ADAPTATION OF A METHIONINE AUXOTROPH ESCHERICHIA COLI GROWTH ASSAY TO MICROTITER PLATES FOR QUANTITATING METHIONINE

A rapid microtiter methionine assay was developed using a methionine auxotroph E. coli strain. The bacterial strain was first grown on rich media to promote extensive bacterial growth and the cells were depleted to exhaust all endogenous methionine. After depletion, cells were transferred to minimal media with increasing concentrations of methionine and microtiter plates were incubated at 37C for 6 h. Methionine microtiter standard curves yielded linear growth responses to increasing concentrations of methionine in the range of 0 to 26.8 μM. Addition of different antibiotic and antifungal agents to the media did not significantly alter the linear growth response observed in the microtiter assay. This microtiter plate E. coli methionine assay has potential as a rapid in vitro assay method for quantifying methionine.     

POTENTIAL RAPID BIOASSAY FOR ALIMET® USING A METHIONINE ESCHERICHIA COLI AUXOTROPH

A potential rapid bioassay for methionine hydroxy analog (MHA) feed additive (ALIMET®) was examined using a methionine auxotroph E. coli strain. Bacterial cells were grown in minimal media containing a concentration range of 0 to 26.8 μM of either L-methionine or MHA as ALIMET®. Increasing either methionine or MHA concentration increased the growth rate of the methionine auxotroph. The estimated substrate affinities for methionine compared to MHA were not significantly different (P > 0.13) and the maximum growth rate estimates were also similar (P > 0.34). Methionine and MHA standard curves yielded linear responses (R²= 0.96) to increasing concentrations of the respective substrate. Based on these results it appears that the E. coli methionine auxotroph would have potential utility for further development of a rapid bioassay of ALIMET®.     

CONSTRUCTION AND GROWTH KINETICS OF A BIOLUMINESCENT METHIONINE AUXOTROPH ESCHERICHIA COLI STRAIN FOR POTENTIAL USE IN A METHIONINE BIOASSAY

Methionine is one of the essential and first limiting amino acids in animal nutrition. In this study, an Escherichia coli methionine auxotroph bacterial strain that exhibits a linear growth response to methionine concentrations was transformed with a plasmid containing genes encoding ampicillin resistance and bioluminescence in order to develop a microbiological technique for methionine quantitation. Transformants were selected based on antibiotic resistance and plasmid containing candidates were confirmed by restriction enzyme digestion and gel electrophoresis. To confirm the bioluminescent phenotype, video imaging of the strain using long exposure photography yielded colonies exhibiting bioluminescence. The strain was also tested in the presence of ampicillin supplemented media with increasing methionine concentrations and growth response (measured as optical density, OD), growth rates and methionine affinities were compared before and after transformation. Although the transformed E. coli methionine auxotroph exhibited somewhat different growth kinetic responses than the nontransformed strain, the standard curves used for estimating methionine concentrations were not different. Based on the results in this study the transformed bioluminescent strain could be used as an OD-based assay if bioluminescence equipment and materials are not available.     

Antibiotic amendment for suppression of indigenous microflora in feed sources for an Escherichia coli auxotroph lysine assay

Growth responses of lysine auxotrophic mutants of Escherichia coli have been used as a measurement of bioavailable lysine in protein sources and animal feeds. Sterilizing feed samples by autoclaving to eliminate non-specific background growth of indigenous feed micro-organisms prior to conducting the bacterial assay may introduce chemical and physical alterations to the feeds, influencing the estimation of available feed lysine. In this study, an antibiotic- and antifungal-supplemented medium was constructed to support growth of an E. coli lysine auxotroph assay organism, and was tested for its ability to repress indigenous bacterial and fungal growth in feed samples. To determine which antibiotics to include, an ampicillin-sensitive E. coli lysine mutant strain (ATCC no. 23812) was screened for antibiotic resistance and transformed with a plasmid carrying an ampicillin resistance gene. Maximum optical density quantitative response of the E. coli auxotroph to lysine was not altered by the antibiotic medium amendments (ampicillin, novobiocin and cycloheximide). Indigenous microfloral growth in a variety of typical animal feeds was suppressed in the presence of the antistatic agents. The estimated lysine recovery was 91.6% and 98.1% when the medium was used in an assay of available lysine in a lysine-supplemented feed. This indicates that the antibiotic-amended basal medium can be used for the E. coli-determined lysine availability of a variety of animal feeds without prior sterilization of the feed sources.     

