An antisense-long-noncoding-RNA modulates p75 expression levels during neuronal polarization.

Proper polarization of newly generated neurons is a critical process for neural network formation and brain development. The pan-neurotrophin p75 receptor plays a key role in this process localizing asymmetrically in one of the differentiating neurites and specifying its axonal identity in response to neurotrophins. During axonal specification, p75 levels are transiently modulated, yet the molecular mechanisms underlying this process are not known. Here, we identified a previously uncharacterized natural antisense transcript, AS-p75, encoded within the p75NGFR mouse gene. Using an model of polarizing murine neurons, we found that AS-p75 and p75 display divergent expression profiles and that p75 expression levels increase upon competition or depletion of AS-p75, indicating that AS-p75 is a negative regulator of p75 expression. Depletion of AS-p75 also results in altered p75 subcellular distribution and affects the polarization process. Overall, our data uncovered AS-p75 as a modulator of p75 expression, offering new insights into the regulation of this neurotrophin receptor during neuronal polarization.