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Large spines are stable and important for memory trace formation. The majority of large spines also contains synaptopodin (SP), an actin-modulating and plasticity-related protein. Since SP stabilizes F-actin, we speculated that the presence of SP within large spines could explain their long lifetime. Indeed, using 2-photon time-lapse imaging of SP-transgenic granule cells in mouse organotypic tissue cultures we found that spines containing SP survived considerably longer than spines of equal size without SP. Of note, SP-positive (SP+) spines that underwent pruning first lost SP before disappearing. Whereas the survival time courses of SP+ spines followed conditional two-stage decay functions, SP-negative (SP-) spines and all spines of SP-deficient animals showed single-phase exponential decays. This was also the case following afferent denervation. These results implicate SP as a major regulator of long-term spine stability: SP clusters stabilize spines, and the presence of SP indicates spines of high stability.
The majority of excitatory synapses terminating on cortical neurons are found on dendritic spines. The geometry of spines, in particular the size of the spine head, tightly correlates with the strength of the excitatory synapse formed with the spine. Under conditions of synaptic plasticity, spine geometry may change, reflecting functional adaptations. Since the cytokine tumor necrosis factor (TNF) has been shown to influence synaptic transmission as well as Hebbian and homeostatic forms of synaptic plasticity, we speculated that TNF-deficiency may cause concomitant structural changes at the level of dendritic spines. To address this question, we analyzed spine density and spine head area of Alexa568-filled granule cells in the dentate gyrus of adult C57BL/6J and TNF-deficient (TNF-KO) mice. Tissue sections were double-stained for the actin-modulating and plasticity-related protein synaptopodin (SP), a molecular marker for strong and stable spines. Dendritic segments of TNF-deficient granule cells exhibited ∼20% fewer spines in the outer molecular layer of the dentate gyrus compared to controls, indicating a reduced afferent innervation. Of note, these segments also had larger spines containing larger SP-clusters. This pattern of changes is strikingly similar to the one seen after denervation-associated spine loss following experimental entorhinal denervation of granule cells: Denervated granule cells increase the SP-content and strength of their remaining spines to homeostatically compensate for those that were lost. Our data suggest a similar compensatory mechanism in TNF-deficient granule cells in response to a reduction in their afferent innervation.
The majority of excitatory synapses terminating on cortical neurons are found on dendritic spines. The geometry of spines, in particular the size of the spine head, tightly correlates with the strength of the excitatory synapse formed with the spine. Under conditions of synaptic plasticity, spine geometry may change, reflecting functional adaptations. Since the cytokine tumor necrosis factor (TNF) has been shown to influence synaptic transmission as well as Hebbian and homeostatic forms of synaptic plasticity, we speculated that TNF-deficiency may cause concomitant structural changes at the level of dendritic spines. To address this question, we analyzed spine density and spine head area of Alexa568-filled granule cells in the dentate gyrus of adult C57BL/6J and TNF-deficient (TNF-KO) mice. Tissue sections were double-stained for the actin-modulating and plasticity-related protein synaptopodin (SP), a molecular marker for strong and stable spines. Dendritic segments of TNF-deficient granule cells exhibited ∼20% fewer spines in the outer molecular layer of the dentate gyrus compared to controls, indicating a reduced afferent innervation. Of note, these segments also had larger spines containing larger SP-clusters. This pattern of changes is strikingly similar to the one seen after denervation-associated spine loss following experimental entorhinal denervation of granule cells: Denervated granule cells increase the SP-content and strength of their remaining spines to homeostatically compensate for those that were lost. Our data suggest a similar compensatory mechanism in TNF-deficient granule cells in response to a reduction in their afferent innervation.
Dendritic spines are small membranous protrusions covering the dendritic tree of principal telencephalic neurons, such as the GC or CA2-pc. The CA2-subregion is crucial for social memory. Dendritic spines are a main site of synaptic plasticity, which is a key element of learning and memory. The plasticity-related protein Synaptopodin (SP) is essential to form the spine apparatus (SA), a spine-specific organelle involved in synaptic plasticity. SP stabilizes dendritic spines. This thesis investigated, for the first time, the dendritic SP-distribution and its influence on spine density and spine head size under different conditions in adult mice ex vivo: 1) SP-overexpression (gain-of-function), 2) SP-deficiency (loss-of-function), and 3) wild type-level of SP-expression in male and female mice (sex-differences in dCA2). SP-overexpression in adult male CSPtg-mice led to a ~doubled ratio of SP+ spines in the OML of the DG, while the spine density, the average spine head size and the average SP-puncta size were not affected. Consistently, SP-deficiency in adult male SP-KO animals had no significant effect on average spine head size. Of importance, under SP-overexpression, many small spines and a few large spines become SP+, assumingly assembling a SA. On a functional level, this may indicate an activation of silent synapses. dCA2 showed sex specific differences in spine density and spine morphology in a layer-specific manner: In males, pc-spines of the basal dCA2-compartment showed larger spine heads than females in the diestrus stage of their cycle (females (diestrus), while spine density was not significantly different. In the apical dCA2-compartment (sr), females (diestrus) showed an increased spine density, while spine head size was still shifted towards larger head sizes in males. In addition, dCA2 showed significant layer-specific differences in spine head size, but in a sex-independent manner: In both sexes, average spine head size in the apical sr was significantly smaller than in the basal so. This findings could reflect a yet unknown compartment-specific difference in synaptic plasticity in the basal compartment, which is preferentially targeted by neuromodulatory input from extrahippocampal sources such as the PVN or SUM99,101,170,189-195. In so of dCA2, there was no sex-specific difference in SP-puncta size or in the ratio of SP+ spines, indicating that SP is distributed in a sex-independent manner in dCA2 in adult mice.