Partitioning of 14C-Photosynthate of Leaves in Roots,Rhizome, and in Essential Oil and Curcumin in Turmeric (Curcuma longa L.)

Incorporation of photosynthetically fixed ¹⁴C was studied at different time intervals of 12, 24, and 36 h in various plant parts—leaf 1 to 4 from apex, roots, and rhizome—into primary metabolites—sugars, amino acids, and organic acids, and secondary metabolites—essential oil and curcumin—in turmeric. The youngest leaves were most active in fixing ¹⁴C at 24 h. Fixation capacity into primary metabolites decreased with leaf position and time. The primary metabolite levels in leaves were maximal in sugars and organic acids and lowest in amino acids. Roots as well as rhizome received maximum photoassimilate from leaves at 24 h; this declined with time. The maximum metabolite concentrations in the roots and rhizome were high in sugars and organic acids and least in amino acids. ¹⁴C incorporation into oil in leaf and into curcumin in rhizome was maximal at 24 h and declined with time. These studies highlight importance of time-dependent translocation of ¹⁴C-primary metabolites from leaves to roots and rhizome and their subsequent biosynthesis into secondary metabolite, curcumin, in rhizome. This might be one of factors regulating the secondary metabolite accumulation and rhizome development.     

Gas chromatographic—mass fragmentographic determination of homopantothenic acid in plasma

A gas chromatographic—mass fragmentographic method was developed for the determination of homopantothenic acid in plasma. Acidified plasma was deproteinized by extraction with chloroform and subsequently the aqueous layer was extracted with ethyl acetate. The organic layer containing homopantothenic acid was reduced to dryness, and the resulting residue was redissolved in N,O-bis(trimethylsilyl)trifluoroacetamide—pyridine solution to allow trimethylsilylation. Aliquots of this solution were injected into the gas chromatograph—mass spectrometer and analyzed by the selected ion monitoring method using l-ascorbic acid as an internal standard. The detection limit for homopantothenic acid was 5 ng/ml of plasma.A precise and sensitive assay for the determination of homopantothenic acid in plasma was established.     

Gas chromatographic—mass spectrometric screening procedure for the identification of formaldehyde-derived tetrahydroisoquinolines in human urine

A gas chromatographic—mass spectrometric method has been developed for the identification of 1,2,3,4-tetrahydroisoquinoline and six metabolites extracted from urine in the picogram range. The derivatization procedure for the substances, formed by reaction of formaldehyde with biogenic amines, employs propionic anhydride and can take place in aqueous medium. In this way artificial formation of these compounds via condensation of biogenic amines with aldehydes or α-keto acids during the work-up procedure is eliminated. The procedure results in hydrophobic compounds, which are quantitatively extractable by liquid—liquid extraction with organic solvents. Further clean-up was performed by solid-phase extraction on C₁₈ sample preparation columns.     

The use of formic acid in carrier gas : Rapid method for identification and determination of phytanic acid by gas chromatography—mass spectrometry—chemical ionization

A rapid gas chromatographic method to determine phytanic acid in plasma from Refsum's disease is described. After a brief alkaline hydrolysis of lipids, the biological sample is directly injected into a glass pre-column; an acid carrier gas (formic acid in nitrogen) is used to displace the long-chain fatty acids from their sodium salts and from their binding to proteins. Formic acid introduced through the column may also be used as a reagent gas for chemical ionization in combined gas chromatography—mass spectrometry; fatty acids (C₁ to C_16:2 and phytanic acid) are easily identified by their M + 1 (base peak) and M − 17 peaks. The described procedure is also suitable for studying normal fatty acids from plasma lipids.     

Role of Steroids and Amino Acids in Pollen Germination of Eichhornia crassipes Solms.

Detection of amino acids from the pollen grains of Eichhornia crassipes together with isolation of β-sitosterol, stigmasterol and free sugars from the pistil were carried out. The role of the growth potential of the pollen and the growth-influencing compounds of the pistil are discussed. Amino acids and free sugars were detected in pollen and in pistils by paper chromatography. The neutral fractions of the alcohol extract (95%) of the pistil on column chromatography [petroleum ether: benzene (2:1)] gave a crystalline compound (m.p. 136-139°C) with positive Liebermann-Burchard test for sterol. A mass spectrum of the compound showed a mixture of β-sitosterol and stigmasterol, which was confirmed by comparative thin-layer chromatography and gas-layer chromatography.     

