And only thanks to pigments, life on Earth is possible. Pigments were the first molecules that microbes used to harvest sunlight. Microbes could then transform the light energy into chemical energy and produce oxygen.

Even the brown-reddish haemoglobin in your blood is an essential pigment as it transports oxygen within your body. Also for bacteria, pigments and their colours have life-saving functions. Here, we will look at how biopigments colour the bacterial world and what bacteria gain from producing them.

Bacterial pigments bring colour to the world of bacteria

Biopigments are molecules with complex chemical structures and at least one excited electron. Depending on the electron’s arrangement, a pigment absorbs light at a specific wavelength. It reflects the colour of the unabsorbed wavelength, which gives the pigment its colour.

As the function of pigments depends on the incoming light, sunlight plays a crucial role for bacteria with pigments. By adding certain pigments to their membrane, bacteria can adapt to environments that are directly affected by sunlight or the lack of it. This gives them an advantage over those bacteria that lack these pigments.

However, some bacteria also use pigments for other purposes, which we discuss further in this article.

Microbes harness photosynthetic power with colourful pigments

Sunlight is incredibly powerful since each light photon contains energy. Bacteria adapted to harvest energy from sunlight with special pigments.

Pigments can capture the incoming photon and transfer its energy to other molecules. This process transforms the incoming light energy into chemical energy. So-called phototrophic microbes are those that gain their energy from light.

The best-known example of a photosynthetic biopigment is chlorophyll in plants, algae and cyanobacteria. Cyanobacteria produce several complexes of bacteriochlorophylls to absorb blue and red light. As the green light is not absorbed, it is reflected, which is why chlorophyll – and thus cyanobacteria, algae and plants – are green.

Some bacteria harvest more light by producing several pigments of different types. They then arrange them in an optimal formation according to the incoming light.

For example, carotenoids capture energy in the green-blueish range and pass it on to the associated chlorophyll. Together, these photosynthetic complexes absorb light energy from almost the entire wavelength spectrum.

Halophilic bacteria and archaea are microbes that produce carotenoids to capture sunlight. You may have seen salt ponds with a reddish colour. This comes from the red and pink-coloured archaea Halobacteria, bacteria Salinibacter or algae Dunaliella. Thanks to their colourful carotenoids, these microbes adapt to salty waters that are exposed to direct sunlight.

Cyanobacteria in the deep sea, lagoons, lakes, ponds or rivers produce similar molecules to chlorophyll. These absorb the blue-green light in water, which allows these bacteria to survive in these dark environments. If you have ever seen a lagoon shining yellow or orange, this was probably due to the colourful cyanobacteria inside.

Bacterial biopigments protect from too much light

As light is full of energy, bacteria also need to protect themselves from getting burned. For this, they produce pigments that take up the excess light energy. Like this, the main photosynthetic complex does not get damaged.

Carotenoids and xanthomonadins are the colourful sun blockers of the microbial world. These molecules absorb high-energy light to protect chlorophyll from damage. Over 600 different carotenoids were described and they usually come in yellow-orange-reddish colours.

The yellow xanthomonadins absorb wavelengths within the energy-rich UV spectrum. Bacteria like Xanthomonas campestris live on plant leaves where they are exposed to direct sunlight. Hence, their yellow xanthomonadin coats are like self-made sunblocks protecting the bacteria.

Also, the pigment melanin shields the producing cell from energy-rich sunlight. Many bacteria living in the soil or bacterial spores produce these pigments. Here, melanin absorbs light from a wide range of the light spectrum to protect the inner of the cell. Hence, melanin-producing bacteria, like Vibrio cholerae and Streptomyces bacteria, are brown or black.

Bacterial pigments let electrons flow and save energy

Since bacterial pigments allow electrons to flow, they can also be energy conductors. Hence, some pigments are important components of energy complexes and synthesis machineries.

For example, yellow flavins are pigments involved in cellular metabolism. The main flavin is riboflavin, which you may know as vitamin B12. This essential molecule – produced only by bacteria – allows our bodies to work.

Phenazines are unique bacterial pigments with yellowish-green fluorescent colours. Pyocyanin, exclusively produced by Pseudomonas bacteria, shuttles electrons – and thus energy – during the respiration process. Hence, pyocyanin is essential for Pseudomonas as it keeps the bacteria healthy and alive.

Some biopigments have anti-oxidant effects

Bacterial pigments don’t just help adapt to external environmental conditions like the sunlight. They also guard the inner bacterial cell from stressful situations.

Excess or uncaptured energy or escaped light photons can react with oxygen. This process produces so-called oxygen radicals, which can damage molecules inside the bacterium. Known as oxidative stress, oxygen radicals can even become life-threatening for bacteria.

Carotenoids and xanthomonadins protect bacterial cells from oxidative stress. These pigments transform the free oxygen radicals into harmless molecules. Since carotenoids and their product vitamin A have similar functions in humans, it is only healthy for us to take up a lot of these with our diet.

In the bacterium Gemmatimonas aurantiaca, orange carotenoids also work like sunscreen and oxidative shield. These pigments both give the bacterium its bright orange colour and protect it from too much sunlight.

Bacteria combat microbial enemies with coloured pigments

As night falls, many bacterial pigments reveal their darker sides. They become important weapons for microbial warfare. Without sunlight, several pigments take on roles as virulence factors and antimicrobials as they mess up cells’ energy and oxygen household.

For example, prodigiosin is the red weapon of Serratia marcescens. As prodigiosin inhibits the growth of several bacterial, fungal and insecticidal pathogens, Serratia marcescens is an important biocontrol bacterium of plant disease.

You may have seen prodigiosin-producing Serratia bacteria on contaminated food. They develop these red, blood-like dots.

Violacein is a purple pigment with anti-viral, anti-bacterial and anti-cancer properties. For example, Chromobacterium violaceum sends membrane bubbles filled with violacein to kill bacterial enemies.

Similarly, Janthinobacterium lividum protects frogs and salamanders as it lives on their skins. Here, the bacterium throws violacein at pathogenic fungi that would otherwise infect and harm the animals.

Pyocyanin, the fluorescent electron-shuttling pigment in Pseudomonas, is also very sensitive to oxygen. It even turns Pseudomonas aeruginosa cultures in the lab blueish just by shaking and airing them.

Yet, not all bacteria have an appropriate coping mechanism for pyocyanin. Hence, these bacteria suffer oxidative stress when they come into contact with this pigment. This is why Pseudomonas uses pyocyanin also to fight bacterial and fungal enemies.

Vivid pigments colour the bacterial world

The Bacterial World is colourful – one of this blog’s taglines. You may have asked yourself what this is about and why bacteria have so many different colours.

From the dazzling pink of halophilic microorganisms to the sunny yellow of phytopathogens, bacterial pigments give their producers shiny and vibrant colours. But thanks to the colourful biopigments, bacteria also gain abilities to survive in new and challenging environments.

Some of these bacterial pigments are essential for us humans and even life on Earth. From some of these colourful biopigments, we produce vitamins that we need for our own metabolism. Also, every oxygen molecule that you just took up with your last breath, at some point, was transformed by a bacterial chlorophyll pigment.

So, I guess it is yet again time to be grateful to bacteria and their vibrant and life-enabling activities!

The post Creating the colours of the rainbow: Bacteria and the vibrant world of pigments appeared first on Bacterialworld.
Bacterialworld - A blog about bacteria: from scientific studies to vivid stories about the fascinating bacterial world

Even though about 70% of the Earth’s surface is covered by water, a majority of that water we cannot drink.

The water that is available to drink can also be contaminated with toxic chemicals or certain microorganisms that would sicken us.

But not all microbes are bad. In fact, many microbes are helping us save our planet. One way of doing this is by cleaning up our drinking water.

We don’t have enough clean freshwater

Everyone needs water to drink.

