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Mechanism of crude oil heart
toxicity on fish revealed from oil spill research
Mechanism of crude oil heart
toxicity on fish revealed from oil spill research
Date:
February 13,
2014
Source:
Stanford University
Summary:
While studying the impact of the 2010 Deepwater
Horizon oil spill on tuna, a research team discovered that crude oil interrupts
a molecular pathway that allows fish heart cells to beat effectively. The
components of the pathway are present in the hearts of most animals, including
humans
...........................
Scientists
from Stanford University and the National Oceanic and Atmospheric
Administration (NOAA) have discovered that crude oil interferes with fish heart
cells. The toxic consequence is a slowed heart rate, reduced cardiac
contractility and irregular heartbeats that can lead to cardiac arrest and
sudden cardiac death.
The
research, published in the Feb. 14 issue of Science, is part of the
ongoing Natural Resource Damage Assessment of the April 2010 Deepwater Horizon
oil spill.
While crude
oil is known to be cardiotoxic to developing fish, the physiological mechanisms
underlying its harmful effects were unclear. Stanford and NOAA scientists
studying the impact of crude oil from the Deepwater Horizon spill on tuna
discovered that it interrupts the ability of fish heart cells to beat
effectively.
Crude oil is
a complex mixture of chemicals, some of which are known to be toxic to marine
animals. Past research has focused in particular on "polycyclic aromatic
hydrocarbons" (PAHs), which can also be found in coal tar, creosote, air
pollution and stormwater runoff from land. In the aftermath of an oil spill,
PAHs can persist for many years in marine habitats and cause a variety of
adverse environmental effects.
The
researchers report that oil interferes with cardiac cell excitability,
contraction and relaxation -- vital processes for normal beat-to-beat
contraction and pacing of the heart.
Their tests
revealed that very low concentrations of crude oil disrupt the specialized ion
channel pores -- where molecules flow in and out of the heart cells -- that
control heart rate and contraction in the cardiac muscle cell.
This
cyclical signaling pathway in cells throughout the heart is what propels blood
out of the pump on every beat. The protein components of the signaling pathway
are highly conserved in the hearts of most animals, including humans.
The
researchers found that oil blocks the potassium channels distributed in heart
cell membranes, increasing the time to restart the heart on every beat. This
prolongs the normal cardiac action potential, and ultimately slows the heartbeat.
The potassium ion channel impacted in the tuna is responsible for restarting
the heart muscle cell contraction cycle after every beat, and is highly
conserved throughout vertebrates, raising the possibility that animals as
diverse as tuna, turtles and dolphins might be affected similarly by crude oil
exposure. Oil also resulted in arrhythmias in some ventricular cells.
"The
ability of a heart cell to beat," explained Barbara Block, a professor of
marine sciences at Stanford, "depends on its capacity to move essential
ions like potassium and calcium into and out of the cells quickly. This dynamic
process, which is common to all vertebrates, is called 'excitation-contraction
coupling.' We have discovered that crude oil interferes with this vital signaling
process essential for our heart cells to function properly."
"We've
known from NOAA research over the past two decades that crude oil is toxic to
the developing hearts of fish embryos and larvae, but haven't understood
precisely why," said coauthor Nat Scholz, leader of the Ecotoxicology
Program at NOAA's Northwest Fisheries Science Center in Seattle. "These
new findings more clearly define petroleum-derived chemical threats to fish and
other species in coastal and ocean habitats, with implications that extend
beyond oil spills to other sources of pollution such as land-based urban
stormwater runoff."
The new
study also calls attention to a previously underappreciated risk to wildlife
and humans, particularly from exposure to cardioactive PAHs that also exist at
relatively enriched levels in air pollution.
"When
we see these kinds of acute effects at the cardiac cell level," Block
said, "it is not surprising that chronic exposure to oil from spills such
as the Deepwater Horizon can lead to long-term problems in fish hearts, as our
NOAA colleagues have observed in studies of larval fish development.
"The
protein ion channels we observe in the tuna heart cells are similar to what we
would find in any vertebrate heart and provide evidence as to how petroleum
products may be negatively impacting cardiac function in a wide variety of
animals," she said. "This raises the possibility that exposure to
environmental PAHs in many animals -- including humans -- could lead to cardiac
arrhythmias and bradycardia, or slowing of the heart."
The
Deepwater Horizon disaster released over 4 million barrels of crude oil during
the peak spawning time for the Atlantic bluefin tuna in the spring of 2010.
Electronic tagging and fisheries catch data indicate that Atlantic bluefin
spawn in the area where the Deepwater Horizon drilling rig collapsed, raising
the possibility that eggs and larvae, which float near the surface waters, were
exposed to oil.
The spill
occurred in the major spawning ground of the western Atlantic population of
bluefin tuna in the Gulf of Mexico. The most recent stock assessment, conducted
in 2012, estimated the spawning population to be at only 36 percent of the 1970
baseline population. Additionally, many other pelagic fishes were also likely
to have spawned in oiled habitats, including yellowfin tuna, blue marlin and
swordfish.
NOAA
scientists have previously shown that exposure to crude oil-derived PAHs
disrupts cardiac function and impairs development in larval fishes. Numerous
studies, particularly in the aftermath of the Exxon Valdez spill in 1989, have
described a syndrome of embryonic heart failure, bradycardia, arrhythmias and
edema in exposed fish embryos. The potential for deleterious effects on young
fish in the northern Gulf of Mexico is still being investigated in the
aftermath of the Deepwater Horizon spill. In the present study, the NOAA team
partnered with Stanford researchers to determine why oil specifically impacts
heart cells.
Taking
advantage of captive populations of bluefin and yellowfin tuna at the Tuna
Research and Conservation Center (a collaborative facility operated by Stanford
and the Monterey Bay Aquarium), the research team was able to directly observe
the effects of crude oil samples collected from the Gulf of Mexico on living fish
heart cells.
Block and
her team bathed isolated cardiac cells from the tuna in low dose crude oil
concentrations similar to what fish in early life stages may have encountered
in the surface waters where they were spawned after the April 2010 oil spill in
the Gulf of Mexico.
They
measured the heart cells' response using a combination of sophisticated
electro-physiological techniques -- including "patch clamping" and
"confocal microscopy" -- to record how ions flowed into and out of
the heart cells, and to identify the specific proteins in the
excitation-contraction pathway that were affected by crude oil chemical
components.
"We can
examine the function of healthy heart cells in vitro and actually measure in
the microscope how they respond to the presence of crude oil in real
time," said Fabien Brette, a research associate in Block's lab and lead
author on the study.
"The
normal sequence and synchronous contraction of the heart requires rapid
activation in a coordinated way of the heart cells," Block said.
"Like detectives, we dissected this process using laboratory physiological
techniques to ask where oil was impacting this vital mechanism."
Story
Source:
The above
story is based on materials provided by Stanford University. Note: Materials may be
edited for content and length.
Journal
Reference:
- Fabien Brette, Ben Machado, Caroline Cros, John P. Incardona, Nathaniel L. Scholz, Barbara A. Block. Crude Oil Impairs Cardiac Excitation-Contraction Coupling in Fish. Science, February 14, 2014 DOI: 10.1126/science.1242747
