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Image 1: Tetrahydrogestrinone aka THG,
aka "The Clear" and the bone of contention
in the "BALCO Scandal" could probably
have been identified years before, if the
WADA detectives already had the new
mammalian androgen responsive reporter
gene assays at their disposal. |
As mentioned in part 1 of this post (cf.
Beyond Vida's Book, Part 1/2), Houtman and the other scientists from
BioDetection Systems B.V. and the
Institute of Public Health and the Environment in the Netherlands, did not exactly want to provide juicers with data on which steroids may cause unexpected side-effects, when they conducted their study in 2008.
The original idea was to demonstrate that their technology would be able to identify even those androgens, which have hitherto not been classified as illegal substances - so called "designer steroids", which would not turn up in the chemical–analytical approaches combining gas chromatography (GC) or liquid chromatography (LC) separations with mass spectrometry (MS) or tandem mass spectrometry (MS/MS) simply because their molecular structure is hitherto unknown (you cannot find what you ain't looking for ;-).
This is the
second part of a two part series,
click here to read more about
nandrolone, trenbolone, testosterone and all the androgens on the list of prohibited substances of the World Anti Doping Agency.
If this method had been available back in the day, when Patrick Arnold developed THG (tetrahydrogestrinone aka "The Clear") for BALCO, the detectives from the World Anti Doping Agency (WADA) would probably have been able to identify Marion Jones and other athletes who used this highly performance-enhancing drug, even before baseball star
Berry Bonds blew the whistle in 2001.
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Figure 1: Relative potency at the androgen (compared to testosterone), progesterone (compared to progesterone) and estrogen alpha and beta receptors (compared to estrogen) of "The Clear" (THG), trenbolone and nandrolone
(calculated based on data from Houtman. 2008) |
Now, more than 10 years later, THG is on the list of WADA prohibited compounds and we know that
"The Clear" is 0.25x as androgenic as dihydrotestosterone and 1.15x more androgenic than testosterone. We also know that
THG is a powerful progestin, with 91% of the receptor activity of "real" progesterone (
trenbolone has 35%), but hardly any translational activity at the level of the estrogen (0.0017% for estrogen-beta) and corticosteroid receptor.
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Figure 2: Relative potency (new reference:
progesterone!) of steroids not on the
WADA list at the progesterone receptor
(data calculated base on Houtman. 2008) |
A few notes on the graphs: Houtman et al. did not measure the relative potency at the progesterone receptor for all of the "other exogenous androgens".
Instead of meshing androgen and progesterone activity into a single graph, I thus decided to seperate the two, because otherwise it would have been difficult to identify which of the steroids actually have "zero" transcriptional activity at the progesterone receptor and which just have not been analyzed by the scientists. Additionally I
recalculated the references using
testosterone and progesterone instead of
DHT and the over-potent progestin
ORG2085.
Among the better known
other (I am sticking to Houtman et al.'s nomenclature, here) exegenous androgens, the Dutch scientists analyzed,
trestolone, or 7a-methyl-19-nor-T (MENT), is certainly the "meanest bitch". It's androgenic activity is almost 10x higher than that
testosterone (and thus 3x more potant than
nandrolone!) and its potency as a transcriptional activator at the level of the
progesterone receptor is still 29% of that of
progesterone and thus more than 9x higher than that of
nandrolone aka "Deca".
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Figure 2: Relative potency at of steroids
not on the WADA list at the androgen
receptor; note that I re-calculated the
values relative to testosterone as a new
reference, this means that you have to
divide the values by 4.68 to get DHT as
a reference, as in Part 1, fig. 2 (data
calculated base on Houtman. 2008) |
The major offenders, as far as chances of
immediate (cf. red box in
part 1 of this article) progesterone-related side effects are concerned, are yet the
norethisterone derivatives (relative potencies compared to
progesteron)
- 11b-ethynyl-NET - 880%
- delta-15-NET - 290%
- 11b-ethenyl-NET - 262%
- 6a-methyl-NET - 253%
- 11b-I37ethyl-NET - 139%
I guess, you probably already suspect that
these are agents in progesterone-only or combined contraceptive pills. So, in essence nothing athletes will be using.
The
7-alpha-methylated derivate of the progestin nethisterone, 7a-methyl-NET, however, has an
androgen/progesterone activity ratio of 427/8. Now, although the respective values for
trenbolone and
nandrolone are only 442/35 and 327/7 this does not necessarily go to tell you that it would make a powerful mass builder, especially in view of the results of previous studies using CHO-AR reporter gene assays, according to which
nandrolone (I do not have data on trenbolone, here) has a 1.6x higher androgen receptor binding affinity than the aforementioned
nethisterone derivate.
