Basically, you see these 3D representations of specific proteins as a crumple of ribbons-- literally like someone ran multi-colored ribbons though scissors to make curls and dumped it on the floor (like a grade school craft project).
So... I understand that proteins are huge organic molecules composed of thousands of atoms, right? Their special capabilities arise from their structure/shape. So basically the molecule contorts itself to a low energy state which could be very complex but which enables it to "bind?" to other molecules expressly because of this special shape and do the special things that proteins do-- that form the basis of living things. Hence the efforts, like Alphafold, to compute what these shapes are for any given protein molecule.
But what does one "do" with such 3D shapes?
They seem intractably complex. Are people just browsing these shapes and seeing patterns in them? What do the "ribbons" signify? Are they just some specific arrangement of C,H,O? Why are some ribbons different colors? Why are there also thread-like things instead of all ribbons?
Also, is that what proteins would really look like if you could see at sub-optical wavelength resolutions? Are they really like that? I recall from school the equipartition theorem-- 1/2 KT of kinetic energy for each degree of freedom. These things obviously have many degrees of freedom. So wouldn't they be "thrashing around" like rag doll in a blender at room temperature? It seems strange to me that something like that could be so central to life, but it is.
Just trying to get myself a cartoonish mental model of how these shapes are used! Anyone?
This is hugely important for developing drugs and vaccines.
To see the effect of this look no further than prions. Prions are the exact same protein that are folded in weird ways. Worse, they can "transmit" this misfolded shape to other otherwise normal proteins. Prions behave differently just because of the different shape and can lead to disease. This is exactly what Mad Cow's Disease (BSE) is.
What we get taught in high school about chemistry is incredibly oversimplified.
One example of this I like is the geometry of a water molecule. When we first learn about atoms, we learn the "solar system" model (aka Bohr). The reality is instead that we have 3D probability distributions of where electrons might be. These clouds are in pairs. I believe this is to do with the inverted wavefunction really we're getting beyond my knowledge of quantum mechanics here so that's just a guess.
Well those clouds additionally form valence shells. We learn about these and how atoms want to form completely valence shells. So Oxygen has 8 electrons ie 4 pairs of electrons. When bonding with 2 hydrogen atoms we end up with a weird geometry of ~104.5 degrees between the two hydrogen atoms because of how these pairs interact. The naive assumption might expect that the two hydrogen atoms are 180 degree apart.
So back to proteins, you may have learned about hydrogen bonds. This affects molecular shape because when a hydrogen atom shares an electron, it is often positively charged. That positive charge pushes away other positive charges. This is the realy difficulty in protein folding because with a molecule of thousands of atoms and weird geometry you may find distant parts of the molecule interacting with hydrogen bonds.
So a single cell consists of thousands (IIRC) of different proteins. Figuring out those interactions is important but incredibly difficult.