How one protein domain changed through time.
The BRCA1 and BRCA2 genes are notorious for harboring mutations that increase susceptibility to breast cancer (thus their name, breast cancer type 1 (or 2) susceptibility protein). They have therefore been intensively studied for what they do in the normal course of our cellular lives. Their common naming does not mean they are similar- their structures are completely different. They play related, but distinct, roles in DNA repair, which is naturally influential in our susceptibility to cancer caused by DNA mutations.
An article some time back delved into the history of one domain of the BRCA1 protein, tracing how its functions have changed significantly over evolutionary time. BRCA1 is a large gene encoding a large protein, (1863 amino acids long), composed of several domains. Proteins frequently possess several domains in order to integrate several functions in an orderly way, such as binding a few different partners that together form a complex and carry out some function. Modular protein domains facilitate evolution by being easily duplicated, transferred, and generally being able to be passed around, thanks to rearrangement mutations. BRCA1 has domains that bind to at least 11 other proteins, most of which play some role in DNA damage responses. So it is a key protein, and damage to it has correspondingly bad effects.
The domains of BRCA1. Each one has some role in the protein's function, which integrates responses to DNA damage. The BRCT domains are on the very end, right side. NLS is nuclear localization (import) sequence, and NES is the nuclear export signal. These would be typically regulated by other interacting proteins or phosphorylation, to control the access of BRCA1 to the nucleus. |
The domain of interest here is the BRCT, or BRCA1 C-terminal domain. It is ~90 amino acids long and BRCA1 has two of them, side by side. Other work has shown that it binds to other proteins, but only after they have been modified by phosphate addition. The DNA damage sensor ATM is one such kinase that adds phosphates to BRCA1 targets such as Abraxis. Thus the BRCT domain plays the key role of bringing this DNA damage repair integrating protein to the right sites, where there is DNA damage to repair.
Structure of the BRCT double domains in BRCA1 (E). The pocket that binds a phosphorylated serine residue on a partner protein such as abraxis is shown in teal, and in (C), close up. (B) shows a single BRCT domain. |
This paper did a sensitive computer search for all possible versions of this domain in all available species and proteins, finding it in 23 human proteins, and in species all the way back to bacteria, so is quite ancient. And the phylogeny they reconstruct indicates that the original versions of these domains had a different function, which was to bind DNA directly, at sites of DNA damage! Such frayed ends also have phosphate groups, so it isn't a huge leap from one function to another. Additionally, other examples of BRCT domains have dispensed with phosphate-dependent binding altogether, but simply bind other proteins regardless. This transition may have happened after phosphorylation became the central way to alert the cell, and key proteins, to the existence of DNA damage, instead of dealing with it solely through enzymes that find & fix such damage directly. This transition allowed a much more robust response by cells, which now includes halting the cell division cycle and activating other stress responses to help the cell recover.
Some of the BRCT domains (along with many others) found in various species and their proteins. |
The BRCT domain is mostly used among proteins involved in DNA repair, and even in humans some versions bind DNA directly (PARP1, RFC1). So through the long path of evolution, this single domain has stuck generally to its original role, while it also- along with the organisms and proteins it acts within- diversified and ramified in its functions. From an initial role in direct DNA damage and end recognition, it has become a card-carrying member of the bureaucracy of the cell, playing regulatory and organizing roles within numerous actors important to DNA handling and repair. It is a classic story of how eukaryotes used their surfeit of energy and material resources to develop whole orders of novel molecular, and concomitant outward, complexity.
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