The first time Vayu Maini Rekdal manipulated
microbes, he made a decent sourdough bread. At the time, young Maini
Rekdal, and most people who head to the kitchen to whip up a salad
dressing, pop popcorn, ferment vegetables, or caramelize onions, did not
consider the crucial chemical reactions behind these concoctions.
Pills illustration (stock image).
Credit: © georgejmclittle / Adobe Stock
Even more crucial are the reactions that happen after the plates are
clean. When a slice of sourdough travels through the digestive system,
the trillions of microbes that live in our gut help the body break down
that bread to absorb the nutrients. Since the human body cannot digest
certain substances -- all-important fiber, for example -- microbes step
up to perform chemistry no human can.
"But this kind of microbial metabolism can also be detrimental," said
Maini Rekdal, a graduate student in the lab of Professor Emily Balskus
and first-author on their new study published in Science.
According to Maini Rekdal, gut microbes can chew up medications, too,
often with hazardous side effects. "Maybe the drug is not going to reach
its target in the body, maybe it's going to be toxic all of a sudden,
maybe it's going to be less helpful," Maini Rekdal said.
In their study, Balskus, Maini Rekdal, and their collaborators at the
University of California San Francisco, describe one of the first
concrete examples of how the microbiome can interfere with a drug's
intended path through the body. Focusing on levodopa (L-dopa), the
primary treatment for Parkinson's disease, they identified which
bacteria are responsible for degrading the drug and how to stop this
microbial interference.
Parkinson's disease attacks nerve cells in the brain that produce
dopamine, without which the body can suffer tremors, muscle rigidity,
and problems with balance and coordination. L-dopa delivers dopamine to
the brain to relieve symptoms. But only about 1 to 5% of the drug
actually reaches the brain.
This number -- and the drug's efficacy -- varies widely from patient
to patient. Since the introduction of L-dopa in the late 1960s,
researchers have known that the body's enzymes (tools that perform
necessary chemistry) can break down L-dopa in the gut, preventing the
drug from reaching the brain. So, the pharmaceutical industry introduced
a new drug, carbidopa, to block unwanted L-dopa metabolism. Taken
together, the treatment seemed to work.
"Even so," Maini Rekdal said, "there's a lot of metabolism that's
unexplained, and it's very variable between people." That variance is a
problem: Not only is the drug less effective for some patients, but when
L-dopa is transformed into dopamine outside the brain, the compound can
cause side effects, including severe gastrointestinal distress and
cardiac arrhythmias. If less of the drug reaches the brain, patients are
often given more to manage their symptoms, potentially exacerbating
these side effects.
Maini Rekdal suspected microbes might be behind the L-dopa
disappearance. Since previous research showed that antibiotics improve a
patient's response to L-dopa, scientists speculated that bacteria might
be to blame. Still, no one identified which bacterial species might be
culpable or how and why they eat the drug.
So, the Balskus team launched an investigation. The unusual chemistry -- L-dopa to dopamine -- was their first clue.
Few bacterial enzymes can perform this conversion. But, a good number
bind to tyrosine -- an amino acid similar to L-dopa. And one, from a
food microbe often found in milk and pickles (Lactobacillus brevis), can
accept both tyrosine and L-dopa.
Using the Human Microbiome Project as a reference, Maini Rekdal and
his team hunted through bacterial DNA to identify which gut microbes had
genes to encode a similar enzyme. Several fit their criteria; but only
one strain, Enterococcus faecalis (E. faecalis), ate all the L-dopa,
every time.
With this discovery, the team provided the first strong evidence
connecting E. faecalis and the bacteria's enzyme (PLP-dependent tyrosine
decarboxylase or TyrDC) to L-dopa metabolism.
And yet, a human enzyme can and does convert L-dopa to dopamine in
the gut, the same reaction carbidopa is designed to stop. Then why, the
team wondered, does the E. faecalis enzyme escape carbidopa's reach?
Even though the human and bacterial enzymes perform the exact same
chemical reaction, the bacterial one looks just a little different.
Maini Rekdal speculated that carbidopa may not be able to penetrate the
microbial cells or the slight structural variance could prevent the drug
from interacting with the bacterial enzyme. If true, other
host-targeted treatments may be just as ineffective as carbidopa against
similar microbial machinations.
But the cause may not matter. Balskus and her team already discovered a molecule capable of inhibiting the bacterial enzyme.
"The molecule turns off this unwanted bacterial metabolism without
killing the bacteria; it's just targeting a non-essential enzyme," Maini
Rekdal said. This and similar compounds could provide a starting place
for the development of new drugs to improve L-dopa therapy for
Parkinson's patients.
The team might have stopped there. But instead, they pushed further
to unravel a second step in the microbial metabolism of L-dopa. After E.
faecalis converts the drug into dopamine, a second organism converts
dopamine into another compound, meta-tyramine.
To find this second organism, Maini Rekdal left behind his mother
dough's microbial masses to experiment with a fecal sample. He subjected
its diverse microbial community to a Darwinian game, feeding dopamine
to hordes of microbes to see which prospered.
Eggerthella lenta won. These bacteria consume dopamine, producing
meta-tyramine as a by-product. This kind of reaction is challenging,
even for chemists. "There's no way to do it on the bench top," Maini
Rekdal said, "and previously no enzymes were known that did this exact
reaction."
The meta-tyramine by-product may contribute to some of the noxious
L-dopa side effects; more research needs to be done. But, apart from the
implications for Parkinson's patients, E. lenta's novel chemistry
raises more questions: Why would bacteria adapt to use dopamine, which
is typically associated with the brain? What else can gut microbes do?
And does this chemistry impact our health?
"All of this suggests that gut microbes may contribute to the
dramatic variability that is observed in side effects and efficacy
between different patients taking L-dopa," Balskus said.
But this microbial interference may not be limited to L-dopa and
Parkinson's disease. Their study could shepherd additional work to
discover exactly who is in our gut, what they can do, and how they can
impact our health, for better or worse.
Journal Reference:
- Vayu Maini Rekdal, Elizabeth N. Bess, Jordan E. Bisanz, Peter J. Turnbaugh, Emily P. Balskus. Discovery and inhibition of an interspecies gut bacterial pathway for Levodopa metabolism. Science, 2019; 364 (6445): eaau6323 DOI: 10.1126/science.aau6323
Courtesy: ScienceDaily
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