To investigate whether patients with spontaneous spinal cerebrospinal fluid leaks (ssCSFLs) have a higher frequency of rare variants in a single gene that could predispose them to this condition, and to study these variants' effects on cell function and dural homeostasis in mice.
SsCSFLs have a strong association with connective tissue diseases (CTDs) including Marfan syndrome and Loeys-Dietz syndrome. Patients with ssCSFLs without specific diagnoses often have nonspecific CTD manifestations, suggesting that mutations in extracellular matrix proteins underlie more common presentations of this condition.
Our case-control study of 49 Type 1b ssCSFL probands and 3 control groups (n = 2244, 1428, 1826) identified FBN2 as a top candidate gene. Recombinant WT and mutant fibrillin-2 fragments were synthesized using the Expi293 system and tested for human dural fibroblast binding and integrin involvement in vitro. Fbn2 variants were introduced in C57BL/6 mice using CRISPR-Cas9, which underwent lumbar infusion testing to determine dural integrity and resistance to rupture, with Fbn1C3041G/+ (Marfan syndrome model) as a positive control group. Single-nuclear RNA sequencing of mouse dura (n = 3-4 mice/group) was analyzed using Seurat in R.
We report a significantly increased burden of rare variants in FBN2 in patients with type 1b ssCSFLs. Two of these mutations reduce human dural fibroblast adhesion to fibrillin-2 fragments in vitro. One disrupts a known integrin binding motif in the TB4 domain; another affects a completely novel binding site in the TB7 domain. Mice harboring the fibrillin-2 TB4 variant (Fbn2D1581V/+) and a mouse model of Marfan syndrome (Fbn1C1041G/+) demonstrate a pronounced predisposition for dural rupture upon controlled leak induction. Single-nuclear RNA sequencing of Fbn2D1581V/+ and Fbn1C1041G/+ mouse dura demonstrates dysregulation of tropoelastin expression in dural fibroblasts.
These data suggest mutations in FBN2 that alter cellular adhesion and/or the synthetic repertoire of matrix elements may lead to increased susceptibility to ssCSFLs.