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	<title>Explore purple and animal lovers Janthinobacterium on Bacterialworld</title>
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	<title>Explore purple and animal lovers Janthinobacterium on Bacterialworld</title>
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		<title>Creating the colours of the rainbow: Bacteria and the vibrant world of pigments</title>
		<link>https://sarahs-world.blog/bacteria-and-the-colourful-world-of-pigments/</link>
					<comments>https://sarahs-world.blog/bacteria-and-the-colourful-world-of-pigments/#respond</comments>
		
		<dc:creator><![CDATA[Sarah]]></dc:creator>
		<pubDate>Tue, 09 Jan 2024 19:01:54 +0000</pubDate>
				<category><![CDATA[Bacteria and their environment]]></category>
		<category><![CDATA[Animals]]></category>
		<category><![CDATA[Antibiotics]]></category>
		<category><![CDATA[Bacterial membrane]]></category>
		<category><![CDATA[Bacterial stress response]]></category>
		<category><![CDATA[Extremophiles]]></category>
		<category><![CDATA[Fungi]]></category>
		<category><![CDATA[Physiology]]></category>
		<category><![CDATA[Plants]]></category>
		<guid isPermaLink="false">https://sarahs-world.blog/?p=5036</guid>

					<description><![CDATA[<p>Our world as well as the bacterial world are full of vibrant colours. These colours exist thanks to biopigments; molecules able to capture light and reflect the corresponding colour. Many organisms, as well as bacteria, learned to use biopigments to harvest energy from sunlight, fight foes and adapt to new and challenging environments. Read on to learn what makes the bacterial world so colourful and why biopigments are the Earth’s life savers.</p>
<p>The post <a href="https://sarahs-world.blog/bacteria-and-the-colourful-world-of-pigments/">Creating the colours of the rainbow: Bacteria and the vibrant world of pigments</a> appeared first on <a href="https://sarahs-world.blog">Bacterialworld</a>.<br />
<a href="https://sarahs-world.blog">Bacterialworld - A blog about bacteria: from scientific studies to vivid stories about the fascinating bacterial world</a></p>
]]></description>
										<content:encoded><![CDATA[
<p class="wp-block-paragraph">The world around us is colourful. Wherever you look, you see various colours of different shades and hues.</p>



<p class="wp-block-paragraph">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.</p>



<p class="wp-block-paragraph">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.</p>



<h2 class="wp-block-heading">Bacterial pigments bring colour to the world of bacteria</h2>



<p class="wp-block-paragraph">Biopigments are molecules with complex chemical structures and at least one excited electron. Depending on the electron&#8217;s arrangement, a pigment absorbs light at a specific wavelength. It reflects the colour of the unabsorbed wavelength, which gives the pigment its colour.</p>



<p class="wp-block-paragraph">As the function of pigments depends on the incoming light, <a href="https://doi.org/10.1002%2Fbab.2170" target="_blank" rel="noreferrer noopener">sunlight plays a crucial role for bacteria with pigments</a>. By adding certain pigments to their <a href="https://sarahs-world.blog/tag/bacterial-membrane/" target="_blank" rel="noreferrer noopener">membrane</a>, 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.</p>



<p class="wp-block-paragraph">However, some bacteria also use pigments for other purposes, which we discuss further in this article.</p>



<h2 class="wp-block-heading">Microbes harness photosynthetic power with colourful pigments</h2>



<p class="wp-block-paragraph">Sunlight is incredibly powerful since each light photon contains energy. Bacteria adapted to harvest energy from sunlight with special pigments.</p>



<p class="wp-block-paragraph">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.</p>



<p class="wp-block-paragraph">The best-known example of a photosynthetic biopigment is chlorophyll in plants, algae and cyanobacteria. <a href="https://doi.org/10.1016/j.fct.2018.08.002" target="_blank" rel="noreferrer noopener">Cyanobacteria produce several complexes of bacteriochlorophylls</a> to absorb blue and red light. As the green light is not absorbed, it is reflected, which is why chlorophyll &#8211; and thus cyanobacteria, algae and plants &#8211; are green.</p>



<p class="wp-block-paragraph">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.</p>



<p class="wp-block-paragraph">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.</p>



<p class="wp-block-paragraph">Halophilic bacteria and archaea are microbes that produce <a href="https://doi.org/10.3390%2Fmd17090524" target="_blank" rel="noreferrer noopener">carotenoids to capture sunlight.</a> You may have seen salt ponds with a reddish colour. This comes from the red and pink-coloured archaea <em>Halobacteria,</em> bacteria <em>Salinibacter</em> or algae <em>Dunaliella.</em> Thanks to their colourful carotenoids, these microbes adapt to salty waters that are exposed to direct sunlight.</p>



<p class="wp-block-paragraph">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 <a href="https://sarahs-world.blog/extremophiles-flourish-at-deep-sea/" target="_blank" rel="noreferrer noopener">bacteria to survive in these dark environments</a>. If you have ever seen a lagoon shining yellow or orange, this was probably due to the colourful cyanobacteria inside.</p>



<h2 class="wp-block-heading">Bacterial biopigments protect from too much light</h2>



