Artur Czupryn

Distribution of synaptic zinc in the developing mouse somatosensory barrel cortex

Histochemical localization of synaptic zinc was examined in the somatosensory (SI) barrel cortex of mouse. The laminar distribution and distribution within the barrel field were described. At postnatal day 3 (P3) and 5 (P5), very faint and uniform zinc staining was present in the lower part of the subplate. At P6, subtle laminar variations emerged. At P8, these variations were clearly observed. Intense zinc staining was found in layers I, II, III, and V. Layers IV and VI showed a weaker staining. From this postnatal age to adult, uneven patchy distribution of synaptic zinc in layer IV could be distinguished in coronal sections. In tangential sections through layer IV, zinc staining showed a barrel‐like pattern due to a higher zinc concentration in septa and the surrounding cortex. Barrel sides revealed a lower zinc concentration compared with the barrel hollow. With brain maturation, the zinc staining increased more intensely outside the barrel field, thus producing a progressively higher contrast between the barrel field and adjacent cortical regions. The differences in zinc staining between the barrel side and barrel hollow diminished with age but were still visible at P70. The changes in synaptic zinc distribution probably reflect the process of synaptic maturation of glutamatergic terminals projecting to the SI cortex. The time course of postnatal changes in terminal zinc distribution suggests that synaptic zinc is not involved in the mechanisms of barrel formation. J. Comp. Neurol. 386:652–660, 1997.

Increase in synaptic hippocampal zinc concentration following chronic but not acute zinc treatment in rats

Electroconvulsive seizures (ECS), one of the most effective treatments of depression, induce mossy fiber sprouting (when assayed by means of synaptic zinc method), and this indicates an increase in the synaptic zinc level in the hippocampus following such therapy. The aim of the present study was to investigate the influence of acute and chronic zinc hydroaspartate administration on the synaptic and total zinc level in the rat hippocampus. We used two methods of zinc determination: (1) zinc-selenium method, which images the pool of synaptic zinc, and (2) flame atomic absorption spectrometry, which assays the total concentration of zinc. Our results indicate that chronic (14 x 65 mg/kg), but not acute, zinc hydroaspartate administration intraperitoneally (i.p.) increases the pool of synaptic zinc in the majority of rat hippocampal layers (by 72-190%), except for the stratum moleculare and stratum radiatum CA, and perforant path DG. On the other hand, no changes were found in total hippocampal zinc level, measured by flame atomic absorption spectrometry. These data suggest that chronic zinc treatment increases the pool of synaptic zinc in the hippocampus, and this effect is similar to that observed following chronic ECS treatment. The measurement of zinc concentration in the whole hippocampus by the flame atomic absorption spectrometry method is not sensitive enough to detect such subtle alteration.

Dissociation of synaptic zinc level and zinc transporter 3 expression during postnatal development and after sensory deprivation in the barrel cortex of mice.

In the neocortex, synaptic zinc level is regulated by sensory experience. Previously, we found that trimming of mystacial vibrissae resulted in an increase of synaptic zinc level in corresponding deprived barrels in the cortex of mice. The present study focused on the relationship between synaptic zinc and zinc transporter 3 (ZnT3) protein expression in the barrel cortex of mice during postnatal development and after sensory deprivation of selected vibrissae. Using immunocytochemistry and western blot analysis, we found that ZnT3 expression is delayed as compared with the onset of synaptic zinc and presynaptic markers, such as synapsin I and synaptophysin. Further, neither long-term deprivation in young mice nor short deprivation in adult mice, that resulted in an increase of synaptic zinc level, produced alterations in ZnT3, synapsin I or synaptophysin expression in deprived barrels. These results suggest that in the barrel cortex ZnT3, synapsin I or synaptophysin are not determinant for the activity-dependent regulation of the synaptic zinc level.

Switch time-point for rapid experience-dependent changes in zinc-containing circuits in the mouse barrel cortex.

It has been previously demonstrated that in the mouse barrel cortex, synaptic zinc is regulated by sensory experience. In adult mice, cutting selected vibrissae produced a rapid but transient elevation of synaptic zinc in the corresponding barrels several hours later, whereas in 8 day-old animals this procedure did not affect synaptic zinc. In the present study, we wished to determine the postnatal age at which zinc-containing terminals gain the ability to respond rapidly to a restriction of sensory input. We therefore examined the effects of 1-day sensory deprivation starting at different postnatal ages. For this purpose we unilaterally trimmed all rows of vibrissae, except for row C, and we then visualized synaptic zinc in the barrel cortex 24h later. Up to postnatal day 15 such procedure had no effect on the level of synaptic zinc. However, beginning at postnatal day 16, 1-day sensory deprivation produced an increase in synaptic zinc within hollows of deprived rows of barrels as compared to non-deprived rows. These results show that during development there is a specific time-point after which zinc-containing circuits may respond rapidly to altered sensory inputs. A comparison of these findings with previous results obtained after chronic sensory deprivation suggests that a specific time window exists in development for persistent alterations in zinc-containing circuits.

