Dégradation d'acides aminés à l'interface eau-sédiment réconstitué d'une lagune méditerranéenne (Golfe du Lion)

Degradation of Amino Acids at a Simulated Water-sediment Interface of a Mediterranean Lagoon Environment, Golfe du Lion The degradation of two ¹⁴C and ³H labelled amino acids at the simulated water-sediment interface of a Mediterranean lagoon was studied. The four day experiments included the respiratory activity measurement and the study of incorporation processes of the radioactivity in specific organic fractions of the ¹⁴C arginine. After active mineralization occurred during the first day, the radioactivity in the acid-soluble fraction decreased and polycondensed products were progressively incorporated. The radioactivity of the ³H lysine was included mainly in the acid soluble fraction. The nature of the substrate, and the reducing conditions in the environment affect the radioactivity distribution in the organic fractions. The identification of amino acids in the acid-soluble and base soluble fractions shows that the labelled arginine and lysine and other amino acids in the acid soluble and base soluble fractions shows that the labelled arginine and lysine released from the initial compounds are important quantitatively.     

Studies on the uptake of (14C) amino acids derived from both dietary (14C) protein and dietary (14C) amino acids by rainbow trout, Salmo gairdneri Richardson

Previous studies have shown that rainbow trout fed on diets containing whole protein have superior growth rates compared to fish fed on diets of similar amino acid composition but containing a high proportion of free amino acids. The influence of several nutritional factors on the uptake of radioactivity from food pellets containing either [U-^I4C] protein or [U-¹⁴C] amino acids into the systemic blood of trout has been investigated. The time taken for radioactivity in the free amino acid fraction of blood to reach a peak after a meal containing [U-¹⁴C] protein had been given was much shorter, and the level of radioactivity in the blood higher, in trout with almost empty stomachs than in fish with almost full stomachs; uptake of radioactivity into blood amino acids was also more rapid and reached much higher concentrations when pellets containing [U-¹⁴C] amino acids were fed than when [U-¹⁴C] protein was fed. Incorporation of radioactivity into blood protein continued for a much longer period and reached higher levels when a pellet containing [U-¹⁴C] protein was fed than when a pellet containing [U-¹⁴C] amino acids was fed. Previous dietary history (low or high protein intake) did not appear to affect the rate of absorption of amino acids from either protein or free amino acid pellets. The uptake rates from pellets containing free amino acids could be slowed by mixing the dietary amino acids with albumin. The distribution, postabsorption, of radioactivity in the different fractions of blood and liver suggested that incorporation of carbon residues into glycogen and lipid from an amino acid diet was greater than from a protein diet. The converse was true of incorporation of radioactivity into tissue protein.     

THE INCORPORATION OF RADIOACTIVE AMINO ACIDS INTO BRAIN SUBCELLULAR PROTEINS DURING TRAINING

—Total proteins, free amino acids, tritiated water and subcellular proteins of mouse brain were examined for changes in radioactivity during operant conditioning after subcutaneous administration of labelled amino acids. The conditioning was based on appetitive learning, using sweetened milk as a reward. During training and incorporation for 20-30 min, both [³H]leucine and [1-¹⁴C]leucine underwent a significant increase in catabolism, resulting in a decreased radioactivity in the free amino acids. [2-²H]Methionine underwent a rapid loss of isotope, so that 90% of the radioactivity was in the form of tritiated water at the end of training, and this phenomenon masked any possible effect of training. The brain uptake of [³⁵S]methionine increased during the training, resulting in an increased radioactivity in the proteins. Uptake of [³H]lysine increased slightly during training only after 1 h incorporation and not after 20 or 30 min, as judged from a time course of radioactivity in the free amino acids. Incorporation into nuclear proteins increased selectively during 20 min, and into nuclear and cytosol proteins after 60 min incorporations. It is concluded that changes in the observed rate of incorporation of a precursor into brain subcellular proteins under the influence of behaviour might be the result of changes in precursor catabolism or uptake, or both, and that each amino acid behaves in a different way. Even the same amino acid gives different results depending on the isotope and its position in the amino acid.     

