Enzymes of asparagine synthesis in maize roots

An asparagine synthetase which is active with either glutamine or NH ₄ ⁺ has been found in maize (Zea mays L.) roots. Unlike the enzyme obtained from legume cotyledons, the maize-root enzyme is only slightly more efficient with glutamine (Km, 1.0 mM) than with NH ₄ ⁺ (Km, 2.0–3.0 mM). The activity of this enzyme is higher in the mature root than in the root-tip region, i.e. root cells develop a capacity to make asparagine from glutamine or NH ₄ ⁺ as they mature. -Cyanoalanine synthetase is also present in maize roots. The apparent Km for cysteine is 2.6 mM and for cyanide is 0.57 mM. The enzyme is more active in the root tip than in mature root tissue. Thus, if asparagine were made in the root tip, the cyanide pathway could represent the mechanism of synthesis. It is our contention, however, that this potential is not realized under normal conditions because ¹⁴C-experiments performed previously have indicated a limited availability of both CN and cysteine in the maize root.     

The Role of β-Hydroxypropionate in Ethylene Biosynthesis

To search precursors of ethylene in banana fruits, ethylene formation from acetate-2-¹⁴C and fumarate-2,3-¹⁴C by banana slices was studied. Ethylene-¹⁴C formation from acetate-2-^l4C was reduced by the addition of malonate or β-hydroxypropionate, and it was enhanced in a sealed chamber in comparison with the case in an aeration chamber. No label of fumarate-2,3-¹⁴C was incorporated into ethylene.

From these facts it was suggested that acetate-2-¹⁴C was incorporated into ethylene via malonate and β-hydroxypropionate. Participation of fumarate in ethylene biosynthesis of banana fruits was ruled out. β-Hydroxypropionate was postulated as an effective precursor of ethylene formation from acetate-2-^l4C.     

Dehydroipomeamarone as an Intermediate in the Biosynthesis of Ipomeamarone, a Phytoalexin from Sweet Potato Root Infected with Ceratocystis fimbriata

Recently, we isolated dehydroipomeamarone, a new sesquiterpenoid from sweet potato (Ipomoea batatas Lam.) root tissue infected with Ceratocystis fimbriata (Ell. et Halst.). The purpose of this investigation was to determine whether dehydroipomeamarone was a precursor in the biosynthetic pathway of ipomeamarone. The incorporation of acetate-2-¹⁴C into ipomeamarone was markedly inhibited by the presence of dehydroipomeamarone. Radioactive dehydroipomeamarone was efficiently converted into ipomeamarone, and the compound was biosynthesized earlier than ipomeamarone according to a time course analysis of the production of the terpenoid. These results support the notion that dehydroipomeamarone is an immediate precursor of ipomeamarone. On the other hand, the production of ipomeamarone was slightly lessened in the presence of dehydroipomeamarone. Thus, the marked reduction of acetate-2-¹⁴C incorporation into ipomeamarone by dehydroipomeamarone may result from both isotopic dilution and an inhibitory effect by exogenous dehydroipomeamarone.     

Participation of Mevalonate in the Biosynthetic Pathway of Ipomeamarone

1. The incorporation of mevalonate-2-¹⁴C into ipomeamarone in sweet potato root tissue infected by Ceratocystis fimbriata was demonstrated, but the rate was low when compared with acetate-2-¹⁴C. No dilution effect of mevalonate was noted during the incorporation of acetate-2-¹⁴C into ipomeamarone. This is very likely to result from the passive transfer of mevalonate into the cells.

2. No dilution effect of acetate during the incorporation of mevalonate-2-¹⁴C into ipomeamarone was noted. This indicates that mevalonate is not incorporated into ipomeamarone after its conversion to acetate.

3. Evidence for incorporation of acetate-2-¹⁴C into mevalonate was shown by the fact that the specific radioactivity of mevalonic acid benzhydrylamide was not lowered throughout repetitive crystallizations. These data also support the participation of mevalonate in ipomeamarone synthesis as an intermediate.

