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Mitochondrial Protein Complexes and Disease Dr Matthew McKenzie (Head) Chern Lim (Postdoctoral Researcher) Abena Nsiah-Sefaa (PhD Student) Monash Institute of Medical Research (MIMR) + Prince Henry’s Institute (PHI) = MIMR-PHI Institute of Medical Research Mitochondria: Powerhouses of the Cell • How do the mitochondria function? • ~1,100 proteins involved • What goes wrong in mito? • Design of new therapies / drugs to fix the defects Ferrari engine 1,078 parts Mitochondria burn sugars and fats to generate ATP • Metabolism of sugars requires 5 protein complexes: • I, III, IV and V • Oxidative Phosphorylation (OXPHOS) • Each complex is made of multiple subunits • Defects in OXPHOS cause Mito Complex I (44 subunits) How are the Complexes Assembled? Separate the protein complexes on a gel (Blue Native Polyacrylamide Gel Electrophoresis: BN-PAGE) Isolated mitochondria from patient skin cells I II III IV Separate by size on gel for analysis Use detergent to make a protein ‘mixture’ I V V OXPHOS Complexes III IV II We can detect all 5 OXPHOS Complexes Loss of Complex I in Mitochondrial Disease CI Prof. Mike Ryan Monash University CV CIII CIV Prof. David Thorburn MCRI Patient Study • Siblings (male and female) • Leigh Syndrome • Examine patient mitochondria on BNPAGE C=control P=patient C P C P C P C P We can determine which complexes are affected in Mito Disease How are the Complexes Assembled? • Complex I assembly is complex! • Sub-complexes (green) are assembled together via a number of discrete stages • Requires additional proteins (colour) that help the assembly process (assembly factors) – 12 known • Defects in the subunits (18) or assembly factors (9) can cause Mito disease Mitochondria burn sugars and fats to generate ATP • Metabolism of fats requires at least 25 proteins • Mitochondrial fatty acid b-oxidation (FAO) • Defects in FAO can cause Mito Medium Chain Acyl-CoA Dehydrogenase (MCAD) Deficiency Prof. Akira Ohtake Saitama University, Japan • Apnea from birth • vomiting, disturbed consciousness at 15 months of age • Lymphocyte (white blood cell) MCAD activity 3.2% of controls * MCAD protein is missing Medium Chain Acyl-CoA Dehydrogenase (MCAD) Deficiency MCAD Deficiency: Are the OXPHOS complexes affected? BN-PAGE FAO protein defect results in OXPHOS Complex I Defect; Important Interactions between two pathways New Models of FAO Disease Take mito patient skin cells: generate induced pluripotent stem (iPS) cells FAO patient skin cells FAO patient iPS cells Pluripotent markers Prof. Jus St John MIMR-PHI Oct4, Sox2 c-Myc, Klf-4 Oct4 Differentiate into neuronal cell types Nestin neural rosette bIII-Tubulin early neurons GFAP astrocytes MAP2 mature neurons Mitochondrial calcium buffering capacity Mitochondrial membrane potential (Dym): TMRM (red) Calcium: Fluo-4 (green) Tra-160 Differentiate into cardiomyocytes Mouse Models of Mitochondrial Disease A/Prof. Ian Trounce CERA • Make mouse models of Mito disease • Understanding of how the disease affects specific organs / tissues • Design and testing of new therapies • Swap mitochondrial DNA (mtDNA) in mouse embryonic stem (ES) cells • Grow mice from ES cells with new, swapped mtDNA Making Mito Mouse Models ES cells with ‘new’ mtDNA Mouse embryo with 100s cells B A B A Figure 3.4.8: A-Founder female chimeric Mus dunni xenocybrid mouse Figure 3.4.8: A-Founder female chimeric Mus