Selective photodestruction of α-amino acids

A problem typically encountered in the analysis of amino acids in chemical evolution experiments and in extracts of meteorites is the large number present. For example, α-, β-, and γ-amino acids, N-mono substituted α-amino acids, and dicarboxylic α-amino acids have been found in extracts of the Murchison meteorite, and many more amino acids are present than have been positively identified by computerized gas chromatographic mass spectrometry. This paper reports an analytical method to selectively destroy the α-amino acids, with only the β- and γ-amino acids remaining in the solution. It is based on the ability of Cu²⁺ to complex with amino acids, the order of stability of these complexes being α > β > γ, = δ, = ε = 0. Aqueous solutions of α-amino acid-Cu²⁺ chelates are known to be decomposed by 254 nm light as well as by nonmonochromatic uv light, yielding a precipitate of Cu₂O. This paper shows that at 254 nm (ligand-metal charge transfer band) the rate of destruction of amino acids in Cu²⁺ aqueous solutions is in the following order, dicarboxylic α-amino acids > α-amino acids > N-monosubstituted α-amino acids β-amino acids ≈ γ-amino acids. Thus by irradiation with 254 nm light in the presence of Cu²⁺ all the amino acids can be destroyed except the β- and γ-amino acids. When almost 100% of the α-amino acids are destroyed, 80% of the β- and γ-amino acids still exist in solution. With this procedure, complex mixtures of amino acids can be simplified to make identification by gas chromatographic mass spectrometry casier.     

Determination of very-long-chain fatty acids in plasma by a simplified gas chromatographic—mass spectrometric procedure

The concentration of very-long-chain fatty acids (VLCFA) (straight chain, more than 22 carbon atoms) in plasma or in cultured fibroblasts is one of the most important diagnostic criteria for the diagnosis of the peroxisomal disorders. A sensitive method for VLCFA assay in plasma, using small sample volume and a simplified procedure, is described. After adequate extraction and derivatization, methyl esters of VLCFA are separated, identificated and quantified by gas chromatography—mass spectrometry (GC—MS). The method is sensitive, reproducible, accurate and relatively simple. GC—MS equipment used for routine organic acid analysis can be used.     

Histochemical procedures for the simultaneous visualization of neutral sugars and either sialic acid and its side chain O-acyl variants or O-sulphate ester. I. Methods based upon the selective periodate oxidation of sialic acids

Summary Five new methods, based upon the selective oxidation of sialic acid residues with 0.4mm periodic acid in approximately 1m hydrochloric acid at 4°C for 1 h (PA^*), have been devised for the simultaneous visualization of neutral sugars and either sialic acid and its side chainO-acyl variants orO-sulphate ester. In the first of these, the selective periodate oxidation—borohydride reduction—saponification—selective periodate oxidation—Thionin Schiff—saponification—borohydride reduction—periodic acid—Schiff (PA^*—Bh—KOH—PA^*—T—KOH—Bh—PAS) technique, sialic acids withO-acyl substituents at C7, C8 or C9 (or which have two of three side chainO-acyl substituents) stain blue while neutral sugars with periodate-sensitivevicinal diols (hexose, 6-deoxyhexose, andN-acetylhexosamine) stain magenta. The second method, the saponification—selective periodate oxidation—Thionin Schiff—saponification—borohydride reduction—periodic acid—Schiff (KOH—PA^*—T—KOH—Bh—PAS), stains all sialic acids blue and neutral sugars magenta. In the third procedure, the selective periodate oxidation—Thionin Schiff—borohydride reduction—periodic acid—Schiff—saponification (PA^*—T—Bh—PAS—KOH) method, sialic acids without side chain substituents (or which have anO-acyl substituent at C7) stain blue and neutral sugars stain magenta. In the fourth method, the saponification-selective periodate oxidation—borohydride reduction—Alcian Blue pH 1.0—periodic acid—Schiff (KOH—PA^*—Bh—AB1.0—PAS) technique,O-sulphate esters stain aquamarine blue and neutral sugars stain magenta. In all of these techniques mixtures of the components stain in various shades of purple. Performance of the KOH—PA^*—Bh—AB1.0—PAS technique without the Alcian Blue pH 1.0 step provides a method for the selective identification of neutral sugars in macromolecules that also contain sialic acids.     