     

The Biosynthesis of Sepedonin

The origin of each carbon of anhydrosepedonin produced by Sepedonium chrysospermum has been elucidated by carbon-14 tracer method. At first, the degradation pathways adequate to such object was studied. The radioactivity incorporated in sepedonin and anhydrosepedonin was considerably high when acetate-1-¹⁴C, acetate-2-¹⁴C and formate-¹⁴C were used as the precursor. The feature of the labeling pattern of anhydrosepedonin was analogous to those of the other fungal tropolones. The carbon atom derived from formate was almost exclusively situated at C-7 position of the tropolone ring. As a whole, the labeling pattern demonstrated that anhydrosepedonin might be synthesized through the poly-ketomethylene pathway.     

Effect of Ethrel and Ceratocystis fimbriata on the Synthesis of Fatty Acids and 6-Methoxy Mellein in Carrot Root

The rate of incorporation of ¹⁴C from acetate-1-¹⁴C into fatty acids by carrot root discs, 18 hours after inoculation with Ceratocystis fimbriata, was 9-fold greater than that in freshly cut discs. The rate in discs treated with water or Ethrel was 3-fold greater. The rate of incorporation of ¹⁴C from glucose-U-¹³C into fatty acids was 3-fold greater 18 hours after any of the above treatments. The rate of ¹⁴C incorporation from malonate-2-¹⁴C into fatty acids 24 hours after inoculation with C. fimbriata or treatment with water was 25 and 60%, respectively, of that in freshly cut discs. Linoleic acid was the principal fatty acid in carrot root, but incorporation of ¹⁴C from acetate-1-¹⁴C into the acid was low until 18 hours after inoculation with C. fimbriata or treatment with Ethrel. Turnover rates of the fatty acids appeared low and were similar for all treatments.     

Studies on Cassava, Manihot utilissima. II. Biosynthesis of Asparagine-14C from 14C-labelled Hydrogen Cyanide and its Relations with Cyanogenesis

Seeds and seedlings of Manihot utilissima were analysed for cyanogenic glycosides und free amino acids, with special reference to valine and isoleucine which serve as precursors of the aglycone moieties of linamarin and lotaustralin. Seeds contained traces of valine and isoleucine but no glycosides, whereas seedlings contained high concentrations of these amino acids and glycosides. Illumination of seedlings led to a steep increase in the concentration of glycosides followed by a decrease without excretion of detectable HCN. Seeds accumulated asparagine, while seedlings accumulated both asparagine and glutamine in the storage and transport of nitrogen. Seedlings incorporated 13.2 per cent of label from valine-¹⁴C(U) and 2.4 per cent of label from isoleucine-¹⁴C(U)into linamarin and lotaustralin, respectively. In both cases, appreciable amounts of label were also incorporated into asparagine. 49 per cent of label from H¹⁴CN was incorporated inio asparagine in which ca. 98 per cent of total radioactivity was located in the amide-carbon atom. The different patterns of labelling which occurred during the assimilation of H¹⁴CN and ¹⁴CO₂ showed that cyanide metabolism did not proceed via CO₂, and that M. utilissima contains an efficient enzyme-system which catalyses the conversion on high concentrations of HCN into asparagine, which subsequently enters different metabolic pools involved with respiration, protein and carbohydrate syntheses. Cyanogenesis in M. utilissima appears lo be directly influenced by available pools of valine and isoleucine, and the metabolism of HCN released from linamarin and lotaustralin by the action of linamarase may be directly related to respiratory and synthetic processes by way of the incorporation of HCN as a unit into asparagine.     

