I knew that cyclobutane existed (a ring of four carbon atoms with attached hydrogen atoms which is 'weird' in the sense that the angles between the bonds are not what would be expected for a carbon atom with four bonds [0]) but learned about the existence of ladderanes today. Their structure looks just soo unusual.
It's interesting that one group of compounds is named using the Latin, in this case for "window" (fenestrane), but "ladderane" makes use of an ordinary English word (by way of Old English and Germanic).
I guess I would have expected a Latin-derived name like "escalane" instead.
The common names for compounds/compound classes like this are usually just left to the person that discovers them. The standardized naming scheme is set by the IUPAC and the name that you get for any reasonably complicated molecule will be a mouthful.
I glanced at the structures first before reading the text and assumed they were oddballs synthesized in the lab. It’s incredible that these are all natural products. Leptocillin also looks astonishingly weird.
And the last example from the article, a tetrasubstituted cyclobutane, probably tells you that the functional groups connected to the cyclobutane could alleviate some of the ring strain in plain cyclobutane.
Similarly, cyclopropane also has incredible ring strain and likely won't be found in nature, but plenty of derivatives can.
Interestingly, cyclobutane and cyclopropane do not have a large difference in ring strain (within about 4% of each other).
Cyclopropanes are well known in natural product structures.
One of the weirdest is this natural product, U-106305, which has 6 cyclopropanes. Made by a strain of Streptomyces!
https://pubs.acs.org/doi/pdf/10.1021/ja9619420
It's not my space, so I don't often read his articles or necessarily recognize his name when it comes up. For me it's the writing style and fear of flourine that I end up recognizing.
I'm ever conflicted with the opposing forces of climate change and meeting the energy needs of our growing and innovative civilization.
Evolution has produced a bountiful assortment of living, breathing solutions that fit into every nook and cranny of our biological state space. Millions of years of adaptation have produced sometimes incredibly niche systems that beautifully capture all of the energy available to them. The biochemical pathways nature discovers are fascinating and complex and of an altogether different nature than what our human innovation capital can find or produce.
So it's incredibly depressing that we're losing all of this amazing biodiversity. A moss or fungus might have more information in its genes - biochemical pathways, metabolic flux, finely tuned balance, encodings of adaptations beyond our understanding, etc. etc. - than the sum total of all human thought thus far. And that's not even considering the non-molecular, ecosystem and even biogeochemical impact these losses can have.
But if we stop building and consuming and making, the plates come crashing down. Our sun burns out. The universe will never know of us.
It's all so complicated. I'm glad we can appreciate these little wonders, though.
Thank you for posting this article. Chemistry is beautiful.
If there is anything out there with the capacity to "know", perhaps one day they'll find our ruins and compose some art along the lines of Shelley's poem Ozymandias. As I've been enjoyed the sci-fi of Adrian Tchaikovsky of late[0], I hope that it's sentient octupuses who can express the tragedy and mystery of our downfall in a dance of colour and movement.
"Extractions and Ire" on YouTube has been having a go at synthesizing a cubane, while the creator does "meme" a lot, it is good chemistry. And a really weird molecule.
https://en.wikipedia.org/wiki/Ladderane
Speaking of unusual structures, here is something like a 2D version of a ladderane:
https://en.wikipedia.org/wiki/Fenestrane
[0] https://en.wikipedia.org/wiki/Orbital_hybridisation#sp3