Actin-dependent regulation of neurotransmitter release at central synapses.

Depolymerization of actin by latrunculin A transiently promotes neurotransmitter release. The mean rate of mEPSCs increases by a Ca2+-independent process, without a concomitant change in the mean amplitude. The readily releasable vesicle pool size and the rate of refilling of the readily releasable pool remain unaltered by latrunculin treatment. Evoked neurotransmitter release also increases in a manner consistent with an increase in vesicle release probability. The observed enhancement of neurotransmitter release is specific to actin depolymerization mediated by latrunculin A and is not caused by cytochalasin D. Our findings indicate that actin participates in a regulatory mechanism that restrains fusion of synaptic vesicles at the active zone.

p75 neurotrophin receptor expression is induced in apoptotic neurons after seizure.

Seizure causes neuronal cell loss in both animal models and human epilepsy. To determine the contribution of apoptotic mechanisms to seizure-induced neuronal cell death, rat brains were examined for the occurrence of terminal deoxynucleotidyl transferase-mediated UTP nick end labeling (TUNEL)-positive nuclei after pilocarpine-induced seizure. Numerous TUNEL-positive cells were observed throughout the postseizure hippocampus, piriform cortex, and entorhinal cortex. Combined TUNEL/NeuN immunocytochemistry demonstrated that the vast majority of TUNEL-positive cells were neurons. To identify components of the signal transduction cascade promoting postseizure apoptosis, the expression of the p75 neurotrophin receptor (p75NTR) was examined. Seizure-induced increases in p75NTR protein and mRNA were detected in hippocampus, piriform cortex, and entorhinal cortex. Immunohistochemical double labeling revealed almost complete correspondence between TUNEL-positive and p75NTR-expressing cells, suggesting that seizure-induced neuronal loss within the CNS occurs through apoptotic signaling cascades involving p75NTR.

Widespread expression of netrin-1 by neurons and oligodendrocytes in the adult mammalian spinal cord.

Netrins are a family of secreted proteins that function as chemotropic axon guidance cues during neural development. Here we demonstrate that netrin-1 continues to be expressed in the adult rat spinal cord at a level similar to that in the embryonic CNS. In contrast, netrin-3, which is also expressed in the embryonic spinal cord, was not detected in the adult. In situ hybridization analysis demonstrated that cells in the white matter and the gray matter of the adult spinal cord express netrin-1. Colocalization studies using the neuronal marker NeuN revealed that netrin-1 is expressed by multiple classes of spinal interneurons and motoneurons. Markers identifying glial cell types indicated that netrin-1 is expressed by most, if not all, oligodendrocytes but not by astrocytes. During neural development, netrin-1 has been proposed to function as a diffusible long-range cue for growing axons. We show that in the adult spinal cord the majority of netrin-1 protein is not freely soluble but is associated with membranes or the extracellular matrix. Fractionation of adult spinal cord white matter demonstrated that netrin-1 was absent from fractions enriched for compact myelin but was enriched in fractions containing periaxonal myelin and axolemma, indicating that netrin-1 protein may be localized to the periaxonal space. These findings suggest that in addition to its role as a long-range guidance cue for developing axons, netrin may have a short-range function associated with the cell surface that contributes to the maintenance of appropriate neuronal and axon-oligodendroglial interactions in the mature nervous system.

Intracerebral adenovirus-mediated p53 tumor suppressor gene therapy for experimental human glioma.

Malignant gliomas of astrocytic origin are good candidates for gene therapy because they have proven incurable with conventional treatments. Although mutation or inactivation of the p53 tumor suppressor gene occurs at early stages in gliomas and is associated with tumor progression, many tumors including high-grade glioblastoma multiforme carry a functionally intact p53 gene. To evaluate the effectiveness of p53-based therapy in glioma cells that contain endogenous wild-type p53, a clinically relevant model of malignant human glioma was established in athymic nu/nu mice. Intracerebral, rapidly growing tumors were produced by stereotactic injection of the human U87 MG glioma cell line that had been genetically modified for tracking purposes to express the Escherichia coli lacZ gene encoding beta-galactosidase. Overexpression of the p53 gene by adenovirus-mediated delivery into the tumor mass resulted in rapid cell death with the eradication of beta-galactosidase-expressing glioma cells through apoptosis. In long-term experiments, the survival of mice treated with the p53 adenoviral recombinant was significantly longer than that of mice that had received control adenoviral recombinant. During the observation period of 1 year, a complete cure was achieved in 27% of animals after a single injection of p53 adenoviral recombinant, and 38% of the animals were tumor free in the group receiving multiple injections of p53 adenoviral recombinant into a larger tumor mass. These experiments demonstrate that overexpression of p53 in gliomas, even in the presence of endogenous functional wildtype p53, leads to efficient elimination of tumor cells. These results point to the potential therapeutic usefulness of this approach for all astrocytic brain tumors.

Apoptotic morphology of dentate gyrus granule cells following experimental cortical impact injury in rats: possible role in spatial memory deficits.

