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Dec. 16, 2019: New findings published today in Nature Communications show that the Zika virus epidemic in Latin America likely suppressed the incidence of dengue in subsequent years to aberrantly low levels. Then, dengue came roaring back.

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When the Zika epidemic burned through the Americas in 2015, it was transmitted in the same areas where dengue virus was already endemic. This was not unexpected, as both viruses are genetically and antigenically similar, and they also share the same mosquito vectors, Aedes aegypti and Aedes albopictus.

But what was surprising was how quickly dengue virus faded into the background in the immediate years following the Zika outbreak. New findings from researchers at the University of Florida’s Emerging Pathogens Institute and UF’s College of Liberal Arts and Sciences Department of Biology, describes how dengue was likely suppressed to abnormally low levels in Latin America in the years following the Zika epidemic. Their work explains a possible mechanism for how dengue then came roaring back in 2019.

The study, which published today in Nature Communications, was led by Rebecca Borchering while she was a postdoctoral researcher in biology at UF. It was conducted by multiple members of the Infectious Disease Dynamics lab which is led by the study’s senior author, Derek Cummings, who is a UF biology professor.

The researchers suspected that something about the immune response to Zika offered cross-protection against subsequent dengue infection. Prior work conducted by Cummings and collaborators, which published in Science, showed that individuals with dengue immunity were partially protected from the new Zika virus.

“In certain parts of Brazil, 60 to 70 percent of the population was infected with Zika within four or five months in 2015,” Borchering says. “The attack rate was extremely high. That was followed by reports in 2017 that Brazil was experiencing a very low incidence of dengue. We decided to test this more rigorously, to see if there was a relationship between Zika infection and subsequent dengue infections.”

Specifically, Cummings wondered, What if being infected with Zika offered immunity against dengue for a year or two? Temporary immunity is observed between dengue viruses so it would make sense that infection with the similar Zika virus might create the same temporary protection.

Using publicly available population-level data stretching from 1999-2017 for Brazil and from 2007-2017 for Colombia, Borchering and colleagues assembled models of dengue incidence. They used historic incidence rates of dengue to build models of dengue incidence and compare incidence in the years during and after the Zika outbreak to those before.

Borchering, now a postdoctoral research associate in the Odum School of Ecology at the University of Georgia, says their first major finding was to establish that statistically, 2017 was an aberrantly low year for dengue in Brazil and Colombia.

Following the Zika outbreak in 2015-2016, Brazil saw 252,054 dengue cases in 2017 and 265,930 in 2018. In strong contrast, 1.6 million cases were reported in 2015.

“Dengue naturally has cycles of high and low incidence years,” Borchering says. “But even given these cycles, the observed dengue incidence was statistically very different from what you would expect given past historic data.”

When there are low amounts of dengue in a population, that means immunity is not being produced, Cummings says. “It tends to mean that in future time periods, you will have more dengue,” he adds. “There is a feedback in the system that immunity suppresses further transmission, and if you have not had a lot of immunity accumulating in the past few years, then you might be waiting for a pretty sizeable outbreak.”

To test whether immunity produced in response to Zika infections that temporarily protects individuals from dengue could explain the decline in dengue seen after the Zika outbreak, the group built simulations of dengue and Zika transmission. They examined a wide range of simulations with multiple assumptions of interactions between dengue and Zika.

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“We found that these low numbers of dengue incidence in 2017 and 2018 were best explained by the simulations that had varying levels of cross-immunity built into them,” says Angkana Huang, a UF doctoral student in biology who also worked on the study. “Which supports the line of thinking that cross-immunity from Zika infections works to suppress dengue transmission in the years following a Zika outbreak.”

The simulations also suggested that periods of reduced dengue could be followed by very large epidemics of dengue, once cross-protection waned and dengue resurged. This finding of the models has unfortunately been seen in real life; many countries of the Americas have experienced record numbers of dengue cases in 2019 including 1.9 million cases reported from Brazil.

There are some limitations to the data, Borchering cautioned. “Many early Zika cases may have been misdiagnosed as dengue, due to shared symptoms, or were not recorded, because it took time to identify that Zika virus was circulating and to establish reporting protocols,” Borchering says. Second, climatological factors and changes in surveillance may affect dengue incidence and could contribute to changes seen in the last few years.

Cummings says that research is needed at the level of individuals to see how Zika and dengue immunity may affect each other, and whether having had Zika was predictive of who has a dengue infection. He expects that dengue will begin to settle back down to normal after this year, as the perturbation of Zika entering the Americas as a novel pathogen settles down.

“The big question now is, when will Zika come back?” Cummings says. “Because it almost certainly will. What we don’t know is how long Zika immunity excludes new Zika outbreaks.”


EPI Explainer: The Four Faces of Dengue

Dengue virus has four different serotypes. Becoming infected with one serotype is thought to confer life-long, or at least long-lasting, immunity against that particular type. It also confers temporary immunity against the three other serotypes. However, after a few years, people are at increased risk of becoming severely ill if they become infected with a different serotype after their initial infection. Because Zika is a genetically similar virus to dengue, many researchers have hypothesized that immunity to Zika virus may follow a similar pattern to dengue and may confer temporary immunity to dengue infection for a year or two; but it may also possibly place people at risk after that time.


Acknowledgements

The work was conducted by researchers at UF (Rebecca Borchering, Angkana Huang, Diana Rojas, Leah Katzelnick, Silvio Martinez, Greg King, Stephanie Cinkovich and Derek Cummings), Johns Hopkins University  (Luis Mier-y-Teran-Romero, Justin Lessler), and the University of California-San Francisco (Isabel Rodriguez-Barraquer).


Creator Credits

Written by DeLene Beeland

Top photo: This is a digitally colorized transmission electron microscopic image of Zika virus, which is a member of the family, Flaviviridae. Virus particles, colored blue, are 40nm in diameter, with an outer envelope, and an inner dense coreand credits here

Chart: Figure 11 from the published paper, courtesy of the authors, shows the different assumptions programmed into various simulations. Panels I-L best match the "trough" in observed dengue cases following the Zika epidemic, when cross-immunity may have temporarily provided an unusually large degree of protection against dengue.

 

Read More

Read Derek Cummings, Ph.D. bio here.

Read Impacts of Zika emergence in Latin America on endemic dengue transmission here (open access).