Saturday, February 15, 2025

Cloudy, With a Chance of RNA

Long RNAs play structural and functional roles in regulation of chromosome replication and expression.

One of the wonderful properties of the fruit fly as a model system of genetics and molecular biology has been its polytene chromosomes. These are hugely expanded bundles of chromosomes, replicated thousands of times, which have been observed microscopically since the late 1800's. They exist in the larval salivary gland, where huge amounts of gene expression are needed, thus the curious evolutionary solution of expanding the number of templates, not only of the gene needed, but of the entire genome. 

These chromosomes where closely mapped and investigated, almost like runic keys to the biology of the fly, especially in the day before molecular biology. Genetic translocations, loops, and other structural variations could be directly observed. The banding patterns of light, dark, expanded, and compressed regions were mapped in excruciating detail, and mapped to genetic correlates and later to gene expression patterns. These chromosomes provided some of the first suggestions of heterochromatin- areas of the genome whose expression is shut down (repressed). They may have genes that are shut off, but they may also be structural components, such as centromeres and telomeres. These latter areas tend to have very repetitive DNA sequences, inherited from old transposons and other junk. 

A diagram of polytene chromosomes, bunched up by binding at the centromeres. The banding pattern is reproducible and represents differences in proteins bound to various areas of the genome, and gene activity.

It has become apparent that RNA plays a big role in managing these areas of our chromosomes. The classic case is the XIST RNA, which is a long (17,000 bases) non-coding RNA that forms a scaffold by binding to lots of "heterogeneous" RNA-binding proteins, and most importantly, stays bound near the site of its creation, on the X chromosome. Through a regulatory cascade that is only partly understood, the XIST RNA is turned off on one of the X chromosomes, and turned on the other one (in females), leading the XIST molecule to glue itself to its chromosome of origin, and then progressively coat the rest of that chromosome and turn it off. That is, one entire X is turned into heterochromatin by a process that requires XIST scaffolding all along its length. That results in "dosage compensation" in females, where one X is turned off in all their cells, allowing dosage (that is, the gene expression) of its expressed genes to approximate those of males, despite the presence of the extra X chromosome. Dosage is very important, as shown by Down Syndrome, which originates from a duplication of one of the smallest human chromosomes, creating imbalanced gene dosage.

A recent paper described work on "ASAR" RNAs, which similarly arise from highly repetitive areas of human chromosomes, are extremely long (180,000 bases), and control expression and chromosome replication in an allele-specific way on (at least) several non-X chromosomes. These RNAs, again, like XIST, specifically bind a bunch of heternuclear binding proteins, which is presumably central to their function. Indeed, these researchers dissected out the 7,000 base segment of ASAR6 that is densest in protein binding sites, and find that, when transplanted into a new location, this segment has dramatic effects on chromosome condensation and replication, as shown below.

The intact 7,000 base core of ASAR6 was transplanted into chromosome 5, and mitotic chromosomes were spread and stained. The blue is a general DNA stain. The green is a stain for newly synthesized DNA, and the red is a specific probe for the ASAR6 sequence. One can see on the left that this chromosome 5 is replicating more than any other chromosome, and shows delayed condensation. In contrast, the right frame shows a control experiment where an anti-sense version of the ASAR6 7,000 base core was transplanted to chromosome 5. The antisense sequence not only does not have the wild-type function, but also inhibits any molecule that does by tightly binding to it. Here, the chromosome it resides on (arrows) is splendidly condensed, and hardly replicating at all (no green color).


Why RNA? It has become clear over the last two decades that our cells, and particularly our nuclei, are swimming with RNAs. Most of the genome is transcribed in some way or other, despite a tiny proportion of it coding for anything. 95% of the RNAs that are transcribed never get out of the nucleus. There has been a growing zoo of different kinds of non-coding RNAs functioning in translational control, ribosomal maturation, enhancer function, and here, in chromosome management. While proteins tend to be compact bundles, RNAs can be (as these ASARs are) huge, especially in one dimension, and thus capable of physically scaffolding the kinds of structures that can control large regions of chromosomes.

Chromosomes are sort of cloudy regions in our cells, long a focus of observation and clearly also a focus of countless proteins and now RNAs that bind, wind, disentangle, transcribe, replicate, and congregate around them. What all these RNAs and especially the various heteronuclear proteins actually do remains pretty unclear. But they form a sort of organelle that, while it protects and manages our DNA, remarkably also allows access to it for sequence-specific binding proteins and the many processes that plow through it.

"In addition, recent studies have proposed that abundant nuclear proteins such as HNRNPU nonspecifically interact with ‘RNA debris’ that creates a dynamic nuclear mesh that regulates interphase chromatin structure."