Transport of long-chain fatty acids in Escherichia coli. Evidence for role of fadL gene product as long-chain fatty acid receptor

Transport of long-chain fatty acids (LCFA) across the cytoplasmic membrane of Escherichia coli requires functional fadL and fadD genes. The fadD gene codes for an acyl-CoA synthetase (fatty acid: CoA ligase (AMP forming] which has broad chain length specificity and is loosely bound to the cytoplasmic membrane. The fadL gene codes for a 43,000-dalton cytoplasmic membrane protein which, acting by an unknown mechanism, is needed specifically for LCFA transport. As a first step to define the role of the fadL gene product, studies were performed to determine if it functions as a LCFA receptor. The LCFA-binding activity was quantitated in intact cells in the absence of LCFA transport by comparing the binding of LCFA in fadD fadL and fadD fadL+ strains. These studies revealed that (i) fadD fadL+ strains bind 6-fold more LCFA than fadD fadL strains; (ii) fadD fadL strains harboring a plasmid containing the fadL gene bind 16-fold more LCFA than fadD fadL strains harboring only the plasmid vector; and (iii) the fadL-specific LCFA-binding activity is regulated by the fadR gene and catabolite repression. Studies with fadL strains harboring fadL plasmids containing in vitro constructed deletions indicate that mutations which alter the physical properties of the 43,000-dalton fadL gene product also affect fadL gene product-specific LCFA-binding activity. Overall, these studies suggest that one role of the fadL gene product in the LCFA transport process is to sequester LCFA at sites in the cell membrane for transport.     

Role of fadR and atoC(Con) mutations in poly(3-hydroxybutyrate-co-3-hydroxyvalerate) synthesis in recombinant pha+ Escherichia coli.

Recombinant Escherichia coli fadR atoC(Con) mutants containing the polyhydroxyalkanoate (PHA) biosynthesis genes from Alcaligenes eutrophus are able to incorporate significant levels of 3-hydroxyvalerate (3HV) into the copolymer poly(3-hydroxybutyrate-co-3-hydroxyvalerate) [P(3HB-co-3HV)]. We have used E. coli fadR (FadR is a negative regulator of fatty acid oxidation) and E. coli atoC(Con) (AtoC is a positive regulator of fatty acid uptake) mutants to demonstrate that either one of these mutations alone can facilitate copolymer synthesis but that 3HV levels in single mutant strains are much lower than in the fadR atoC(Con) strain. E. coli atoC(Con) mutants were used alone and in conjunction with atoA and atoD mutants to determine that the function of the atoC(Con) mutation is to increase the uptake of propionate and that this uptake is mediated, at least in part, by atoD+. Similarly, E. coli fadR mutants were used alone and in conjunction with fadA, fadB, and fadL mutants to show that the effect of the fadR mutation is dependent on fadB+ and fadA+ gene products. Strains that were mutant in the fadB or fadA locus were unable to complement a PHA biosynthesis pathway that was mutant at the phaA locus (thiolase), but a strain containing a fadR mutation and which was fadA+ fadB+ was able to complement the phaA mutation and incorporated 3HV into P(3HB-co-3HV) to a level of 29 mol%.     

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.     

Purification and characterization of an outer membrane-bound protein involved in long-chain fatty acid transport in Escherichia coli

We report the purification and localization of the fadL gene product (FLP), an essential component of the long-chain fatty acid transport machinery in Escherichia coli. FLP was extracted from total membranes by differential extraction with the nonionic detergents Tween 20 and Triton X-100. This protein was further purified from a Tween 20-insoluble-Triton X-100-soluble extract by salt fractionation, gel filtration chromatography, and hydrophobic interaction chromatography. This regime results in a 95-fold purification of FLP from total membranes. The purified protein preparation was homogeneous based on silver staining and gave the characteristic behavior established for the fadL gene product in the presence of sodium dodecyl sulfate at different temperatures prior to sodium dodecyl sulfate-polyacrylamide gel electrophoresis (Mr of 33,000 when heated at 25 degrees C and Mr of 43,000 when heated at 100 degrees C) and on two-dimensional polyacrylamide gels (pI of 4.6 and a Mr of 33,000). Purified FLP was rich in hydrophobic residues accounting for approximately 45% of the total amino acid composition. To localize FLP, antisera were raised against the purified protein and were used to probe differentially fractionated membranes by Western immunoblotting. This procedure demonstrated the presence of this protein only in the outer membrane fraction of fadL+ strains. We confirmed the outer membrane localization of FLP by measuring long-chain fatty acid transport in fadL+ and fadL strains treated with EDTA to alter outer membrane permeability and in spheroplasts generated from fadL+ and fadL strains. Both EDTA-treated cells and spheroplasts transported long-chain fatty acids at essentially the same rate regardless of whether they contained a wild-type or mutant fadL gene. These data imply that FLP is a protein in the outer membrane which is specifically involved in long-chain fatty acid transport.     