<p class="wp-block-paragraph">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.</p>



<p class="wp-block-paragraph">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.</p>



<p class="wp-block-paragraph">The <a href="https://doi.org/10.1094/MPMI-11-19-0326-CR" target="_blank" rel="noreferrer noopener">yellow xanthomonadins absorb wavelengths within the energy-rich UV spectrum</a>. Bacteria like <em>Xanthomonas campestris</em> live on plant leaves where they are exposed to direct sunlight. Hence, their <a href="https://sarahs-world.blog/plant-pathogenic-bacteria/" target="_blank" rel="noreferrer noopener">yellow xanthomonadin coats are like self-made sunblocks protecting the bacteria</a>.</p>



<figure class="wp-block-image aligncenter size-large is-resized"><img fetchpriority="high" decoding="async" width="791" height="1024" src="https://sarahs-world.blog/wp-content/uploads/X_xanthomonas_campestris_no_BG-791x1024.jpg" alt="" class="wp-image-3720" style="width:453px;height:auto" srcset="https://sarahs-world.blog/wp-content/uploads/X_xanthomonas_campestris_no_BG-791x1024.jpg 791w, https://sarahs-world.blog/wp-content/uploads/X_xanthomonas_campestris_no_BG-232x300.jpg 232w, https://sarahs-world.blog/wp-content/uploads/X_xanthomonas_campestris_no_BG-768x994.jpg 768w, https://sarahs-world.blog/wp-content/uploads/X_xanthomonas_campestris_no_BG-1187x1536.jpg 1187w, https://sarahs-world.blog/wp-content/uploads/X_xanthomonas_campestris_no_BG.jpg 924w" sizes="(max-width: 791px) 100vw, 791px" /></figure>



<p class="wp-block-paragraph">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 <em>Vibrio cholerae</em> and <em>Streptomyces</em> bacteria, are brown or black.</p>



<h2 class="wp-block-heading">Bacterial pigments let electrons flow and save energy</h2>



<p class="wp-block-paragraph">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.</p>



<p class="wp-block-paragraph">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 &#8211; produced only by bacteria &#8211; allows our bodies to work.</p>



<p class="wp-block-paragraph">Phenazines are unique bacterial pigments with yellowish-green fluorescent colours. Pyocyanin, exclusively produced by <em>Pseudomonas </em>bacteria, <a href="https://sarahs-world.blog/bacterial-respiration-gains-energy/">shuttles electrons &#8211; and thus energy &#8211; during the respiration process</a>. Hence, <a href="https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7916356/" target="_blank" rel="noreferrer noopener">pyocyanin is essential for <em>Pseudomonas</em> as it keeps the bacteria healthy and alive</a>.</p>



<h2 class="wp-block-heading">Some biopigments have anti-oxidant effects</h2>



<p class="wp-block-paragraph">Bacterial pigments don&#8217;t just help adapt to external environmental conditions like the sunlight. They also <a href="https://sarahs-world.blog/salmonella-stress/" target="_blank" rel="noreferrer noopener">guard the inner bacterial cell from stressful situations</a>.</p>



<p class="wp-block-paragraph">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 <a href="https://sarahs-world.blog/tag/bacterial-stress-response/">oxidative stress</a>, oxygen radicals can even become life-threatening for bacteria.</p>



<p class="wp-block-paragraph">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.</p>



<p class="wp-block-paragraph">In the bacterium <em>Gemmatimonas aurantiaca,</em> 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.</p>



<figure class="wp-block-image aligncenter size-large is-resized"><img decoding="async" width="791" height="1024" src="https://sarahs-world.blog/wp-content/uploads/G_gemmatimonas_aurantiaca-791x1024.png" alt="" class="wp-image-5037" style="width:419px;height:auto" srcset="https://sarahs-world.blog/wp-content/uploads/G_gemmatimonas_aurantiaca-791x1024.png 791w, https://sarahs-world.blog/wp-content/uploads/G_gemmatimonas_aurantiaca-232x300.png 232w, https://sarahs-world.blog/wp-content/uploads/G_gemmatimonas_aurantiaca-768x994.png 768w, https://sarahs-world.blog/wp-content/uploads/G_gemmatimonas_aurantiaca-1187x1536.png 1187w, https://sarahs-world.blog/wp-content/uploads/G_gemmatimonas_aurantiaca-1583x2048.png 1583w" sizes="(max-width: 791px) 100vw, 791px" /></figure>



<h2 class="wp-block-heading">Bacteria combat microbial enemies with coloured pigments</h2>



<p class="wp-block-paragraph">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&#8217; energy and oxygen household.</p>



<p class="wp-block-paragraph">For example, prodigiosin is the red weapon of <em>Serratia marcescens.</em> As prodigiosin inhibits the growth of several bacterial, fungal and insecticidal pathogens, <em>Serratia marcescens</em> is an <a href="https://sarahs-world.blog/bacterial-killer-weapon-as-biocontrol-agent/" target="_blank" rel="noreferrer noopener">important biocontrol bacterium of plant disease</a>.</p>



<p class="wp-block-paragraph">You may have seen prodigiosin-producing <em>Serratia</em> bacteria on contaminated food. They develop these red, blood-like dots.</p>



