Serendipitous discovery could lead to treatment for strokes, cardiac arrest
From: Massachusetts General Hospital
May 28, 2021 -- Lack of oxygen, which is
harmful to the brain, causes hydrogen sulfide 'sewer gas' to accumulate in the
brain. The brains of lab animals repeatedly exposed to hydrogen sulfide became
tolerant to the gas and lack of oxygen. Researchers identified the mechanism
that induces this tolerance, which could lead to new treatments for brain
injuries caused by oxygen deprivation.
In a surprising discovery, researchers
at Massachusetts General Hospital (MGH) identified a mechanism that protects
the brain from the effects of hypoxia, a potentially lethal deprivation of
oxygen. This serendipitous finding, which they report in Nature
Communications, could aid in the development of therapies for strokes, as
well as brain injury that can result from cardiac arrest, among other
conditions.
However, this study began with a very
different objective, explains senior author Fumito Ichinose, MD, PhD, an
attending physician in the Department of Anesthesia, Critical Care and Pain
Medicine at MGH, and principal investigator in the Anesthesia Center for
Critical Care Research. One area of focus for Ichinose and his team is
developing techniques for inducing suspended animation, that is, putting a
human's vital functions on temporary hold, with the ability to
"reawaken" them later. This state of being would be similar to what
bears and other animals experience during hibernation. Ichinose believes that
the ability to safely induce suspended animation could have valuable medical
applications, such as pausing the life processes of a patient with an incurable
disease until an effective therapy is found. It could also allow humans to
travel long distances in space (which has frequently been depicted in science
fiction).
A 2005 study found that inhaling a gas
called hydrogen sulfide caused mice to enter a state of suspended animation.
Hydrogen sulfide, which has the odor of rotten eggs, is sometimes called
"sewer gas." Oxygen deprivation in a mammal's brain leads to
increased production of hydrogen sulfide. As this gas accumulates in the tissue,
hydrogen sulfide can halt energy metabolism in neurons and cause them to die.
Oxygen deprivation is a hallmark of ischemic stroke, the most common type of
stroke, and other injuries to the brain.
In the Nature Communications study,
Ichinose and his team initially set out to learn what happens when mice are
exposed to hydrogen sulfide repeatedly, over an extended period. At first, the
mice entered a suspended-animation-like state -- their body temperatures
dropped and they were immobile. "But, to our surprise, the mice very
quickly became tolerant to the effects of inhaling hydrogen sulfide," says
Ichinose. "By the fifth day, they acted normally and were no longer
affected by hydrogen sulfide."
Interestingly, the mice that became
tolerant to hydrogen sulfide were also able to tolerate severe hypoxia. What
protected these mice from hypoxia? Ichinose's group suspected that enzymes in
the brain that metabolize sulfide might be responsible. They found that levels
of one enzyme, called sulfide:quinone oxidoreductase (SQOR), rose in the brains
of mice when they breathed hydrogen sulfide several days in a row. They
hypothesized that SQOR plays a part in resistance to hypoxia.
There was strong evidence for this
hypothesis in nature. For example, female mammals are known to be more
resistant than males to the effects of hypoxia -- and the former have higher
levels of SQOR. When SQOR levels are artificially reduced in females, they
become more vulnerable to hypoxia. (Estrogen may be responsible for the
observed increase in SQOR, since protection from the adverse effects of hypoxia
is lost when a female mammal's estrogen-producing ovaries are removed.)
Moreover, some hibernating animals, such as the thirteen-lined ground squirrel,
are highly tolerant of hypoxia, which allows them to survive as their bodies'
metabolism slows down during the winter. A typical ground squirrel's brain has
100 times more SQOR than that of a similar-sized rat. However, when Ichinose
and colleagues "turned off" expression of SQOR in the squirrels'
brains, their protection against the effects of hypoxia vanished.
Meanwhile, when Ichinose and colleagues
artificially increased SQOR levels in the brains of mice, "they developed
a robust defense against hypoxia," explains Ichinose. His team increased
the level of SQOR using gene therapy, an approach that is technically complex
and not practical at this point. On the other hand, Ichinose and his colleagues
demonstrated that "scavenging" sulfide, by using an experiment drug
called SS-20, reduced levels of the gas, thereby sparing the brains of mice
when they were deprived of oxygen.
Human brains have very low levels of
SQOR, meaning that even a modest accumulation of hydrogen sulfide can be
harmful, says Ichinose. "We hope that someday we'll have drugs that could
work like SQOR in the body," he says, noting that his lab is studying
SS-20 and several other candidates. Such medications could be used to treat
ischemic strokes, as well as patients who have suffered cardiac arrest, which
can lead to hypoxia. Ichinose's lab is also investigating how hydrogen sulfide
affects other parts of the body. For example, hydrogen sulfide is known to
accumulate in other conditions, such as certain types of Leigh syndrome, a rare
but severe neurological disorder that usually leads to early death. "For
some patients," says Ichinose, "treatment with a sulfide scavenger
might be lifesaving."
The lead author of the study is Eizo
Marutani, MD, an investigator in MGH's Department of Anesthesia Critical Care
and Pain Medicine and an instructor at Harvard Medical School (HMS). Ichinose
is also the William Thomas Green Morton Professor of Anaesthesia at HMS.
https://www.sciencedaily.com/releases/2021/05/210525160848.htm
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