Inside or outside: detecting the cellular location of bacterial pathogens.

Salmonella are intracellular pathogens that infect and multiply inside macrophages. Although Salmonella are some of the best-studied pathogens, it is difficult to determine quickly and reliably whether the bacteria are intracellular or extracellular. We have developed a novel method using differential fluorescence of two fluorescent proteins to determine the cellular location of pathogenic bacteria in macrophage infection assays. Using the differential expression of two unique fluorescent proteins that are expressed under specific conditions, we have developed a real-time assay for macrophage infections. The critical advantages of this system are that it does not alter the bacterial surface, it is not toxic to either the bacteria or the host cell, and it may be used in real-time quantitative assays. This assay can be readily applied to any other model pathogenic systems such as Listeria, Mycobacteria, and Legionella in which intracellular gene expression has been characterized.

A role for Salmonella fimbriae in intraperitoneal infections.

Enteric bacteria possess multiple fimbriae, many of which play critical roles in attachment to epithelial cell surfaces. SEF14 fimbriae are only found in Salmonella enterica serovar Enteritidis (S. enteritidis) and closely related serovars, suggesting that SEF14 fimbriae may affect serovar-specific virulence traits. Despite evidence that SEF14 fimbriae are expressed by S. enteritidis in vivo, previous studies showed that SEF14 fimbriae do not mediate adhesion to the intestinal epithelium. Therefore, we tested whether SEF14 fimbriae are required for virulence at a stage in infection after the bacteria have passed the intestinal barrier. Polar mutations that disrupt the entire sef operon decreased virulence in mice more than 1,000-fold. Nonpolar mutations that disrupted sefA (encoding the major structural subunit) did not affect virulence, but mutations that disrupted sefD (encoding the putative adhesion subunit) resulted in a severe virulence defect. The results indicate that the putative SEF14 adhesion subunit is specifically required for a stage of the infection subsequent to transit across the intestinal barrier. Therefore, we tested whether SefD is required for uptake or survival in macrophages. The majority of wild-type bacteria were detected inside macrophages soon after i.p. infection, but the sefD mutants were not readily internalized by peritoneal macrophages. These results indicate that the potential SEF14 adhesion subunit is essential for efficient uptake or survival of S. enteritidis in macrophages. This report describes a role of fimbriae in intracellular infection, and indicates that fimbriae may be required for systemic infections at stages beyond the initial colonization of host epithelial surfaces.

Increasing DNA transfer efficiency by temporary inactivation of host restriction.

E. coli and Salmonella typhimurium are widely used bacterial hosts for genetic manipulation of DNA from prokaryotes and eukaryotes. Introduction of foreign DNA by electroporation or transduction into E. coli and Salmonella is limited by host restriction of incoming DNA by the recipient cells. Here, we describe a simple method that temporarily inactivates host restriction, allowing high-frequency DNA transfer. This technique might be readily applied to a wide range of bacteria to increase DNA transfer between strains and species.

Integration host factor facilitates repression of the put operon in Salmonella typhimurium.

Transcriptional regulation of the put operon is mediated by a unique mechanism involving autogenous regulation by the PutA protein, a membrane-associated dehydrogenase. The 420-bp put control region contains the putP and putA promoters, multiple operator sites, multiple catabolite repression protein binding sites, and several potential integration host factor (IHF)-binding sites (ihf). In this study, we show that IHF facilitates repression of the put operon in vivo, and IHF binds specifically to two ihf sites in the put control region in vitro. DNA gyrase mutants that alter the degree of chromosomal supercoiling do not affect put regulation, indicating that the effect of IHF on put expression is in this case independent of supercoiling.

Family Spirosomaceae: gram-negative ring-forming aerobic bacteria.

