Addressing C-F bonds and amyloid-formation in biological systems
National Institute of Neurological Disorders and Stroke
The ingestion, pulmonary inhalation, and dermal infiltration of C-F bond-containing compounds, most commonly found in
the form of per- and polyfluoroalkyl organic acids, causes oxidative stress, inflammation, DNA damage, and developmental
defects in infants and adults. These chemicals accumulate in the brain, disrupt neurological function and compromise
cognitive and locomotory behavior. Yet, we lack a high-resolution road-map of the interactions between C-F bonds and
biomolecular assemblies driving the trajectory towards neurodegenerative outcomes. This gap constitutes a significant
barrier to advancing measures designed to mitigate C-F chemistry-associated neurotoxicity. Emerging experimental and
computational data from our laboratory reveals that perfluorooctanoic acid, perfluorodecanoic acid and perfluorosulfonic
acid corrupt biomolecular structures through C-F:side-chain interactions in tested soluble, globular proteins found in milk
and tissues (matrices where C-F chemistries have been detected). Furthermore, they impaired the physiological function in
these proteins through displacement of physiological ligands or by compromising the binding of co-factors. The
neuroblastoma-derived SHSY-5Y cell line insulted with the said C-F moieties displayed altered gene expression
corresponding to reactive oxygen species (ROS), protein ubiquitination, inflammation along with compromised cytoskeletal
integrity. C-F bond ingestion ablated dopaminergic (DA) neurons in the nematode C. elegans and induced locomotory
deficits in a manner mimicking paraquat. Based on these findings, we propose to gather data towards our hypothesis that
C-F bond exposure perturbs biomolecular, cellular and organismal assemblies to onset neurodegeneration-linked
trajectories. In Aim 1, we will determine whether organic fluoroacids alter mRNA levels in differentiated SHSY-5Y cells
and in neuroprotective gut bacteria (Lactobacillus rhamnosus, Bifidobacterium lactis and Lactobacillus acidophilus). We
will examine whether the neuroblastoma cell line exposed to C-F chemistry displays readouts designed to inform the onset
of neurodegeneration-associated trajectories (including α-synuclein aggregation). In Aim 2, we will further address in a
preclinical model whether C-F burden induces protein aggregation (α-synuclein, amyloid β, mHTT), interferes with
dopaminergic neuronal assembles and induces locomotory deficits. Completion of the proposed work will complement
ongoing experimental biophysical, structural (crystallographic, NMR) and computational (docking, molecular dynamics
simulations) mapping of the interactions between these anthropogenic “forever” chemicals and amyloid-forming proteins
potentially resulting in a soluble-to-toxic transformation. It will prepare the stage for vertebrate testing. The findings from
this relatively understudied area likely exposes interventional targets for C-F chemistry associated neurotoxicity, spurs
therapeutic efforts and can also guide the development of more biocompatible alternatives.