Crassulacean Acid Metabolism and Crassulacean Acid Metabolism Modifications in Peperomia camptotricha

Peperomia camptotricha, a tropical epiphyte from Mexico, shows variable forms of Crassulacean acid metabolism (CAM). Young leaves exhibit CAM-cycling, while mature leaves show an intermediate type of metabolism, between CAM and CAM-cycling, having approximately the same amount of nighttime gas exchange as daytime. Metabolism of young leaves appears independent of daylength, but mature leaves have a tendency toward more CAM-like metabolism under short days (8 hours). Large differences in the physical appearance of plants were found between those grown under short daylengths and those grown under long daylengths (14 hours). Some anatomical differences were also detected in the leaves. Water stress caused a switch to CAM in young and mature leaves, and as water stress increased, they shifted to CAM-idling.     

Anaerobic Amino Acid Metabolism

Anoxic stress induces a strong change in sugar, protein, and amino acid metabolism in higher plants. Sugars are rapidly consumed through the anaerobic glycolysis to sustain energy production. Protein degradation under anoxia is a mechanism to release free amino acids contributing in this way to maintaining the osmotic potential of the tissue under stress. Among free amino acids, a particular role is played by glutamic acid, being a precursor of some characteristic compounds of the anaerobic metabolism (alanine, -aminobutyric acid, and putrescine). The glutamine synthetase/glutamate synthase cycle contributes to ammonia reassimilation and primary assimilation of nitrate, and resynthesizes constantly glutamate for the synthesis of other compounds. Some polypeptides involved in these pathways are expressed under anoxia. The importance of amino acid metabolism for the response to anaerobic stress is discussed.     

The Metabolism of Abscisic Acid

The light-catalysed isomerization of (+)-abscisic acid (ABA)to its trans isomer during isolation from leaves was monitoredby the addition of (±)-[2-¹⁴C]ABA to the extraction medium.(+)Trans-abscisic acid (t-ABA) was found to occur naturallyin rose (Rosa arvensis) leaves at 20µg/kg fresh weight;(+)-ABA was present at 594µg/kg. (±)-[2-¹⁴D]Trans-abscisicacid was not isomerized enzymically to ABA in tomato shoots. (±)-Abscisic acid was converted by tomato shoots to awater-soluble neutral product, ‘Metabolite B’, whichwas identified as abscisyl-ß-D-glucopyranoside. When(±)-[2-¹⁴C]trans-abscisic acid in an equimolar mixturewith (±)-[2-¹⁴C}ABA was fed to tomato shoots it was convertedto its glucose ester 10 times faster than was ABA. Trans-abscisyl-ß-D-glucopyrano8ide only was formedfrom (±)-[2-¹⁴C]t-ABA in experiments lasting up to 30h. Glucosyl abscisate was formed slowly from ABA and the freeacid fraction contained an excess of the unnatural (–).ABAas did the ABA released from abscisyl-ß-D-glucopyranosideby alkaline hydrolysis. The (+).ABA appeared to be the solesource of the acidic ‘Metabolite C" previously noted. The concentrations of endogenous (+)-, (+)-[2-¹⁴C]-, and (–)-[2-¹⁴C]ABAremaining as free acid, and also in the hydrolysate of abscisyl-ß-D-glucopyranoside,were measured by the ORD, UV absorption, and scintillation spectrometryof highly purified extracts of ABA from tomato shoots whichhad been supplied with racemic [2-^l4C]ABA.     

Bacterial Metabolism of Mevalonic Acid

Soluble cell-free extracts of actinomycete S4 grown on media containing mevalonate catalyze acetoacetate formation from mevalonate, mevaldate, and β-hydroxy-β-methylglutaryl-coenzyme A (CoA). Conversion of mevalonate to acetoacetate involves formation of free β-hydroxy-β-methylglutaryl-CoA, but not free mevaldate. The reaction favors mevalonate oxidation, and nicotinamide adenine dinucleotide, rather than nicotinamide adenine dinucleotide phosphate, acts as oxidant.     

