Fluidity difference of membrane lipids in human normal and leukemic lymphocytes as controlled by serum components.

Lymphocytes isolated from the peripheral blood of patients with chronic lymphatic leukemia and from normal healthy donors were analyzed for fluidity of membrane lipids. The degree of lipid fluidity in normal and leukemic lymphocytes was quantitatively monitored by a method based on fluorescence polarization analysis of a fluorescent probe that is embedded in lipid regions of cellular membrances. The present studies were performed on lymphocytes isolated from 26 blood samples from 16 patients with chronic lymphatic leukemia and 36 blood samples from 36 normal health donors. A signifcant increase in the degree of fluidity of membrane lipids was found in lymphocytes isolated from leukemic patients as compared to that found for lymphocytes isolated from healthy donors. In vitro incubation of leukemic lymphocytes in normal serum resulted in a decrease in the fluidity of cellular membranes, whereas incubation of normal lymphocytes in leukemic serum resulted in an increase in the fluidity of membrane lipids. These observations suggest that normal and leukemic lymphocytes can be quantitatively characterized by monitoring degree of fluidity of cellular membrane lipids and that the fluidity difference between normal and leukemic lymphocytes is controlled by components in the blood serum.

Enzymic activity at interfaces. II. Enzymic activity of microsomal nuclease and bovine pancreatic ribonuclease at the air/water interface.

The adsorption isotherms and the spreading tendency of microsomal nuclease (nucleate 3'-oligonucleotidohydrolase, EC 3.1.4.7) and bovine pancreatic ribonuclease (ribonucleate 3'-pyrimidino-oligonucleotidohydrolase, EC 3.1.4.22) in the presence of isopropyl alcohol as spreading agent have been determined using enzymes radioactively labelled by acetylation. In parallel, the concentration-surface pressure relations have been established. The enzymic activity of microsomal nuclease spread from isopropyl alcohol containing aqueous solutions was only a few percent of its activity in bulk, while the activity of the adsorbed enzyme was only slightly reduced. Adsorbed monolayers of RNAase were almost inactivated, while the spread monolayers in the presence of isopropyl alcohol became reactivated after exposure to the substrate for several hours. The exposure time for the reactivation decreases with increasing surface concentration.

Dynamics and composition of serum lipids in hyperlipoproteinemias.

The microviscosity of serum lipids in patients with hyperlipoproteinemia and normal donors was determined by monitoring the degree of fluorescence polarization of the fluorescent probe 1,6-diphenyl-1,3,5-hexatrine (DPH). Determination of serum lipids--serum total cholesterol, serum triglycerides, and serum phospholipids--revealed that an increase in the ratio of cholesterol/triglyceride + phospholipid is accompanied by an increase in the degree of fluorescence polarization and an increase in the microviscosity values. Similar results were obtained with sonicated liposomes prepared from serum lipids extracts. This correlation between dynamics and composition of serum lipids was further supported by results obtained with an artificial model system of sonicated lipids dispersions. The results have shown that high microviscosity values are characteristic in patients with high levels of serum cholesterol, and that low microviscosity values are characteristic in patients with high levels of serum triglycerides. It is suggested therefore that this technique may serve as a basis for a rapid screening test for hyperlipoproteinemias.

The structure and biosynthesis of new tetrahydropyrimidine derivatives in actinomycin D producer Streptomyces parvulus. Use of 13C- and 15N-labeled L-glutamate and 13C and 15N NMR spectroscopy.

Two novel compounds, 2-methyl, 4-carboxy, 5-hydroxy-3,4,5,6-tetrahydropyrimidine (THP(A] and 2-methyl, 4-carboxy-3,4,5,6-tetrahydropyrimidine (THP(B] have been identified in the pool of Streptomyces parvulus by in vivo and in vitro studies. 13C and 15N were introduced into the compounds by feeding S. parvulus with 15N- and 13C-labeled L-glutamate. High resolution 13C and 15N NMR have been applied to elucidate their structure and biosynthesis in S. parvulus. The splitting patterns and coupling constants of adjacent nitrogen-carbon molecular fragments enable us to unravel their molecular structure. Two different glutamate pools are responsible for their biosynthesis, THP(A) carbon skeleton derives from the extracellular L-[13C]glutamate, whereas THP(B) stems from D-fructose via the intracellular glutamate. During cell growth, THP(A) is synthesized and becomes the major constituent of the intracellular pool. It is consumed after THP(B) is accumulated intracellularly. The onset of THP(A) and -(B) synthesis seems correlated to the time of actinomycin D synthesis. Their high cellular concentrations during actinomycin D synthesis suggest that they may function as nitrogen storage. Other possible functions of THP molecules within the cell are discussed.