Role for fadR in unsaturated fatty acid biosynthesis in Escherichia coli

Escherichia coli K-12 mutants constitutive for the synthesis of the enzymes of fatty acid degradation (fad) synthesize significantly less unsaturated fatty acid (UFA) than do wild-type (fadR+) strains. The constitutive fadR mutants synthesize less UFA than do fadR+) strains both in vivo and in vitro. The inability of fadR strains to synthesize UFAs at rates comparable to those of fadR+ strains is phenotypically asymptomatic unless the fadR strain also carries a lesion in fabA, the structural gene for beta-hydroxydecanoyl-thioester dehydrase. Unlike fadR+ fabA(Ts) mutants, fadR fabA(Ts) strains synthesize insufficient UFA to support their growth even at low temperatures and, therefore, must be supplemented with UFA at both low and high temperatures. The low levels of UFA in fadR strains are not due to the constitutive level of fatty acid-degrading enzymes in these strains. These results suggest that a functional fadR gene is required for the maximal expression of UFA biosynthesis in E. coli.     

Linker mutagenesis of a bacterial fatty acid transport protein. Identification of domains with functional importance

The product of the fadL gene (FadL) of Escherichia coli is a multifunctional integral outer-membrane protein required for the specific binding and transport of exogenous long-chain fatty acids [C12-C18]. FadL also serves as a receptor for the bacteriophage T2. In order to define regions of functional importance within FadL, the fadL gene has been mutagenized by the insertion of single-stranded hexameric linkers into the unique SalI restriction site that lies towards the 3' end of the gene and into four HpaII restriction sites distributed throughout the coding region. The five insertion mutants were classified into three groups based on their specific growth rates (alpha) in minimal media containing the long-chain fatty acid oleate (C18:1) as a sole carbon and energy source: Oleslow, alpha = 0.035-0.045; Ole +/-, alpha = 0.020-0.035; and Ole-, alpha less than or equal to 0.005 (wild-type, alpha = 0.07-0.10). The hexameric insertion at the SalI site (fadL allele termed S1; insertion after amino acid 410) conferred an Oleslow phenotype and resulted in a reduction of long-chain fatty acid transport (36% the wild-type level). This insertion mutant, however, bound oleic acid at wild-type levels and was fully functional as a receptor for the bacteriophage T2. The modified FadL-S1 protein did not have the heat-modifiable property characteristic of wild-type FadL. Insertions in the four HpaII sites (fadL alleles termed H1, H2, H3, and H5; after amino acids 41, 81, 238, and 389, respectively) resulted in all three classes of mutants. The fadL insertion mutant H5 was defective for long-chain fatty acid transport but bound oleic acid at significant levels. Together with the S1 allele, these data suggest that the carboxyl terminus of FadL is crucial for long-chain fatty acid transport. The insertion mutants H1 and H2 were defective for both oleic acid binding and transport suggesting that the amino terminus of FadL is important for long-chain fatty acid binding and transport. The fadL linker mutant H3 was defective in oleic acid binding yet had significant levels of oleic acid transport. These studies delineated for the first time different regions of the fadL gene that encode domains of FadL implicated in the binding and transport of long-chain fatty acids.     

Properties of beta-galactosidase III: implications for entry of galactosides into Klebsiella.

Klebsiella sp. strain CT-200 lacks both its plasmid-borne lac operon, which specifies beta-galactosidase I, and its chromosomal lac operon, which specifies beta-galactosidase II, but it expresses a gene for a third beta-galactosidase, beta-galactosidase III, constitutively. CT-200 was examined to determine whether there was a beta-galactoside permease associated with the beta-galactosidase III gene. The failure of CT-200 to transport thiomethyl-beta-galactoside, o-nitrophenyl-beta-D-galactopyranoside, phenyl-beta-galactoside, lactulose, or galactosyl-arabinose was taken as evidence that beta-galactoside permease is not part of a beta-galactosidase III operon. Optimal assay conditions for beta-galactosidase II, whose activity was used as a measure of beta-galactoside transport, are reported here, as are an improved purification method and some physical and catalytic properties of the enzyme not previously reported.     

