the cytosolic fraction. MARCKS expression in frontal cortex did not differ significantly between strains. To examine the dynamic regulation of MARCKS subcellular distribution, mice from each strain were subjected to 60 min restraint stress and MARCKS subcellular distribution was determined 24 h later. Restraint stress resulted in a significant reduction in membrane MARCKS expression in C57BL/6J hippocampus but not in the DBA/2J hippocampus despite similar stress-induced increases in serum corticosterone. Restraint stress did not affect cytosolic or total MARCKS levels in either strain. Similarly, restraint stress (30 min) in rats also induced a significant reduction in membrane MARCKS, but not total or cytosolic MARCKS, in the hippocampus but not in frontal cortex. In rats, chronic lithium treatment prior to stress exposure reduced hippocampal MARCKS expression but did not affect the stress-induced reduction in membrane MARCKS. Collectively these data demonstrate higher resting levels of MARCKS in the hippocampus of DBA/2J mice compared to C57BL/6J mice, and that acute stress leads to a long-term reduction in membrane MARCKS expression in C57BL/6J mice and rats but not in DBA/2J mice. These strain differences in hippocampal MARCKS expression and subcellular translocation following stress may contribute to the differences in behaviors requiring hippocampal plasticity observed between these strains.

Distribution of alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionate-type glutamate receptor subunits (GluR2/3) along the ventral visual pathway in the monkey

By using immunohistochemical methods, we examined the distribution of cells expressing subunits of alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionate (AMPA)-selective glutamate receptors (GluR2/3) in the cortical areas of the occipitotemporal pathway in monkeys. GluR2/3-immunoreactive (-ir) cells were primarily pyramidal cells; this category, however, also included large stellate cells in layer IVB of the striate cortex (V1) and fusiform cells in layer VI of all the areas examined. GluR2/3 immunoreactivity differed among the areas in laminar distribution and intensity. In V1, GluR2/3-ir cells were identified mainly in layers II, III, IVB, and VI. The prestriate areas V2 and V4 and the inferior temporal areas TEO and TE contained GluR2/3-ir cells in layers II, III, and VI. In the TE, GluR2/3-ir cells were also abundant in layer V. In area 36 of the perirhinal cortex, neurons in layers II, III, V, and VI were labeled in a similar manner to the TE labeling, but with greater staining intensity and numbers, especially in layer V. Thus, GluR2/3 immunoreactivity increased rostrally along the pathway. Within V1 and V2, cells strongly stained for GluR2/3 formed clusters that colocalized with cytochrome oxidase (CO)-rich regions. These distinct laminar and regional distribution patterns of GluR2/3 expression may contribute to the specific physiological properties of neurons within various visual areas and compartments.

Transcriptional and post-transcriptional regulation of a brain growth protein: regional differentiation and regeneration induction of GAP-43

During axonal regeneration synthesis of different growth-associated proteins is increased. As yet there is no clear picture of the specific contribution made by the transcriptional and post-transcriptional machinery that provides the gene products necessary for process outgrowth. Here we focus our study on the transcriptional processes in neurons by using intron-directed in situ hybridization to the primary transcript of a brain growth protein GAP-43. In most brain regions, levels of primary transcript expression of GAP-43 were highly correlated with levels of its mRNA. However, there were notable dissociations: in hippocampal granule cells, high levels of primary transcript were evident yet no GAP-43 mRNA was detected. In locus coeruleus the reverse was true; there were high levels of GAP-43 mRNA but no detectable primary transcript. A primary transcript antitermination mechanism is proposed to explain the first dissociation, and a post-transcriptional mRNA stabilization mechanism to explain the second. Transcriptional activation during nerve regeneration was monitored by assessing primary transcript induction of GAP-43 in mouse facial motor neurons. This induction, as well as its mRNA, was restricted to the side of the facial nerve crush. Increases were first observed at 24 h with a rapid increase in both measures up to 3 days. To our knowledge, this is the first in vivo evidence demonstrating transcriptional activation of a brain growth protein in regenerating neurons. The present study points to the GAP-43 transcriptional mechanism as a key determinant of GAP-43 synthesis. Along with the recruitment of post-transcriptional mechanisms, such synthesis occurs in response to both intrinsic developmental programs and extrinsic environmental signals.

Neurochemical gradients along monkey sensory cortical pathways: calbindin-immunoreactive pyramidal neurons in layers II and III

We examined the distribution of neurons containing immunoreactivity for three calcium-binding proteins, calbindin, parvalbumin and calretinin, as well as nonphosphorylated neurofilament protein, in cortical areas along the ventral and dorsal cortical visual pathways, and in ventrally-directed somatosensory and auditory cortical pathways. Calbindin-immunoreactive pyramidal neurons showed the most prominent regional differences. They were largely restricted to layers II and III and their number monotonically increased from the primary sensory areas to the anteroventral areas along the ventral visual pathway and along the ventrally-directed somatosensory and auditory pathways. The number of calbindin-immunoreactive pyramidal neurons in layers II and III also increased along the dorsal visual pathway, but the number in the last recognized stage of the dorsal visual pathway (area 7a) was significantly smaller than that at the corresponding stage in the ventral visual pathway (TE). The number of calbindin-immunoreactive pyramidal neurons was highest in layers II and III of areas 35/36, TG, and TF/TH, which represent terminal cortical regions of the pathways. These results show neurochemical differences between cortical areas located at early and late stages along serial corticocortical pathways, as well as confirming differences between pyramidal neurons in the supragranular and infragranular layers.

Development of GAP-43 mRNA in the macaque cerebral cortex

To estimate the extent of axonal growth in various areas of the cerebral cortex, we measured the amount of GAP-43 mRNA in the cerebral cortex of developing macaque monkeys. In four areas, i.e., the prefrontal area (FD delta), the temporal association area (TE), the primary somatosensory area (PC), and the primary visual area (OC), the amount of GAP-43 mRNA was measured from the intermediate fetal period [embryonic day 120 (E120)] to the adult stage. In two other areas, i.e., the parietal association area (PG) and the secondary visual area (OB), the amount of GAP-43 mRNA was measured during the postnatal period. The amount of GAP-43 mRNA was highest at E120, decreased roughly exponentially, and approached the asymptote by postnatal day 70 (P70). The amount of GAP-43 mRNA was higher in the association areas (FD delta, TE, and PG) than in the primary sensory areas (PC and OC) during development and at the adult stage. These findings suggest that axonal growth in the cerebral cortex is most exuberant before or during the intermediate fetal period and approximately ends by P70. Furthermore, axonal growth is evidently more intensive in the association areas than in the primary sensory areas during the stage following the intermediate fetal period.

