Viruses Prompt Bacteria To Produce Pink Pigments

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Plants use certain color pigments in order to convert light into energy by way of photosynthesis. They allow plants to gather light energy. This also works in a similar way for microbes, for instance cyanobacteria.

The fact that a very large number of viruses are able to contribute towards pigment production has now been demonstrated by biologists from the University of Kaiserslautern with a colleague from Israel. The viruses introduce genetic material into the bacteria which then allows them to produce the pink-colored pigments.

Cyanobacteria (also known as blue-green algae) and other oceanic bacteria are able to convert carbon dioxide and water into carbohydrates and oxygen with the help of sunlight, just like plants. Says microbiology Professor Nicole Frankenberg-Dinkel from the University of Kaiserslautern:

“They use light-harvesting complexes in order to capture the energy from the light. These consist of proteins and colour pigments."

The latter are also responsible for the characteristic coloration. In the case of plants, for example, this is the green pigment ‘chlorophyll’, in cyanobacteria this is the blue pigment ‘phycocyanobilin’ and the pink pigment ‘phycoerythrobilin’.

“The synthesis of these pigments is already well understood,” the microbiologist adds. “So far researchers have only been able to demonstrate their presence in organisms which release oxygen through the process of photosynthesis."

In addition to this form of conventional photosynthesis performed by plants and cyanobacteria, there are also other variants that do not release any oxygen.

Phycoerythrobilin Synthesis

The biologists at Kaiserslautern sought to investigate, together with their Israeli research colleague and bioinformatician Oded Béjà (from the Technion-Israel Institute of Technology), the extent to which pigment synthesis is prevalent in certain marine regions. The biosynthesis of pink pigment ‘phycoerythrobilin’ was the focus of their work.

Phycoerythrobilin is a red phycobilin, i.e. an open tetrapyrrole chromophore found in cyanobacteria and in the chloroplasts of red algae, glaucophytes and some cryptomonads.

“The genetic information for the synthesis of the pink pigment is widespread throughout all the world’s oceans,"

says the professor. This is where the researchers made a notable discovery: this information is wide spread in viruses.

“The viruses carry genetic information which can be used to produce the pink-coloured pigments,” Frankenberg-Dinkel explains.

The viruses introduce this genetic information into bacterial cells which enable them to synthesise the pink pigment.

“What is new is that we are able to use bioinformatic analyses to determine the type of viruses which carry this genetic information”, Frankenberg-Dinkel continues. “We were able to show that the viruses most likely affect those microbes for which we do not yet know what purpose the pigment serves."

For her study, Frankenberg-Dinkel and her team analysed datasets obtained from metagenome databases.

“These contain all the genetic information of all the organisms we would usually extract during a field trip at sea, for example,” the researcher explains. “This technique allows us to gain a detailed insight into the ecosystem without having to investigate it on location."

Benjamin Ledermann et al.
New biosynthetic pathway for pink pigments from uncultured oceanic viruses
Environmental Microbiology (2016). DOI: 10.1111/1462-2920.13290