Tryptophan Biosynthesis and Production of Other Related Compounds from Indole and L-Serine by Mixed Ruminal Bacteria, Protozoa, and Their Mixture In Vitro

Tryptophan (Trp) biosynthesis and production of other related compounds from 1 mM each of indole (IND), L-serine (Ser), and IND plus Ser by mixed ruminal bacteria (B), protozoa (P), and their mixture (BP) in an in vitro system were quantitatively investigated. Ruminal microorganisms were anaerobically incubated at 39°C for 12 h. Trp and other related compounds produced in both the supernatants and microbial hydrolyzates of the incubation were analyzed by HPLC. B, P, and BP suspensions were not able to produce Trp when incubated with only IND or Ser. Appreciable amounts of Trp (9.8, 3.1, and 6.6% of substrate) were produced from IND plus Ser after 12 h by B, P, and BP suspensions, respectively. Trp produced from IND + Ser in B was found only in the hydrolyzate, whereas it was found in the medium as a free form in P after a 12-h incubation period. Rumen bacteria and protozoa were separately demonstrated for the first time to produce Trp from IND plus Ser, and the ability of P to produce Trp from IND plus Ser was about one-third that of B in 12 h. Trp produced from IND plus Ser by B, P, and BP suspensions was simultaneously degraded into its related compounds, and, among them, indoleacetic acid (IAA) was a major product found in B. Production of IAA was 4.3, 0.3, and 3.2% of IND in 12 h by B, P, and BP suspensions, respectively. A small amount of skatole (SKT) (1.1 and 2.5% in B and BP, respectively) and p-cresol (CRL) (2.4 and 3.4% in B and BP, respectively) were also produced from IND plus Ser during 12-h incubation. P suspension produced no SKT or CRL from IND plus Ser in 12-h incubation. These results suggested for the first time that both rumen bacteria and protozoa have an ability to produce Trp from IND plus Ser, and the ability was higher in B than in P. The ratios of Trp produced from IND plus Ser to that from indolepyruvic acid by B, P, and BP were 1:3.4, 1:14.2, and 1:6.6 during 12-h incubation period. From these results, the degree of importance of producing Trp from IND plus Ser in the rumen was indicated. Received: 18 February 1999 / Accepted: 18 May 1999     

Production of Skatole and para-Cresol by a Rumen Lactobacillus sp.

The objective of this study was to examine the substrate specificity of several ruminal strains of a Lactobacillus sp. which previously was shown to produce skatole (3-methylindole) by the decarboxylation of indoleacetic acid. A total of 13 compounds were tested for decarboxylase activity. The Lactobacillus strains produced p-cresol (4-methylphenol) by the decarboxylation of p-hydroxyphenylacetic acid, but did not produce either o-cresol or m-cresol from the corresponding hydroxyphenylacetic acid isomers. These strains also decarboxylated 5-hydroxyindoleacetic acid to 5-hydroxyskatole and 3,4-dihydroxyphenylacetic acid to methylcatechol. Skatole and p-cresol were produced in a 0.5:1 ratio, when indoleacetic acid and p-hydroxyphenylacetic acid were combined in equimolar concentrations. Competition studies with indoleacetic acid and p-hydroxyphenylacetic acid suggested that two different decarboxylating enzymes are involved in the production of skatole and p-cresol by these strains. This is the first demonstration of both skatole production and p-cresol production by a single bacterium.     

Aromatic amino acid biosynthesis and production of related compounds from p-hydroxyphenylpyruvic acid by rumen bacteria,protozoa and their mixture