Loss of hippocampal neurons as a result of traumatic brain injury (TBI) is thought to contribute to the observed spatial memory deficits. Using a rodent model of experimental brain injury, we have examined the nature of hippocampal cell death following TBI. Light microscope examination of stained sections showed the presence of a large number of hyperchromatic and dystrophic neurons in the dentate gyrus of the hippocampus. These cells appeared to be undergoing nuclear condensation. Electron microscope examination demonstrated the presence of cell shrinkage, condensed chromatin, nuclear segmentation, and cytoplasmic vacuolization. Detection of a DNA ladder and in situ labeling (TUNEL) were also consistent with the process of apoptosis. However, in some dystrophic neurons these morphologies were also accompanied by the presence of swollen mitochondria and a lack of distinctive rough endoplasmic reticulum which are typically associated with necrosis. These findings show that cortical impact injury produces cell death in the hippocampus which has both apoptotic and necrotic features.

Delayed, selective neuronal death following experimental cortical impact injury in rats: possible role in memory deficits.

Clinical and experimental studies show that loss of neurons in the hippocampus and/or the entorhinal cortex can impede formation and storage of spatial memory. Using a controlled cortical impact model of traumatic brain injury (TBI) in rats, we have examined the temporal and spatial pattern of neuronal death using silver impregnation and cresyl violet staining. Dystrophic neurons can be detected in the dentate gyrus, and the CA1 and CA3 subfields of the hippocampus for up to 2 weeks following injury. These dystrophic cells appeared shrunken and possessed features of apoptosis. Areas containing the dystrophic cells suffer substantial cell loss as demonstrated by thinning of the neuronal layers. Dystrophic cells are also found in the amygdala, entorhinal and piriform cortices, thalamic and hypothalamic regions, and surrounding the contusion site. The loss of these cells may contribute to the memory deficits observed following TBI.

Altered synchrony and connectivity in neuronal networks expressing an autism-related mutation of neuroligin 3.

The neuroligin (NL) gene family codes for brain specific cell adhesion molecules that play an important role in synaptic connectivity. Recent studies have identified NL mutations linked to patients with autism spectrum disorders (ASD). Cognitive deficits seen in autistic patients are hypothesized to arise from altered synchronicity both within and between brain regions. Here we show how the expression of autism-associated neuroligin mutation R471C-NL3 affects synchrony in dissociated cultures of rat hippocampal neurons. Spontaneous network activity patterns of cultures expressing wild type and mutant NL3 were measured by optical techniques. Firing events were quantified and compared by cross-correlation analysis. Our results suggest that NL3 overexpression enhances synchrony of spontaneous activity patterns, however, this ability is reduced with the R471C-NL3 mutation. We investigated the structural basis of this phenomenon using fractal dimension analysis to characterize the arrangement of axon trajectories. R471C-NL3 cultures were associated with lower fractal dimensions and higher lacunarity values, indicating a decrease in the complexity of axonal architecture. Transfection of R471C-NL3 into a subpopulation of cells in a network resulted in neuronal degeneration. This degeneration likely affected the inhibitory population of neurons, as there were half as many (P<0.01, n=12) glutamate decarboxylase (GAD) 65 expressing cells in R471C-NL3 cultures compared to wild type NL3 and control cultures. Electrophysiological recordings showed a reduction of inhibitory activity in networks carrying the mutation in comparison to networks overexpressing wild-type NL3. Together, these data support the hypothesis that the autism-associated NL3 mutation affects information processing in neuronal networks by altering network architecture and synchrony.

Tissue-plasminogen activator is induced as an immediate-early gene during seizure, kindling and long-term potentiation.

The requirement of protein and messenger RNA synthesis for long-term memory suggests that neural activity induced by learning initiates a cascade of gene expression. Here we use differential screening to identify five immediate-early genes induced by neuronal activity. One of these is tissue-plasminogen activator (tPA), an extracellular serine protease, which is induced with different spatial patterns in the brain by three activity-dependent events: (1) convulsive seizure increases expression of tPA in the whole brain; (2) stimulation of the perforant path produces an epileptiform after-discharge that ultimately leads to kindling increases the levels of tPA throughout the hippocampus bilaterally; and (3) brief high-frequency stimulation of the perforant path that produces long-term potentiation (LTP) causes an NMDA (N-methyl-D-aspartate) receptor-mediated increase in the levels of tPA mRNA which is restricted to the granule cells of the ipsilateral dentate gyrus. As release of tPA is correlated with morphological differentiation, the increased expression of tPA may play a role in the structural changes that accompany activity-dependent plasticity.

Construction of a recombinant adenovirus containing the denV gene from bacteriophage T4 which can partially restore the DNA repair deficiency in xeroderma pigmentosum fibroblasts.

