Modern electron microscopy (EM) such as fine-scale transmission EM, focused ion beam scanning EM, and EM tomography have enormously improved our knowledge about the synaptic organization of the normal, developmental, and pathologically altered brain. In contrast to various animal species, comparably little is known about these structures in the human brain. Non-epileptic neocortical access tissue from epilepsy surgery was used to generate quantitative 3D models of synapses. Beside the overall geometry, the number, size, and shape of active zones and of the three functionally defined pools of synaptic vesicles representing morphological correlates for synaptic transmission and plasticity were quantified. EM tomography further allowed new insights in the morphological organization and size of the functionally defined readily releasable pool. Beside similarities, human synaptic boutons, although comparably small (approximately 5 µm), differed substantially in several structural parameters, such as the shape and size of active zones, which were on average 2 to 3-fold larger than in experimental animals. The total pool of synaptic vesicles exceeded that in experimental animals by approximately 2 to 3-fold, in particular the readily releasable and recycling pool by approximately 2 to 5-fold, although these pools seemed to be layer-specifically organized. Taken together, synaptic boutons in the human temporal lobe neocortex represent unique entities perfectly adapted to the “job” they have to fulfill in the circuitry in which they are embedded. Furthermore, the quantitative 3D models of synaptic boutons are useful to explain and even predict the functional properties of synaptic connections in the human neocortex.
Background Cardioprotection by preventing or repairing mitochondrial damage is an unmet therapeutic need. To understand the role of cardiomyocyte mitochondria in physiopathology, the reliable characterization of the mitochondrial morphology and compartment is pivotal. Previous studies mostly relied on two‐dimensional (2D) routine transmission electron microscopy (TEM), thereby neglecting the real three‐dimensional (3D) mitochondrial organization. This study aimed to determine whether classical 2D TEM analysis of the cardiomyocyte ultrastructure is sufficient to comprehensively describe the mitochondrial compartment and to reflect mitochondrial number, size, dispersion, distribution, and morphology. Methods Spatial distribution of the complex mitochondrial network and morphology, number, and size heterogeneity of cardiac mitochondria in isolated adult mouse cardiomyocytes and adult wild‐type left ventricular tissues (C57BL/6) were assessed using a comparative 3D imaging system based on focused ion beam‐scanning electron microscopy (FIB‐SEM) nanotomography. For comparison of 2D vs. 3D data sets, analytical strategies and mathematical comparative approaches were performed. To confirm the value of 3D data for mitochondrial changes, we compared the obtained values for number, coverage area, size heterogeneity, and complexity of wild‐type cardiomyocyte mitochondria with data sets from mice lacking the cytosolic and mitochondrial protein BNIP3 (BCL‐2/adenovirus E1B 19‐kDa interacting protein 3; Bnip3−/−) using FIB‐SEM. Mitochondrial respiration was assessed on isolated mitochondria using the Seahorse XF analyser. A cardiac biopsy was obtained from a male patient (48 years) suffering from myocarditis. Results The FIB‐SEM nanotomographic analysis revealed that no linear relationship exists for mitochondrial number (r = 0.02; P = 0.9511), dispersion (r = −0.03; P = 0.9188), and shape (roundness: r = 0.15, P = 0.6397; elongation: r = −0.09, P = 0.7804) between 3D and 2D results. Cumulative frequency distribution analysis showed a diverse abundance of mitochondria with different sizes in 3D and 2D. Qualitatively, 2D data could not reflect mitochondrial distribution and dynamics existing in 3D tissue. 3D analyses enabled the discovery that BNIP3 deletion resulted in more smaller, less complex cardiomyocyte mitochondria (number: P < 0.01; heterogeneity: C.V. wild‐type 89% vs. Bnip3−/− 68%; complexity: P < 0.001) forming large myofibril‐distorting clusters, as seen in human myocarditis with disturbed mitochondrial dynamics. Bnip3−/− mice also show a higher respiration rate (P < 0.01). Conclusions Here, we demonstrate the need of 3D analyses for the characterization of mitochondrial features in cardiac tissue samples. Hence, we observed that BNIP3 deletion physiologically acts as a molecular brake on mitochondrial number, suggesting a role in mitochondrial fusion/fission processes and thereby regulating the homeostasis of cardiac bioenergetics.
Background The oxidative phosphorylation (OXPHOS) that takes place in the mitochondria produces chemical energy in form of ATP, the main energy source of the heart. Proper mitochondrial function determines the contractility of the heart. Changes in myocardial ATP levels are often associated with cardiovascular disease. However, mitochondrial dysfunction remains an unmet therapeutic challenge. The F1FO ATP-synthase protein complex catalyses the last step of OXPHOS, synthesising ATP and determining the respiratory function of cardiac mitochondria. An increased ATP pool during cardiovascular challenges, regulated by F1FO ATP-synthase, could therefore significantly improve the clinical outcome of affected patients. In neurons, Bcl2-familiy members like BCL2/adenovirus E1B 19 kDa protein-interacting protein 3 (BNIP3) have been suggested to be involved in the regulation of metabolic efficiency through interaction with the mitochondrial F1FO ATP synthase. A similar metabolic regulation in the cardiac context remains unclear. Furthermore, BNIP3 has a significant impact on the loss of cardiomyocytes under various pathological conditions and is thus a potential mediator of energy metabolism in cardiomyocytes. Methods and results With native gel-electrophoresis, cardiac BNIP3 of C57BL/6J mice was first identified in higher oligomeric complexes in similar molecular weight range as mitochondrial F1FO ATP-synthase. Using 60Å-precise proximity-ligation assays to determine possible binding partners, F1FO ATP-synthase was uncovered for the first time as an interacting protein of BNIP3. This interaction was confirmed by co-immunoprecipitation of BNIP3 and F1FO ATP-synthase and by spatial localization using electron microscopy. Peptide microarray studies elucidate the f subunit of F1FO ATP-synthase as the structural interaction site. Functional analysis using extracellular flux analyser technology revealed significantly elevated mitochondrial respiratory activity in Bnip3 knock out mice and human cardiomyocytes during BNIP3 inhibition. Increased ATP levels in C57BL/6J mice after acute inhibition of BNIP3 confirmed the observed regulatory effect of BNIP3 on F1FO ATP-synthase activity. Finally, depletion of BNIP3 in mice improves stress resistance with an augmented chronotropic capacity during dobutamine-induced cardiac stress. Conclusion Depletion of BNIP3 suggests a regulatory role of BNIP3 in cardiac mitochondrial energy homeostasis via interaction with F1F0 ATP-synthase in oligomeric complexes. Since acute inhibition of BNIP3 activity allows positive modulation of cardiac performance by elevating the available ATP pool, this may serve as a beneficial treatment for patients with cardiovascular disease in the future. Funding Acknowledgement Type of funding sources: Public grant(s) – National budget only. Main funding source(s): German research foundation (DFG)
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