Biochemical characterization of mitochondrial and lysosomal particles in old rat liver

Quantifying dense bodies and lipofuscin during aging: a morphologist's perspective

Secondary lysosomes, residual or dense bodies containing lipofuscin or age pigment accumulate in post-mitotic and inter-mitotic cells during aging. The consensus is that the accumulation of this auto-fluorescent material is an index of cellular senescence. Biochemical and morphological studies have independently demonstrated marked age-related increases in the cell and tissue contents of lipofuscin. Most morphological studies on aging have been qualitative, have included only two or three age groups and have not yielded data that are easily correlated with biochemical analyses. One of the best documented age-related changes in hepatocytes and cardiac myocytes is the accumulation of dense bodies and lipofuscin inclusions. Independent stereologic studies reported two- to eightfold age-related increases in the dense body volume fraction of rat hepatocytes. Furthermore, we reported a fourfold increase in the dense body volume fraction of cardiac myocytes in rats between 6 and 30 months of age. These and other studies confirm the use of quantitative morphology to estimate the increases in dense body and lipofuscin inclusions as indices of age. Whether or not the accumulated lipofuscin compromises cell functions in senescent animals has not been adequately addressed. On the one hand, there is little evidence that several-fold increases in this subcellular compartment impair the functional capacities of either hepatocytes or cardiac myocytes. On the other hand, the age-related accumulation of immunoprecipitable, but catalytically inactive, lysosomal enzymes in both liver and heart muscle may be a reflection of increased lipofuscin deposits in the dense bodies.

Cardiolipin prevents rate-dependent uncoupling and provides osmotic stability in yeast mitochondria

The role of cardiolipin in mitochondrial function was studied by comparing the energy-transforming and osmotic properties of mitochondria isolated from the Saccharomyces cerevisiae cardiolipin synthase-null mutant crd1Delta, which has no cardiolipin, and the isogenic wild type. The results indicated that the importance of cardiolipin for energetic coupling strongly depends on the rate of oxidative phosphorylation, which was set by using NADH (maximal rate limited by coupling mechanism) or ethanol (moderate rate limited by electron supply) as a respiratory substrate, or by modulating the steady-state rate of NADH supply. The absence of cardiolipin resulted in only a small effect on oxidative phosphorylation proceeding at a moderate rate, but led to significant uncoupling (decreased ADP/O and increased state 4 respiration) at the maximal rate of respiration. This indicates that cardiolipin prevents rate-dependent uncoupling in the energy-transforming apparatus. This role of cardiolipin may derive from its strong interaction with, and modulation of the function of, respiratory complexes, and from its effects on the physical properties of the membrane. The importance of cardiolipin for mitochondrial osmotic properties was determined by comparing oxidative phosphorylation, release of matrix enzyme, shrinking ability and volume dynamics upon hypotonically induced swelling in crd1Delta and wild-type mitochondria. Opening of the yeast mitochondrial unspecific channel (YMUC) in the wild-type and mutant mitochondria was also tested. It was found that the lack of cardiolipin strongly undermines the osmotic stability of the mitochondrial membrane.

Evidence for and against the causal involvement of mitochondrial DNA mutation in mammalian ageing

Current experimental evidence on the role of mitochondrial DNA mutation in ageing is assessed alongside reports implicating other genetic and non-genetic causes, including inter-relationships between the mitochondrial and nuclear genomes and their potential effect on mitochondrial structure and function. The role of a 5-kb mtDNA deletion, identified as age-dependent in a variety of human and other mammalian species, is specifically evaluated in the context of its functional effect in mitotic and non-mitotic adult tissue. Downstream effects of mitochondrial decline are considered in terms of the maintenance of ATP production. Associated sequelae then are discussed specifically with reference to restrictions in the supply of ribose moieties for DNA and RNA synthesis, and to disruption of NADPH production and hence cellular anti-oxidant defences.

Effect of aging on the activity of the phosphate carrier and on the lipid composition in rat liver mitochondria

The effect of aging on the activity of the phosphate carrier and on the lipid composition in rat liver mitochondria has been investigated. It was found that the rate of phosphate transport in mitochondria from aged rats (28 months old) is significantly reduced (around 40%) compared to that obtained in mitochondria from young control rats (5 months old). Kinetic analysis of the phosphate transport indicates that only the Vmax of this process is affected, while there is no change in the Km values. The lower activity of the phosphate carrier in mitochondria from aged rats is also documented by swelling experiments. The age-related decrement in the activity of the phosphate carrier was found not to be due neither to a change in the endogenous content of phosphate nor to a change in the transmembrane delta pH value. Inhibitor titrations with mersalyl provide no evidence for a lower content of functional phosphate translocase in mitochondria from aged rats. There is no difference either in the respiratory control ratios or in the ADP/O ratios between mitochondria from young and aged animals. The hepatic mitochondrial lipid composition is altered significantly in aged rats: the total cholesterol increases (31%), the phospholipids decrease (12%), and the cholesterol/phospholipid molar ratio increases (44%). Among the phospholipids cardiolipin shows the greatest alteration (30% decrease with age). Alterations were also found in the pattern of fatty acids. The age-related decrement in the activity of the phosphate carrier appears to be dependent on changes in the lipid domain surrounding the carrier protein molecule in the mitochondrial membrane.