<p class="wp-block-paragraph">Violacein is a purple pigment with anti-viral, anti-bacterial and anti-cancer properties. For example, <a href="https://sarahs-world.blog/bacteria-firing-toxic-bubbles/" target="_blank" rel="noreferrer noopener"><em>Chromobacterium violaceum</em> sends membrane bubbles filled with violacein to kill bacterial enemies</a>.</p>



<p class="wp-block-paragraph">Similarly, <em>Janthinobacterium lividum</em> protects frogs and salamanders as it lives on their skins. Here, the <a href="https://sarahs-world.blog/bacteria-colourful-antibiotics/" target="_blank" rel="noreferrer noopener">bacterium throws violacein at pathogenic fungi that would otherwise infect and harm the animals</a>.</p>



<figure class="wp-block-image aligncenter size-large is-resized"><img decoding="async" width="921" height="1024" src="https://sarahs-world.blog/wp-content/uploads/J_Janthinobacter_lividum2-1-921x1024.jpg" alt="" class="wp-image-3810" style="width:545px;height:auto" srcset="https://sarahs-world.blog/wp-content/uploads/J_Janthinobacter_lividum2-1-921x1024.jpg 921w, https://sarahs-world.blog/wp-content/uploads/J_Janthinobacter_lividum2-1-270x300.jpg 270w, https://sarahs-world.blog/wp-content/uploads/J_Janthinobacter_lividum2-1-768x854.jpg 768w, https://sarahs-world.blog/wp-content/uploads/J_Janthinobacter_lividum2-1.jpg 924w" sizes="(max-width: 921px) 100vw, 921px" /></figure>



<p class="wp-block-paragraph">Pyocyanin, the fluorescent electron-shuttling pigment in <em>Pseudomonas</em>, is also very sensitive to oxygen. It even turns <em>Pseudomonas aeruginosa</em> cultures in the lab blueish just by shaking and airing them.</p>



<p class="wp-block-paragraph">Yet, not all bacteria have an <a href="https://sarahs-world.blog/antimicrobial-resistance-mechanisms/" target="_blank" rel="noreferrer noopener">appropriate coping mechanism</a> for pyocyanin. Hence, these bacteria suffer oxidative stress when they come into contact with this pigment. This is why <em>Pseudomonas</em> <a href="https://sarahs-world.blog/antibiotics-produced-by-bacteria/">uses pyocyanin also to fight bacterial and fungal enemies</a>.</p>



<h2 class="wp-block-heading">Vivid pigments colour the bacterial world </h2>



<p class="wp-block-paragraph">The <a href="https://sarahs-world.blog/coloured-bacteria-from-a-to-z/" target="_blank" rel="noreferrer noopener">Bacterial World is colourful</a> &#8211; one of this blog’s taglines. You may have asked yourself what this is about and why bacteria have so many different colours.</p>



<p class="wp-block-paragraph">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.</p>



<p class="wp-block-paragraph">Some of these bacterial pigments are essential for us humans and even life on Earth. From some of these colourful biopigments, we <a href="https://doi.org/10.3390%2Fnu15081923">produce vitamins that we need for our own metabolism</a>. Also, every oxygen molecule that you just took up with your last breath, at some point, was transformed by a bacterial chlorophyll pigment.</p>



<p class="wp-block-paragraph">So, I guess it is yet again time to be grateful to bacteria and their vibrant and life-enabling activities!</p>
<p>The post <a href="https://sarahs-world.blog/bacteria-and-the-colourful-world-of-pigments/">Creating the colours of the rainbow: Bacteria and the vibrant world of pigments</a> appeared first on <a href="https://sarahs-world.blog">Bacterialworld</a>.<br />
<a href="https://sarahs-world.blog">Bacterialworld - A blog about bacteria: from scientific studies to vivid stories about the fascinating bacterial world</a></p>
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		<title>Bacteria use antibiotics to kill their foes and protect others</title>
		<link>https://sarahs-world.blog/antibiotics-produced-by-bacteria/</link>
					<comments>https://sarahs-world.blog/antibiotics-produced-by-bacteria/#respond</comments>
		
		<dc:creator><![CDATA[Sarah]]></dc:creator>
		<pubDate>Sat, 11 Dec 2021 17:01:57 +0000</pubDate>
				<category><![CDATA[Bacterial wars]]></category>
		<category><![CDATA[Antibiotics]]></category>
		<category><![CDATA[Antimicrobial resistance]]></category>
		<category><![CDATA[Bacterial interactions]]></category>
		<category><![CDATA[Bacterial movement]]></category>
		<category><![CDATA[Bacterial multicellularity]]></category>
		<category><![CDATA[Plants]]></category>
		<category><![CDATA[Toxins]]></category>
		<guid isPermaLink="false">https://sarahs-world.blog/?p=3906</guid>

