Systems biology of mitochondrial dysfunction

The human body consumes vast amounts of metabolites that are transformed into one another, modified to useful building blocks and broken down to harvest their energy. Mitochondria are at the core of this metabolic turnover and oxidative phosphorylation provides most cellular ATP in almost all human tissues. Despite the variability of metabolite and oxygen supply, mitochondria can readily adapt to their cellular niche. This requires a general flexibility in the expression patterns of the roughly 1,150 mitochondrial proteins, and fine tuning of protein actions. Failure to meet the cellular metabolic demand causes a wide range of tissue specific symptoms in human. This thesis explores the use of high­throughput omics techniques in understanding enzy­ matic remodeling during mitochondrial disease. In the first part, I introduce the reader to the concepts of systems biology, and broadly discuss current methods and tools with a focus on mitochondria. Then, I describe the fine­tuning of mitochondrial function by post­translational modifications, in particular protein methylation and phosphorylation, and how this links to the large metabolic network of the one­carbon cycle. I conclude with primers on mitochondria in development and mitochondrial RNA metabolism. After that, I will present four publications in light of the discussed concepts and methods: In study I, we find that the highly abundant metabolite S­adenosylmethionine is indis­ pensable for mitochondrial function. Its cytoplasmic production controls mitochondrial func­ tion by regulating iron­sulfur clusters biosynthesis and stability of the electron transport chain complex I, which has implications during ageing and cancer development. We apply a novel labeling method and mass spectrometry­based proteomics to identify 205 high­confidence methylation sites on mitochondrial proteins in fruit flies, and validate several by targeted pro­ teomics in mouse and human. In study II, we describe SILAF, a novel and highly efficient method to label amino acids in the fruit fly proteome. We exploit SILAF to characterize the mitochondrial phosphoproteome in a fly model of mitochondrial disease, and we pinpoint two regulatory phosphorylation sites. In study III, we investigate the role of the scaffold protein SQSTM1/p62 in neuronal de­ velopment. We find that the protein is required for differentiation of patient­derived neuronal epithelial stem cells, caused by an impaired switch from glycolytic to oxidative metabolism. In study IV, we use various fruit fly models to examine the interactions of proteins in mi­ tochondrial RNA metabolism. Using transcriptomics, we identify leakage of double­stranded RNA into the cytosol when mitochondrial RNA degradation is impaired and we suggest that this contributes to increased susceptibility to infection upon mitochondrial dysfunction. Our studies take a novel view on mitochondrial dysfunction, and our post­translational modification screens give insight into a novel layer of complexity in the cell. The studies expose the opportunities and challenges of data­driven life science and can serve as a primer towards a digital representation of mitochondrial disease

Defects of mitochondrial RNA turnover lead to the accumulation of double-stranded RNA in vivo

The RNA helicase SUV3 and the polynucleotide phosphorylase PNPase are involved in the degradation of mitochondrial mRNAs but their roles in vivo are not fully understood. Additionally, upstream processes, such as transcript maturation, have been linked to some of these factors, suggesting either dual roles or tightly interconnected mechanisms of mitochondrial RNA metabolism. To get a better understanding of the turn-over of mitochondrial RNAs in vivo, we manipulated the mitochondrial mRNA degrading complex in Drosophila melanogaster models and studied the molecular consequences. Additionally, we investigated if and how these factors interact with the mitochondrial poly(A) polymerase, MTPAP, as well as with the mitochondrial mRNA stabilising factor, LRPPRC. Our results demonstrate a tight interdependency of mitochondrial mRNA stability, polyadenylation and the removal of antisense RNA. Furthermore, disruption of degradation, as well as polyadenylation, leads to the accumulation of double-stranded RNAs, and their escape out into the cytoplasm is associated with an altered immune-response in flies. Together our results suggest a highly organised and inter-dependable regulation of mitochondrial RNA metabolism with far reaching consequences on cellular physiology

C6orf203 is an RNA-binding protein involved in mitochondrial protein synthesis.

In all biological systems, RNAs are associated with RNA-binding proteins (RBPs), forming complexes that control gene regulatory mechanisms, from RNA synthesis to decay. In mammalian mitochondria, post-transcriptional regulation of gene expression is conducted by mitochondrial RBPs (mt-RBPs) at various stages of mt-RNA metabolism, including polycistronic transcript production, its processing into individual transcripts, mt-RNA modifications, stability, translation and degradation. To date, only a handful of mt-RBPs have been characterized. Here, we describe a putative human mitochondrial protein, C6orf203, that contains an S4-like domain-an evolutionarily conserved RNA-binding domain previously identified in proteins involved in translation. Our data show C6orf203 to bind highly structured RNA in vitro and associate with the mitoribosomal large subunit in HEK293T cells. Knockout of C6orf203 leads to a decrease in mitochondrial translation and consequent OXPHOS deficiency, without affecting mitochondrial RNA levels. Although mitoribosome stability is not affected in C6orf203-depleted cells, mitoribosome profiling analysis revealed a global disruption of the association of mt-mRNAs with the mitoribosome, suggesting that C6orf203 may be required for the proper maturation and functioning of the mitoribosome. We therefore propose C6orf203 to be a novel RNA-binding protein involved in mitochondrial translation, expanding the repertoire of factors engaged in this process

ANGEL2 phosphatase activity is required for non-canonical mitochondrial RNA processing.

