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Inborn Errors of Metabolism01:20

Inborn Errors of Metabolism

Phenylketonuria (PKU) is a protein metabolism disorder characterized by high blood levels of the amino acid phenylalanine. This results from a mutation in the gene responsible for phenylalanine hydroxylase, an enzyme that converts phenylalanine into tyrosine. When this enzyme is deficient, phenylalanine builds up in the blood, leading to symptoms such as vomiting, rashes, seizures, growth deficiency, and severe mental retardation. An early diagnosis and a diet restricting phenylalanine intake...
ATP Synthase: Mechanism01:48

ATP Synthase: Mechanism

In animals, the mitochondrial F1F0 ATP synthase is the key protein that synthesizes ATP molecules through a complex catalytic mechanism. While the nuclear genome encodes the majority of ATP synthase subunits, the mitochondrial genome encodes some of the enzyme's most critical components. The formation of this multi-subunit enzyme is a complex multi-step process regulated at the level of transcription, translation, and assembly. Defects in one or more of these steps can result in decreased ATP...
Animal Mitochondrial Genetics02:59

Animal Mitochondrial Genetics

Among all the organelles in an animal cell, only mitochondria have their own independent genomes. Animal mitochondrial DNA is a double-stranded, closed-circular molecule with around 20,000 base pairs. Mitochondrial DNA is unique in that one of its two strands, the heavy, or H, -strand is guanine rich, whereas the complementary strand is cytosine rich and called the light, or L, -strand. Compared to nuclear DNA, mitochondrial DNA has a very low percentage of non-coding regions and is marked by...
Mitochondrial Precursor Proteins01:39

Mitochondrial Precursor Proteins

Mitochondrial precursors are partially unfolded or loosely folded polypeptide chains. Newly synthesized precursors are inhibited from spontaneously folding into their native conformation by the cytosolic chaperones, heat shock proteins 70 (Hsp70), and mitochondrial import stimulation factors (MSFs). Precursors bound to MSFs are guided to the TOM70-TOM37 receptors, while precursors bound to Hsp70  chaperones are targetted to TOM20-TOM22 receptor complexes.
Most of the mitochondrial precursors...
Electron Transport Chain: Complex I and II01:46

Electron Transport Chain: Complex I and II

The mitochondrial electron transport chain (ETC) is the main energy generation system in the eukaryotic cells. However, mitochondria also produce cytotoxic reactive oxygen species (ROS) due to the large electron flow during oxidative phosphorylation. While Complex I is one of the primary sources of superoxide radicals, ROS production by Complex II is uncommon and may only be observed in cancer cells with mutated complexes.
ROS generation is regulated and maintained at moderate levels necessary...
Translocation of Proteins into the Mitochondria01:19

Translocation of Proteins into the Mitochondria

Mitochondrial precursors are translocated to the internal subcompartments via independent mechanisms involving distinct protein machineries called translocases.
Sorting of outer membrane proteins:
Mitochondrial outer membrane proteins are of two types: the transmembrane, beta-barrel porins, and the membrane-anchored, alpha-helical proteins. Beta-barrel porin precursors are translocated by the TOM complex and inserted into the outer mitochondrial membrane by the SAM complex. In contrast,...

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Related Experiment Video

Updated: Jun 27, 2026

Visualization of Mitochondrial Respiratory Function using Cytochrome C Oxidase / Succinate Dehydrogenase (COX/SDH) Double-labeling Histochemistry
06:53

Visualization of Mitochondrial Respiratory Function using Cytochrome C Oxidase / Succinate Dehydrogenase (COX/SDH) Double-labeling Histochemistry

Published on: November 23, 2011

Mitochondrial dysfunction in mut methylmalonic acidemia.

Randy J Chandler1, Patricia M Zerfas, Sara Shanske

  • 1Genetic Diseases Research Branch, National Human Genome Research Institute, National Institutes of Health, Bethesda, MD 20892, USA.

FASEB Journal : Official Publication of the Federation of American Societies for Experimental Biology
|December 18, 2008
PubMed
Summary
This summary is machine-generated.

Methylmalonic acidemia causes mitochondrial dysfunction, leading to enlarged mitochondria and impaired respiratory function in affected tissues. This study in mice and a patient highlights tissue-specific pathology and suggests mitochondrial support as a therapeutic strategy.

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Area of Science:

  • Biochemistry
  • Genetics
  • Mitochondrial Biology

Background:

  • Methylmalonic acidemia is an inherited metabolic disorder affecting multiple organ systems.
  • The underlying cause is defective methylmalonyl-CoA mutase (MUT) activity.
  • Mitochondrial dysfunction's role in this organic acidemia requires further investigation.

Purpose of the Study:

  • To investigate mitochondrial ultrastructure and respiratory chain function in methylmalonic acidemia.
  • To determine if mitochondrial dysfunction is a key feature of this metabolic disorder.
  • To correlate findings in a mouse model with human patient data.

Main Methods:

  • Construction and analysis of a background-modified Mut-knockout mouse model.
  • Examination of mitochondrial ultrastructure in liver, pancreas, and kidney tissues.
  • Assessment of respiratory chain enzyme activity and intracellular glutathione levels.
  • Histopathological and biochemical analysis of liver tissue from a methylmalonic acidemia patient.

Main Results:

  • Mut(-/-) mice developed enlarged mitochondria (megamitochondria) in hepatocytes early in life.
  • Significant respiratory chain dysfunction, including diminished cytochrome c oxidase activity, was observed in mutant mouse liver extracts.
  • Megamitochondria and tubulointerstitial renal disease were noted in other tissues and in older mice.
  • Human patient liver samples showed similar morphological and enzymatic abnormalities.

Conclusions:

  • Mitochondrial dysfunction and megamitochondria formation are characteristic features of methylmalonic acidemia.
  • These mitochondrial defects occur in a tissue-specific manner.
  • Findings suggest therapeutic strategies targeting mitochondrial function and oxidative stress.