In 1944, a PhD student of genetics at Columbia University Evelyn Witkin has made the occasional mistake. During his first experiment in a laboratory in cold spring Harbor in new York, she accidentally exposed millions of e coli lethal dose of ultraviolet light. Returning the next day to check the samples, she discovered that they are all dead. Except one, in which four bacterial cells survived and continued its growth. Somehow, these cells are able to cope with UV irradiation. For Witkin was a good coincidence that all the cells of this culture has got exactly the mutation that helped them survive — so successful that she doubted whether it was a coincidence at all.
Over the next twenty years, Witkin has tried to understand how and why were these mutants. Her research has led to the so-called SOS-response, mechanism of DNA repair, which is used by bacteria, when their genomes are damaged; during the restoration of dozens of genes become active, and the mutation rate increases. These mutations are most often harmful than useful, but they allow you to adapt, for example, to UV light or antibiotics.
Since then, some evolutionary biologists was tormented by the question: does the nature of this order? Is the splash mutation is only a secondary consequence the recovery process is inherently error-prone? Or, according to some researchers, the increase in the rate of mutations is an evolutionary adaptation that helps the bacteria to grow faster in a stressful environment?
The scientific challenge is not only to convincingly demonstrate that a harsh environment causes non-random mutations. And to find the working mechanism, compatible with the rest of molecular biology that would make a good mutation more likely. Different waves of the surveys of bacteria and more complex organisms trying to find answers to these questions for decades.
The last and perhaps the best answer is to explain some types of mutations, anyway — came from studies of yeast, as reported in the June PLOS Biology. A group of scientists led by Jonathan Housley, a specialist in molecular biology and genetics at the Institute of Babraham in Cambridge, proposed a mechanism, which causes more mutations to the genome of the yeast in those regions in which can be the most adaptive.
“This is a completely new way by which environment can affect the genome and allow you to adapt if necessary. This is one of the processes that we’ve seen,” said Philip Hastings, Professor of molecular and human genetics at the Medical College of Baylor, which had not participated in experiments of the group of Housley. Other scientists supported this work, but with the caveat that controversial ideas require more support with facts.
Increasing the diversity in the genome
“Rather than ask a very broad question like “is it always random mutations?”, I decided to use a more mechanistic approach,” says Housley. He and his colleagues drew attention to a special type of mutation called variations of the number of copies. DNA often contains many copies of extended sequences of base pairs or even entire genes. The exact number may vary from individual to individual, because when cells divide their DNA to dividing cells mistakenly can be inserted or deleted copies of the gene sequences. In humans, for example, 5-10% of the genome show variation in the number of copies from person to person — and sometimes these variations are associated with cancer, diabetes, autism and genetic disorders. Housley suspects that at least in some cases, this variation in the number of genes may be a response to stress or danger in the environment.
In 2015, Housley and his colleagues described the mechanism by which yeast cells seem to get more variations in the number of copies of genes related to ribosomes, the parts of the cell that synthesizes proteins. However, they have not proven that this increase was a purposeful adaptive response to a change or restriction in the cellular environment. However, they found that the yeast make more copies of ribosomal genes when nutrients are abundant, and the need for protein may be higher.
So Housley decided to test whether these mechanisms directly affect genes, antivirus dangerous environmental changes. In its work in 2017 with the team, he focused on CUP1, a gene that helps the yeast to resist the toxic effects of copper. They found that when yeast are exposed to copper variations in the number of copies of CUP1 in the cells grow. On average, most cells less copies of the gene, but yeast cells acquired more — about 10% of the total population — and became resistant to copper, thanks to which began to flourish. “A small number of cells that did everything right, was in such an advantage that could surpass all others.”
But this change in itself did not mean much: if copper in the environment has caused mutations, the change of the variation of the number of copies, CUP1 could be nothing more than a consequence of a higher rate of mutation. To exclude this possibility, the researchers cleverly reworked the CUP1 gene, to respond to harmless, non mutagenic sugar, galactose, instead of the copper. When the modified yeast cells were exposed to galactose, the variation of the number of copies is also changed.