The bacteria having a unique ring-like morphology first isolated from nasal mucus by Weibel in 1887 were classified as a new genus Spirosoma by Migula in 1894. However, because these bacteria were not completely described for taxonomic purposes and their cultures were no longer available, the genus was deleted from the Bergey's Manual of Determinative Bacteriology, 6th edition, 1948. Orskov (1928) created a new genus "Microcyclus" (a name that has been found to be illegitimate and replaced with Ancylobacter by Raj 1983) to describe these nonmotile vibroid bacteria that occasionally formed ring-like structures. Several similar isolates found in many countries during the last 60 years were readily identified with this genus on the basis of the characteristic morphology alone. For the first time, these fascinating bacteria were extensively reviewed by Raj in 1977 and again in 1981. However, during the last decade, the systematics of these microcyclus bacteria has been reexamined and redefined. It has been shown that these Gram-negative ring-forming aerobic bacteria constitute a heterogeneous group of five genera: Ancylobacter, Cyclobacterium, Flectobacillus, Runella, and Spirosoma; the last four genera have been grouped into a family Spirosomaceace (reviving the old discarded name originally proposed by Migula 1894), thus separating them from the genus Ancylobacter which remains unaffiliated with any family yet (Bergey's Manual of Systematic Bacteriology, Vol. I, 9th ed., 1984). Also, this article reviews the recent studies reported on the ecology, morphogenesis, metabolism, and physiology of the picturesque bacteria.

Mutations of putP that alter the lithium sensitivity of Salmonella typhimurium.

The putP gene encodes the major proline permease in Salmonella typhimurium that couples transport of proline to the sodium electrochemical gradient. To identify residues involved in the cation binding site, we have isolated putP mutants that confer resistance to lithium during growth on proline. Wild-type S. typhimurium can grow well on proline as the sole carbon source in media supplemented with NaCl, but grows poorly when LiCl is substituted for NaCl. In contrast to the growth phenotype, proline permease is capable of transporting proline via Na+/proline or Li+/proline symport. Therefore, we selected mutants that grow well on media containing proline as the sole carbon source in the presence of lithium ions. All of the mutants assayed exhibit decreased rates of Li+/proline and Na+/proline cotransport relative to wild type. The location of each mutation was determined by deletion mapping: the mutations cluster in two small deletion intervals at the 5' and 3' termini of the putP gene. The map positions of these lithium resistance mutations are different from the locations of the previously isolated substrate specificity mutations. These results suggest that Lir mutations may define domains of the protein that fold to form the cation binding site of proline permease.

Regulation of proline utilization in Salmonella typhimurium: molecular characterization of the put operon, and DNA sequence of the put control region.

The two genes required for proline utilization (put) in Salmonella typhimurium form a divergent operon. Extensive genetic evidence suggests that transcription of the put operon is autoregulated by the putA gene product, a membrane-associated dehydrogenase. In order to understand the mechanism of regulation, we characterized plasmid clones of the put operon. A 7.5 kb clone contains both of the put structural genes and regulatory sites. This clone only expressed two unique proteins corresponding to the putA and putP gene products. By comparing the physical and genetic maps of the put operon, the position of the put regulatory region was defined and the DNA sequence of this region was determined. Analysis of the DNA sequence indicated several potential regulatory sites for the put genes. Based on genetic and physical mapping studies, the most likely regulatory sites are two convergent promoters approximately 30 bp apart. A 27 bp palindrome located between the two promoters may be the operator for autoregulation by the PutA protein. The putA translational start site is 40 bp downstream of its putative mRNA start site. The putP promoter and its translational start site are separated by a 400 bp untranslated region.

Isolation and characterization of Salmonella typhimurium glyoxylate shunt mutants.