Summary. Aromatic amino acid biosynthesis and production of related compounds from p-hydroxyphenylpyruvic acid (HPY) by mixed rumen bacteria (B), protozoa (P), and their mixture (BP) in an in vitro system were quantitatively investigated. Microbial suspensions prepared from mature, fistulated goats fed Lucerne (Medicago sativa) cubes and a concentrate mixture were anaerobically incubated at 39°C for 12 h. Tyrosine (Tyr), phenylalanine (Phe), tryptophan (Trp) and other related compounds in both supernatants and hydrolyzates of all incubations were analyzed by HPLC. Large amounts of Tyr (27.0, 47.0 and 50.8% of disappeared HPY in B, P and BP, respectively) were produced from 1 mM HPY during a 12-h incubation period. The formation of Tyr in P was 1.8 and 1.6 times higher than those in B and BP, respectively. Appreciable amounts of Phe (3–12% of the disappeared HPY) and Trp (2–10% of the disappeared HPY) were also produced from HPY in B, P, and BP. Phe synthesis in B and P was almost similar but Trp synthesis in B was 1.8 times higher than that in P. The biosynthesis of both Phe and Trp from HPY in BP was higher than those in B plus P. A large amount of p-hydroxyphenylacetic acid (about 45% of the disappeared HPY) was produced from HPY in B which was 1.9 times higher than that in P. p-Hydroxybenzoic acid produced from HPY in P was 1.6 times higher than that in B. Considerable amounts of phenylpropionic acid, phenyllactic acid, and phenylpyruvic acid (2–6% of the disappeared HPY) were produced only in B. Received March 21, 2001 Accepted July 4, 2001     

Synthesis of <Emphasis Type="SmallCaps">dl</Emphasis>-tryptophan by modified broad specificity amino acid racemase from <Emphasis Type="Italic">Pseudomonas putida</Emphasis> IFO 12996

Broad specificity amino acid racemase (E.C. 5.1.1.10) from Pseudomonas putida IFO 12996 (BAR) is a unique racemase because of its broad substrate specificity. BAR has been considered as a possible catalyst which directly converts inexpensive l-amino acids to dl-amino acid racemates. The gene encoding BAR was cloned to utilize BAR for the synthesis of d-amino acids, especially d-Trp which is an important intermediate of pharmaceuticals. The substrate specificity of cloned BAR covered all of the standard amino acids; however, the activity toward Trp was low. Then, we performed random mutagenesis on bar to obtain mutant BAR derivatives with high activity for Trp. Five positive mutants were isolated after the two-step screening of the randomly mutated BAR. After the determination of the amino acid substitutions in these mutants, it was suggested that the substitutions at Y396 and I384 increased the Trp specific racemization activity and the racemization activity for overall amino acids, respectively. Among the positive mutants, I384M mutant BAR showed the highest activity for Trp. l-Trp (20 mM) was successfully racemized, and the proportion of d-Trp was reached 43% using I384M mutant BAR, while wild-type BAR racemized only 6% of initial l-Trp.     

Studies on the utilization of methionine sulfoxide and methionine sulfone by rumen microorganisms in vitro

Summary.  An in vitro experiment was conducted to test the ability of mixed rumen bacteria (B), protozoa (P), and their mixture (BP) to utilize the oxidized forms of methionine (Met) e.g., methionine sulfoxide (MSO), methionine sulfone (MSO₂). Rumen contents were collected from fistulated goats to prepare the microbial suspensions and were anaerobically incubated at 39°C for 12 h with or without MSO (1 mM) or MSO₂ (1 mM) as a substrate. Met and other related compounds produced in both the supernatants and hydrolyzates of the incubation were analyzed by HPLC. During 6- and 12-h incubation periods, MSO disappeared by 28.3 and 42.0%, 0.0 and 0.0%, and 40.6 and 62.4% in B, P, and BP suspensions, respectively. Rumen bacteria and the mixture of rumen bacteria and protozoa were capable to reduce MSO to Met, and the production of Met from MSO in BP (156.6 and 196.1 μmol/g MN) was about 17.3 and 14.1% higher than that in B alone (133.5 and 171.9 μmol/g MN) during 6- and 12-h incubations, respectively. On the other hand, mixed rumen protozoa were unable to utilize MSO. Other metabolites produced from MSO were found to be MSO₂ and 2-aminobutyric acid (2AB) in B and BP. MSO₂ as a substrate remained without diminution in all-microbial suspensions. It was concluded that B, P, and BP cannot utilize MSO₂; but MSO can be utilized by B and BP for producing Met. Received December 28, 2001 Accepted May 21, 2002 Published online October 14, 2002 Acknowledgements The authors are extremely grateful to Professor H. Ogawa, the University of Tokyo, Japan and Dr. Takashi Hasegawa, Miyazaki University, Japan for inserting permanent rumen fistulae in goats. We would like to thank MONBUSHO for the award of a research scholarship to Mamun M. Or-Rashid since 1996–2001. Authors' address: Shaila Wadud, Laboratory of Animal Nutrition and Biochemistry, Division of Animal Science, Miyazaki University, Miyazaki 889-2192, Japan, Fax. +81-985-58-7201, E-mail: rafatkun@hotmail.com     

