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The role of nuclear-encoded subunits of cytochrome c oxidase in mitochondrial metabolism
Čunátová, Kristýna
Mitochondria, 'the powerhouses of the cell', house the integral metabolism pathway of oxidative phosphorylation to produce the majority of cellular energy. Mammalian cytochrome c oxidase, also called complex IV (cIV), is indispensable for the overall oxidative phosphorylation function as the terminal oxidase, and for its regulation to sustain energetic needs. Since cIV is a multimeric enzyme composed of subunits encoded by nuclear and mitochondrial genomes, its biogenesis is a complicated process, which needs to be coordinated to complete a fully functional complex. Further, the setup of individual nuclear-encoded subunits isoforms of cIV may fine-tune cIV function based on the tissue or the environment context. Despite the physiological and pathological relevance of cIV composition, biogenesis, and the secondary deficiencies triggered by cIV defects, nuclear-encoded subunits' function remains poorly understood. At first, mammalian COX4 subunit isoforms with tissue- and oxygen-dependent expression were studied in the HEK293 cellular model with an exclusive expression of COX4I1 or COX4I2 isoform. Remarkably, the COX4I2 isozyme showed lower affinity to oxygen, which may imply regulation of cIV activity under hypoxia, and is of physiological relevance for the oxygen-sensing mechanism. Further,...
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The role of nuclear-encoded subunits of cytochrome c oxidase in mitochondrial metabolism
Čunátová, Kristýna ; Pecina, Petr (advisor) ; Gahura, Ondřej (referee) ; Ugalde, Cristina (referee)
Mitochondria, 'the powerhouses of the cell', house the integral metabolism pathway of oxidative phosphorylation to produce the majority of cellular energy. Mammalian cytochrome c oxidase, also called complex IV (cIV), is indispensable for the overall oxidative phosphorylation function as the terminal oxidase, and for its regulation to sustain energetic needs. Since cIV is a multimeric enzyme composed of subunits encoded by nuclear and mitochondrial genomes, its biogenesis is a complicated process, which needs to be coordinated to complete a fully functional complex. Further, the setup of individual nuclear-encoded subunits isoforms of cIV may fine-tune cIV function based on the tissue or the environment context. Despite the physiological and pathological relevance of cIV composition, biogenesis, and the secondary deficiencies triggered by cIV defects, nuclear-encoded subunits' function remains poorly understood. At first, mammalian COX4 subunit isoforms with tissue- and oxygen-dependent expression were studied in the HEK293 cellular model with an exclusive expression of COX4I1 or COX4I2 isoform. Remarkably, the COX4I2 isozyme showed lower affinity to oxygen, which may imply regulation of cIV activity under hypoxia, and is of physiological relevance for the oxygen-sensing mechanism. Further,...
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Mitochondrial cytochrome c oxidase: cyanide inhibition and role of assembly factor Surf1 defect
Nůsková, Hana ; Drahota, Zdeněk (advisor) ; Kalous, Martin (referee)
The activity of mitochondrial cytochrome c oxidase (COX) can be affected by either exogenous or endogenous factors. The most efficient and in the environment abundant compound that inhibits COX is cyanide. The very frequent cause of COX deficiency in humans is represented by a defect in the SURF1 gene. The mechanism of cyanide inhibitory effect on COX as well as the conditions for its recovery are not yet fully explained. Three parameters of COX function, namely the transport of electrons (oxygen consumption), the transport of protons (mitochondrial membrane potential, m) and the enzyme affinity to oxygen (p50 value), were studied with regard to the inhibition by KCN and its reversal by pyruvate. The function of COX was analysed in intact isolated rat liver mitochondria, both within the respiratory chain and as a sole enzyme, using succinate or an artificial electron donor ascorbate + TMPD as a substrate. 250 M KCN completely inhibited both electron- and proton-transporting function of COX, and this inhibition was reversible as proved with washing of mitochondria. The addition of 60 mM pyruvate induced the maximal recovery of both parameters to 60 - 80 % of original values. Using KCN in the low concentration range up to 5 M, a profound, 30-fold decrease of COX affinity to oxygen was observed....
