Analysis of the role of Cox20 during the early steps of Cox2 biogenesis

Lorenzi, Isotta

18 March 2016

No description available.

610

Ribosome

Cytochrome c oxidase

Mitochondria

Cox2

Respiratory chain

Biologie (PPN619875151)

Exprese vybraných defektů oxidativní fosforylace na úrovni kultivovaných fibroblastů. / Expression of selected defects of oxidative phosphorylation system in cultivated fibroblasts

Marková, Michaela

January 2015

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...

Evolutionary Relationships Among Duiker Antelope (Bovidae: Cephalophinae)

Johnston, Anne

17 December 2011

Duikers are a species rich subfamily of threatened African antelope whose recent origin poses a challenge to the molecular identification of taxa and estimation of their phylogeny. I test the ability of DNA barcodes to identify all taxa within this group. I then use mitochondrial and nuclear genes to estimate a multi-locus species tree and to date divergence times. DNA barcodes are unable to distinguish many sister taxa, calling into question the utility of barcodes for the regulation of duiker trade or in identification of field-collected feces. The multi-locus phylogeny provides support for the relationships among major duiker lineages and placement of two problematic taxa, but challenges the validity of the savanna genus and identifies hybridization between taxa. This study reveals that most duikers diverged during the Pleistocene, meriting further inquiry into the role that Pleistocene glacial cycling played in the diversification and population structuring of duikers.

Barcode

Cytochrome c oxidase subunit 1 (COX1)

Bushmeat, Pleistocene

Phylogeny

Africa

Evolution

Úloha tkáňově specifických izoforem podjednotky 4 v sestavování a funkci cytochrom c oxidázy / The role of tissue specific isoforms of subunit 4 in assembly and function of cytochrome c oxidase

Čunátová, Kristýna

January 2018

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...

Connecting genotype to phenotype: drosophila simulans mitochondria as a model.

Melvin, Richard G, Biotechnology & Biomolecular Science, UNSW

January 2008

The influence of genotype variation on phenotype has been a longstanding question in biology but it is now one of the greatest challenges of the post-genomics era. Discovering the link between common gene variants that affect phenotypes within and between populations is likely to provide insight into the molecular physiology of phenotypic traits and the mechanisms by which they evolve. The overall goal of this thesis is to link naturally occurring genotypic variation with the organism??s phenotype. The specific goal of this thesis is to connect natural variation in the mitochondrial genotype with the organismal phenotype using the model organism Drosophila simulans. Mitochondria are intracellular organelles found in most eukaryotes and produce over 90% of the energy needed by cells. Determining the connection of mitochondrial genotype to whole organism phenotype is of particular interest because of the broad use of mitochondrial (mt) DNA as a molecular marker in evolutionary biology and population genetics, the organelle??s central role in cellular energy production, the potential for the mitochondria to influence organismal distribution particularly in the face of climate change and in human degenerative disease. I use the model organism D. simulans because it has high genetic variability, can be easily sampled from the wild and manipulated in the lab, and the energy producing reactions that take place in its mitochondria are highly conserved among metazoa. I studied naturally occurring mutations to understand the influence of these changes in natural populations. The four studies in this thesis have employed a Genotype-Biochemistry-Phenotype (GBP) model to link naturally occurring variation in the mitochondrial genotype with organism phenotype in D. simulans mitochondria. Three major conclusions can be drawn from the thesis that follow the genotype to biochemistry to phenotype model. Firstly, a subset of the mutations in genes that comprise the mitochondrial genotype is functionally significant. Secondly, the biochemical efficiency of OXPHOS is regulated by mitochondrial homeostasis. Thirdly, key organismal life history traits influenced by the mitochondrial genotype and this is mediated through the biochemistry of OXPHOS.

Genotype

Phenotype

Mitochondria

mtDNA

Drosophila

Candidate complex approach

Cytochrome c oxidase

Metabolism

Drosophilidae

Genotype-environment interaction

Connecting genotype to phenotype: drosophila simulans mitochondria as a model.

Melvin, Richard G, Biotechnology & Biomolecular Science, UNSW

January 2008

The influence of genotype variation on phenotype has been a longstanding question in biology but it is now one of the greatest challenges of the post-genomics era. Discovering the link between common gene variants that affect phenotypes within and between populations is likely to provide insight into the molecular physiology of phenotypic traits and the mechanisms by which they evolve. The overall goal of this thesis is to link naturally occurring genotypic variation with the organism??s phenotype. The specific goal of this thesis is to connect natural variation in the mitochondrial genotype with the organismal phenotype using the model organism Drosophila simulans. Mitochondria are intracellular organelles found in most eukaryotes and produce over 90% of the energy needed by cells. Determining the connection of mitochondrial genotype to whole organism phenotype is of particular interest because of the broad use of mitochondrial (mt) DNA as a molecular marker in evolutionary biology and population genetics, the organelle??s central role in cellular energy production, the potential for the mitochondria to influence organismal distribution particularly in the face of climate change and in human degenerative disease. I use the model organism D. simulans because it has high genetic variability, can be easily sampled from the wild and manipulated in the lab, and the energy producing reactions that take place in its mitochondria are highly conserved among metazoa. I studied naturally occurring mutations to understand the influence of these changes in natural populations. The four studies in this thesis have employed a Genotype-Biochemistry-Phenotype (GBP) model to link naturally occurring variation in the mitochondrial genotype with organism phenotype in D. simulans mitochondria. Three major conclusions can be drawn from the thesis that follow the genotype to biochemistry to phenotype model. Firstly, a subset of the mutations in genes that comprise the mitochondrial genotype is functionally significant. Secondly, the biochemical efficiency of OXPHOS is regulated by mitochondrial homeostasis. Thirdly, key organismal life history traits influenced by the mitochondrial genotype and this is mediated through the biochemistry of OXPHOS.