Fungal Metabolism of Sorbic Acid

The metabolism of sorbic acid (S A) by 11 species of Mucor and 14 other fungi in addition to Mucor sp. A–73 were studied. All species of Mucor metabolized SA to trans-4-hexenol (4–HEL) without exception. The metabolic pathway was investigated precisely by using the resting cells of Mucor sp. A–73. The reduction of SA to 4–HEL by the fungus demanded glucose. The reduction of SA to sorbic alcohol (SAL) was catalyzed by the inducible enzymic system and that of SAL to 4–HEL by the constitutive enzyme. In the phosphate buffer, a part of 4–HEL produced from SA was further transformed into mono-trans-4-hexenyl phosphate by Mucor sp. A–73.

The reductive action of the fungus upon several trans-2-alkenoic acids was also examined.     

Metabolism of Indole-3-acetic Acid: IV. Biological Properties of Amino Acid Conjugates

The biological activity of 20 l-alpha-amino acid conjugates of indole-3-acetic acid (IAA) to stimulate cell elongation of Avena sativa coleoptile sections and to stimulate growth of soybean cotyledon tissue cultures has been examined at concentrations of 10(-4) to 10(-7)m. In the Avena coleoptile test, most of the amino acid conjugates stimulated elongation. Several of the conjugates stimulated as much elongation as IAA but their half-maximum concentrations tended to be higher. Some of the more active conjugates were alanine, glycine, lysine, serine, aspartic acid, cystine, cysteine, methionine, and glutamic acid.In the soybean cotyledon tissue culture test, all of the l-alpha-amino acid conjugates of IAA stimulated growth except for the phenylalanine, histidine, and arginine conjugates. Most of the conjugates produced responses at least as great as that caused by IAA. Conjugates with half-maximum concentrations lower than IAA included cysteine, cystine, methionine, and alanine. These conjugates exceed the IAA-induced callus growth at all tested concentrations. Other conjugates significantly better than IAA at 10(-6)m were serine, glycine, leucine, proline, and threonine.     

Fatty Acid Metabolism in Microorganisms

The production of pimelic acid from azelaic acid by microorganisms was studied. About 100 strains of bacteria which were able to utilize azelaic acid as a sole carbon source were isolated from soil and other natural materials. Among these bacteria, several strains produced a large quantity of an organic acid (pimelic acid) from azelaic acid in their culture fluids during the cultivation. The acid was isolated from the culture fluid of strain A133 in crystalline form. The crystal was identified as pimelic acid by physicochemical and biological methods.

From the results of investigations on the morphological and physiological characters, the bacterial strain A133 was assumed to be Micrococcus sp.     

Amino Acid Metabolism in Microorganisms

Certain strains of Streptomyces were found to convert l-methionine into 3-methylthio-propylamine (MTPA), but not d-methionine. Now, optical resolution of DL-methionine was attempted using this phenomenon. Streptomyces sp. K37 was cultured in a medium containing DL-methionine (10 mg/ml). The culture filtrate was applied to a column of Diaion SA-21A (OH form). MTPA was recovered from the effluent by ether exraction. The Diaion SA-21A was eluted with 1N HCl and the eluate was applied to a column of Diaion SK-1 (H form). d-Methionine was eluted from the column with 1N NH₄OH and recovered after concentration, decolorization with active carbon, and precipitation with ethanol. The yields of MTPA and d-methionine from the broth were 69.5% and 89.5%, respectively.     

Fatty Acid Metabolism in Microorganisms

During the investigation on the metabolism of azelaic acid by Micrococcus sp., it was found that the bacterium produced a large amount of keto acid (α-ketoglutaric acid) under the restricted condition for nitrogen source. The acid was identified as α-ketoglutaric acid by physico-chemical and biological methods. The mechanism of the production of α-ketoglutaric acid from azelaic acid was investigated. From the result, it was suggested that α-ketoglutaric acid production proceeded thrpugh the further oxidation of acetic acid produced from azelaic acid and that the production might be functioned by TCA cycle enzymes of the bacterium. Similarly, α-ketoglutaric acid was found to be produced remarkably from other various fatty acids.     

