About bacterial movement on Bacterialworld

Learning with Agrobacterium tumefaciens: Understanding plants better

The bacterial world is teeming with superheroes that hold the key to unravelling nature’s mysteries. Some bacteria have build remarkable partnerships with plants which not only help us better understand plants but also revolutionize agriculture and biotechnology. Here, we delve into the fascinating relationship between the bacterium Agrobacterium tumefaciens and plants and see how it allowed us to uncover the green world of plants.

Even at the dark and cold bottom of the sea, microbes flourish

Microbes are everywhere. And some have superpowers that allow them to grow in extremely challenging and harsh environments. Especially at the dark and cold bottom of the sea, extremophiles flourish since they interact with other microbes and eat pollutants and contaminants. Interestingly, their microbial activities can also impact our global climate.

How bacteria gain energy from cellular respiration to fuel life

To gain energy, all organisms – including bacteria – need to break molecules apart to get their electrons. In bacteria, this process is called bacterial respiration. Here, we will look at where this energy is stored, what bacteria do with both the electrons and energy and how we use bacterial respiration for our own advantages.

Bacterial killer weapons as biocontrol to protect plants

To feed the growing population on our planet, we need to improve our agriculture for plants to stay healthy and produce crops efficiently. One way to protect plants from diseases is to use biocontrol bacteria that actively kill intruding pathogens. Hence, by increasing our food supply, bacteria can help us save this planet.

Bacteria use antibiotics to kill their foes and protect others

We use antibiotics to kill bacteria and fungi. Yet, antibiotics are produced by these microbes to ensure their own survival in the environment. But not only microbes that produce antibiotics benefit from them, but often even other organisms. Read on to find out how antibiotics can help many players.

Floating veils for large bacteria to attach to and fetch nutrients

Thiovulum majus is a large bacterium that needs a lot of nutrients and energy. To find the perfect location in shallow water, it builds white net-like veils. By attaching to these veils and fast rotation, the bacteria bring in freshwater with lots of new nutrients to keep the community alive.

Comic of the different shapes of bacteria

Looking fabulous: Why bacteria need to stay in shape too

For a long time, bacteria were classified according to their shapes. With new technologies, we learned that the bacterial shapes help them survive in their environments and face harsh conditions. Spheres, rods, stars and screws: Learn about the different bacterial shapes.

How plant-pathogenic bacteria understand plant language and make them sick

Bacteria learned to live on all sorts of surfaces and in different environments. This also includes plants. Unfortunately, some bacteria can also make plants sick. These have special mechanisms with which they speak the language of plants with the goal to enter them.

Neisseria gonorrhoeae uses their bacterial pili to attach to human gut cells.

About twitching bacteria and their pili

Some bacteria have special hair-like structures to connect to surfaces or other organisms. These bacterial pili help them move along that surface or pull themselves closer to a prey or host. Read about why bacteria need those pili when they are out hunting or infecting us.

Bacteria use capsules as micro-invisibility cloaks

When bacteria enter the human body, they are welcomed by our immune system that is ready to fight them off. However, some bacteria can put on invisibility cloaks that help them hide from the immune system. Thanks to this sugar coat – the so-called bacterial capsule – bacteria can sneak into our bodies, infect us and make us sick.

Bacterial glue to grow and survive

To grow biofilms in water, bacteria need to properly glue themselves to a given surface. The bacterium Caulobacter crescentus produces a bacterial glue that is super strong so that the bacteria will not get washed away. Thanks to this glue, Caulobacter can settle down on almost any surface to build biofilms in water.

Bacteria wrap themselves in their swimming flagella

Bacteria swim through liquids with their flagella. Some bacteria even have two flagella at opposite ends that help them to swim through mucus and slime. This movement helps bacteria to infect the human body. Now, researchers start to better understand how these flagella work together to move the bacterium forward.

There are many different ways of how bacteria can transport drugs within the human body.

Of microbots and bacterial ghosts – How bacteria could transport drugs within our bodies

To overcome the medical problem of how drugs can reach a specific target within the body, researchers try to use new approaches. These are often based on bacteria or their products. Here, we will explore drug transport mechanisms for which we could use bacteria and their amazing superpowers.

Bacteria can form multicellular organisms. They can form bacterial filaments, multicellular aggregates, hyphae networks or magnetotactic multicellular prokaryotes.

Together we are strong – bacteria form multicellular organisms

When thinking of bacteria, you might have the picture of a single cell in your mind. But interestingly, some bacteria come as multicellular organisms with advanced functions. Here, we will learn what multicellular bacteria are and why bacteria form multicellular organisms. We will then look at some colourful examples of multicellular bacteria.

Magnetotactic bacteria align with the Earth's magnetic field lines

How bacteria read and follow the Earth’s magnetic field

Magnetotactic bacteria have magnetosomes with which they can sense magnetic field lines. This allows magnetotactic bacteria to swim towards North or South to find the perfect location in the deep and dark water.

Springtail are attracted to the geosmin produced by Streptomyces bacteria. They eat the bacteria and transport them to new places.

Bacteria produce geosmin to trick bugs into hitchhiking

Bacteria produce many different molecules with unique tastes and smells. We and animals can react in specific ways to the bacterial molecules, however it is not always clear how these molecules actually help the bacteria. A new study focused on one such molecules and revealed that bacteria produce geosmin to attract small animals to use them to hitchhike.

The incredible superpowers of bacteria: unveiling nature’s tiny heroes

Microbes and bacteria touch every aspect of our lives. They have so many superpowers that impact the environment, food production, bioremediation and even the climate. Here, we will look at 20 of the most fascinating bacterial superpowers and tell you where you might encounter them throughout your day. But don’t forget, there are plenty more.

Bacteria like Desulfovibrio vulgaris produce scissors that cut the bacteria free from their biofilms.

Bacteria breaking free from home

To protect themselves from the environment, bacteria build shielding biofilms houses. But once such a house gets old, bacteria need to break out it. For that, bacteria produce special scissors that can break biofilms and set free the bacteria.

Vibrio bacteria use their T6SS killing machine for movement or DNA uptake.

Should I kill or should I go? Bacteria making decisions

Bacteria have powerful killing machines with which they carve out their own niches. To kill competitors, bacteria from the Vibrio family, have a powerful crossbow and its arrows availble. However, these bacteria can decide whether they risk a kill and take up what’s left of the dead prey or they escape the dangerous situation. Here, we look at how bacteria decide to kill or flee.

Invasive bacteria use attachment tools like pili and adhesins to adhere to cells

How bacteria get (too) attached

Pathogenic bacteria developed different mechanisms to attach to human host cells. However, our immune system learned to fight back, so that a constant battle between bacteria and host is happening in our bodies.

bacterial movement