Metabolic regulation in Streptomyces parvulus during actinomycin D synthesis, studied with 13C- and 15N-labeled precursors by 13C and 15N nuclear magnetic resonance spectroscopy and by gas chromatography-mass spectrometry.

Recent studies have suggested that the onset of synthesis of actinomycin D in Streptomyces parvulus is due to a release from L-glutamate catabolic repression. In the present investigation we showed that S. parvulus has the capacity to maintain high levels of intracellular glutamate during the synthesis of actinomycin D. The results seem contradictory, since actinomycin D synthesis cannot start before a release from L-glutamate catabolic repression, but a relatively high intracellular pool of glutamate is needed for the synthesis of actinomycin D. Utilizing different labeled precursors, D-[U-13C]fructose and 13C- and 15N-labeled L-glutamate, and nuclear magnetic resonance techniques, we showed that carbon atoms of an intracellular glutamate pool of S. parvulus were not derived biosynthetically from the culture medium glutamate source but rather from D-fructose catabolism. A new intracellular pyrimidine derivative whose nitrogen and carbon skeletons were derived from exogenous L-glutamate was obtained as the main glutamate metabolite. Another new pyrimidine derivative that had a significantly reduced intracellular mobility and that was derived from D-fructose catabolism was identified in the cell extracts of S. parvulus during actinomycin D synthesis. These pyrimidine derivatives may serve as a nitrogen store for actinomycin D synthesis. In the present study, the N-trimethyl group of a choline derivative was observed by 13C nuclear magnetic resonance spectroscopy in growing S. parvulus cells. The choline group, as well as the N-methyl groups of sarcosine, N-methyl-valine, and the methyl groups of an actinomycin D chromophore, arose from D-fructose catabolism. The 13C enrichments found in the peptide moieties of actinomycin D were in accordance with a mechanism of actinomycin D synthesis from L-glutamate and D-fructose.

13C-NMR, 1H-NMR and gas-chromatography mass-spectrometry studies of the biosynthesis of 13C-enriched L-lysine by Brevibacterium flavum.

The basic metabolic pathways of lysine biosynthesis in Brevibacterium flavum, a strain which excretes excessive amounts of L-lysine, have been followed by using two 13C-labeled precursors. 13C- and 1H-NMR spectroscopies in conjunction with gas chromatography mass spectrometry (GC-MS) have revealed the various metabolic pathways leading to L-[13C]lysine. Discrete metabolic pathways give rise to distinct labeling patterns. L-Lysine resulting from [1-13C]glucose fermentation is relatively specifically labeled: L-[3,5-13C]lysine is the main product. Experimental and theoretical approaches based on the 13C-enrichment values of intracellular glutamate, a major intermediate metabolite, allowed us to assess the relative contribution of the major metabolic pathways forming lysine. The labeling pattern of glutamate reflects the isotope distribution in 2-oxoglutarate. When [2-13C]acetate is used as the sole carbon source in the culture, the energy-producing steps of the Krebs cycle are essential. The higher activity of the Krebs cycle, when endogenous carbohydrates are exhausted from the culture, is indicated by the increased 13C enrichment in C-1 of lysine and reveal a high content of isotopomers of four, five and six 13C atoms in the lysine molecule, pointing out that the four-carbon intermediates of the cycle are being derived from the glyoxylate shunt pathway. Such a phenomenon does not occur in glucose fermentation. GC-MS analyses of 13C enrichments and isotopomer distributions in metabolites and end products are in good agreement with the predicted contribution of each metabolic pathway. This new methodological approach of combined NMR and GC-MS has been demonstrated to be applicable to various other metabolic studies.

13C nuclear magnetic resonance and gas chromatography-mass spectrometry studies of carbon metabolism in the actinomycin D producer Streptomyces parvulus by use of 13C-labeled precursors.