dunni xenocybrid mouse (#1, generated from Mus dunni xenocybrid ES clone 7) used for (#1, generated from Mus dunni xenocybrid ES clone 7) used for breeding. This mouse was determined to be ~90% chimeric by coat breeding. This mouse was determined to be ~90% chimeric by coat colour. B-Wild type Mus musculus C57BL/6 mouse. colour. B-Wild type Mus musculus C57BL/6 mouse. * Mitochondrial Defects in Mito Mouse Model • Age-related Disease Model • Loss of Substantia Nigra dopaminergic neurons (as in Parkinson’s disease) • Subtle motor impairment with aging Mitochondrial Oxygen Consumption in Mouse Brain Use technique to generate new mice with other forms of Mito Disease (Funding from AMDF) Accelerated decline in Mito mice brain respiration at 24 months of age Acknowledgements McKenzie Research Group Chern Lim Abena Nsiah-Sefaa Kirsty Carey Complex I Assembly Michael Ryan (Monash University) David Thorburn (MCRI) Xenomouse Models Ian Trounce (CERA) Carl Pinkert (Auburn) Zane Andrews (Monash) FAO Disorders Justin St. John (MIMR-PHI) Avihu Boneh (MCRI) Akira Ohtake (Saitama University) Kei Murayama (Chiba Children’s Hospital) Funding AMDF Australian Research Council Monash University William Buckland Foundation Ophthalmic Research Institute Of Australia (ORIA) Carbohydrate metabolism: Glycolysis Carbohydrate: amylase digestion (saliva, small intestine) Monosacharides: transported across intestinal wall: glycogen or metabolism Glycolysis 1 glucose molecule - 2 ATP (~30 from OXPHOS) Mitochondrial fatty acid b-oxidation (FAO) • Fats stored as triacylglycerol in adipose tissue – metabolized by lipases (activated by glucagon, epinephrine or β-corticotropin via cAMP and PKA) palmitic acid (C16:0) oleic acid (C18:1) b alpha-linolenic acid (C18:3) glycerol Fatty acids -Free fatty acids enter circulation; bound to albumin -enter cells via fatty acid transporters (FATs, eg. FAT/CD36) -activated in cytoplasm to a fatty-acyl CoA ester -palmitate yields ~129 ATP Hardie D G , Sakamoto K Physiology 2006;21:48-60 Metabolic changes induced by AMP-activated protein kinase (AMPK) in muscle, including stimulation of glucose and fatty acid uptake, fatty acid oxidation, mitochondrial biogenesis, inhibition of glycogen synthesis and muscle hypertrophy via inhibition of TOR Glucose-Fatty Acid (Randle) Cycle malonyl-CoA decarboxylase (ACC) acetyl-CoA carboxylase (ACL) ATPcitrate lyase phosphofructokinase-1 PDH kinases Ketone synthesis • Acetyl-CoA generated in the liver can be converted to ketones: acetoacetate, βhydroxybutyrate, and acetone only in liver not in liver! Lactic Acidosis in mitochondrial disease Glycolysis requires NAD+ glucose pyruvate NAD+ TCA cycle acetylCoA Pyruvate dehydrogenase NADH NADH NAD+ NADH NAD+ lactate NADH [NADH] NADH oxidized to NAD+ by complex I. If a defect is present then NADH accumulates X X NAD+ Excess NADH oxidized to NAD+ by reduction of pyruvate to lactate Complex I H+ Fatty acid oxidation defects…Lorenzo’s Oil • Lorenzo Odone (1979-2008): – Adrenoleukodystrophy (ALD) – Progressive damage to brain, peripheral nervous system, adrenal glands (myelin damage) – loss of hearing, speech, sight, paralysis – over-accumulation of very-long chain fatty acids (VLCFAs, C25-C30) – X-linked: ABCD1 gene; peroxisome b-oxidation of VLCFAs (transporter) – Augusto and Michaela Odone devised treatment! (Hugo Moser) – Treat with triacylglycerides of oleic acid (C18:1) and erucic acid (22:1)