AGITATION DURING INCUBATION REDUCES THE TIME REQUIRED FOR A LYSINE MICROBIOLOGICAL GROWTH ASSAY USING AN ESCHERICHIA COLI AUXOTROPHIC MUTANT

Microbiological assays involving Escherichia coli lysine auxotrophs must be optimized to facilitate routine use. Our objectives in this study were to characterize growth of an auxotrophic E. coli lysine mutant (American Type Culture Collection strain #23812) and examine the effect of agitation on E. coli mutant growth. A defined minimal salts basal medium was used and supplemented with various lysine concentrations. The E. coli lysine auxotroph responded to increasing lysine concentration with increasing optical density. When maximum optical density (MOD) was determined for the auxotroph, a linear increase was obtained as lysine concentrations were increased (R²± 0.96) for both agitation and static cultures. Growth rates were not significantly (p > 0.05) affected by lysine concentrations, cultural conditions or their combined effect. However, growth with agitation significantly (p < 0.05) reduced the assay time by shortening the lag phase and causing stationary phase to occur earlier. The values of R² (± 0.96) relatively remained constant over the range while the bacterial population were in the stationary phase. In conclusion, the lysine growth assay using the E. coli lysine auxotroph can be made more rapid by agitating the culture during incubation.     

Application of an Escherichia coli green fluorescent protein-based lysine biosensor under nonsterile conditions and autofluorescence background

AIMS: To examine the utility of an Escherichia coli green fluorescent protein (GFP) containing biosensor for quantification of bioavailable lysine in selected feed samples under nonsterile conditions and to estimate the background fluorescence of analyzed feed samples and evaluate the risk of confounding GFP emission from the lysine assay organism. METHODS AND RESULTS: Escherichia coli lysine auxotroph GFP based biosensor was used to determine the percentage of bioavailable lysine in two samples of soybean-, cottonseed-, and meat and bone meal under nonsterile conditions. The fluorescence emitted by GFP was successfully measured using a spectrofluorimeter to monitor bacterial growth response to protein-derived lysine and lysine containing small peptides. The autofluorescence of analyzed feed samples at different concentrations could also be estimated. CONCLUSIONS: When feed protein concentrations are decreased, autofluorescence interference can be avoided. SIGNIFICANCE: The E. coli lysine auxotroph GFP-based biosensor can successfully be used for the determination of bioavailable lysine in these selected animal feed proteins under nonsterile conditions. IMPACT OF THE STUDY: E. coli GFP biosensor for lysine has potential for routine application in animal feeds.     

Quantitative detection of crystalline lysine supplementation in poultry feeds using a rapid bacterial bioluminescence assay

Lysine is an essential amino acid for both humans and animals; and it is usually the first or second limiting amino acid in most formulated diets. In order to estimate the lysine content in feeds and feed sources, rapid amino acid bioassays have been developed. The objective of this work is to assess a rapid assay for lysine supplementation in chicken feeds, using a luminescent Escherichia coli lysine-auxotrophic strain, to avoid prior thermal sterilization. An E. coli lysine auxotroph carrying a plasmid with lux genes was used as the test organism. The lysine assay was conducted using depleted auxotrophic cells in lysine samples. Luminescence was measured with a Dynex MLX luminometer after addition of the aldehyde substrate. Growth response (monitored as optical density at 600 nm) and light emission response of the assay E. coli strain were monitored to generate standard curves. Bioluminescent analysis of feed samples indicated that the method works well in the presence of a complex feed matrix. Comparison of both optical density and luminescent-based methods indicated that, when the assay takes place under optimal conditions, both methodologies correlated well ( r(2)=0.99). Except for the 0.64% lysine-supplemented feed, estimates for lysine based on the bacterial assay were over 80% (82-97%) of the theoretical values. Animal data showed that the bacterial bioluminescent method correlated well with the chick bioassay when diets with different levels of lysine supplementation were assayed for lysine bioavailability ( r(2)=0.97). Luminescent methodology coupled with a bacterial growth assay is a promising technique to assess lysine availability in supplemented animal feeds.     

