Biological complexity: cell pore complex controls (Introduction)

by David Turell , Monday, May 04, 2020, 19:05 (1452 days ago) @ David Turell

More complexity described:

https://phys.org/news/2020-05-nuclear-pore-puzzle-super-resolution-microscopy.html

"The results reveal that most Nuclear Envelope Transmembrane (NET) proteins travel into the cell's nucleus through small tunnels, known as peripheral channels, whose existence has long been debated by scientists.

"Mistakes in the location or function of NET proteins are linked to many human diseases such as muscular dystrophies, cardiomyopathy, blood and bone disorders, and cancers.

"Most soluble proteins travel via Nuclear Pore Complexes (NPCs), vast tunnel-like structures spanning the nuclear envelope—the protective membrane that surrounds the nucleus, the command centre of the cell.

"'NPCs are one of the cells most important molecular machines, controlling the transport of proteins and RNA into and out of the nucleus, but their size and complexity has led to many different theories emerging on NET protein transport." says a lead author of the study, Professor Eric Schirmer at the University of Edinburgh.

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"The study is the first to find conclusive functional proof of the existence and importance of smaller peripheral channels, at the edge of central NPC channels, for NET protein transport.

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"Blocking the NPC tunnels did not disrupt transport, although the team found that 10% of NET proteins straddle both tunnels, using them simultaneously for faster and more efficient transport.

"'Nobel Laureate Gunter Blobel was a visionary in his suggesting that the NPCs—huge tunnel complexes containing hundreds of structural proteins—were highly plastic and dynamic." says Schirmer. "This is underscored by this study where NETs simultaneous usage of both central and peripheral channels could only happen if the NETs effectively slice through this dynamic protein complex.'"

Comment: If this degree of complexity doesn't convince a designer is needed and does exist, nothing will.