The denV gene from bacteriophage T4 encodes a pyrimidine dimer-specific endonuclease that has the capacity to initiate excision repair of DNA. Cells from excision repair-deficient xeroderma pigmentosum (XP) patients are able to carry out excision repair initiated by the denV gene product and introduction of the denV gene into XP cells results in the partial restoration of colony-forming ability after irradiation with UV light. In this work we have constructed a helper-independent recombinant human adenovirus, Ad5denV, which contains the denV gene. A 1.9 kb cartridge consisting of the denV gene flanked by the long terminal repeat (LTR) promoter from Rous sarcoma virus (RSV) and the simian virus 40 (SV40) polyadenylation (poly A) splice signals, was inserted into the E3 region of an E3 deletion mutant (Ad5d1E3) of adenovirus type 5. Infection of human fibroblasts and other permissive human cells with Ad5denV resulted in lytic infection and expression of the denV gene was confirmed by primer extension of infected cell RNA. The ability of the denV gene to restore the DNA repair deficiency in XP fibroblasts was examined using host cell reactivation of viral structural antigen formation for UV-irradiated adenovirus. The control virus, Ad5VSV, was also a recombinant which contained the gene for vesicular stomatitis virus glycoprotein G inserted into the E3 region of Ad5d1E3. UV survival of Ad5denV was similar to that of Ad5VSV following infection of two normal fibroblast strains and a Cockayne syndrome fibroblast strain, CS7SE, from complementation group B. In contrast, UV survival of Ad5denV was significantly greater than that for Ad5VSV after infection of three unrelated XP fibroblast strains from complementation groups A, C and E. However, UV survival of Ad5denV in the XP fibroblasts did not reach levels obtained in normal fibroblasts, indicating that restoration of the XP defect was partial.

cAMP response element-binding protein is activated by Ca2+/calmodulin- as well as cAMP-dependent protein kinase.

In a variety of nerve cells of the brain, action potentials activate gene expression by means of Ca2+ influx. To determine how Ca2+ influx alters gene expression, we have examined the pattern of phosphorylation of a protein that binds to the cAMP response element (CRE). We have found that purified bovine brain CRE-binding protein is a substrate for the Ca2+/calmodulin-dependent kinase II (Cam kinase) as it is for the cAMP-dependent protein kinase (kinase A). Tryptic peptide maps show that the same peptide is phosphorylated in vitro both by kinase A and by Cam kinase. Moreover, in vitro transcription assays using a CRE-containing c-fos promoter indicate that phosphorylation of CRE-binding protein by Cam kinase increases gene transcription. Thus, action potentials in nerve cells and the consequent influx of Ca2+ can activate CRE-binding proteins by means of Cam kinase. This kinase therefore provides a direct second-messenger pathway by which impulse activity at the membrane can influence gene transcription. This has been shown independently by Sheng et al. (Sheng, M., Thomson, M. A. & Greenberg, M. E. (1991) Science, in press), who found that depolarization and Ca2+ influx mediate induction of c-fos in PC12 rat pheochromocytoma cells through phosphorylation of CRE-binding protein. These several findings indicate that CRE-binding protein(s) is a convergence point for synaptic activity acting through kinase A and impulse activity acting through Cam kinase. Together the two kinases could activate transcription in a synergistic manner, which could allow CRE-binding protein to couple short-term to long-term associative forms of synaptic plasticity.

Recovery of tail-elicited siphon-withdrawal reflex following unilateral axonal injury is associated with ipsi- and contralateral changes in gene expression in Aplysia californica.

Behavioral, cellular and molecular changes were examined following axonal injury in the marine mollusc Aplysia californica. Unilateral nerve injury was performed by crushing the pleural-pedal connective and the peripheral pedal nerves innervating one side of the posterior body wall and the tail. The injury procedure severs the axons of the pleural sensory neurons resulting in the blockade of the tail-elicited siphon-withdrawal reflex. Partial reflex recovery is observed within 3 d and reaches 50% of the pretest value by six weeks postinjury. Retrograde staining of injured nerves combined with electrophysiological recordings from siphon motor neurons show that axons can regenerate through the crushed site and reconnect with the tail by three weeks postinjury. Moreover, the behavioral and electrophysiological measurements suggest that the contralateral sensory neurons may contribute to the early recovery of the siphon-withdrawal reflex. The levels of mRNAs coding for actin and calreticulin are elevated while the mRNAs coding for intermediate filament protein, sensorin A, FMRFamide are reduced in the ipsilateral pleural ganglia as detected by Northern blots. In the contralateral pleural ganglia, the levels of mRNAs coding for actin, sensorin A and FMRFamide are elevated. These molecular changes in both the ipsi- and contralateral sides are consistent with the hypothesis that both sides are participating in the behavioral recovery following unilateral axonal injury.

Remodeling of synaptic actin induced by photoconductive stimulation.

Use-dependent synapse remodeling is thought to provide a cellular mechanism for encoding durable memories, yet whether activity triggers an actual structural change has remained controversial. We use photoconductive stimulation to demonstrate activity-dependent morphological synaptic plasticity by video imaging of GFP-actin at individual synapses. A single tetanus transiently moves presynaptic actin toward and postsynaptic actin away from the synaptic junction. Repetitive spaced tetani induce glutamate receptor-dependent stable restructuring of synapses. Presynaptic actin redistributes and forms new puncta that label for an active synapse marker FM5-95 within 2 hr. Postsynaptic actin sprouts projections toward the new presynaptic actin puncta, resembling the axon-dendrite interaction during synaptogenesis. Our results indicate that activity-dependent presynaptic structural plasticity facilitates the formation of new active presynaptic terminals.