Humans can only drink freshwater, which makes up less than 3% of the world’s water supply. Freshwater is found in lakes, rivers, and streams. It is also locked away in the icecaps as glaciers, up in the atmosphere as water vapor, and deep in the soil as groundwater.

Of the small amount of freshwater easily accessible to us, we have used or contaminated much of that freshwater. Agricultural practices have diverted many sources of freshwater for animals and crops. Climate change and warmer temperatures cause farmers to use more freshwater resources as well. And global industrial practices can lead to toxic chemicals entering the environment and water.

This means that now we have less freshwater available to drink than ever.

We have learned ways to clean our drinking water, but this requires a lot of chemicals, energy, and money. Good thing microbes can help us decontaminate our drinking water in faster, easier, and cheaper ways.

Microbes clean water by filtering out bad bacteria

Drinking certain types of bacteria can make us sick. You have probably heard of outbreaks of E. coli or Salmonella leading to people being ill.

These microbes normally live in animals’ digestive tracks and are excreted in their wastes. They can enter the water system from runoff from farms, and ingesting them can make us really unwell. Luckily, microbes can help remove pathogenic bacteria from our water.

A simple method of water filtration includes having water flow over a bed of microbes and sand to remove any contaminates, called ‘slow sand filtration.’ At the top of the sand is a gelatinous layer of microbes, known as a biofilm. In such a biofilm live various bacteria, fungi, protozoa, archaea, and other aquatic microorganisms.

This layer is the so-called Schmutzdecke, which is German for “dirty layer.” As water flows over this biofilm, microbes in the Schmutzdecke trap and consume particles and pathogenic microbes. Every Schmutzdecke layer has a unique community of microbes based on the contaminants in the water. In this way, beneficial microbes remove harmful ones and decontaminate our drinking water.

Slow sand filters can purify away 90-99% of contaminating bacteria! The Schmutzdecke removes most of the fecal contaminating bacteria like E. coli. This system does not involve the use of chemical disinfectants, which can select possibly pathogenic bacteria that become resistant to decontamination efforts.

Also, the Schmutzdecke feeds on the microbes and organic matter found in the contaminated water. Hence, slow sand filters are a cheap and low-maintenance way to filter water in resource-limited areas throughout the world.

Microbes clean our drinking water by preventing bacterial build-up

The Schmutzdecke is an example of a community of microbes filtering water to remove pathogenic microbes and make the water safe to drink. But decontaminating water does not always need a whole community of microbes. Sometimes just one part of a microbe is enough to clean the water. In fact, researchers have found a protein from bacteria that can help stop bacterial contamination.

Pathogenic bacteria like Pseudomonas aeruginosa can contaminate water lines that carry water to homes and businesses. To let other P. aeruginosa know they have found a place to stay, bacterial cells send messages to each other in the form of chemical molecules. This communication system, called quorum sensing, allows bacteria to ‘sense’ the number of other bacteria, (a ‘quorum’) around them.

If enough P. aeruginosa cells grow in the same area and send the same message, they will start to form a biofilm. Just like the Schmutzdecke, biofilms act as a gelatinous layer and are difficult to break up. That’s where that special bacterial protein comes in to help stop biofilm formation.

This protein is called AiiA_DH82 and comes from the deep-sea bacterium Bacillus velezensis (DH82 strain). AiiADH82 binds and degrades the chemical messages that bacteria use to communicate with each other.

Without those chemical signals, bacteria do not know they should start forming a biofilm. Adding AiiA_DH82 to P. aeruginosa cultures decreased bacterial growth and significantly inhibited biofilm formation in P. aeruginosa-contaminated water. Scientists hope one day to apply the AiiA_DH82 protein to water lines and drinking fountains. In these, bacteria could group to reduce bacterial contamination and keep our drinking water safe.

Microbes clean our drinking water

People everywhere need clean water for cooking, cleaning, and drinking. However, clean drinking water is a limited resource. Toxic chemicals or pathogenic microbes can pollute our water. Current methods to purify water cost a lot of energy and money.

We are fortunate that microbes are here to help us clean up our water and our environment. As the global population increases, using microbes to clean drinking water is a cheaper, sustainable and more environmentally friendly way to produce the needed levels of clean water. A great example of how microbes are making our world better.

Along with microbes, we can save the planet!

Take away messages from this week’s article:

• Clean drinking water is a limited and necessary resource for everyone on the planet
• Microbes can clean polluted drinking water by reducing the growth of pathogenic bacteria
• Microbial decontamination of drinking water is a sustainable and inexpensive way to provide clean drinking water to our increasing global population

The post How Microbes Clean our Drinking Water appeared first on Bacterialworld.
Bacterialworld - A blog about bacteria: from scientific studies to vivid stories about the fascinating bacterial world

And with an increasing global population, it will be important to find ways to increase the world’s food supply in sustainable ways.

Adding microbial communities, called biofertilizers, to soil can increase crop yield and plant health all without adding any toxic chemicals.

Lucky for us that microbes once again can help save our planet by addressing our global food crisis.

A global challenge

While the global population grows to almost 8 billion people, the land for agriculture remains limited. One way to meet this growing challenge is to increase the quantity of food produced on the same amount of land.

In the past, farmers added expensive chemical fertilizers to their crops. These meant to increase important soil nutrients – specifically nitrogen and phosphorus – and help the plants produce more food.

Unfortunately, these chemicals enter and pollute nearby water systems, harming our health as well as the health of our planet. Plus, producing these chemical fertilizers releases greenhouse gases that add to climate change.

One sustainable method to increase crop production is to add microbial communities to agricultural plants; so-called microbial biofertilizers.

Microbes as biofertilizers

These biofertilizers are soil microorganisms that provide nutrients, stimulate growth, and improve plant health. Also, biofertilizers are more sustainable, less toxic, and cheaper than traditional fertilizers.

Here, we will look at what biofertilizers actually do and how these microbes work for the plants.

Helping plants get nutrients

All living organisms need nitrogen, but not all nitrogen found in the soil is in a useable form. In fact, nitrogen is a major limiting nutrient for plants because most nitrogen in the soil is in a form that plants cannot use.

Hence, microorganisms first need to “fix” the nitrogen and then convert it into a usable form. For this, bacteria make an enzyme called nitrogenase that converts nitrogen from atmospheric nitrogen (N₂) to ammonia (NH₃). Now, plants can absorb this nitrogen form and use it for energy and growth.

Some plants have evolved to work with bacteria to make it easier for them to absorb the fixed nitrogen. For example, the roots of certain legume plants include special root nodules. In these live nitrogen-fixing bacteria called Rhizobia. When chickpea seeds were grown together with these bacteria, their yield increased 250%. Also, adding Bradyrhizobium species to mung bean plants promoted plant growth and yield and plants had a higher tolerance to insecticides.

Cyanobacteria also help plants fix nitrogen. When wheat plants grew together with cyanobacteria species Calothrix ghosei, Hapalosiphon intricatus, and Nostoc species, they grew higher and had more grain. Additionally, co-cultivation with Nostoc or Anabaena species resulted in increased root length and wheat plant nitrogen levels. Cyanobacteria are important nitrogen-fixing bacteria in aquatic environments too, especially for rice production.

Helping plants grow

Besides nitrogen, soil bacteria can provide plants with many nutrients, vitamins, and plant hormones. These are called phytohormones. Phytohormones promote plant growth by acting as signaling molecules to regulate plant metabolism and stress response.

When Rhizobia bacteria grew together with the mustard plant Brassica juncea and produced phytohormones, the plants grew better. Also, in corn (maize), inoculation with Azospirillum brasilense resulted in increased plant growth correlated with elevated phytohormone levels.

Over 80% of Rhizobia bacteria produce the major phytohormone indole-3-acetic acid (IAA). This phytohormone regulates plant growth, cell differentiation, and stress response. Thus, when bacteria secrete indole-3-acetic acid, it promotes root growth. This helps plants take up nutrients better.