Cortical distribution of neurofibrillary tangles in Alzheimer's disease matches the pattern of neurons that retain their capacity of plastic remodelling in the adult brain

The formation of neurofibrillary tangles in Alzheimer's disease shows a preferential involvement of certain cytoarchitecturally defined cortical areas suggesting systematic differences in regional neuronal vulnerability. The cellular and molecular nature of this selective neuronal vulnerability that follows a certain hierarchy of structural brain organization is largely unknown. In the present study, we compared the regional pattern of tangle density in Alzheimer's disease with systematic regional differences in neuronal plasticity that can be observed both during ageing and in Alzheimer's disease. Changes in dendritic length and arborization of Golgi-impregnated pyramidal neurons were analysed after three-dimensional reconstruction in 12 cortical areas. The intensity of dendritic remodelling that was observed during ageing as well as in Alzheimer's disease was regionally different and decreased in the following order: transentorhinal region > limbic areas (entorhinal region, hippocampus) > non-primary association areas (37, 40, 46) > primary sensory association areas (7, 18, 22) > primary sensory and motor cortex (17, 41, 4). These regional differences of neuronal plasticity follow the same pattern as the regional vulnerability to tangle formation in Alzheimer's disease. The results of the present study provide evidence that a high degree of structural neuronal plasticity might predispose neurons to tangle formation.

GAP-43: an intrinsic determinant of neuronal development and plasticity

Several lines of investigation have helped clarify the role of GAP-43 (FI, B-50 or neuromodulin) in regulating the growth state of axon terminals. In transgenic mice, overexpression of GAP-43 leads to the spontaneous formation of new synapses and enhanced sprouting after injury. Null mutation of the GAP-43 gene disrupts axonal pathfinding and is generally lethal shortly after birth. Manipulations of GAP-43 expression likewise have profound effects on neurite outgrowth for cells in culture. GAP-43 appears to be involved in transducing intra- and extracellular signals to regulate cytoskeletal organization in the nerve ending. Phosphorylation by protein kinase C is particularly significant in this regard, and is linked with both nerve-terminal sprouting and long-term potentiation. In the brains of humans and other primates, high levels of GAP-43 persist in neocortical association areas and in the limbic system throughout life, where the protein might play an important role in mediating experience-dependent plasticity.

Levels of the growth-associated protein GAP-43 are selectively increased in association cortices in schizophrenia

The pathophysiology of schizophrenia may involve perturbations of synaptic organization during development. The presence of cytoarchitectural abnormalities that may reflect such perturbations in the brains of patients with this disorder has been well-documented. Yet the mechanistic basis for these features of the disorder is still unknown. We hypothesized that altered regulation of the neuronal growth-associated protein GAP-43, a membrane phosphoprotein found at high levels in the developing brain, may play a role in the alterations in brain structure and function observed in schizophrenia. In the mature human brain, GAP-43 remains enriched primarily in association cortices and in the hippocampus, and it has been suggested that this protein marks circuits involved in the acquisition, processing, and/or storage of new information. Because these processes are known to be altered in schizophrenia, we proposed that GAP-43 levels might be altered in this disorder. Quantitative immunoblots revealed that the expression of GAP-43 is increased preferentially in the visual association and frontal cortices of schizophrenic patients, and that these changes are not present in other neuropsychiatric conditions requiring similar treatments. Examination of the levels of additional markers in the brain revealed that the levels of the synaptic vesicle protein synaptophysin are reduced in the same areas, but that the abundance of the astrocytic marker of neurodegeneration, the glial fibrillary acidic protein, is unchanged. In situ hybridization histochemistry was used to show that the laminar pattern of GAP-43 expression appears unaltered in schizophrenia. We propose that schizophrenia is associated with a perturbed organization of synaptic connections in distinct cortical associative areas of the human brain, and that increased levels of GAP-43 are one manifestation of this dysfunctional organization.

Distinctions between hippocampus of mouse and rat: protein F1/GAP-43 gene expression, promoter activity, and spatial memory

We began these experiments as an attempt to replicate in the mouse the induction by kainate (KA) of F1/GAP-43 mRNA we observed in adult rat hippocampal granule cells [Mol. Brain Res., 33 (1995) 22-28]. However, even though KA induced behavioral seizures in the mouse similar to those in the rat, neither induction of F1/GAP-43 mRNA nor subsequent mossy fiber sprouting observed in the rat was detected in three different mouse strains. It was also surprising that the distribution of constitutive levels of F1/GAP-43 mRNA in mouse and rat hippocampus was qualitatively different. Indeed, F1/GAP-43 expression in CA3 pyramidal cells was significantly greater in rat than mouse, while F1/GAP-43 expression in CA1 cells of rat and mouse was equivalent using densitometric analysis. Thus, F1/GAP-43 expression in rat is quantitatively higher in CA3 and CA1 pyramidal cells. In mouse, expression was equivalent in these two subfields. In a transgenic mouse bearing a rat F1/GAP-43 promoter-reporter (lacZ) construct (line 252), in-vivo promoter activity of F1/GAP-43 was studied in hippocampal cells. Transgene expression in hippocampal pyramidal subfields, high in CA3, low in CA1 pyramidal cells, paralleled the distribution of rat F1/GAP-43 mRNA levels, not mouse. Differences in the constitutive F1/GAP-43 expression pattern in hippocampus between rat and mouse may therefore be determined by different recognition elements present on the F1/GAP-43 promoter. KA injected into the line 252 transgenic mouse did not activate the rat F1/GAP-43 promoter in mouse hippocampal granule cells. The absence of both F1/GAP-43 mRNA expression induction and promoter activation in mouse granule cells after KA is likely related to genera differences in transcriptional regulatory mechanisms, though post-transcriptional mechanisms cannot be excluded. Since the different hippocampal chemistry of F1/GAP-43 in rat and mouse likely extends to other molecular species, behaviors in rat and mouse that depend on hippocampal function might be different as well. We therefore evaluated spatial memory ability in a delayed matching-to-sample task. In contrast to rat, we were surprised to find no evidence of the ability to learn this task in three different mouse strains. Since interest in mouse genetics in relation to behavior and memory functions of hippocampus is growing, generalizations concerning hippocampal function from studies carried out on the mouse need to be made with caution considering the specific behavioral, pharmacological, and general molecular differences observed here. One can also be opportunistic and exploit the natural variations between these two genera to gain insight into the molecular mechanisms underlying information storage.

