From egg to embryo …
… how developing zebrafish keep RNA levels in check
Mature egg cells and early embryos do not generate their own RNA molecules – instead, they rely on stored maternal RNAs to synthesise their proteins. As the embryo develops, some of these RNAs become superfluous and need to be degraded. Researchers at the Research Institute of Molecular Pathology (IMP) pinpointed Ski7 as a regulator of normal RNA levels in early zebrafish embryos. Their findings were published in the journal “PLOS Genetics”.
At the beginning of an embryo’s development, all cellular processes are regulated by maternal products deposited in the egg, such as RNA molecules and proteins. As the embryo grows, some of these accumulated molecules become superfluous and need to be removed to ensure development continues normally. Although scientists have identified many molecular pathways that regulate RNA degradation in the embryo, some pieces of the puzzle are still missing to understand the full picture.
In yeast, two multiprotein complexes, called the exosome and ‘superkiller’ (Ski), work together to degrade unwanted RNA molecules. Historically, scientists assumed the Ski-exosome mechanism did not operate in animals as it does in yeast, because the key protein that mediates the interaction between the exosome and the Ski complex, Ski7, was nowhere to be found in animal genomes. However, some developmental stages in animals, such as the transition stage from an egg cell to an embryo, require major changes in RNA abundance and could make use of Ski7 or a similar protein to help the process.
“The Ski7 protein acts as an adaptor between the exosome and the Ski complex, and we hypothesised that it should be there for this system to work,” explains Luis Cabrera-Quio, a recent PhD graduate of the Pauli Lab. “Two recent studies pinpointed the well-hidden location of Ski7 in the mouse and human genomes – we are the first group to identify and characterize it in fish.”
In a new study published in “PLOS Genetics”, researchers at the IMP have located Ski7 in the zebrafish genome and measured its expression levels in zebrafish embryos. To understand its potential functions in development, the scientists used the CRISPR/Cas9 system to generate a mutant line of zebrafish that lacked the gene to produce Ski7. They then compared normal embryos to the mutant line to see what functions were impaired by the mutation.
Ski7, a regulator of RNA levels
“When we found that Ski7 was highly expressed in the mature eggs and early embryos of zebrafish, we realised it might play an important role in the oocyte-to-embryo transition. Generating mutant fish that couldn’t produce Ski7 was the logical next step to understand this protein’s function,” says Andrea Pauli, Group Leader at the IMP.
The first difference that the scientists noted was that a fraction of mutant embryos failed to develop altogether. However, those that completed their first cell division went on to grow normally and reached adulthood. This partial survival suggests that Ski7 may play an important – yet not always vital – role for healthy development. The main question remained: does Ski7 help regulating RNA degradation in zebrafish like it does in yeast?
When the team compared the gene expression patterns of normal and mutant embryos, they found that the absence of Ski7 led to thousands of genes being either overly expressed, or abnormally low. As a result, the abundance of specific RNAs and proteins in mutant embryos differed from their natural counterpart.
Stress resistance and Ski7
The next step was to investigate what mis-regulated genes normally do. The scientists surveyed the over- and underabundant RNAs in mutant fish embryos and found that many of them encoded for proteins that play a role in the response to reductive/oxidative stress. In yeast, lab-generated mutants that lack Ski7 tend to be less resistant to environmental stress. However, Quio and colleagues were in for surprising results with the zebrafish.
Although only a fraction of mutant embryos developed normally, the survivors had become more resistant to reductive stress than the normal, wildtype embryos. “That was really unexpected – it could be that Ski7 contributes to the dynamic regulation of the reduction/oxidation balance in early embryos. When it is absent, some embryos never develop, and those that do might compensate this lack of regulation with their overabundant maternal RNAs, producing proteins that enable the embryo to withstand reductive agents,” says Quio. This idea, however, remains to be tested.
Overall, Ski7’s basic role in degrading superfluous RNA molecules proves to be highly conserved, from unicellular organisms such as yeast to complex animals such as fish, mice, and humans. The study shows that Ski7 plays an important part in the normal development of egg cells and early embryos in the zebrafish by selectively regulating RNA levels.
About the IMP
The Research Institute of Molecular Pathology (IMP) in Vienna is a basic life science research institute largely sponsored by Boehringer Ingelheim. With over 200 scientists from 40 countries, the IMP is committed to scientific discovery of fundamental molecular and cellular mechanisms underlying complex biological phenomena. The IMP is part of the Vienna BioCenter, one of Europe’s most dynamic life science hubs with 1,850 employees from 70 countries in four research institutes, three universities and 35 biotech companies.
Wissenschaftliche Ansprechpartner:
Mehdi Khadraoui
T: +43 664 808 473 625
E: mehdi.khadraoui@imp.ac.at
Originalpublikation:
Cabrera-Quio, L. E., Schleiffer, A., Mechtler, K., Pauli, A.: “Zebrafish Ski7 tunes RNA levels during the oocyte-to-embryo transition”. PLOS Genetics, 4 March 2021, DOI: e1009390
Weitere Informationen:
https://journals.plos.org/plosgenetics/article?id=10.1371/journal.pgen.1009390
http://www.imp.ac.at
http://www.viennabiocenter.org
Media Contact
All latest news from the category: Life Sciences and Chemistry
Articles and reports from the Life Sciences and chemistry area deal with applied and basic research into modern biology, chemistry and human medicine.
Valuable information can be found on a range of life sciences fields including bacteriology, biochemistry, bionics, bioinformatics, biophysics, biotechnology, genetics, geobotany, human biology, marine biology, microbiology, molecular biology, cellular biology, zoology, bioinorganic chemistry, microchemistry and environmental chemistry.
Newest articles
Innovative 3D printed scaffolds offer new hope for bone healing
Researchers at the Institute for Bioengineering of Catalonia have developed novel 3D printed PLA-CaP scaffolds that promote blood vessel formation, ensuring better healing and regeneration of bone tissue. Bone is…
The surprising role of gut infection in Alzheimer’s disease
ASU- and Banner Alzheimer’s Institute-led study implicates link between a common virus and the disease, which travels from the gut to the brain and may be a target for antiviral…
Molecular gardening: New enzymes discovered for protein modification pruning
How deubiquitinases USP53 and USP54 cleave long polyubiquitin chains and how the former is linked to liver disease in children. Deubiquitinases (DUBs) are enzymes used by cells to trim protein…