Epigenetic Regulation of Mitochondrial DNA

Johansson, Jennie

January 2020

This mini-review investigates and compiles the latest knowledge regarding epigenetic changes on the mammalian mitochondrial DNA and its proteins. Methylation of the DNA, acetylation of the proteins and silencing of genes by short non-coding RNAs are the main epigenetic changes known today to affect mitochondrial DNA, mostly leading to repression. Methylation mainly occurs at non-CpG sites in the main non-coding region called the D-loop, with methylation patterns being cell type specific. Acetylation of proteins are mainly controlled by the deacetylase SIRT3, with its function being correlated to longevity. On the other hand, mitochondrial dysfunction is directly associated with a plethora of diseases, such as neurodegenerative disorders and heart disorders. The mitochondrion and nucleus are immensely dependent on each other and exchange vital proteins and RNAs, with epigenetic changes on one potentially affecting the other. Recent research shows that heteroplasmy is a proven cause of mitochondrial malfunction and that paternal inheritance is possible. The mitochondrial haplotype also shows different vulnerability to certain diets and diseases, leading to the conclusion that the mitochondrial haplotype can be used to more than just tracing human origins, such as to predicting and preventing diseases.

Acetylation

Epigenetics

Heteroplasmy

Methylation

Mitochondrial haplotype

Mitochondrion

Non coding RNA

Phosphorylation

Genetics

Genetik

Conversion of antigen-specific effector/memory T cells into Foxp3-expressing Treg cells by inhibition of CDK8/19 / CDK8/19阻害による抗原特異的エフェクターメモリーT細胞からFoxp3を発現する制御性T細胞への変換

Akamatsu, Masahiko

25 May 2020

京都大学 / 0048 / 新制・論文博士 / 博士(医学) / 乙第13356号 / 論医博第2202号 / 新制||医||1044(附属図書館) / (主査)教授 生田 宏一, 教授 濵﨑 洋子, 教授 竹内 理 / 学位規則第4条第2項該当 / Doctor of Medical Science / Kyoto University / DFAM

Treg cell induction

CDK8/19 inhibition

STAT5 phosphorylation

antigen-specific Treg cells

490

Studium unikátní signální dráhy Ser/Thr proteinkinázy StkP a fosfatázy PhpP u Streptococcus pneumoniae / Study of the unique signaling pathway of Ser/Thr protein kinase StkP and phosphatase PhpP in Streptococcus pneumoniae

Keil, Jan

January 2021

The major human pathogen Streptococcus pneumoniae is a unique model for the study of eukaryotic-type serine/threonine protein kinases and its cognate phosphatases in bacteria, since it encodes only a single signaling pair composed of the StkP protein kinase and PhpP phosphatase. This signaling pair plays a role in several cellular processes, mainly in cell wall biosynthesis and cell division. StkP and PhpP proteins with a pleiotropic effect appear to regulate a complex signaling cascade by phosphorylation of many substrates. However, only a few have been characterized so far. Using MS analysis, we have identified about 90 phosphopeptides that are potential substrates for the StkP kinase and PhpP phosphatase. This diploma thesis is focused on the characterization of the new substrate Spr0929 and its role in pneumococcal physiology. One of the objectives was to investigate cell morphology of strains carrying deletion of the spr0929 gene in different genetic backgrounds. It turned out that the role of Spr0929 in cell morphology is strain specific. The growth curves of strains with this deletion were compared to that of the wild type in various physiological conditions as well. As Spr0929 contains a nucleoid-associated domain called NdpA, determination of its cell localization was an important...

Exploiting the MLL-rearranged leukemia gene signature to identify molecular targets for novel therapies

Gracia-Maldonado, Gabriel

January 2019

No description available.

Molecular Biology

Gene expression

MEIS1

Innate Immune Signaling

MLL leukemia

LAMP5

Oxidative Phosphorylation

Mécanismes moléculaires contrôlant l’ubiquitination et l’endocytose du transporteur de fer IRON-REGULATED TRANSPORTER 1 d’Arabidopsis thaliana / Molecular mechanisms driving the ubiquitination and endocytosis of the Arabidopsis iron transporter IRON-REGULATED TRANSPORTER 1

