The fadL gene product of Escherichia coli is an outer membrane protein required for uptake of long-chain fatty acids and involved in sensitivity to bacteriophage T2.

The fadL+ gene of Escherichia coli encodes an outer membrane protein (FadL) essential for the uptake of long-chain fatty acids (C12 to C18). The present study shows that in addition to being required for uptake of and growth on the long-chain fatty acid oleate (C18:1), FadL acts as a receptor of bacteriophage T2. Bacteriophage T2-resistant (T2r) strains lacked FadL and were unable to take up and grow on long-chain fatty acids. Upon transformation with the fadL+ clone pN103, T2r strains became sensitive to bacteriophage T2 (T2s), became able to take up long-chain fatty acids at wild-type levels, and contained FadL in the outer membrane.     

Long-chain fatty acid transport in Escherichia coli. Cloning, mapping, and expression of the fadL gene

Transport of long-chain fatty acids across the inner membrane of Escherichia coli K-12 requires a functional fadL gene (Maloy, S. R., Ginsburgh, C. L., Simons, R. W., and Nunn, W. D. (1981) J. Biol. Chem. 256, 3735-3742). Mutants defective in the fadL gene lack a 33,000-dalton inner membrane protein as evaluated using two-dimensional pI/sodium dodecyl sulfate (SDS) polyacrylamide gel electrophoresis (Ginsburgh, C. L., Black, P. N., and Nunn, W. D. (1984) J. Biol. Chem. 259, 8437-8443). In an effort to determine whether the fadL gene is the structural gene for this 33,000-dalton protein, we have cloned, mapped, and analyzed the expression of the fadL gene. The fadL gene has been localized on a 2.8-kilobase EcoRV fragment of E. coli genomic DNA. Plasmids containing this gene (i) complement all fadL mutants, (ii) increase the long-chain fatty acid transport activity of fadL strains harboring them by 2- to 3-fold, and (iii) direct the synthesis of a membrane protein which has the same molecular weight and isoelectric point as that described by Ginsburgh et al. This is a heat-modifiable protein which has an apparent molecular weight of 43,000 daltons when solubilized at 100 degrees C in the presence of SDS and 33,000 daltons when solubilized at 50 degrees C in the presence of SDS.     

Kinetics of the utilization of medium and long chain fatty acids by mutant of Escherichia coli defective in the fadL gene.

Experiments were performed to assess the role of the fadL gene in Escherichia coli. These studies have revealed that this organism requires a functional fadL gene in order to (i) transport optimally the fatty acids C10 to C18:1 into the cell, (ii) optimally grow on and oxidize C10 to C18:1 fatty acids, and (iii) incorporate efficiently C12 to C18:1 fatty acids into its membrane phospholipids. A defect in the fadL gene does not prevent E. coli from optimally utilizing fatty acids with chain lengths less than 10 carbon atoms. These results suggest that the fadL gene governs a transport component(s) which is required for the optimal transport of fatty acids with chain lengths greater than 9 carbon atoms.     

Evidence for the involvement of unsaturated fatty acids in initiating chromosome replication in Escherichia coli

The analogue 3-decynoyl-N-acetylcysteamine inhibits the synthesis of unsaturated fatty acids in Escherichia coli, resulting in the accumulation of saturated fatty acids in the membrane (Kass, 1968).In the presence of this analogue, DNA, RNA and protein synthesis continue at a linear rate for approximately two doubling times, and then cease. On the other hand, the analogue will inhibit the formation of new replication forks (premature initiation), which normally arise as a result of thymine starvation.Unlike other temperature-sensitive DNA mutants, mutants that are defective in initiating DNA replication (dnaA or dnaC) are unable to replicate DNA at a permissive temperature if they terminate replication at 42 °C in the presence of 3-decynoyl-N-acetylcysteamine.When replication is terminated at 42 °C, cultures of dnaA or dnaC mutants normally will reinitiate replication upon lowering the temperature to 30 °C. For each mutant this reinitiation is characterized by a particular temperature sensitivity. Such mutants become more temperature sensitive if the temperature is lowered in the presence of 3-decynoyl-N-acetylcysteamine. All the effects of this analogue can be reversed by the addition of unsaturated fatty acids.These results are interpreted using a model in which replication is initiated at a particular lipid site on the membrane. In the absence of unsaturated fatty acids functional lipid sites are not made. Functional sites, however, can be used again provided they are not inactivated by interaction with an inactive dnaA or dnaC product.     

