Biallelic truncating mutations in FMN2, encoding the actin-regulatory protein Formin 2, cause nonsyndromic autosomal-recessive intellectual disability.

Dendritic spines represent the major site of neuronal activity in the brain; they serve as the receiving point for neurotransmitters and undergo rapid activity-dependent morphological changes that correlate with learning and memory. Using a combination of homozygosity mapping and next-generation sequencing in two consanguineous families affected by nonsyndromic autosomal-recessive intellectual disability, we identified truncating mutations in formin 2 (FMN2), encoding a protein that belongs to the formin family of actin cytoskeleton nucleation factors and is highly expressed in the maturing brain. We found that FMN2 localizes to punctae along dendrites and that germline inactivation of mouse Fmn2 resulted in animals with decreased spine density; such mice were previously demonstrated to have a conditioned fear-learning defect. Furthermore, patient neural cells derived from induced pluripotent stem cells showed correlated decreased synaptic density. Thus, FMN2 mutations link intellectual disability either directly or indirectly to the regulation of actin-mediated synaptic spine density.

New recessive truncating mutation in LTBP3 in a family with oligodontia, short stature, and mitral valve prolapse.

Latent TGFB-binding protein 3 (LTBP3) is known to increase bio-availability of TGFB. A homozygous mutation in this gene has previously been associated with oligodontia and short stature in a single family. We report on two sisters with homozygous truncating mutations in LTBP3. In addition to oligodontia and short stature, both sisters have mitral valve prolapse, suggesting a link between truncating LTBP3 mutations and mitral valve disease mediated through the TGFB pathway.