University of Copenhagen: Warring genetic parasites could lead to new defenses against dangerous bacteria
Plasmids – a type of autonomous genetic parasites in bacteria – are armed with a previously unknown arsenal of CRISPR-Cas “gene tools” that are frequently deployed to combat other plasmids, according to research from the University of Copenhagen. Because plasmids spread antibiotic resistance and harmful properties among bacteria, the research could lead to new defenses against harmful bacteria.
A plasmid is a small ring-shaped DNA molecule, a so-called mobile genetic element, found in bacteria and certain other types of microorganisms.
CRISPR-Cas has become somewhat of a superstar over the past decade as a gene editing tool with revolutionary potential, especially in the health sciences. Originally known as an immune defense in bacteria, naturally occurring CRISPR-Cas has proven more diverse and versatile in nature than scientific researchers once believed. Now, a group of researchers at the University of Copenhagen’s Department of Biology has investigated the prevalence of CRISPR-Cas systems in plasmids.
What does CRISPR-Cas mean?
DNA fragments (CRISPR) and Cas protein scissors (e.g., Cas9) can locate specific DNA sequences and cut them.
It is predicted that CRISPR-Cas will play a revolutionary role as a gene editing tool, not least in the health sciences, for the treatment of genetic disorders, among other things.
CRISPR systems were originally seen as an immune system for bacteria, particularly against viruses. However, many researchers now see CRISPR-Cas as a “Guns for Hire” tool that can be deployed for a multitude of purposes, by many different actors, including bacteria, plasmids – and humans.
The researchers examined more than 30,000 complete plasmid genomes and found CRISPR-Cas in about three percent of them – a high proportion even when compared to bacteria. They also found various representatives of as many as five out of the six known types of CRISPR-Cas in the plasmid genomes studied. The results demonstrate that CRISPR-Cas systems are both widespread and diverse in plasmids and, interestingly, that the vast majority of them target other plasmids.
“In part, this is exciting because it supports a more recent understanding of plasmids as having a higher degree of autonomy from their host cells, typically bacteria. But also, because in the long run, it can open up pathways to combat virulence and resistance in bacteria, which plasmids help spread,” explains Rafael Pinilla-Redondo, who is one of the study’s main researchers and based at the University of Copenhagen’s Department of Biology.
CRISPR acts like a genomic GPS, where a stored memory of foreign DNA fragments can be used to locate a target for Cas proteins, the “genetic scissors”. In the majority of the study’s findings, it was DNA from other plasmids that was discovered in the immune memory of the CRISPR-Cas systems, – i.e. placed in the crosshairs.
Part of a paradigm shift
According to the researchers, this suggests a struggle for resources among plasmids, where plasmids serve their own interests by working actively to prevent other plasmids from accessing the host bacterium in which they reside. In this battle, they use CRISPR as a weapon.
What is a plasmid?
A plasmid is a small ring-shaped DNA molecule, a so-called mobile genetic element, found in bacteria and certain other types of microorganisms.
It is reminiscent of viruses, since both are parasites within cells. Plasmids can reproduce independently of the host cell and often provide benefits to the host cell.
Among other things, they can give or transfer genetic properties to a bacterium, such as by making it antibiotic-resistant or pathogenic, in a process known as horizontal gene transfer.
Plasmids have long been an important tool in molecular biology for, among other things, gene cloning and the introduction of genetic material into bacterial cells.
The researchers had the opportunity to simultaneously examine the host bacteria of the 30,000+ plasmid dataset for the same CRISPR-Cas sequences. The idea was to study whether the sequences found in plasmids mirrored the CRISPR contents in host cells, but this was generally not the case.
“Our findings suggest that plasmids have a high degree of autonomy from the bacteria in which they live. While plasmids depend on their host, they are also genetically independent entities that serve their own interests. Their different CRISPR-Cas content is a great example of this autonomy,” says Rafael Pinilla-Redondo.
The new research results will contribute to what the researchers consider a paradigm shift in microbiology.
In microbiology, gene flow or gene transfer refers to when genetic material moves between cells, mediated mobile genetic elements. While some mobile genetic elements are allowed to slip in, to the benefit of a cell, others are stopped because they are detrimental. The common understanding has long been that bacteria control gene flow.
The paradigm shift points to an understanding where bacteria actually play a far less important role influencing gene flow.
“What was once presumed to be bacteria fighting to protect themselves from genetic parasites, like viruses and plasmids, is far more complex. Perhaps, it should be better understood as the parasites fighting among themselves, for example, over which ones should be allowed to live behind a cow’s ear,” explains Rafael Pinilla-Redondo.
The possibility for new weapons against antibiotic resistance
The new knowledge about how plasmids use CRISPR may impact how we combat dangerous bacteria in the future. Plasmids are key to the spread of harmful genes between bacteria through what is known as horizontal gene transfer.
What is horizontal gene transfer?
Horizontal gene transfer is when one organism transfers genes to another organism that is not its own offspring.
To a great extent, the ability of bacteria to adapt to new environments and challenges depends on the supply of new genes in this way.
The phenomenon is responsible for the looming antibiotic resistance crisis, as bacteria rapidly develop resistance to antibiotics by acquiring resistant genes. It is very often mediated by plasmids, making plasmid proliferation a global public health problem.
The proliferation of genetic material is crucial for bacteria’s ability to adapt to new environments and challenges. From an antibiotic resistant bacterium, a plasmid can copy itself and transfer that property to surrounding bacteria as part of its own DNA.
As such, battles between plasmids can help researchers learn more about how to fight them too.
“By understanding how plasmids compete among themselves, we may be able to learn how to slow them down and thereby slow the spread of antibiotic resistance and virulent, harmful properties between bacteria,” says Søren Johannes Sørensen, a microbiology professor and co-author of the research article.
“In the long term, it’s possible that we will be able to make the strategies of plasmids our own and use them as tools. Without borrowing from nature, we would be quite limited. But if we can learn about the strengths and weaknesses of the plasmids from themselves, opportunities will arise,” he says.