In addition to a single bacterial species, communities of microbes help plants stay healthy and grow. Archaea, bacteria and fungi all associate with the roots of plants and synergistically provide nutrients to the plant. Researchers are studying these communities to understand important microbial interactions. The aim is to design microbial communities specific to each crop that promote higher crop production in the future. Just think, one day you could order a biofertilizer optimized for your unique climate, soil, and plant!

Fighting plant enemies

Not only do microbes provide their hosts with nutrients to promote growth, they also protect their hosts from deadly pathogens. Especially fungal pathogens are known enemies that threaten plants.

For example, Pseudomonas and Bacillus strains release toxic chemicals such as hydrogen cyanide to inhibit fungi that infect coffee plants. Other Bacillus strains produce antifungal molecules and simultaneously increase corn (maize) seedling growth. The bacterium Ochrobactrum anthropi TRS‐2 can fight fungi, and application of this bacterium on tea plants decreased brown root rot caused by the fungi Phellinus noxius.

Some bacteria even produce biofilms on the roots of plants as a barrier against invading fungal pathogens!

Agricultural crops are also prone to infection by nematodes, commonly called roundworms. Nematophagous bacteria can deter nematode growth by sending out toxins, and competing for nutrients. For example, Pasteuria penetransbacteria infects nematodes, while Pseudomonas strains can produce antibiotics against nematodes that infect potato plants. No matter the pathogen, soil bacteria have evolved ways to promote and protect their host plant.

Microbial biofertilizers assist our global challenge

As the world’s population increases, we will need sustainable and inexpensive ways to increase agricultural production. Just as microbes add nutrients and flavors to our meals, bacteria can nourish our crops as well. Plus, biofertilizers are a greener, healthier, and less expensive alternative to traditional chemical fertilizers.

So, next time you go out into your garden, think about adding some biofertilizers like compost or manure instead of chemicals to help your fruits and vegetables grow.

Along with bacteria, we can help save the planet!

Take away messages from this week’s article:

• The increasing human population is creating a global food crisis 
• Microbes can act as biofertilizers by providing important nutrients and helping promote plant growth
• Microbial biofertilizers are a sustainable and inexpensive way to increase global food production

The post Microbes as biofertilizers appeared first on Bacterialworld.
Bacterialworld - A blog about bacteria: from scientific studies to vivid stories about the fascinating bacterial world

Many organisms learned to produce bioethanol: plants, fungi and yes, also bacteria. And they can use many different substrates to do so: plants and wood or food waste. You probably know the alcoholic smell of over-ripe fruits or juices.

So, why not use this bacterial superpower to help us with our energy crisis? Let’s look at another possibility of how bacteria could save the health of our planet by producing alternative energy sources.

Where does bioethanol come from?

Microbes can produce ethanol in a process called microbial fermentation. This means that they break down sugars to produce ethanol and energy for the cell.

This process also takes place when producing wine and beer or rising bread dough.

But to produce biofuels, it gets a bit messier because the substrates often come from food or plant waste. And often, uncharacterised microbial communities cover them.

In these cases, the microbial communities work together to make use of all the components of the waste.

For example, the walls of plant cells contain very rigid and long sugar molecules – so-called polymers. Certain bacteria can break down these long polymers into single sugar molecules.

Then, other organisms – often yeast strains – produce ethanol from the sugar molecules in the fermentation process. And when producing beer or wine or rising bread, it is usually our good old friend the baker’s yeast that produces the ethanol for us.

But when it comes to producing bioethanol, we need a lot of it and we need it fast. How lucky are we that one bacterium produces bioethanol a lot more efficiently than yeast strains?

Meet Zymomonas mobilis – the fastest bacterial bioethanol producer.

Why does Zymomonas mobilis not get drunk?

From every single sugar molecule, Zymomonas mobilis produces two ethanol molecules. As you can imagine, Zymomonas mobilis produces a lot of ethanol during its lifetime. So much, it would get you and me super drunk and would damage our bodies irreversibly. But ethanol is not just toxic for us – it also is for bacteria.

Ethanol is a so-called chaotropic compound. This means it disturbs the organisation of biological macromolecules. Hence, proteins and DNA can get disrupted and lose their function. Like this, the bacterial outer envelope gets completely disorganised and bacterial cells lose their stability.

Because of that, most bacteria cannot stand the tiniest bit of ethanol as they get drunk and become intoxicated.

But not Zymomonas mobilis.

This bacterium can live on ethanol without losing it. It knows very well how to protect itself from the toxic effects of ethanol.

Zymomonas mobilis carries a special sugar in its outer envelope. Because of these sugar molecules, a water layer surrounds the membrane. And this water layer blocks the ethanol from coming into contact with the membrane. Hence, the sugar-water shield protects the membrane and the bacterium.

Also, Zymomonas mobilis produces a biofilm that blocks ethanol from entering the bacterial community. And researchers also found that when Zymomonas mobilis lives in biofilms, it produces even more ethanol.

This sounds like something to create communities of Zymomonas mobilis biofilms that efficiently produce ethanol on an industrial scale.

Zymomonas mobilis as an efficient biofuel-producer

Researchers are already on it to use this superhero bacterium to tackle our energy crisis. They are looking into feeding Zymomonas mobilis different substrates from food leftovers or plant waste.

Unfortunately, our superhero bacterium cannot break down the long sugar polymers from plant cells. This means that for industrial processes, the food or plant waste needs to be pre-treated to break down the polymers. But this step also increases costs and processing time.

An alternative is to use other bacteria or microbes that can break down the polymers into single sugar molecules.

Zymomonas mobilis then uses its very efficient sugar transporters to import the sugar molecules into the bacterium. Now, the bacterium can ferment the sugars and produce bioethanol.

Can you see how this is yet another example of how microbes feed each other?

So far, this process is not optimised for huge-scale industrial applications. But it seems clear that it might be bacteria that help us with yet another crisis.

The post Bacteria to produce alternative and green energy sources appeared first on Bacterialworld.
Bacterialworld - A blog about bacteria: from scientific studies to vivid stories about the fascinating bacterial world

Some microbes come to make their hosts sick. Other microbes are there to help and protect them.

This is a story of both types of microbes and an unusual host: amphibians.

Yes, also frogs and salamanders and other amphibians carry microbes on their skins.

And some of these microbes mean to kill the animals. But, luckily, the animals are protected by helpful bacteria that produce colourful antibiotics.

Read on to find out how bacteria and fungi do not get along on the skin of amphibians. We will also explore how bacteria protect amphibians from extinction.

About fungi that infect the skins of their hosts

Many frogs, salamanders and other amphibians have gone extinct because of a deadly fungal infection. And it seems that many more animals are already infected and sick from that same pathogen.

The bad guys? The two fungal species Batrachochytrium dendrobatidis and Batrachochytrium salamandrivorans. They cause a deadly skin disease on frogs and other exotic amphibians.

Similarly, the fungus Trichophyton rubrum can infect our skin and hair. This pathogen causes a disease that you may know as ringworm or athlete’s foot. Typically, you can see such a fungal infection as a red, itchy and circular rash.

But luckily there is a new weapon around to keep these fungal intruders at bay: Bacteria that get rid of the fungus to protect their hosts.

Bacteria produce colourful antibiotics…

Few microbes can grow and thrive on the gloomy skin of frogs or salamanders. One such microbe is the bacterium Janthinobacterium lividum.

This bacterium has an interesting taste for food. It eats the released skin when the amphibians shed their skin. And it also really likes the mucus on the surface of the amphibians.

As a thank you for the good meal, the bacteria help the amphibians in the fight against the deadly fungus.

How?

Generally, bacteria produce antibiotics to get rid of annoying competitors. For example, Janthinobacterium produces the antibiotic violacein, which has a dark violet colour. This antibiotic also kills the fungi that make the frogs sick.

