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lthough the role of
"good" viruses in human health is still relatively mysterious, we are
slowly unraveling the importance of our viral visitors. In this special
feature, we introduce a neglected section of the microbiome — the virome.
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on PinterestIllustration of bacteriophages infecting a bacterium.
The role of bacteria and
our microbiome in health and disease is at the forefront of medical research.
We are a long way from
answering the many questions posed by recent findings, but it is now firmly
established that without our personal fleet of "friendly"
microorganisms — our microbiome — we would not thrive.
Medical science, however,
does not sit on its haunches; its eyes are always fixed on the horizon,
straining to describe the shape of things hidden in the far distance.
As we struggle to unpick
the almost unbearably complex interactions between bacteria and health, the
next challenge is already waiting in the wings: the role of the virome.
What is the virome?
When we hear the word
"microbiome," we immediately think of bacteria, but technically, the
microbiome is the sum of all microorganisms in a particular environment. Some scientists
use the term to refer to the sum of the genetic material of these
microorganisms.
So, aside from bacteria,
the microbiome also includes viruses (the virome) and fungi (the mycobiome),
among other visitors. To date, scientists have paid comparatively little
attention to the virome or mycobiome.
Viruses
have made themselves at home in a range of ecological niches in the human body,
especially on mucosal surfaces, such as the insides of the nose and mouth and
the lining of the gut.
In this feature, we will
concentrate on the gut virome because it hosts the greatest number of viral
occupants and has been investigated the most.
Of course, viruses are most
famous for causing diseases, such as smallpox, hepatitis, HIV, and rabies. Because of
the urgency associated with viral disease, this aspect has taken up the lion's
share of researchers' time. However, many viruses do not have the slightest
interest in human cells.
Introducing the bacteriophage
Scientists consider the virome to be "the
largest, the most diverse, and the most dynamic part of [the] microbiome,"
and the majority of the viruses in our guts
are bacteriophages. Wherever there are bacteria, there are bacteriophages in
abundance.
As
other researchers explain: "Phages are
the most abundant life forms on Earth, being virtually omnipresent. [...] Some
freshwater sources may contain up to 10 billion per [milliliter]."
Bacteriophages infect
bacteria, commandeer their cell machinery, and use it to replicate their
genetic material.
It is now abundantly clear
that gut bacteria influence health and disease, so it is no surprise that
viruses that infect gut bacteria may have a significant influence, too.
Phage therapy
From the 1920s to the
1950s, scientists investigated whether bacteriophages could be used to treat
bacterial infections. After all, these viruses are adept at destroying human
pathogens.
Scientists found that phage therapy was both effective and, importantly, free from side effects.
Scientists found that phage therapy was both effective and, importantly, free from side effects.
When antibiotics were
discovered, phage therapy faded into the background. Antibiotics could be
manufactured with relative ease, and they killed a broad spectrum of bacterial
species.
However, with today's
hi-tech capabilities and the fearsome backdrop of antibiotic resistance,
interest in phage therapy may enjoy a resurgence.
One factor that makes phage
therapy attractive is its specificity. Often, antibiotics wipe out a wide spectrum of
bacterial species. Now that we know that "good" bacteria live in the
gut, however, it is clear that this is not ideal.
Bacteriophages,
meanwhile, only target a narrow range of strains
within the same bacterial species.
Plus, they only replicate
if their target bacteria are in the local area. Taken together, this means that
they only attack the desired bacterium, and they continue to replicate until
they have wiped out the infection.
Friends for life
Bacteriophages join the
human journey at an early stage. One study examined meconium — a newborn's
first poop — and found no evidence of viruses.
However, just 1 week after
birth, each gram of a baby's poop contained about 100 million virus particles,
most of which were bacteriophages. Our virome truly is a lifelong companion.
Each human has a distinct
selection of bacteriophages, which is collectively referred to as the phageome.
People who have roughly the same diet share more similarities, but overall,
each individual's phageome varies wildly.
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From symbiosis to dysbiosis
Bacteriophages, as
mentioned, destroy bacteria. However, in some situations, bacteriophages can
benefit populations of bacteria.
In the gut, bacteriophages predominantly exist as prophages. In this stage, their genetic code is incorporated into a bacterium's genome, ready to produce bacteriophages if activated.
