Deletion of Any Single Gene Provokes Mutations Elsewhere in the Genome

Johns Hopkins researchers report that the deletion of any single gene in yeast cells puts pressure on the organism’s genome to compensate, leading to a mutation in another gene. Their discovery, which is likely applicable to human genetics because of the way DNA is conserved across species, could have significant consequences for the way genetic analysis is done in cancer and other areas of research, they say.

Summarized in a report to be published on Nov. 21 in the journal Molecular Cell, the team's results add new evidence that genomes, the sum total of species' genes, are like supremely intricate machines, in that the removal of a single, tiny part stresses the whole mechanism and might cause another part to warp elsewhere to fill in for the missing part.

“The deletion of any given gene usually results in one, or sometimes two, specific genes being 'warped' in response,” says J. Marie Hardwick, Ph.D., the David Bodian Professor of Molecular Microbiology and Immunology at the Johns Hopkins Bloomberg School of Public Health and a professor of pharmacology and molecular sciences at the school of medicine. “Pairing the originally deleted gene with the gene that was secondarily mutated gave us a list of gene interactions that were largely unknown before.”

Hardwick says the findings call researchers to greater scrutiny in their genetic analyses because they could unwittingly attribute a phenomenon to a gene they mutated, when it is actually due to a secondary mutation.

“This work has the potential to transform the field of cancer genetics,” Hardwick says. “We had been thinking of cancer as progressing from an initial mutation in a tumor-suppressor gene, followed by additional mutations that help the cancer thrive. Our work provides hard evidence that a single one of those ‘additional mutations’ might come first and actively provoke the mutations seen in tumor-suppressor genes. We hope that our findings in yeast will help to identify these ‘first’ mutations in tumors.”

The beauty of working with yeast, Hardwick says, is that it is easy to delete, or “knock out,” any given gene. Her team started with a readily available collection of thousands of different yeast strains, each with a different gene knockout.

At their preferred temperature, each of these strains of yeast grows robustly even though they each have a different gene missing. Hardwick's team first asked a fundamental question: Within a given strain of yeast, does each cell have the same genetic sequence as the other cells, as had generally been presumed?

“We know, for example, that within a given tumor, different cells have different mutations or versions of a gene,” explains Hardwick. “So it seemed plausible that other cell populations would exhibit a similar genetic diversity.”

To test this idea, her team randomly chose 250 single-knockout strains from the thousands of strains in the collection. For each strain, they generated six sub-strains, each derived from a single yeast cell from the “parental batch.”

They then put each sub-strain through a “stress test” designed to detect sub-strains with behaviors that varied from the behavior of the parental batch. All of the sub-strains grew indistinguishably without stress, but when the temperature was gradually raised for only a few minutes, some sub-strains died because they could not handle the stress. When the Hardwick team examined their genes, they found that, in addition to the originally knocked-out gene, each of the sub-strains that faltered also had a mutation in another gene, leading the team to conclude that the cells in each strain of the single-gene knockouts do not all share the same genetic sequence.

They then tested all 5,000 of the original single-gene knockout strains to find sub-strains that could overgrow when given low-nutrient food — a trait that tumor cells often possess. This was another stress test designed to detect differences between the individual cells taken from the parental batches. They identified 749 such knockout strains and showed that their growth differences were often due to secondary mutations.

In total, the team’s evidence indicates that 77 percent of all the knockout strains have acquired one or two additional mutations that affect cell survival and/or excessive growth when food is scarce.

Hardwick believes that stressing yeast in other ways may lead to an even higher percentage of double-mutant strains. In fact, she said she believes that “essentially any gene, when mutated, has the power to alter other genes in the genome.” Deleting the first gene seems to cause a biological imbalance that is sufficient to provoke additional adaptive genetic changes, she explains.

Furthermore, in all of the strains that they examined, they found that the secondary mutations that appeared after a given knockout were always in the same one or two genes as in their earlier observations. Unexpectedly, Hardwick said, the altered growth of the sub-strains was usually due to the secondary mutations, not the original knockout, and many of those secondary mutations were in genes that are known to be cancer-causing in humans.

Other authors of the report include Xinchen Teng, Catherine Gilbert, Sarah Wheelan, Jef Boeke and Fernando Pineda of the Johns Hopkins University School of Medicine, and Margaret Dayhoff-Brannigan, Wen-Chih Cheng, Cierra Sing and Nicola Diny of the Johns Hopkins University Bloomberg School of Public Health and Maitreya Dunham of the University of Washington, Seattle.

This work was supported by grants from the National Institute of Neurological Disorders and Stroke (NS083373, NS037402) and the National Institute of General Medical Sciences (GM077875, P50-GM071508, U54 GM103520).

Media Contacts:
Catherine Kolf; 443-287-2251; ckolf@jhmi.edu
Tim Parsons; 410-955-6878; tmparson@jhsph.edu
Vanessa McMains; 410-502-9410; vmcmain1@jhmi.edu

Media Contact

Catherine Kolf EurekAlert!

More Information:

http://www.jhmi.edu

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.

Back to home

Comments (0)

Write a comment

Newest articles

Lighting up the future

New multidisciplinary research from the University of St Andrews could lead to more efficient televisions, computer screens and lighting. Researchers at the Organic Semiconductor Centre in the School of Physics and…

Researchers crack sugarcane’s complex genetic code

Sweet success: Scientists created a highly accurate reference genome for one of the most important modern crops and found a rare example of how genes confer disease resistance in plants….

Evolution of the most powerful ocean current on Earth

The Antarctic Circumpolar Current plays an important part in global overturning circulation, the exchange of heat and CO2 between the ocean and atmosphere, and the stability of Antarctica’s ice sheets….

Partners & Sponsors