Dubeaux, Guillaume

08 December 2016

L’ubiquitination est une modification post-traductionnelle qui joue un rôle majeur chez les organismes vivants. Chez Arabidopsis thaliana, le transporteur de fer racinaire IRT1 est endocyté à la suite de la monoubiquitination de deux résidus lysine situés au niveau de sa grande boucle cytosolique. Cependant, les mécanismes régissant l’endocytose médiée par l’ubiquitine ainsi que son rôle biologique restent flous. Au cours de ma Thèse, j’ai mis en évidence que la dynamique d’IRT1 était contrôlée par les métaux substrats secondaires du transporteur (à savoir le zinc, le manganèse et le cobalt). En l’absence de ces métaux, IRT1 est localisé à la membrane plasmique avec une polarité latérale le positionnant sur la face externe des cellules de l’épiderme racinaire. La présence de ces mêmes métaux à un niveau physiologique entraîne la monoubiquitination d’IRT1 et son internalisation vers les endosomes précoces. J’ai démontré que lorsque les métaux substrats secondaires d’IRT1 sont présents en excès, les modifications monoubiquitine sont alors allongées en chaînes de polyubiquitines liées par le résidu lysine-63, entrainant ainsi son adressage vers la vacuole et sa dégradation. Mes travaux ont par ailleurs permis d’élucider les mécanismes moléculaires impliquées dans la réponse des plantes à l’excès de métaux substrats d’IRT1. J’ai notamment montré que l’endocytose d’IRT1 était dépendante i) d’un motif riche en résidus histidine dans la séquence d’IRT1 qui est capable de fixer ces métaux autres que le fer, ii) de la phosphorylation d’IRT1 au niveau d’un résidu thréonine par une protéine kinase en cours d’investigation, et iii) de l’E3 ligase à domaine RING IDF1. D’un point de vue physiologique, l’endocytose d’IRT1 médiée par l’ubiquitine et dépendante des métaux protège la plante d’une suraccumulation de ces métaux autres que le fer qui sont hautement réactifs. / Ubiquitination is a post-translational modification playing a major role in living organisms. In Arabidopsis thaliana, the root iron transporter IRT1 is endocytosed following the monoubiquitination of two lysine residues located in its large cytosolic loop. However, the mechanisms driving IRT1 ubiquitin-mediated endocytosis and its biological relevance remains unclear. During my PhD, I uncovered that IRT1 dynamics is controlled by its secondary metal substrates (i.e. zinc, manganese and cobalt). In the absence of these non-iron metals, IRT1 is found at the cell-surface of root epidermal cells with an outer lateral polarity, while their presence at physiological levels triggers IRT1 monoubiquitination, internalization and accumulation in early endosomes. However, upon non-iron metal excess, monoubiquitin modifications are extended into K63 polyubiquitin chains to promote the vacuolar targeting of IRT1 and its degradation. I investigated further the molecular mechanisms driving plant responses to non-iron metal excess. I notably showed that this regulation by non-iron metals is dependent on i) a histidine-rich stretch in IRT1 that is able to directly bind to non-iron metals, ii) the subsequent recruitment of a kinase currently under investigation which phosphorylates IRT1 at a threonine residue, and iii) the RING E3 ligase IDF1. Altogether, the metal-dependent ubiquitin-mediated endocytosis of IRT1 protects the plant from overaccumulation of highly reactive non-iron metals.

Nutrition métallique

Ubiquitination

Endocytose

Phosphorylation

Trafic intracellulaire

Polarité

Metal nutrition

Ubiquitination

Endocytosis

Phoshorylation

Intracellular trafficking

Polarity

Adaptorové domény signálních proteinů: analýza fosforylačních míst a role v mechanorecepci / Adaptor domains in signalling proteins: phosphorylation analysis and a role in mechanosensing

Tatárová, Zuzana

January 2012

P130Cas (Crk-associated substrate, CAS) is a multiadaptor protein important in integrin signalling where it positively regulates cell motility, invasion, proliferation and survival. CAS lacks enzymatic activity, but its binding to other signalling proteins could lead to the change of phosphorylation status of its substrate domain, which is the main mode, through which CAS takes part in regulating cell behavior. Local tensions in focal adhesions lead to an extension of CAS substrate domain, leaving phosphorylation sites more accessible for kinases, which subsequently leads to an increased CAS substrate domain phosphorylation. The CAS anchorage in focal adhesions is mediated by its SH3 domain, probably through the interactions with FAK, and also by C-terminal domain, where interaction partners are not known. The aim of my project is to find out, which proteins mediate the CAS anchorage to the focal adhesions. The elucidation of CAS anchorage to focal adhesions will contribute to the understanding of mechanosensory function of CAS. Experimental data suggest that tyrosine phosphorylation of the CAS SH3 domain plays an important role in the regulation of its binding properties. Another goal of my diploma project was to analyze the significance of tyrosine phosphorylation within SH3 domain and other...