Production of tyrosine and other aromatic compounds from phenylalanine by rumen microorganisms

Summary Rumen contents from three fistulated Japanese native goats fed Lucerne hay cubes (Medicago sativa) and concentrate mixture were collected to prepare the suspensions of mixed rumen bacteria (B), mixed protozoa (P) and a combination of the two (BP). Microbial suspensions were anaerobically incubated at 39°C for 12h with or without 1 MM ofl-phenylalanine (Phe). Phe, tyrosine (Tyr) and other related compounds in both supernatant and microbial hydrolysates of the incubations were analyzed by HPLC. Tyr can be produced from Phe not only by rumen bacteria but also by rumen protozoa. The production of Tyr during 12h incubation in B (183.6 mol/g MN) was 4.3 times higher than that in P. One of the intermediate products between Phe and Tyr seems to bep-hydroxyphenylacetic acid. The rate of the net degradation of Phe incubation in B (76.O mol/g MN/h) was 2.4 times higher than in P. In the case of all rumen microorganisms, degraded Phe was mainly (>53%) converted into phenylacetic acid. The production of benzoic acid was higher in P than in B suspensions. Small amount of phenylpyruvic acid was produced from Phe by both rumen bacteria and protozoa, but phenylpropionic acid and phenyllactic acid were produced only by rumen bacteria.     

Tryptophan biosynthesis and production of other related compounds from indolepyruvic acid by mixed ruminal bacteria,protozoa, and their mixture in vitro

Tryptophan (Trp) biosynthesis and the production of other related compounds by mixed ruminal bacteria (B), protozoa (P), and their mixture (BP) in an in vitro system were quantitatively investigated by using 1 mM of indole-3-pyruvic acid (IPA) as substrate. Ruminal microorganisms were anaerobically incubated at 39 degrees C for 12 h. Trp and other related compounds in both the supernatants and the microbial hydrolyzates of the incubation were analyzed by HPLC. As a whole, about 334, 440, and 436 &mgr;M of Trp were produced from IPA in 12 h by B, P, and BP suspensions, respectively. In the B suspension, a greater portion of synthesized Trp (242 &mgr;M) from IPA was accumulated as free form in the medium, whereas a large amount of Trp (92 &mgr;M) was incorporated into cell protein in a 12-h incubation. On the other hand, in the P suspension, a large amount of Trp (475 &mgr;M) from IPA was also found as free form in the supernatant in a 12-h incubation. Protozoa did not incorporate Trp into cell protein, but they liberated endogenous Trp (34 &mgr;M) into the medium. The net productions of Trp from IPA were 344.3 and 447.7 &mgr;mol/g of microbial nitrogen in 12 h by B and P suspensions, respectively. The ability of P to synthesize Trp from IPA was about 30% higher than that of B in 12 h. Trp produced from IPA by B, P, and BP suspensions were simultaneously degraded into its related compounds, and among them, indoleacetic acid (IAA) was a major product found in all microbial suspensions. Productions of IAA were 124, 25, and 99 &mgr;M from IPA in 12 h by B, P, and BP suspensions, respectively. The formation of indolelactic acid (ILA) from IPA was observed for the first time in all microbial suspensions, and it was about 84, 24, and 54 &mgr;M in 12 h by B, P, and BP, respectively. Higher IAA and ILA productions were observed in B when compared with P. A small amount of skatole (SKT) (26 &mgr;M) was produced from IPA in B, whereas a sizable amount of SKT (38 &mgr;M) was found in BP after a 12-h incubation. p-Cresol (CRL) was also produced from IPA by both B (43 &mgr;M) and BP (65 &mgr;M) suspensions in 12 h, and this is also the first discovery to show the formation of CRL from IPA by B and BP suspensions. BP suspension was more active to produce both SKT and CRL from IPA, though P suspension has no ability to produce either SKT or CRL from IPA during a 12-h incubation.     

