So, they talked of cocci and bacilli based on the spheres and rods that they saw under the microscope.

And they classified microbes and bacteria based on these shapes.

It came only with later, modern technologies that scientists learned that there was more to bacteria than their shapes. Even though bacteria looked similar, they had different superpowers.

Yet, some of these bacterial superpowers are indeed influenced by their cell shapes.

So, what is it about bacterial shapes? Why do bacteria look differently? And how do the different shapes of bacteria help them survive and thrive?

What gives bacteria their shapes?

To protect themselves from the environment, bacteria as well as all other organisms have cell envelopes. These keep the cellular machines and internal parts together so that a bacterium can function within this envelope.

And this envelope also gives bacteria their shape.

Both Gram-positive and Gram-negative bacteria have a layer of so-called peptidoglycan within their envelope. This peptidoglycan layer is made of sugars that are linked together by very strong bonds. This is why the peptidoglycan layer is pretty rigid and stiff and has a specific shape in each bacterium.

Either on the inside or on the outside, the peptidoglycan layer is linked to the cellular membranes. Together, these make up the bacterial envelope with a specific cell shape.

What different shapes do bacteria have?

Microbiologists have different ways to classify known bacterial shapes. Here, I will introduce you to the bacterial shapes according to what makes the most sense to me.

Rod-shaped bacteria

As the name suggests, these bacteria have a rod or cylindrical shape. Examples of rod-shaped bacteria are Escherichia coli and Bacillus subtilis.

Scientists are also convinced that rod-shaped bacteria are the evolutionary ancestors of all other bacterial shapes.

The shape comes from proteins that form long cables within the bacterial cell. These span out the whole bacterium from one end to the other.

Rod-shaped bacteria grow by two modes that we talk about in Why bacteria divide into two and grow with the help of a strong ring: First, they extend their cell size by growing the peptidoglycan, the cable proteins and the membrane.

Second, the cable proteins determine the middle of the cell, where the bacterium produces a special ring. Eventually, this ring narrows so that the bacterium divides and two bacterial cells form.

Spherical bacteria

The spherical bacteria – or so-called cocci – include many pathogenic bacteria like Staphylococcus aureus, Streptococcus pneumoniae and Neisseria gonorrhoeae.

Microbiologists think that spherical bacteria were once rod-shaped as well. However, spherical bacteria do not have these long cable proteins that extend their cell bodies. Thus, they stay spherical and grow by dividing their spherical cells right in the middle.

However, sometimes the two daughter cells do not completely divide and they stay attached to each other. This is why some spherical bacteria live as so-called diplococci.

Curved bacteria

Curved bacteria have the shape of a comma or banana and are sometimes also slightly twisted. Examples of curved or banana-shaped bacteria are Caulobacter crescentus and Vibrio cholerae.

These curved bacteria usually live in watery environments where there are flows. Here, the curved shape helps the bacteria to align with the flow while staying attached to a surface.

In the case of Caulobacter crescentus, one end of the bacterium is glued to a surface with a strong super glue. When this bacterium divides in the middle, one daughter cell remains attached to the surface, while the other one can swim away and find a new location to settle down.

Spiral bacteria

Spiral bacteria are a mix of rods and curves which give them a helical twist. Hence, these bacteria have a corkscrew shape.

Many pathogenic bacteria use their corkscrew shape to swim through gel-like solutions. This includes Helicobacter pylori and Campylobacter jejuni.

Since spiral – or helical – bacteria are also thinner, they can reach locations that are too narrow for other bacteria to reach. They also use their flagella to push themselves forward and “wriggle” through narrow pores.

Star-shaped bacteria

Some bacteria look even fancier than others: They are real stars – yes, bacteria with a star shape.

While we don’t know much yet about star-shaped bacteria, they belong to the so-called Stella species or are Methylomirabilis oxyfera. These usually grow in freshwater, soil and sewage.

The star shape comes from six little arms that extend out of the bacterial cell. These push and grow to the outside giving these bacteria a shiny star shape.

Why do bacteria have different shapes?

Now that we have seen the different shapes of bacteria, you might ask yourself, why do bacteria have these different shapes? How do they help them?

As always in biology, it comes down to how a property helps a bacterium survive in a certain location. Often, the cell shape gives a bacterium advantages over other bacteria and it is easier for them to settle down and face harsh environments.

