Natural products were used as drugs long before there was a
drug industry, and there is a case to be made that they make good starting
points for lead discovery. For one thing, they tend to be more
“three-dimensional” than many synthetic molecules. For another, the fact that
some organism, somewhere, made them proves that they can bind to proteins. Practical Fragments has previously
highlighted examples in which natural products were conceptually fragmented
into smaller molecules or incorporated into a fragment library. In a new paper
in ACS Chemical Biology, Ronald Quinn
at Griffith University
and a team of Australian and US
collaborators describe a fragment library consisting entirely of natural
products.
The researchers assembled a library of 331 natural products
with the following characteristics:
- MW ≤ 250 Da (mean = 195.6)
- ClogP < 4 (mean 0.4)
- hydrogen bond donors ≤ 4 (mean 1.3)
- hydrogen bond acceptors ≤ 5 (mean 2.6)
- rotatable bonds ≤ 6 (mean 2.2)
- polar surface area ≤ 45% (mean 17.7%)
The maximum number of donors and acceptors allowed is slightly higher than typical in a fragment library, consistent with the fact that natural products tend to have more oxygen and nitrogen atoms than your typical Suzuki-derived biphenyl. However, the molecular weights are kept low, and despite the tolerance for more lipophilic molecules, the vast majority of the library has ClogP < 3 (with many molecules having ClogP < 0).
Having assembled the library, the researchers used native mass spectrometry to screen pools of eight fragments against the malarial
enzyme Plasmodium falciparum 2′-deoxyuridine
5′-triphosphate nucleotidohydrolase (PfdUTPase).
They found that a molecule called securinine binds to the enzyme, and six
analogs also showed varying degrees of binding as assessed by mass
spectrometry.
At this point things get a bit strange. Most of the
molecules show some anti-plasmodial activity in culture, but they all seem to
modestly activate PfdUTPase. It is unclear whether these
two observations are mechanistically related: is the activation of PfdUTPase really what’s causing the
anti-plasmodial activity, or are the molecules hitting a different target?
In fact, securinine comes up as a hit in a variety of
different biological assays. Looking at the molecular
structure this is perhaps not surprising: it contains a reactive electrophilic
center that has previously been shown to react with amines under mild
conditions, so presumably it can react with all sorts of biological
nucleophiles in vivo. This is not to say that covalent inhibitors are
unacceptable – dimethyl fumarate looks set to become a blockbuster drug – but
it is nice to know if you are dealing with them, and the authors seem not to have considered the possibility.
In the end, I do think libraries of natural products such as
these could be useful, but they will require care in their construction, use,
and interpretation. Just as there are many synthetic compounds best left out of
screening collections, the same goes for natural products. Toxoflavin, for
example, is a notorious redox cycling PAIN that has (embarrassingly) been
reported as an inhibitor for multiple targets with no evidence for specificity. I’m not ready to put securinine
into this category, but I would urge caution.
Just because something is natural doesn’t mean it’s healthy.
Interesting take on NP. My belief (which is likely wrong) is part of the problem with NP is that the chemistry is REALLY tough and thus doing SAR on them is almost impossible. So, outside of the rare cases where there are some easily available related compounds, where does this lead you?
ReplyDeleteI have not seen the structures of the rest of the natural product fragment library, but I guess many are relatively simple structures? If so the chemistry should be more traceable.
ReplyDeleteMebbe, but the one hit they showed has plenty of chirality and bridging carbons.
ReplyDeleteThere's quite a few natural products that have become drugs without any modification at all, or are derived from isolated NPs (ex. a fair chunk of our antibiotics).
ReplyDeleteAn SAR screen is always welcome, but not always mandatory.
SAR can indeed be challenging with natural products. However, since many of them have been the object of chemical manipulation for decades there is often a rich literature on analoging. Securinine itself, for example, can be readily aminated enantioselectively. That said, more fundamental changes in the skeleton are not necessarily trivial; a 2009 total synthesis of securinine is 10 steps, though with a relatively high (20%) overall yield.
ReplyDeleteAlthough bound by pace and the unforgiving laws of economic patience, this is a very exciting approach. To Dr. Teddy, sure the SAR is harder -- hire some chemists -- but as with all natural products the potential advantage is that the bio-availability issues have been prescreened by the laws of natural selection.
ReplyDeletePlease excuse my ignorance, but how far does the NP have to be modified during the SAR process to become novel IP that may be patent-protected (and thus, profitable)?
ReplyDeleteDoes this impact the utility of fragment NP libraries vs synthetic fragment libraries?