Studies on the release of exogenous and endogenous GABA and glutamate from rat brain synaptosomes

The aim of the present study was to determine whether exogenous radioactive GABA and glutamate previously taken up by rat brain synaptosomes are released preferentially with respect to the endogenous unlabeled amino acids. Preferential release was monitored by comparing the specific radioactivity of the amino acids released to that present in synaptosomes at the beginning and at the end of the release period. The GABA released spontaneously or by depolarizing the synaptosomes with high K⁺ in the presence of Ca²⁺ had the same specific radio-activity as that present in synaptosomes before or after superfusion. Depolarization with veratridine or superfusion with OH-GABA caused a moderate increase (15–20%) in the specific radioactivity of the GABA released and a corresponding slight decrease in that of superfused synaptosomes. In conditions causing a supraadditive release of exogenous and endogenous GABA (see ref. 13), the specific radioactivity of the GABA released was increased 20–30%. The GABA with higher-than-average specific radioactivity is probably representative of the cytoplasmic pool of this amino acid. The glutamate released spontaneously had a specific radioactivity lower than that present in synaptosomes at the start of superfusion, and also the specific radioactivity in superfused synaptosomes was lower than at the start of superfusion. The glutamate released by aspartate (by heteroexchange), by veratridine, or by high K⁺ had a specific radioactivity higher than that of the amino acid released spontaneously, similar to that present in synaptosomes at the start of superfusion, and higher than that found in superfused synaptosomes. These findings suggest that exogenous radioactive glutamate is released preferentially with respect to the endogenous amino acid and to the glutamate synthesized from glucose during the superfusion period.     

Transport and Partitioning of CO(2) Fixed by Root Nodules of Ureide and Amide Producing Legumes

Nodulated and denodulated roots of adzuki bean (Vigna angularis), soybean (Glycine max), and alfalfa (Medicago sativa) were exposed to ¹⁴CO₂ to investigate the contribution of nodule CO₂ fixation to assimilation and transport of fixed nitrogen. The distribution of radioactivity in xylem sap and partitioning of carbon fixed by nodules to the whole plant were measured. Radioactivity in the xylem sap of nodulated soybean and adzuki bean was located primarily (70 to 87%) in the acid fraction while the basic (amino acid) fraction contained 10 to 22%. In contrast, radioactivity in the xylem sap of nodulated alfalfa was primarily in amino acids with about 20% in organic acids. Total ureide concentration was 8.1, 4.7, and 0.0 micromoles per milliliter xylem sap for soybean, adzuki bean, and alfalfa, respectively. While the major nitrogen transport products in soybeans and adzuki beans are ureides, this class of metabolites contained less than 20% of the total radioactivity. When nodules of plants were removed, radioactivity in xylem sap decreased by 90% or more. Pulse-chase experiments indicated that CO₂ fixed by nodules was rapidly transported to shoots and incorporated into acid stable constituents. The data are consistent with a role for nodule CO₂ fixation providing carbon for the assimilation and transport of fixed nitrogen in amide-based legumes. In contrast, CO₂ fixation by nodules of ureide transporting legumes appears to contribute little to assimilation and transport of fixed nitrogen.     

METABOLIC SEGREGATION OF INTRACELLULAR FREE AMINO ACIDS IN PLATYMONAS (CHLOROPHYTA)1

¹⁴C-amino acids were supplied to Platymonas subcordiformis (Wille) Hazen and the incorporation of radioactivity into protein and other compounds was followed. Alanine was rapidly metabolized by both N-limited and N-sufficient cells. Arginine and lysine were metabolized rapidly by N-limited cells, but were sequestered from metabolism in N-sufficient cells. This suggests the existence of two functionally distinct pools; a “metabolic” pool that is rapidly metabolized and preferentially used for incorporation into protein, and a “storage” pool rich in basic amino acids that is sequestered from metabolism.     

EFFECTS OF ENVIRONMENTAL FACTORS ON PHOTOSYNTHESIS PATTERNS IN PHAEODACTYLUM TRICORNUTUM (BACILLARIOPHYCEAE). I. EFFECT OF NITROGEN DEFICIENCY AND LIGHT INTENSITY1

Cultures of the marine diatom Phaeodactylum tricornutum Bohlin incorporated, a large proportion of the total fixed carbon (50% or more) into amino acids and amides during short periods of photo-assimilation of ¹⁴C-labelled carbon dioxide. Although increasing nitrogen limitation in a nitrate-limited chemostat had little significant effect on the proportion of C incorporated into amino acids and amides combined, it did affect the distribution of radioactivity within individual compounds of this group. In particular, increasing degrees of N deficiency reduced the proportion incorporated into amides to almost undetectable levels, reduced the proportion in alanine and increased the proportion in glutamic acid. Also, increasing N limitation decreased the relative synthesis of sugar phosphates and increased the proportion of C assimilated into intermediates of the tricarboxylic acid cycle. Reduced light intensity did not have any significant effect on the proportion of C incorporated into the total amino acids and amides, but did cause a decrease in the radioactivity     