					<description><![CDATA[<p>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.</p>
<p>The post <a href="https://sarahs-world.blog/antibiotics-produced-by-bacteria/">Bacteria use antibiotics to kill their foes and protect others</a> appeared first on <a href="https://sarahs-world.blog">Bacterialworld</a>.<br />
<a href="https://sarahs-world.blog">Bacterialworld - A blog about bacteria: from scientific studies to vivid stories about the fascinating bacterial world</a></p>
]]></description>
										<content:encoded><![CDATA[
<p class="wp-block-paragraph">Antibiotics &#8211; we use them to kill harmful bacteria or fungi when we&#8217;re sick. Yet, antibiotics are actually produced by bacteria and fungi in the first place.</p>



<p class="wp-block-paragraph">But what do bacteria and fungi use antibiotics for? Why do they produce them? And what are the advantages of microbes having antibiotics as molecular weapons?</p>



<h2 class="wp-block-heading">What are antibiotics?</h2>



<p class="wp-block-paragraph">The father of antibiotics, Selman Waksman, first used the word <a href="https://sarahs-world.blog/tag/antibiotics/" target="_blank" rel="noreferrer noopener"><em>antibiotics</em> </a>for any small molecule made by a microbe that can inhibit the growth of other microbes.</p>



<p class="wp-block-paragraph">So, microbes &#8211; especially bacteria and fungi &#8211; use antibiotics to <a href="https://sarahs-world.blog/category/bacterial-wars/" target="_blank" rel="noreferrer noopener">kill other microbes</a>. These other microbes can be bacteria, fungi or bigger organisms. Not <a href="https://sarahs-world.blog/tag/virus/" target="_blank" rel="noreferrer noopener">viruses </a>though!!!</p>



<p class="wp-block-paragraph"><a href="https://sarahs-world.blog/difference-between-bacteria-viruses/" target="_blank" rel="noreferrer noopener">Why not viruses</a>?</p>



<p class="wp-block-paragraph">Because antibiotics bind and inhibit cellular machines in living organisms. These molecules often bind to so-called targets. Antibiotic targets can be proteins or enzymes that make for example the cell wall, other proteins or components of the respiration complex.</p>



<p class="wp-block-paragraph">These proteins are generally essential. So, when antibiotics inhibit the proteins, the cells are missing these essential functions. And without them, they cannot survive and die.</p>



<p class="wp-block-paragraph">Hence, like other <a href="https://sarahs-world.blog/the-bacterial-armoury/">bacterial toxins</a>, antibiotics are lethal.</p>



<p class="wp-block-paragraph">Interestingly though, bacteria and fungi make antibiotics <a href="https://dx.doi.org/10.1016%2Fj.cub.2009.04.001" target="_blank" rel="noreferrer noopener">from simple building blocks</a>. These are present in every cell and can be amino acids, lipids or even sugars.</p>



<p class="wp-block-paragraph">But instead of using these building blocks for their normal functions, microbes link them together in different ways. With this, they create new &#8211; and fancier &#8211; molecules that barely resemble the original blocks.</p>



<div class="wp-block-image"><figure class="aligncenter size-full is-resized"><img loading="lazy" decoding="async" src="https://sarahs-world.blog/wp-content/uploads/Structures-common-antibiotics.jpg" alt="Molecular structures of different antibiotics from different classes." class="wp-image-3908" width="755" height="563" srcset="https://sarahs-world.blog/wp-content/uploads/Structures-common-antibiotics.jpg 997w, https://sarahs-world.blog/wp-content/uploads/Structures-common-antibiotics-300x224.jpg 300w, https://sarahs-world.blog/wp-content/uploads/Structures-common-antibiotics-768x574.jpg 768w" sizes="(max-width: 755px) 100vw, 755px" /><figcaption>Different examples of antibiotic molecules.</figcaption></figure></div>



<p class="wp-block-paragraph">Then, they transport these antibiotics to the outside or <a href="https://sarahs-world.blog/bacteria-firing-toxic-bubbles/">send them off in outer membrane vesicles</a>. When the antibiotic hits another microbe, there are two possibilities: either the microbe is resistant to the activity of the antibiotic or it dies from it.</p>



<p class="wp-block-paragraph">But what about the microbe that produces the antibiotic? Is it resistant to the antibiotic itself?</p>



<h2 class="wp-block-heading">Why are microbes that produce antibiotics not get killed?</h2>



<p class="wp-block-paragraph">Since antibiotics are meant to KILL other microbes, then why do producing microbes not get killed by their own antibiotics? The answer is self-protection!</p>



<p class="wp-block-paragraph">Whenever bacteria or fungi produce antibiotics, they always also produce some sort of self-protective means. Just as when <a href="https://sarahs-world.blog/tag/toxins/" target="_blank" rel="noreferrer noopener">bacteria produce other toxins</a>, they always need to make sure <a href="https://dx.doi.org/10.1016%2Fj.jmb.2019.06.033" target="_blank" rel="noreferrer noopener">they are not killed by their own weapons</a>.</p>



<p class="wp-block-paragraph">These self-protectors usually keep the antibiotic in an inactive state. For example, they completely surround the antibiotic molecule so that it cannot bind to its usual target within the cell. Another strategy is to add a small molecule to the antibiotic &#8211; again to keep it from binding to its target.</p>



<p class="wp-block-paragraph">Then, when the microbe is ready to transport the antibiotic outside of the cell, it takes the self-protection off the antibiotic. This releases only the toxic part &#8211; the antibiotic itself &#8211; into the surrounding.</p>



