ACSF2: A MEDIUM-CHAIN ACYL-CoA SYNTHETASE WITH A POTENTIAL ROLE IN NEURONAL DIFFERENTIATION

Abstract

ABSTRACTBy activating fatty acids to their CoA derivatives, acyl-CoA synthetases (ACS) play an essential role in fatty acid metabolism. We previously identified ACSF2 as an ACS that was phylogenetically distinct from known families of short-chain, medium-chain, long-chain, very long-chain, and bubblegum ACSs. Functionally, ACSF2 preferentially activated medium-chain fatty acids. In this work, we provide further characterization of this unique ACS. ACSF2 mRNA expression was found in most tissues, although immunohistochemical analysis revealed differences in protein expression between various cell types in each tissue. Endogenous ACSF2 was found in the Golgi region in Neuro2a and P19 cells, and disruption of the Golgi in Neuro2a cells with nocodazole disrupted ACSF2 localization. In contrast, MA-10, HepG2, and skin fibroblasts had a mitochondrial ACSF2 localization. ACSF2 activated saturated fatty acids containing 6 to 10 carbons when overexpressed in COS-1 cells. The Kmapp for C10:0 was 24.4 μM and Vmaxapp was 385 nmol/20min/mg COS cell protein. Knockdown by RNA interference revealed that ACSF2 was responsible for most of the medium-chain ACS activity in Neuro2a cells. A lysine residue critical for activity in bacterial short-chain ACSs was found in ACSF2, and mutation of this residue to alanine abolished enzyme activity. Neurite outgrowth results when Neuro2a cells are induced to differentiate with retinoic acid, and ACSF2 migrated to nodes and points of neurite-neurite contact along with the presynaptic marker, synaptophysin. ACSF2-deficient Neuro2a cells showed significantly blunted neurite outgrowth in response to retinoic acid. These results suggest that this medium-chain ACS may play an important role in neuronal development.