The Origin of Carbons of Dihydrofuran Ring and C-6 in the Biosynthesis of Rotenone

For the investigation of rotenone biosynthesis, acetate-2-¹⁴C, mevalonic acid-2-¹⁴C lactone and methionine-methyl-¹⁴C were administered to Derris elliptica plants, respectively, and the distribution of carbon-14 in the labeled rotenone was determined by degradation. When mevalonic acid-2-¹⁴C lactone was incorporated into rotenone, the radioactivity was found equally in the carbons at both C-7′ and C-8′, indicating that these carbons are derived from the carbon-2 of mevalonic lactone. In the case of methionine-methyl-¹⁴C about 80% of the total radioactivity was found to enter two methoxyl groups. This result demonstrates that methionine is an efficient precursor of the methoxyl group. Furthermore, it is also suggested that methionine may be a precursor of the carbon at C-6.     

Asparagine Biosynthesis by Cotton Roots: Carbon Dioxide Fixation and Cyanide Incorporation 1

Asparagine is the dominant amino acid in cotton root tips (Acala SJ-1). Two biosynthetic pathways may be operative. First, asparagine is an ultimate product of nonphotosynthetic CO(2) fixation. Whereas short term (14)CO(2) labeling experiments indicate that malate is the predominant product, asparagine appears exponentially and does not appear to be in an active metabolic pool. Other products labeled with (14)CO(2) are citrate, aspartate, and glutamate. No neutral components are labeled. Secondly, asparagine is synthesized via a pathway starting with cyanide. Major amino acid products labeled with (14)CN(-) are beta-cyanoalanine and asparagine. Similarly to CO(2) fixation, asparagine synthesized from cyanide is not in an active metabolic pool. Other products labeled include anion and neutral components. The exact nature of the latter is not known.     

FORMATION OF LIGNIN IN TISSUE CULTURE OF PINUS STROBUS

The formation of shikimic acid and lignin from glucose in thecambium tissue was investigated. Glucose-1-¹⁴C, shikimic acid-G-¹⁴C, sodium acetate-1-¹⁴C and sodium acetate-2-¹⁴C were administeredto the tissue culture of strob pine. Glucose was well incorporatedinto shikimic acid, but acetic acid was less effective. Shikimicacid was very efficient as a precursor of aromatic nucleus andglucose was also converted efficiently to lignin. The extentof incorporation of acetic acid, however, was considerably low.A possibility was discussed that in the cultured tissue ligninand its precursor were synthesized from glucose via the shikimicacid pathway. (Received May 14, 1960; )     

Biosynthesis of the 3-benzylchroman-4-one eucomin in Eucomis bicolor

Feeding experiments have demonstrated the specific incorporation of radioactivity from dl-phenylalanine-[1-¹⁴C], l-phenylalanine-[U-¹⁴C], sodium acetate-[2-¹⁴C] and l-methionine-[methyl-¹⁴C] into the 3-benzylchroman-4-one eucomin in Eucomis bicolor. The labelling patterns indicate that eucomin is biosynthesized by the addition of a carbon atom derived from methionine onto a C₁₅ chalcone-type skeleton. Radioactivity from 2′,4′,4-trihydroxy-6′-methoxychalcone-[methyl-¹⁴C] and 2′,4′-dihydroxy-4,6′-dimethoxychalcone-[6′-methyl-¹⁴C] was incorporated into eucomin, the latter compound being the better precursor, demonstrating the feasibility that 2′-methoxychalcones are biosynthetic precursors of the “homoisoflavonoids”. Possible biosynthetic relationships in this class of compounds are discussed.     