Use of a two-hybrid system to investigate molecular interactions of GAP-43

We used the 'interaction trap' (two-hybrid system) to identify polypeptides that interact with the neuronal phosphoprotein, GAP-43, in an intracellular environment. GAP-43 (neuromodulin, B-50, F1), a protein kinase C (PKC) substrate important for the growth and plasticity of neuronal connections, has been implicated in vitro in several signal transduction pathways. In the yeast-based cloning system, the only strong interaction that was detected between GAP-43 and the calcium effector protein, calmodulin (CaM). PKC phosphorylates GAP-43 on serine 41. When we changed this serine to an aspartate residue to mimic constitutive phosphorylation, the interaction with CaM was blocked. Surprisingly, the N-terminal third of GAP-43 alone bound CaM more strongly than did intact GAP-43, suggesting that the protein's C-terminus may play a role in modulating the interaction with CaM. These results, along with other recent findings, suggest a novel role for the interaction between GAP-43 and CaM.

Intrinsic Connections in the macaque inferior temporal cortex

Intrinsic connections in the inferior temporal cortex were analyzed by making extracellular injections of biocytin in Japanese macaques. Analysis was focused mainly on the dorsal part of area TE, in which a functional columnar organization has been shown. Interlaminar connections were analyzed in coronal section after laminar-specific microinjections, and intralaminar connections were examined from tangential sections. After injections at various depths in the dorsal TE, both axons and cell bodies were strongly labeled above or below the injection site in a columnar appearance. Axons from layer 3 ran in bundles towards the white matter and gave off prominent collaterals in layer 5. Ascending axons from lower to upper layers were also present (e.g., layers 4, 5, and 6 to layer 3). In tangential sections, there were abundant axons running parallel to the pia mater. These horizontal axons, particularly those in layers 2 and 3, produced patches of terminals 0.5 +/- 0.1 mm (mean +/- s.d.) in size and cylindrical in shape, spanning layers 1-3 or even to layers 4 and 5. In the tangential plane, they were distributed in an anisotropic manner around the injection. The farthest patch appeared at 4 mm from the injection site. The center-to-center distance between nearest-neighbor patches was 0.7 +/- 0.3 mm. These patches were found only within the dorsal TE and did not extend into the lower bank of the superior temporal sulcus or into the ventral part of area TE. Area TEO, which is a major afferent source to area TE, had axonal patches with spacing similar to those in area TE but with smaller sizes (0.4 +/- 0.1 mm). The results show that intrinsic horizontal axons both in area TE and in area TEO arborize in a patchy manner, as has been reported for several other cortical areas. In are TE, the size and spacing of the terminal patches match those of columns with similar stimulus selectivity. Thus, these patches may be related to the functional modularity in area TE. Vertical connections across layers and cylindrical patches of horizontal axons most likely contribute to the shared stimulus selectivity among cells within a column.

Rapid induction by kainic acid of both axonal growth and F1/GAP-43 protein in the adult rat hippocampal granule cells

Hippocampal granule cells do not normally express the axonal growth- and plasticity-associated protein F1/GAP-43 in the adult rat. Using three different methods that lead to hypersynchronous activity in limbic circuits, expression of F1/GAP-43 mRNA can be induced in granule cells which is followed by sprouting in mossy fibers, the axons of granule cells. F1/GAP-43 mRNA expression in granule cells was induced in the temporal, but not septal, hippocampus beginning at 12 hours after kainic acid (KA) subcutaneous injection (10 mg/kg). Beginning 2 days after KA treatment, mossy fiber sprouts restricted to the temporal hippocampus were observed in the supragranular layer. In the same animal we also observed that levels of protein F1/GAP-43 immunoreactivity in this layer apparently increased at this same 2 day time point and same ventral hippocampal location. F1/GAP-43 protein levels and mossy fiber sprouting showed an increase up to 10 days after KA treatment. Sprouting was at a maximum at 40 days, the longest time point studied. These events parallel axonal regeneration with one critical difference: granule cell axons are not damaged by kainate. The rapid onset of axonal growth in the adult is striking and occurs earlier than reported previously (2 days vs. 12 days). Such growth closely associated with elevated levels of protein F1/GAP-43 may occur as a result of a) reactive synaptogenesis caused by the availability of post-synaptic surface on granule cell dendrites at the supragranular layer, b) Hebbian co-activation of the post-synaptic granule cells and their presynaptic afferents, and c) loss of target-derived inhibitory growth factor.

Is the lack of protein F1/GAP-43 mRNA in granule cells target-dependent?

Protein F1/GAP-43 is differentially expressed in brain with high levels present in regions associated with memory functions. However, in hippocampus the granule cells lack F1/GAP-43 expression. To determine if this lack of expression is due to inhibitory signals from the target cells, we selectively destroyed CA3 pyramidal cells unilaterally using microinjections of excitotoxins. Kainate lesions induced F1/GAP-43 mRNA expression bilaterally in granule cells at 24 h post-injection. Since the induction contralateral to the lesion was not due to loss of target cells, that induction may be ascribed to consequences of seizure activity. However, F1/GAP-43 mRNA hybridization decreased by 3 d post-lesion and was at background levels by 6 d, indicating that the lack of F1/GAP-43 expression in granule cells is restored despite a lack of target neurons. Unilateral lesions of CA3 cells using ibotenate, which are not as complete as kainate but do not cause seizures, did not induce F1/GAP-43 mRNA in granule cells on either the contralateral or, in 4 of 5 cases, the ipsilateral side. Taken together, these data suggest that the CA3 target is not essential for the absence of F1/GAP-43 expression in granule cells. To compare the extent of damage caused by the lesions, we investigated the location of astrocytes undergoing reactive gliosis, employing as a reporter glial fibrillary acidic protein (GFAP) gene expression. After both kainate and ibotenate injections GFAP hybridization increased in the lesioned area as well as in the contralateral hippocampus. These results indicate that injections of kainate, and possibly ibotenate to a lesser extent, may affect behavior not only by damaging cells at the injection site, but also by altering gene expression in cells at distant sites.