It is still unclear to researchers, how Janthinobacterium transports the antibiotic to the fungus. We already know that the bacterium Chromobacterium violaceum produces membrane bubbles filled with violacein. And that it throws these purple bubbles at its competitors. So, one idea is that Janthinobacterium uses a similar strategy and throws violacein bubbles at the fungus.

Also, when Janthinobacterium grows on the skin of frogs, it triggers the frog to produce more anti-fungal molecules. These molecules kill the fungus and other pathogenic bacteria that are dangerous to the frog.

… and protect them from deadly fungi

Janthinobacterium is not the only bacterium that produces colourful antibiotics to protect its host.

You might have seen red dots in your shower every once in a while. These come from the bacterium Serratia marcescens which makes a red antibiotic. Interestingly, this bacterium can also live on the skins of amphibians. And here, the red antibiotic also protects from deadly fungi.

Other bacteria, like allrounder Pseudomonas, also live on the skins of some amphibians. And these bacteria produce many different antifungals to protect their hosts.

Hence, it looks as if the right skin bacteria protect frogs and salamanders from deadly fungi. And these bacteria keep throwing around colourful bubbles filled with antibiotics – sounds like a bacterial festival to celebrate their hosts?

Colourful bacterial antibiotics to save amphibians?

Now, researchers are trying to save amphibians from the deadly fungus with a process called bioaugmentation. With this strategy, researchers introduce special bacterial communities to the environment. And they hope that the bacteria will jump over to different amphibians.

Bacteria like Janthinobacterium then hopefully establish stable communities on the skins of amphibians and protect them from fungal infections. And let’s hope that these bacterial parties will save more frog species from extinction!

The post Bacteria produce colourful antibiotics to protect frogs appeared first on Bacterialworld.
Bacterialworld - A blog about bacteria: from scientific studies to vivid stories about the fascinating bacterial world

What’s your New Year’s resolution?

Are you trying to eat healthier by eating microbially fermented foods full of nutrients?

Or do you want to be more friendly to the environment by using green bio-plastics?

Keeping this planet green and healthy is a great New Year’s resolution. And one that microbes can help us with.

For example, microbes can degrade and remove the toxic pollution that we have produced. They do that in a process called microbial bioremediation.

Just another way microbes help save the planet.

Our pollution problem

Oil spills, chemical leaks, industrial discharge. We hear about these types of toxic pollution all too often. Increased urbanization, industrialization, and utilization of natural resources pollute and contaminate the environment, which is unhealthy to humans and the planet.

Unfortunately, it is much easier to spill oil or leak a chemical than it is to clean it up. Especially, if the pollution compound is toxic. Cleaning up these types of pollution is costly and may be harmful to the environment.

Why microbial bioremediation?

How lucky are we that microbes can make cleaning up these messes easier? Our microbial friends can degrade and detoxify environmental pollution. This process is called microbial bioremediation.

Microbes absorb or eat toxic pollutants. They then break them down into harmless compounds. This process is a more cost-effective and environmentally friendly method to clean up toxic pollution.

Cleaning up after oil spills

We use petroleum oil in multiple ways, from powering our cars and homes to manufacturing plastics and medicines. Most petroleum oil is found deep in the ground and it takes much energy and expense to pump the oil to the surface.

Unfortunately, sometimes we spill some of that oil. The 2010 Deepwater Horizon oil spill in the Gulf of Mexico is the largest known oil spill and it released 4.9 million barrels of oil into the ocean! What an environmental disaster!

Petroleum oil is a type of fossil fuel full of different organic compounds called hydrocarbons. They contain hydrogen (“hydro”) and carbon molecules. For us humans, ingesting these compounds would be deadly.

So, when that oil disaster happened in 2010, microbiologists and their microbial friends came to the rescue. Luckily, some microbes have special enzymes that recognize and degrade hydrocarbons into smaller compounds. They then use these smaller compounds to grow and reproduce.

Microbes eating hydrocarbons

Many bacteria can degrade petroleum oil. For example, a special Pseudomonas aeruginosa strain can break down oil droplets and grow on petroleum oil with nothing else to eat.

Additional Pseudomonas strains as well as Bacillus subtilis strains are capable of eating hydrocarbons too.

Researchers have also found communities of bacteria working together to degrade and remove petroleum oil. And they are now developing ways to implement these bacterial communities for cleaning up oil spills from contaminated soil and water.

Fungi are also used for bioremediation, called mycoremediation (“myco” refers to fungus). Researchers discovered 16 different fungi species that degrade hydrocarbons in crude oil.

The superhero fungi Trichoderma viridae, Aspergillus flavus and Varicosporium elodeae have the highest rates of degradation. And the Exophiala xenobiotica fungus degrades a hydrocarbon compound found in car gasoline.

Scientists are working to use these microbes in larger bioremediation projects as greener and cheaper ways to clean up oil spills.

Detoxifying heavy metal contamination

Oil spills are not the only toxic pollution generated by us humans. Through many industrial processes, we release heavy metals such as copper, lead, and mercury. Once in the environment, heavy metals can enter the food supply and accumulate in our bodies. Unfortunately, these can lead to health issues and sometimes even cancer.

Removing heavy metals from contaminated water and soils is costly, time-consuming, and ineffective at low concentrations of the contaminate. Good thing microbes can make this process faster and more efficient.

They help remove heavy metals through a process called biosorption. Microbial cell walls are made up of proteins and sugars with a slightly negative charge. Metals have a positive charge.

Thus, microbes can attract and bind these toxic metals. This means microbes act like magnets and pull out the toxic metals from the environment.

Many microbes can absorb a variety of metals. But these microbes also need to protect themselves from toxic metals. For this, they have special enzymes that transform the metals into less toxic forms inside the cell.

However, even microbes cannot survive if the concentration of toxic metals is too high. So, it is important to find microbes that can tolerate high levels of metals and detoxify them. Scientists have discovered some Aspergillus species that can survive high concentrations of copper and nickel metals.

These microbes must also be superb at decontaminating. One rockstar strain of Aspergillus flavus removed over 97% of mercury contamination. And two Pseudomonas species strains removed over 75% of copper, lead, and zinc contamination. Microbes like these will be vital for removing future heavy metal contamination.

Microbes creating a cleaner future

There are a lot of toxic materials in our world. As human activity increases, so too does the amount of toxic pollution we create on our planet. The results of oil spills and heavy metal contamination hurt our human health as well as the health of our planet.

Luckily, microbes have evolved ways to survive and detoxify these types of pollution. Our microbial friends can help remove these toxins and clean up messes created by us. By harnessing the power of microbes, bioremediation projects address our pollution problem and work to make our planet a greener and healthier place. And that’s a great New Year’s resolution!

Along with microbes, we can save the planet!

Take away messages from this week’s article:

• Toxic pollution is a major problem for the health of humans and our planet
• Microbes can detoxify environmental pollution in a process called microbial bioremediation
• Microbial bioremediation is an environmentally friendly and relatively inexpensive way to clean up toxic pollution

The post Microbial bioremediation: microbes cleaning-up our toxic messes appeared first on Bacterialworld.
Bacterialworld - A blog about bacteria: from scientific studies to vivid stories about the fascinating bacterial world

Microbes are necessary for many of our favorite foods, such as bread, cheese, and chocolate, and the beverages we wash them down with, like beer and wine!

With the holidays fast approaching, let’s look at how microbes play a central role in the holiday menu.

Microbes Help Make What You Eat

Microbes are everywhere, including your food. Not only known for food spoilage, but some microbes also help preserve and add flavor to foods. In a process called microbial fermentation, microbes convert sugars in foods into different compounds, such as alcohols or acids.

