Microbial synthesis of L-[15N]leucine L-[15N]isoleucine, and L-[3-13C]-and L-[3'-13C]isoleucines studied by nuclear magnetic resonance and gas chromatography-mass spectrometry.

The preparation of leucine and isoleucine labeled with 15N and of site-specific 13C-labeled isoleucines is described. This method is based on the induction of the biosynthetic pathways specific for branched chain amino acids in glutamic acid producing bacteria, and controlled provision of stable isotope labeled precursors. Corynebacterium glutamicum (ATCC 13032), a glutamic acid overproducer, was incubated in leucine production medium which consisted of a basal medium supplemented with [15N]ammonium sulfate, glucose, and sodium alpha-ketoisocaproate. production of L-[15N]leucine reached 138 mumol/ml at an isotopic efficiency of 90%. It was purified and checked by proton NMR and GC-MS. The electron impact (EI) spectrum showed 95 atom% enrichment. The cultivation of C. glutamicum in a similar medium containing alpha-ketobutyrate yielded L-[15N]isoleucine at a concentration of 120 mumol/ml. The GC-MS EI and chemical ionization (CI) spectra confirmed enrichment of 96 atom% 15N as that of the labeled precursors. The biosynthesis of L-[13C]isoleucine was carried out by induced cells which were transferred to a similar medium in which [2-13C]- or [3-13C]pyruvic acid replaced glucose. 13C NMR of the product isoleucine revealed single-site enrichment at C-3 or at C-3' respective to the precursor [13C]pyruvate; i.e., C-3 was labeled from [2-13C]pyruvate and C-3' from [3-13C]pyruvate. Mass spectrometric analysis confirmed that all molecules were labeled only in one carbon. This site-specific incorporation of [13C]pyruvate is contrasted with the labeling pattern obtained when producing cells were supplied with [2-13C]acetate, instead of pyruvate, when most label was incorporated into carbons 3 and 3' of the same isoleucine molecule.

Enzyme-Linked Immunosorbent Assay for Specific Identification and Enumeration of Azospirillum brasilense Cd. in Cereal Roots.

The enzyme-linked immunosorbent assay is suggested as a reliable, sensitive, and highly specific method for the identification and enumeration of Azospirillum brasilense Cd. As few as 10 CFU/ml can be practically identified by this method. At higher bacterial numbers, sensitivity increased linearly up to 5 x 10 CFU/ml, yielding useful standard curves. No cross-reaction was found either with different closely related Azospirillum strains or with other rhizosphere bacteria. The method allows for a specific identification of A. brasilense Cd. both in pure cultures and in mixtures with other bacterial species, even when the colony morphology is variable. The method was successfully applied to assess the degree of root colonization on various cereals by A. brasilense Cd.

Microbial preparation of L-[15N]tyrosine and [15N]tyramine and their gas chromatographic-mass spectrometric analyses.

The preparation of L-[15N]tyrosine and [15N]tyramine by microbial synthesis is described. Immobilized Erwinia herbicola cells were added to a reaction mixture containing phenol, pyruvic acid, and 15NH4Cl. The reaction was driven by excess nonlabeled pyruvate and phenol. Under these denaturing concentrations of phenol, immobilized cells were more effective than free ones. Gram quantities of L-[15N]tyrosine were obtained without label dilution. The conversion of this L-[15N]tyrosine into [15N]tyramine by Streptococcus faecalis was performed at maximal efficiency. Gas chromatographic-mass spectrometric studies and 1H and 15N NMR analyses of the labeled compounds are reported.

Natural-abundance 13C nuclear magnetic resonance studies of regulation and overproduction of L-lysine by Brevibacterium flavum.

Natural-abundance 13C NMR spectroscopy has been used to study the metabolism of the L-lysine-producing bacterium, Brevibacterium flavum. Relationships of biomass formation, precursor uptake, and product excretion, as a function of culture medium, oxygen supply and specific cell membrane permeability, were rapidly determined using 67.89-MHz 13C NMR. The induction of lysine production throughout the growth cycle was studied. Intracellular and extracellular levels of free metabolites and unconsumed precursor were quantitatively measured as a function of growth culture conditions. Limited availability of oxygen resulted in accumulation and excretion of unfavorable products: lactate, succinate, alanine and valine. However, under optimal aeration conditions L-lysine was the sole metabolite detected extracellularly. Various important long-lived intermediates and storage compounds were detected in the intact cells (by NMR measurements). Carbon resonances of carbohydrates and amino acids were resolved and easily identified. Of particular interest are those of trehalose carbons, a storage carbohydrate. Natural-abundance 13C NMR spectroscopy seems most suitable for biotechnological processes where high concentrations of intermediates and end-products can be observed. We anticipate that this approach will be employed to screen overproducing bacterial strains.

In vivo 15N NMR studies of regulation of nitrogen assimilation and amino acid production by Brevibacterium lactofermentum.

Glutamic acid producer Brevibacterium lactofermentum intact cells were used to demonstrate the feasibility of in vivo 15N NMR to follow nitrogen assimilation and amino acid production throughout the growth cycle. The induction of glutamic acid production by different growth conditions was studied. Intracellular and extracellular levels of free metabolites were estimated as function of oxygen supply and biotin concentration. 15N NMR enabled us to distinguish two phases during the fermentation. At the early stage of fermentation, glutamic acid was accumulated intracellularly independent of oxygen supply and no product was excreted. In the late growth phase, the permeability of the cells developed and L-glutamic acid was excreted. The effect of aeration and biotin concentration on cellular contents and excretion was also studied by 15N NMR. Glutamate, N-acetylglutamine, and glutamine were the main nitrogenous pools independent of cell culture conditions. Free ammonia was not accumulated intracellularly although glutamic acid fermentation can be characterized as the process of nitrogen assimilation and the uptake of ammonia is the key step. In conclusion, the application of in vivo 15N NMR spectroscopy unraveled various problems of nitrogen metabolism, in a rapid and nondestructive manner.

Microbial production of L-[15N]glutamic acid and its gas chromatography-mass spectrometry analysis.

L-[15N]Glutamic acid was prepared in high yields via a fermentative process. Brevibacterium lactofermentum, growing on a medium containing 97% enriched 15NH4Cl as a sole isotopic precursor, excreted mostly L-[15N]glutamic acid. The L-[15N]glutamic acid was purified and identified. Gas chromatography-mass spectrometry analysis was performed to demonstrate its usefulness in clinical studies.