MARCKS and protein F1/GAP-43 mRNA in chick brain: effects of imprinting

The phosphorylation of MARCKS, but not protein F1/GAP-43, is increased in the intermediate and medial portion of the hyperstriatum ventrale (IMHV) after chick imprinting. Here we investigated if MARCKS, but not F1/GAP-43, gene expression would also be altered after imprinting. We first investigated the constitutive mRNA distribution of MARCKS and F1/GAP-43 in chick brain. MARCKS mRNA was expressed in most cells and exhibited a relatively homogeneous distribution. In contrast, F1/GAP-43 mRNA levels were elevated in discrete brain regions, as we had observed in mammals. The highest F1/GAP-43 mRNA levels in the chick brain were in sensory and associational structures such as the hyperstriatal complex and neostriatum, and lower levels were in structures involved in motor control, such as paleostriatum. These results in chick are consistent with the previously drawn generalization that F1/GAP-43 mRNA is expressed in those brain regions which exhibit synaptic plasticity. After imprinting, MARCKS mRNA levels in IMHV were higher in good learners than poor learners. In contrast, analysis of F1/GAP-43 mRNA levels revealed no differences related to training in any brain region sampled. These selective results for MARCKS but not F1/GAP-43 parallel the prior findings on their phosphorylation, and are consistent with our hypothesis that the very same proteins that are post-translationally modified in association with learning and memory also undergo alterations in their gene expression.

Immunocytochemical localization of a growth-associated protein (GAP-43) in rat adrenal gland

We have localized at light and electron-microscopic level the growth-associated protein GAP-43 in adrenal gland using single and double labelling immunocytochemistry. Clusters of GAP-43-immunofluorescent chromaffin cells and many immunofluorescent fibres were observed in the medulla. GAP-43-immunoreactive fibres also formed a plexus under the capsule, crossed the cortex and ramified in the zona reticulata. Double labelled sections showed the coexpression of GAP-43 with a subpopulation of tyrosine hydroxylase- and of dopamine-beta-hydroxylase-immunoreactive chromaffin cells. Dual colour immunofluorescence for GAP-43 and calcitonin gene-related peptide (CGRP) revealed that some of the GAP-43-immunoreactive fibres also express CGRP. Pre-embedding electron microscopy showed GAP-43 immunoreactivity associated with the plasma membranes and cytoplasm of noradrenaline-producing chromaffin cells, and with processes of nonmyelin-forming Schwann cells. Immunoreactive unmyelinated axons and terminals were also observed. The immunostained terminals made symmetrical synaptic contacts with chromaffin cells. Immunoreactive unmyelinated fibres and small terminals were present in the cortex. Our results show that GAP-43 is expressed in noradrenergic chromaffin cells and in various types of nerve fibres that innervate the adrenal. Likely origins for these fibres include preganglionic sympathetic fibres which innervate chromaffin cells, postganglionic sympathetic fibres in the cortex, and CGRP containing sensory fibres.

B-50 (GAP-43) in Onuf's nucleus of the adult cat

The nucleus of Onuf in the sacral spinal cord contains motoneurons that innervate the pelvic floor muscles and possess somatic and autonomic characteristics. We show in this study that in the intact adult cat, the immunocytochemical labelling of the nervous tissue-specific growth-associated protein, B-50 (GAP-43), which persists in Onuf's nucleus, differs markedly from that in the remaining 'purely somatic' motor nuclei of the sacral spinal cord. At the light microscopic level, an intense B-50 (GAP-43) immunoreactivity (B-50-IR) in the neuropil of Onuf's nucleus contrasts with a faint staining in the other spinal motor nuclei. Ultrastructurally, B-50-IR is found in Onuf's nucleus within some unmyelinated small diameter nerve fibres and numerous axon terminals on dendritic and somatic surfaces. Conversely, in all other motor nuclei only a few of these structures are stained. No other cellular profiles show B-50-IR in the tissue examined. According to the proposed functions of B-50 (GAP-43), its persistence in mature spinal axon terminals may indicate a latent capability of functional and structural remodeling, as well as an involvement in long-term enhancement in synaptic transmission. If so, these properties would be considerably more pronounced in Onuf's nucleus as compared to purely somatic motor nuclei.

Immunocytochemistry of B-50 (GAP-43) in the spinal cord and in dorsal root ganglia of the adult cat

The distribution of the neural-specific growth associated protein B-50 (GAP-43), which persists in the mature spinal cord and dorsal root ganglia, has been studied by light and electron microscopic immunohistochemistry in the cat. Throughout the spinal cord, B-50 immunoreactivity was seen confined to the neuropil, whereas neuronal cell bodies were unreactive. The most conspicuous immunostaining was observed in the dorsal horn, where it gradually decreased from superficial laminae (I-II) toward more ventral laminae (III-V), and in the central portion of the intermediate gray (mainly lamina X). In these regions, the labelling was localized within unmyelinated, small diameter nerve fibres and axon terminals. In the rest of the intermediate zone (laminae VI-VIII), B-50 immunoreactivity was virtually absent. The intermediolateral nucleus in the thoracic and cranial lumbar cord showed a circumscribed intense B-50 immunoreactivity brought about by the labelling of many axon terminals on preganglionic sympathetic neurons. In motor nuclei of the ventral horn (lamina IX), low levels of B-50 immunoreactivity were present in a few axon terminals on dendritic and somal profiles of motoneurons. In dorsal root ganglia, B-50 immunoreactivity was mainly localized in the cell bodies of small and medium-sized sensory neurons. The selective distribution of persisting B-50 immunoreactivity in the mature cat throughout sensory, motor, and autonomic areas of the spinal cord and in dorsal root ganglia suggests that B-50-positive systems retain in adult life the capacity for structural and functional plasticity.

