Abstract
The proper subcellular localization of RNAs and local translational regulation is crucial in highly compartmentalized cells, such as neurons. RNA localization is mediated by specific cis-regulatory elements usually found in mRNA 3′UTRs. Therefore, processes that generate alternative 3′UTRs—alternative splicing and polyadenylation—have the potential to diversify mRNA localization patterns in neurons. Here, we performed mapping of alternative 3′UTRs in neurites and soma isolated from mESC-derived neurons. Our analysis identified 593 genes with differentially localized 3′UTR isoforms. In particular, we have shown that two isoforms of Cdc42 gene with distinct functions in neuronal polarity are differentially localized between neurites and soma of mESC-derived and mouse primary cortical neurons, at both mRNA and protein level. Using reporter assays and 3′UTR swapping experiments, we have identified the role of alternative 3′UTRs and mRNA transport in differential localization of alternative CDC42 protein isoforms. Moreover, we used SILAC to identify isoform-specific Cdc42 3′UTR-bound proteome with potential role in Cdc42 localization and translation. Our analysis points to usage of alternative 3′UTR isoforms as a novel mechanism to provide for differential localization of functionally diverse alternative protein isoforms.
Highlights
The neuron is a highly polarized cell, consisting of cell body and extensions
Brain-derived neurotrophic factor (BDNF) represents an example of such multi-UTR genes showing differential subcellular localization depending the 3 UTR length: BDNF with short 3 UTR is restricted to soma, while its long version is localized in dendrites [10]
We used excitatory neurons differentiated from mouse embryonic stem cells by inducible expression of a pioneer proneural transcription factor ASCL1 [7,31,32,33,34]
Summary
The neuron is a highly polarized cell, consisting of cell body (soma) and extensions (neurites - axons and dendrites). Such polarity is crucial to neuronal function and relies largely on asymmetric subcellular localization and translation of mRNAs (reviewed in [1]). MRNA localization and local regulation of translation allow neurons to control gene expression locally and thereby rapidly respond to local external stimuli. They have been implicated in multiple neuronal processes, including dendritic arborization, axon guidance and long-lasting changes in synaptic efficacy, which serve as a foundation of learning and memory. The last splice junction in mRNA is normally found upstream of the stop codon, to escape the nonsense-mediated decay (NMD) [11]
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