A microliter method for the gas chromatographic determination of long-chain non-esterified fatty acids in human serum or plasma

Non-esterified fatty acids (NEFA) from C₁₂ to C₂₄ are assayed in human serum or plasma in a four-step procedure: extraction, volume reduction, methylation and gas chromatography. NEFA are extracted with chloroform—heptane—methanol from 50–100 μl of serum or plasma buffered with phosphate. After adding ethyl acetate the volume of the extract is reduced under partial reflux to 5–7 μl. Potassium carbonate, methyl iodide and a crown ether are added to the dry concentrate and the NEFA are selectively methylated with a yield of 100% by heating in a microrefluxer for 10 min. Gas chromatography is carried out with 1 μl of the reaction mixture on a packed column by temperature-programmed operation. Thirteen individual fatty acids are determined in sera of normal adults. The coefficients of variation for 24 determinations of a pooled serum were 2.7% for the total NEFA content and 3–10% for most of the individual NEFA.     

Gas—liquid chromatography of isobutyl ester,N(O)-heptafluorobutyrate derivatives of amino acids on a glass capillary column for quantitative separation in clinical biology

A gas chromatographic method adapted to routine analysis has been developed for quantitative separation on glass capillary columns for free proteic and other known amino acids normally or abnormally found in physiological fluids. The procedure involves ion-exchange chromatography and isobutyl ester, N(O)-heptafluorobutyrate derivatization of free plasma and urine amino acid samples. Derivatized components were ascertained by combined gas chromatography—mass spectrometry. The use of glass for the capillary column is mandatory to achieve qualitative and quantitative analysis of the known occurring amino acids in urine and small plasma samples. Quantitative analysis of several types of human amino acid disorders are presented.     

Influence of arbuscular mycorrhiza on organic solutes in maize leaves under salt stress

A pot experiment was conducted to examine the effect of the arbuscular mycorrhizal (AM) fungus, Glomus mosseae, on plant biomass and organic solute accumulation in maize leaves. Maize plants were grown in sand and soil mixture with three NaCl levels (0, 0.5, and 1.0 g kg⁻¹ dry substrate) for 55 days, after 15 days of establishment under non-saline conditions. At all salinity levels, mycorrhizal plants had higher biomass and higher accumulation of organic solutes in leaves, which were dominated by soluble sugars, reducing sugars, soluble protein, and organic acids in both mycorrhizal and non-mycorrhizal plants. The relative abundance of free amino acids and proline in total organic solutes was lower in mycorrhizal than in non-mycorrhizal plants, while that of reducing sugars was higher. In addition, the AM symbiosis raised the concentrations of soluble sugars, reducing sugars, soluble protein, total organic acids, oxalic acid, fumaric acid, acetic acid, malic acid, and citric acid and decreased the concentrations of total free amino acids, proline, formic acid, and succinic acid in maize leaves. In mycorrhizal plants, the dominant organic acid was oxalic acid, while in non-mycorrhizal plants, the dominant organic acid was succinic acid. All the results presented here indicate that the accumulation of organic solutes in leaves is a specific physiological response of maize plants to the AM symbiosis, which could mitigate the negative impact of soil salinity on plant productivity.     

A two-step extraction procedure for concentrating acidic organic volatiles in aqueos solution prior to gas chromatographic head-space analysis,as exemplified by short-chain fatty acids produced by Bacillus cereus

A concentration procedure for short-chain fatty acids in aqueos solution is described, utilizing extraction by diethyl ether followed by re-extraction of fatty acid salts from the ether phase into a small amount of aqueous NaOH. The samples were acidified and analyzed by automatic head-space gas chromatography using a fused silica capillary column. The method's usefulness for trace analysis of short-chain fatty acids was exemplified in a study on broth cultures of Bacillus cereus where acetic, isobutyric and isovaleric acids could be readily detected after only 12 h of incubation.     

ANTIBIOTIC SUBSTANCES FROM A STRAIN OF BACILLUS SUBTILIS

SUMMARY: Strain B₇ of B. subtilis , isolated from soil collected from the gardens of the Bose Institute, Calcutta, was found to elaborate at least four different antibiotic substances. Fraction I was a brick red amorphous powder with certain resemblances to the bacillomycin group of antibiotics, soluble in alcohols, pyridine, etc., but insoluble in ether, water and acids. It had an ultraviolet absorption maximum at 276 mμ, melted with decomposition at 311°, and was a polypeptide positive to ninhydrin. On hydrolysis 12 amino acids were found. Fraction II was a white amorphous powder soluble in alcohols and ether but insoluble in water and petroleum ether. It melted at 158–162° and was a ninhydrin positive polypeptide composed of 7 amino acids. Fraction III was a yellow amorphous powder soluble in water and acetone, less soluble in ether and practically insoluble in chloroform. It was not a polypeptide. Fraction IV was a yellowish white amorphous powder with solubility characteristics similar to those of fractions I and II. It was a polypeptide composed of 10 amino acids.     

