This large cohort study showed that higher serum CXCL9 was associated with greater burden of white matter disease in the brain, independent of vascular risk factors, renal function, and genetic predisposition, supporting a role for CXCL9 in white matter pathogenesis.

Background and Objectives.

Individual variability in synaptic gene expression and synapse density in induced pluripotent stem cell–derived neurons predicted macro-scale alterations in gray matter volume and gamma-band activity in patients with Schizophrenia.

SIRS2026.

This genetic association study tests whether genetically driven variability in excitatory neurons’ transcriptome and synapse density in patient-derived neurons in vitro explain individual changes in cortical morphology, electrophysiology, and cognitive impairments in vivo.

Why are some people unable to hear from birth, even though their inner ear appears intact? One possible cause lies in the so-called OTOF gene. It plays a central role in transmitting sound signals from the hair cells to the auditory nerve. Without this function, acoustic information does not reach the brain.

Researchers from the German Primate Center—Leibniz Institute for Primate Research, the University Medical Center Göttingen, and the Max Planck Institute for Multidisciplinary Sciences have now, for the first time, generated marmosets in which this gene has been knocked out precisely. The animals are healthy and develop normally, but are deaf from birth. This provides the first primate model that realistically replicates key characteristics of human deafness. The results are published in Nature Communications.

Hearing loss is one of the most common congenital sensory disorders in humans. A major cause is a defect in the OTOF gene. This gene ensures that the protein otoferlin is produced in the inner ear. This protein is necessary for sound signals to travel from the hair cells to the auditory nerve. Without it, the ear still functions externally, but the signals do not reach the brain.