Giant aquatic bacterium is a master of adaptation

November 19, 2020

The largest freshwater bacterium, Achromatium oxaliferum, is highly flexible in its requirements, as researchers led by the IGB have now discovered: It lives in places that differ extremely in environmental conditions such as hot springs and ice water. The bacterial strains from the different ecosystems do not differ in their gene content, but rather chose what to express. The adaptation is probably achieved by a process which is unique to these bacteria: only relevant genes are enriched in the genomes and transcribed, while others are archived in cell compartments.

Achromatium is special in many respects: It is 30,000 times larger than its "normal" counterparts that live in water and owing to its calcite deposits it is visible to the naked eye. It has several hundred chromosomes, which are most likely not identical. This makes Achromatium the only known bacterium with several different genomes.

The researchers have analyzed sequence data bases of sediments and show that Achromatium is universal. It is found in a broad range of environments: in shallow waters as well as in the ocean at a depth of 4000 metres. It can be found in hot springs and ice-cold water; in acidic and alkaline environments as well as in hypersaline waters.

Typically, such a wide range of environmental conditions would result in the establishment of new species, well-adapted to their specific environment. However, Achromatium defies this expectation. Though, equipped with equal functionality, the bacteria in the various ecosystems differ in their gene expression patterns by transcribing only relevant genes.

Compartments formed by folded cell membrane might serve as gene archives

"We suggest environmental adaptation in Achromatium occurs by increasing the copy number of relevant genes across the cell's hundreds of chromosomes. This is in stark contrast to other bacteria which eventually lose irrelevant genes. So the high number of genomes makes the versatility possible", explains Dr. Danny Ionescu, leader of the study from IGB.

Achromatium is full of calcium carbonate crystals that are located between the outer and cytoplasmic membranes. These crystals fold the cytoplasmic membrane forming pockets of cytoplasm which the researchers suggest to hold clusters of chromosomes. They hypothesize that these clusters enable Achromatium to "archive" genes of no immediate use.

No copy of the mother cell: each bacterium is unique

"The functional versatility of Achromatium and its genomic features contradict what we know for other bacteria, for example the concept of bacterial species and the driving forces of bacterial speciation. In Achromatium, mother and daughter cells are likely not identical and each cell is unique holding a multitude of genes, some of which are not essential for life in a particular habitat. Therefore, each cell keeps the potential to rapidly adapt to changing or new environmental conditions", concludes Professor Hans-Peter Grossart, co-author of the study and head of the aquatic microbial ecology group at IGB.

Forschungsverbund Berlin

Related Bacteria Articles from Brightsurf:

Siblings can also differ from one another in bacteria
A research team from the University of Tübingen and the German Center for Infection Research (DZIF) is investigating how pathogens influence the immune response of their host with genetic variation.

How bacteria fertilize soya
Soya and clover have their very own fertiliser factories in their roots, where bacteria manufacture ammonium, which is crucial for plant growth.

Bacteria might help other bacteria to tolerate antibiotics better
A new paper by the Dynamical Systems Biology lab at UPF shows that the response by bacteria to antibiotics may depend on other species of bacteria they live with, in such a way that some bacteria may make others more tolerant to antibiotics.

Two-faced bacteria
The gut microbiome, which is a collection of numerous beneficial bacteria species, is key to our overall well-being and good health.

Microcensus in bacteria
Bacillus subtilis can determine proportions of different groups within a mixed population.

Right beneath the skin we all have the same bacteria
In the dermis skin layer, the same bacteria are found across age and gender.

Bacteria must be 'stressed out' to divide
Bacterial cell division is controlled by both enzymatic activity and mechanical forces, which work together to control its timing and location, a new study from EPFL finds.

How bees live with bacteria
More than 90 percent of all bee species are not organized in colonies, but fight their way through life alone.

The bacteria building your baby
Australian researchers have laid to rest a longstanding controversy: is the womb sterile?

Hopping bacteria
Scientists have long known that key models of bacterial movement in real-world conditions are flawed.

Read More: Bacteria News and Bacteria Current Events is a participant in the Amazon Services LLC Associates Program, an affiliate advertising program designed to provide a means for sites to earn advertising fees by advertising and linking to