Abstract
Amyotrophic lateral sclerosis (ALS) is a form of motor neuron disease (MND) that is characterized by the progressive loss of motor neurons within the spinal cord, brainstem, and motor cortex. Although ALS clinically manifests as a heterogeneous disease, with varying disease onset and survival, a unifying feature is the presence of ubiquitinated cytoplasmic protein inclusion aggregates containing TDP-43. However, the precise mechanisms linking protein inclusions and aggregation to neuronal loss are currently poorly understood. Bimolecular fluorescence complementation (BiFC) takes advantage of the association of fluorophore fragments (non-fluorescent on their own) that are attached to an aggregation-prone protein of interest. Interaction of the proteins of interest allows for the fluorescent reporter protein to fold into its native state and emit a fluorescent signal. Here, we combined the power of BiFC with the advantages of the zebrafish system to validate, optimize, and visualize the formation of ALS-linked aggregates in real time in a vertebrate model. We further provide in vivo validation of the selectivity of this technique and demonstrate reduced spontaneous self-assembly of the non-fluorescent fragments in vivo by introducing a fluorophore mutation. Additionally, we report preliminary findings on the dynamic aggregation of the ALS-linked hallmark proteins Fus and TDP-43 in their corresponding nuclear and cytoplasmic compartments using BiFC. Overall, our data demonstrates the suitability of this BiFC approach to study and characterize ALS-linked aggregate formation in vivo. Importantly, the same principle can be applied in the context of other neurodegenerative diseases and has therefore critical implications to advance our understanding of pathologies that underlie aberrant protein aggregation.
Highlights
Aggregate Formation in DiseaseProtein misfolding and aggregation are hallmarks of many different neurodegenerative diseases; the preciseProtein aggregation is hypothesized to be caused when a particular protein folds into a stable alternative or intermediate conformation and starts to accumulate intra- or extracellularly
We further provide in vivo validation of an optimized Bimolecular fluorescence complementation (BiFC) construct and show the selectivity of this approach using competitive injections as a control for nonspecific protein interactions, which have previously been reported in BiFC assays [64]
In order to determine if BiFC could be used to investigate protein aggregation in zebrafish, the aggregation prone and
Summary
Aggregate Formation in DiseaseProtein misfolding and aggregation are hallmarks of many different neurodegenerative diseases; the preciseProtein aggregation is hypothesized to be caused when a particular protein folds into a stable alternative or intermediate conformation and starts to accumulate intra- or extracellularly. TDP-43 and FUS are predominately nuclear proteins, which have wellcharacterized nuclear functions, such as transcription, mRNA splicing and poly-adenylation, miRNA biogenesis (reviewed in [26,27,28]). Under physiological conditions, both proteins are found in low levels in the cytoplasm [29], where they have emerging roles in mRNA stability and transport, regulation of translation, miRNA processing, stress response, mitochondrial and autophagy regulation, and synaptic function (reviewed in [30]). Clinical verification of TDP-43 and FUS pathology are currently limited to postmortem tissue examination These histological techniques provide only a static snapshot of the aggregation pattern at predetermined stages of the disease. This significantly limits the ability to investigate the dynamic molecular mechanisms that are believed to trigger aggregate formation, maturation and mislocalization into the cytoplasm
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