These ncRNAs are found all over the genome. Some come from introns. Originally it was assumed that the spliced-out bits of mRNA from the introns get degraded by cells. It now seems much more likely that at least some (if not all or most) are actually processed to act as functional ncRNAs in their own right. Others overlap genes, frequently transcribed from the opposite strand to the protein-coding mRNA. Yet others are found in regions where there are no protein-coding genes at all.
We met two ncRNAs in the last chapter. These were
In addition to X inactivation, long ncRNAs also appear to play a critical role in imprinting. Many imprinted regions contain a section that encodes a long ncRNA, which silences the expression of surrounding genes. This is similar to the effect of
The
This finding was particularly important as it provided some of the first insights into a question that had been puzzling epigeneticists. How do histone modifying enzymes, which put on or remove epigenetic marks, get localised to specific regions of the genome? Histone modifying enzymes can’t recognise specific DNA sequences directly, so how do they end up in the right part of the genome?
The patterns of histone modifications are localised to different genes in different cell types, leading to exquisitely well-regulated gene expression. For example, the enzyme known as EZH2 methylates the amino acid called lysine at position 27 on histone H3, but it targets different histone H3 molecules in different cell types. To put it simply, it may methylate histone H3 proteins positioned on gene A in white blood cells but not in neurons. Alternatively, it may methylate histone H3 proteins positioned on gene B in neurons, but not in white blood cells. It’s the same enzyme in both cells, but it’s being targeted differently.
There is increasing evidence that at least some of the targeting of epigenetic modifications can be explained by interactions with long ncRNAs. Jeannie Lee and her colleagues have recently investigated long ncRNAs that bind to a complex of proteins. The complex is called PRC2 and it generates repressive modifications on histones. PRC2 contains a number of proteins, and the one that interacts with the long ncRNAs is probably EZH2. The researchers found that the PRC2 complex bound to literally thousands of different long ncRNA molecules in embryonic stem cells from mice[134]. These long ncRNAs may act as bait. They can stay tethered to the specific region of the genome where they are produced, and then attract repressive enzymes to shut off gene expression. This happens because the repressive enzyme complexes contain proteins like EZH2 that are capable of binding to RNA.
Scientists love to build theories, and in some ways a nice one was shaping up around long ncRNAs. It seemed that they bind to the region from which they are transcribed, and repress gene expression on that same chromosome. But if we go back to our analogy from the start of this chapter, we’d have to say that it’s now becoming clear we have built a pretty small shed and already cemented quite a bit of rubble to the roof.