A method for the estimation of amino acid radioactivity in biological samples

A method for quantitative estimation of total radioactivity present in the free amino acid fraction of tissue samples has been described. Samples deproteinized with cold acetone were extracted, in acidic medium, with ethyl (peroxide free); after centrifugation, the aqueous phase was used for amino acid derivatization at 40°C for 15 h with 1-flouro-2,4-dinitrobenzene in bicarbonate-buffered medium. Aliquots of the derivatized samples were acidified and extracted twice again with ethyl ether. The combined organic phases were placed in glass scintilation vials, dried, and used for the determination of its radiactivity, corresponding to the radioactivity present in the free amino acid fraction of the sample. Deproteinized samples of rat blood plasma, as well as hen egg white and yolk were tested after addition of known quantities of ¹⁴C-labelled amino acids or glucose, for validation of the method. No glucose radioactivity was found in any of the extracted samples. All radioactivity added to the samples in the form of ¹⁴C-labelled alanine, glutamic acid, leucine and phenylalanine was quantitatively recovered in the derivatized fraction; only a fraction of arginine radioactivity was recovered.     

Photosynthetic assimilation of 14C into amino acids in potato (Solanum tuberosum) and asparagine in the tubers

Asparagine is the predominant free amino acid in potato tubers and the present study aimed to establish whether it is imported from the leaves or synthesised in situ. Free amino acid concentrations are important quality determinants for potato tubers because they react with reducing sugars at high temperatures in the Maillard reaction. This reaction produces melanoidin pigments and a host of aroma and flavour volatiles, but if free asparagine participates in the final stages, it results in the production of acrylamide, an undesirable contaminant. ¹⁴CO₂ was supplied to a leaf or leaves of potato plants (cv. Saturna) in the light and radioactivity incorporated into amino acids was determined in the leaves, stems, stolons and tubers. Radioactivity was found in free amino acids, including asparagine, in all tissues, but the amount incorporated in asparagine transported to the tubers and stolons was much less than that in glutamate, glutamine, serine and alanine. The study showed that free asparagine does not play an important role in the transport of nitrogen from leaf to tuber in potato, and that the high concentrations of free asparagine that accumulate in potato tubers arise from synthesis in situ. This indicates that genetic interventions to reduce free asparagine concentration in potato tubers will have to target asparagine metabolism in the tuber.     

Incorporation of 3H-Gibberellin A20 in roots of G2 peas

Following application of ³H-Gibberellin A₂₀ (GA₂₀) to roots of G2 pea seedlings and homogenization of the roots, about 3% of the radioactivity in the tissue could be precipitated from a 30,000 × g supernatant with trichloroacetic acid (TCA) (soluble fraction) while about 5% of the radioactivity pelleted at 30,000 × g (particulate fraction). The radioactivity in the particulate fraction was soluble in sodium dodecyl sulfate (SDS), but was not dialyzable and was insoluble in ethanol. Electrophoresis of the soluble fraction gave only one band of radioactivity, while that of the particulate fraction gave multiple bands. Acid hydrolysis of the soluble fraction released radioactivity that ran coincident with acid-treated GA₂₀ on silicic-acid column chromatography. The particulate fraction gave numerous radioactive peaks following acid hydrolysis, two of which were coincident with GA₂₀ and GA₂₉ (hydroxylation product of GA₂₀) on silicic acid chromatography. Treatment of the particulate and soluble fractions with RNase, DNase, and proteases showed a significant solubilization of radioactivity only with the proteases, suggesting that the GA is bound to a proteinaceous macromolecule. Complete proteolytic hydrolyis followed by thin layer chromatography showed 65% of the radioactivity from the soluble fraction running separately from free GAs or the individual amino acids; the particulate fraction gave mainly (60%) free GAs on enzymatic hydrolysis and much smaller amounts (17%) in a position separate from that of the GAs or amino acids. Binding of ³H-GA to protease-sensitive material was obtained with biologically active ³H-GA₂₀ and ³H-GA₁.     