Bread

Microbes are also necessary to produce our foods. Many holiday meals include special bread that depends on the microorganism yeast. Bread making usually uses the yeast Saccharomyces cerevisiae to eat the sugar in bread dough to make carbon dioxide (CO₂) bubbles that expand and rise the bread.

Microbes can also give bread some of its flavors. Sourdough bread gained popularity during the COVID-19 pandemic because of the ease of culturing the sourdough yeast, called a starter. Sourdough’s unique flavor comes from the starter’s mixture of yeast and lactic acid bacteria. These Lactobacillus bacteria ferment and produce lactic acid, which gives sourdough that ‘sour’ taste and helps to prevent the bread from going stale.

Cheese

After making your holiday loaf, you will need to put something on those slices. Cheese is one of my favorite bread sidekicks and appears on many holiday menus.

Like bread, cheese requires a starter culture of bacteria to convert the sugars in the milk into acids such as lactic acid. Next, during cheese ‘ripening,’ added secondary microbial cultures give each cheese its unique flavor and texture. These secondary cultures can include bacteria, yeast, or even mold, like in the case of blue cheese, and all help produce those much-loved flavors.

Microbes Help Make What You Drink

Bread and cheese are delicious, but they are even better when paired with a nice beverage. Luckily, microbes help make some delicious drinks as well.

Beer

One of the oldest microbially-made drinks is beer. Beer dates back over 5,000 years, though recent evidence suggests people first fermented beer over 13,000 years ago! Like today’s beer, ancient cultures ground grains in large vats and exposed them to yeast that would eat the sugars and ferment it into alcohol and CO₂.

This process adds flavor to the drink as well as many nutrients and essential B vitamins. Most importantly, the alcohol kills possible contaminates and makes the water safe to consume. Adding hops aids its antimicrobial activity by inhibiting Gram-positive bacteria.

While the first beers relied on wild yeast strains naturally found in the air and dust, today’s brewers add specific strains of yeast for desired alcohol and flavor profiles. Or they might add bacteria. Many Belgian ales have Brettanomyces yeasts to produce their notable sour flavor, while German Berliner Weisse beers are fermented by Saccharomyces cerevisiae and Lactobacillus bacteria.

Wine

If beer is not your thing, possibly you will want a nice glass of wine this holiday season. You can thank microbes for that too.

Wine is produced when yeast ferment grapes, yielding both alcohol and CO₂ like for beer. Microbes are important not only for fermenting grapes, but specific yeast, fungi, and bacteria are important for keeping grapes healthy.

Additionally, some fungi are critical to produce specific wines. Botrytis cinerea is a fungus that helps to dry out and concentrate the sugars of a grape through a so-called ‘noble rot’. These grapes produce a sweet dessert wine called a botrytized wine. However, if Botrytis cinerea infects grapes during moist conditions, this ‘gray rot’ destroys the grape crop. Thus, having the right microbiome is important for agriculture just as it is for humans.

Kombucha

If you don’t like beer or wine, you can always try kombucha. This non-alcoholic beverage is produced from acetic acid bacteria and yeasts called a “tea fungus” that ferment tea. The bacteria and yeasts live symbiotically in a biofilm clump called a scoby (“symbiotic culture of bacteria and yeast”). Here, microbes work together to convert the sugars into acids that give the tea a nice tart flavor.

And don’t forget dessert!

Cakes, candies, and cookies are all staples of the holidays. These sweet treats would not be the same without microbes to add flavor and rise.

My favorite sweet, chocolate, comes from cacao beans that are initially fermented for many days by wild yeasts and bacteria. This process breaks down the beans and leads to the production of those oh so yummy chocolate flavors. Just another reason to love microbes!

Welcome Microbes to Your Next Meal

Microbes are vital for giving us so many of the foods and flavors we love. From foods like bread, cheese, and chocolate or drinks like beer, wine or kombucha, microbial fermentation plays an important role in many of our favorite dishes. Fermented foods give us flavors, vitamins, and additional food preservation.

These foods can also help maintain healthy digestive systems. Yoghurt, which is another fermented milk product, contains beneficial bacteria that can help maintain a balanced microbiome.

Not only do microbes help save the planet, but they also save our meals and our health too. So this holiday season, remember to incorporate microbial dishes into your menu.

The post Microbially Powered Meals: How microbes help make our foods appeared first on Bacterialworld.
Bacterialworld - A blog about bacteria: from scientific studies to vivid stories about the fascinating bacterial world

Everywhere in the world, you can find plastics, from grocery bags to pens to spandex leggings.

We use plastics because they are lightweight, flexible, and durable.

But their durability is also their biggest drawback. Plastic takes a long time to decompose, which becomes a huge burden for our environment and planet.

The plastic problem

But let’s start by looking at what plastic exactly is.

Plastics are made up of smaller monomer units that link together and form a chain called a polymer. Different monomers have different chemical structures. Different combinations of these plastic monomers make different types of plastics. That’s how a flexible grocery bag and a sturdy toothbrush can both be made from plastic.

It is like a brick building. There are many types of bricks, and different varieties of bricks are combined to build different sorts of buildings.

No matter the type of plastic, the links between two plastic monomers are very strong. This is what makes plastic so sturdy but also why it takes so long for plastics to break down naturally.

A typical plastic grocery bag takes 10-20 years to break down while a plastic bottle can take 100-450 years.

Currently, recycling plastics requires a lot of heat and chemicals to break the strong bonds between the monomers. Once those bonds are broken, the monomers can be reused to make something new.

As you can see, the recycling process is very energy-dependent, so we generally manage to recycle less than 10% of plastics. That means most plastic waste ends up burned (12%) or in landfills or oceans (79%) where it can sicken wildlife. One group predicted that 4.8 to 12.7 million metric tons of plastic had ended up in the oceans in 2010 alone! This causes major problems for aquatic life.

Plastic-degrading bacteria to the rescue

Gladly, we have some super bacteria that help us find new ways to degrade and recycle plastic. This will make the whole process easier, greener and less energy-intensive.

The key is plastic-degrading bacteria that have special enzymes to break down different types of plastics. Even though enzymes are proteins that speed up chemical reactions, most of these are fairly slow when it comes to degrading plastic polymers. Many of them still need high temperatures to perform best, which means a lot of energy input for recycling.

But recently, scientists discovered the bacterium Ideonella sakaiensis 201-F6 that can ‘eat’ plastic.

Yes, you read correctly.

Ideonella sakaiensis secretes an enzyme that breaks down the links between plastic monomers. These smaller monomers give the bacterium energy and building blocks. Just like how humans cut bread into slices to make it easier to eat, Ideonella sakaiensis breaks down plastic into smaller pieces to eat.

But Ideonella sakaiensis isn’t the only bacterium that loves eating plastic.

A recent study found that a strain of Pseudomonas eats polyurethane, another commonly used plastic polymer.

Other microbes like eating plastic too

And it’s not only bacteria that can be found in plastic-rich environments to degrade our plastic pollution. Also, other microorganisms evolved to eat plastic.

Isolated from landfill soil, the fungi Trichoderma viride breaks down plastic found in the landfill. The marine fungus Zalerion maritimum degraded small pieces of plastic, called microplastics, found throughout the oceans.

Harnessing microbial superpowers

Gladly, researchers are well on the way to using the power of microbes to help recycle plastics.

The bacterium Ideonella sakaiensis uses the enzyme PETase to break down a common type of plastic called polyethylene terephthalate (PET). Scientists hope to use the bacteria with their PETase enzymes in bioreactors to degrade plastic polymers. This would reduce the energy input needed for recycling.

But to achieve this, scientists need to better understand how PETase binds and degrades PET. For this, they determined the 3-D structure of the enzyme.

Based on these data, scientists tried to increase the efficiency of PET degradation, for which they slightly changed the protein structure of the enzyme. This already improved the degradation rate of the enzyme, but they continue to modify and improve PETase activity. Hopefully, this ongoing improvement will bring us a much more efficient plastic-degrading PETase enzyme that we can use for recycling plastics.