Protein kinase C-delta in rat brain: association with sensory neuronal hierarchies

Originally characterized as the calcium- and phospholipid-dependent protein kinases, the protein kinases C include at least eight separate isoforms, some of which are calcium-independent and all of which are highly enriched in brain. Of the calcium-independent isoforms, the delta subspecies of protein kinase C has the most restricted complement of lipid activators and substrate specificity, suggesting that it may have a unique role in cell signalling pathways. Using immunocytochemistry, we report that the distribution of protein kinase C-delta immunoreactivity in rat brain is also restricted, being present in all sensory systems. Moreover, it is found in alternating hierarchies of sensory pathways: in all sensory systems except auditory, it is found in first- and third-order neurons, while in the auditory system, it is found in second- and fourth-order neurons. Thalamocortical systems are intensely immunoreactive, including barrel fields of the rat parietal cortex. Outside of sensory systems, protein kinase C-delta is present in cerebellum within longitudinal stripes in Purkinje neurons, and in the caudate-putamen, it appears to be associated with the striosome (patch) compartment. In contrast to all other protein kinase C isoforms, protein kinase C-delta is absent from hippocampus. These findings suggest that protein kinase C-delta may have a unique role in signal transduction in the central nervous system (CNS), especially in sensory systems.

Learning selectively increases protein kinase C substrate phosphorylation in specific regions of the chick brain

The effect of imprinting, an early form of exposure learning, on the phosphorylation state of the protein kinase C substrates myristoylated alanine-rich C-kinase substrate (MARCKS) and protein F1/43-kDa growth-associated protein (F1/GAP-43) was studied in two regions of the chick forebrain. One region, the intermediate and medial part of the hyperstriatum ventrale (IMHV), is probably a site of long-term memory; the other, the wulst, contains somatic sensory and visual projection areas. After imprinting, a significant increase in MARCKS protein phosphorylation was observed in the left IMHV but not the right IMHV. No significant alteration in F1/GAP-43 was observed in IMHV. MARCKS was resolved into two acidic components of pI approximately 5.0 and approximately 4.0. Phosphorylation of the pI approximately 5.0 MARCKS but not the pI approximately 4.0 MARCKS was significantly altered by imprinting. The partial correlation between preference score (an index of learning) and phosphorylation, holding constant the effect of approach activity during training, was significant only for the pI approximately 5.0 MARCKS in the left IMHV. A significant negative partial correlation between preference score and F1/GAP-43 phosphorylation in the right wulst was observed. Because the imprinting-induced alteration in MARCKS is selective with respect to phosphoprotein moiety, hemispheric location, and brain region, we propose that these alterations may be central to the learning process.

Cognition stimulating drugs modulate protein kinase C activity in cerebral cortex and hippocampus of adult rats

The in vivo and in vitro effect of oxiracetam, aniracetam and alpha-glycerylphosphorylcholine (alpha GPC) on protein kinase C (PKC) activity was studied in rat brain cortex and hippocampus. Administration of oxiracetam and alpha GPC in vivo elicited an early increase of particulate histone-directed PKC activity accompanied by a decrease of soluble activity and followed a few hours later by a down regulation of the enzyme. The effect was also observed in vitro when either oxiracetam or alpha GPC were administered at nanomolar concentrations to rat brain cortex slices. Aniracetam had no effect in the cortex but promoted PKC translocation both in vivo and in vitro in the hippocampus. In cortex slices the effect of oxiracetam was antagonized by the addition of AP-5, an NMDA receptor blocker, but not by CNQX and L-AP3, antagonists of AMPA and metabotropic glutamate receptors, respectively. Scopolamine also prevented the increase of particulate PKC elicited by oxiracetam in vitro. In the hippocampus the increase of particulate PKC activity was antagonized by AP-5, CNQX and L-AP3, indicating participation by both ionotropic and metabotropic glutamate receptors in the action of aniracetam. The data support the hypothesis that PKC activation may be a common mechanism amongst cognition stimulating drugs from different chemical classes.

GAP-43 mRNA localization in the rat hippocampus CA3 field

Gene expression of the axonal growth-associated protein, GAP-43, has been studied in the adult rat brain by in situ hybridization histochemistry. This protein is synthesized at high levels in neuronal somata in immature and regenerating neurons, but after establishment of mature synaptic relations its synthesis generally declines sharply, thus providing a marker denoting propensity for exhibiting synaptic plasticity. Detailed examination of the distribution of mRNA for GAP-43 in rat hippocampus is selectively and robustly expressed in the pyramidal neurons of field CA3 and, to a lesser extent, the polymorph neurons of the hilus of the dentate gyrus. Additional hippocampal regions of moderate expression include the tenia tecta and the subicular and entorhinal fields, but CA1 and CA2 are strikingly lower in signal. The significance of this pattern of localization is considered in the context of the phosphorylation of GAP-43 and its role in influencing synaptic events underlying the establishment and maintenance of long-term potentiation and plasticity in the hippocampus.

Protein kinase C increase in rat brain cortical membranes may be promoted by cognition enhancing drugs

Protein Kinase C (PKC) activity was measured in soluble and particulate fractions of rat individual brain cortices after in vivo treatment with two cognition enhancers: oxiracetam and alpha-glicerylphosphorylcholine. Both drugs induced an increase (+40-50%) of PKC particulate activity at 1 hr after the treatment. The effect was transient; at 5 hours PKC activity was lower than in controls. The dose response curve to oxiracetam was bell shaped, the increase of PKC being significant at 100 mg/kg. At higher doses the drug induced a decrease in enzyme activity. The increased PKC activity may be related to the cortical effects of these compounds.

Does GAP-43 support axon growth by increasing the axonal transport velocity of calmodulin?