Quantification of dimethindene in plasma by gas chromatography—mass fragmentography using ammonia chemical ionization

A gas chromatographic—mass fragmentographic method using ammonia chemical ionization for the determination of dimethindene in human plasma is described. The drug was isolated from plasma by liquid—liquid extraction with hexane—2-methylbutanol. Plasma components were separated on a capillary column coated with chemically bonded methyl silicone. For detection of dimethindene, its quasi-molecular ion (M + H⁺) was mass fragmentographically monitored after chemical ionization with ammonia as reagent gas. Dimethindene was quantified using methaqualone as the internal standard: the quantification limit in plasma was 0.2 ng/ml, the within-run precision was 8.0% and the inter-run precision 5.6%. The plasma concentration—time profile was established after a single dose of 4 mg of dimethindene with an average maximum concentration of 5.5 ng/ml, detectable up to 48 h post application.     

Quantitative gas—liquid chromatography of neutral sugars in human serum glycoproteins : Fucose, mannose, and galactose as predictors in ovarian and small cell lung carcinoma

A precise and accurate gas—liquid chromatographic (GLC) method has been developed for the quantitative analysis of the neutral sugars -fucose (6-deoxygalactose), mannose, galactose, and glucose in ethanol precipitates of human serum proteins. The chromatographic conditions and sample preparation resulted in short analysis times (20 min per run) and made routine analyses practicable (twelve samples per day). The alditol acetate derivatization yielded single derivatives for each sugar. Complete separation was achieved on a 2.0 m × 2 mm I.D. column with 2.0% Silar-7 CP on Chromosorb W AW 80–100 mesh. The results of hydrolysis showed that the release of fucose and galactose preceded the release of mannose. Hydrolysis with AG 50W-X8 (H⁺) ion-exchange resin in 0.5 N HCI at 100° for 7 h optimized glycosidic bond cleavage with only minimal destruction of fucose, mannose and galactose. A combination of strong cation- and anion-exchange resin columns was used to remove chromatographic background of peptides, amino acids, amino sugars, and inorganic ions. An average R.S.D. of less than 4% with recovery of <86% for the three sugars was achieved. The homogeneity of the chromatographic peaks for the neutral sugars of normal human serum glycoproteins was confirmed by GLC—mass spectrometry. Significantly elevated ratios of fucose, galactose, and mannose to serum protein were observed for patients with small cell lung and ovarian carcinomas.     

Isolation of plasma membranes from Ehrlich ascites tumor cells Influence of amino acids on (Na + K)-ATPase and K-stimulated phosphatase

A method was developed for isolating plasma membranes from Ehrlich ascites tumor cells. The plasma membranes appeared as highly irregular shrunken sacs or ghosts. Enzymatic characterization of the plasma membranes showed them to be high in (Na⁺ + K⁺-ATPase activity and K⁺-stimulated phosphatase activity. A detailed study showed that both of these latter enzymic functions were stimulated by various amino acids. Such stimulation occurred in the 1–15 mM range of amino acids and was most effective for aromatic species, e.g. phenylalanine and histidine. The amino acid stimulation, which appeared to show little or no stereospecificity, was eliminated by a one carbon separation of NH₂ and COOH groups. Since the metal chelating agent EDTA was also effective in mimicking the stimulation by amino acids, and since a mild washing procedure did not render membranes insensitive to subsequent amino acid or EDTA stimulation, it is proposed that the operation of the (Na⁺ + K⁺)-ATPase (and K⁺-stimulated phosphatase) is to some extent controlled by a tightly bound metal. The possible physiological function of an amino acid-regulated transport ATPase is discussed.     

Determination of plasma fatty acid composition in neonates by gas chromatography

Total fatty acids in plasma of neonates have been analysed as their methyl esters by gas chromatography. They were separated on a capillary column coated with a SP-2380 stationary phase. As little as 100 μl of plasma is used for the analysis. The extraction procedure was performed with dichloromethane—methanol (2:1) and fatty acids were methylated with boron trifluoride—methanol. The quantification of fatty acids is based on an internal standard method. Absolute values (μg fatty acid per 100 μl plasma) are given together with relative values (%). At a signal-to-noise ratio of 3, the detection limits for flame ionisation detection are between 0.08 to 0.51 ng. The high sensitivity and precision permits the effective determination of the fatty acids in neonate plasma.     