Amino Acid Metabolism in Microorganisms

3-Methylthiopropylamine (MTPA) formation from l-methionine in Streptomyces sp. K37 was studied in detail. The reaction was confirmed to be catalyzed by the decarboxylase of l-methionine. The properties of the enzyme were studied in detail using acetone dried cells or cell-free extract. The enzyme was specific for l-methionine. Pyridoxal phosphate stimulated the reaction and protected the enzyme against heat inactivation. The optimum pH for the reaction was 6.0~8.0 and the optimum temperature was about 40°C. Carbonyl reagents (10^?2~10^?3 m) inhibited the reaction completely, and silver nitrate and mercuric chloride (10^?3~10^?4 m) markedly inhibited the reaction. Km value for the reaction was 1.21 × 10^?5 m. l-Methionine assay using the decarboxylase was attempted and was found to be applicable to practical use.     

Amino Acid Metabolism in Microorganisms

Certain Streptomyces strains were found to accumulate an unknown substance in culture broth when the microorganisms were grown in the medium containing dl-methionine. The substance was isolated from the culture broth as hydrochloride and was identified as 3-methylthiopropylamine (MTPA), decarboxylated product of methionine, from its melting point, chemical composition, infrared spectrum, and other properties. Cultural conditions for MTPA formation in Streptomyces sp. K 37 were investigated. The yield of MTPA from l-methionine reached about 90% with a culture medium containing corn steep liquor. Namely, 6.47 mg of MTPA per millilitre of culture broth was produced from 10 mg of l-methionine per millilitre of the growth medium. The transforming activity was found in the cells of the early culture period. MTPA-producing activity was induced by l- methionine in the medium. d-Methionine was not utilized as a substrate of the reaction with intact cells. Optimum pH for the reaction appeared to be 6.0~8.0.     

{gamma}-Amiobutyric Acid Metabolism in Plants: Part 1. Metabolism in Yeasts

The metabolism of -aminobutyric acid (AB) by two yeasts, Saccharomycescerevisiae and Torulopsis utilis, was investigated. Both yeastsgrew well upon AB as a sole source of nitrogen (N), and thelag phase for Torulopsis was shorter than when provided the N-source. The metabolism of AB by Torulopsis, whichwas associated with an increased O₂ uptake, was adaptive incharacter. The enzyme whose formation was induced by the supplyof AB was a transaminase, which was apparently specific forAB as the amino donor. Small amounts of transaminase were presentin unadapted, -grown cells. The optimum pH, equilibrium constant, Michaelis' constant, and coenzyme requirementwere investigated for the transamination reaction involving-ketoglutaric acid (KG) as amino group acceptor. Succinic semi-aldehyde(SSA) was a product of this transamination reaction.The possibility;that some AB was converted into SSA by a direct oxidative deaminationremained unconfirmed. The further conversion of SSA into succinic acid was establishedusing intact. cells for both yeasts. This oxidation processwas shown to be linked to the reduction of pyridine nucleotidesvising extracts of Saccharomyces as a source of SSA dehydrogenase.Dehydrogenase activity could be ascribed to two separate enzymes,one linked to DPN, and the other utilizing TPN and requiringMg⁺⁺ as an activator. The properties of the former enzyme, whichwas more important quantitatively, were investigated and comparedwith those described in the literature for an aldehyde dehydrogenaseof baker's yeast and for SSA dehydro-genases of Pseudomonas.Torulopsis extracts could catalyse the reduction of SSA to -hydroxybutyricacid (OHB); the OHB dehydrogenase involved required TPNH asa coenzyme. Certain other properties of this enzyme are recorded. The possibility is discussed that AB and SSA act as intermediatesin a metabolic pathway that may form a by-pass of the KG-succinatestage of the tricarboxylic acid cycle.