For example, spherical cells have the lowest surface-to-volume ratio. This means they have a large envelope surface through which they can take up a lot of nutrients. All this while their cell volume is relatively small. So they don’t actually need that many nutrients. This helps cocci to grow in locations where there are little amounts of nutrients.

On the other hand, rod-shaped bacteria often have flagella. And thanks to their shapes, they are efficient swimmers. This allows them to swim to new places in cases of danger or the lack of nutrients.

Bacterial cell shapes help face harsh environments

Also, straight rod cells can pack into biofilms more efficiently and build organised structures. This helps them colonise different locations and resist dangerous environments.

Many rod-shaped bacteria also form longer filamentous organisms. These stronger and larger structures protect bacteria from being eaten by other organisms. Another advantage of these multicellular organisms is that they allow more cells to attach to surfaces and colonise hosts.

Lastly, both curved and helical bacteria use their shapes to get better around their environments. Curved bacteria grow in watery environments but also in our guts. Here, their shapes help them align with the flow of water or our gut content while they stay attached to a surface or the gut wall. This keeps them at their preferred location and protects them from being flushed away.

Spiral bacteria use a fascinating helical movement to screw through gel-like or viscous fluids. This for example helps pathogens swim through the mucus of our stomach and guts and colonise us and make us sick.

Bacteria and their shapes

Here, we looked at the different shapes that bacteria have and how these help them survive. Bacteria always face harsh and new environments and conditions and only survive if they have the right tools or means.

So, by adapting their shapes, bacteria often have advantages over other bacteria. Plus, they look cool and fabulous!

The post Looking fabulous: Why bacteria need to stay in shape too appeared first on Bacterialworld.
Bacterialworld - A blog about bacteria: from scientific studies to vivid stories about the fascinating bacterial world

So, yes, also bacteria are always trying to find their siblings and communicate with them. And once they know they are not alone, they start reacting as a group.

Some bacteria start building biofilms – houses to keep the bacteria inside safe. Others like to talk to each other and produce goodies that everyone can enjoy. And other bacteria even form multicellular organisms with new superpowers.

Yet, some bacterial species like to move only in groups. Researchers call this bacterial movement twitching.

Bacteria can only twitch and move in groups when they have so-called twitching pili. Not all bacteria have these types of pili and – unfortunately for us – many bacterial pathogens produce them. And these bacteria use their pili to infect us and make us sick.

So, let’s have a look at what these bacterial pili are.

What are bacterial pili?

Bacterial pili look like little hair that grow out of bacterial cells.

This hair is anchored to the bacterial cell envelope and can be attached to any site of the bacterial surface. Some bacteria only have on pilus, others have two pili at opposite ends and some bacteria even produce bundles of pili that work together.

The pilus hair is a helix of an endless number of the same protein: the so-called pilin protein. This pilin works like a perfect puzzle piece: Each end of the pilin fits the next pilin piece. Like this, endless pilin puzzle pieces attach to each other in a circular manner and form a stable hair-like helix structure.

But not to lose their precious hair, bacteria need to attach the pilus to their cell envelope. For this, bacteria have a huge anchoring complex on the inside of their cell envelope. And this anchor holds the pilus at the correct location.

To make this pilus dynamic, bacteria link the anchor to a tiny motor. This motor has a ring shape that surrounds the anchor and thus the hair. And bacteria need this motor for the actual moving process.

How do bacteria move with pili?

This circular motor on the inside of the cell envelope has two main functions: to extend and retract the pilus. Endless circles of extending the pilus, attaching to a surface and retracting the pilus allow bacteria to move.

To extend or lengthen the pilus hair, the motor (orange) binds the pilin proteins inside the bacterium (grey circles) and transports them outside of the cell. This costs energy, which is why bacteria need this little motor. Hence, by adding more pilin protein to the pilus from the inside, the pilus hair (grey) extends towards the outside.

On the outside at the end of the pilus hair sits a protein (green) that can stick to surfaces. When this protein attaches to a surface, the motor on the inside of the bacterium changes its direction. Instead of adding pilins to the pilus and lengthening the hair, the motor takes pilins off the pilus and thus shortens the hair.

Now, the bacterium is attached to a surface while the pilus shortens. Like this, the bacterium pulls itself towards that surface.

This means that the attachment to the surface has to be so strong, that it can pull the bacterial cell towards this new location. This works like the bacterial superglue that some bacteria use to grow and survive.

What is the function of bacterial pili?

Bacterial pili can attach to all sorts of surfaces. Mainly, bacteria use this movement in environments of low water or on wet surfaces like human tissue.