Amino Acid Synthesis in Photosynthesizing Spinach Cells : EFFECTS OF AMMONIA ON POOL SIZES AND RATES OF LABELING FROM CO(2)

Isolated cells from leaves of Spinacia oleracea have been maintained in a state capable of high rates of photosynthetic CO₂ fixation for more than 60 hours. The incorporation of ¹⁴CO₂ under saturating CO₂ conditions into carbohydrates, carboxylic acids, and amino acids, and the effect of ammonia on this incorporation have been studied. Total incorporation, specific radioactivity, and pool size have been determined as a function of time for most of the protein amino acids and for γ-aminobutyric acid. The measurements of specific radio-activities and of the approaches to ¹⁴C “saturation” of some amino acids indicate the presence and relative sizes of metabolically active and passive pools of these amino acids.     

Long distance translocation of sucrose, serine, leucine, lysine, and carbon dioxide assimilates: I. Soybean

To determine the selectivity of movement of amino acids from source leaves to sink tissues in soybeans (Glycine max [L.] Merr. `Wells'), ¹⁴C-labeled serine, leucine, or lysine was applied to an abraded spot on a fully expanded trifoliolate leaflet, and an immature sink leaf three nodes above was monitored with a GM tube for arrival of radioactivity. Comparisons were made with ¹⁴C-sucrose and ¹⁴CO₂ assimilates. Radioactivity was detected in the sink leaf for all compounds applied to the source leaflet. A heat girdle at the source leaf petiole essentially blocked movement of applied compounds, suggesting phloem transport. Transport velocities were similar (ranged from 0.75 to 1.06 cm/min), but mass transfer rates for sucrose were much higher than those for amino acids. Hence, the quantity of amino acids entering the phloem was much smaller than that of sucrose. Extraction of source, path, and sink tissues at the conclusion of the experiments revealed that 80 to 90% of the radioactivity remained in the source leaflet. Serine was partially metabolized in the transport path, whereas lysine and leucine were not. Although serine is found in greater quantities than leucine and lysine in the source leaf and path of soybeans, applied leucine and lysine were transported at comparable velocities and in only slightly lower quantities than was applied serine. Thus, no selective barrier against entry of these amino acids into the phloem exists.     

INCORPORATION OF 14C FROM [U-14C]GLUCOSE INTO FREE AMINO ACIDS IN MOUSE BRAIN LOCI IN VIVO UNDER NORMAL CONDITIONS

By macroautoradiography and by GLC separation, differences in the uptake of radioactive carbon from [U-¹⁴C]glucose into free amino acids (glutamate + glutamine, aspartate + asparagine, GABA, alanine and glycine) in mouse cerebral neocortex, hippocampus, thalamus and hypothalamus were investigated. (1) The autoradiographical densities in the thalamus, cerebral neocortex and hippocampus measured with a microdensitometer were higher than that in the hypothalamus at 5 min after subcutaneous injection. At 180 min, densities in the cerebral neocortex, hippocampus and hypothalamus were higher than that in thalamus. (2) The free amino acid levels determined by GLC varied with each brain region. (3) The specific radioactivity (d.p.m./μmol) of alanine in each brain region was higher than that of the other amino acids at 5 min after the injection. The specific radioactivity of GABA in the brain regions was clearly higher than that of (glutamate + glutamine), (aspartate + asparagine) and glycine at 5 and 15 min. (4) The autoradiographical data were in good agreement with the chemical data at 5 min but were different at 180 min. (5) Variations in specific radioactivity of each free amino acid among brain regions at 5 min were influenced greatly by existing free amino acid concentrations in each region.     

Studies on the incorporation of ( 14 C)amino acids into protein by isolated rat brain nuclei

—Various parameters of the in vitro incorporation of [¹⁴C]amino acids into protein by cell nuclei isolated and purified from rat brain and liver were investigated. Nuclei purified through 2.2 m sucrose solution were capable of amino acid incorporation in vitro; and washing procedure to eliminate hypertonic sucrose before incubation was essential since sucrose in high concentration was inhibitory. Microbial contamination was found to be a serious source of error and the use of sterile conditions for incubation were necessary to obtain reproducible and valid results. Using completely sterile conditions, Na ⁺, K⁺, RNase, DNase, puromycin, cycloheximide and chloramphenicol were without any effect on the ability of brain and liver nuclei to incorporate labelled amino acids into protein. Results of time-course and preincubation experiments revealed that some factors essential for amino acid incorporation pass out of the nucleus into the medium. In addition, approximately 15 per cent of the labelled nuclear proteins with higher specific radioactivity was recovered in the incubation medium. Incorporation of [¹⁴C]leucine was proportional to the concentration of labelled amino acid and to the number of nuclei, and it is suggested that carefully controlled conditions of incubation are essential to obtain valid comparisons between different types of nuclei in terms of their relative abilities to incorporate amino acids in vitro. No evidence was obtained indicating isotope dilution phenomenon in these experiments. Whether or not in vitro incorporation of amino acid by nuclei represents protein synthesis is discussed.     