Dopad izolovaného deficitu F1FO-ATP syntázy na ostatní komplexy oxidační fosforylace v kožních fibroblastech v závislosti na podmínkách kultivace / Impact of isolate deficiency of F1FO-ATP syntthase on other complexes of oxidative phosphorylation in skin fibroblasts depending on cullture conditions

Kedrová, Kateřina

January 2014

Isolated deficiency of F1FO-ATPsynthase is a soubgroup of mitochondrial diseases caused by mutations in nuclear and mitochondrial-encoded structural subunits, or nuclear-encoded assembly factors of F1FO-ATPsynthase. The most often mutations are found in a MTATP6 gene localized in the mitochondrial DNA and a TMEM70 gene, localized in the nuclear DNA. A MTATP6 gene encodes subunit a of F1FO-ATPsynthase and its mutation usually leads to reduced phosphorylation activity of F1FO-ATPsynthase. A TMEM70 gene encodes a 21 kDa mitochondrial protein of the inner mitochondrial membrane of not completely explained function and its mutation results in the decrease in a content of fully assembled F1FO- ATPsynthase. The aim of this thesis was to investigate the impact of isolated F1FO- ATPsynthase deficiency on the oxidative phosphorylation system (complex I-IV), other selected mitochondrial proteins, and mitochondrial network in two cell lines of primary human skin fibroblasts with an isolated deficiency of F1FO-ATPsynthase (mutation m.8851T>C in MTATP6 and mutation c.317-2A>G in TMEM70) during the first days of their cultivation in media containing galactose or glucose as a carbohydrate source with a presence or absence of L-glutamine. The control cell line was found to have higher amounts of respiratory chain...

Příprava a charakterizace Ca2+/kalmodulin-dependentní protein kinasy kinasy 2 (CaMKK2). / Preparation and characterization of Ca2+/calmodulin-dependent protein kinase kinase 2 (CaMKK2).

Jarosilová, Kateřina

January 2017

Calmodulin kinase cascade is a signaling pathway which is involved in the response to the increasing intracellular calcium levels. Ca2+ is a ubiquitous second messenger which promotes wide-range of cellular signaling events. Many of these signaling pathways start with the binding of Ca2+ to its primary intracellular receptor calmodulin. Calmodulin in turn binds to its downstream targets in the Ca2+ /calmodulin signaling cascade. One of the most important enzymes of this cascade is a Ca2+ /calmodulin-dependent protein kinase kinase 2 (CaMKK2). CaMKK2 is a serine/threonine protein kinase which regulates for example gene transcription or energy homeostasis by phosphorylation of its downstream targets. Catalytic domain (which provides kinase activity) is located in the middle part of the protein and possesses structure typical for kinases. CaMKK2 consists of 588 amino acids but the secondary structure is known only for the region of the kinase domain (298 residues). The rest of the protein is assumed to be unstructured as long as CaMKK2 is not bound to any interaction partner. The aim of this study was to prepare several constructs of human isoform of CaMKK2 for the further structural and activity studies. It is believed that CaMKK2 is regulated by site-specific phosphorylation. Phosphorylation of some...

Studium systému oxidativní fosforylace u vzácných typů mitochondriálních onemocnění / Oxidative phosphorylation system in rare types of mitochondrial diseases

Zdobinský, Tomáš

January 2019

In their bioenergetic metabolism mammalian cells are primarily dependent on ATP production through the oxidative phosphorylation system (OXPHOS). Defects of OXPHOS function can lead to occurrence of mitochondrial disorders with different severity and diverse symptoms. Most severely affected are usually tissues with high energy demand which are also difficult to access for biochemical and other examinations. The aim of this thesis was mainly to characterize the effects of mutations in seven different genes (OPA1, DARS2, NDUFS8, NR2F1, HTRA2, MGME1, POLG) on bioenergetic metabolism and mitochondrial network structure of skin fibroblasts from eight different patients diagnosed with mitochondrial disorders. The main method used was measurement of oxygen uptake by permeabilized cells using highly sensitive polarography. Significant changes in fibroblast respiration of four patients were found. Changes in mitochondrial network morphology were found in two of those and two other patient cell lines compared to controls using fluorescent microscopy and different cultivating conditions. Skin fibroblasts are relatively easy to obtain and offer a number of benefits for both diagnostic and study purposes. The results of this work illustrate the possibilities of their use for validation of potential causal...

Protein kinázy typu AGC a jejich role při regulaci transportu auxinu / The role of AGC protein kinases in the regulation of auxin transport

Martincová, Marie

January 2011

There are several members of the subfamily of plant AGC kinases (AGCVIII) suggested to play a role in the regulation of auxin transport, protein kinases PID, WAG1, WAG2 and D6. They all have been shown to perform regulatory phosphorylation of PIN auxin efflux carriers. It is the asymmetrical subcellular localization of PIN proteins that enables the auxin molecules to be transported through a tissue in a polar manner. Regulation of their expression, localization or activity can therefore affect the quantity and directionality of auxin transport. This thesis is focused on better understanding of the PID-mediated regulation of auxin transport. The auxin accumulation as well as the localization of PIN and PID proteins has been studied using stable and transient expression of Arabidopsis thaliana PID in tobacco cell line BY-2. As shown here, the activity of PID does not enhance the activity of PINs, but still it has a positive effect on auxin efflux by increasing the amount of PIN proteins on the plasma membrane. Results presented here suggest that PID-mediated phosphorylation of PIN proteins most likely promotes their exocytosis from endosomal compartments towards the plasma membrane. Using transient co-expression of PID kinase mutated in its ATP-binding site and PIN1-RFP it was shown that functional...