For example, a bacterium can connect with its pilus to another bacterial cell. Now, when the bacterium retracts the pilus, it pulls the other bacterium closer. Like this, bacteria can form aggregates which helps them in the first steps of settling down and building biofilm houses.

Also, when several bacteria stick together and form bigger groups, they can move along a surface in a coordinated manner. This helps bacteria conquer new environments quicker and find new resources. For example, the bacterium Pseudomonas aeruginosa can reach out in swarms trying to find more space and new places to live in.

Interestingly, multicellular Myxobacteria move as huge cell aggregates to attack their prey. These bacteria use their twitching pili to glide along a surface, attach to a prey and pull the whole aggregate towards the prey. Like this, the Myxobacteria quickly run over their prey so it does not stand a chance.

However, bacterial pathogens also use pili to infect us. The bacterium Neisseria gonorrhoeae can attach its pilus to human epithelial and endothelial cells. When the bacterium then retracts the pilus, it pulls itself closer to the cell and attaches to it more tightly. Now, it can infect the cell and eventually the host.

But not all is lost with bacteria and their pili. Currently, researchers are trying to better understand how bacteria use their pili and how this machine works mechanistically. They will then try to find drugs that inhibit the pili. This could be an alternative way to inhibit bacterial pathogens and maybe even drug-resistant bacteria.

The post About twitching bacteria and their pili appeared first on Bacterialworld.
Bacterialworld - A blog about bacteria: from scientific studies to vivid stories about the fascinating bacterial world

Vaccines helped eradicate deadly diseases like smallpox.

And for over a century, researchers developed vaccines according to Pasteur’s principle. They isolated the microorganism and inactivated it. Then they injected the now harmless microorganism into people. 

Now these people were vaccinated.

Their immune systems would detect this foreign microorganism and develop antibodies against it. The next time this person gets infected with the real microorganism, the antibodies would be ready to fight the intruder.

New challenges for researchers

But unfortunately, developing vaccines is not always that easy.

Especially, when researchers have trouble growing an organism in the lab. As it is the case with the hepatitis C virus. And then there are nasty pathogens like Neisseria meningitidis. These know too well how to hide from the immune system and cause deadly meningitis. Or to fight a clever virus like HIV, we need help from extra skilled parts of our immune system. Let alone a virus as SARS-CoV-2 that emerged from nowhere and for which we need a vaccine real quick.

To develop vaccines against these microorganisms, researchers needed a new strategy. They try to find new vaccines that activate the immune system and trigger it to produce antibodies. These antibodies have to detect a specific piece of foreign microorganism. Often, this is a protein from the surface of the virus or the bacterium: the so-called antigen. 

But not every antigen is a good antigen that activates the immune system.

Hence, researchers need to produce and test different antigens. And for this, they rely on fancy technologies and super-efficient helpers: bacteria. Here, we will look at how researchers use bacteria in the hunt for vaccines. 

Bacterial pets in the lab

For some researchers, the bacterium Escherichia coli is a dear lab pet. They know exactly how to grow, change, regulate, mutate, shock and kill this bacterium. And they appreciate that their favourite lab bacterium can carry big chunks of DNA and produce almost any protein.

So, to produce and test antigens, researchers need to make DNA with a gene for an antigen.

Bacterial machines to produce DNA

To produce any piece of DNA, researchers use a special DNA production machine from the bacterium Thermus aquaticus. This bacterium lives in hot regions, so its enzymes only work at hot temperatures. 

Hence, researchers can control this DNA production machine by regulating the temperature. And like this, they can produce any gene they need.

Bacterial machines to cut and paste DNA

The problem is that the gene alone is not stable. This is why researchers need to put this gene (in blue in the picture below) into a plasmid. Plasmids are stable DNA circles (in yellow), that bacteria recognise and produce. 

To link these two pieces of DNA together, researchers use special scissors. These scissors cut the gene and the plasmid so that they now work like puzzle pieces. They can only fit together. 

These scissors also come from bacteria and, interestingly, every bacterium has its own type of scissors. This means researchers can produce many different puzzle pieces that always work in pairs.

Next, the plasmid and the gene need to be glued together. And for this, researchers use a glue stick from a virus. And yes, it works like the plaster in the picture.

Finally, we have a big chunk of DNA with a gene for an antigen.

Now, researchers need to produce this antigen.

Guess what, they use bacteria for that too!