GAP-43 is a neuronal protein whose synthesis is elevated during developmental and regenerative axon growth. We propose that one consequence of this increased synthesis may be the delivery of calmodulin-like proteins to the distal portions of the growing axon at an increased velocity; this is because calmodulin, which is transported slowly in mature intact axons, can bind to GAP-43, which is transported rapidly. The release of calmodulin from GAP-43 would be regulated by phosphorylation by protein kinase C. Such a rapid carrier function could be important for allowing certain recently synthesized slowly transported proteins to reach the moving growth cone in time to support its function. This hypothetical carrier mechanism is consistent with the phosphorylation pattern, calmodulin binding, transport velocity, and growth-association of GAP-43, and suggests an explanation for the specific importance of newly synthesized GAP-43 in supporting axon growth.

The potential for muscarinic receptor subtype-specific pharmacotherapy for Alzheimer's disease

In several neurodegenerative disorders, including Alzheimer's disease, a loss of the cholinergic projections of the basal forebrain to the cerebral cortex and hippocampus occurs. Studies of the anatomic and physiologic characteristics of these ascending cholinergic systems suggest that they are important in processing information and in memory function. Muscarinic receptors are situated at various critical control points in these pathways. Activation of postsynaptic muscarinic receptors often increases the excitability of neurons; thus, the signal-to-noise ratio for sensory processing is enhanced. In addition, muscarinic receptors negatively control cholinergic tone at presynaptic sites. Molecular biologic methods have disclosed the existence of five muscarinic receptors, which are coupled to different second messenger systems. The evidence reviewed suggests that at least four of the five muscarinic receptor genes are expressed as functional receptor proteins in the neocortex and hippocampal formation. On the basis of the current information about their pharmacologic properties and coupling mechanisms in nervous tissue, drugs that selectively affect subtypes of muscarinic receptors could enhance cortical cholinergic function and thereby ameliorate certain cognitive impairments in Alzheimer's disease.

Production of the neuronal growth-associated protein GAP-43 in a bacterial expression system

GAP-43, a major protein of neuronal growth cones and certain presynaptic terminals, is a candidate for important functions in both axon growth and synaptic plasticity. To facilitate studies that may elucidate these functions, we have efficiently generated large quantities of GAP-43 by introducing a GAP-43 cDNA into a bacterial expression system driven by T7-RNA polymerase. Two constructs were expressed in this system: one (pT7Ava-GAP) produces a fusion protein in which the first 16 amino acids of GAP-43 are replaced by 11 amino acids of the phage T7 capsid protein; the other (pT7FL-GAP) produces full length GAP-43. After the bacteria were lysed, both products were soluble, and could be efficiently purified by HPLC chromatography on a C4 reversed-phase column. One liter of bacterial culture yielded 50 mg of purified fusion protein or 10 mg of complete GAP-43. When it was incubated with protein kinase C, the fusion protein was phosphorylated at the same single site (serine 41) that is phosphorylated in cultured neurons. The ability to produce large quantities of GAP-43 by this procedure should expedite future studies investigating its structure, posttranslational modification, and function.

Habituation-like decrease in the responses of neurons in inferior temporal cortex of the macaque

In both anesthetized and behaving macaques, we examined the responses of neurons in the inferior temporal cortex (IT) to repeated presentation of a visual stimulus. In anesthetized animals, the responsiveness of IT neurons decreased with repeated stimulus presentation at interstimulus intervals (ISIs) of 2-12 s but not at 20 s. Responsiveness recovered after a 5-min period of no stimulus presentation. The response decrement was similar in anesthetized and awake animals at a 2-s ISI, but at a 6-s ISI, response decrement in the awake animal was much less.

Contrasting patterns of protein phosphorylation in human normal and Alzheimer brain: focus on protein kinase C and protein F1/GAP-43

We introduce a new procedure to study kinase substrates in postmortem human brain. By adding purified exogenous protein kinase C (PKC) and the phospholipid phosphatidylserine to brain homogenates in vitro we are able to analyze PKC substrates. A human 53-kDa phosphoprotein is described that appears to be homologous to rat and monkey protein F1 (GAP-43). This identity is based on molecular weight, isoelectric point, phosphorylation by exogenous protein kinase C, enhancement of its phosphorylation by three activators (phospholipids, calcium and phorbol esters), phosphopeptide maps, and cross-reactivity with an antibody raised against rat protein F1. Protein F1 is a PKC substrate associated with synaptic plasticity and nerve growth. Its phosphorylation in rat brain has been correlated with long-term potentiation, an electrophysiological model of memory. In the present study of normal brain, human protein F1 shows an occipitotemporal in vitro phosphorylation gradient. This is consistent with previous observations in nonhuman primates. This gradient is less pronounced in Alzheimer's disease (AD). Changes in the in vitro phosphorylation pattern of three other non-PKC substrates in Alzheimer's disease, including one with characteristics similar to microtubule-associated protein tau, are also reported. These results suggest that protein phosphorylation can be studied in postmortem human brain and that PKC-mediated phosphorylation of protein F1, already linked to synaptic plasticity and memory, may be altered in AD.

An ELISA assay for GAP-43

An ELISA assay for the growth associated protein GAP-43 was developed to determine rapidly its relative abundance in neuronal tissue. The assay was performed with affinity-purified anti-GAP-43 antibody that detected a single band of Mr = 42,000-45,000 on Western blots of rat brain homogenates but no bands on blots of liver homogenates. GAP-43 was determined by ELISA assay in as little as 0.6 microgram protein of brain homogenate. The assay was highly reproducible; the standard error of the mean of sample to sample variation was less than 5%. When ELISA development time was held constant, the standard error of the mean of inter-assay variation was between 2 and 7%. Using this method, GAP-43 immunoreactivity was examined in developing rat brain. At post-natal day 1, GAP-43 immunoreactivity was 3-4 times greater than that observed in the adult, remained elevated for several weeks, and decreased by the end of the first month of life. These results are in accord with previous studies on the expression or synthesis of GAP-43 during neuronal development.

