Brain-derived neurotrophic factor (BDNF) plays a role in neuroplasticity, appetite regulation, and reward processing. Its possible involvement in eating disorders (EDs) has been investigated; however, Show more
Brain-derived neurotrophic factor (BDNF) plays a role in neuroplasticity, appetite regulation, and reward processing. Its possible involvement in eating disorders (EDs) has been investigated; however, contradictory findings and substantial methodological heterogeneity have prevented definitive conclusions. To systematically evaluate peripheral BDNF levels in individuals with EDs, healthy controls and recovered individuals. A systematic review with meta-analysis was conducted according to the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) statement (CRD420250654199). Observational studies and randomized controlled trials comparing BDNF levels in individuals with and without EDs were included. The Newcastle-Ottawa Scale and risk-of-bias tool for randomized trials were used. Twenty-one studies were included. BDNF serum levels were significantly lower in acute anorexia (AN) compared with healthy controls (Standardized Mean Difference [SMD] = -0.49;p < 0.001,n = 17), with significance maintained after excluding outliers (SMD = -0.41; p < 0.001,n = 8). No significant difference was found between recovered AN and controls. Bulimia nervosa (BN) individuals showed significantly lower BDNF serum levels (SMD = -0.72;p < 0.001,n = 4). Longitudinal studies showed a significant increase in serum BDNF levels after recovery (SMD = 1.78;p = 0.003,n = 6). These findings support a predominantly state-related association between peripheral BDNF levels and illness stage in AN and BN, rather than a stable condition-specific. Evidence for binge-eating disorders is extremely limited, relying on a single eligible study. Interpretation is constrained by methodological heterogeneity, variability in recovery definitions, and the largely correlational nature of the evidence. Further standardized, high-quality longitudinal studies are needed to clarify whether peripheral BDNF alterations reflect state-related mechanisms, trait vulnerability, or dynamic biological changes across illness stages. Show less
Tissue-specific integrative omics has the potential to reveal new genic elements important for developmental disorders. Two pediatric patients with global developmental delay and intellectual disabili Show more
Tissue-specific integrative omics has the potential to reveal new genic elements important for developmental disorders. Two pediatric patients with global developmental delay and intellectual disability phenotype underwent array-CGH genetic testing, both showing a partial deletion of the DLG2 gene. From independent human and murine omics datasets, we combined copy number variations, histone modifications, developmental tissue-specific regulation, and protein data to explore the molecular mechanism at play. Integrating genomics, transcriptomics, and epigenomics data, we describe two novel DLG2 promoters and coding first exons expressed in human fetal brain. Their murine conservation and protein-level evidence allowed us to produce new DLG2 gene models for human and mouse. These new genic elements are deleted in 90% of 29 patients (public and in-house) showing partial deletion of the DLG2 gene. The patients' clinical characteristics expand the neurodevelopmental phenotypic spectrum linked to DLG2 gene disruption to cognitive and behavioral categories. While protein-coding genes are regarded as well known, our work shows that integration of multiple omics datasets can unveil novel coding elements. From a clinical perspective, our work demonstrates that two new DLG2 promoters and exons are crucial for the neurodevelopmental phenotypes associated with this gene. In addition, our work brings evidence for the lack of cross-annotation in human versus mouse reference genomes and nucleotide versus protein databases. Show less