Regulation of serine transhydroxymethylase activity in Salmonella typhimurium

The regulation of serine transhydroxymethylase (EC 2.1.2.1.; l-serine:tetrahydrofolic-5,10-hydroxymethyltransferase) has been investigated in Salmonella typhimurium LT2. Our results indicate that limitation of a methionine auxotroph for methionine does not cause derepression of this enzyme as reported for Escherichia coli. However, a sixfold decrease in specific activity was observed when S. typhimurium cells were grown in glucose minimal medium supplemented with serine, glycine, methionine, adenine, guanine, and thymine. None of these compounds added to the growth medium individually produced more than a 42% reduction of wild-type enzyme activity. This enhanced repression by the combination of compounds suggests a form of cumulative repression of this enzyme. Growth of serine and thymine auxotrophs, with the respective requirement of each limiting, did not result in increased enzyme activity. However, growth of a purine auxotroph with a limiting amount of either guanine or inosine resulted in a five- to sevenfold increase in enzyme activity. A second condition causing significant derepression (fourfold increase) above the levels observed with cells grown in minimal medium was the addition of 0.5 mug of trimethoprim per ml, an inhibitor of the dihydrofolate reductase activity. (A partial report on this work was presented at 1974 meeting of the American Society for Microbiology.)     

Bacterial ethylene synthesis from 2-oxo-4-thiobutyric acid and from methionine

The ability of selected bacterial cultures to synthesize ethylene during growth in nutrient broth supplemented with methionine or 2-oxo-4-methylthiobutyric acid (KMBA) was examined. Although most cultures transformed KMBA into ethylene, only those of Escherichia coli SPAO and Chromobacterium violaceum were able to convert exogenously added methionine to ethylene. In chemically defined media, E. coli SPAO produced the highest amounts of ethylene from methionine and KMBA. This capability was affected by the nature of the carbon source and the type and amount of nitrogen source used for growth. When glutamate was used as sole source of carbon and nitrogen for growth, the activity of the ethylenogenic enzymes was reduced to 25% of that observed with cultures grown with glucose and NH4Cl. Neither methionine nor KMBA significantly affected the ethylenogenic capacity of E. coli SPAO. Menadione and paraquat, compounds that generate superoxide radicals, stimulated ethylene synthesis by harvested cells, but not by cell-free extracts of E. coli SPAO. In addition, cells of Pseudomonas aeruginosa, which produced no ethylene in culture in the presence of exogenously added KMBA, yet possessed the necessary enzymes in an active form, were able to synthesize ethylene from KMBA when incubated with menadione or paraquat.     

IMPROVEMENT OF SELECTIVITY FOR ISOLATION OF ESCHERICHIA COLI O157:H7 FROM GENERIC ESCHERICHIA COLI

A modified selective medium was developed to increase selectivity for isolation of Escherichia coli O157 from generic E. coli based on the knowledge that E. coli O157:H7 has more resistance against HCl condition than E. coli. As a preliminary experiment, four strains of E. coli O157:H7 (ATCC 35150, 43889, 43890, and 43894) were tested to determine the maximum concentration of 6N HCl (from 0 to 250 μL) added to 50 mL of MacConkey agar medium (MAC). The maximum level was 125 μL/50 mL (6N HCl/MAC), which E. coli O157:H7 strains could tolerate against the HCl concentration. After determination, comparative growth of 15 isolates of E. coli O157 and generic E. coli were evaluated on modified selective medium (HCl-MAC; with the addition of 125 μL/50 mL) and conventional MAC, respectively. All tested strains of E. coli O157 were grown on both media, whereas 9 out of 15 generic E. coli (60% of tested strains) were strongly inhibited on HCl-MAC. For selective isolation of E. coli O157 from generic E. coli, HCl-MAC has an effective potential for an implemental use. This information can extend as a baseline for use of HCl to conventional medium for successful isolation E. coli O157 from generic E. coli.     

Characterization of unexpected growth of Escherichia coli O157:H7 by modeling

Modeling of batch kinetics in minimal synthetic medium was used to characterize Escherichia coli O157:H7 growth, which appeared to be different from the exponential growth expected in minimal synthetic medium and observed for E. coli K-12. The turbidimetric kinetics of 14 of the 15 O157:H7 strains tested (93%) were nonexponential, whereas 25 of the 36 other E. coli strains tested (70%) exhibited exponential kinetics. Moreover, the anomaly was almost corrected when the minimal medium was supplemented with methionine. These observations were confirmed with two reference strains by using plate count monitoring. In mixed cultures, E. coli K-12 had a positive effect on E. coli O157:H7 and corrected its growth anomaly. This demonstrated that commensalism occurred, as the growth curve for E. coli K-12 was not affected. The interaction could be explained by an exchange of methionine, as the effect of E. coli K-12 on E. coli O157:H7 appeared to be similar to the effect of methionine.     