Canonical RNA processing in mammalian mitochondria is defined by tRNAs acting as recognition sites for nucleases to release flanking transcripts. The relevant factors, their structures, and mechanism are well described, but not all mitochondrial transcripts are punctuated by tRNAs, and their mode of processing has remained unsolved. Using Drosophila and mouse models, we demonstrate that non-canonical processing results in the formation of 3\u27 phosphates, and that phosphatase activity by the carbon catabolite repressor 4 domain-containing family member ANGEL2 is required for their hydrolysis. Furthermore, our data suggest that members of the FAST kinase domain-containing protein family are responsible for these 3\u27 phosphates. Our results therefore propose a mechanism for non-canonical RNA processing in metazoan mitochondria, by identifying the role of ANGEL2

Guidelines for the use of flow cytometry and cell sorting in immunological studies (third edition)

The third edition of Flow Cytometry Guidelines provides the key aspects to consider when performing flow cytometry experiments and includes comprehensive sections describing phenotypes and functional assays of all major human and murine immune cell subsets. Notably, the Guidelines contain helpful tables highlighting phenotypes and key differences between human and murine cells. Another useful feature of this edition is the flow cytometry analysis of clinical samples with examples of flow cytometry applications in the context of autoimmune diseases, cancers as well as acute and chronic infectious diseases. Furthermore, there are sections detailing tips, tricks and pitfalls to avoid. All sections are written and peer‐reviewed by leading flow cytometry experts and immunologists, making this edition an essential and state‐of‐the‐art handbook for basic and clinical researchers.DFG, 389687267, Kompartimentalisierung, Aufrechterhaltung und Reaktivierung humaner Gedächtnis-T-Lymphozyten aus Knochenmark und peripherem BlutDFG, 80750187, SFB 841: Leberentzündungen: Infektion, Immunregulation und KonsequenzenEC/H2020/800924/EU/International Cancer Research Fellowships - 2/iCARE-2DFG, 252623821, Die Rolle von follikulären T-Helferzellen in T-Helferzell-Differenzierung, Funktion und PlastizitätDFG, 390873048, EXC 2151: ImmunoSensation2 - the immune sensory syste

Droplet-based screening of phosphate transfer catalysis reveals how epistasis shapes MAP kinase interactions with substrates.

The combination of ultrahigh-throughput screening and sequencing informs on function and intragenic epistasis within combinatorial protein mutant libraries. Establishing a droplet-based, in vitro compartmentalised approach for robust expression and screening of protein kinase cascades (>107 variants/day) allowed us to dissect the intrinsic molecular features of the MKK-ERK signalling pathway, without interference from endogenous cellular components. In a six-residue combinatorial library of the MKK1 docking domain, we identified 29,563 sequence permutations that allow MKK1 to efficiently phosphorylate and activate its downstream target kinase ERK2. A flexibly placed hydrophobic sequence motif emerges which is defined by higher order epistatic interactions between six residues, suggesting synergy that enables high connectivity in the sequence landscape. Through positive epistasis, MKK1 maintains function during mutagenesis, establishing the importance of co-dependent residues in mammalian protein kinase-substrate interactions, and creating a scenario for the evolution of diverse human signalling networks.RCUK | Biotechnology and Biological Sciences Research Council (BBSRC) - BB/M011194/1 EC | Horizon 2020 Framework Programme (EU Framework Programme for Research and Innovation H2020) - 721613 EC | Horizon 2020 Framework Programme (EU Framework Programme for Research and Innovation H2020) - 659029 EC | EU Framework Programme for Research and Innovation H2020 | H2020 Priority Excellent Science | H2020 European Research Council (H2020 Excellent Science - European Research Council) - 69566

FBXL4 deficiency increases mitochondrial removal by autophagy

Abstract Pathogenic variants in FBXL4 cause a severe encephalopathic syndrome associated with mtDNA depletion and deficient oxidative phosphorylation. To gain further insight into the enigmatic pathophysiology caused by FBXL4 deficiency, we generated homozygous Fbxl4 knockout mice and found that they display a predominant perinatal lethality. Surprisingly, the few surviving animals are apparently normal until the age of 8–12 months when they gradually develop signs of mitochondrial dysfunction and weight loss. One‐year‐old Fbxl4 knockouts show a global reduction in a variety of mitochondrial proteins and mtDNA depletion, whereas lysosomal proteins are upregulated. Fibroblasts from patients with FBXL4 deficiency and human FBXL4 knockout cells also have reduced steady‐state levels of mitochondrial proteins that can be attributed to increased mitochondrial turnover. Inhibition of lysosomal function in these cells reverses the mitochondrial phenotype, whereas proteasomal inhibition has no effect. Taken together, the results we present here show that FBXL4 prevents mitochondrial removal via autophagy and that loss of FBXL4 leads to decreased mitochondrial content and mitochondrial disease