Simulated docking reveals putative channels for the transport of long-chain fatty acids in Vibrio cholerae

Abstract

ABSTRACTFatty acids (FA) play an important role in biological functions, such as membrane homeostasis, metabolism, and as signaling molecules. FadL is the only known protein that uptakes long-chain fatty acids in Gram-negative bacteria, and this uptake has traditionally been thought to be limited to fatty acids up to 18 carbon atoms in length. Recently however, it was found Vibrio cholerae has the ability to uptake fatty acids greater than 18 carbon atoms and this uptake corresponds to higher bacterial survivability. Using E. coli’s FadL as a template, V. cholerae FadL homologs vc1042, vc1043, and vca0862 have been folded, simulated on an atomistic level using molecular dynamics, and analyzed revealing the FadL transport channels. For vc1042 and vc1043 these transport channels have more structural accommodations for the many rigid unsaturated bonds of long-chain polyunsaturated fatty acids, while vca0862 was found to lack transport channels within the signature beta barrel of FadL proteins.IMPORTANCEFatty acids are important precursors for membrane phospholipids as well as energy sources for bacteria. V. cholerae’s uptake of long-chain fatty acids has not been studied to the atomistic level at this point, and by doing so, the resulting putative pathways show important structural details of the transport protein. Not only do the transport channels have unique differences between one another, the predicted transport mechanics of V. cholerae’s protein homologs differ substantially from the E. coli FadL’s pathway found from X-ray crystallography studies.