Genetic characterization of a highly efficient alternate pathway of serine biosynthesis in Escherichia coli.

There exists in Escherichia coli a known set of enzymes that were shown to function in an efficient and concerted way to convert threonine to serine. The sequence of reactions catalyzed by these enzymes is designated the Tut cycle (threonine utilization). To demonstrate that the relevant genes and their protein products play essential roles in serine biosynthesis, a number of mutants were analyzed. Strains of E. coli with lesions in serA, serB, serC, or glyA grew readily on minimal medium supplemented with elevated levels of leucine, arginine, lysine, threonine, and methionine. No growth on this medium was observed upon testing double mutants with lesions in one of the known ser genes plus a second lesion in glyA (serine hydroxymethyltransferase), gcv (the glycine cleavage system), or tdh (threonine dehydrogenase). Pseudorevertants of ser mutants capable of growth on either unsupplemented minimal medium or medium supplemented with low levels of leucine, arginine, lysine, threonine, and methionine were isolated. At least two unlinked mutations were associated with such phenotypes.     

Reduction of methionine sulfoxide to methionine by Escherichia coli.

L-Methionine-dl-sulfoxide can support the growth of an Escherichia coli methionine auxotroph, suggesting the presence of an enzyme(s) capable of reducing the sulfoxide to methionine. This was verified by showing that a cell-free extract of E. coli catalyzes the conversion of methionine sulfoxide to methionine. This reaction required reduced nicotinamide adenine dinucleotide phosphate and a generating system for this compound. The specific activity of the enzyme increased during logarithmic growth and was maximal when the culture attained a density of about 10(9) cells per ml.     

CYCLOHEXIMIDE AS A MEDIA AMENDMENT FOR ENUMERATING BACTERIAL POPULATIONS IN ANIMAL FEEDS

The present study was designed to evaluate cycloheximide as a potential media amendment for differential bacterial and fungal enumeration of animal feeds. The objectives of this study were to determine the effect of cycloheximide on bacterial growth rates and to evaluate its efficacy for the reduction of indigenous spreading fungi when enumerating bacterial populations in three types of feeds and after short or long-term storage. Escherichia coli, Bacillus cereus, Staphylococcus aureus, Listeria monocytogenes and Pseudomonas fluorescens were grown in tryptic soy broth containing cycloheximide to determine its effect on bacterial specific growth rates. Growth rates of B. cereus and S. aureus were significantly decreased by the addition of 600 and 1000 mg/L cycloheximide respectively, but other pure cultures were not significantly influenced by cycloheximide addition. Intrinsic bacterial populations from feed were not significantly affected by cycloheximide additions at concentrations from 10 to 300 mg/L, but the indigenous spreading molds from feeds were significantly decreased by these cycloheximide concentrations and were decreased below detection levels by 300 mg/L of cycloheximide. The addition of 300 mg/L of cycloheximide effectively eliminates fungal growth for accurate enumeration of bacterial populations in feeds.     

Prevalence of Escherichia coli O157 in cattle feeds in Midwestern feedlots

Comparisons of enrichment methods (with or without antibiotics and with or without a preenrichment step) using gram-negative (GN) broth or tryptic soy broth (TSB) were conducted with feeds inoculated with Escherichia coli O157:H7. TSB was more sensitive than GN broth, and TSB with a preenrichment step followed by TSB with antibiotics was more sensitive than plain TSB enrichment, in detecting E. coli O157 in inoculated feeds. Feed samples were collected from feed bunks from 54 feedlots to determine the prevalence of E. coli O157 in cattle feeds. TSB preenrichment followed by TSB with antibiotics and the standard GN broth enrichment were used for each feed sample. All samples underwent immunomagnetic separation and were plated onto sorbitol MacConkey agar with cefixime and potassium tellurite. Identification of E. coli O157 was based on indole production, positive latex agglutination for O157 antigen, API 20E test strip results, PCR for the eaeA gene, and the presence of at least one Shiga toxin. E. coli O157 was detected in 52 of 504 feed samples (10.3%) by using GN broth enrichment and in 46 of 504 feed samples (9.1%) by using TSB followed by TSB supplemented with cefixime and vancomycin. E. coli O157 was detected in 75 of 504 feed bunk samples (14.9%) by one or both methods. There was no correlation between E. coli O157 prevalence and generic coliform counts in feeds. The prevalence of E. coli O157 in cattle feed warrants further studies to increase our knowledge of the on-farm ecology of E. coli O157 in order to develop strategies to prevent food-borne disease in humans.     