Growth of Salmonella typhimurium on acetate as a sole carbon source requires expression of the glyoxylate shunt; however, the genes for the glyoxylate shunt enzymes have not been previously identified in S. typhimurium. In this study, we isolated transposon insertions in the genes for the two unique enzymes of this pathway, aceA (isocitrate lyase) and aceB (malate synthase). The aceA and aceB genes were located at 89.5 min on the S. typhimurium genetic map. Genetic linkage to nearby loci indicated that the relative gene order is purDJ metA aceB aceA. Transposon insertions in aceB were polar on aceA, suggesting that the genes form an operon transcribed from aceB to aceA. Transcriptional regulation of the aceBA operon was studied by constructing mini-Mu d(lac Kan) operon fusions. Analysis of these fusions indicated that expression of the aceBA operon is regulated at the level of transcription; the aceBA genes were induced when acetate was present and repressing carbon sources were absent. Although glucose represses expression of the aceBA operon, repression does not seem to be mediated solely by cyclic AMP-cyclic AMP receptor protein complex. Mutants with altered regulation of the aceBA operon were isolated.

Acetohydroxy acid synthase I is required for isoleucine and valine biosynthesis by Salmonella typhimurium LT2 during growth on acetate or long-chain fatty acids.

Salmonella typhimurium LT2 normally expresses two acetohydroxy acid synthases (AHAS I and AHAS II). The function of AHAS I in this organism was unclear, since AHAS I-deficient (ilvBN) mutants of LT2 grew well on glucose or succinate minimal media, whereas AHAS II-deficient (ilvGM) mutants requried isoleucine for normal growth on glucose minimal media. We report that AHAS I-deficient mutants of S. typhimurium required isoleucine and valine for growth on acetate or oleate minimal media, whereas AHAS II-deficient mutants were able to grow on these media without isoleucine supplementation.

Regulation of the put operon in Salmonella typhimurium: characterization of promoter and operator mutations.

The two genes required for proline utilization by S. typhimurium form a divergent operon. Expression of the put operon is induced by proline and subject to catabolite repression. Genetic evidence suggests that putA protein autogenously represses transcription of the putA and putP genes. In order to establish the molecular mechanism of put operon regulation we isolated regulatory mutations in the put control region. These mutants were selected using two phenotypes: the ability to degrade a toxic proline analogue, dehydroproline, due to overexpression of putA enzyme activity, or overexpression of lacZ from put::Mud operon fusions. The effect of each mutation on transcription in both directions was determined by measuring lacZ expression from putA and putP operon fusions. These regulatory mutations were cis-dominant when the putA protein was provided in trans, and they map in a region between the two genes. The phenotypes of the mutants suggest that the put regulatory region has a single operator site where the putA protein binds to repress transcription in both directions, and the putA and putP promoters overlap.

Proline transport in Salmonella typhimurium: putP permease mutants with altered substrate specificity.

The putP gene encodes a proline permease required for Salmonella typhimurium LT2 to grow on proline as the sole source of nitrogen. The wild-type strain is sensitive to two toxic proline analogs (azetidine-2-carboxylic acid and 3,4-dehydroproline) also transported by the putP permease. Most mutations in putP prevent transport of all three substrates. Such mutants are unable to grow on proline and are resistant to both of the analogs. To define domains of the putP gene that specify the substrate binding site, we used localized mutagenesis to isolate rare mutants with altered substrate specificity. The position of the mutations in the putP gene was determined by deletion mapping. Most of the mutations are located in three small (approximately 100-base-pair) deletion intervals of the putP gene. The sensitivity of the mutants to the proline analogs was quantitated by radial streaking to determine the affinity of the mutant permeases for the substrates. Some of the mutants showed apparent changes in the kinetics of the substrates transported. These results indicate that the substrate specificity mutations are probably due to amino acid substitutions at or near the active site of proline permease.

Regulation of proline utilization in Salmonella typhimurium: characterization of put::Mu d(Ap, lac) operon fusions.

