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.     

Regulation of branched-chain amino acid transport in Escherichia coli.

The repression and derepression of leucine, isoleucine, and valine transport in Escherichia coli K-12 was examined by using strains auxotrophic for leucine, isoleucine, valine, and methionine. In experiments designed to limit each of these amino acids separately, we demonstrate that leucine limitation alone derepressed the leucine-binding protein, the high-affinity branched-chain amino acid transport system (LIV-I), and the membrane-bound, low-affinity system (LIV-II). This regulation did not seem to involve inactivation of transport components, but represented an increase in the differential rate of synthesis of transport components relative to total cellular proteins. The apparent regulation of transport by isoleucine, valine, and methionine reported elsewhere was shown to require an intact leucine, biosynthetic operon and to result from changes in the level of leucine biosynthetic enzymes. A functional leucyl-transfer ribonucleic acid synthetase was also required for repression of transport. Transport regulation was shown to be essentially independent of ilvA or its gene product, threonine deaminase. The central role of leucine or its derivatives in cellular metabolism in general is discussed.     

Regulation of peptide transport in Escherichia coli: induction of the trp-linked operon encoding the oligopeptide permease.

Growth of Escherichia coli in medium containing leucine results in increased entry of exogenously supplied tripeptides into the bacterial cell. This leucine-mediated elevation of peptide transport required expression of the trp-linked opp operon and was accompanied by increased sensitivity to toxic tripeptides, by an enhanced capacity to utilize nutritional peptides, and by an increase in both the velocity and apparent steady-state level of L-[U-14C]alanyl-L-alanyl-L-alanine accumulation for E. coli grown in leucine-containing medium relative to these parameters of peptide transport measured with bacteria grown in media lacking leucine. Direct measurement of opp operon expression by pulse-labeling experiments demonstrated that growth of E. coli in the presence of leucine resulted in increased synthesis of the oppA-encoded periplasmic binding protein.     

Regulation of the trimethylamine N-oxide (TMAO) reductase in Escherichia coli: analysis of tor::Mud1 operon fusion

Summary Mud1 insertion mutants of Escherichia coli were obtained in which the lac structural genes were fused to the promoter of torA, a gene encoding the trimethylamine N-oxide (TMAO) reductase. Expression of the fusion is induced by TMAO and repressed by oxygen. However, in contrast to the nar operon which codes for the nitrate reductase structural genes, the tor::Mud1 fusion was found to be independent of the positive control exerted by the nirR gene product and not repressed by the molybdenum cofactor. The torA gene which is strongly linked to pyrF (28.3 U) is different from any tor gene already described in E. coli or in Salmonella typhimurium.     

Regulation of the L-arabinose operon of Escherichia coli

Over forty years of research on the L-arabinose operon of Escherichia coli have provided insights into the mechanism of positive regulation of gene activity. This research also discovered DNA looping and the mechanism by which the regulatory protein changes its DNA-binding properties in response to the presence of arabinose. As is frequently seen in focused research on biological subjects, the initial studies were primarily genetic. Subsequently, the genetic approaches were augmented by physiological and then biochemical studies. Now biophysical studies are being conducted at the atomic level, but genetics still has a crucial role in the study of this system.     

Regulation of aromatic amino acid transport systems in Escherichia coli K-12.

The regulation of the aromatic amino acid transport systems was investigated. The common (general) aromatic transport system and the tyrosine-specific transport system were found to be subject to repression control, thus confirming earlier reports. In addition, tryosine- and tryptophan-specific transport were found to be enhanced by growth of cells with phenylalanine. The repression and enhancement of the transport systems was abolished in a strain carrying an amber mutation in the regulator gene tyrR. This indicates that the tyrR gene product, which was previously shown to be involved in regulation of aromatic biosynthetic enzymes, is also involved in the regulation of the aromatic amino acid transport systems.     

Regulation of the Escherichia coli cad operon: location of a site required for acid induction.