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The role of tissue specific isoforms of subunit 4 in assembly and function of cytochrome c oxidase
Čunátová, Kristýna ; Pecina, Petr (advisor) ; Stibůrek, Lukáš (referee)
Oxidative phosphorylation apparatus (OXPHOS) is responsible for production of majority of ATP in mammalian organisms. This process, occurring in the inner mitochondrial membrane, is partly regulated by nuclear-encoded subunits of cytochrome c oxidase (COX), the terminal enzyme of electron transport chain. Cox4 subunit, participating in OXPHOS regulation, is an early-assembly state subunit, which is necessary for incorporation of Cox2 catalytic subunit, thus for assembly of catalytically functional COX enzyme. Moreover, regulated expression of two isoforms (Cox4i1, Cox4i2) of Cox4 subunit is hypothesized to optimize respiratory chain function according to tissue oxygen supply. However, the functional impact of the isoform switch for mammalian tissues and cells is still only partly understood. In the present thesis, unique HEK293 cell line-based model with complete absence of subunit Cox4 (knock-out, KO) was prepared employing novel CRISPR CAS9-10A paired nickase technology and further characterized. Knock-out of both isoforms Cox4i1 and Cox4i2 (COX4i1/4i2 KO clones) showed general decrease of majority of Cox subunits resulting in total absence of fully assembled COX. Moreover, detected Complex I subunits as well as the content of assembled Complex I were decreased in COX4i1/4i2 KO clones. On the...
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Biochemical and molecular studies of cytochrome c oxidase and ATP synthase deficiencies
Fornůsková, Daniela ; Zeman, Jiří (advisor) ; Hyánek, Josef (referee) ; Stiborová, Marie (referee)
Mgr. Daniela Fornuskova PhD thesis Biochemical and molecular studies of cytochrome c oxidase and ATP synthase deficiencies ABSTRACT The mammalian organism fully depends on the oxidative phosphorylation system (OXPHOS) as the major energy (ATP) producer of the cell. Disturbances of OXPHOS may be caused by mutations in either mitochondrial DNA (mtDNA) or nuclear DNA (nDNA). One part of the thesis is focused on the role of early and late assembled nuclear-encoded structural subunits of cytochrome c oxidase (CcO) as well as Oxa1l, the human homologue of the yeast mitochondrial Oxa1 translocase, in the biogenesis and function of the human CcO complex using stable RNA interference of COX4, COX5A, COX6A1 and OXA1L, as well as expression of epitope-tagged Cox6a, Cox7a and Cox7b, in HEK (human embryonic kidney)- 293 cells. Our results indicate that, whereas nuclear- encoded CcO subunits Cox4 and Cox5a are required for the assembly of the functional CcO complex, the Cox6a subunit is required for the overall stability of the holoenzyme. In OXA1L knockdown HEK-293 cells, intriguingly, CcO activity and holoenzyme content were unaffected, although the inactivation of OXA1 in yeast was shown to cause complete absence of CcO activity. In addition, we compared OXPHOS protein deficiency patterns in mitochondria from skeletal...
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Regulation and Disorders of Mammalian Cytochrome c Oxidase
Kovářová, Nikola ; Houštěk, Josef (advisor) ; Stibůrek, Lukáš (referee) ; Kalous, Martin (referee)
Cytochrome c oxidase (COX) represents the terminal enzyme complex of respiratory chain metabolic pathway and it occurs as monomer, dimer or as a part of respiratory supercomplexes in the inner mitochondrial membrane. COX assembly process is complicated, highly regulated and depends on many ancillary proteins. Mutations in COX subunits, which are encoded by mitochondrial and nuclear DNA, or in genes encoding its assembly proteins are frequent cause of very severe mitochondrial disorders. SURF1 assembly protein participates in the first steps of COX assembly, but its exact function is not yet clarified. In humans, mutations of SURF1 gene lead to severe COX defect and fatal neurodegenerative disorder, Leigh syndrome. Knockout of SURF1 gene in mouse causes isolated COX defect as well, but less pronounced and without involvement of CNS. The aim of the thesis was detailed analysis of disturbed COX biogenesis in a condition of SURF1 gene mutations or SURF1 gene knockout, from assembly of COX monomer to interaction of COX into supercomplexes, and to the impact of isolated COX defect on other OXPHOS complexes. Mutations of SURF1 gene in patient's fibroblasts led to marked accumulation of COX assembly intermediates and to a defect in formation of functional COX monomer, which was preferentially built into an...