<div class="wp-block-image"><figure class="aligncenter size-large is-resized"><img loading="lazy" decoding="async" src="https://sarahs-world.blog/wp-content/uploads/IMG-20191124-WA0003-1024x777.jpg" alt="Bacterial toxins and antibiotics chew up essential components of a bacterial cell. They can degrade, DNA or RNA, the bacterial cell envelope or essential molecules or form pores in the bacterial cell envelope. If a bacterium has the cognate immunity, it is safe from the toxin's actions." class="wp-image-1198" width="538" height="408" srcset="https://sarahs-world.blog/wp-content/uploads/IMG-20191124-WA0003-1024x777.jpg 1024w, https://sarahs-world.blog/wp-content/uploads/IMG-20191124-WA0003-300x228.jpg 300w, https://sarahs-world.blog/wp-content/uploads/IMG-20191124-WA0003-768x583.jpg 768w, https://sarahs-world.blog/wp-content/uploads/IMG-20191124-WA0003-1536x1166.jpg 1536w, https://sarahs-world.blog/wp-content/uploads/IMG-20191124-WA0003.jpg 1217w" sizes="(max-width: 538px) 100vw, 538px" /><figcaption>Bacteria need to protect themselves from antibiotics. By <a href="https://sarahs-world.blog/tag/sciart">Noémie Matthey.</a></figcaption></figure></div>



<p class="wp-block-paragraph">Note, however, that these self-protection mechanisms are not antibiotic resistance mechanisms. Self-protection mechanisms are meant to inactive antibiotics only temporarily. Hence, these mechanisms are reversible. The antibiotic can still become active and thus toxic.</p>



<p class="wp-block-paragraph"><a href="https://sarahs-world.blog/about-antimicrobial-resistance-and-their-problems/">Resistance mechanisms, on the other hand, are meant to inactive antibiotics permanently</a>. Hence, these mechanisms are irreversible. Since this usually completely destroys the antibiotic, it cannot become active anymore.</p>



<p class="wp-block-paragraph">But what triggers microbes and especially bacteria to produce antibiotics? How do antibiotics help the producing cell in their daily circumstances?</p>



<h2 class="wp-block-heading">Why do bacteria produce antibiotics?</h2>



<p class="wp-block-paragraph">To answer this question, we need to look at where the bacteria live that make antibiotics. And<a href="https://doi.org/10.1093/femsre/fux005" target="_blank" rel="noreferrer noopener"> two-thirds of the known antibiotics are made by bacteria from the Actinobacteria family</a>. Within this family, <em>Streptomyces </em>is the best-known member that produces half of all known antibiotics.</p>



<p class="wp-block-paragraph">Another example is bacteria from the <em>Myxococcus</em> family. So, where do <em>Streptomyces</em> and <em>Myxococcus</em> bacteria live? Interestingly, these bacteria call the soil their home.</p>



<p class="wp-block-paragraph">And in the soil, they often confront lots of friends and foes. And they need to constantly <a href="https://sarahs-world.blog/category/bacterial-wars/">fight for their own survival</a>.</p>



<p class="wp-block-paragraph"><a href="https://sarahs-world.blog/multicellular-organisms/#Myxobacteria" target="_blank" rel="noreferrer noopener"><em>Myxococcus</em> is known as a wolf-pack predator</a> because it kills its prey in massive attacks. Colonies of <em>Myxococcous</em> roll over their prey, secrete antibiotics and thus kill them and feed on them.</p>



<p class="wp-block-paragraph"><em>Streptomyces</em>, on the other hand, uses its antibiotics a bit more civil.</p>



<p class="wp-block-paragraph">To move in the environment, <a href="https://sarahs-world.blog/multicellular-organisms/#Streptomyces"><em>Streptomyces</em> bacteria grow as long filaments</a> throughout the soil. They build long chains and branch out into the soil as<a href="https://sarahs-world.blog/tag/bacterial-multicellularity/" target="_blank" rel="noreferrer noopener"> multicellular organisms</a>. These branches are filled with <em>Streptomyces</em> cells but also <a href="https://sarahs-world.blog/bacterial-sporulation/">spores </a>so that the bacteria can extend to new places.</p>



<div class="wp-block-image"><figure class="aligncenter size-large is-resized"><img loading="lazy" decoding="async" src="https://sarahs-world.blog/wp-content/uploads/S_streptomyces_adults-791x1024.jpg" alt="Sciart of how Streptomyces bacteria produce antibiotics and throw them at bacterial foes." class="wp-image-3912" width="562" height="728" srcset="https://sarahs-world.blog/wp-content/uploads/S_streptomyces_adults-791x1024.jpg 791w, https://sarahs-world.blog/wp-content/uploads/S_streptomyces_adults-232x300.jpg 232w, https://sarahs-world.blog/wp-content/uploads/S_streptomyces_adults-768x994.jpg 768w, https://sarahs-world.blog/wp-content/uploads/S_streptomyces_adults.jpg 924w" sizes="(max-width: 562px) 100vw, 562px" /><figcaption> Antibiotics produced by <em>Streptomyces</em> bacteria. By<a href="https://sarahs-world.blog/tag/sciart"> Noémie Matthey.</a></figcaption></figure></div>



