Summary: Members of the British military who witnessed nuclear test programs in the 1950s and 60s are no more likely to pass on genetic alterations to their offspring and future generations than other members of the military, a new study reports.
Source: University of Bristol
Military men who had been present when British nuclear weapons were tested in the 1950s and 60s are no more likely to pass on to their descendants more changes to their DNA in comparison to other veterans, a new study involving University of Bristol researchers, has found.
The study, published in the journal Scientific Reports, set out to see whether or not the amount and type of genetic changes seen in the children of nuclear test veterans, when compared to their parents, is as would be expected in families more generally.
The findings are from the first study looking into whether there is a genetic legacy associated with having been present at the test sites, including Christmas Island and the Australian outback.
To study this, researchers analyzed blood samples from 30 family trios: the father, the mother and their surviving biological child conceived soonest after the father returned from nuclear test sites. For comparison purposes, samples were analyzed from a matched control group of 30 family trios of veterans of similar age and military service who hadn’t been at test sites. All were invited to the study through their GPs in a multi-step recruitment process.
The team found that, for each comparison, the number and type of genetic changes were in line with what would be expected naturally, with no significant differences between the nuclear test veteran and control groups.
Dr. Rhona Anderson, the study lead from Brunel University London, and Director of the Center for Health Effects of Radiological and Chemical Agents, said: “Our study showed no significant increases in the frequency of newly arising genetic changes in the offspring of nuclear test veteran fathers. This result should reassure the study participants and the wider nuclear test veteran community.”
Dr. Alex Moorhouse, now based at the University of Bristol’s School of Cellular and Molecular Medicine, carried out the whole genome sequencing analysis while at the University of Leicester, said: “This is the first study of the transgenerational genome wide mutational risk in the human germline as a result of exposure to ionizing radiation. It is an important epidemiological study, particularly for the British Nuclear Test Veterans who participated at the nuclear test sites, and for their families.”
Dr. Moorhouse and colleagues from the University of Leicester, led by Professor Yuri Dubrova, extracted DNA from each sample and sequenced and analyzed the whole genome, producing a readout of each participant’s genetic information. All the samples were processed blind, so the research team didn’t know whether they were analyzing blood from a nuclear test veteran or control family trio.
Comparing the readouts between the generations meant the researchers could identify different types of newly arising germline genetic changes, such as when building blocks of DNA swap places or are deleted, and then count them.
Once the samples were revealed as being part of the veteran group or control group, the study team, which included researchers at the London School of Hygiene & Tropical Medicine, were able to make comparisons.
They compared their data with previous studies of how often newly arising germline genetic changes happen in humans more generally. The researchers also compared the nuclear test veteran family group with the control family group, focusing on genetic changes collectively known as single nucleotide variants, structural variants and clustered mutations, and a particular type where DNA building blocks are inserted or deleted, known as indels.
A paper published earlier this month by the researchers revealed that a higher proportion of the nuclear test veterans in the study said that at least one of their children or grandchildren had been born with a congenital anomaly—sometimes known as birth defects, such as of the heart or of the limbs—and that a higher proportion of control veterans reported chemical or radiation exposure through their jobs.
However, these differences are not explained by the genetic analysis carried out on the family members studied in these two groups.
Professor Dubrova added: “Overall, our findings may reflect the low radiation doses thought to be received by the nuclear test veterans. Another consideration is the time gap between the date of last attendance at a test site and when the next child was conceived.”
When analyzing the genetic changes seen in the nuclear test veteran and control groups, the researchers spotted that one particular pattern of changes to the DNA building blocks—known as SBS16, a mutation signature—differed between the groups, happening more often in the nuclear test veteran family trios.
“That this signature is present more for nuclear test veteran families is most likely explained by it being a feature of a small group of the study’s participants,” Dr. Anderson said. “However, we cannot rule out with sufficient confidence that this could be a random occurrence unrelated to the background of these families.”
No evidence of increased mutations in the germline of a group of British nuclear test veterans
The potential germline effects of radiation exposure to military veterans present at British nuclear tests in Australia and the South Pacific is of considerable interest.
We analyzed germline mutations in 60 families of UK military personnel comprising 30 control and 30 nuclear test veterans (NTV). Using whole-genome sequencing we studied the frequency and spectra of de novo mutations to investigate the transgenerational effect of veterans’ (potential) exposure to radiation at nuclear bomb test sites.
We find no elevation in total de novo single nucleotide variants, small insertion-deletions, structural variants or clustered mutations among the offspring of nuclear test veterans compared to those of control personnel.
We did observe an elevated occurrence of single base substitution mutations within mutation signature SBS16, due to a subset of NTV offspring. The relevance of this elevation to potential exposure of veteran fathers and, future health risks, require further investigation.
Overall, we find no evidence of increased mutations in the germline of a group of British nuclear test veterans.