Bacteria are protein production machines

First, the plasmid with the gene for the antigen needs to go inside the bacterial cell. For that, researchers electrocute the bacteria together with the plasmid. Yes, electrocute them! Poor bacteria!

But this brings the plasmids into the bacteria.

Next, researchers grow these bacteria with the plasmid. The bacteria now produce a lot of that plasmid and a lot of that antigen (blue).

Next, researchers need to kill the bacteria and clean the antigens from them.

With all the antigens produced now, the fun experiments can get started. 

Finding the best antigen for a vaccine

Generally, researchers produce many different antigens to find the best one as a vaccine. The best antigen is the one that binds to an antibody the tightest.

To test all the antigens, researchers do an experiment that is funnily called ELISA. And they can do this ELISA experiment only thanks to bacteria.

Some bacteria from the Streptomyces family produce the protein streptavidin. This protein binds very, very tightly to the vitamin biotin. Obviously, researchers make use of these two proteins in the lab.

In the simplest version of an ELISA experiment, researchers glue antigens to a surface (yellow, blue and green). Then, they add liquids with different antibodies (grey) to these antigens to test which one binds most tightly. 

These antibodies are linked to a biotin molecule (grey circle). Next, the researchers add streptavidin (green) that is linked to an enzyme. Now, only if the antibody bound the antigen, the streptavidin can bind the biotin. And if that happens, the enzyme can change the colour of the liquid. 

Like this, researchers can test many different antigens and “see” for which the colour changes. These are the ones that bound to an antibody.

Researchers need to repeat all these steps many times; each time changing the antigen a bit to make it more efficient.

But eventually, this antigen becomes a vaccine.

And just as bacteria produced the antigen in the lab, they might have to do that in large amounts to produce the masses of vaccines needed.

About vaccines produced by bacteria

Bacteria can produce different proteins and therefore different vaccines.

For example, the vaccine against the hepatitis E virus is completely made by bacteria. Bacteria produce the envelope proteins of the virus. These then assemble and build the virus structure. This vaccine now has the same structure as the virus, but it is inactive and harmless since no viral DNA is inside the envelope. 

Some vaccines also have components from different organisms. 

Our immune system can very well detect the sugars on the surface of bacteria. Hence, researchers attach some of these sugars to vaccines. Like this, they attract the big players of the immune system to the vaccine. This activates the immune system so that it develops antibodies against the vaccine.

Researchers also linked bacterial proteins to vaccines. Here, researchers found that bacterial toxins or proteins from the bacterial surface attract and activate the immune system. But not to worry, researchers worked out how to inactivate the toxin so that the vaccine is not harmful.

Not all vaccines are produced by bacteria

Lastly, researchers developed new strategies to produce vaccines without bacteria. And they even use this strategy for some vaccine candidates against SARS-CoV-2 that causes the COVID-19 disease.

These vaccines only contain a piece of RNA enveloped in a lipid membrane. And, yes, this concept looks a lot like bacterial outer membrane vesicles that transport DNA or drugs. 

In this case, our body produces the protein – the antigen – from the RNA. This again activates the immune system and triggers it to make antibodies against the antigen.

So while the delivery mode of the vaccine is pretty different, the way to activate the immune system is still the same.

Bacteria are important in the hunt for vaccines

Some microorganisms are real burdens to the world population. Hence, researchers had to come up with new strategies to tackle them. There is no vaccine against the nasty SARS-CoV-2 yet, and maybe the final vaccine will be produced completely independent of bacteria. But still, bacteria are massively helping researchers in the lab. 

They are amazing little machines to produce proteins or transport DNA or drugs. And they evolved helpful enzymes that every lab researcher uses daily. No biology-related research would work without the amazing mechanisms of bacteria.

Ever since the pandemic started, a lot of people ask me whether we can have bacteria kill the nasty SARS-CoV-2. I doubt it will be a direct fight between bacteria and viruses. But I am convinced that in the end bacteria and their superpowers will save this planet.

Researching and writing this post was possible due to the Journalism Research Grant from the Berlin Science Week.

it’s been a great first adventure as a proper science journalist at the #BerlinScienceWeek https://t.co/ZlJFOb9e18

— Sarah Wettstadt (@DrBommel) November 6, 2020

The post Bacteria are key players in vaccine research appeared first on Bacterialworld.
Bacterialworld - A blog about bacteria: from scientific studies to vivid stories about the fascinating bacterial world