<p class="wp-block-paragraph">When the bacteria hit a period of bad weather or don&#8217;t find much food, they release their spores as a survival strategy. Plus, they start releasing nutrients for the spores. But these nutrients also attract other organisms like bacteria.</p>



<p class="wp-block-paragraph">Hence, at the same time, <em>Streptomyces</em> produces a huge amount of antibiotics to fend off these putative food-stealers. Like this, <em>Streptomyces</em> makes sure their spores are safe and can survive in their new homes for a while.</p>



<h2 class="wp-block-heading">How do antibiotics produced by bacteria help others?</h2>



<p class="wp-block-paragraph">Like <em>Streptomyces</em>, lots of bacteria use antibiotics to fight off predators. This assures their own survival and that of their species.</p>



<p class="wp-block-paragraph">Yet, more and more research finds that bacteria not only kill other species with antibiotics so they can survive. The killing also benefits their hosts.</p>



<p class="wp-block-paragraph">For example, the bacterium <a href="https://sarahs-world.blog/bacteria-colourful-antibiotics/"><em>Janthinobacterium lividum </em>lives on frogs where it produces the antibiotic violacein</a>. This antibiotic kills fungi so that the bacterium protects the frog from deadly fungal infections.</p>



<div class="wp-block-image"><figure class="aligncenter size-large is-resized"><a href="https://sarahs-world.blog/bacteria-colourful-antibiotics/"><img loading="lazy" decoding="async" src="https://sarahs-world.blog/wp-content/uploads/J_Janthinobacter_lividum2-1-921x1024.jpg" alt="Colourful schematic of  Janthinobacterium lividum that lives on frogs where it produces the antibiotic violacein to protect the animal from deadly fungi." class="wp-image-3810" width="461" height="512" srcset="https://sarahs-world.blog/wp-content/uploads/J_Janthinobacter_lividum2-1-921x1024.jpg 921w, https://sarahs-world.blog/wp-content/uploads/J_Janthinobacter_lividum2-1-270x300.jpg 270w, https://sarahs-world.blog/wp-content/uploads/J_Janthinobacter_lividum2-1-768x854.jpg 768w, https://sarahs-world.blog/wp-content/uploads/J_Janthinobacter_lividum2-1.jpg 924w" sizes="(max-width: 461px) 100vw, 461px" /></a><figcaption>Antibiotics produced by bacteria to kill deadly fungi. By <a href="https://sarahs-world.blog/tag/sciart/" target="_blank" rel="noreferrer noopener">Noémie Matthey</a>.</figcaption></figure></div>



<p class="wp-block-paragraph">Also, a bacterium that lives in our noses is the harmless <em>Staphylococcus lugdunensis</em>. This bacterium produces the antibiotic lugdunin. That <a href="https://doi.org/10.1038/nature18634" target="_blank" rel="noreferrer noopener">inhibits the harmful <em>Staphylococcus aureus</em> </a>from settling down in our noses. Now, scientists look into how we could use the harmless <em>Staphylococcus lugdunensis</em> to protect us from infections.</p>



<p class="wp-block-paragraph">Another example of microbes that produce antibiotics to help others is the three-member association of ants, <em>Streptomyces</em> and a fungus. Several species of ants grow fungi for food. They feed their fungi with fresh plants and let them grow in special underground gardens.</p>



<p class="wp-block-paragraph">To not contaminate these fungal gardens, ants carry symbiotic <em>Streptomyces</em> that produce antibiotics. Like this, the antibiotics kill other microbes and keep the fungal gardens free of harmful intruders. As a thank you, the ants feed the <em>Streptomyces</em> and give them a place to live.</p>



<h2 class="wp-block-heading">About antibiotic-producing microbes</h2>



<p class="wp-block-paragraph">So, just as we use antibiotics to kill harmful bacteria and fungi, antibiotic-producing microbes do the same. They want to fight off predators and assure their own survival.</p>



<p class="wp-block-paragraph">When you think about it: we use their own killer weapons against them. Poor microbes!</p>
<p>The post <a href="https://sarahs-world.blog/antibiotics-produced-by-bacteria/">Bacteria use antibiotics to kill their foes and protect others</a> appeared first on <a href="https://sarahs-world.blog">Bacterialworld</a>.<br />
<a href="https://sarahs-world.blog">Bacterialworld - A blog about bacteria: from scientific studies to vivid stories about the fascinating bacterial world</a></p>
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		<title>Bacteria produce colourful antibiotics to protect frogs</title>
		<link>https://sarahs-world.blog/bacteria-colourful-antibiotics/</link>
					<comments>https://sarahs-world.blog/bacteria-colourful-antibiotics/#respond</comments>
		
		<dc:creator><![CDATA[Sarah]]></dc:creator>
		<pubDate>Sun, 28 Mar 2021 09:23:00 +0000</pubDate>
				<category><![CDATA[The microbial world]]></category>
		<category><![CDATA[Animals]]></category>
		<category><![CDATA[Antibiotics]]></category>
		<category><![CDATA[Bacterial interactions]]></category>
		<category><![CDATA[Fungi]]></category>
		<category><![CDATA[Microbial communities]]></category>
		<category><![CDATA[Toxins]]></category>
		<guid isPermaLink="false">https://sarahs-world.blog/?p=3155</guid>

