👤 Naguib Mechawar

Inflammation has emerged as a prominent feature of bipolar disorder (BD) pathophysiology, drawing attention to brain barriers known to regulate immune-brain interactions. While perturbation of the blood-brain barrier has been reported in BD, the blood-cerebrospinal fluid (CSF) barrier formed largely by the choroid plexus (ChP) remains underexamined. To address this gap in knowledge, we used a multiplex array to measure cytokine protein abundance in postmortem ChP tissue from individuals with BD and unaffected controls, revealing elevated levels of CCL2 and SPP1, factors associated with monocyte and macrophage recruitment and activation. In contrast, expression of cytokines involved in tissue homeostasis, trophic support, and immune signaling, including OSM, IGF-1, CX3CL1, TGFB3, GDNF, LIF, BDNF, SCF, and FGFs, was reduced. Several cytokines, including CCL2 and PLGF, exhibited condition-specific divergent age trajectories. Bulk RNA sequencing of the same cohort revealed a modest set of differentially expressed genes, including transcripts associated with oxidative stress, mitochondrial function, and immune regulation that were upregulated in BD. Notably, the BD CSF biomarker NELL2 was downregulated in the ChP. Gene set enrichment analysis highlighted activation of inflammatory and cellular stress pathways, as well as reduced expression of junction-related gene programs. These findings suggest a shift in ChP function in BD characterized by increased pro-inflammatory signaling and reduced trophic and barrier-supportive activity. Together, these data identify the ChP as an active site of immune dysregulation in BD and support the broader notion of brain barrier dysfunction in mood disorder pathology. Show less

Decreased cerebrospinal fluid (CSF) levels of synaptic proteins, possibly reflecting impaired synaptic function, have been observed in major depressive disorder (MDD). To investigate the diagnostic utility of the soluble N-ethylmaleimide-sensitive-factor attachment receptor (SNARE) complex protein, synaptosomal-associated protein of 25 kDa (SNAP-25), for MDD. Overall, 208 participants with one of MDD, schizophrenia (SCZ) or bipolar disorder (BD), and healthy controls (HCs) were retrospectively enrolled. CSF levels of SNAP-25 were assessed relative to MDD characteristics and the diagnostic potential was analysed. In subgroups of patients, CSF levels of presynaptic neurexin 3 (NRXN3), postsynaptic neurogranin (NRGN) and Alzheimer's disease biomarkers were measured for comparison. SNAP-25 levels, but not the levels of the other synaptic markers, were significantly decreased in MDD compared with HCs, allowing for discrimination with 68% sensitivity and 67% specificity. SNAP-25 was not associated with MDD severity or antidepressant medication. Compared with HCs, SCZ also displayed decreased SNAP-25 enabling discrimination with 64% sensitivity and 77% specificity. There were strong correlations between levels of synaptic proteins and established Alzheimer pathology markers, with subtle differences in the association pattern between disorders. Our data suggest that SNAP-25, NRXN3 and NRGN versus beta-amyloid and phosphorylated tau protein 181 (ptau) are regulated differentially across psychiatric disorders and that SNAP-25 has a moderate diagnostic potential for MDD and SCZ. We propose that CSF SNAP-25 level might represent an integrated readout of reduced synaptic function, rather than of synaptic degeneration, in MDD. Further studies are needed to analyse whether this potential can be increased by using multimarker measurements and whether it will be possible to subtype psychiatric disorders according to synaptic involvement in pathophysiology. SNAP-25 and other synaptic proteins in CSF might aid diagnosis and subtyping of MDD and SCZ. The current development of sensitive methods to also determine synaptic proteins in blood samples from patients will advance the validation of the biomarker potential and contribute to understanding of synaptic involvement in the pathophysiology of MDD and SCZ. Show less

Major depressive disorder (MDD) is a leading cause of disease burden worldwide. While the incidence, symptoms and treatment of MDD all point toward major sex differences, the molecular mechanisms underlying this sexual dimorphism remain largely unknown. Here, combining differential expression and gene coexpression network analyses, we provide a comprehensive characterization of male and female transcriptional profiles associated with MDD across six brain regions. We overlap our human profiles with those from a mouse model, chronic variable stress, and capitalize on converging pathways to define molecular and physiological mechanisms underlying the expression of stress susceptibility in males and females. Our results show a major rearrangement of transcriptional patterns in MDD, with limited overlap between males and females, an effect seen in both depressed humans and stressed mice. We identify key regulators of sex-specific gene networks underlying MDD and confirm their sex-specific impact as mediators of stress susceptibility. For example, downregulation of the female-specific hub gene Dusp6 in mouse prefrontal cortex mimicked stress susceptibility in females, but not males, by increasing ERK signaling and pyramidal neuron excitability. Such Dusp6 downregulation also recapitulated the transcriptional remodeling that occurs in prefrontal cortex of depressed females. Together our findings reveal marked sexual dimorphism at the transcriptional level in MDD and highlight the importance of studying sex-specific treatments for this disorder. Show less

Fatty acids (FA) play an integral role in brain function and alterations have been implicated in a variety of complex neurological disorders. Several recent genomic studies have highlighted genetic variability in the fatty acid desaturase (FADS1/2/3) gene cluster as an important contributor to FA alterations in serum lipids as well as measures of FA desaturase index estimated by ratios of relevant FAs. The contribution to alterations of FAs within the brain by local synthesis is still a matter of debate. Thus, the impact of genetic variants in FADS genes on gene expression and brain FA levels is an important avenue to investigate. Analyses were performed on brain tissue from prefrontal cortex Brodmann area 47 (BA47) of 61 male subjects of French Canadian ancestry ranging in age from young adulthood to middle age (18-58 years old), with the exception of one teenager (15 years old). Haplotype tagging SNPs were selected using the publicly available HapMap genotyping dataset in conjunction with Haploview. DNA sequencing was performed by the Sanger method and gene expression was measured by quantitative real-time PCR. FAs in brain tissue were analysed by gas chromatography. Variants in the FADS1 gene region were sequenced and analyzed for their influence on both FADS gene expression and FAs in brain tissue. Our results suggest an association of the minor haplotype with alteration in estimated fatty acid desaturase activity. Analysis of the impact of DNA variants on expression and alternative transcripts of FADS1 and FADS2, however, showed no differences. Furthermore, there was a significant interaction between haplotype and age on certain brain FA levels. This study suggests that genetic variability in the FADS genes cluster, previously shown to be implicated in alterations in peripheral FA levels, may also affect FA composition in brain tissue, but not likely by local synthesis. Show less