The genes for proline utilization were fused to the structural genes of the lac operon by use of the hybrid Mu phage derivative Mu d(Ap lac). Stable deletion derivatives of these fusions were selected and used to study the transcriptional regulation of the put genes. Analysis of these fusions showed that the putA gene product, a bifunctional oxidase-dehydrogenase, also serves to negatively control transcription of the putA and putP genes. Transcription of the put genes is repressed only in putA+ strains; this repression is lifted when exogenous proline is supplied. Transcription of the put genes is stimulated by cyclic AMP in putA+ and putA strains. Maximal induction of the put genes in putA+ strains requires oxygen or an alternative electron acceptor. This oxygen effect is mediated by the putA protein since putA mutants show maximal transcription even without an electron acceptor. The orientation of the Mu d(Ap lac) insertions was determined by formation of Hfr's via the lac homology on F'ts114 lac+. The direction of chromosome mobilization by these Mu d(Ap lac)-directed Hfr's demonstrated that the putP and putA genes are divergently transcribed from a central regulatory region lying between them.

Genetic regulation of the glyoxylate shunt in Escherichia coli K-12.

The expression of the glyoxylate shunt enzymes is required for growth of Escherichia coli on acetate or fatty acids as a sole carbon source. The genes for the two unique enzymes of the glyoxylate shunt, aceA and aceB, are located at 90 min on the E. coli K-12 genetic map. Polar mutations in the aceB gene eliminate aceA gene function, suggesting that these genes constitute an operon and the direction of transcription is from aceB to aceA. Mu d (Ap lac) fusions with the aceA gene have been constructed to study the regulation of the ace operon. Expression of the ace operon is under the transcriptional control of two genes: the iclR gene, which maps near the ace operon, and the fadR gene, which maps at 25 min, and is also involved in the regulation of the fatty acid degradation (fad) regulon. Merodiploid studies demonstrated that both the iclR and fadR genes regulate the glyoxylate shunt in a trans-dominant manner.

Role of gene fadR in Escherichia coli acetate metabolism.

Mutants of Escherichia coli K-12 constitutive for fatty acid degradation (fadR) showed an increased rate of utilization of exogenous acetate. Acetate transport, oxidation, and incorporation into macromolecules was approximately fivefold greater in fadR mutants than fadR+ strains during growth on succinate as a carbon source. This effect was due to the elevated levels of glyoxylate shunt enzymes in fadR mutants, since (i) similar results were seen with mutants constitutive for the glyoxylate shunt enzymes (iclR), (ii) induction of the glyoxylate shunt in fadR+ strains by growth on acetate or oleate increased the rate of acetate utilization to levels comparable to those in fadR mutants, and (iii) fadR and fadR+ derivatives of mutants defective for the glyoxylate shunt enzymes showed equivalent rates of acetate utilization under these conditions. These results suggest that the operation of the glyoxylate shunt may play a significant role in the utilization of exogenous acetate by fadR mutants.

Transport of long and medium chain fatty acids by Escherichia coli K12.

Kinetic, metabolic, and physical parameters of long and medium chain fatty acid transport by Escherichia coli K12 were determined. Uptake of long chain fatty acids (C11-C18:1) mediated by the fadL gene involves concentrative transport. Evidence for this is as follows: (i) characteristic Ki and Vmax values were obtained for long chain fatty acids, (ii) long chain fatty acid transport was inhibited by energy inhibitors, (iii) long chain fatty acids were concentrated 10-fold inside the cell against a concentration gradient, (iv) efflux of transported long chain fatty acids did not occur, and (v) an energy of activation of 11.72 kcal mol-1 and Q10 of 2.3 were obtained for long chain fatty acid transport. The fadL gene product shows some activity with medium chain fatty acids (C7-C10) as well. Medium chain fatty acids also appear to enter the cell by simple diffusion since: (i) medium chain fatty acid transport by fadL strains is not saturable under our assay conditions, (ii) fadL strains do not concentrate medium chain fatty acids against a concentration gradient, and (iii) medium chain fatty acids are available for efflux in fadL strains. Physical parameters of long and medium chain fatty acid transport are also reported. These results present evidence for separate mechanisms of long and medium chain fatty acid transport in E. coli.

Selection for loss of tetracycline resistance by Escherichia coli.

An improved medium for the direct, positive selection of tetracycline-sensitive clones from a population of tetracycline-resistant strains of Escherichia coli is described.

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.

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.