The cad operon encodes lysine decarboxylase and a protein homologous to amino acid antiporters. These two genes are induced under conditions of low pH, anaerobiosis, and excess lysine. The upstream regulatory region of the cad operon has been cloned into lacZ expression vectors for analysis of the sequences involved in these responses. Deletion analysis of the upstream region and cloning of various fragments to make cadA::lacZ or cadB::lacZ protein fusions or operon fusions showed that cadA was translated more efficiently than cadB and localized the pH-responsive site to a region near an upstream EcoRV site. Construction of defined end points by polymerase chain reaction further localized the left end of the regulatory site. The presence of short fragments bearing the regulatory region on high-copy-number plasmids greatly reduced expression from the chromosomal cad operon, suggesting that titration of an essential activator protein was occurring. With nonoptimal polymerase chain reaction conditions, a set of single point mutants were made in the upstream regulatory region. Certain of these altered regulatory regions were unable to compete for the regulatory factor in vivo. The locations of these essential bases indicate that a sequence near the EcoRV site is very important for the activator-DNA interaction. In vivo methylation experiments were conducted with cells grown at pH 5.5 or at pH 8, and a difference in protection was observed at specific G residues in and around the region defined as important in pH regulation by the mutation studies. This work defines essential sequences for acid induction of this system involved in neutralization of extracellular acid.     

Cation transport in Escherichia coli. IX. Regulation of K transport

Kinetics of K exchange in the steady state and of net K uptake after osmotic upshock are reported for the four K transport systems of Escherichia coli: Kdp, TrkA, TrkD, and TrkF. Energy requirements for K exchange are reported for the Kdp and TrkA systems. For each system, kinetics of these two modes of K transport differ from those for net K uptake by K-depleted cells (Rhoads, D. B. F.B. Walters, and W. Epstein. 1976. J. Gen. Physiol. 67:325-341). The TrkA and TrkD systems are inhibited by high intracellular K, the TrkF system is stimulated by intracellular K, whereas the Kdp system is inhibited by external K when intracellular K is high. All four systems mediate net K uptake in response to osmotic upshock. Exchange by the Kdp and TrkA systems requires ATP but is not dependent on the protonmotive force. Energy requirements for the Kdp system are thus identical whether measured as net K uptake or K exchange, whereas the TrkA system differs in that it is dependent on the protonmotive force only for net K uptake. We suggest that in both the Kpd and TrkA systems formation of a phosphorylated intermediate is necessary for all K transport, although exchange transport may not consume energy. The protonmotive-force dependence of the TrkA system is interpreted as a regulatory influence, limiting this system to exchange except when the protonmotive force is high.     

Photoaffinity labeling of fatty acid-binding proteins involved in long chain fatty acid transport in Escherichia coli.

The photoreactive fatty acid 11-m-diazirinophenoxy-[11-3H]undecanoate was shown to be taken up specifically by the fatty acid transport system expressed in Escherichia coli grown on oleate. This photoreactive fatty acid analogue was therefore used to identify proteins involved in fatty acid uptake in E. coli. The fadL protein was labeled by the probe, confirmed to be exclusively in the outer membrane and to exhibit the heat modifiable behavior typical of outer membrane proteins. The apparent pI of the incompletely denatured form of the protein having the mobility of a 33-kDa protein was 4.6 while that of the fully denatured form was consistent with the calculated value of 5.2. The denaturation was reversible depending upon the protein to detergent ratios. The photoreactive fatty acid partitions into the outer membrane, resulting in extensive photolabeling of the lipid; a high affinity fatty acid-binding site is not apparent in total membranes labeled using free fatty acids due to this large binding capacity of the outer membrane. However, when the free fatty acid concentration was controlled by supplying it as a bovine serum albumin complex, the fadL protein exhibited saturable high affinity fatty acid binding, having an apparent Kd for the probe of 63 nM. The methods described very readily identify fatty acid-binding proteins: the fact that even when the sensitivity was increased 500-fold, no evidence was found for the presence of a fatty acid-binding protein in the inner membrane is consistent with the proposal that fatty acid permeation across the plasma membrane is not protein mediated but occurs by a simple diffusive mechanism.