Improved electro-transformation of highly DNA-restrictive corynebacteria with DNA extracted from starved Escherichia coli

Abstract Differences of up to 33000-fold in electro-transformability of highly DNA restrictive corynebacteria are observed in the DNA of a shuttle plasmid extracted from Escherichia coli hosts propagated in different nutritional conditions. Growth of the host in minimal medium increases plasmid transformability, whereas growth on rich media decreases it. In the E. coli DH5a host, the starvation-dependent increase in DNA transformability is reverted by supplementing with methionine, an obligate S-adenosyl-methionine (SAM) precursor. This suggests that an E. coli nutritionally modulated SAM-dependent DNA-methyltransferase may be involved in this phenomenon.     

Selective labeling of a membrane peptide with 15N-amino acids using cells grown in rich medium

Nuclear magnetic resonance spectra of membrane proteins containing multiple transmembrane helices have proven difficult to resolve due to the redundancy of aliphatic and Ser/Thr residues in transmembrane domains and the low chemical shift dispersity exhibited by residues in alpha-helical structures. Although (13)C- and (15)N-labeling are useful tools in the biophysical analysis of proteins, selective labeling of individual amino acids has been used to help elucidate more complete structures and to probe ligand-protein interactions. In general, selective labeling has been performed in Escherichia coli expression systems using minimal media supplemented with a single labeled amino acid and nineteen other unlabeled amino acids and/or by using auxotrophs for specific amino acids. Growth in minimal media often results in low yields of cells or expression products. We demonstrate a method in which one labeled amino acid is added to a rich medium. These conditions resulted in high expression (> or =100 mg/L) of a test fusion protein and milligram quantities of the selectively labeled membrane peptide after cyanogen bromide cleavage to release the peptide from the fusion protein. High levels of (15)N incorporation and acceptable levels of cross-labeling into other amino acid residues of the peptide were achieved. Growth in rich media is a simple and convenient alternative to growth in supplemented minimal media and is readily applicable to the expression of proteins selectively labeled with specific amino acids.     

Methionineless Death in Escherichia coli

Methionine auxotrophs of strains derived from Escherichia coli 15 lose their colony-forming ability when deprived of this amino acid. Late addition of methionine to liquid cultures did not restore plating efficiency but permitted growth of surviving cells. This phenomenon, termed methionineless death (mld), was not observed with methionine auxotrophs of E. coli strains B, W, or K(12), nor was a similar amino acidless death observed with corresponding auxotrophs of E. coli 15 for arginine, tryptophan, proline, isoleucine, and leucine. Mld was not dependent upon the genetic site determining methionine auxotrophy, nor did it affect the decarboxylation of methionine or the stability of methionyl-transfer ribonucleic acid synthetase activity of starved cells. Death was not altered by the presence of spermine or spermidine but was abolished by the methionine analogue, alpha-methylmethionine. Simultaneous starvation of another amino acid in a multiple auxotroph also significantly reduced mld, suggesting a possible role of protein synthesis. The onset of mld is correlated with a lower net increase of deoxyribonucleic acid.     

Stereospecificity of tripeptide utilization in a methionine auxotroph of Escherichia coli K-12

The stereospecificity of peptide utilization in Escherichia coli K-12 4212, a methionine auxotroph, was investigated using diastereomers of trimethionine and trimethionine methyl ester. Of the eight stereoisomers examined, only l-Met-l-Met-l-Met, l-Met-l-Met-d-Met, and d-Met-l-Met-l-Met and the corresponding methyl esters serve as growth substrates. Triornithine-resistant mutants of strain 4212 were isolated which failed to transport d-Met-l-Met-l-Met. These results provide evidence that an oligopeptide containing a d residue at its amine terminus can enter E. coli by the oligopeptide transport system.