The plastic-degrading power of microbial communities

Additionally, communities of bacteria and microbes have the possibility of acting as plastic-degrading bioreactors. Researchers found a marine microbial biofilm that broke down weathered plastics. They then added bacteria, which they already knew would degrade plastic, to the biofilm. This addition increased the plastic degrading efficiency of the community.

And it looks as if nature already evolved a system to address our plastic waste. A bacterial community isolated from a plastic-processing plant degraded plastic at higher levels as compared to a formulated community of laboratory bacterial strains.

Why was that?

Well, when scientists looked at the genes of the native community, they found new bacterial strains. And these strains of bacteria most likely evolved to degrade plastic better than known strains.

Just imagine what types of plastic-degrading microbes scientists may find if they continue to look for them!

Let’s hope that one day we can implement microbial enzymes and communities in plastic recycling processing.

A cleaner future thanks to plastic-degrading bacteria

Plastics continue to pollute our planet. As these items fill landfills and oceans, they break into smaller and smaller pieces that are easily consumed by and sicken wildlife. Small microplastics can act as a surface for pathogenic and antibiotic-resistant bacteria to live on and spread. And microplastics have even been found in human drinking water.

Plus, the more plastic we lose to pollution the less plastic is available to recycle and reuse. This means more plastic needs to be produced using non-renewable fossil fuels. And we all know that fossil fuels are not sustainable as they contribute to air and water pollution as well as climate change. All of these factors compound the present plastic problem the planet faces today.

With more research, let’s hope we can find more bacteria that are able to degrade plastic polymers. By using microbes and microbial enzymes, possibly we can reduce overall plastic waste. However, even with microbes’ help, we can all play a part and reduce our plastic consumption. That means, buying reusable over disposable products and recycling plastics appropriately.

Along with microbes, we can save the planet!

Take-away messages from this week’s article

• Plastic pollution is a major problem for the planet
• Plastic is hard to break down, but some bacteria degrade plastic thanks to their special enzymes
• Communities of bacteria and microbes can work together to degrade and recycle plastic

The post Plastic Degrading Microbes For a Cleaner Future appeared first on Bacterialworld.
Bacterialworld - A blog about bacteria: from scientific studies to vivid stories about the fascinating bacterial world

We are completely surrounded by them and we surely would not be the same if it was not for our microbial friends.

Unfortunately, every once in a while, we read and hear negative news articles about certain players of the microbial world. And then we forget that many other microbes and bacteria are actually very helpful to us, our health, the environment and food production.

But the goal of the BacterialWorld blog is to remind you how colorful and interesting the microbial world is.

20 interesting microbes everyone should have heard about

The microbial world consists of many interesting players: bacteria, viruses, phages, fungi, protozoa, unicellular eukaryotes and microscopic animals. And together, they all make the microbial world such a diverse and fascinating environment.

So, here, we assembled a list of common and interesting microbes. Some of them you might find delightful, others you rather want to avoid and that is okay.

We want you to be aware that there are many more cool microbes and bacteria out there than what you hear in the news.

And that thanks so research, we know a lot about how to use these microbes or how to avoid them if they are dangerous.

For this list, I got help from microbe lover Rachel and her GIANTmicrobes which she introduced during the #MicrobesinMay challenge on Twitter.

Ready to learn about the microbial world and interesting bacteria and microbes?

1. The bacterium Escherichia coli

Escherichia coli is rod-shaped and can have flagella all around its cell. 

Most people have heard of Escherichia coli because of contaminated food or lakes. However, most strains are harmless and this bacterium is actually super important for your digestive health.

This is also why Escherichia coli is by far the most intensively studied and best-understood organism on the planet.

Escherichia coli serves as a model organism for microbiology and biotechnology. It is helping scientists to learn about everything DNA-related, as well as protein production and cell growth. In most research labs of biological or life sciences, scientists use this organism every day to produce proteins, produce gene fragments or use it as a vehicle for plasmids and vectors.

2. The Influenza virus

The influenza virus is an RNA orthomyxovirus that causes respiratory infections, which you may know as the ‘seasonal flu’. Luckily, there is a vaccine against the flu that you should get every year if you are able to.

Influenza is an RNA virus that contains 8 genetic segments. Generally, RNA viruses are prone to mutate a lot; this happens during so-called antigenic drift and antigenic shift events. These “shifts and drifts” can change the structure of the virus’s surface proteins. Unfortunately, this change makes it harder for our immune system to recognize and respond to the virus.

Because the flu virus is ever-changing, you should help your immune system to recognize the new antigens. You can do this best by getting the new FluShot every season. But be aware that each virus is different and a FluShot will not protect you against other viruses.

3. The fungus Saccharomyces cerevisiae

You may encounter this fungus – almost on a daily basis. Saccharomyces cerevisiae is also known as the common yeast.

We use this yeast to make beer and bread. Like many other microorganisms, Saccharomyces cerevisiae performs microbial fermentation. This means it eats sugar and turns it into alcohol in beer and CO2 for bubbles in beer and bread.

We cannot state enough that the yeast Saccharomyces cerevisiae is a fungus and not a bacterium. It produces rounded cells and researchers use it as a model organism for eukaryotes. This means its DNA is enclosed in a membrane and not swimming around freely as in bacteria. Humans are also eukaryotes, so lots of knowledge of human cellular and molecular biology comes from yeast research.

Saccharomyces cerevisiae also plays a role in biotechnology. Some strains produce biofuels while others produce recombinant proteins that we use as therapeutics.

4. The bacterium Lactobacillus acidophilus

Lactobacillus acidophilus gets its name because it produces lactic acids from sugars, which usually makes its surrounding very acidic.

Lactobacillus acidophilus cells are rod-shaped and usually grow in pairs or chains. This bacterium lives in our mouths and guts where it prevents the growth of other bacteria by maintaining a healthy microbiota.

This bacterium also helps make yogurt, since it breaks apart milk sugars to make acids and other healthy molecules. This is why Lactobacillus acidophilus is also a probiotic, meaning a microbe that promotes health. There are many claims out there promoting its use to increase health, but more research is needed.

5. The Rhinovirus

The Rhinovirus may look cute but it is one of those nasty viruses that you may not like. It causes the common cold and we all know how we feel not cute with a cold. There are more than 100 different varieties of rhinoviruses and together they cause almost half of all colds.

Rhinovirus is an RNA virus in a 20-sided capsid. They are some of the smallest viruses and can spread by aerosol or direct contact. The virus replicates best in temperatures slightly cooler than body temperature, like in the nose. In fact, “rhino” means nose in Greek.

Currently, there is no vaccine against Rhinovirus. And since it’s a virus, antibiotics won’t work against it.

The best way to protect yourself is good hand hygiene and physical distance from people with a cold.

6. The microscopic water bear

One of the most interesting and cutest microbes is definitely the water bear.

But what exactly are water bears?

Hypsibius dujardini are microscopic creatures, classified as the Tardigrada phylum.

As the name suggests water bears resemble bears and walk on eight tiny legs. Tardigrade means “slow walker”. So if you imagine a slow-walking bear through water, this is kind of what water bears are!

Besides being adorable, water bears can survive extreme conditions and they are found worldwide in diverse environments. Many species live in water or around moss. To survive in any habitat, water bears enter a state of cryptobiosis where it dries out and stops its metabolism. In this state, they can last several decades.

Water bears can live in hot springs, polar ice, mountains and deep in the ocean. In fact, researchers found that water bears can even survive the vacuum of space! That’s good since a capsule containing some crashed on the moon in 2019.

Learn more about what tardigrades look like under the microscope.

7. The microscopic rotifers

To us, Rotifers are certainly one of the most interesting and cutest microbes. These microscopic animals are almost all female and can reproduce without the involvement of males.