Deprivation and denervation differentially affect zinc-containing circuitries in the barrel cortex of mice

In the neocortex, a population of glutamatergic synapses contains chelatable zinc that is released upon depolarization. The present study compares the effect of chronic tactile deprivation and vibrissectomy performed at different postnatal ages on the synaptic zinc distribution in the mouse barrel cortex. We found that a chronic unilateral tactile deprivation resulted in an increase of synaptic zinc in deprived barrels. Distribution and intensity of zinc staining in non-deprived barrels resembled the control situation. The increase of zinc staining was observed if chronic deprivation started in early postnatal life or in adolescent mice but not in 70-day-old animals. This suggests that a critical period exists for plasticity of zinc containing terminals in the barrel cortex. The alteration of zinc staining was localized to not only the thalamorecipient layers IV but also layer II/III, and upper layer V. Neonatal denervation of selected vibrissal rows resulted in rearrangement of synaptic zinc distribution following cytoarchitectonic alterations in the barrel field. However, no changes in the intensity of zinc staining were observed. Vibrissectomy performed after the critical period for barrel formation did not affect either the distribution or intensity of zinc staining. It appears that the integrity of vibrissa-barrel pathway is necessary to induce activity-dependent alterations in synaptic zinc.

Deciphering defective subventricular adult neurogenesis in cyclin D2-deficient mice

Adult neurogenesis occurring in the brain of adult mammals is considered to have potential therapeutical applications. New neurons are produced constitutively from postnatal neural stem cells/precursors residing in two neurogenic regions: the subventricular zone (SVZ) of the lateral ventricles and the subgranular layer in the dentate gyrus of the hippocampus. Newly-generated neuroblasts from the SVZ migrate long distance towards the olfactory bulb and repopulate different subtypes of inhibitory interneurons modulating the olfactory processing. It was reported that cyclin D2 knockout mice (cD2-KO) present reduced generation of new hippocampal neurons, however proliferation deficiency and mechanisms responsible for dysregulation of subventricular precursors, derived progenitors, and olfactory interneurons need to be detaily investigated. In this report, proliferative activity of different subpopulations of SVZ neural precursors, cell migration, and differentiation in cD2-KO mice was characterized. For that goal, EdU, a thymidine analogue, proliferation mapping combined with multi-epitope immunohisto-chemical detection of endogenous stage-specific cell markers was carried out. Severely reduced number of newly-generated cells in the subventricular niche was demonstrated that was not accompanied by increased level of apoptotic death. Surprisingly, the number of B1 quiescent precursor subpopulation was not affected, whereas the number of B1 type active primary precursors, intermediate/transiently-amplifying progenitors (C type cells), and neuroblasts (A type cells) were reduced. The analyses suggest that cycline D2 might be critical for transition of B1 precursor quiescent cells into B1 active cells. We also demonstrate that the subpopulation of calbindin interneurons is reduced in the olfactory bulb. Deciphering processes underlying a potential modulation of intensity of adult neurogenesis at the cellular levels could lead to replacement therapies after injury, stroke, or neurodegenerative disease in the central nervous system.

Immunophenotyping and transcriptional profiling of in vitro cultured human adipose tissue derived stem cells

Adipose-derived stem cells (ASCs) have become an important research model in regenerative medicine. However, there are controversies regarding the impact of prolonged cell culture on the ASCs phenotype and their differentiation potential. Hence, we studied 10 clinical ASCs replicates from plastic and oncological surgery patients, in six-passage FBS supplemented cultures. We quantified basic mesenchymal cell surface marker transcripts and the encoded proteins after each passage. In parallel, we investigated the differentiation potential of ASCs into chondrocytes, osteocytes and adipocytes. We further determined the effects of FBS supplementation and subsequent deprivation on the whole transcriptome by comprehensive mRNA and miRNA sequencing. Our results show that ASCs maintain differentiation potential and consistent profile of key mesenchymal markers, with apparent expression of distinct isoforms, in long-term cultures. No significant differences were observed between plastic and oncological surgery cohorts. ASCs in FBS supplemented primary cultures are almost committed to mesenchymal lineages as they express key epithelial-mesenchymal transition genes including early mesenchymal markers. Furthermore, combined mRNA/miRNA expression profiling strongly supports a modulatory role for the miR-30 family in the commitment process to mesenchymal lineages. Finally, we propose improvements to existing qPCR based assays that address alternative isoform expression of mesenchymal markers.