In the gut, bacteriophages predominantly exist as prophages. In this stage, their genetic code is incorporated into a bacterium's genome, ready to produce bacteriophages if activated.
At this point in their
life, a bacteriophage is not harmful to a bacterium — they exist in symbiosis.
Because bacteria can
exchange genetic material with each other, the genetic code of prophages can
also be transferred between individual
bacteria.
They can exchange "genes associated with
antibiotic resistance, virulence, or metabolic pathways between different
bacterial species." This could benefit some bacterial species, potentially
allowing them to broaden their niche. However, the growth could be at the
expense of other colonies of bacteria in the gut.
"Prophages are symbiotic to their host
bacteria, and these bacteria are symbiotic to our body. Therefore, phages can
indirectly provide benefit to a multicellular organism like [a] human beyond
what is experienced immediately by their host bacterial cells."
Once prophages are
triggered to become active — for instance, in times of stress or
if the host bacterium is in danger — they can cause a widespread change in the
gut's microbial community.
The shift from harmless
prophage to so-called lytic phage can wipe out communities of bacteria,
potentially providing "bad" bacteria with some breathing space and
allowing them to fill the void.
This is called community shuffling and can lead to dysbiosis — a microbial imbalance.
This is called community shuffling and can lead to dysbiosis — a microbial imbalance.
From dysbiosis to diagnosis
Dysbiosis is associated
with a range of conditions, including inflammatory bowel disease, chronic fatigue
syndrome, obesity, Clostridium difficile (C. diff) infection, and colitis.
However, researchers are still unsure of the role of bacteriophages in these
conditions.
In these cases, dysbiosis
might occur via other mechanisms. Alternately, it might be a symptom of the
conditions, rather than the cause.
Researchers have observed
changes in gut bacteria in a surprisingly varied range of diseases,
including type 2 diabetes, schizophrenia, depression, anxiety, Parkinson's disease, and many more.
Because
bacteriophages outnumber the bacteria in our guts and rely on them to
replicate, they must be either affected by or involved in any fluctuations.
Bacteriophages may not be
driving changes in the gut — changes that, it must be added, may not be driving
the disease. Instead, bacteriophage populations might just be altered,
passively, by the changes in gut bacteria.
Whether the ebb and flow of
bacteriophage communities is important in health and disease will be
challenging to investigate. But even if it is not pivotal in the pathology of a
disease, spotting these fluctuations might have other benefits.
As an example, there is the
potential to use the virome as a diagnostic marker. For instance, scientists
have identified disease-specific alterations in the gut virome
in people with inflammatory bowel disease, which is a notoriously difficult
condition to diagnose.
The trouble with viruses
Studying bacteria is far
from easy; after all, they are incredibly small. Bacteria are generally 0.4–10
micrometers across. To provide some context: 10 micrometers is just
one-hundredth of a millimeter or four ten-thousandths of an inch.
Viruses,
however, are even smaller, at just 0.02–0.4 micrometers across.
Aside from the difficulties
inherent in working on such a tiny scale, viruses pose other challenges.
If scientists want to
understand which bacterial species are present in any given population, they
extract genetic information.
From this, they isolate
specific stretches of code and match them to existing databases; most commonly,
they use the 16S rRNA gene. This particular gene can be found in almost all bacterial species, and over evolutionary time,
it has remained relatively unchanged.
However, some regions of
16S RNA are considered hypervariable. Differences between these regions allow
researchers to identify species.
Viruses, on the other hand,
do not share any equivalent genes among species. This, until relatively
recently, made studying the virome almost impossible, but advances in next-generation sequencing are slowly knocking down
barriers.
At this stage, the role of
viruses in human health is nowhere near as clear as their role in disease.
With that said, it also
seems highly likely that viruses do play a substantial part in maintaining a
healthy body. Only with advances in research techniques will their full impact
be understood.
Given the immediate
concerns of antibiotic resistance, perhaps renewed interest in the
bacteriophage will see more time dedicated to this mysterious element of
medical science.
Still, understanding the
interplay between the components of our microbiome will be hard-won
information; as one paper explains:
"The composition of the gut microbiome
is not the same during the several stages of life, or even during the hours of
the same day."
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