The cells seem to be directed more variations to the right place in the genome, where they would be useful. After additional work, the scientists have identified the biological mechanism behind this phenomenon. It was known that when the cells replicate their DNA, replication engine sometimes stops. Typically, the mechanism can be restarted and continue working in the place where you left off. When he can’t, the cell returns to the beginning of the replication, but it sometimes randomly deletes a gene sequence or make additional copies. This leads to the usual variations in the number of copies. But Housley and his team came to the conclusion that the combination of factors leads to the fact that these copy errors are likely to impress the genes that actively respond to stress from the environment, and therefore likely to demonstrate variation in the number of copies.
The key here is that these effects are concentrated on the genes that respond to the environment, and that they can give natural selection more opportunity to fine-tune gene expression levels that are optimal for certain problems. The results seem to show experimental evidence that a complex environment can stimulate the cells to control these genetic changes that best improve their form. They can also remind you of the outdated dodawanie the ideas of the French naturalist Jean-Baptiste Lamarck, who believed that organisms evolyutsioniruet in the transmission of acquired environmental characteristics to their offspring. Housley argues that the resemblance is only superficial.
“We have identified a mechanism that arose entirely in the process of Darwinian selection of random mutations and which stimulates non-random mutations into useful places,” says Housley. “It’s not lomakovsky adaptation. It all just leads to one and the same, but without the problems associated with lomakovsky adaptation”.
Adaptive mutation and disputes
Since 1943, when the microbiologist Salvador Luria and the biophysicist Max Delbrück demonstrated the experiment that brought a Nobel prize scientist, in which mutations of Escherichia coli occurred by chance, observations of the SOS response in bacteria has gradually led scientists to wonder whether in this rule to be an important retreat. For example, in a controversial work, published in Nature in 1988, John Cairns at Harvard and his team found that when they placed the bacteria are not digesting the lactose in milk sugar, in an environment where sugar was the only food source, soon the cells acquired the ability to convert lactose into energy. Cairns claimed that this result shows that cells were the mechanisms, allowing them to make selective mutations that they have found useful.
Experimental confirmation of this idea was insufficient, but some biologists were inspired to be advocates of a broader theory of adaptive mutation. They believe that even if the cells can’t send the exact mutation in certain conditions, they can adapt, increasing the rate of mutations and contributing to genetic changes.
The work of the team of Housley, it seems, fits perfectly into this theory. Yeast have a mechanism of “no choice, standing in front of the mechanism, which reads as follows: should I mutate this gene, to solve the problem,” said Patricia foster, a biologist from Indiana University. “This shows that evolution can be accelerated”.
Hastings from Baylor agrees with her and notes the fact that the mechanism Housley explains why additional mutations do not occur throughout the genome. “We need to rewrite the gene, make it happen”.
The theory of adaptive mutation, however, is less acceptable to most biologists, and many of them are skeptical of the original experiments by Cairns and new — Housley. They argue that even if a higher rate of mutations allows to adapt to the ambient pressure, to prove that the increased rate of mutations was itself an adaptation to the pressure, convincing will be very difficult. “This interpretation is appealing at an intuitive level,” says John Roth, a geneticist and microbiologist at the University of California at Davis, “but to me it doesn’t seem right. I do not believe that these examples are caused by the pressure of the mutations correct. There may be others, not the most obvious explanation of the phenomenon.”
“I think the work Housley is beautiful and fits to a dispute about the adaptive mutation,” says Paul Sniegowski, a biologist at the University of Pennsylvania. “But it is only a hypothesis.” To confirm it with certainty, “I’ll have to check it how do evolutionary biologists” — creating a theoretical model and determined whether this adaptive metroeast to develop in a reasonable period of time, and then certain populations of organisms in the laboratory to implement this mechanism.
Despite the doubters, Housley and his team are persistent in their studies and consider them necessary for the understanding of cancer and other biomedical problems. “The development of cancer, resistant to chemotherapy, is a common phenomenon and is a serious obstacle to the treatment of this disease,” says Housley. He believes that chemotherapy and other pressure exerted on the tumor can promote tumor further mutation, including the development of resistance to drugs.
“We are actively working,” says Housley, “but still ahead”.
According to the materials of Quanta
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