					<description><![CDATA[<p>A deadly fungus kills many exotic amphibians. Luckily, some bacteria antibiotics to kill the fungal intruder and thus protect the animal. With this colourful strategy, the right microbial community might even save whole species from extinction.</p>
<p>The post <a href="https://sarahs-world.blog/bacteria-colourful-antibiotics/">Bacteria produce colourful antibiotics to protect frogs</a> appeared first on <a href="https://sarahs-world.blog">Bacterialworld</a>.<br />
<a href="https://sarahs-world.blog">Bacterialworld - A blog about bacteria: from scientific studies to vivid stories about the fascinating bacterial world</a></p>
]]></description>
										<content:encoded><![CDATA[
<p class="wp-block-paragraph"><a href="https://sarahs-world.blog/tag/microbial-communities/">Microbial communities</a> grow everywhere and on almost any host, be it <a href="https://sarahs-world.blog/tag/human-body/">humans</a>, plants or <a href="https://sarahs-world.blog/tag/animals/">animals</a>.</p>



<p class="wp-block-paragraph">Some microbes come to make their hosts sick. Other microbes are there to help and protect them.</p>



<p class="wp-block-paragraph">This is a story of both types of microbes and an unusual host: amphibians.</p>



<p class="wp-block-paragraph">Yes, also frogs and salamanders and other amphibians carry microbes on their skins.</p>



<p class="wp-block-paragraph">And some of these microbes mean to kill the animals. But, luckily, the animals are protected by helpful bacteria that produce colourful antibiotics.</p>



<p class="wp-block-paragraph">Read on to find out how bacteria and <a href="https://sarahs-world.blog/tag/fungi/">fungi </a>do not get along on the skin of amphibians. We will also explore how bacteria protect amphibians from extinction.</p>



<h2 class="wp-block-heading" id="about-fungi-that-infect-the-skins-of-their-hosts">About fungi that infect the skins of their hosts</h2>



<p class="wp-block-paragraph">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.</p>



<p class="wp-block-paragraph">The bad guys? The<a href="https://doi.org/10.1655/0018-0831-76.2.167" target="_blank" rel="noreferrer noopener"> two fungal species <em>Batrachochytrium dendrobatidis</em> and <em>Batrachochytrium salamandrivorans</em></a><em>. </em>They cause a deadly skin disease on frogs and other exotic amphibians.</p>



<p class="wp-block-paragraph">Similarly, the <a href="https://doi.org/10.1111/ijd.12217" target="_blank" rel="noreferrer noopener">fungus <em>Trichophyton rubrum</em> can infect our skin and hair</a>. This pathogen causes a disease that you may know as ringworm or athlete&#8217;s foot. Typically, you can see such a fungal infection as a red, itchy and circular rash.</p>



<p class="wp-block-paragraph">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.</p>



<h2 class="wp-block-heading" id="bacteria-produce-colourful-antibiotics">Bacteria produce colourful antibiotics&#8230;</h2>



<p class="wp-block-paragraph">Few microbes can grow and thrive on the gloomy skin of frogs or salamanders. One such microbe is the bacterium <em>Janthinobacterium lividum</em>.</p>



<figure class="wp-block-image aligncenter size-large is-resized"><img loading="lazy" decoding="async" src="https://sarahs-world.blog/wp-content/uploads/J_janthinobacterium_lividum-791x1024.jpg" alt="Janthinobacterium lividum" class="wp-image-4671" style="width:421px;height:545px" width="421" height="545" srcset="https://sarahs-world.blog/wp-content/uploads/J_janthinobacterium_lividum-791x1024.jpg 791w, https://sarahs-world.blog/wp-content/uploads/J_janthinobacterium_lividum-232x300.jpg 232w, https://sarahs-world.blog/wp-content/uploads/J_janthinobacterium_lividum-768x994.jpg 768w, https://sarahs-world.blog/wp-content/uploads/J_janthinobacterium_lividum.jpg 924w" sizes="(max-width: 421px) 100vw, 421px" /><figcaption class="wp-element-caption"><em>Janthinobacterium lividum</em> produces colourful antibiotics.</figcaption></figure>



<div class="wp-block-buttons is-content-justification-center is-layout-flex wp-container-core-buttons-is-layout-3e41869c wp-block-buttons-is-layout-flex">
<div class="wp-block-button has-custom-font-size is-style-fill has-medium-font-size"><a class="wp-block-button__link has-vivid-purple-background-color has-text-color has-background has-text-align-center wp-element-button" href="https://sarahs-world.blog/coloured-bacteria-from-a-to-z/" style="color:#f9d46d" target="_blank" rel="noreferrer noopener"><strong>Learn more about <em>Janthinobacterium lividum</em> in our colouring book.</strong></a></div>
</div>



