Andreas Vlachos

Synaptopodin Regulates Plasticity of Dendritic Spines in Hippocampal Neurons

The spine apparatus is an essential component of dendritic spines of cortical and hippocampal neurons, yet its functions are still enigmatic. Synaptopodin (SP), an actin-binding protein, is tightly associated with the spine apparatus and it may play a role in synaptic plasticity, but it has not yet been linked mechanistically to synaptic functions. We studied endogenous and transfected SP in dendritic spines of cultured hippocampal neurons and found that spines containing SP generate larger responses to flash photolysis of caged glutamate than SP-negative ones. An NMDA-receptor-mediated chemical long-term potentiation caused the accumulation of GFP-GluR1 in spine heads of control but not of shRNA-transfected, SP-deficient neurons. SP is linked to calcium stores, because their pharmacological blockade eliminated SP-related enhancement of glutamate responses, and release of calcium from stores produced an SP-dependent increase of GluR1 in spines. Thus, SP plays a crucial role in the calcium store-associated ability of neurons to undergo long-term plasticity.

Increased Dentate Gyrus Excitability in Neuroligin-2-Deficient Mice in Vivo

The postsynaptic adhesion protein neuroligin-2 (NL2) is selectively localized at inhibitory synapses. Here, we studied network activity in the dentate gyrus of NL2-deficient mice following perforant path (PP) stimulation in vivo. We found a strong increase in granule cell (GC) excitability. Furthermore, paired-pulse inhibition (PPI) of the population spike, a measure for γ-aminobutyric acid (GABA)ergic network inhibition, was severely impaired and associated with reduced GABA(A) receptor (GABA(A)R)-mediated miniature inhibitory postsynaptic currents recorded from NL2-deficient GCs. In agreement with these functional data, the number of gephyrin and GABA(A)R clusters was significantly reduced in the absence of NL2, indicating a loss of synaptic GABA(A)Rs from the somata of GCs. Computer simulations of the dentate network showed that impairment of perisomatic inhibition is able to explain the electrophysiological changes observed in the dentate circuitry of NL2 knockout animals. Collectively, our data demonstrate for the first time that deletion of NL2 increases excitability of cortical neurons in the hippocampus of intact animals, most likely through impaired GABA(A)R clustering.

Repetitive Magnetic Stimulation Induces Functional and Structural Plasticity of Excitatory Postsynapses in Mouse Organotypic Hippocampal Slice Cultures

Repetitive transcranial magnetic stimulation (rTMS) is a noninvasive brain stimulation technique that can alter cortical excitability in human subjects for hours beyond the stimulation period. It thus has potential as a therapeutic tool in neuropsychiatric disorders associated with alterations in cortical excitability. However, rTMS-induced neural plasticity remains insufficiently understood at the cellular level. To learn more about the effects of repetitive magnetic stimulation (rMS), we established an in vitro model of rMS using mouse organotypic entorhino-hippocampal slice cultures. We assessed the outcome of a high-frequency (10 Hz) rMS protocol on functional and structural properties of excitatory synapses in mature hippocampal CA1 pyramidal neurons. Whole-cell patch-clamp recordings, immunohistochemistry, and time-lapse imaging techniques revealed that rMS induces a long-lasting increase in glutamatergic synaptic strength, which is accompanied by structural remodeling of dendritic spines. The effects of rMS on spine size were predominantly seen in small spines, suggesting differential effects of rMS on subpopulations of spines. Furthermore, our data indicate that rMS-induced postsynaptic changes depend on the NMDA receptor-mediated accumulation of GluA1-containing AMPA receptors. These results provide first experimental evidence that rMS induces coordinated functional and structural plasticity of excitatory postsynapses, which is consistent with a long-term potentiation of synaptic transmission.

A role for the spine apparatus in LTP and spatial learning

Long-term potentiation (LTP) of synaptic strength is a long-lasting form of synaptic plasticity that has been linked to information storage. Although the molecular and cellular events underlying LTP are not yet fully understood, it is generally accepted that changes in dendritic spine calcium levels as well as local protein synthesis play a central role. These two processes may be influenced by the presence of a spine apparatus, a distinct neuronal organelle found in a subpopulation of telencephalic spines. Mice lacking spine apparatuses (synaptopodin-deficient mice) show deficits in LTP and impaired spatial learning supporting the involvement of the spine apparatus in synaptic plasticity. In our review, we consider the possible roles of the spine apparatus in LTP1 (protein synthesis-independent), LTP2 (translation-dependent and transcription-independent) and LTP3 (translation- and transcription-dependent) and discuss the effects of the spine apparatus on learning and memory.

