Background: Electron transport chain (ETC) complexes, pyruvate dehydrogenase complex (PDC), and α-ketoglutarate dehydrogenase complex (KGDC) are important elements in mitochondrial metabolism. The localization of the aforementioned protein complexes differs since oxidative phosphorylation complexes are membrane proteins, while dehydrogenase complexes (DCs) are contained in the mitochondrial matrix. Our previous cryo-electron tomography (cryo-ET) studies showed the existence of a full oxidative phosphorylation system supercomplex consisting of ETC complexes and ATP synthases (Nesterov et al., 2021). Literature data also shows the binding of fatty acid oxidation enzymes to ETC complex I (Wang et al., 2010). Although it has long been shown that PDCs can bind to complex I (Sumegi et al., 1984) in vitro, this has not been visualized directly in mitochondria and the binding mechanisms are still unknown. Methods: The mitochondria were isolated from Wistar rat heart ventricles according to a standard procedure (Nesterov et al., 2021). The dense mitochondrial suspension was diluted to ~0.3mg/ml in a respiration medium. Phosphorylation was started 10 minutes prior to vitrification. Experimental data was obtained by cryo-ET using Titan Krios and processed with IMOD and RELION. Results: The tomograms show that the significant part of DCs is localized near the inner membrane of partially destroyed mitochondria in an array-like fashion. Sole PDCs and KGDCs can be identified on the images and their position appears to be close to ETC complex I. Subtomogram averaging of close to the membrane DCs showed that there is no specific density between them, suggesting that they are not linked with identical proteins or that this link may be soft. Significant damage to the mitochondrial membrane leads to the formation of membrane-unbound DCs fraction. It suggests that coupling of DCs with ETC complexes can be controlled in vivo by the topology of the inner mitochondrial membrane and the volume of the mitochondrial matrix. Conclusion: The obtained results show a possibility of unprecedentedly large multienzyme complex formation, including almost all main mitochondrial metabolic systems. Although cryo-ET of partially destroyed mitochondria showed close localization of PDC and KGDC to complex I, further studies are required in intact mitochondria. The mechanism of their binding also remains an open question.
Background: Currently, different approaches of active and passive targeted drug delivery are being developed. One of the most promising methods of targeted drug delivery is the use of capsules. For instance, colloidosomes—capsules consisting of the shell formed by colloidal particles at the interface of the emulsion—can be used for targeted delivery of antitumor drugs or any other drugs in liquid form. Here we present results of cryo-EM study of submicrocapsules with the soybean oil core and with the shell consisting of SiO2 nanoparticles and detonation nanodiamonds (DNDs) stabilized with chitosan and alginate. Methods: Сryo-electron tomography (Cryo-ET) was used to identify the morphological features of the submicrocapsules. Preliminary screening of samples and cryo-ET data collection were performed using Titan Krios cryo-EM (ThermoFisher Scientific, US) equipped with Falcon 2 direct electron detector. The restoration of the tomographic series was carried out using IMOD software. Eman2 was used for segmentation and UCSF Chimera was used for visualization of the 3D model. Submicron capsules were obtained by stabilizing oil droplets with a mixture of SiO2 nanoparticles and DNDs. To form a stable shell, an additional layer of silica particles and polyelectrolyte layers of alginate/chitosan were applied to the droplets of the dispersed phase of the emulsion by physical adsorption. Results: Cryo-EM data showed the presence of submicrocapsules with a diameter in the range of 200-900 nm. Although a significant fraction of submicrocapsules was found to be partially destroyed, results of cryo-ET study of intact capsules demonstrated that silicon dioxide nanoparticles form a net, while DNDs form clusters. Conclusion: Here we demonstrate the results of the study of submicron capsules with a shell of silica nanoparticles and DNDs. It was found that a uniform distribution of DNDs is not a prerequisite for the creation of submicron capsules that contradicts the theoretical model.
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