Genotype

Phenotype

Mitochondria

mtDNA

Drosophila

Candidate complex approach

Cytochrome c oxidase

Metabolism

Drosophilidae

Genotype-environment interaction

The effect of photobiomodulation on cerebral blood flow

Iennaco, Maria

15 May 2021

Photobiomodulation (PBM) therapy involves the irradiation of tissues with red to near- infrared (NIR) light at low power densities to stimulate healing, reduce inflammation, and promote optimal cellular functioning. These beneficial effects are thought to occur due to the absorption of NIR light by the chromophore, and terminal enzyme in the mitochondrial electron transport chain, cytochrome c oxidase (CCO). It is hypothesized that increased oxygen consumption due to the photostimulation of CCO, as well as photodissociation of the vasodilator nitric oxide from its binding site in the binuclear center of CCO, contribute to improved tissue healing by increasing blood flow to the irradiated region. Applied to the brain, PBM therapy has the potential to improve many neurological injuries and diseases for which reduced cerebral blood flow (CBF) is a common finding. This study examines whether cortical irradiation with NIR light has an impact on CBF in mice. Mice were administered brain PBM via 810nm, 190mW LED for 18 minutes. CBF was measured before, during, and after treatment using Doppler Optical Coherence Tomography. Results from 16 trials demonstrated a significant, 40% increase in CBF during NIR treatment. This CBF increase was not observed during control trials. Additionally, irradiation with a 730nm LED did not increase CBF, indicating that the blood flow increase observed with 810nm irradiation was not simply due to tissue heating. These findings provide support for the value of PBM therapy for the treatment of neurological conditions. / 2023-05-14T00:00:00Z

Biomedical engineering

Cytochrome C oxidase

Light therapy

Near-infrared light therapy

Optical coherence tomography

Stroke

Vasodilation

Discrete Mitochondrial Aberrations in the Spinal Cord of Sporadic ALS Patients

Delic, Vedad, Kurien, Crupa, Cruz, Josean, Zivkovic, Sandra, Barretta, Jennifer, Thomson, Avery, Hennessey, Daniel, Joseph, Jaheem, Ehrhart, Jared, Willing, Alison E., Bradshaw, Patrick, Garbuzova-Davis, Svitlana

01 August 2018

Amyotrophic lateral sclerosis (ALS) is an adult onset neurodegenerative disease characterized by progressive motor neuron degeneration in the brain and spinal cord leading to muscle atrophy, paralysis, and death. Mitochondrial dysfunction is a major contributor to motor neuron degeneration associated with ALS progression. Mitochondrial abnormalities have been determined in spinal cords of animal disease models and ALS patients. However, molecular mechanisms leading to mitochondrial dysfunction in sporadic ALS (sALS) patients remain unclear. Also, segmental or regional variation in mitochondrial activity in the spinal cord has not been extensively examined in ALS. In our study, the activity of mitochondrial electron transport chain complex IV was examined in post-mortem gray and white matter of the cervical and lumbar spinal cords from male and female sALS patients and controls. Mitochondrial distribution and density in spinal cord motor neurons, lateral funiculus, and capillaries in gray and white matter were analyzed by immunohistochemistry. Results showed that complex IV activity was significantly decreased only in gray matter in both cervical and lumbar spinal cords from ALS patients. In ALS cervical and lumbar spinal cords, significantly increased mitochondrial density and altered distribution were observed in motor neurons, lateral funiculus, and cervical white matter capillaries. Discrete decreased complex IV activity in addition to changes in mitochondria distribution and density determined in the spinal cord in sALS patients are novel findings. These explicit mitochondrial defects in the spinal cord may contribute to ALS pathogenesis and should be considered in development of therapeutic approaches for this disease.

complex IV

cytochrome c oxidase

gray and white matter

immunohistochemistry

RRID:AB_141514

RRID:AB_94052

Biomedical Sciences

Characterization of Three Mutations in Conserved Domain of Subunit III of Cytochrome c Oxidase from Rhodobacter sphaeroides

Omolewu, Rachel

20 December 2010

No description available.

Biochemistry

Biophysics

cytochrome c oxidase

mitochondria, DCCD

rhodobacter sphaeroides

subunit III

site-directed mutagenesis

Habitat selection, cryptic diversity, phylogeny, and phylogeography of the European Lepidocyrtus lanuginosus species group (Collembola: Entomobryidae)

Zhang, Bing

14 December 2018

No description available.

570

DNA barcoding

genetic variation

mitochondrial genes

pigmentation

springtail

ribosomal subunit 28S rDNA D1–2 domain

elongation factor 1-α

cytochrome c oxidase subunit I

cytochrome c oxidase subunit II

Quaternary ice age

genetic structure

Biologie (PPN619462639)