Mapping the development of the rat brain by GAP-43 immunocytochemistry

Growth-associated protein-43 (GAP-43) is a phosphoprotein of the nerve terminal membrane which has been linked to the development and restructuring of axonal connections. Using a monospecific antibody prepared in sheep against purified GAP-43, we examined the temporal and spatial changes in the distribution of this protein from embryonic stage day 13 (E13) to adulthood. At stages in which neurons are still dividing and migrating, levels of GAP-43 are extremely low, as is seen in the cortical plate throughout the embryonic period. With the onset of process outgrowth, intense GAP-43 immunoreactivity appears along the length of axons: by E13, such staining is already strong in the brainstem, where it continues up through the first postnatal week and then disappears. In the neocortex, intense fiber staining first appears several days later but ends at the same time as in the brainstem. At the end of the period of intense axonal staining there is a brief interval in which high levels of GAP-43 immunostaining are seen in the neuropil. In regions of the brain in which specific developmental events have been characterized anatomically and physiologically, the period of dense neuropil staining coincides with the formation of axonal end-arbors, the beginning of synaptogenesis, and the time at which synaptic organization can be modified by the impingent pattern of activity (i.e. the critical period). Over the next few days, staining in neuropil declines sharply in most regions except for certain structures in the rostral neuraxis which may be sites of ongoing synaptic remodeling.

Abnormal retinal projections alter GAP-43 patterns in the diencephalon

In Syrian hamsters, mature retinal terminals contain only low levels of the growth-associated protein, GAP-43, whereas the lateral posterior nucleus (LP) of the thalamus contains high levels of this protein. Damage to the superior colliculus in neonatal hamsters induces retinal terminals to form dense patches of innervation in the LP, an area which otherwise receives little if any direct retinal input. The present study used GAP-43 antibodies to examine the interaction between abnormally routed optic fibers and the cells in the anomalous thalamic target zone. Immunohistochemistry revealed very little GAP-43 in the abnormal retinal projection to the LP, indicating that the normal developmental decline in GAP-43 levels occurs even in an inappropriate extracellular environment. Moreover, retinal fibers were found to exclude the protein from its normal territory, forming negatively-stained islands in those regions of the LP containing the retinal terminals. In order to identify the normal source of GAP-43-positive terminals in the LP, we surgically removed two major extrinsic afferents to this region, or we chemically eliminated local interneurons. Whereas removing projections from the SC or posterior cortex did not alter GAP-43 immunoreactivity in the LP, destruction of local interneurons with ibotenic acid resulted in markedly diminished levels of this protein. These results show that retinal terminals induced to form in an abnormal target area undergo their normal diminution of GAP-43, and that these retinal projections displace other GAP-43-rich terminals in the LP that appear to arise from local interneurons.

DARPP-32, a phosphoprotein enriched in dopaminoceptive neurons bearing dopamine D1 receptors: distribution in the cerebral cortex of the newborn and adult rhesus monkey

DARPP-32, a dopamine (DA) and cAMP-regulated phosphoprotein, is associated with dopaminoceptive neurons bearing D-1 receptors in the basal ganglia. The present study addressed the distribution of DARPP-32 in the primate cerebral cortex and its putative association with D-1 receptor laden cells in this structure. DARPP-32-like immunoreactive (LIR) neurons were examined in the cerebral cortex of 3-day-old (P3), 6-week-old (P42), and adult rhesus monkeys. In the younger cases, a large number of DARPP-32 positive neurons, with the morphological characteristics of pyramidal cells, were observed throughout the cortex, in layers V-VI, and to a lesser extent in layer II and uppermost layer III. In the parietal, insular, temporal, and occipital cortices, DARPP-32 positive neurons were arranged in a monolayer in layer Va. They were often clustered in small groups with a bundling of their dendrites. In the primary motor cortex, Betz cells were among the labeled population. In the association and somatosensory areas, the basal dendrites of DARPP-32 positive neurons and the prominent tufting of their apical dendrites in layer I contributed to an essential bilaminar pattern resembling the distribution reported for DA afferents and D-1 receptors in these areas. The prominence and widespread distribution of DARPP-32 positive neurons in layer V may be a specialization of primate cortex since such cells are found only in restricted locations in rodents. The literature on the connections of the cerebral cortex suggests that a large number of the DARPP-32 positive neurons in layer VI and perhaps even in layer Va may be corticothalamic neurons. An important developmental observation was the presence of DARPP-32-LIR neurons in the white matter. They were prominent in the neonates but could not be seen in the adult. Their location as well as their type and shape were reminiscent of interstitial neurons. In the adult monkeys, the distribution of DARPP-32-LIR neurons was more circumscribed: they were numerous in the ventral temporal gyrus and in areas related to the limbic system: caudal orbitofrontal cortex, insula, temporal pole, entorhinal, and anterior cingulate cortex. Weak labeling was detected in layer Va of the superior temporal and parietal cortex, in some prefrontal areas (10, 13, and medial 9), and in the premotor and supplementary motor cortex; in adults, unlike neonates, few DARPP-32-LIR neurons were present in the dorsolateral prefrontal cortex, the primary motor or the primary visual or prestriate cortices.(ABSTRACT TRUNCATED AT 400 WORDS)

The neural mechanism of declarative memory consolidation and retrieval: a hypothesis

This paper proposes a new theory addressing the neural mechanism of declarative memory consolidation and retrieval. The premise of the theory is that the cortex is responsible for the storage of declarative memory while the medial temporal lobe is responsible for the consolidation and retrieval of declarative memory. The theory suggests that the medial temporal lobe can only accomplish its functions related to memory by hierarchically and cooperatively regulating the descending limbic system, including the hypothalamus, epithalamus, septum, mammillary bodies and the bed nucleus of the stria terminalis. These descending limbic structures, together with the amygdala, further send efferents to the four ascending NA, 5-HT, DA and ACh systems. It is these four ascending extrathalamic regulatory systems that provide the feedback neural pathways to the cortex and regulate the processes of memory consolidation and retrieval in the cortex. Therefore, the coupling of these descending limbic structures to the ascending NA, 5-HT, DA and ACh systems completes the neural circuits responsible for the consolidation and retrieval of new declarative memories. This neural mechanism of declarative memory consolidation and retrieval is universal to all species in higher mammals.