Quantitative determination of aromatic amino acids and related compounds in rumen fluid by high-performance liquid chromatography

A rapid method for the quantitative determination of tyrosine (Tyr), phenylalanine (Phe), p-hydroxybenzoic acid (HBA), p-hydroxyphenylacetic acid (HPA), benzoic acid (BZA), p-hydroxyphenylpyruvic acid (HPY), phenylacetic acid (PAA), phenyllactic acid (PLA), tryptophan (Trp), indoleacetic acid (IAA), phenylpyruvic acid (PPY), phenylpropionic acid (PPA) and cinnamic acid (CNA) in goat rumen fluid was established by high-performance liquid chromatography (HPLC). The mobile phase used for isocratic elution was 50 mM sodium phosphate buffer (pH 6.5)–methanol (97:3, v/v). The flow-rate was 1.0 ml/min; column temperature 40°C and compounds were monitored at 215 nm with a UV absorbance detector after injection of 10 μl of filtered rumen fluid. Analysis was completed within 40 min. The minimum detectable limits of quantification (μM) of these compounds were Tyr, 2; Phe, 3; HBA, 1; HPA, 2; BZA, 2; HPY, 8; PAA, 3; PLA, 4; Trp, 2; IAA, 2; PPY, 15; PPA, 8 and CNA, 4. Detectable levels of Tyr, Phe, HPA, BZA, HPY, PAA, PLA, Trp and PPA were found in the deproteinized rumen fluid of goat fed a haycube and concentrate mixture. PAA was the predominant compound before and after feeding. The concentrations of HPA, BZA, PAA, PLA and PPA in the goat rumen fluid increased after feeding, while the concentration of Tyr decreased. Phe, HPY and Trp were minor components at all times. PPY, IAA and CNA were not detected and HBA was not completely resolved in the goat rumen fluid.     

Isolation and characteristics of a skatole-producing Lactobacillus sp. from the bovine rumen.

A bacterium that is capable of decarboxylating indoleacetic acid to skatole (3-methylindole) has been isolated from an L-tryptophan enrichment of bovine rumen fluid. The bacterium is a gram-positive, nonmotile, nonsporeforming rod. It is an obligate anaerobe, and strains predominatly produce D-(-)-lactic acid, with smaller amounts of L-(+)-lactic acid and acetic acid, from sugar. All four strains isolated gave a negative reaction to the indole test because they cannot form skatole directly from tryptophan. This is the first report of indoleacetic acid decarboxylation to skatole in pure culture and the demonstration of skatole production by a Lactobacillus species.     

Characterization of a tryptophan 6-halogenase from <Emphasis Type="Italic">Streptomyces toxytricini</Emphasis>

Tryptophan (Trp) halogenases are found in various bacteria and play an important role in natural product biosynthesis. Analysis of the genome of Streptomyces toxytricini NRRL 15443 revealed an ORF, stth, encoding a putative Trp halogenase within a non-ribosomal peptide synthetase gene cluster. This gene was cloned into pET28a and functionally overexpressed in Escherichia coli. The enzyme halogenated both l- and d-Trp to yield the corresponding 6-chlorinated derivatives. The optimum activity was at 40°C and pH 6 giving k _cat /K _M value of STTH of 72,000 min⁻¹ M⁻¹. The enzyme also used bromide to yield 6-bromo-Trp.     

