Fig 2: The PAS1 domain is critical for NPAS3 aggregation, as determined by the expression of Flag-tagged NPAS3 fragment in SH-SY5Y cells. (a) Schematic of the fragments of NPAS3 expressed. (b) Expression of the flag-tagged NPAS3 fragments confirmed by Western blotting in HEK293 cells. A mock transfection with no plasmid is used as a negative control. (c–g) Typical localization patterns of these NPAS3 fragments when over-expressed in SH-SY5Y cells: fragments containing amino acids 1-111 (c) or 1-156 (d) (bHLH domain with or without linker region) are seen in the nucleus, while those containing amino acids 1-208 (e,f) or 1-354 (g) (bHLH and PAS1 domains, with or without linker region) are seen in the cytoplasm and in some instances form discernable aggregates. The nucleus (DAPI) and actin cytoskeleton (phalloidin) are shown for context. All amino acid numbers refer to the 933 long amino acid splice variant of human NPAS3 (NP_001158221.1). (h) Quantification of the localization patterns of these aggregates in a blinded assay (5–6 experimental replicates per plasmid, with 4–12 cells being counted in each). n.s.: not significant.

Fig 3: Raised levels of NPAS3 in the serum of a subset of schizophrenia patients. (a) Sample Western blot of whole serum samples from patients with schizophrenia (S) or depression (D), as well as control individuals (C). Stained with an anti-NPAS3 antibody, showing 14 samples (all samples in Supplementary Figure S7). Each lane was loaded with exactly 10 μL of serum. (b) Amount of 130 kDa NPAS3 detected in all serum samples, normalized to the mean over the entire experiment. (c) Amount of 130 kDa NPAS3 detected in only those samples that showed more than mean levels of 130 kDa NPAS3. NPAS3 signal in each category is shown relative to the average NPAS3 signal over all samples. (d) Patient symptom severities, shown as total scores on the positive, negative and general psychopathology scales of PANSS [45], of schizophrenia patients with above background levels NPAS3 in blood serum (n = 7, “NPAS3 positive”) compared to other schizophrenia patients in the study (n = 41, “NPAS3 negative”). There are no significant differences between the two groups. (e) Average number of first- or second-degree relatives of these patients with known diagnosis of mental illness. * p < 0.05, ** p < 0.01, ns: not significant.

Fig 4: Insoluble (aggregating) NPAS3 in 46 insular cortex samples. (a) Sample Western blot of whole cortex homogenates, showing no discernable NPAS3, while actin is visible. (b) Blots of the insoluble protein fractions, which are strongly enriched for aggregating proteins, derived from all insular cortex samples. (c) Quantification of the amount of NPAS3 in each sample, grouped by diagnostic status. There were no statistically significant effects, although there is a trend difference between Alzheimer’s disease patients and control individuals. NPAS3 signal in each category is shown relative to the average NPAS3 signal over all samples.

Fig 5: Insoluble protein in human insular cortex samples, from 15 victims of suicide, 11 control individuals, 4 patients with MDD and 3 patients with Alzheimer’s disease. (A–D) Quantified levels of DISC1 (A), TRIOBP-1 (B), CRMP1 (C) and NPAS3 (D) protein seen in the insoluble protein fraction of post mortem insular cortex samples. Values are normalized to a common sample loaded on each membrane. Original Western blot data for DISC1, TRIOBP-1 and CRMP1 are in Figure S1. NPAS3 data (D) have been published previously [13] but are reanalyzed and summarized here for comparison. The NPAS3 data also include a few additional samples, which were not available for this study. (E) For the protein isoforms analyzed further (CRMP1 Lv and Sv, DISC1 70 kDa, TRIOBP-1 72 kDa, NPAS3 130 kDa), the proteins present in the insoluble pellet at a level at least 50% higher than the mean, which are interpreted as aggregating for the purposes of this study. The number of proteins found to be insoluble (aggregating) in each sample can be seen in Figure 3. Graphs prepared using GraphPad Prism.