Escherichia coli cyclopropane fatty acid synthase.

Escherichia coli fatty acid cyclopropane synthase (CFAS) was overproduced and purified as a His6-tagged protein. This recombinant enzyme is as active as the native enzyme with a Km of 90 microm for S-AdoMet and a specific activity of 5 x 10(-2) micromol.min(-1).mg(-1). The enzyme is devoid of organic or metal cofactors and is unable to catalyze the wash-out of the methyl protons of S-AdoMet to the solvent, data that do not support the ylide mechanism. Inactivation of the enzyme by 5,5'-dithiobis-(2-nitrobenzoic acid) (DTNB), a pseudo first-order process with a rate constant of 1.2 m(-1).s(-1), is not protected by substrates. Graphical analysis of the inactivation by DTNB revealed that only one cysteine is responsible for the inactivation of the enzyme. The three strictly conserved Cys residues among cyclopropane synthases, C139, C176 and C354 of the E. coli enzyme, were mutated to serine. The relative catalytic efficiency of the mutants were 16% for C139S, 150% for C176S and 63% for C354S. The three mutants were inactivated by DTNB at a rate comparable to the rate of inactivation of the His6-tagged wild-type enzyme, indicating that the Cys responsible for the loss of activity is not one of the conserved residues. Therefore, none of the conserved Cys residues is essential for catalysis and cannot be involved in covalent catalysis or general base catalysis. The inactivation is probably the result of steric hindrance, a phenomenon irrelevant to catalysis. It is very likely that E. coli CFAS operates via a carbocation mechanism, but the base and nucleophile remain to be identified.     

Evidence for horizontal gene transfer in Escherichia coli speciation.

After extracting more than 780 identified Escherichia coli genes from available data libraries, we investigated the codon usage of the corresponding coding sequences and extended the study of gene classes, thus obtained, to the nature and intensity of short nucleotide sequence selection, related to constraints operating at the nucleotide level. Using Factorial Correspondence Analysis we found that three classes ought to be included in order to match all data now available. The first two classes, as known, encompass genes expressed either continuously at a high level, or at a low level and/or rarely; the third class consists of genes corresponding to surface elements of the cell, genes coming from mobile elements as well as genes resulting in a high fidelity of DNA replication. This suggests that bacterial strains cultivated in the laboratory have been fixed by specific use of antimutator genes that are horizontally exchanged.     

Engineering Escherichia coli to convert acetic acid to free fatty acids

Fatty acids (FAs) are promising precursors of advanced biofuels. This study investigated conversion of acetic acid (HAc) to FAs by an engineered Escherichia coli strain. We combined established genetic engineering strategies including overexpression of acs and tesA genes, and knockout of fadE in E. coli BL21, resulting in the production of ~1 g/L FAs from acetic acid. The microbial conversion of HAc to FAs was achieved with ~20% of the theoretical yield. We cultured the engineered strain with HAc-rich liquid wastes, which yielded ~0.43 g/L FAs using waste streams from dilute acid hydrolysis of lignocellulosic biomass and ~0.17 g/L FAs using effluent from anaerobic-digested sewage sludge. ¹³C-isotopic experiments showed that the metabolism in our engineered strain had high carbon fluxes toward FAs synthesis and TCA cycle in a complex HAc medium. This proof-of-concept work demonstrates the possibility for coupling the waste treatment with the biosynthesis of advanced biofuel via genetically engineered microbial species.     

Regulation of fatty acid biosynthesis in Escherichia coli.