sAPPα antagonizes dendritic degeneration and neuron death triggered by proteasomal stress

Impaired proteasomal function is a major hallmark in the pathophysiology of neurodegenerative diseases, including Alzheimers disease (AD). Here we investigated the biological properties of the secreted cleavage product of APP (sAPPalpha) in antagonizing stress signalling, dendritic degeneration and neuronal cell death induced by the proteasome inhibitor epoxomicin. Analysis of executioner caspase activation demonstrated that sAPPalpha was able to protect PC12 cells from apoptosis triggered by epoxomicin, as well as by genotoxic stress (UV irradiation). This anti-apoptotic effect of sAPPalpha was associated with inhibition of the stress-triggered c-Jun N-terminal kinase (JNK)-signalling pathway. The anti-apoptotic effect of sAPPalpha could also be confirmed in organotypic slice cultures of Thy1-GFP mouse hippocampi. Confocal time-lapse imaging of CA1 pyramidal neurons revealed that preincubation with sAPPalpha preserves the structural integrity of neurons after epoxomicin treatment. Taken together, our data demonstrate that sAPPalpha is neuroprotective under conditions of proteasomal stress.

The Spine Apparatus, Synaptopodin, and Dendritic Spine Plasticity

The spine apparatus (SA) is an essential component of mature dendritic spines of cortical and hippocampal neurons, yet its functions are still enigmatic. Synaptopodin (SP), an actin-binding protein, colocalizes with the SA. Hippocampal neurons in SP-knockout mice lack SA, and they express lower LTP. SP probably plays a role in synaptic plasticity, but only recently it is being linked mechanistically to synaptic functions. These authors and others have studied endogenous and transfected SP in dendritic spines of cultured hippocampal neurons. They found that spines containing SP generate twice as large responses to flash photolysis of caged glutamate than SP-negative ones. An N-methyl-d-aspartate receptor—mediated chemical LTP caused accumulation of GFP-GluR1 in spine heads of control but not of shRNA transfected, SP-deficient neurons. SP is linked to calcium stores, because their pharmacological blockade eliminated SP-related enhancement of glutamate responses. Furthermore, release of calcium from stores produces an SP-dependent delivery of GluR1 into spines. Thus, SP plays a crucial role in the calcium store-associated ability of neurons to undergo long-term plasticity.

Lamina-Specific Distribution of Synaptopodin, an Actin-Associated Molecule Essential for the Spine Apparatus, in Identified Principal Cell Dendrites of the Mouse Hippocampus

Synaptopodin is an actin‐associated molecule found in a subset of telencephalic spines. It is an essential component of the spine apparatus, a Ca2+‐storing organelle and has been implicated in synaptic plasticity (Deller et al. [ 2003 ] Proc Natl Acad Sci U S A 100:10494–10499). In the rodent hippocampus, Synaptopodin is distributed in a characteristic region‐ and lamina‐specific manner. To learn more about the cellular basis underlying this distribution, the regional, laminar, and cellular localization of Synaptopodin and its mRNA were analyzed in mouse hippocampus. First, Synaptopodin puncta densities were quantified after immunofluorescent labeling using confocal microscopy. Second, the dendritic distribution of Synaptopodin‐positive puncta was studied using three‐dimensional confocal reconstructions of Synaptopodin‐immunostained and enhanced green fluorescence protein (EGFP)‐labeled principal neurons. Synaptopodin puncta located within dendrites of principal neurons were primarily found in spines (>95%). Analysis of dendritic segments located in different layers revealed lamina‐specific differences in the percentage of Synaptopodin‐positive spines. Densities ranged between 37% (outer molecular layer) and 14% (stratum oriens; CA1). Finally, synaptopodin mRNA expression was studied using in situ hybridization, laser microdissection, and quantitative reverse transcriptase‐polymerase chain reaction. Expression levels were comparable between all regions. These data demonstrate a lamina‐specific distribution of Synaptopodin within dendritic segments of identified neurons. Within dendrites, the majority of Synaptopodin‐positive puncta were located in spines where they represent spine apparatuses. We conclude, that this organelle is distributed in a region‐ and layer‐specific manner in the mouse hippocampus and suggest that differences in the activity of afferent fiber systems could determine its distribution. J. Comp. Neurol. 487:227–239, 2005.