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Image 2: The dissection of the
prostate (image by Gray. 2005) is
an unsavory, yet obligatory part
of the Hershberger assay, an in-
vivo method to evaluate the
androgenic activity of steroids
that was developed by
T.V. Hershberger in the 1960s. |
Different tests, different results: Most of the data you will currently find
on message-boards and certain webpages is based on the
"old" CHO-AR
reporter gene assays, the results of which often contradict relative
activity levels measured by
AR CALUX. According to the CHO-AR gene assay, for example the
nandrolone would be the more potent androgen receptor agonist (2.65x more potent,
Sonneveld. 2005). According to the
Chemical
Activated
Luciferase gene e
Xpression test, on the other hand, its almost the other way around. Lastly, according to the
good old Hershberger-test, which was developed in the 1960 and '70s as an in-vivo procedure to evaluate the androgenic activity of steroids in rats,
7a-methyl-NET has 6.25x the androgenic activity of
nandrolone. While it is likely that the CALUX assay is the most reliable method, when it comes to the exact cellular mechanisms, the good old Hershberger-tests, Julius Vida (the "Vida" from "Vida's Book") used, as well, still have their merit, as they provide some insight into what may happen when the compound is administered to an actual living organism.
Similar to the WADA-prohibited compounds, where with the exception of
4-chloro-19-nor-T, 19-norclostebol (4%) and
19-nor-androstenediol (1%) most of the compounds that have been tested exhibited <1% of the receptor activity of
estradiol at both the estrogen beta and alpha receptors,
compared to estradiol none of the tested (estrogen receptor transcriptional activity was measured for only 10 out of 36 androgens)
compounds had significant estrogenic activity.
7a-methyl-NET, the progestin discussed in the previous paragraph, for example has a relative potency of 0.038%, which is more than 4x higher than the 0.009% potency of
nandrolone, yet still less than half of the activity of DHEA (0.081%).
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| Figure 3: Relative potency of steroid metabolits at the androgen receptor, note that I re-calculated the
values relative to testosterone as a new reference, this means that you have to
divide the values by 4.68 to get DHT as a reference, as in Part 1, fig. 2 (data calculated base on Houtman. 2008) |
Similarly, out of the
less-androgenic (cf. figure 3) metabolites and isomers Houtman et al. actually tested, only
5a-androstane-3b,17b-diol (0.543%) and
4-androstenediol (4-AD) (0.125%) presented significant interactions with the estrogen beta receptor (0.039% and 0.012% at the alpha receptor).
If I may remind you of the the high transcriptional activity of
nandrolone and
trenbolone, I've discussed in the
first part of this article, which corresponds well with the progesterone related side-effects many athletes complain about,
the
relatively high activity of 4-AD at the estrogen receptor (25x higher than testosterone) in the CALUX assay is yet another sign for the real-world relevance of the luciferase assay data (cf. red box "
Different tests, different results"). After all,
androst-4-ene-3b,17b-diol, which happens to be one of the pro-hormones that has lately re-appeared on the "supplement" market, is well-known to be one of the "wetter" compounds.
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| Figure 4: Relative potency of several natural and synthetic steroids at the corticosteroid receptor with cortisol as a reference (data calculated based on Houtman. 2008) |
Finally, we will have
a brief look at those steroids which mess with the glucocorticoid receptor. Other than the usual suspects in figure 4, only
fluoxymesterone (0.27%),
5a-hydrogen-11b-methyl-NET (0.52%),
11b-methyl-19-nor-T (1.97%),
7a-methyl-19-nor-T aka "Trestolone" or "MENT" (1.56%) and
progesterone (0.65%) exhibit any notable corticosteroid activity (expressed relative to the potency of cortisol). However,
nandrolone, trenbolone and other anabolics with progestational activity appear to exert indirect effects on the mammalian corticosteroid metabolism (
Moor. 1971) and may thus induce downstream effects the CALUX assay obviously cannot detect (suggested read: red box on DHEA and aromatization in
part 1 of this article).
With the issue of literal "side-effects", i.e. effects not related to direct transcriptional activity at the receptor sites, I want to conclude this two part series on the immediate effects of a broad range of androgens on androgen, progesterone, estrogen and corticosteroid receptors by reminding you of the fact that
despite an ever-increasing accuracy and the constant development of even more sophisticated analytical methods, there still is (and probably never will be) a machine, where you insert a certain molecule, press a few buttons and get a print out that says: "Person A; age: 25, sex: male; training: 5x a week; nutrition: [...] will gain Xlbs of lean mass and shed Ylbs of fat on a Z-week cycle of XYZmg of compound ALPHA".
