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What is genomic surveillance?

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  • Innovation and Research
  • Covid-19

This article was written by 51精品视频's Alexander Sundermann, clinical research coordinator and doctor of public health student; Lee Harrison, professor of epidemiology, medicine and infectious diseases, and microbiology; and Vaughn Cooper, professor of microbiology and molecular genetics,聽for The Conversation.聽Faculty members and researchers who want to learn more about publishing in The Conversation can聽.

鈥淵ou can鈥檛 fix what you don鈥檛 measure鈥 is a maxim in the business world. And it holds true in the world of public health as well.

Early in the pandemic, the United States . That failure meant officials didn鈥檛 know the true number of people who had COVID-19. They were left to respond to the pandemic without knowing how quickly it was spreading and what interventions minimized risks.

Now the U.S. faces a similar issue with a different type of test: genetic sequencing. Unlike a COVID-19 test that diagnoses infection, genetic sequencing decodes the genome of SARS-CoV-2 virus in samples from patients. Knowing the genome sequence helps researchers understand two important things 鈥 how the virus is mutating into variants and how it鈥檚 traveling from person to person.

Before the COVID-19 pandemic, this kind of genomic surveillance was reserved mainly for conducting small studies of antibiotic-resistant bacteria, investigating outbreaks and monitoring influenza strains. As and experts, we perform these kinds of tests every day in our labs, working to puzzle out how the coronavirus is evolving and moving through the population.

Particularly now, as new coronavirus variants of concern continue to emerge, genomic surveillance has an important role to play in helping bring the pandemic under control.

Tracking virus鈥 travels and changes

Genome sequencing involves deciphering the order of the nucleotide molecules that spell out a particular virus鈥檚 genetic code. For the coronavirus, that genome contains a string of around 30,000 nucleotides. Each time the virus replicates, errors are made. These mistakes in the genetic code are called mutations.

Most mutations do not significantly change the function of the virus. Others may be important, particularly when they that and cause infection. how infectious the virus is, how severe the infection may become, and how well current vaccines protect against it.

Researchers are particularly on the lookout that distinguish virus specimens from others or match known variants.

Scientists can use the genetic sequences to track how the virus is being transmitted in the community and in health care facilities. For example, if two people have viral sequences with zero or very few differences between them, it suggests the virus was transmitted from one to the other, or from a common source. On the other hand, if there are a lot of differences between the sequences, these two individuals did not catch the virus from each other.

This kind of information lets public health officials tailor interventions and recommendations for the public. Genomic surveillance can also be important in health care settings. , to that .

Surveillance can provide a warning

But how do researchers know if variants are emerging and if people should be concerned?

Take the B.1.1.7 variant, first detected in the United Kingdom, which has strong genomic surveillance in place. Public health investigators discovered that a certain sequence with multiple changes, including the spike protein, was Even amid a national shutdown, , more so than its predecessors.

Scientists looked further into this variant鈥檚 genome to determine how it was overcoming the distancing recommendations and other public health interventions. They found particular mutations in the spike protein 鈥 with names like 鈭69-70 and N501Y 鈥 that made it easier for the virus to infect human cells. Preliminary research suggests these mutations translated into a higher rate of transmission, meaning that from person to person than prior strains.

Vaccine developers and other scientists then used this genetic information to test whether the new variants change how well the vaccines work. Fortunately, preliminary research that has not yet been peer-reviewed found that the B.1.1.7 variant . More worrisome are other variants such as P.1. and B.1.351, first discovered in Brazil and South Africa, respectively, that .

Setting up a genomic surveillance system

Detecting variants of concern and developing a public health response to them requires a robust genomic surveillance program. That translates to scientists sequencing virus samples from about 5% of the total number of COVID-19 patients, selected to be representative of the populations most at risk from the disease. Without this genomic information, new variants may spread rampantly and undetected through the country and globally.

So how is the U.S. performing in the ? Not very well, and , coming in 34th in the . Even within the U.S., there is for genomes sequenced per number of cases, ranging from Tennessee at 0.09% to Wyoming at 5.82%.

But this is about to change. The Centers for Disease Control and Prevention, in conjunction with other agencies of the federal government, is partnering with private labs, state and local public health labs, academia and others

Reaching the new is not as simple as footing a hefty bill for a laboratory to perform the tests, though. Laboratories must collect the samples, often from different sources: public health labs, hospitals, clinics, private testing labs. Once the sequencing test is performed, bioinformaticians use advanced programs to identify important mutations. Next, public health professionals merge the genomic data with the epidemiological data to determine how the virus is spreading. All of this requires investment in training people to perform these tasks as a team.

Ultimately, to be useful, a successful genomic surveillance program must be fast and the data needs to be made publicly available immediately to inform real-time decision-making by public health officials and vaccine manufacturers. Such a program is one of the public health tools that will help bring the current pandemic under control and set up the U.S. to be able to respond to future pandemics.