Production of indolic compounds by rumen bacteria isolated from grazing ruminants

AIM: To screen rumen bacterial cultures and fresh ruminal isolates for indole and skatole production. METHODS AND RESULTS: Culture collection strains and fresh bacterial isolates from rumen contents of sheep and dairy cows were screened for the production of indolic compounds. Clostridium aminophilum FT, Peptostreptococcus ssp. S1, Fusobacterium necrophorum D4 produced indole and Clostridium sticklandii SR produced indoleacetic acid. Fresh isolates from sheep (TrE9262 and TrE7262) and dairy cows (152R-1a, 152R-1b, 152R-3 and 152R-4) produced indole, indolepropionic acid, tryptophol and skatole from the fermentation of tryptophan and indoleacetic acid. Glucose altered the indolic compounds produced in some, but not all, isolates. TrE7262 and 152R-4 were identified as Clostridium sporogenes and 152R-1b as a new Cl. aminophilum strain. Isolates TrE9262, 152R-1a and 152R-3 were not closely related to any described species but belong to Megasphaera, Prevotella and Actinomyces genera, respectively. CONCLUSIONS: Rumen bacteria that produced a range of indolic compounds were identified. Some isolates are distinct from the previously described bacteria and may represent novel species. SIGNIFICANCE AND IMPACT OF THE STUDY: These observations will contribute to understanding skatole and indole formation in the rumen and will lead to methods that control the formation of indolic compounds in pasture-grazed ruminants.     

Uptake and conversion of <Emphasis Type="SmallCaps">d</Emphasis>-amino acids in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>

The d-enantiomers of proteinogenic amino acids fulfill essential functions in bacteria, fungi and animals. Just in the plant kingdom, the metabolism and role of d-amino acids (d-AAs) still remains unclear, although plants have to cope with significant amounts of these compounds from microbial decay in the rhizosphere. To fill this gap of knowledge, we tested the inhibitory effects of d-AAs on plant growth and established a method to quantitate 16 out of 19 proteinogenic amino acids and their d-enantiomers in plant tissue extracts. Therefore, the amino acids in the extracts were derivatized with Marfey’s reagent and separated by HPLC–MS. We used two ecotypes (Col-0 and C24) and a mutant (lht1) of the model plant Arabidopsis thaliana to determine the influence and fate of exogenously applied d-AAs. All of them were found in high concentrations in the plant extracts after application, even in lht1, which points to additional transporters facilitating the import of d-AAs. The addition of particular amino acids (d-Trp, d-Phe, d-Met and d-His) led to the accumulation of the corresponding l-amino acid. In almost all cases, the application of a d-AA resulted in the accumulation of d-Ala and d-Glu. The presented results indicate that soil borne d-AAs can actively be taken up and metabolized via central metabolic routes.     

Catabolism of methionine and threonine in vitro by mixed ruminal bacteria and protozoa

Summary. In vitro studies were conducted to examine the metabolism of methionine (Met) and threonine (Thr) using mixed ruminal bacteria (B), mixed ruminal protozoa (P), and a combination of these two (BP). Rumen microorganisms were collected from fistulated goats fed with lucerne cubes (Medicago sativa) and a concentrate mixture twice a day. Microbial suspensions were anaerobically incubated with or without 1 mM each of the substrates at 39°C for 12 h. Met, Thr and their related amino compounds in both the supernatants and microbial hydrolyzates of the incubation were analyzed by HPLC. Met was degraded by 58.7, 22.1, and 67.3% as a whole in B, P, and BP suspensions, respectively, during 12 h incubation. In the case of Thr, these values were 67.3, 33.4, and 76.2% in B, P, and BP, respectively. Met was catabolized by all of the three microbial suspensions to methionine sulfoxide and 2-aminobutyric acid. Catabolism of Thr by B and BP resulted in the production of glycine and 2-aminobutyric acid, while P produced only 2-aminobutyric acid. From these results, the existence of diverse catabolic routes of Met and Thr in rumen microorganisms was indicated. Received August 2, 2000 Accepted February 27, 2001     

Thin layer chromatographical detection of tyrosine produced from <Emphasis Type="SmallCaps">l</Emphasis>-[U-<Superscript>14</Superscript>C]phenylalanine by ruminal microbes