Metabolism of U14C leucine and U14C valine by adult female Glossina morsitans during pregnancy

After U¹⁴C leucine or U¹⁴C valine injections into haemolymph of adult female Glossina morsitans during late pregnancy, radioactivity was detected in the post-parturient female and its larval offspring in the injected material, lipids, and a range of non-essential amino acids. The level of radioactivity recorded from the third instar larva was higher than that remaining in the injected adult, and the activity was higher in amino acids than in the lipid fraction. Radiometric analysis of oöcyte and intra-uterine progeny 24 hr after haemocoelic administration to females of labelled leucine or valine revealed a pattern of radioactivity coincident with growth characteristics of these young stages. Rate of leucine uptake by the in utero third instar larva was slightly higher than that of valine, and this instar continues feeding even only a few hours before parturition. For both labelled materials, expired carbon dioxide and excreta from remales in early pregnancy showed significantly higher radioactivity than those in late pregnancy. Uric acid is the main nigrogenous waste of leucine and valine metabolism, though small amounts of these amino acids are also lost during excretion, with valine elimination being higher than leucine.     

Thein vitro activity of the microsomal fraction isolated from the spleen and the lymph nodes after immunization of the donor

The microsomal fraction from the spleen (after perfusion) of immunized rabbits incubated for 20 min at 37° C under usual conditions in the presence of energy sources incorporates¹⁴C-labelled amino acids both into the solubilized (by adding deoxycholate), and into the nonsolubilized part (15%). The cell supernatant incorporates under these conditions the¹⁴C-labelled amino acids into total proteins in the absence of microsomes but in a lower degree. The cell supernatant contains gamma globulin detectable by immunoelectrophoresis. Gamma globulin obtained by specific precipitation of the solubilized microsomal fraction with antigamma-globulin serum had an measurable radioactivity. The precipitate of gamma globulin obtained from the supernatant of the incubation medium in the same manner (after removing the microsomes) had a specific activity twice as high. On separating the microsomal fraction extract and the incubation medium supernatant on DEAE cellulose most fractions show on extinction maximum at 260 nm in the first case and at 280 nm in the second case. The microsomal fraction isolated from the spleen and lymph nodes of immunized pigs-48 and 72 h after revaccination, when incubatedin vitro, incorporated¹⁴C-labelled amino acids into total protein. After ultrasonic disintegration in 0.14m NaCl and filtration through a Sephadex G 25 column it is specifically precipitated with the antigammaglobulin serum. Gamma globulin isolated after incubation of the microsomal fraction had a measurable radioactivity. AntiHSA antibodies determined by adsorption on immunosorbent did not possess significant radioactivity. Only the concentrated supernatant of the incubation medium showed minute radioactivity of 75–94 counts/min /ml. The problem of investigating the formation of nascent specific antibodies on a subcellular levelin vitro during the early period of secondary response to the antigen is discussed, in particular the problem of their detection. An erratum to this article is available at .     

Galactolipid Synthesis in Vicia faba Leaves: IV. Site(s) of Fatty Acid Incorporation into the Major Glycerolipids

The fatty acids of the major glycerolipids of Vicia faba leaves were analyzed immediately following ¹⁴CO₂ feeding. The leaves were fractionated into chloroplast and cytoplasmic fractions and the location of radioactivity in the fatty acids determined. The results indicate that the major site of incorporation of fatty acids is in the phospholipids. Phosphatidylcholine contained the highest level of radioactivity in the cytoplasmic fraction, whereas phosphatidylglycerol contained radioactivity in both the chloroplast and cytoplasmic fractions. The galactolipids contained very little radioactivity in comparison, this radioactivity being confined to high speed centrifugal fractions believed to contain the envelopes of the chloroplast. Our results suggest that phosphatidylcholine is a major site of incorporation of fatty acids (mainly in oleic acid) in the cytoplasm, whereas phosphatidylglycerol is also a site of incorporation involving both oleic and palmitic acids, inside and outside the chloroplast.     