GAP-43 in adult visual cortex

GAP-43 was purified from cat brain by a rapid isolation procedure and was used to raise highly specific polyclonal antibodies in rabbits. Immunoblots of proteins from adult cat, monkey and human visual cortex as well as bovine cortex also showed specific staining of a single protein that was present in both soluble and membrane fractions. Immunocytochemistry of both cat and human adult visual cortex showed that GAP-43 has a laminar distribution.

Phosphoproteins localized to presynaptic terminal linked to persistence of long-term potentiation (LTP): quantitative analysis of two-dimensional gels

Previous findings suggest: (1) that altering protein kinase C (PKC) activity alters the persistence of long-term potentiation (LTP) in the intact hippocampal formation; and (2) that PKC activity is directly correlated with persistence of LTP in vivo as measured by the in vitro phosphorylation of two major PKC substrates in adult hippocampus, protein F1 and 80k. Using quantitative analysis of two-dimensional gels, we report here two additional phosphoproteins of 72 and 55 kDa which were directly correlated to persistence of LTP induced in the intact dorsal hippocampal formation. The phosphorylation of both proteins in response to addition of different kinase stimulators was distinct from that of protein F1 and 80k. Moreover, neither protein was a substrate for exogenous PKC. The physicochemical properties of these phosphoproteins suggest they are identical to the previously described synaptic vesicle proteins IIIa and IIIb, and as such are immunologically indistinguishable. Because proteins IIIa and IIIb are known to be phosphorylated by a Ca2+/calmodulin (CaM)-stimulated kinase, and protein F1 is known to be a plasma membrane-associated protein (P-57) which releases bound CaM in response to phosphorylation by PKC, the present findings suggest a potential mechanism in which PKC-mediated changes in plasma membrane proteins produce CaM kinase-mediated changes in synaptic vesicle proteins through a phosphorylation cascade. These membrane/vesicle alterations are postulated to underlie the increased synaptic efficacy which marks persistent LTP.

Type I protein kinase C isozyme in the visual-information-processing pathway of monkey brain

Previously using PKC isozyme-specific antibodies for immunoblot analysis, we demonstrated the heterogeneous distribution of PKC isozymes in various regions of monkey and rat brains and that type I PKC was most abundant in cerebellum, hippocampus, amygdala, and cerebral cortex (Huang et al.: J Biol Chem 262:15714-15720, 1987). Using these antibodies, we have also demonstrated that type I, II, and III PKC are products of PKC genes gamma, beta, and alpha, respectively (Huang et al.: Biochem Biophys Res Commun 149:946-952, 1987). By immunocytochemical analysis, type I PKC-specific antibody showed strong reactivity in various types of neuron in hippocampal formation, amygdala, cerebellum, and neocortex. In hippocampal formation, granule cells of dentate gyrus and pyramidal cells of hippocampus were heavily stained. By immunoblot analysis, relative levels of PKC isozymes in several areas of monkey cerebral cortex involved in the visual information processing and storage were determined. Both type II and III PKCs appeared to be evenly distributed and at moderate levels, type I PKC formed a gradient of increasing concentration rostral along the cerebral cortex of occipital to temporal and then to the limbic areas. Neurobehavioral studies have demonstrated that the neocortical and limbic areas of the anterior and medial temporal regions participate more directly than the striate, prestriate, and posterior temporal regions in the storage of visual representations and that both hippocampus and amygdala are important in the memory formation. As type I PKC is present at high levels in hippocampus, amygdala, and anterior temporal lobe, we predict that the type I protein kinase C may participate in the plastic changes important for mnemonic function.

Light-microscopic immunolocalization of the growth- and plasticity-associated protein GAP-43 in the developing rat brain

Growth-associated protein-43 (GAP-43) is a developmentally regulated, fast-axonally transported phosphoprotein whose synthesis and transport are enhanced during periods of growth and synaptic terminal formation. GAP-43 is a substrate of protein kinase C and is identical to protein F1, a phosphoprotein which is regulated during long-term potentiation in the hippocampus. In order to characterize the cellular localization of GAP-43, we have raised a specific antiserum against it, and used this as a probe to show that GAP-43 is neuron-specific, and is localized to growing neuronal processes in developing rat brain, and to presynaptic terminals in both the peripheral and central nervous system. In the mature CNS, GAP-43 immunoreactivity is present in most neuropil areas, but is especially dense in the molecular layers of the cerebellum, neocortex, and the hippocampus, structures known to exhibit synaptic plasticity. Its localization, together with biochemical data concerning the dynamics of its synthesis and its identity as protein F1, suggest that GAP-43 may be involved in axon growth in the developing nervous system, and in some aspect of synaptic plasticity in the mature CNS. These data also suggest that axon growth and synaptic plasticity in the brain may be regulated by a common mechanism, both involving the protein kinase C-mediated phosphorylation of GAP-43.

Growth-associated protein GAP-43 is expressed selectively in associative regions of the adult human brain

GAP-43 is a neuron-specific phosphoprotein that has been linked with the development and functional modulation of synaptic relationships. cDNAs for the human GAP-43 gene were used to reveal high overall levels of GAP-43 mRNA in a number of integrative areas of the neocortex, but low levels in cortical areas involved in the initial processing of sensory information, in several brainstem structures, and in caudate-putamen. Neurons expressing highest levels of GAP-43 mRNA were found by in situ hybridization to be concentrated in layer 2 of association cortex and in hippocampal pyramidal cells. Control studies showed that several other RNAs had regional distributions that were different from GAP-43, although the mRNA encoding the precursor of the Alzheimer amyloid beta protein followed a similar pattern of expression. These results suggest that a restricted subset of cortical and hippocampal neurons may be specialized for synaptic remodeling and might play a role in information storage in the human brain.

Human GAP-43: its deduced amino acid sequence and chromosomal localization in mouse and human

The growth-associated protein (GAP-43) is considered a crucial component of an effective regenerative response in the nervous system. Its phosphorylation by protein kinase C correlates with long-term potentiation. Sequence analysis of human cDNAs coding for this protein shows that the human GAP-43 gene is highly homologous to the rat gene; this homology extends into the 3'-untranslated region. However, the human protein contains a 10 amino acid insert. Somatic cell hybrids demonstrate localization of the GAP-43 gene to human chromosome 3 and to mouse chromosome 16.