Project description:New and rapid antimicrobial susceptibility/resistance testing methods are required for bacteria from positive blood cultures. In the current study we developed and evaluated a targeted LC-MS/MS assay for the detection of beta-lactam, aminoglycoside and fluoroquinolone resistance mechanisms in blood cultures positive for E. coli or K. pneumoniae. Selected targets were the beta-lactamases SHV, TEM, OXA-1-like, CTX-M-1-like, CMY-2-like, chromosomal E. coli AmpC, OXA-48-like, NDM, VIM and KPC, the aminoglycoside modifying enzymes AAC(3)-Ia, AAC(3)-II, AAC(3)-IV, AAC(3)-VI, AAC(6’)-Ib, ANT(2”)-I and APH(3’)-VI, the 16S-RMTases ArmA, RmtB, RmtC and RmtF, the quinolone resistance mechanisms QnrA, QnrB, AAC(6’)-Ib-cr, the wildtype QRDR of GyrA, and for E. coli, the porins OmpC and OmpF. The developed assay was evaluated using 100 prospectively collected positive blood cultures, 100 negative blood cultures inoculated with isolates that were previously collected from blood cultures, and 48 isolates inoculated with isolates carrying genes of less prevalent resistance mechanisms.

Project description:The role of OXPHOS respiratory supercomplexes remains still unknown. To answer this question we use as a model a SCAF1 null allele model in zebrafish. SCAF1 (cox7a2l) is the only supercomplex assembly factor identified in vertebrates and it is involved in the physical link of III-IV complexes. Therefore the SCAF1 null allele model lack all III-IV interactions. We demonstrate that supercomplexes provide an advantage in the optimization of metabolic resources.

Project description:Respiratory supercomplexes provide metabolic efficiency in zebrafish

Project description:The mitochondrial respiratory chain (MRC) enzymes associate in supercomplexes (SC). This structural interdependency may explain why defects in a single component often produce combined enzyme deficiencies in patients. A point in case is the alleged destabilization of complex I in the absence of complex III. To clarify the structural and functional relationships between complexes, we have used comprehensive proteomic, functional and biogenetical approaches to analyze a MT-CYB-deficient human cell line.

Project description:Reorganization of Mitochondrial Respiratory Supercomplexes Induces Myoblasts Differentiation

Project description:The mitochondrial inner membrane contains a unique phospholipid known as cardiolipin (CL), which stabilises the protein complexes embedded in the membrane and supports its overall structure. Recent evidence indicates that the mitochondrial ribosome may associate with the inner membrane to facilitate co-translational insertion of the hydrophobic oxidative phosphorylation (OXPHOS) proteins into the inner membrane. We generated three mutant knockout cell lines for the cardiolipin biosynthesis gene Crls1 to investigate the effects of cardiolipin loss on mitochondrial protein synthesis. Reduced CL levels caused altered mitochondrial morphology and transcriptome-wide changes that were accompanied by reduced uncoordinated mitochondrial translation rates and impaired respiratory supercomplex formation. Aberrant protein synthesis was caused by impaired formation and distribution of mitochondrial ribosomes. Reduction or loss of cardiolipin resulted in resulted in different mitochondrial and endoplasmic reticulum stress responses. We show that cardiolipin is required to stabilise the interaction of the mitochondrial ribosome with the membrane via its association with OXA1 during active translation. This interaction facilitates insertion of newly synthesised mitochondrial proteins into the inner membrane and stabilises the respiratory supercomplexes.

