Disrupting the Balance of Protein Quality Control Protein UBQLN2 Accelerates Tau Proteinopathy.

Tau protein accumulation drives toxicity in several neurodegenerative disorders. To better understand the pathways regulating tau homeostasis in disease, we investigated the role of ubiquilins (UBQLNs)-a class of proteins linked to ubiquitin-mediated protein quality control (PQC) and various neurodegenerative diseases-in regulating tau. Cell-based assays identified UBQLN2 as the primary brain-expressed UBQLN to regulate tau. UBQLN2 efficiently lowered wild-type tau levels regardless of aggregation, suggesting that UBQLN2 interacts with and regulates tau protein under normal conditions or early in disease. Moreover, UBQLN2 itself proved to be prone to accumulation as insoluble protein in male and female tau transgenic mice and the human tauopathy progressive supranuclear palsy. Genetic manipulation of UBQLN2 in a tauopathy mouse model demonstrated that a physiological UBQLN2 balance is required for tau homeostasis. UBQLN2 overexpression exacerbated phosphorylated tau pathology and toxicity in mice expressing P301S mutant tau, whereas P301S mice lacking UBQLN2 showed significantly reduced phosphorylated tau. Further studies support the view that an imbalance of UBQLN2 perturbs ubiquitin-dependent PQC and autophagy. We conclude that changes in UBQLN2 levels, whether because of pathogenic mutations or secondary to disease states, such as tauopathy, contribute to proteostatic imbalances that exacerbate neurodegeneration.SIGNIFICANCE STATEMENT We defined a role for the protein quality control protein Ubiquilin-2 (UBQLN2), in age-related neurodegenerative tauopathies. This group of disorders is characterized by the accumulation of tau protein aggregates, which differ when UBQLN2 levels are altered. Given the lack of effective disease-modifying therapies for tauopathies and the function of UBQLN2 in handling various disease-linked proteins, we explored the role of UBQLN2 in regulating tau. We found that UBQLN2 reduced tau levels in cell models but behaved differently in mouse brain, where it accelerated mutant tau pathology and tau-mediated toxicity. A better understanding of the diverse functions of regulatory proteins like UBQLN2 can elucidate some of the causative factors in neurodegenerative disease and outline new routes to therapeutic intervention.

Ubiquilin-2 regulates pathological alpha-synuclein.

The key protein implicated in Parkinson's disease and other synucleinopathies is α-synuclein, and a post-translationally modified form of the protein, phosphorylated at serine 129 (pS129), is a principal component in Lewy bodies, a pathological hallmark of PD. While altered proteostasis has been implicated in the etiology of Parkinson's disease, we still have a limited understanding of how α-synuclein is regulated in the nervous system. The protein quality control protein Ubiquilin-2 (UBQLN2) is known to accumulate in synucleinopathies, but whether it directly regulates α-synuclein is unknown. Using cellular and mouse models, we find that UBQLN2 decreases levels of α-synuclein, including the pS129 phosphorylated isoform. Pharmacological inhibition of the proteasome revealed that, while α-synuclein may be cleared by parallel and redundant quality control pathways, UBQLN2 preferentially targets pS129 for proteasomal degradation. Moreover, in brain tissue from human PD and transgenic mice expressing pathogenic α-synuclein (A53T), native UBQLN2 becomes more insoluble. Collectively, our studies support a role for UBQLN2 in directly regulating pathological forms of α-synuclein and indicate that UBQLN2 dysregulation in disease may contribute to α-synuclein-mediated toxicity.

Shared and divergent phase separation and aggregation properties of brain-expressed ubiquilins.

The brain-expressed ubiquilins, UBQLNs 1, 2 and 4, are highly homologous proteins that participate in multiple aspects of protein homeostasis and are implicated in neurodegenerative diseases. Studies have established that UBQLN2 forms liquid-like condensates and accumulates in pathogenic aggregates, much like other proteins linked to neurodegenerative diseases. However, the relative condensate and aggregate formation of the three brain-expressed ubiquilins is unknown. Here we report that the three ubiquilins differ in aggregation propensity, revealed by in-vitro experiments, cellular models, and analysis of human brain tissue. UBQLN4 displays heightened aggregation propensity over the other ubiquilins and, like amyloids, UBQLN4 forms ThioflavinT-positive fibrils in vitro. Measuring fluorescence recovery after photobleaching (FRAP) of puncta in cells, we report that all three ubiquilins undergo liquid-liquid phase transition. UBQLN2 and 4 exhibit slower recovery than UBQLN1, suggesting the condensates formed by these brain-expressed ubiquilins have different compositions and undergo distinct internal rearrangements. We conclude that while all brain-expressed ubiquilins exhibit self-association behavior manifesting as condensates, they follow distinct courses of phase-separation and aggregation. We suggest that this variability among ubiquilins along the continuum from liquid-like to solid informs both the normal ubiquitin-linked functions of ubiquilins and their accumulation and potential contribution to toxicity in neurodegenerative diseases.