Histochemical procedures for the simultaneous visualization of neutral sugars and either sialic acid and its O-acyl variants or O-sulphate ester. II. Methods based upon the periodic acid-phenylhydrazine-Schiff reaction

Summary Four methods based upon the periodic acid—phenylhydrazine—Schiff reaction have been developed for the simultaneous visualization of neutral sugars with periodate oxidizablevicinal diols (hexose, 6-deoxyhexose,N-acetylhexosamine) and either sialic acids or side chainO-acyl sialic acids. In the first of these procedures, the saponification—periodic acid oxidation—2,4-dinitrophenylhydrazine—Azure A—Schiff—saponification (KOH—PA—DNPH—Az—KOH) method, all sialic acids stain Azure blue, neutral sugars with oxidizablevicinal diols stain yellow and mixtures of such components stain in various shades of green. In the second technique, periodic acid oxidation—2,4-dinitrophenylhydrazine—Azure A Schiff—saponification (PA—DNPH—Az—KOH), Azure Blue staining is confined to sialic acids without side chain substituents or which have anO-acyl substituent at position C7, while in the third method, the selective periodate oxidation—borohydride reduction—saponification—periodic acid oxidation—2,4-dinitrophenyl hydrazine—Azure A—Schiff—saponification (PA^*—Bh—KOH—PA—DNPH—Az—KOH) technique, only sialic acids withO-acyl substituents at positions C7, C8 or C9 (or which have two or threeO-acyl side chain substituents) stain Azure blue. Finally in the fourth procedure, periodic acid oxidation—2,4-dinitrophenylhydrazine—Azure A—Schiff—saponification—borohydride reduction—periodic acid oxidation—Schiff (PA—DNPH—Az—KOH—Bh—PAS), sialic acids without side chain substituents or which haveO-acyl substituents at C7 stain Azure blue, sialic acids substituted at position C8 or C9 (or which are di- or tri-substituted) stain magenta and neutral sugars stain yellow. Where mixtures of these components are present, a wide range of colours is obtained.     

Mass spectrometric analysis of N-carboxymethylamino acids as periodate oxidation derivatives of Amadori compounds application to glycosylated haemoglobin

Summary Periodate oxidation of free and protein-bound Amadori compounds formed by the condensation of reducing sugars with primary amino groups generates, on acid hydrolysis, N-carboxymethyl derivatives of amino acids. The analysis of these modified amino acids may be used to estimate both the extent and the site of protein glycosylation. The present study describes the use of gas chromatography-mass spectrometry (GC/MS) and gas chromatographytandem mass spectrometry (GC/MS/MS) for the identification of the various N-carboxymethylamino acids. Application of this approach to the quantitation of N-carboxymethylvaline and N -carboxymethyllysine resulting from the oxidation of glycosylated haemoglobin is presented.     

The radioracemization of amino acids by ionizing radiation: Geochemical and cosmochemical implications

A number of optically active amino acids, both in the solid state and as sodium or hydrochloride salts in aqueous solution, have been exposed to ionizing radiation from a 3000 Ci⁶⁰Co -ray source to see if radioracemization might accompany their well-known radiolysis. -Ray doses causing 55–68% radiolysis of solid amino acids typically engendered 2–5% racemization, while aqueous solutions of the sodium salts of amino acids which underwent 53–66% radiolysis showed 5–11% racemization. Amino acid hydrochloride salts in aqueous solution, on the other hand, showed little or no radioracemization accompanying their radiolysis. Both radiolysis, and radioracemization were roughly proportional to -ray dose in the range studied (1–36×10⁶ rads). Mechanisms for the radioracemization of amino acids in the solid state and as aqueous sodium salts are discussed, and the absence of radioracemization for aqueous hydrochloride salts is rationalized. Isovaline, a non-protein amino acid which has been isolated from the Murchison meteorite, contains no -hydrogen atom and is therefore incapable of racemizationvia the chemical mechanisms by which ordinary amino acids racemize. Nevertheless, isovaline suffers radioracemization in the solid state to an extent comparable to that shown by ordinary amino acids, as do its sodium and hydrochloride salts in the solid state. The sodium salt of isovaline in aqueous solution, however, fails to racemize during its radiolysis. Several implicaitons of the newly described phenomenon of radiomization are pointed out for the fields of geochemistry and cosmochemistry.A portion of this research has been described previously at the 144th National Meeting of the American Association for the Advancement of Science, Washington D.C., Feb. 12–17, 1978, at the Fourth College Park Colloquium on Chemical Evolution, University of Maryland, College Park, Maryland, Oct. 18–20, 1978, and at the Carnegie Institution of Washington Conference: Advances in the Biogeochemistry of Amino Acids, Airlie House, Warrenton, Virginia, Oct. 29—Nov. 1, 1978.