Our understanding of fatty acid biosynthesis in Escherichia coli has increased greatly in recent years. Since the discovery that the intermediates of fatty acid biosynthesis are bound to the heat-stable protein cofactor termed acyl carrier protein, the fatty acid synthesis pathway of E. coli has been studied in some detail. Interestingly, many advances in the field have aided in the discovery of analogous systems in other organisms. In fact, E. coli has provided a paradigm of predictive value for the synthesis of fatty acids in bacteria and plants and the synthesis of bacterial polyketide antibiotics. In this review, we concentrate on four major areas of research. First, the reactions in fatty acid biosynthesis and the proteins catalyzing these reactions are discussed in detail. The genes encoding many of these proteins have been cloned, and characterization of these genes has led to a better understanding of the pathway. Second, the function and role of the two essential cofactors in fatty acid synthesis, coenzyme A and acyl carrier protein, are addressed. Finally, the steps governing the spectrum of products produced in synthesis and alternative destinations, other than membrane phospholipids, for fatty acids in E. coli are described. Throughout the review, the contribution of each portion of the pathway to the global regulation of synthesis is examined. In no other organism is the bulk of knowledge regarding fatty acid metabolism so great; however, questions still remain to be answered. Pursuing such questions should reveal additional regulatory mechanisms of fatty acid synthesis and, hopefully, the role of fatty acid synthesis and other cellular processes in the global control of cellular growth.     

Functional role of fatty acyl-coenzyme A synthetase in the transmembrane movement and activation of exogenous long-chain fatty acids. Amino acid residues within the ATP/AMP signature motif of Escherichia coli FadD are required for enzyme activity and fatty acid transport

Fatty acyl-CoA synthetase (FACS, fatty acid:CoA ligase, AMP forming; EC ) plays a central role in intermediary metabolism by catalyzing the formation of fatty acyl-CoA. In Escherichia coli this enzyme, encoded by the fadD gene, is required for the coupled import and activation of exogenous long-chain fatty acids. The E. coli FACS (FadD) contains two sequence elements, which comprise the ATP/AMP signature motif ((213)YTGGTTGVAKGA(224) and (356)GYGLTE(361)) placing it in the superfamily of adenylate-forming enzymes. A series of site-directed mutations were generated in the fadD gene within the ATP/AMP signature motif site to evaluate the role of this conserved region to enzyme function and to fatty acid transport. This approach revealed two major classes of fadD mutants with depressed enzyme activity: 1) those with 25-45% wild type activity (fadD(G216A), fadD(T217A), fadD(G219A), and fadD(K222A)) and 2) those with 10% or less wild-type activity (fadD(Y213A), fadD(T214A), and fadD(E361A)). Using anti-FadD sera, Western blots demonstrated the different mutant forms of FadD that were present and had localization patterns equivalent to the wild type. The defect in the first class was attributed to a reduced catalytic efficiency although several mutant forms also had a reduced affinity for ATP. The mutations resulting in these biochemical phenotypes reduced or essentially eliminated the transport of exogenous long-chain fatty acids. These data support the hypothesis that the FACS FadD functions in the vectorial movement of exogenous fatty acids across the plasma membrane by acting as a metabolic trap, which results in the formation of acyl-CoA esters.     

The putative fabJ gene of Escherichia coli fatty acid synthesis is the fabF gene.

Siggaard-Andersen and coworkers (M. Siggaard-Andersen, M. Wissenbach, J. Chuck, I. Svendsen, J. G. Olsen, and P. von Wettstein-Knowles, Proc. Natl. Acad. Sci. USA 91:11027-11031, 1994) recently reported the DNA sequence of a gene encoding a beta-ketoacyl-acyl carrier protein synthase from Escherichia coli. These workers assigned this gene the designation fabJ and reported that the gene encoded a new beta-ketoacyl-acyl carrier protein synthase. We report that the fabJ gene is the previously reported fabF gene that encodes the known beta-ketoacyl-acyl carrier protein synthase II.