Elucidating how long 3'UTRs form and cause autoinflammation
Columbia University Health Sciences, New York NY
Investigators
Abstract
PROJECT SUMMARY The highly dynamic nature of RNA structure is key to diversifying RNA function. Notably, certain RNA structures can act as immunostimulatory molecules. Our immune system uses various pattern recognition receptors (PRRs) to detect immunostimulatory RNA molecules and trigger inflammation. PRRs are present in all immune and non- immune cells ensuring a rapid and broad immune response. Many PRRs are specialized in detecting long double-stranded RNA (dsRNA) structures, classically thought to be present in the viral genome. Interestingly, our studies, as well as the studies of others, have demonstrated that aberrant sensing of endogenous (self) dsRNAs by PRRs can cause severe autoinflammatory diseases. We recently uncovered that neurons are intrinsically enriched for long dsRNAs. In homeostasis, neuronal dsRNAs stimulated PRRs to produce low (âtonicâ) levels of type I interferon (IFN), which protected neurons from viral infection. However, when dsRNA levels were dysregulated (âtoo highâ), dsRNAs caused pathological inflammation. Therefore, neuronal dsRNA levels must be tightly regulated within a âGoldilocks zoneâ to prevent neuroinflammation. Furthermore, our findings suggest that neuronal dsRNAs could be an attractive therapeutic target to control inflammation. However, the identities of neuronal dsRNAs remain enigmatic. We recently identified three genes that induce dsRNAs in neurons. We demonstrated that neuron-enriched genes ELAVL2, ELAVL3, and ELAVL4 (HuB, HuC, and HuD) can increase (i) the length of 3â untranslated regions (UTRs), (ii) dsRNA load, and (iii) activation of dsRNA-sensing PRRs (e.g., MDA5, PKR, and TLR3). This finding indicates that dsRNA levels correlate with 3âUTR length, giving rise to the idea that 3âUTRs could be major sites for dsRNA formation in neurons. Indeed, neurons are well known to express the longest average length 3âUTR in the human body. The central hypothesis to be tested in this application is that long 3â²UTRs serve as major sources for self-dsRNAs that activate PRRs in neurons. First, we will identify additional âgenesâ that can lengthen 3âUTRs and give rise to dsRNAs (Aim 1), then we will determine the âmechanismâ of how Hu proteins lengthen 3âUTRs and increase dsRNAs (Aim 2). Lastly, we will determine the âfunctional significanceâ of 3âUTRs in a disease model for AicardiâGoutières syndrome (AGS) (Aim 3). AGS is a severe neuroinflammatory disorder that can be caused by aberrant sensing of self-dsRNAs. With the proposed aims, we will test an innovative idea that globally modulating 3âUTR length can fine-tune innate immune responses in cells. Since 3âUTRs and dsRNAs are extremely divergent across species (even between mice and humans), we will utilize various human cells (including human stem cell derived neurons), and apply cutting edge genome engineering, dsRNA imaging, biochemistry, and novel dsRNA sequencing technologies our lab developed. This is a highly collaborative project at the intersection of immunology, RNA biology, and neurobiology. We envision that these studies can lead to novel therapeutic strategies that target RNA or RNA- associated pathways to control inflammation in neural and autoimmune disorders.
View original record on NIH RePORTER →