Skip to main content

Translation of genes more complex than expected

Researchers from the group of Marvin Tanenbaum at the Hubrecht Institute have shown that translation of the genetic information stored in our DNA is much more complex than previously thought. This discovery was made by developing a type of advanced microscopy that directly visualizes the translation of the genetic code in a living cell. Their study is published in the scientific journal Cellon June 6th.
Illustration of DNA in cell
From gene to protein
Each cell in our body contains the same DNA, yet different cells, like brain cells or muscle cells, have different functions. The differences in cell function depend on which parts of the genetic information (called genes) are active in each cell. The genetic information stored in these genes is translated by specialized translation factories called ribosomes. Ribosomes read the genetic code and assemble proteins based on the information stored in this genetic code analogous to a factory building a machine based on a blueprint. Proteins are the workhorses of our body and perform the functions encoded in our genes. For our cells and organs to function correctly, it is critical that the genetic information stored in our genes is translated accurately to proteins. If the genetic code is translated incorrectly, harmful proteins can be produced, which can lead to neurological diseases such as Huntington's disease.
The 'reading frame' of genes
The genetic code is translated in groups of 3 letters, each resembling a word, which is translated into a single part of the protein. If a ribosome starts translating the code at the wrong position, a shift in the 3-letter-code can occur. For example, the sentence below should read:
"the man saw his new red car"
However, if a ribosome starts translating this sentence one letter too late, the sentence would read:
"hem ans awh isn ewr edc ar"
In the case of the genetic code, this phenomenon is called 'out-of-frame' translation. Sanne Boersma, researcher at the Hubrecht Institute explains: "As illustrated by the example sentence, out-of-frame translation has a big effect on the protein and usually results in a protein that behaves differently and can damage the cell." Until now, it was unclear how the ribosome knows where to start translating the code, and how often the ribosome gets it wrong.
A new method: SunTag and MoonTag
The researchers developed a new method to visualize the decoding of our genetic information in living cells. They were able to label different protein products in different colors and visualize the production of each type of protein using advanced microscopy. Each protein was labeled using a specific label, or tag, called the SunTag and MoonTag, which they could see through the microscope. By combining the MoonTag and the SunTag, the researchers could now see for the first time how often out-of-frame translation takes place.
A big surprise
The researchers discovered that out-of-frame translation happens surprisingly frequently. In extreme cases, almost half of all the proteins that were built, used a different reading frame or code than the expected code. These surprising findings show that the genetic information stored in our DNA is far more complex than previously thought. Based on the new study, our DNA likely encodes thousands of previously unknown proteins with unknown functions. Sanne Boersma: "Because of our study, we can now ask very important questions: what do all these new proteins do? Do they have important functions in our body or are they waste side-products of translation that can damage our cells?"
Story Source:
Materials provided by Hubrecht Institute
Note: Content may be edited.

Comments

Post a Comment

Popular posts from this blog

Home births as safe as hospital births: International study suggests

A large international study led by McMaster University shows that low risk pregnant women who intend to give birth at home have no increased chance of the baby's perinatal or neonatal death compared to other low risk women who intend to give birth in a hospital. The results have been published by  The Lancet 's  EClinicalMedicine  journal. "More women in well-resourced countries are choosing birth at home, but concerns have persisted about their safety," said Eileen Hutton, professor emeritus of obstetrics and gynecology at McMaster, founding director of the McMaster Midwifery Research Centre and first author of the paper. "This research clearly demonstrates the risk is no different when the birth is intended to be at home or in hospital." The study examined the safety of place of birth by reporting on the risk of death at the time of birth or within the first four weeks, and found no clinically important or statistically different risk between home...
Post a Comment
Read more

Dark matter may be older than the Big Bang

Dark matter, which researchers believe make up about 80% of the universe's mass, is one of the most elusive mysteries in modern physics. What exactly it is and how it came to be is a mystery, but a new Johns Hopkins University study now suggests that dark matter may have existed before the Big Bang. The study, published August 7 in  Physical Review Letters , presents a new idea of how dark matter was born and how to identify it with astronomical observations. "The study revealed a new connection between particle physics and astronomy. If dark matter consists of new particles that were born before the Big Bang, they affect the way galaxies are distributed in the sky in a unique way. This connection may be used to reveal their identity and make conclusions about the times before the Big Bang too," says Tommi Tenkanen, a postdoctoral fellow in Physics and Astronomy at the Johns Hopkins University and the study's author. While not much is known about its origins,...
Post a Comment
Read more

Scientists challenge notion of binary sexuality with naming of new plant species

A collaborative team of scientists from the US and Australia has named a new plant species from the remote Outback. Bucknell University biology postdoctoral fellow Angela McDonnell and professor Chris Martine led the description of the plant that had confounded field biologists for decades because of the unusual fluidity of its flower form. The discovery, published in the open access journal  PhytoKeys , offers a powerful example of the diversity of sexual forms found among plants. The new species of bush tomato discovered in remote Australia provides a compelling example of the fact that sexuality among Earth's living creatures is far more diverse -- and interesting -- than many people likely realize. Bucknell University postdoctoral fellow Angela McDonnell and biology professor Chris Martine led the study following an expedition last year to relocate populations of the new plant, which were first noted by Australian botanists during the 1970s. Herbarium specimens from th...
Post a Comment
Read more