A Novel FadL Homolog, AltL, Mediates Transport of Long-Chain Alkanes and Fatty Acids in Acinetobacter venetianus RAG-1.

Due to the barrier effect of lipopolysaccharide (LPS) in the outer membrane of Gram-negative bacteria, transporters are required for hydrophobic alkane uptake. However, there are few reports on long-chain alkane transporters. In this study, a potential long-chain alkane transporter (AltL) was screened in Acinetobacter venetianus RAG-1 by comparative transcriptome analysis. Growth and degradation experiments showed that altL deletion led to the loss of n-octacosane utilization capacity of RAG-1. To identify the function of AltL, we measured the existence and accumulation of alkanes in cells through the constructed alkane detection system and isotope transport experiment, which proved its long-chain alkane transport function. Growth experiments using different chain-length n-alkanes and fatty acids as substrates showed that AltL was responsible for the transport of (very) long-chain n-alkanes (C20 to C38) and fatty acids (C18A to C28A) and was also involved in the uptake of medium-chain n-alkanes (C16 to C18). Subsequently, we analyzed the distribution of AltL in bacteria, and found that AltL homologs are widespread in Gamma-, Beta-, and Deltaproteobacteria. An AltL homolog in Pseudomonas aeruginosa was also identified to participate in long-chain alkane transport by a gene deletion and growth assay. We also found that overexpression of altL in Pseudomonas aeruginosa enhanced the degradation of C16 to C32 n-alkanes. In addition, structure analysis showed that AltL has longer extracellular loops than other FadL family members, which may be involved in the binding of alkanes. These results showed that AltL is a novel transporter and that it is mainly responsible for the transport of long-chain n-alkanes and (very) long-chain fatty acids and has broad application potential. IMPORTANCE Petroleum pollution has caused great harm to the natural environment, and alkanes are the main components of petroleum. Many Gram-negative bacteria can use alkanes as carbon and energy sources, which is an important strategy for oil pollution remediation. Alkane uptake is the first step for its utilization. Hence, the characterization of transport proteins is of great significance for the recovery of oil pollution and other potential applications in industrial engineering bacteria. At present, some short- and medium-chain alkane transporters have been identified, but stronger hydrophobic long-chain alkane transporters have received little attention. In this study, the broad-spectrum transporter AltL, identified in RAG-1, makes up for the lack of research on the transport of long-chain alkanes and (very) long-chain fatty acids. Meanwhile, the structural features of longer extracellular loops might be related to its unique transport function on more hydrophobic and larger substrates, indicating it is a novel type alkane transporter.