Long-term synaptic morphometry changes after induction of long-term potentiation and long-term depression in the dentate gyrus of awake rats are not simply mirror phenomena

Mechanisms of expression of long-term synaptic plasticity are believed to involve morphological changes of the activated synapses and remodelling of connectivity. Here, we investigated changes in synaptic and neuronal parameters in the dentate gyrus 24 h after induction of long-term potentiation (LTP) and long-term depression (LTD) in awake rats. In dentate granule cells, tetanization of the medial or lateral perforant paths induces LTP in specific synaptic bands along the dendrites in the middle and outer molecular layers, respectively, and tetanization of the lateral path induces robust LTD heterosynaptically in the middle molecular layer. This functional segregation allowed us to assess morphological changes associated with LTP and LTD in each pathway in the same population of neurons. Electron microscopy and unbiased counting methods were used to estimate neuronal density, axospinous, axodendritic and perforated synapse density, multiple synapse bouton density and postsynaptic density (PSD) area. Whereas there was no change in neuronal density, PSD area and multiple synapse boutons 24 h after either LTP or LTD, there was a noninput-specific increase in unperforated axospinous synapses after both LTP and LTD. However, we found that LTP of the medial, but not lateral, perforant path is associated with a specific increase in perforated axospinous synapses in the potentiated area. We also show that heterosynaptic LTD is associated with an input-specific increase in axodendritic synapse density. These results suggest that each perforant pathway may differ with respect to the nature of LTP-induced long-term changes and show that morphologically LTD is not simply the converse of LTP

Application of the New Stereological Probes to the Study of the Melanosome in Cloudman S91 Melanoma Cells

The relationship between melanosome size and number and melanin content has been investigated in Cloudman S91 melanoma cells growing in vitro using both “model-based” and “design-based” stereological procedures. Cells were cultured for 4 days, harvested at daily intervals, and resin-embedded for light and electron microscopy; one aliquot of each sample of cells was assayed to determine its melanin content. By comparing their volume-weighted mean nuclear volume and their number-weighted mean nuclear volume, we have found that the nuclei of Cloudman melanoma cells form a fairly homogeneous population. The volume fraction and absolute volume of premelanosomes (Vvpm, cell and Vpm) and mature melanosomes (Vvmm, cell and Vmm) were all found to decrease progressively throughout the period of culture as did the number of premelanosomes (Npm) and mature melanosomes (Nmm). Whilst the volume-weighted mean volume of individual stage I and stage II premelanosomes, (vipm), remained fairly constant at about 10 nm3, the volume of individual stage III and IV mature melanosomes showed significant variation ranging between about 13 nm3 and 32 nm3. The melanin content of the cells decreased progressively over the 4 days of culture. There were, however, considerable variations in both the average melanin content per unit volume of mature melanosomes, in the range 170–600 fg/μm3, and in the melanin content per individual mature melanosome, in the range 3–12 fg. Our findings show that stereological techniques can provide unbiased and sensitive tools for the study of the morphological basis of melanogenesis; their value will become even more evident when they are combined with techniques for the localization of melanogenic enzymes and their substrates