What’s the difference between bacteria and viruses?
Both bacteria and viruses are invisible to the naked eye and cause your sniff, fever or cough, so how
can we tell the difference?
With bacteria rapidly developing resistance to antibiotics, it is increasingly important that we know
the distinction, because viruses can’t be treated with antibiotics, nor bacteria with antivirals.
Rapid and effective testing is imperative, so we can successfully treat the offending microorganism.
COVID-19 is teaching us the hard way–we have no treatment for a new virus until we have anti-viral
drugs and vaccines specifically targeted against it.
Therapies developed against an existing virus often do not work, or work poorly, against a new virus.
Until this time, our best weapons are handwashing and physical distancing.
On a biological level, the main difference is that bacteria are free-living cells that can live inside or
outside a body, while viruses are a non-living collection of molecules that need a host to survive.
Many bacteria help us: living in our gut digesting and helping absorption of our food, fixing nitrogen
and decomposing organic materials in soil. Similarly, not all viruses are bad—we now know there are
also beneficial viruses present in our gut, skin and blood that can kill undesirable bacteria and more
dangerous viruses.
Bacteria and viruses are all around us
Bacteria and viruses may not be visible with the human eye, but they are all around us in truly
staggering numbers.
In our oceans, there are 10 billion times more bacteria than there are stars in the universe.
The millions of viruses in the world laid end to end would stretch for 100 million light years.
Microorganisms, living harmlessly on, and in our bodies, outnumber human cells by 10 to 1, playing a
vital role in human health.
But not all microorganisms exist in harmony with us. Pathogens are a subset of microorganisms that
can cause disease and these include representatives of bacteria, fungi, viruses, helminths and
protozoa.
1% of the world’s known microbial population is known to be pathogenic to humans— approximately
1400 species.
What are bacteria?
Bacteria are free-living cells that can live inside or outside a body.
Bacteria are prokaryotes—the smallest, simplest and most ancient cells, with free-floating genetic
material. These microscopic single-celled organisms can be rod, spiral or spherical in shape.
There are two types of bacteria: Gram-negative and Gram-positive. The key difference is the presence
of an extra outer membrane in Gram-negative bacteria. It’s essentially an extra line of defence that
makes it harder for antibiotics to penetrate, thus making Gram-negative bacteria more difficult to kill
and more prone to developing resistance.
Bacteria are abundant in soil, inhabiting plant root systems to provide services like nitrogen fixing or
acting as antifungal agents. Thermophilic (heat-loving) bacteria fix sulphur to produce sulphide and
energy for photosynthesis in aquatic sediments or organically rich waters.
Dangerous bacteria live in soil, a good reason to wear gardening gloves.
Dangerous bacteria also live in soil, a good reason to wear gardening gloves. The floods in northern
Queensland in 2019 brought Burkholderia pseudomallei to the surface, bacteria which cause a serious
infection known as melioidosis.
In our bodies, bacteria inhabit the human digestion system, live on our skin and contribute to energy
metabolism, digestion, brain function and general wellbeing. But if the balance of these bacteria is
tipped by a dose of antibiotics or ill-health, then gut discomfort or skin infections are common.
Infectious diseases caused by bacteria have killed well over half of all humans who have ever lived on
Earth. Historically, bacterial infections have started major pandemics such as the bubonic plague,
which is estimated to have killed 50-60 per cent of the population of Europe during the Black Death in
the 14th Century.
Bacteria reproduce mainly by binary fission
Bacteria reproduce mainly by binary fission–replicating their DNA so they have two copies on
opposite sides of the cell, then growing a new cell wall down the middle to produce two daughter
cells. This doubling time takes between 20 minutes and an hour.
This short generation time allows mutations to emerge and accumulate rapidly and quickly cause
significant changes in bacteria, such as resistance to antibiotics.
Communication is key
Bacteria can communicate with one another by releasing chemical signalling molecules, allowing the
population to act as one multicellular organism.
Depending on the density of molecules and the signal it generates, the bacterial community can
adapt and respond to compete for resources in a process known as quorum sensing.
Communication gives bacteria some of the qualities of higher organisms.
This ability to communicate with one another allows bacteria to coordinate gene expression, and
therefore the behaviour, of the entire community.
This process gives bacteria some of the qualities of higher organisms and is a powerful weapon
against antibiotics. It can trigger some bacteria to shut down and become dormant when exposed to
an antibiotic, and they are able to regenerate when the antibiotic is gone.
What are viruses?
Viruses are an assembly of different types of molecules that consist of genetic material (either a
single- or double-stranded DNA or RNA) with a protein coat and sometimes a layer of fat too (an
envelope).
