Hormone-mimicking chemicals harm fish now—and their unexposed offspring later
Brian Bienkowski for Environmental Health News
The study, published in Environmental Science and Technology,
is the first of its kind in a fish that can live in freshwater, brackish water
or salt water, and suggests that compounds in pesticides and birth control that
pollute waterways are not only harming fish living there now, but their
offspring and the subsequent generation as well.
The results are
troublesome as the negative effects seen in fish offspring—including reduced
survival and reproduction problems—could lead to population level declines over
time.
"These effects can carry over into indirectly exposed fish and those not exposed at all," Bethany DeCourten, lead author of the study and a postdoctoral consultant at the University of California Davis' Department of Anatomy, Physiology and Cell Biology, told EHN.
The research offers the
latest evidence of the deeply embedded biological problems for humans and
animals exposed to endocrine-disrupting chemicals—which mimic natural
hormones—that are pervasive in our environment.
"These findings
suggest that single-generation toxicity testing may not be adequate to
determine the effects of these chemicals on long-term population
viability," the authors wrote.
Low levels lead to
generational impacts
Researchers exposed
inland silverside fish to bifenthrin, levonorgestrel, ethinylestradiol, and
trenbolone to levels currently found in waterways.
"Our concentrations
were actually on the low end" of what is found in the wild, DeCourten
said, adding that it was low amounts of chemicals in parts per trillion.
Bifenthrin is a
pesticide; levonorgestrel and ethinylestradiol are synthetic hormones used in
birth controls; and trenbolone is a synthetic steroid often given to cattle to
bulk them up.
Such
endocrine-disruptors have already been linked to a variety of health problems
in directly exposed fish including altered growth, reduced survival, lowered
egg production, skewed sex ratios, and negative impacts to immune systems. But
what remains less clear is how the exposure may impact future generations.
For their study,
DeCourten and colleagues started the exposure when the fish were embryos and
continued it for 21 days.
They then tracked
effects on the exposed fish, and the next two generations.
They found:
- The exposed fish had impacted gene expression and DNA methylation, increased deformities, and decreased egg production;
- The first generation, which was indirectly exposed within their parents, had reduced hatching success, and deformities in developing larvae;
- And the second generation, which had no exposure, had the largest decrease in survival rates, and altered DNA methylation.
In looking at two
subsequent generations, the study roughly corresponds to three years in the
wild, DeCourten said. "We saw impacts on survival in the second
generation," she said. "This definitely could impact populations as a
whole. Right now, we just don't really have an idea of exactly what that could
mean for wild populations."
Senior author of the
study Susanne Brander said it's reasonable to think that other fish species
would be similarly impacted, especially other estuary and marine fish, as the
salt content in water can change the way fish respond to different stressors,
including pollution.
Brander, an assistant
professor at Oregon State University, has been working with inland silverside
fish for a little more than a decade. She said labs all over the country now
use the fish in routine testing to test whether wastewater effluent is toxic or
not.
It's a "model
organism for estuary and marine and coastal habitats," she told EHN.
Inherited problems
DeCourten said the
altered DNA methylation is one of the plausible ways that future generations
would experience health impacts from previous generations' exposure.
Hormone-disrupting compounds have been shown to impact DNA methylation, which
is an important marker of how an organism will develop.
"Methyl groups are
added to specific sites on the genome, [the exposure] is not changing the
genome itself, but rather how the genome is expressed," she said.
"And that can be inherited throughout generations."
In addition, Brander
said there are essentially different "tags" that exist on DNA
molecules, which tell genes how to turn on and off. She said the exposure to
different compounds may be "influencing which methyl tags get taken on or
off as you proceed through generations."
The researchers said the
study should prompt future toxics testing to consider impacts on future
generations.
"The results …
throw a wrench in the current approach to regulating chemicals, where it's
often short-term testing looking at simple things like growth, survival, and
maybe gene expression," Brander said.
"These findings are
telling us we really at least need to consider" the next two generations,
she added.
Banner photo: Inland
Silverside fish from a U.S.Fish and Wildlife Service beach seining operation at
Liberty Island in the San Joaquin-Sacramento Bay-Delta. (Credit: USFWS)