Rotifers are tiny free-living creatures found mostly in freshwater. Rotifers have a cylindrical body and a ring of cilia around their heads. When the cilia move, it appears as a wheel (rotifer means “wheel bearer”). This movement pushes food into the animal and helps them move through the water.

Rotifers are sexually dimorphic and the males are much smaller and usually do not live long.

Reproduction of this microbe is rather interesting: Unfertilized eggs grow as clones within their mother. But studies have found genetic differences without sexual reproduction. It is now just a question of how?

8. The bacterium Porphyromonas gingivalis

The bacterium Porphyromonas gingivalis causes bad breath and gum disease, so make sure to brush and floss regularly to keep it in check.

Porphyromonas gingivalis cells are rod-shaped and live in our mouths. They are anaerobic, so they don’t need oxygen to grow. This may seem odd since we should have oxygen in our mouths all the time. However, many different microbes grow in our mouths where they form biofilms. These are layers of almost no oxygen, in which the bacteria settle.

In the oral biofilm, the dental plaque, Porphyromonas gingivalis lives close to the gum line where oxygen is depleted. Here, the bacteria can infect the gum and cause erosion called periodontitis.

9. The Rubellavirus

The “little red” Rubellavirus is known to produce red rashes on children’s arms and faces. Luckily, there is a vaccine to prevent infection.

Rubella is an RNA virus in a 20-sided capsid wrapped by a lipid membrane. Also called German measles because it was first identified in Germany, rubella was once a common childhood disease causing rash, fever and sore throat. While it posed minor risks to children, rubella could be deadly for the unborn in the womb.

Today rubella is very rare because of the MMR vaccine, which protects against mumps, measles, and rubella. Thanks to scientific research and vaccination, many countries could be declared “free of endemic transmission of rubella”.

10. The morbillivirus

Separately, the virus that causes the measles. This virus leads to red spots all over the body and can be deadly. Fortunately, the MMR vaccine prevents infection.

Morbillivirus is a spherical RNA virus. Measles is very contagious and spreads by personal contact and contaminated surfaces. It infects the respiratory system and causes rash, fever, cough, running nose and red eyes. Measles can cause serious complications and be deadly for kids.

Today, morbillivirus is still responsible for more than 100 000 deaths yearly, down from more than 2 million deaths annually. This is due to the introduction and widespread use of the MMR vaccine.

11. The bacterium Shigella dysenteriae

If you’ve ever experienced Shigella dysenteriae, you would remember! This bacterium infects the intestines and causes shigellosis, which is incredibly painful and uncomfortable. Antibiotics treat this disease, but hygiene is the best prevention.

Shigella dysenteriae are rod-shaped bacteria. They have a biological needle with which they fire the so-called ‘Shiga toxin’ into our gut cells. This leads to stomach pain and watery diarrhea.

This bacterium travels through the fecal-oral route, from contaminated food or hands. It is very contagious because it needs only a few cells to make someone sick.

What’s the best way to protect yourself? Always cook food thoroughly to kill all bacteria. And wash your hands to prevent spread!

12. The human papillomavirus

This virus may look cute, but human papillomavirus has been linked to certain cancers! The human papillomavirus is a common virus that infects many. Thankfully, there is a new vaccine to prevent high-risk infections.

The human papillomavirus is a DNA virus surrounded by a circular capsid. This virus is very common and in most cases, one may not have any symptoms while the body clears the virus.

Sometimes, the virus causes small tumors called papillomas that appear as warts. If left untreated, those tumors can become cancerous.

The human papillomavirus spreads by direct contact and is one of the most common sexually transmitted diseases worldwide. A vaccine is available to prevent infection from the major cancer-associated human papillomavirus types.

13. The bacterium Anabaena

Anabaena, known as cyanobacteria, are photosynthetic bacteria, even though they resemble eukaryotic algae. These helpful bacteria contain pigments that give Anabaena the blue-green colour.

Commonly found in aquatic environments, cyanobacteria use their pigments to convert light into energy. Using that light along with CO2 and water, they convert it to sugar and oxygen. In fact, cyanobacteria are a major source of oxygen in our atmosphere today!

The bacteria are even more interesting since some of their cells have special superpowers. These so-called heterocysts can “fix” nitrogen.

Heterocysts have extra thick- cell walls to exclude oxygen that otherwise harms nitrogen-fixing enzymes. The heterocysts then share the fixed nitrogen with surrounding cells.

14. The bacterium Clostridium botulinum

Clostridium botulinum produces a neurotoxin known for causing botulism. But that same toxin is also a component of Botox. Just another way we use microbes for good.

Clostridium botulinum is a rod-shaped, spore-forming, anaerobic bacterium. Found in soils, it can enter the food supply as spores. Under correct conditions, like in canning, spores germinate and produce the toxin. Thus, food should be processed with high heat and pressure to kill spores.

The botulinum toxin is the most toxic substance known and causes paralysis. While botulism is serious and can be deadly, scientists found ways to use the muscle-paralyzing function of this toxin. In small doses, the toxin treats muscle disorders such as spasms. Also found in Botox, the toxin paralyzes muscles that lead to wrinkles.

15. The varicella-zoster virus

Remember those itchy spots caused by chickenpox? I do! But now many children don’t have to experience the results of the varicella-zoster virus because of the chickenpox vaccine (lucky them!).

The varicella-zoster virus is a highly contagious DNA herpesvirus. As a primary infection, the virus causes so-called varicella. You might remember this as body rash and itchy blisters that last a few days.

Yet, the varicella-zoster virus actually can remain dormant in our nervous system (called latency) and reactivate later in life. This secondary infection can then lead to herpes zoster, also called shingles.

While chickenpox is usually a non-serious childhood disease, shingles affect adults and can have serious complications and pain. That’s why there is a separate shingles vaccine, too. No one wants to be itchy or in pain, so make sure to get the vaccine!

16. The bacterium Borrelia burgdorferi

Borrelia burgdorferi is a spirochete bacterium shaped like a corkscrew with flagella at both ends. These bacteria live in ticks and can infect humans when bitten by an infected tick.

These bacteria cause Lyme disease, a zoonotic disease where the pathogen jumps from an animal to a human.

Lyme disease is best known for causing a bull’s eye rash. But it also causes fever, headaches and fatigue. Some cases of Lyme disease are asymptomatic and if left untreated can lead to serious neurological or heart issues. Make sure to protect yourself when going hiking and camping.

17. The bacterium Listeria monocytogenes

This bacterium has made headlines, but not for anything fun. Listeria monocytogenes has led to many food recalls because of contamination concerns. It can grow at 0°C, so even refrigerated food can be infected.

Listeria monocytogenes cells are rod-shaped and covered with flagella. This food-borne pathogen causes listeriosis that may result in sepsis, meningitis, or death. It’s especially dangerous for immunocompromised and unborn, which is why pregnant women shouldn’t eat soft cheese or uncooked meat.

Listeria monocytogenes is found in environments where food grows. Contamination can occur during food harvesting and processing. Once inside a human cell, they manipulate it so that the cell propels the bacteria into the next cell.

18. The Epstein-Barr virus

Did you know that the Epstein-Barr virus is one of the most common human viruses? It causes the commonly called kissing disease because we transfer the virus by saliva and bodily fluids.

The Epstein-Barr virus is a DNA herpesvirus with a lipid envelope. Most infections occur in childhood and are asymptomatic or with only mild symptoms. Roughly 90% of adults have antibodies against Epstein-Barr, which means they were once infected with this virus.

When infecting adults for the first time, the Epstein-Barr virus can cause mononucleosis. Symptoms include fever, sore throat and extreme fatigue, lasting weeks to months. You can prevent the spread by not sharing utensils or drinking cups.

19. The bacterium Staphylococcus aureus

One of the best-known bacterial warriors is Staphylococcus aureus and its methicillin-resistant super brother MRSA. These two can infect almost all parts of the human body with their arsenal of virulence factors.

