Control of mRNA turnover: implication of cytoplasmic RNA granules

The control of mRNA turnover is essential for the cell to rationalize its mRNA content both under physiological conditions and upon stress. Several mechanisms involved in the control of mRNA turnover have been elucidated. These include surveillance mechanisms such as nonsense-mediated decay, non-stop mediated decay and non-go-mediated decay that eliminate aberrant mRNAs, and regulatory mechanisms including AU-mediated decay, GU-mediated decay, and CDE-mediated decay that ensure mRNA plasticity. In general, the mechanisms of RNA decay rely on interactions between specific cis-acting RNA elements and selected RNA-binding proteins that either prevent the degradation of mRNA targets or induce the recruitment of decaying effectors leading to mRNA degradation. Formation of cytoplasmic RNA granules including processing bodies, stress granules, UV granules, and exosome granules have recently emerged as an additional mechanism that control mRNA turnover of selected mRNAs. Here we will review briefly review the main mechanisms that control mRNA decay and highlight possible implication of RNA granules in such mechanisms.

[Allele-specific therapy: suppression of nonsense mutations by readthrough inducers]

Ten percent of human hereditary diseases are linked to nonsense mutations (premature termination codon). These mutations lead to premature translation termination, trigger the synthesis of a truncated protein and possibly lead to mRNA degradation by the NMD pathway (nonsense mediated mRNA decay). For the past ten years, therapeutic strategies have emerged which attempt to use molecules that facilitate tRNA incorporation at premature stop codon (readthrough), thus allowing for the synthesis of a full length protein. Molecules currently used for this approach are mostly aminoglycoside antibiotics (gentamicin, amikacin…) that bind the decoding center of the ribosome. This therapeutic approach has been studied for various genetic diseases including Duchenne muscular dystrophy (DMD) and cystic fibrosis. The feasibility of this approach depends on induced readthrough level, mRNA quantity, re-expressed protein functionality and characteristics of each disease.

[<< Catch me if you can >>: how the structural and functional integrity of eukaryotic RNA molecules is monitored by surveillance mechanisms]

Cellular RNAs are invariably organized in ribonucleoprotein particles, or RNPs, regardless of their size, structure or function. RNPs are monitored by active surveillance mechanisms for their structural and functional integrity at every single step of their "life". A limited number of key endoRNase and/or exoRNase activities are recruited to multiple metabolic pathways by specific adaptors. These trans-acting factors are often endowed with synthesis activities in the formation of mature RNA termini, as well as degradation and surveillance activities. Quality control mechanisms are robust because they are partially redundant. The actual mechanisms that discriminate aberrant RNAs from normal RNAs are still loosely defined. Surveillance is essential to cellular homeostasis and has been linked to several human diseases.

[RNase L, a crucial mediator of innate immunity and other cell functions]

The 2-5A/RNase L pathway is one of the first cellular defences against viruses. RNase L is an unusual endoribonuclease which activity is strictly regulated by its binding to a small oligonucleotide, 2-5A. 2-5A itself is very unusual, consisting of a series of 5'- triphosphorylated oligoadenylates with 2'-5' bonds. But RNase L activity is not limited to viral RNA cleavage. RNase L plays a central role in innate immunity, apoptosis, cell growth and differentiation by regulating cellular RNA stability and expression. Default in its activity leads to increased susceptibility to virus infections and to tumor development. RNase L gene has been identified as HPC1 (Hereditary Prostate Cancer 1) gene. Study of RNase L variant R462Q in etiology of prostate cancer has led to the identification of the novel human retrovirus closely related to xenotropic murine leukemia viruses (MuLVs) and named XMRV.

[Aberrant regulation of mRNA 3' untranslated region in cancers and inflammation]

Almost 10% of mammalian coding mRNAs contain in their 3' untranslated region a sequence rich in adenine and uridine residues known as AU-rich element (ARE). Many of them encode oncogenes (for instance c-Myc and c-Fos), cell cycle regulators (cyclin D1, A1, B1), cytokines (TNFalpha, IL2) and growth factors (GM-CSF) which are overexpressed in cancer or inflammatory diseases due to increased mRNA stability and/or translation. AREs are recognized by a group of proteins, collectively called AUBPs which display various functions. For instance, HuR/ELAV is mainly known to protect ARE-containing mRNAs from degradation, while AUF1, TTP and KSRP act to destabilize their bound target mRNAs and TIA/TIAR to inhibit their translation. Alterations in ARE sequences or AUBP abundance, cellular localization or activity due to post-translational modifications such as phosphorylation can promote or enhance malignancy or perturb immune homeostasis. Here, c-myc and TNFalpha are chosen as examples to illustrate how altered 3' UTR gene regulation impacts on pathologies.