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The role of tissue specific isoforms of subunit 4 in assembly and function of cytochrome c oxidase
Čunátová, Kristýna ; Pecina, Petr (advisor) ; Stibůrek, Lukáš (referee)
Oxidative phosphorylation apparatus (OXPHOS) is responsible for production of majority of ATP in mammalian organisms. This process, occurring in the inner mitochondrial membrane, is partly regulated by nuclear-encoded subunits of cytochrome c oxidase (COX), the terminal enzyme of electron transport chain. Cox4 subunit, participating in OXPHOS regulation, is an early-assembly state subunit, which is necessary for incorporation of Cox2 catalytic subunit, thus for assembly of catalytically functional COX enzyme. Moreover, regulated expression of two isoforms (Cox4i1, Cox4i2) of Cox4 subunit is hypothesized to optimize respiratory chain function according to tissue oxygen supply. However, the functional impact of the isoform switch for mammalian tissues and cells is still only partly understood. In the present thesis, unique HEK293 cell line-based model with complete absence of subunit Cox4 (knock-out, KO) was prepared employing novel CRISPR CAS9-10A paired nickase technology and further characterized. Knock-out of both isoforms Cox4i1 and Cox4i2 (COX4i1/4i2 KO clones) showed general decrease of majority of Cox subunits resulting in total absence of fully assembled COX. Moreover, detected Complex I subunits as well as the content of assembled Complex I were decreased in COX4i1/4i2 KO clones. On the...
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Regulation and Disorders of Mammalian Cytochrome c Oxidase
Kovářová, Nikola ; Houštěk, Josef (advisor) ; Stibůrek, Lukáš (referee) ; Kalous, Martin (referee)
Cytochrome c oxidase (COX) represents the terminal enzyme complex of respiratory chain metabolic pathway and it occurs as monomer, dimer or as a part of respiratory supercomplexes in the inner mitochondrial membrane. COX assembly process is complicated, highly regulated and depends on many ancillary proteins. Mutations in COX subunits, which are encoded by mitochondrial and nuclear DNA, or in genes encoding its assembly proteins are frequent cause of very severe mitochondrial disorders. SURF1 assembly protein participates in the first steps of COX assembly, but its exact function is not yet clarified. In humans, mutations of SURF1 gene lead to severe COX defect and fatal neurodegenerative disorder, Leigh syndrome. Knockout of SURF1 gene in mouse causes isolated COX defect as well, but less pronounced and without involvement of CNS. The aim of the thesis was detailed analysis of disturbed COX biogenesis in a condition of SURF1 gene mutations or SURF1 gene knockout, from assembly of COX monomer to interaction of COX into supercomplexes, and to the impact of isolated COX defect on other OXPHOS complexes. Mutations of SURF1 gene in patient's fibroblasts led to marked accumulation of COX assembly intermediates and to a defect in formation of functional COX monomer, which was preferentially built into an...
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Expression of selected defects of oxidative phosphorylation system in cultivated fibroblasts
Marková, Michaela ; Hansíková, Hana (advisor) ; Kalous, Martin (referee)
AAbbssttrraacctt:: The mammalian organism is entirely dependent on ATP production by oxidative phosphorylation system (OXPHOS) on the inner mitochondrial membrane. OXPHOS is composed of respiratory chain complexes I-IV, ATP synthase and also include two electron transporters cytochrome c and coenzyme Q. Disorders of mitochondrial energy metabolism caused by OXPHOS defects are characterized by extreme heterogeneity of clinical symptoms, variability of tissues affected and the severity of the defect at the level of individual tissues. The mitochondrial disorders are not always clearly expressed at the level of available tissue or most easily available cultured fibroblasts and/or currently available methods are not capable to detect the defects on the fibroblasts level. The aim of this master thesis was to identify by biochemical methods, especially by high sensitive polarography, OXPHOS disorders in cultured fibroblasts. Cell lines from 10 patients with isolated (SURF21, SCO1 ND1, ND5) or combined defects of OXPHOS complexes whose biochemical defect was confirmed in muscle tissue as well as 14 patients with non- mitochondrial diseases (8 patients with Huntington disease, 6 patients with disorder of sulphur amino acids metabolism) were analysed. Furthermore impact of various cultivation conditions on OXPHOS...
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