Elevated levels of glyoxylate shunt enzymes in Escherichia coli strains constitutive for fatty acid degradation.

Mutants of Escherichia coli K-12 constitutive for the synthesis of the enzymes of fatty acid degradation (fadR) have elevated levels of the glyoxylate shunt enzymes, isocitrate lyase and malate synthase. A temperature-sensitive fadR strain has high levels of glyoxylate shunt enzymes when grown at elevated temperatures but has low, inducible levels of glyoxylate shunt enzymes when grown at low temperatures. The increased activity of glyoxylate shunt enzymes did not appear to be due to the degradation of intracellular fatty acids in fadR strains or differences in allosteric effectors in fadR versus fadR+ strains. These studies suggest that the fadR gene product may be involved in the regulation of the glyoxylate operon.     

Expression of a beta-galactosidase gene from Clostridium acetobutylicum in Lactococcus lactis subsp. lactis

A beta-galactosidase gene from Clostridium acetobutylicum NCIB 2951 was expressed after cloning into pSA3 and electroporation into derivatives of Lactococcus lactis subsp. lactis strains H1 and 7962. When the clostridial gene was introduced into a plasmid-free derivative of the starter-type Lact. lactis subsp. lactis strain H1, the resulting construct had high beta-galactosidase activity but utilized lactose only slightly faster than the recipient. beta-galactosidase activity in the construct decreased by over 50% if the 63 kb Lac plasmid pDI21 was also present with the beta-galactosidase gene. Growth rates of Lac+ H1 and 7962 derivatives were not affected after introduction of the clostridial beta-galactosidase, even though beta-galactosidase activity in a 7962 construct was more than double that of the wild-type strain. When pDI21 was electroporated into a plasmid-free variant of strain 7962, the recombinant had high phospho-beta-galactosidase activity and a growth rate equal to that of the H1 wild-type strain. The H1 plasmid-free strain grew slowly in T5 complex medium, utilized lactose and contained low phospho-beta-galactosidase activity. We suggest that beta-galactosidase expression can be regulated by the lactose phosphotransferase system-tagatose pathway and that Lact. lactis subsp. lactis strain H1 has an inefficient permease for lactose and contains chromosomally-encoded phospho-beta-galactosidase genes.     

Regulation of fatty acid degradation in Escherichia coli: dominance studies with strains merodiploid in gene fadR.

Strains stably merodiploid in the 25-min region of the chromosome of Escherichia coli were constructed and used in dominance tests between various wild-type and mutant alleles of the fadR gene. Whereas the monoploid fadR+ and fadR strains were inducible and constitutive, respectively, for the enzymes involved in fatty acid degradation (fad), merodiploids with at least one fadR+ allele were inducible. This observation was true whether the fadR+ allele resided on the main chromosome or on the episome. These results show that fadR+ is trans dominant to fadR, and they are consistent with the proposal that the fadR gene product is a repressor protein. Complementation tests were also performed by constructing 24 merodiploids harboring fadR alleles on both the main chromosome and the episome. All of these fadR/fadR diploids were able to utilize the noninducing substrate decanoate as sole carbon source, suggesting that only one polypeptide is encoded by the fadR gene.     

Insertion of an E. coli lacZ gene in Acetobacter xylinus for the production of cellulose in whey

A mini-Tn10:lacZ:kan was inserted into a wild-type strain of Acetobacter xylinus by random transposon mutagenesis, generating a lactose-utilising and cellulose-producing mutant strain designated ITz3. Antibiotic selection plate assays and Southern hybridisation revealed that the lacZ gene was inserted once into the chromosome of strain ITz3 and was stably maintained in non-selective medium after more than 60 generations. The modified strain had, on the average, a 28-fold increase in cellulose production and a 160-fold increase in beta-galactosidase activity when grown in lactose medium. beta-Galactosidase activity is present in either lactose or sucrose medium indicating that the gene is constitutively expressed. Cellulose and beta-galactosidase production by the modified strain was also evaluated in pure and enriched whey substrates. Utilisation of lactose in whey substrate by ITz3 reached 17 g l(-1) after 4 days incubation.     

