Imagine traveling back in time and meeting your caveman ancestor of 10,000 years ago. Imagine telling him about what life is like today: that, with the tap of a finger you turn darkness into light, a cold room into a warm one and a tube in the wall of your cave into a spring of hot and cold water. You tell him...
you can fly from one place to another, and watch any place on
this Earth without ever leaving your cave. You tell him you never have to run after
your food, or fear that you run out of it. Your ancestor will have a hard time
believing you. In his world only his gods can do all that.
Then you tell him how
some of your friends think his way of life is preferable for health, which is
why you are visiting him because you want to see for yourself. Before I get to your
ancestor's most likely answer, let's get on the same page with those friends of
ours first.
You have probably heard them talk about the past 10,000
years having done nothing to our genetic make-up. In other words, your
ancestor's DNA blueprint was the same as yours. Today this blueprint collides
with a space age environment in which we don't expend any energy to get our
food, and the food we acquire delivers far more energy and far less nutrients
than what had been the case during 99.9% of human evolution.
According to this
view, today's epidemics of obesity, diabetes, cardiovascular diseases and
cancer are simply the collateral damage of this collision. This explanation is
so persuasive that it is being parroted by every media type and talking head
who can spell the word 'genetics'.
I'm afraid it is not that simple. Here is why:
Remember when the 3 billion letters, or base-pairs, of the
human genome had first been decoded at the beginning of this century. This
decryption had been delivered with the promise of revolutionizing medicine.
Aside from new therapies, the hottest items were prognostic and diagnostic
tools, which, we were made to believe, would lay in front of each individual his
biomedical future. And with this ability to predict would come the ability to
prevent, specifically all those diseases which result from an unfavorable
interaction between genes and environment.
Almost ten years later we are nowhere near this goal. OK, we
have identified some associations between some genetic variants and the
propensity to become obese or get a heart attack or diabetes. But these associations
are far from strong and they hardly help us to improve risk prediction. Just
this year, Vaarhorst and colleagues had investigated the ability of a genetic
risk score to improve the risk prediction of conventional risk scores which are
based on biomarkers, such as the ones used in the Framingham score. Less than
3% of the study participants would have been reclassified based on the genetic
risk score [1].
In a study which was released just yesterday, genetic markers for the development of diabetes in asymptomatic people at high risk, did not improve conventional biomarker risk scoring at all [2].
In a study which was released just yesterday, genetic markers for the development of diabetes in asymptomatic people at high risk, did not improve conventional biomarker risk scoring at all [2].
Obviously we are not simply our genes. This is because genes
do not make us sick or healthy. Genes make proteins. And on the way from gene
to protein a lot of things happen on which genes do not have any influence. To
express a gene, as biologists call it, that gene must first be transcribed on
RNA and then translated from RNA into the final protein. Whether a gene is
transcribed in the first place depends on whether it is being made accessible
for this transcription process. Today we know at least two processes which can
"silence" the expression of a gene, even though it is present in your
DNA. These processes are called DNA methylation and histone modification. Simply
imagine them as Mother Nature's way of keeping a gene under wraps.
That's a good thing if the protein product of the silenced
gene would be detrimental to your health. It could well be the other way round,
too. Anyway, these happenings have been called epigenetics. Epigenetic
mechanisms enable cells to quickly match their protein production with changing
environmental conditions. No need to wait for modifications of the genetic
blueprint which takes many generations and a fair element of chance to
materialize. The most astonishing discovery is that these epigenetic changes may
become heritable, too. Which means, there is really no need to change the
genetic code.
I believe you get the picture now. While it is true that
your ancestor's genetic code is indistinguishable from yours 10,000 years
later, the way your body expresses this code in the form of proteins and
hormones can differ in many ways. Which is why researchers are now as much
excited about epigenetics as they used to be about genetics 10 years ago.
I don't want to be the party pooper, but whenever I see such
excitement I'm reminded of how it has often evaporated after some further
discoveries. Here I'm skeptical because of the picture, which we are beginning
to see. Insulin, for example, is known to regulate the expression of many
genes. At least in rats it has been shown that insulin's suppressive effect on
gene expression in the liver, can be altered by short term fasting [3].
That means, relatively minor
behavioral changes may affect the way our organism expresses its genetic code.
Observations like these support the idea
that we are not our genes, but what we make of them. In plain words: let's not hide
behind the "it's-our-stone-age-genes" excuse, to explain why we are
fat and lazy and ultimately chronically sick.
Now, back to your ancestor and his response to your friends' suggestions
that his way of life is preferable for health. When you also tell him you live a
lot longer than the 40 years he has on average, he'll tell you: You have got
some nutcase friends over there. Let me live like a god first and then I'll
worry about health later.
Maybe, we are not so different from our stone age
ancestors after all. Lu, Y., Feskens, E., Boer, J., Imholz, S., Verschuren, W., Wijmenga, C., Vaarhorst, A., Slagboom, E., Müller, M., & Dollé, M. (2010). Exploring genetic determinants of plasma total cholesterol levels and their predictive value in a longitudinal study Atherosclerosis, 213 (1), 200-205 DOI: 10.1016/j.atherosclerosis.2010.08.053
Zhang Y, Chen W, Li R, Li Y, Ge Y, & Chen G (2011). Insulin-regulated Srebp-1c and Pck1 mRNA expression in primary hepatocytes from zucker fatty but not lean rats is affected by feeding conditions. PloS one, 6 (6) PMID: 21731709
No comments:
Post a Comment
Please comment with the civility and respect that you would use in a person-to-person conversation.
Please note: Comments, which contain links to sites promoting any kind of product will be removed!