Interaction with Telomerase Telomerase is the ribonucleoprotein responsible for adding species-dependent tandem repeat sequences (TTAGGG in humans) to the ends of telomeres. These telomeric repeats function to protect the ends of the chromosome from
DNA damage or end-to-end fusion with adjacent chromosomes. Since evidence has also shown that TERRA expression is regulated in a telomere-length-dependent manner, while functioning as a positive regulator of telomerase activity at short telomeres however evidence of this relationship
in vivo remains elusive.
TERRA & Telomerase at Short Telomeres In seemingly contradictory fashion, it is believed that TERRA may instead coordinate the recruitment of telomerase and encourage subsequent telomere elongation for cells containing short telomeres. Specifically in short telomeres of yeast, evidence suggests that TERRA molecules help to form clusters with the yeast telomerase RNA TLC1. These clusters, known as T-Recs, have been shown to preferentially localize to short telomeres and may therefore encourage telomerase-based elongation. Furthermore, proteins that preferentially bind the UUAGGG repeats within TERRA molecules, such as the heterogeneous nuclear ribonucleoprotein
hnRNP1A, have been shown to prevent the direct TERRA-telomerase inhibition found at short telomeres, thus promoting telomerase-mediated elongation. The true nature of TERRA's interaction with telomerase remains incompletely described. However, it remains clear that the ability of telomerase to add telomeric repeats to the ends of chromosomes is intricately intertwined with its interaction with TERRA.
Heterochromatin Regulation In general, long non-coding RNAs are known to mediate
epigenetic changes on chromatin by functioning as recruiters for chromatin-modifying enzymes to genomic loci. TERRA is thought to play a similar role, recruiting both heterochromatic proteins and associated chromatin-remodeling complexes to telomeres, helping to establish or maintain heterochromatin formation. One manner in which chromatin maintains its condensed hetererochromatic state at the telomere is through the enzymes
DNA methyltransferases 1 and 3b (
DNMT1/3b). Experiments where these factors have been depleted result in increased TERRA expression levels, suggesting that methylation status of the subtelomeric region may help to regulate the expression of TERRA. Further post-translational modifications of telomeric histones may also play a pivotal role in TERRA regulation. Decreased density of trimethylated histones
H3K9me3 and H4K30me3 have been shown to correlate with increased TERRA levels. RNA pulldown experiments have also shown that TERRA associates with heterochromatin proteins, including
HP1α,
HP1β, and the origin recognition complex (
ORC). These factors are known to play a role in establishment of heterochromatin and subsequent transcriptional silencing. TERRA-mimicking oligonucleotides have also been shown to associate with other chromatin remodeling complexes such as the
NuA Histone Acetyltransferase Complex,
BAF-Type SWI/SNF Nucleosome Remodeling Complex, and the NoRC
Chromatin Remodeling Complex. It is believed that TERRA may work to stabilize the interaction of these factors with chromatin to promote heterochromatin formation. Overall, evidence has shown a complex relationship whereby TERRA can both regulate the heterochromatic state and be regulated by the heterochromatic state. Increased density of repressive histone marks that cause chromatin to become more condensed correlate with observed decreases in TERRA expression. Concurrently, epigenetic changes that result in chromatin becoming more euchromatic or "open" in nature correlates with increased TERRA expression. Listed above are factors shown to contribute to modulating TERRA expression, but this is by no means an exhaustive list.
Regulation of Telomere Length TERRA has been shown to exist exclusively within the nucleus of
eukaryotic cells where it specifically associates with the ends of chromosomes at the telomere. While TERRA has not been shown to be an essential or permanent component of telomere chromatin, it is believed that TERRA's primary function is to transiently maintain the structural integrity at
telomeres, either through direct interaction with telomeric DNA or by the binding of associated telomeric proteins.
Direct Telomeric Interactions Data has shown that TERRA interacts with telomeric DNA to form
G-Quadruplex structures both
in vitro and
in vivo. These structures form due to the abundance of
guanine found in the TERRA transcript and their ability to associate through
Hoogsteen hydrogen bonding. The resulting square planar structure is known as a
guanine tetrad (also known as a G-tetrad or G-quartet) and when two or more guanine tetrads stack on top of each other, they form a G-quadruplex. These complex structures have been shown help to modulate telomere length through inhibition telomerase's ability to add tandem TTAGGG repeats, specifically in cells with long telomeres. This inhibitive effect seems to function in a telomere length-dependent manner; TERRA expression has also been shown to be cell cycle regulated via the chromatin-remodeling protein
ATRX, with the highest expression of TERRA being present at the
G1 phase following
mitosis and before progressively declining to its lowest in
S phase. In cells with long telomeres and high TERRA expression, this could potentially lead to replicative arrest and the eventual collapse of the replication fork, resulting in double-stranded breaks at the telomere. TERRA has also been indicated to be involved with the stabilization of the telomere-protecting
Shelterin complex at the ends of telomeres. Evidence shows that TERRA functions together with
hnRNPA1 to displace RPA from single-stranded DNA following replication and promotes the loading of the Shelterin component
POT1 onto telomere ends. This helps to stabilize the Shelterin complex so that it can properly cap the ends of chromosomes and protect them from recognition by DNA damage signaling pathways.
TERRA and the Alternative Lengthening of Telomeres (ALT) Pathway In cells that lack telomerase expression, it is well-established that most cells instead maintain the ends of their telomeres through the recombination-based
Alternative Lengthening of Telomeres (ALT) pathway. It is proposed that TERRA may work to delay the onset of cellular senescence in these cells and instead promote mechanisms of
homologous recombination, thereby driving the ALT phenotype as an alternative means of maintaining telomere ends. In support of this model, TERRA expression has also been shown relate to cellular ALT-status. Cells that have been experimentally confirmed to utilize the ALT pathway have markedly higher levels of TERRA expression compared to non-ALT cells. and members of the heterogeneous nuclear ribonucleoprotein (
hnRNP) family have also been shown to regulate the displacement of TERRA from the ends of telomeres. The ability of these mechanisms to actively coordinate the displacement of TERRA provides evidence that TERRA is not a stable constituent of the telomeric chromatin, but not necessarily unstable itself. Instead, the regulated control of TERRA displacement suggests a link between TERRA localization at the telomere and overall genome integrity. For example, in short telomeres with low TERRA expression, UPF1 and other SMG factors may work in concordance with
DNA Polymerase δ to remove TERRA from the telomere during replication and alleviate fork stalling to allow for progression of replicative machinery. Additionally, replication fork stalling and SMG factor recruitment may also aid in telomerase localization to the telomeres where
de novo repeats may be added to promote elongation of short chromosomes. == Proposed Role in Human Disease ==