<p class="wp-block-paragraph"></p>



<p class="wp-block-paragraph">This bacterium has an interesting taste for food. It eats the <a href="https://doi.org/10.1128/AEM.01294-09" target="_blank" rel="noreferrer noopener">released skin when the amphibians shed their skin</a>. And it also really likes the mucus on the surface of the amphibians.</p>



<p class="wp-block-paragraph">As a thank you for the good meal, the bacteria help the amphibians in the fight against the deadly fungus.</p>



<p class="wp-block-paragraph">How?</p>



<p class="wp-block-paragraph">Generally, <a href="https://sarahs-world.blog/antibiotics-produced-by-bacteria/">bacteria produce antibiotics</a> to get rid of annoying competitors. For example, <a href="https://sarahs-world.blog/bacteria-firing-toxic-bubbles/"><em>Janthinobacterium</em> produces the antibiotic violacein,</a> which has a dark violet colour. This antibiotic also kills the fungi that make the frogs sick. </p>



<p class="wp-block-paragraph">It is still unclear to researchers, how <em>Janthinobacterium</em> transports the antibiotic to the fungus. We already know that the<a href="https://sarahs-world.blog/bacteria-firing-toxic-bubbles/"> bacterium <em>Chromobacterium violaceum</em> produces membrane bubbles </a>filled with violacein. And that it throws these purple bubbles at its competitors. So, one idea is that <em>Janthinobacterium</em> uses a similar strategy and throws violacein bubbles at the fungus.</p>



<p class="wp-block-paragraph">Also, when <em>Janthinobacterium</em> grows on the skin of frogs, <a href="https://doi.org/10.1007/s00248-019-01385-9" target="_blank" rel="noreferrer noopener">it triggers the frog to produce more anti-fungal molecules</a>. These molecules kill the fungus and other pathogenic bacteria that are dangerous to the frog.</p>



<h2 class="wp-block-heading" id="and-protect-them-from-deadly-fungi">&#8230; and protect them from deadly fungi</h2>



<p class="wp-block-paragraph"><em>Janthinobacterium</em> is not the only bacterium that produces colourful antibiotics to protect its host.</p>



<p class="wp-block-paragraph">You might have seen red dots in your shower every once in a while. These come from the bacterium <em>Serratia marcescens</em> which makes a red antibiotic. Interestingly, this bacterium can <a href="https://doi.org/10.1007/s00248-017-1095-7" target="_blank" rel="noreferrer noopener">also live on the skins of amphibians. And here, the red antibiotic also protects from deadly fung</a>i.</p>



<figure class="wp-block-image aligncenter size-large is-resized"><img loading="lazy" decoding="async" src="https://sarahs-world.blog/wp-content/uploads/J_Janthinobacter_lividum2-1-921x1024.jpg" alt="The bacterium Janthinobacterium lividum lives on frogs. Here, the bacteria produce colourful antibiotics to protects the frogs from pathogenic fungal species." class="wp-image-3810" style="width:618px;height:686px" width="618" height="686" srcset="https://sarahs-world.blog/wp-content/uploads/J_Janthinobacter_lividum2-1-921x1024.jpg 921w, https://sarahs-world.blog/wp-content/uploads/J_Janthinobacter_lividum2-1-270x300.jpg 270w, https://sarahs-world.blog/wp-content/uploads/J_Janthinobacter_lividum2-1-768x854.jpg 768w, https://sarahs-world.blog/wp-content/uploads/J_Janthinobacter_lividum2-1.jpg 924w" sizes="(max-width: 618px) 100vw, 618px" /><figcaption class="wp-element-caption">Bacteria produce colourful antibiotics to protect fungi. By <a href="https://sarahs-world.blog/tag/sciart/">Noémie Matthey</a>. </figcaption></figure>



<p class="wp-block-paragraph">Other bacteria, like allrounder <em>Pseudomonas</em>, also live on the skins of some amphibians. And these bacteria produce many different antifungals to protect their hosts.</p>



<p class="wp-block-paragraph">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 &#8211; sounds like a bacterial festival to celebrate their hosts?</p>



<h2 class="wp-block-heading" id="colourful-bacterial-antibiotics-to-save-amphibians">Colourful bacterial antibiotics to save amphibians?</h2>



<p class="wp-block-paragraph">Now, researchers are trying to save amphibians from the deadly fungus with a process called bioaugmentation. With this strategy, researchers <a href="http://dx.doi.org/10.1128/AEM.04147-15" target="_blank" rel="noreferrer noopener">introduce special bacterial communities to the environment.</a> And they hope that the bacteria will jump over to different amphibians.</p>



<p class="wp-block-paragraph">Bacteria like <em>Janthinobacterium</em> then hopefully establish stable communities on the skins of amphibians and protect them from fungal infections. And let&#8217;s hope that these bacterial parties will save more frog species from extinction!</p>
<p>The post <a href="https://sarahs-world.blog/bacteria-colourful-antibiotics/">Bacteria produce colourful antibiotics to protect frogs</a> appeared first on <a href="https://sarahs-world.blog">Bacterialworld</a>.<br />
<a href="https://sarahs-world.blog">Bacterialworld - A blog about bacteria: from scientific studies to vivid stories about the fascinating bacterial world</a></p>
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