Staphylococcus aureus cells are round-shaped and form grape-like clusters. Most people have this Gram-positive bacterium in their nose or on their skin.

Unfortunately, with certain triggers, this harmless bacterium can become a pathogen. Then, Staphylococcus aureus produces virulence factors, such as toxins, enzymes, and antibody-inactivating proteins. These bacteria can also form biofilms on medical implants.

What about MRSA? Those are strains of Staphylococcus aureus that are resistant to the antibiotic methicillin (Methicillin-resistant Staphylococcus aureus). Antibiotic resistance occurs when bacteria acquire ways to inactive antibiotics and has become a worldwide health crisis.

20. The protozoan Toxoplasma gondii

Love cats? Well, those cats might have a ‘friend’: Toxoplasma gondii. This parasite can be carried by cats and is one of the most common parasites in the world. The infection causes toxoplasmosis which is an important zoonosis.

Toxoplasma gondii is an obligate intracellular parasite. It can reproduce sexually only in cats (called the definitive host) or asexually in any warm-blooded host (such as mice or humans). A cat can become infected by eating an infected mouse, then pass the infection to humans via litter.

Toxoplasmosis infections can occur from eating contaminated food or from infected cat droppings. In most cases, the infection is asymptomatic. However, immunocompromised and pregnant people are at risk for complications.

Which one is your favorite among the interesting microbes?

We hope we could give you a broad overview of interesting microbes and bacteria common in the environment and on the human body. This list of common microbes is meant to raise awareness of how multifaceted the microbial world is.

Yes, some of these microbes cause diseases. But thanks to research, we now have ways to boost our immune systems to clear diseases caused by pathogens or to prevent microbial diseases in the first place with vaccines.

And don’t forget that so many microbes are actually super helpful and fun to look at! Just look at this cute water bear dancing around!

If you have questions about any of these microbes or want to learn more about any player in the microbial world, comment below or send us an email.

And if you want to know more about Rachel and interesting bacteria, follow her on Twitter, or connect with her on LinkedIn.

The post 20 interesting microbes everyone should have heard about appeared first on Bacterialworld.
Bacterialworld - A blog about bacteria: from scientific studies to vivid stories about the fascinating bacterial world

If you are like me, you would make sure to always have your stock filled with this delicacy.

Especially in tough times, you need it more than ever. And you are trying to hide the chocolate from yourself. Yet, you would always find it again and indulge in its sweet-bitter taste that feels like home to you.

But did you know that chocolate, as well as other foods like beer and wine and bread, would not taste as we know it if it wasn’t for our little microbial friends?

That bacteria and microbes actually make the chocolate taste because they produce certain molecules that give it its flavour?

So, next time you enjoy your piece of chocolate, be grateful to bacteria and their superpowers for providing you with such a delicious fermentation product.

Where does chocolate come from?

It all starts with cocoa beans.

Cocoa beans are the seeds of the fruit pod of the tree Theobroma cacao that grows in tropical regions. These beans usually grow within the slimy white-creamy pulp inside the pod.

When the pods are ripe, people harvest and open them. They take out the beans and the pulp from the pod and leave them in the sun to ferment. This takes up to a week, during which the beans are regularly moved to avoid the growth of toxic fungi.

When the beans are dry, they are roasted to kill the remaining bacteria. This process is also important for the flavour of the beans. Then the beans are crushed into cocoa nibs and separated into cocoa powder and cocoa butter and processed into delicious chocolate.

Which bacteria are involved in cocoa fermentation?

When growing on the tree, the inner of the fruit pod is free of microbes. Only the surface of the pod is covered by different bacteria, yeasts and fungi. This consortium of microorganisms is the co-called COCOBIOTA.

When opening the pods, the microbes from the outside come in contact with the inner pulp where they start doing their magic. Without the microbial activity, the pulp is full of sucrose and citric acid and tastes very “sugary acidic and really good. Really unexpected.” as our graphical wizard, Noémie knows from her own experience.

Interestingly, cocoa fermentation is a naturally occurring process, so no artificial bacterial starter culture is added. Only those microbes that are present on the pod ferment the beans.

And scientists found that the superheroes of chocolate fermentation are lactic acid bacteria like Lactobacillus fermentum and Acetobacter pasteurianus and the yeasts Saccharomyces cerevisiae, Hanseniaspora thailandica, Hanseniaspora opuntiae and Pichia kudriavzevii. Also, many other microbes, that are still not well characterised, are involved in the process.

What happens during cocoa fermentation?

Since the inner pulp of the bean is so acidic, not many bacteria grow on it. However, yeasts and lactic acid bacteria love this kind of sour environment. So, they grow and metabolise the pulp.

First, yeast enzymes break down the sucrose of the pulp into the sugars glucose and fructose.

Next, different yeast strains metabolise the glucose and fructose and produce ethanol from the sugars. This is the actual fermentation process. In the next step, lactic acid bacteria make acetic acid and lactic acid from the ethanol.

Due to the metabolic activity of the microbes, the temperature of the pulp rises. Yeasts generally do not like this warmth and die.

Instead, other microbes break down the citric acid which makes the pulp less acidic. Now it is an environment that is very friendly for other bacteria so that bacteria like Bacillus, and fungi, as for example Penicillium citrinum and Aspergillus fumigatus start growing.

This consortium of microorganisms produces several compounds that diffuse into the cocoa beans. Without the bacterial activity, the raw beans “are definitely far from chocolate taste” as Noémie put it.

What chocolate-tasting molecules do bacteria produce during cocoa fermentation?

Scientists are just starting to understand the microbial network and metabolism that create the chocolate taste. You can understand the bacterial metabolism as the following phenomenon.

When bacteria live in an environment with an overload of nutrients (like within the pulp full of sugar), they switch their metabolism to high activity. In this mode, bacteria use their normal metabolism to grow and divide and be happy. On top of that, they have all that excess sugar with which they fill up the cell storage for bad times. And from these stored sugars, they produce additional fancy molecules, so-called secondary metabolites.

Imagine the sugars as your monthly salary. In normal times, you pay all your basic monthly bills, like rent, electricity etc, and probably put the rest in your savings. When you get a massive paycheck and swim in cash, you do all that as well, plus you buy some additional fancy stuff that you don’t really need to survive. This additional stuff represents those secondary metabolites.

Secondary metabolites are often super complex molecules and certain bacteria even produce unique compounds that no one else produces. For example, antibiotics are secondary metabolites as well and so are certain probiotics.

Bacteria produce the right mix for the chocolate taste

In the case of chocolate, the right composition of the secondary metabolites is important to give chocolate its unique taste.

For example, the bitter taste of chocolate comes from caffeine and theobromine. These compounds are especially important if you prefer chocolate with higher cocoa content as it contains more caffeine and less sugar.

Another group of secondary metabolites that microbes produce during cocoa fermentation is polyphenols. Polyphenols are also prebiotics so they are actually beneficial for our health. You can find other polyphenols also in some fruits, nuts, red wine and, obviously, chocolate.

In all, by producing the right mix of these secondary metabolites, bacteria and fungi change the taste of the cocoa bean into the delicious chocolate flavour that you are familiar with.

Thank bacteria for the delicious chocolate taste

And to make you feel better when enjoying your chocolate: Researchers found in animal and human studies that cocoa itself has health benefits. After eating cocoa, people showed lower rates of cardiovascular disease, diabetes and vasodilation which might even have positive impacts on learning and memory regions.

However, as always when it comes to diet, quantity is key ?

So, the next time you enjoy your chocolate, be grateful to bacteria and their chocolatey superpowers!

The post Bacteria are responsible for the delicious chocolate taste appeared first on Bacterialworld.
Bacterialworld - A blog about bacteria: from scientific studies to vivid stories about the fascinating bacterial world