Summary.  Thin layer chromatographical detection of tyrosine (Tyr) synthesized from l-[U-¹⁴C]phenylalanine (Phe) (1 mM) by rumen bacteria (B) and protozoa (P) collected from fistulated Japanese Goat was carried out. About 16 and 12% of the added Phe was converted to Tyr by B and P, respectively. Large amount of radioactivity in ether fractions indicated an abundant production of aromatic acids from Phe. Small amount of radioactivity found in CO₂ fractions implied an occurrence of considerable decarboxylation reaction(s) by rumen bacteria and protozoa. Received July 18, 2001 Accepted December 3, 2001     

Pathways of IAA production from tryptophan by plants and by their epiphytic bacteria: Metabolism of indolepyruvic acid and indolelactic acid

Metabolites of indolepyruvic acid and indolelactic acid were investigated using 2 systems: a bacterial (pea stem homogenates containing the epiphytic bacteria) and a plant system (pea stem sections under sterile conditions). The products of spontaneous indolepyruvic acid decomposition in aqueous solution and during chromatography were investigated, too. Biological indolepyruvic acid conversion yields, besides those substance amounts which occur spontaneously, indoleacetic acid, indoleethanol (tryptophol) and (only in the sterile plant system) indoleacetaldehyde. An inhibitor extract from pea stems decreases the indoleacetic acid and increases the indoleethanol and indoleacetaldehyde gain. Indolelactic acid is not metabolized in the sterile plant sections. Indolelactic acid oxidation by the bacteria-containing homogenate yields indolepyruvic acid and is inhibited by the inhibitor extract.     

<Emphasis Type="SmallCaps">d</Emphasis>-Hexosaminate production by oxidative fermentation

Microbial production of d-hexosaminate was examined by means of oxidative fermentation with acetic acid bacteria. In most strains of acetic acid bacteria, membrane-bound d-glucosamine dehydrogenase (synonymous with an alternative d-glucose dehydrogenase distinct from quinoprotein d-glucose dehydrogenase) oxidized d-hexosamines to the corresponding d-hexosaminates in a stoichiometric manner. Conversion of d-hexosamines to the corresponding d-hexosaminates was observed with growing cells of acetic acid bacteria, and d-hexosaminate was stably accumulated in the culture medium even though d-hexosamine was exhausted. Since the enzyme responsible is located on the outer surface of the cytoplasmic membrane, and the enzyme activity is linked to the respiratory chain of the organisms, resting cells, dried cells, and immobilized cells of acetic acid bacteria were effective catalysts for d-hexosaminate production. d-Mannosaminate and d-galactosaminate were also prepared for the first time by means of oxidative fermentation, and three different d-hexosaminates were isolated from unreacted substrate by a chromatographic separation. In this paper, d-hexosaminate production by oxidative fermentation carried out mainly with Gluconobacter frateurii IFO 3264 is exemplified as a typical example.     

Content of indoleacetic acid and its metabolism in root nodules ofMelilotus alba

The root nodules ofMelilotus alba, a leguminous fodder herb, contain a high amount of indoleacetic acid (IAA). The tryptophan pool present in the nodule might serve as a source for the IAA production. Metabolism of IAA in the nodules was evidenced by the presence of IAA-metabolizing enzymes, IAA oxidase and peroxidase. A high amount of IAA was produced by the symbiont isolated from the nodules in culture, when supplemented with tryptophan. For IAA production, the bacteria preferred thel-isomer over thedl- ord-isomer of tryptophan. The possible role of nodular IAA production on the legume-Rhizobium symbiosis is discussed.     

