Mitochondrial dysfunction

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Milestones in Cell Division

Apoptosis: A dysfunctional harlequin

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Ackerman and co-workers describe a genetic model for

neurodegeneration that is mediated by oxidative stress. And, in so doing, they

highlight a vital role for a key pro-apoptotic molecule - the apoptosis-inducing

factor - in neuronal survival.

Mitochondrial dysfunction has been implicated in several

neurodegenerative disorders, including Alzheimer's and Parkinson's diseases. The

changes in mitochondrial function can lead to increased energy production and

oxidative stress, and subsequent apoptosis. Reporting in Nature, Ackerman

and co-workers now describe a genetic model for neurodegeneration that is

mediated by oxidative stress. And, in so doing, they highlight a vital role for

a key pro-apoptotic molecule - the apoptosis-inducing factor (AIF) - in neuronal

survival.

The authors were investigating a late-onset neurodegenerative mouse

model called harlequin (Hq). The mutant mice showed a progressive loss of

granule cells from the cerebellum, and TUNEL staining showed various

characteristics of apoptosis in these cells, including nicked DNA, chromatin

condensation and blebbing. There was also a progressive degeneration of retinal

cells in the Hq mutant mice.

Ackerman and co-workers genetically mapped the Hq mutation, and

showed that it is due to a proviral insertion in the Aif gene. This leads to an

80% reduction in Aif messenger RNA and protein relative to wild-type levels.

Under normal physiological conditions, AIF is found in the mitochondrial

intermembrane space. Here it acts as an oxidoreductase, a group of molecules

that have been implicated in maintaining free-radical homeostasis. So the

authors compared the levels of antioxidant enzymes (catalase and glutathione),

lipid peroxidation and DNA oxidative damage between Hq and wild-type mice. They

observed increases in the levels of all of these factors in the Hq mice,

indicating that a loss of AIF function might lead to increased oxidative stress.

As the crystal structure of AIF is similar to that of glutathione

reductase - an enzyme that is involved in recycling of glutathione, and a potent

scavenger of hydrogen peroxide (H2O2) - the authors examined the

H2O2-sensitivity of Hq granule cells. They found that these cells were more

sensitive than wild type to both exogenously and endogenously generated H2O2.

But when mutant granule cells were infected with retrovirus containing wild-type

Aif sequences, the susceptibility to H2O2 was rescued. Moreover, overexpression

of AIF in wild-type neurons resulted in a decreased sensitivity to H2O2.

Finally, abnormalities in the cell cycle have been observed in

degenerating neurons, so the authors examined cell-cycle control in the Hq mice.

A series of experiments showed that granule and retinal cells from Hq mice

re-enter the cell cycle aberrantly, before they die by apoptosis, supporting the

idea of a link between cell-cycle re-entry and oxidative stress.

How do these results square with AIF's known function as a

pro-apoptotic molecule? The authors propose that AIF normally acts, either

indirectly or directly, as a free-radical scavenger in the mitochondrial

membrane - it prevents oxidative stress by mopping up H2O2 in particular. Under

conditions that induce apoptosis, however, AIF translocates to the cytoplasm and

nucleus, where it promotes chromatin condensation and other features of

apoptosis. As well as shedding light on the functions of AIF, then, this study

has pinpointed the first in vivo model for studying how oxidative stress might

affect cell-cycle re-entry and apoptosis.

Alison

References

a.. Klein, J. A. et al. The harlequin mouse mutation downregulates

apoptosis-inducing factor. Nature 419, 367-374 (2002) | Article | | PubMed |

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