Fructose and glutamate metabolism was monitored in cell suspensions of streptomyces parvulus by 13C nuclear magnetic resonance. The experiments were performed for cells grown with various 13C sources in a growth medium containing D-[U-13C]fructose, L-[13C]glutamate, or L-[U-13C]aspartate and with nonlabeled precursors to compare intracellular pools in S. parvulus cells at different periods of the cell life cycle. The transport of fructose into the cells was biphasic in nature; during rapid transport, mannitol, fructose, and glucose 6-phosphate were accumulated intracellularly, whereas during the passive diffusion of fructose, the intracellular carbohydrate pool comprised mainly trehalose (1,1'-alpha-alpha-D-glucose). The regulation of fructokinase activity by the intracellular intermediates may play an important role in fructose catabolism in S. parvulus. Transaldolase activity in S. parvulus was determined from the 13C nuclear magnetic resonance labeling pattern of trehalose carbons obtained from cells grown in medium containing either L-[U-13C]aspartate or L-[U-13C]glutamate. Only carbons 4, 5, and 6 of the disaccharide were labeled. Isotopomer analysis of the trehalose carbons led us to conclude that the flux through the reverse glycolytic pathway, condensation of glyceraldehyde 3-phosphate with dihydroxyacetone phosphate, makes at best a minor contribution to the 13C-labeled glucose units observed in trehalose. The pentose pathway and transaldolase activity can explain the labeling pattern of 4,5,6-13C3 of trehalose. Moreover, the transfer of the 13C label of L-[U-13C]aspartate into the different isotopomers of trehalose C4, C5, and C6 by the transaldolase activity allowed us to calculate the relative fluxes from oxaloacetate via gluconeogenesis and through the tricarboxylic acid cycle. The ratio of the two fluxes is approximately 1. However, the main carbon source for trehalose synthesis in S. parvulus is fructose and not glutamate or aspartate. The 13C enrichment and isotopomer population, measured by nuclear magnetic resonance and gas chromatography-mass spectrometry, of the actinomycin D peptide ring enabled us to specify the origins of the five amino acids of actinomycin D. Threonine and proline exhibited isotopomer populations similar to that of the extracellular L-[13C]glutamate, indicating that protein catabolism is the origin of their 13C label, whereas the isotopomer populations of sarcosine and N-methylvaline were similar to those of the new intracellular pool of S. parvulus that originated from D-[U-13C]fructose during the production of actinomycin D.

The conformation of new tetrahydropyrimidine derivatives in solution and in the crystal.

We have recently identified by NMR techniques two new tetrahydropyrimidine derivatives, 2-methyl-4-carboxy-5-hydroxy-3,4,5,6-tetrahydropyrimidine [THP(A)] and 2-methyl-4-carboxy-3,4,5,6-tetrahydropyrimidine [THP(B)], which accumulated in actinomycin D producing Streptomyces parvulus. Their relatively high intracellular concentrations during actinomycin D synthesis and identity of the time of onset of their synthesis with that of actinomycin D synthesis leads us to suggest that they may function in the self-defense mechanism of actinomycin-producing organisms. Here we present a combination of one-dimensional and two-dimensional 1H- and 13C-NMR studies in solution and X-ray crystallography of THP(A) and THP(B). Our results demonstrate identical conformations of THP(A) and of THP(B) in H2O solution and in the crystal. THP(A) and THP(B) form zwitterionic molecules with the half-chair conformation. Both techniques, NMR and X-ray crystallography, indicate that the carboxyl group of THP(B) is in an axial position and that the carboxyl and the hydroxyl groups of THP(A) are also in axial positions. The coplanar zigzag configurations (H4 C4 C5 C6 H6) of THP(A) and THP(B), deduced from NMR coupling measurements, were confirmed by X-ray diffraction studies. The crystal structure of THP(B) indicates that the hydrogen atoms of the methyl group are disordered, exhibiting two distinct conformations, whereas the methyl group hydrogens of THP(A) exhibit only one conformation. This finding is in accordance with the dynamic properties of THP(A) and THP(B) derived from carbon spin-lattice relaxation rate measurements. In spite of a different crystal packing and considerable differences in the dynamic properties (T1) in solution, the two molecules exhibit an almost identical conformation. The similar conformation of the two different crystals can be considered as evidence for a relatively high internal stability of the molecule against intermolecular forces.

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.