Scientists find 'first-ever animal' that doesn't need oxygen to live

A jellyfish-like parasite is the first ever animal discovered that lives without oxygen  and it could shed light on where to look for life on alien worlds.

Researchers at Tel Aviv University in Israel say the jellyfish-like parasite spends its life clinging to the inside of a salmon in a low to zero oxygen environment.

The organism doesn’t have a mitochondrial genome – that is the system that breaks down oxygen that multicellular organisms use to power their cells and breathe.

Henneguya salminicola isn’t new, it is a common salmon parasite and part of the same family as corals and jellyfish – but its genome has only just been mapped.

The team don’t know exactly how it survives without oxygen but suggest it could be leeching energy producing chemicals from the salmon. 

Henneguya Slminicola isn’t new, it is a common salmon parasite and part of the same family as corals and jellyfish – but its genome has only just been mapped

The creature lives within the stomach of a salmon but it is not harmful to the fish and can stay with it for its entire life cycle, study authors confirmed.

After the genome was sequenced it was studied under a fluorescence microscope in an attempt to better understand how it lives with no oxygen.

This tagged various genes within the genome and that is how they found it had no mitochondrial DNA or even the genes to produce it.

‘Our discovery confirms that adaptation to an anaerobic environment is not unique to single-celled eukaryotes, but has also evolved in a multicellular, parasitic animal,’ the researchers wrote in their paper.

‘Hence, H. salminicola provides an opportunity for understanding the evolutionary transition from an aerobic to an exclusive anaerobic metabolism.’

Other simpler species are able to survive without oxygen – anaerobic metabolic mechanisms – but this is the first form of complex life. 

Species that have adapted to anaerobic processes did so to survive in low-oxygen environments and replaced mitochondrial systems with anaerobic ones.  

The creature lives within a salmon but it is not harmful to the fish and can stay with it for its entire life cycle, study authors confirmed

Researchers believe it may have devolved from a more advanced free living jellyfish ancestor over millions of years. 

It has lost most of the original jellyfish genome but retained some complex structures – including stinging cells that it uses to cling on to the salmon.

This isn’t the first creature discovered that can go extended periods without oxygen – but is the first complex organism that doesn’t require it at all. 

‘Loss of superfluous genes likely conveys an evolutionary advantage, as it has been shown that the bioenergetic cost of a gene is higher in small genomes,’ the authors wrote in their paper.

Researchers believe it may have devolved from a more advanced free living jellyfish ancestor over millions of years

The team suggest the change may have evolved due to a lack of available oxygen inside the host species.

‘Our discovery shows that aerobic respiration, one of the most important metabolic pathways, is not ubiquitous among animals.’ 

The discovery could change the search for life on other worlds as it means life could survive in far more diverse environments.

This could include on Mars and even under the icy surfaces of the Moons of Saturn, Jupiter and Neptune. 

As well as potentially pointing towards life on alien worlds it could help fisheries fight against the parasite – which leaves an unsightly cyst on the skin of the host fish.

It isn’t harmful to humans but does make the fish harder to sell, according to fishery experts. 

The research has been published in the journal PNAS.

WHAT ARE PROKARYOTES AND EUKARYOTES AND HOW DO THEY DIFFER?

Both Eukaryotes and Prokaryotes are cells – they are the fundamental building block that life is built from but they are very different.

Prokaryotes

Prokaryotes are simple celled organisms including bacteria and archaea without a distinct nucleus.

A stock image showing prokaryotes. They were on Earth for two billion years before more complex life evolved

They are microscopic and likely the first type of life, evolving about 4 billion years ago on Earth.

It’s contents – the DNA, proteins and metabolites are all contained in a single cell membrane, rather than in separate compartments. 

The name comes from the Greek for ‘before nucleus’ and were the only life on Earth for more than two billions years. 

They usually reproduce through a process called binary fission where a single cell divides into two identical daughter cells.

Eukaryotes

These are organisms made of more complex cells and form the building blocks of everything from algae and plants to humans and mushrooms.

Single-celled flagellate Eukaryote Euglena under the microscope. They can reproduce both asexually through mitosis and sexually through meiosis and gamete fusion

They are also microscopic but can be multicellular or single celled organisms.

They evolved on Earth about 1.5 billion years ago and contain a nucleus, separate compartments and mitochondria.

The mitochondria is the powerhouse of a cell and crucial for respiration and energy production.

The name comes from the Greek for ‘true nucleus’. 

They can reproduce both asexually through mitosis and sexually through meiosis and gamete fusion.