Biochemical changes in mouse liver after palmitoyl-ethanolamide (PEA) administration

PEA (palmitoylethanolamide; N-(2-hydroxyethyl)palmitamide) daily and orally administered to male mice caused: (1) increased incorporation of labelled orotic acid into DNA and RNA, (2) an increase in the activity of uridine kinase and decrease of tryptophan pyrrolase, (3) decreased ribonuclease activity of isolated liver ribosomes, (4) raising of specific radioactivity after injection of labelled amino acids in both mitochondrial and microsomal fractions of liver homogenate, (5) increased incorporation of [¹⁴C]-palmitic acid and ³²P into liver phospholipids.     

Incorporation of [14C]glucosamine into synaptosomes in vitro

Abstract— Synaptosomes isolated from rat cerebral cortex by zonal centrifugation in-corporated radioactive glucosamine into macromolecules in vitro as glucosamine, galactosamine, N-acetylneuraminic acid, and glucuronic acid. The largest percentage of incorporated radioactivity was recovered in the particulate fraction in which radioactive carbohydrates were bound in covalent linkage requiring acid hydrolysis or enzymatic digestion for release. Less than 20 per cent of the particulate radioactivity represented incorporation into gangliosides. Some 20 per cent of the radioactivity was incorporated into proteins as glucosamine, identified in hydrolysates by paper chromatography and by the amino acid analyser. After incubation, radioactivity was demonstrable in the proteins as sialic acid by paper chromatography and specific enzymic digestion; and as glucuronic acid by chromatography, electrophoresis, and digestion with hyaluronidase. Incorporation of carbohydrate was stimulated by sodium and potassium at concentrations demonstrated to enhance incorporation of amino acids, and involved the macro-molecules of all subsynaptosomal fractions. Significant incorporation of radioactivity was found in the synaptic plasma membrane. The synthesis of glycoproteins was suggested by simultaneous incorporation of [¹⁴C]glucosamine and [³H]leucine into glycopeptides subsequently hydrolysed and subjected to polyacrylamide gel electrophoresis and two-dimensional paper chromatography and electrophoresis. Such studies demonstrated that amino acids and carbohydrates may be incorporated into glycoproteins of the synaptic membrane and suggest the possibility of local synthesis as well as modification of material brought to the nerve ending by axoplasmic flow.     

Metabolism of C-labeled photosynthate and distribution of enzymes of glucose metabolism in soybean nodules

The metabolism of translocated photosynthate by soybean (Glycine max L. Merr.) nodules was investigated by ¹⁴CO₂-labeling studies and analysis of nodule enzymes. Plants were exposed to ¹⁴CO₂ for 30 minutes, followed by ¹²CO₂ for up to 5 hours. The largest amount of radioactivity in nodules was recovered in neutral sugars at all sampling times. The organic acid fraction of the cytosol was labeled rapidly. Although cyclitols and malonate were found in high concentrations in the nodules, they accumulated less than 10% of the radioactivity in the neutral and acidic fractions, respectively. Phosphate esters were found to contain very low levels of total label, which prohibited analysis of the radioactivity in individual compounds. The whole nodule-labeling patterns suggested the utilization of photosynthate for the generation of organic acids (principally malate) and amino acids (principally glutamate).

The radioactivity in bacteroids as a percentage of total nodule label increased slightly with time, while the percentage in the cytosol fraction declined. The labeling patterns for the cytosol were essentially the same as whole nodule-labeling patterns, and they suggest a degradation of carbohydrates for the production of organic acids and amino acids. When it was found that most of the radioactivity in bacteroids was in sugars, the enzymes of glucose metabolism were surveyed. Bacteroids from nodules formed by Rhizobium japonicum strain 110 or strain 138 lacked activity for phosphofructokinase and NADP-dependent 6-phosphogluconate dehydrogenase, key enzymes of glycolysis and the oxidative pentose-phosphate pathways. Enzymes of the glycolytic and pentose phosphate pathways were found in the cytosol fraction.

In three experiments, bacteroids contained about 10 to 30% of the total radioactivity in nodules 2 to 5 hours after pulse-labeling of plants, and 60 to 65% of the radioactivity in bacteroids was in the neutral sugar fraction at all sampling times. This strongly suggests some absorption and metabolism of sugars by bacteroids in spite of the lack of key enzymes. Bacteroids did possess enzymes for the formation of hexose phosphates from glucose or fructose. Radioactivity in α,α-trehalose in bacteroids increased until, after 5 hours, trehalose was a major labeled compound in bacteroids. Thus, trehalose synthesis may be a major fate of sugars entering bacteroids.