This is so cool. Thank you.

Lex Friedman had an evolutionary biologist on his podcast, sometime in the last few months. The way he explained it was that the accumulation of simple mechanisms trend towards the more complex mechanisms via gradients, electron affinity, etc. I believe it was with Michael Levin, but I can’t play the audio to confirm right now.

I’ve had the opportunity to work with quite a few patients that were born with anatomical structures where they shouldn’t be or oriented abnormally (e.g. Apert syndrome and dextrocardia). It’s fascinating stuff from a biological standpoint.

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Your cells have, for example, some "programs" that tell them to grow and divide, and some programs that tell them to commit suicide. Those programs are normally only turned on when appropriate.

In a cancer cell, mutations cause one or more programs telling the cell to grow and divide to be constantly turned on, and the suicide programs to be broken (so even if it would be appropriate, they will not commit suicide).

There are some other programs that tend to be broken in cancer cells too, but those are two of the main ones.

You're not wrong. Think of cells as a factory making a product. In cancer, not only is the product wrong but you can't shut off the factory. Also why cancer is so awful if you get it younger. To go back to the factory analogy, in a young person, the factory is shiny and new and efficient, so it makes the cancer really fast. Whereas in an older person, the factory already isn't in the greatest of shape, even before the cancer.

Cells are always having a few mutations in their DNA, but there are systems in the cell that will recognize excess mutations and kill the cell before it can cause problems.

Things can really start to get out of hand when you get mutations in those proofreading systems themselves. Then you get a set of cells that can start mutating freely. Eventually natural selection takes over and the mutant cells keep accumulating more and more mutations that help them replicate and spread, leading to cancer.

Cells have a variety of processes going on inside of them to do things like maintain homeostasis, replicate, fix DNA errors, produce power, etc. They even have machinery to self terminate when something goes wrong.

In a cancer cell one of the processes has broken down and the self termination process has ALSO broken down. Once that's happened you essentially have a rogue cellular factory inside of your body that can hijack the resources you need to survive and can replicate itself going from one cell to enough to kill you by any number of factors. The cancer could just physically put pressure on organs like the brain. It could produce a wild amount of signaling hormones therefore causing secondary non-cancerous cells to follow erroneous instructions. It could also take over resources that other parts of your body need to survive.

Pretty much. They don't do much normal stuff beyong replication and releasing hormones that stimulate capillary growth to keep them fed.

Thats about it they stop listening to the "cyclins" that regulates cell replication. This is usually quite common and the body can destroy the cells as long as theyre recognised. When they arent recognised and grow out of control it can get out of hand.

It's really hard to explain in words even in a book let alone in a few paragraphs.

Perhaps an analogy:

Langton's Ant is a mathematical curiosity. The idea is an infinite grid. The 'ant' is a marker with position and direction and gets set in motion from anywhere in any direction (the grid is infinite and uniform so it makes no difference). When the ant lands on a cell (a grid square), if the cell is white it turns it black and turns right, if the cell is black it turns it white and turns left. The future behaviour of the ant and the grid is entirely determined by those two rules and the colour-scape of the grid. No other information is present. But the picture it creates is immensely complicated.

Fractals like the Mandelbrot Set and Julia Sets could be another example.

A simple set of iterated rules can produce a very complicated structure and do so repeatedly and reliably. If you don't change the rules you'll always get the same structure.

The degrees of separation between the rules that DNA (combined with all sorts of biochemistry) provide and the physical structures they lead to are as a chasm but they are still pretty reliable and predictable so clones will reliably look almost exactly the same as each other (same rules, same outcome).

Another analogy would be trying to understand how a sequence of zeroes and ones, or the simple rules of machine code, can lead to what we can achieve even just nowadays with AI (outthinking grandmasters at Chess, generating convincing art, etc). It boggles the mind (or should). The rules of DNA (and their interaction with all sorts of biochemistry) are arguably much more complex and varied than machine code so it shouldn't really come as a surprise that it can produce an infinitude of possible biological shapes and yet do so as predictably and consistently as a computer program.

Does that make sense?

Since you get half of your genes from each parent, getting the specific let's say ALIGNMENT of the expression of genes is why your nose looks the same.