Vessel ultrastructure in APP23 transgenic mice after passive anti-Aβ immunotherapy and subsequent intracerebral hemorrhage

Passive immunization of amyloid precursor protein (APP) transgenic mice with anti-amyloid beta (Abeta) antibodies was shown to reduce Abeta-deposition in brain and to improve cognition. However, immunotherapy may also be accompanied by a significant increase in the frequency of intracerebral hemorrhages. Because hemorrhages are associated with amyloid-laden vessels, this raises the question whether high concentrations of anti-Abeta antibodies may directly or indirectly lead to a structural destabilization of the vessel wall. To address this point, transmission electron microscopy was performed and the ultrastructure of bleeding and non-bleeding vessels in immunized and non-immunized APP23 transgenic animals was analyzed. To localize bleeding vessels, hemosiderin-positive macrophages were visualized by pre-embedding Perls Berlin Blue histochemistry. Vessels were analyzed morphologically, anomalies evaluated and quantified. Bleeding vessels were, furthermore, reconstructed in three dimensions to analyze the spatial distribution of amyloid deposits and other pathological changes of the vessel wall. This in-depth morphological analysis revealed that bleeding vessels in immunized as well as in non-immunized APP23 mice were surrounded by a higher number of macrophages compared to non-bleeding vessels in the same animals. However, no differences in the number of macrophages or other structural parameters, such as amyloid deposition, were observed between bleeding vessels of immunized and non-immunized mice. No pathologies which may indicate impending bleeding were observed in the vascular wall of non-bleeding vessels. We conclude, that the increased hemorrhage frequency observed after passive immunization with anti-Abeta antibodies does not lead to overt structural changes in the vessel wall of APP23 transgenic mice. Minor structural alterations of the vessel wall, however, cannot be excluded due to the sample size of our study and the high complexity of the three-dimensional vessel wall ultrastructure.

Repetitive magnetic stimulation induces plasticity of inhibitory synapses

Repetitive transcranial magnetic stimulation (rTMS) is used as a therapeutic tool in neurology and psychiatry. While repetitive magnetic stimulation (rMS) has been shown to induce plasticity of excitatory synapses, it is unclear whether rMS can also modify structural and functional properties of inhibitory inputs. Here we employed 10-Hz rMS of entorhinohippocampal slice cultures to study plasticity of inhibitory neurotransmission on CA1 pyramidal neurons. Our experiments reveal a rMS-induced reduction in GABAergic synaptic strength (2–4 h after stimulation), which is Ca2+-dependent and accompanied by the remodelling of postsynaptic gephyrin scaffolds. Furthermore, we present evidence that 10-Hz rMS predominantly acts on dendritic, but not somatic inhibition. Consistent with this finding, a reduction in clustered gephyrin is detected in CA1 stratum radiatum of rTMS-treated anaesthetized mice. These results disclose that rTMS induces coordinated Ca2+-dependent structural and functional changes of specific inhibitory postsynapses on principal neurons.

Synaptopodin regulates denervation-induced homeostatic synaptic plasticity

Synaptopodin (SP) is a marker and essential component of the spine apparatus (SA), an enigmatic cellular organelle composed of stacked smooth endoplasmic reticulum that has been linked to synaptic plasticity. However, SP/SA-mediated synaptic plasticity remains incompletely understood. To study the role of SP/SA in homeostatic synaptic plasticity we here used denervation-induced synaptic scaling of mouse dentate granule cells as a model system. This form of plasticity is of considerable interest in the context of neurological diseases that are associated with the loss of neurons and subsequent denervation of connected brain regions. In entorhino-hippocampal slice cultures prepared from SP-deficient mice, which lack the SA, a compensatory increase in excitatory synaptic strength was not observed following partial deafferentation. In line with this finding, prolonged blockade of sodium channels with tetrodotoxin induced homeostatic synaptic scaling in wild-type, but not SP-deficient, slice cultures. By crossing SP-deficient mice with a newly generated transgenic mouse strain that expresses GFP-tagged SP under the control of the Thy1.2 promoter, the ability of dentate granule cells to form the SA and to homeostatically strengthen excitatory synapses was rescued. Interestingly, homeostatic synaptic strengthening was accompanied by a compensatory increase in SP cluster size/stability and SA stack number, suggesting that activity-dependent SP/SA remodeling could be part of a negative feedback mechanism that aims at adjusting the strength of excitatory synapses to persisting changes in network activity. Thus, our results disclose an important role for SP/SA in homeostatic synaptic plasticity.