A new paper published online in The Lancet
challenges the assumption that raising a person's HDL — the so-called
"good cholesterol" — will necessarily lower the risk of a heart
attack.
The new research
underscores the value of using genetic approaches to test biological hypotheses
about human disease prior to developing specific drugs.
A team led by researchers
from the Broad Institute and Massachusetts General Hospital (MGH) explored
naturally occurring genetic variations in humans to test the connection between
HDL levels and heart attack. By studying the genes of roughly 170,000
individuals, the team discovered that, when examined together, the 15
HDL-raising variants they tested do not reduce the risk of heart attack.
"It's been assumed
that if a patient, or group of patients, did something to cause their HDL levels to go up, then
you can safely assume that their risk of heart attack will go down," said
senior author Sekar Kathiresan, director of preventive cardiology at MGH,
associate professor of medicine at Harvard Medical School, and an associate
member of the Broad Institute. "This work fundamentally questions
that."
Each of the variants
Kathiresan and his colleagues studied reflects potentially distinct ways the
body might raise HDL. The findings raise significant questions about whether
developing drugs against the genes explored in this study, which involves an
international team of investigators to bring together patient samples, will
prove effective in lowering heart attack risk across the population.
"Our study
highlights the value of human genetic information in understanding disease
biology prior to developing and testing drugs in the clinic," said
co-author David Altshuler, director of the Program in Medical and Population
Genetics at the Broad Institute and a Harvard Medical School professor at MGH.
"This kind of
research is not about personalized prediction — rather, it's about testing
mechanisms and therapeutic hypotheses before drug discovery."
In the blood, cholesterol
is carried by particles called lipoproteins, which come in different sizes and
densities. These include HDL, or high-density lipoprotein, and LDL, or
low-density lipoprotein. There is a well-studied connection between elevated
LDL, often called the "bad cholesterol," and heart attack.
Decades of research,
including studies of genetic disorders in humans and the discovery of the LDL
receptor and its role in cholesterol regulation, paved the way for the development
of life-saving drugs known as statins. This work showed beyond any reasonable
doubt that many different methods of reducing a person's LDL levels lower the
risk of heart disease.
Large-scale studies of
genetic variation tied to LDL have been revealing, but the data on HDL are not
so clear. More than 30 years ago, human epidemiological studies first revealed
an association between HDL and risk for heart attack: the higher the levels,
the lower the risk. Experiments in cells and mice further support the idea and
suggest that HDL is protective because it may remove cholesterol from the
sites where it can do damage.
However, it has been
difficult for researchers to prove conclusively that raising HDL levels is
beneficial, primarily for two reasons. First, studies of human genetic diseases
where individuals have very low HDL levels have not yielded definitive answers
as to the impact on heart attack. And second, because there are currently no
drugs that specifically elevate HDL levels, it has been difficult to prove in
humans that such an intervention will lower heart attack risk.
"There are many
biomarkers measurable in the blood that track with disease but only a very
small number are actually causal and directly participate," said first
author Benjamin Voight, who since completing this work has left the Broad and
MGH for a position as an assistant professor at University of Pennsylvania.
"The reason you want to distinguish between causal and non-causal
biomarkers is because of the implications for therapy."
To investigate,
Kathiresan teamed up with colleagues from MGH, the Broad Institute, and beyond,
including Voight and co-first author Gina Peloso. Together, the researchers
looked to the human genome for help.
Individuals typically
carry two copies of each gene in the genome; which copy a child will inherit
from each parent is essentially a random decision, like flipping a coin. This
phenomenon, sometimes called "Mendelian randomization," provides a powerful
means of testing connections between genes, biomarkers, and disease — similar
to the way that randomized controlled clinical trials can evaluate the
effectiveness of new drugs.
Using this technique,
researchers study two groups of people — those who carry a particular gene
variant, and those who do not. When sufficiently large groups are studied, both
groups should be similar in every factor, except for the specific gene variant
or biomarker of interest, allowing researchers to home in on whether the
biomarker actually causes a particular trait or condition. By harnessing this
method, Kathiresan and his team tested whether certain genetic variants that
can dial up a person's HDL levels impact the chances of developing heart
attack.
What they found was
surprising. Individuals who carried a particular variation in a gene called
endothelial lipase had HDL levels that were elevated about 6mg/dl, or 10% — a
change expected to decrease heart attack risk by about 13%. However, these
individuals showed no difference in their risk of heart disease compared to
people without the variant.
Similarly, the
researchers identified a panel comprised of not just one but 14 different
HDL-raising variants. They devised a scoring system based on the total number
of copies of the gene variants a person carries — ranging from 0 to 28 — and
then asked whether that score relates to the risk of heart attack. Here also
they uncovered no association.
Kathiresan emphasizes
that these results do not diminish the value of HDL levels as a predictor — a
so-called biomarker — that can help estimate the likelihood of a person going
on to develop heart attack.
"We know that HDL is
a great biomarker ¬— it's quite useful in identifying individuals at higher
risk of having a heart
attack in the future," said Kathiresan. "But we have shown
that you cannot assume that raising HDL by any mechanism will help patients.
Perhaps other mechanisms exist that can lower risk, but we will need to keep
searching for them."
"It takes a decade
or more, and costs up to hundreds of millions of dollars, to discover a drug
and carry out clinical trials. And yet, the vast majority of such clinical
trials fail due to lack of efficacy or toxicities," said Altshuler.
"Human genetics offers a valuable approach to evaluating the underlying
therapeutic hypothesis prior to spending so much time and money on drug
discovery, hopefully allowing the industry to focus resources on hypotheses
that are most likely to prove safe and effective in patients."
More information: Voight et al. A Mendelian randomization study for plasma
high-density lipoprotein cholesterol and risk for myocardial infarction.
Published online May 16, 2012 The Lancet DOI:10.1016/S0140-6736(12)60312-2
Journal reference: Lancet
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