Nutritional and medicinal aspects of <Emphasis Type="SmallCaps">d</Emphasis>-amino acids

This paper reviews and interprets a method for determining the nutritional value of d-amino acids, d-peptides, and amino acid derivatives using a growth assay in mice fed a synthetic all-amino acid diet. A large number of experiments were carried out in which a molar equivalent of the test compound replaced a nutritionally essential amino acid such as l-lysine (l-Lys), l-methionine (l-Met), l-phenylalanine (l-Phe), and l-tryptophan (l-Trp) as well as the semi-essential amino acids l-cysteine (l-Cys) and l-tyrosine (l-Tyr). The results show wide-ranging variations in the biological utilization of test substances. The method is generally applicable to the determination of the biological utilization and safety of any amino acid derivative as a potential nutritional source of the corresponding l-amino acid. Because the organism is forced to use the d-amino acid or amino acid derivative as the sole source of the essential or semi-essential amino acid being replaced, and because a free amino acid diet allows better control of composition, the use of all-amino-acid diets for such determinations may be preferable to protein-based diets. Also covered are brief summaries of the widely scattered literature on dietary and pharmacological aspects of 27 individual d-amino acids, d-peptides, and isomeric amino acid derivatives and suggested research needs in each of these areas. The described results provide a valuable record and resource for further progress on the multifaceted aspects of d-amino acids in food and biological samples.     

Evaluation of different markers for determination of the microbial nitrogen flow into the duodenum of dairy cows

2.6‐Diaminopimelic acid (DAPA), ribonucleic acid (RNA), ¹⁵N, D‐alanine (D‐ALA) and the amino acid profiles (AAP) were compared as microbial markers for determination of the microbial protein synthesis in the rumen. Three dairy cows (Schwarzbuntes Milchrind, LW 602 kg), each fitted with a rumen cannula and a re‐entrant cannula in the proximal duodenum, were offered four isoenergetic and isonitrogenous diets (mean daily intake 15.0 ± 0.45 kg DM; forage: concentrate = 50:50) in a periodic experiment. The diets contained soyabean extracted meal, meat and bone meal, pea meal and dried clover as major sources of protein. On the 4th day after administration of 9 g ¹⁵N‐labelled urea (95 atom‐% ¹⁵N‐excess) per day, samples of rumen fluid and duodenal digesta were obtained 3 h after feeding. The bacteria were isolated by differential centrifugation. Bacteria harvested from the rumen had significantly higher ¹⁵N enrichment and D‐ALA: N ratio than ‘duodenal’ bacteria. However, DAPA: N ratio was higher in ‘duodenal’ bacteria compared to rumen bacteria. There were no differences in RNA: N ratio between rumen and ‘duodenal’ bacteria. The source of the bacteria in the digestive tract has an influence on the ratio of microbial N: total N, especially when ¹⁵N, AAP, DAPA and D‐ALA but not RNA were used as markers. The most reproducible method was D‐ALA (C.V. 4.7 for rumen and 6.8 for ‘duodenal’ bacteria) followed by ¹⁵N (10.8 resp. 4.8) and RNA (9.7 resp. 8.2). The results obtained with ¹⁵N and D‐ALA agreed closely at the same source of bacteria. The RNA method reached the level of these markers (¹⁵N, D‐ALA) when the bacteria were isolated from the duodenum. It is concluded that D‐ALA (bacteria isolated from rumen and duodenum) and also ¹⁵N (bacteria isolated from duodenum) were the best markers for estimation of the microbial protein synthesis.     

Amplification of the tryptophan operon gene in Escherichia coli chromosome to increase l-tryptophan biosynthesis

Classical mutagenesis could desensitize the feedback inhibition of l-tryptophan (l-Trp) biosynthesis. Among the mutants, a5-fluorotryptophan-resistant strain, Escherichia coli EMS4-C25 produced 3 g/l of l-Trp within 18 h. The feedback-resistant l-Trp operon gene (trp) prepared from E. coli EMS4-C25 was inserted into pUC19 and pHSG576 to generate pTC701 and pTC576, respectively. When pHSG576 and pTC701 were introduced into E. coli EMS4-C25, chromosomal integration occured through homologous recombination. By using Souther hybridization, we demostrated that the integrated plasmids existed as multicopies. The strains with integrated foreign trp operon gene had higher activities of anthranilate synthase and Trp synthase than those found for the host strain and produced 9.2 g/l of l-Trp with 13% conversion yield from d-glucose. The integration and implification of the trp-operon-beraing plasmid avoided the plasmid instability and increased l-TRp production. Correspondence to: E.-C. Chan