They can assume different shapes and sizes—spacecraft designs, spirals, cylinders and ball shapes.
Viruses that are enveloped with a layer of fat (such as SARS-CoV-2 which causes COVID-19) can be
more readily killed by simple handwashing, because soap disrupts this fatty layer.
Viruses can’t reproduce on their own (unlike bacteria) so they aren’t considered ‘living’, but they can
survive on surfaces for a varying level of time.
Viruses are a
non-living collection of molecules that need a host to survive.
Viruses need to enter a living cell (such as a human cell) to be able to reproduce, and once inside they
take over all of the cellular machinery and force the cell to make new virus.
Viruses cause diseases including the flu, herpes simplex virus, Ebola, Zika and the formidable
common cold.
Viruses can be quite selective about where they live and reproduce–many viruses don’t even infect
humans. Some viruses only infect bacteria, some only infect plants, and many only infect animals.
However, a virus can evolve to jump into humans. This often happens with influenza: for example bird
flu or swine flu which originated in birds and pigs and managed to infect humans. SARS-CoV-2, the
virus that causes COVID-19, probably jumped into humans from bats.
The life cycle of a virus can be divided into the following stages: entry of the virus into the host cell;
replication of the viral genome; production of new viral proteins; assembly of those viral proteins into
new viruses and then release from the host cell (either by killing the cell or by budding off the host
cell membrane) ready to infect new cells.
Why is it so important to tell the difference?
Molecular tools are improving doctors’ ability to identify viral or bacterial infections more quickly and
efficiently—the hope is that doctors can test patients at the GP’s surgery or in an emergency and find
out straight away if their illness is caused by a virus or bacteria.
The goal is for quick tests to be available in the GP surgery.
It is important to know the difference between a viral and a bacterial infection so doctors can treat
the right illness, and antibiotics aren’t used unnecessarily, contributing to the rise of antibioticresistant superbugs.
It is also why you shouldn’t expect your doctor to prescribe antibiotics if you’re suffering from a viral
infection such as a cold.
Researchers at IMB are working on ways to be able to capture and identify bacteria from infections
within hours—this currently takes days.
Taking advantage of these molecular powerhouses
Researchers are re-engineering the lethal design of bacteria and viruses to find ways to stop their
infectious cycles.
At the moment, vaccines are under development to protect us against COVID-19.
Vaccines show
the immune system important parts of the virus so that the immune system can prepare the tools to
fight the real virus effectively—vaccines trick the immune system into responding like it has
previously seen the virus.
The best studied of these immune ‘tools’ are antibodies, which stop viruses from getting into new
cells. But the immune system also makes killer cells, which stop viral replication by killing any
infected host cells.
Traditionally vaccines are weak or inactivated forms of the virus.
There are many potential vaccine candidates in the pipeline globally, made using a wide range of new
technologies.
These vaccine technologies include the use of subunit vaccines: researchers make viral proteins and
put them into the body, so that the immune system makes antibodies against those viral proteins.
This method is usually safer and quicker than using live or inactivated virus.
Other technologies trick the body to make those viral proteins itself, these include delivery of RNA in
liposomes or DNA plasmids in nanoparticles, as well as modified safe viruses and existing vaccines.
By studying virus life cycles and how viruses are detected by the immune system, we can discover
new ways to target the virus and treat viral disease even without a vaccine.
Bacterial and viral infections are often related
While bacterial and viral infections are different, they are often related.
Severe cases of viral pneumonia often end up with an associated bacterial infection. This is
particularly true with COVID-19, where up to 50% of the severely ill hospitalised patients have
developed a bacterial infection. So, despite COVID-19 being caused by a virus, antibiotics are really
important to treat the associated bacterial infections.
As antibiotic-resistant bacteria are an increasing global problem, researchers at IMB are investigating
the surface activity of bacteria at molecular level and have discovered how they elude the human
immune system . They are also looking at developing new therapies to treat resistant bacteria, and
working to help researchers around the world discover new antibiotics.
We’re now well on the way to developing preventative therapies, biomarkers and vaccines to foil
these elusive microbial assassins from plaguing our world.
W
hat is a virus?
A virus is a non-living thing, a collection of molecules that
need a host to survive. They can destroy cells.
What is Bacteria?
Bacteria is a free-living cell that can live inside or outside of
a body.
Where can viruses and bacteria be found in the world?
Everywhere!
How are Viruses treated?
Vaccines or taking medication non as Antivirals or immune
system/antibodies. Vaccines are preventative and antivirals
are for when you already are sick.
How are Bacteria treated?
Antibiotics.