Electrochemical evaluation of cellular physiological status under stress in Escherichia coli with the rpoS-lacZ reporter gene

We developed an electrochemical detection method for evaluating cellular physiological status based on the stringent response as a means to monitor cell viability. A reporter plasmid was constructed by inserting the beta-galactosidase gene (lacZ) under the control of the rpoS promoter, and then used to transform E. coli cells. Electrochemical responses from the products catalyzed by beta-galactosidase expressed by these E. coli cells were detected using the chronoamperometric technique in a nondestructive manner. Comparisons of response currents between the relA-positive strain and relA-negative strain revealed that increases in these currents were caused by the stringent response due to the stressful alcoholic environment, and thus as a model of stressful cultivating conditions. The current was proportional to the beta-galactosidase activity assayed by a conventional method that required the destruction of cells. The cellular physiological status, which depends on the stringent response as a viability marker, therefore, could then be evaluated online with a current using the rpoS-lacZ reporter gene in the relA-positive strain without pretreatment.     

New locus (ttr) in Escherichia coli K-12 affecting sensitivity to bacteriophage T2 and growth on oleate as the sole carbon source.

The nature of resistance to phage T2 in Escherichia coli K-12 was investigated by analyzing a known phage T2-resistant mutant and by isolating new T2-resistant mutants. It was found that mutational alterations at two loci, ompF (encoding the outer membrane protein OmpF) and ttr (T-two resistance), are needed to give full resistance to phage T2. A ttr::Tn10 mutation was isolated and was mapped between aroC and dsdA, where the fadL gene (required for long-chain fatty acid transport) is located. The receptor affected by ttr was the major receptor used by phage T2 and was located in the outer membrane. Phage T2 was thus able to use two outer membrane proteins as receptors. All strains having a ttr::Tn10 allele and most of the independently isolated phage T2-resistant mutants were unable to grow on oleate as the sole carbon and energy source, i.e., they had the phenotype of fadL mutants. The gene fadL is known to encode an inner membrane protein. The most likely explanation is that fadL and ttr are in an operon and that ttr encodes an outer membrane protein which functions in translocating long-chain fatty acids across the outer membrane and also as a receptor for phage T2.     

Studies on beta-galactoside transport in a Proteus mirabilis merodiploid carrying an Escherichia coli lactose operon

Merodiploid derivatives bearing an F-linked lac operon (i(+), o(+), z(+), y(+), a(+)) from Escherichia coli were prepared from a Proteus mirabilis strain unable to utilize lactose and from a lac deletion strain of E. coli. A suitable growth medium was found in which the episomal element in the P. mirabilis derivative was sufficiently stable to allow induction of the episome-borne lac operon and thus to permit a comparison of the activities and properties of E. coli lac products in the intracellular environments of P. mirabilis and E. coli. In both derivatives the episomal lac operon was shown to be repressed in the absence of inducer. Kinetics of induction with gratuitous inducer (isopropyl-1-thio-beta-d-galactoside) were similar for both beta-galactosidase activity (beta-d-galactoside galactohydrolase, EC 3.4.1.23) and beta-galactoside transport activity in both derivatives, although the ratio of galactoside transport to beta-galactosidase activity was approximately 1.6-fold higher in the E. coli derivative. Comparison of beta-galactosidase and M-protein (lac y gene product)-specific activities indicated coordinate expression of the induced lac operon in both derivatives. Quantitatively, the maximal beta-galactosidase specific activity was two or three times higher for the E. coli derivative. A significant sodium azide inhibition (65% inhibition by 10 mM sodium azide) of lactose permease-mediated transport of o-nitrophenyl-beta-galactoside from an outside region of high concentration to an inside region of very low concentration ("downhill transport") was observed for the P. mirabilis derivative. Identical conditions for the E. coli derivative yielded only about 15% inhibition. Active transport of thiomethyl-beta-galactoside was similar for both derivatives, the major difference being that active transport was more sensitive to azide poisoning in the P. mirabilis derivative. Preliminary examination of the thiomethyl-beta-galactoside derivatives following active transport did not demonstrate the accumulation of a phosphorylated product in either strain but did reveal an unidentified derivative present in the P. mirabilis merodiploid extract which was not detectable in the E. coli merodiploid.