Keshav Singh, Ph.D., and colleagues have done just that, in a mouse
model developed at the University of Alabama at Birmingham. When a
mutation leading to mitochondrial dysfunction is induced, the mouse
develops wrinkled skin and extensive, visible hair loss in a matter of
weeks. When the mitochondrial function is restored by turning off the
gene responsible for mitochondrial dysfunction, the mouse returns to
smooth skin and thick fur, indistinguishable from a healthy mouse of the
same age.
The mouse in the center photo shows
aging-associated skin wrinkles and hair loss after two months of
mitochondrial DNA depletion. That same mouse, right, shows reversal of
wrinkles and hair loss one month later, after mitochondrial DNA
replication was resumed. The mouse on the left is a normal control, for
comparison.
Credit: UAB
"To our knowledge, this observation is unprecedented," said Singh, a professor of genetics in the UAB School of Medicine.
Importantly, the mutation that does this is in a nuclear gene
affecting mitochondrial function, the tiny organelles known as the
powerhouses of the cells. Numerous mitochondria in cells produce 90
percent of the chemical energy cells need to survive.
In humans, a decline in mitochondrial function is seen during aging,
and mitochondrial dysfunction can drive age-related diseases. A
depletion of the DNA in mitochondria is also implicated in human
mitochondrial diseases, cardiovascular disease, diabetes, age-associated
neurological disorders and cancer.
"This mouse model," Singh said, "should provide an unprecedented
opportunity for the development of preventive and therapeutic drug
development strategies to augment the mitochondrial functions for the
treatment of aging-associated skin and hair pathology and other human
diseases in which mitochondrial dysfunction plays a significant role."
The mutation in the mouse model is induced when the antibiotic
doxycycline is added to the food or drinking water. This causes
depletion of mitochondrial DNA because the enzyme to replicate the DNA
becomes inactive.
In four weeks, the mice showed gray hair, reduced hair density, hair
loss, slowed movements and lethargy, changes that are reminiscent of
natural aging. Wrinkled skin was seen four to eight weeks after
induction of the mutation, and females had more severe skin wrinkles
than males.
Dramatically, this hair loss and wrinkled skin could be reversed by
turning off the mutation. The photos below show the hair loss and
wrinkled skin after two months of doxycycline induction, and the same
mouse a month later after doxycycline was stopped, allowing restoration
of the depleted mitochondrial DNA.
Little change was seen in other organs when the mutation was induced,
suggesting an important role for mitochondria in skin compared to other
tissues.
The wrinkled skin showed changes similar to those seen in both
intrinsic and extrinsic aging -- intrinsic aging is the natural process
of aging, and extrinsic aging is the effect of external factors that
influence aging, such as skin wrinkles that develop from excess sun or
long-term smoking.
Among the details, the skin of induced-mutation mice showed increased
numbers of skin cells, abnormal thickening of the outer layer,
dysfunctional hair follicles and increased inflammation that appeared to
contribute to skin pathology. These are similar to extrinsic aging of
the skin in humans. The mice with depleted mitochondrial DNA also showed
changed expression of four aging-associated markers in cells, similar
to intrinsic aging.
The skin also showed disruption in the balance between matrix
metalloproteinase enzymes and their tissue-specific inhibitor -- a
balance of these two is necessary to maintain the collagen fibers in the
skin that prevent wrinkling.
The mitochondria of induced-mutation mice had reduced mitochondrial
DNA content, altered mitochondrial gene expression, and instability of
the large complexes in mitochondria that are involved in oxidative
phosphorylation.
Reversal of the mutation restored mitochondrial function, as well as
the skin and hair pathology. This showed that mitochondria are
reversible regulators of skin aging and loss of hair, an observation
that Singh calls "surprising."
"It suggests that epigenetic mechanisms underlying
mitochondria-to-nucleus cross-talk must play an important role in the
restoration of normal skin and hair phenotype," Singh said, who has a
secondary UAB appointment as professor of pathology. "Further
experiments are required to determine whether phenotypic changes in
other organs can also be reversed to wildtype level by restoration of
mitrochondrial DNA."
Journal Reference:
- Bhupendra Singh, Trenton R. Schoeb, Prachi Bajpai, Andrzej Slominski, Keshav K. Singh. Reversing wrinkled skin and hair loss in mice by restoring mitochondrial function. Cell Death & Disease, 2018; 9 (7) DOI: 10.1038/s41419-018-0765-9
Courtesy: ScienceDaily
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