Project description:It is now accepted that mitochondrial respiratory complex subunits assemble in supercomplexes. However, studying supercomplexes has typically relied upon antibody-based protein quantification, often limited to a single subunit per respiratory complex. To provide a deeper insight into mitochondrial plasticity and supercomplex formation, we combined Blue Native Polyacrylamide Gel Electrophoresis (BN-PAGE) and high-resolution mass spectrometry-based proteomics in sedentary and exercise-trained skeletal muscle. We quantified 422 mitochondrial proteins within ten bands. Our analyses revealed the often-unaccounted presence of complex II and V subunits within the majority of supercomplexes. Upon exercise-induced mitochondrial biogenesis, non-stoichiometric changes in subunits and their incorporation into supercomplexes were apparent. Finally, we uncovered the dynamics of supercomplex-related assembly proteins and mtDNA-encoded subunits within supercomplexes, as well as the high-molecular mass complexes of ubiquinone biosynthesis enzymes and Lactb, a mitochondrial-localized obesogenic polymer. Thus, combining BN-PAGE and mass spectrometry to comprehensively analyze respiratory supercomplexes illuminates previously undetectable complexity in mitochondrial plasticity.

Project description:New and rapid diagnostic methods are needed for the detection of antimicrobial resistance to aid in the curbing of drug-resistant infections. Targeted LC-MS/MS is a method that could serve this purpose, as it can detect specific peptides of resistance mechanisms with high accuracy. In the current study, we aimed to develop an accurate, rapid and high-throughput targeted LC-MS/MS assay based on parallel reaction monitoring for detection of the most prevalent aminoglycoside modifying enzymes and 16S ribosomal RNA methyltransferases in E. coli and K. pneumoniae that confer resistance to the most commonly used aminoglycosides. Specific tryptic peptides needed for detection were selected and validated for AAC(3)-Ia, AAC(3)-II, AAC(3)-IV, AAC(3)-VI, AAC(6’)-Ib, AAC(6’)-Ib-cr, ANT(2”)-I, APH(3’)-VI, ArmA, RmtB, RmtC and RmtF. In total, 205 different isolates containing different aminoglycoside resistance mechanisms that consisted mostly of E. coli and K. pneumoniae were selected for assay development and validation. MS results were automatically analyzed and were compared to WGS results which were regarded as the reference. The average sensitivity and specificity for the detection of the different mechanisms by LC-MS/MS compared to WGS was 95.1 % and 98.0 %, respectively. Furthermore, MS results were also used to predict resistance and susceptibility to gentamicin, tobramycin and amikacin in only the E. coli and K. pneumoniae isolates (n=191). The category interpretations were correctly predicted for gentamicin in 97.4 % of the isolates, for tobramycin in 97.4 % of the isolates, and for amikacin in 82.7 % of the isolates. The current study shows that targeted LC-MS/MS can be applied for accurate and rapid detection of aminoglycoside resistance mechanisms.

Project description:In the mutualisms involving certain pseudomyrmicine ants and different myrmecophytes (i.e., plants sheltering colonies of specialized “plant-ant” species in hollow structures), the ant venom contributes to the host plant biotic defenses by inducing the rapid paralysis of defoliating insects and causing intense pain to browsing mammals. Using integrated transcriptomic and proteomic approaches, we identified the venom peptidome of the plant-ant Tetraponera aethiops (Pseudomyrmecinae). The transcriptomic analysis of its venom glands revealed that 40 % of the assembled contigs encoded only seven peptide precursors related to the ant venom peptides from the A-superfamily. Among the 12 peptide masses detected by liquid chromatography-mass spectrometry (LC-MS), nine mature peptide sequences were characterized and confirmed through proteomic analysis. These venom peptides, called pseudomyrmecitoxins (PSDTX), share amino acid sequence homologies with myrmeciitoxins known for their dual offensive and defensive functions on both insects and mammals. Furthermore, we demonstrated through reduction/alkylation of the crude venom that four PSDTXs were homo- and heterodimeric. Thus, we provide the first indication that the defensive venom composition of the ant genus Tetraponera is a streamlined peptidome. We provide the first insights into the defensive venom composition of the ant genus Tetraponera indicative of a streamlined peptidome.

Project description:We identified the chaperone DNAJC30 as an important factor to maintain NADH:ubiquinone oxidoreductase (complex I) activity. In this complexome analysis we detected DNAJC30 in substoichiometric amounts attached to respiratory supercomplexes (I/III2/IVn and demonstrate an accumulation of complex I containing respiratory supercomplexes in the patient cell line with DNAJC30 mutations compared to the control cell line.