On the repair and resurrection of DNA, which gets a lot of help from a family of proteins including RAD51, DMC1, and RecA.
Proteins do all sorts of amazing things, from composing pores that can select a single kind of ion- even just a proton- to allow across a membrane, to massive polymerizing enzymes that synthesize other proteins, DNA, and RNA. There is really no end to it. But one of the most amazing, even incredible, things that happens in a cell is the hunt for DNA homology. Even over a genome of billions of base pairs, it is possible for one DNA segment to find the single other DNA segment that matches it. This hunt is executed for several reasons. One is to line up the homologous chromosomes at meiosis, and carry out the genetic cross-overs between them (when they are lined up precisely) that help scramble our genetic lineages for optimal mix-and-matching during reproduction. Another is for DNA repair, which is best done with a good copy for reference, especially when a full double-strand break has happened. Just this week, a fascinating article showed that memories in our brains depend in some weird way on DNA breaks occurring in neurons, some of which then use the homologous repair process, including homology search, to patch things up.
The protein that facilitates this DNA homology search is deeply conserved in evolution. It is called RecA in bacteria, radA and radB in archaea, and the RAD51 family in eukaryotes. Naturally, the eukaryotic family is most closely related to the archaeal versions (RAD51 and DMC1 evolving from radA, and a series of other, and poorly understood family members, from radB). In this post, I will mostly just call them all RAD51, unless I am referring to DMC1 specifically. The name comes from genetic screens for radiation-sensitive mutants in human and other eukaryotes, since RAD51 plays a crucial role in DNA repair, as noted above. RAD51 is not a huge protein, but it is an ATPase. It binds to itself, forming linear filaments with ATP at the junction points between units. It binds to a single strand of DNA, which is going to be what does the hunting. And it binds, in a complicated way, to another double-stranded DNA, which it helps to open briefly to allow its quality as a target to be evaluated.
This diagram shows how the notorious (when mutated) oncogene BRCA2 (in green) works. It binds RAD51 (in blue) and brings it, chain-gang style, to the breakpoints of DNA damage to speed up and specify repair. |
There have been several structural studies by this point that clarify how RAD51 does its thing. ATP is simply required to form filaments on single-stranded DNA. When a match has been found and RAD51 is no longer needed, ATP is cleaved, and RAD51 falls off, back to reserve status. The magic starts with how RAD51 binds the single stranded DNA. One RAD51 binds for every ~3 bases in the DNA, and the it binds the phosphate backbone, so that the bases are nicely exposed in front, and all stretched out, ready to hunt for matching DNA.
A series of RAD51 molecules (in this case, RecA from bacteria) bound sequentially to single-stranded DNA (red). Note the ATP homolog chemicals in yellow, positioned between each protein unit. One can see that the DNA is stretched out a bit and the bases point outwards. |
A closeup view of one of the RAD51 units from above, showing how the bases of the DNA (yellow) are splayed out into the medium, ready to find their partners. They are arranged in orientations similar to how they sit in normal (B-form) DNA, further enhancing their ability to find partners. |
The second, and more mysterious part of the operation is how RAD51 scans double-stranded DNA throughout the genome. It has binding sites for double-stranded DNA, away from the single-stranded DNA, and then it also has a little finger that splits open the double-stranded DNA, encouraging separation and allowing one strand to face up to the single stranded DNA that is held firmly by the RAD51 polymer. The transient search happens in eight-base increments, with tighter capture of the double-strand DNA happening when nine bases are matched, and committment to recombination or repair happening when a match of fifteen bases is found.
These structures show an intermediate where a double-stranded DNA (ends in teal and lavender, and separated DNA segments in green and red) has been captured, making a twelve base match with the stable single-stranded DNA (brown). Note how the double-stranded DNA ends are held by outside portions of the RAD51 protein. Closeup on the right shows the dangling, non-paired DNA strand in red, and the newly matched duplex DNA with green-brown colored base interactions. |
These structures can only give a hint of what is going on, since the whole process relies so clearly on the brownian motion that allows super-rapid diffusion of the stablized single-strand DNA+RAD51 over the genome, which it scans efficiently in one-dimensional fashion, despite all the chromatin and other proteins parked all over the place. And while the structures provide insight into how the process happens, it remains incredible that this search can happen, on what is clearly a quite reliable basis, day and day out, as our genomes get hit by whatever the environment throws at us.
"Unfortunately, most RAD51 and RAD51 paralog point mutations that have been clinically identified are classified as variants of unknown significance (VUSs). Future studies to reclassify these RAD51 gene family VUSs as pathogenic or benign are desperately needed, as many of these genes are now included on hereditary breast and ovarian cancer screening panels. Reclassification of HR-deficient VUSs would enable these patients to benefit from therapies that specifically target HR deficiency, as do poly(ADP)-ribose polymerase (PARP) inhibitors in BRCA1/2-deficient cells."
Lastly, one paper made the point that clinicians need better understanding of the various mutations that can affect RAD51 itself. Genetic testing now is able to find all of our mutations, but we don't always know what each mutation is capable of doing. Thus deeper studies of RAD51 will have beneficial effects on clinical diagnosis, when particular mutations can be assigned as disease-causing, thus justifying specific therapies that would otherwise not be attempted.
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