Biosynthesis of monoterpenes in plants from 14C-labelled acetate and CO2

Degradation of (+)-isothujone biosynthesized by Tanacetum vulgare or Thuja plicata from acetate-[1-¹⁴C], -[2-¹⁴C] and -[2-³H₃] or from CO₂-[14C] at physiological concentration revealed a pattern of asymmetric labelling whereby tracer predominantly (72–98% resided in that part of the skeleton derived from IPP. This is similar to the patterns previously obtained for uptake of MVA-[2-¹⁴C] but differed from those reported in other species with acetate-[¹⁴C] as precursor. Within the IPP-derived moiety the 3 parts derived from acetate units were not equivalently labelled. Partial degradations of geraniol and (+)-pulegone formed in Pelargonium graveolens and Mentha pulegium after uptake of ¹⁴C-labelled acetate or CO₂ showed that the C-2 units of the skeletons of these monoterpenes were also labelled to widely differing extents and these patterns persisted over a range of feeding and seasonal conditions. These results suggest that metabolic pools of acetyl-CoA and/or acetoacetyl-CoA exist in these plants. The general occurrence of such pools and the consequent nonequivalent labelling patterns in secondary metabolism could invalidate biosynthetic conclusions drawn from partial degradations of labelled natural products.     

Polyprenyl quinones and α-tocopherol in Calendula officinalis

In various cellular subfractions of Calendula officinalis leaves a study was made of the distribution of polyprenyl quinones and α-tocopherol and the dynamics of their labelling with ¹⁴CO₂ and acetate-[1-¹⁴C] and incorporation of mevalonate-[2-¹⁴C] after 3 hr. It was confirmed that plastoquinone occurs only in the chloroplasts, ubiquinone only in the mitochondria and α-tocopherol in both these subfractions. Phylloquinone was found in the chloroplast and mitochondrial fractions as well as in the post-mitochondrial supernatant. Studies of the dynamics of radioactive precursor incorporation indicated that α-tocopherol is metabolized more rapidly than the polyprenyl quinones studied; the incorporation of mevalonate-[2-¹⁴C] suggests that the side chain of plastoquinone can be synthesized in the cytoplasm and transported to the chloroplasts.     

The Biosynthesis of Some Isothiocyanates and Oxazolidinethiones in Rape (Brassica campestris L.)

The incorporation of the radioactivity from acetate-1-¹⁴C, acetate-2-¹⁴C, dl-methionine-1-¹⁴C, dl-methionine-2-¹⁴C, dl-methionine-3,4-¹⁴C, dl-homomethionine-2-¹⁴C, dl-allyl-glycine-2-¹⁴C, and dl-2-amino-5-hydroxyvalerate-2-¹⁴C into the aglycones of progoitrin, gluconapin, and glucobrassicanapin of maturing rape plants (Brassica campestris L.) was investigated. Radioactivity from dl-methionine-2-¹⁴C, dl-methionine-3,4-¹⁴C, dl-homomethionine-2-¹⁴C, and acetate-2-¹⁴C were incorporated into the 3 major thioglucosides. The other organic compounds were poorly incorporated except for dl-allylglycine-2-¹⁴C into glucobrassicanapin. The results obtained suggest that the rape plant can synthesize amino acids by the condensation of acetate (as acetyl CoA) to α-keto acids to yield a homologue of the original amino acid. These newly formed amino acids are then employed to synthesize the 3 major thioglucosides.     

Molecular interaction of acrylonitrile and potassium cyanide with rat blood

The interaction of acrylonitrile (VCN) with rat blood has been investigated at the molecular level in an attempt to understand the possible mechanism of its toxicity. The results obtained were compared to those with potassium cyanide (KCN), a compound known to liberate cyanide (CN^?) in biologic conditions. The radioactivity derived from K¹⁴CN was eliminated faster than that from [1-¹⁴C]VCN. Up to a maximum of 94% of ¹⁴C from VCN in erythrocytes was detected covalently bound to cytoplasmic and membrane proteins, whereas 90% of the radioactivity from KCN in erythrocytes was found in the heme fraction of hemoglobin. Determination of specific activity showed that binding occurred more in vivo than in vitro which indicated that the VCN molecule was bioactivated inside erythrocytes. These results indicate that KCN interacts mainly through CN^? liberation and binding to heme, whereas VCN, which binds to cytoplasmic and membrane proteins, may cause damage to red cells by mechanisms other than release of CN^?.     

Biosynthesis of lysine and other amino acids in the developing maize endosperm

Tracer studies with aspartic acid-[4-¹⁴C], alanine-[1-¹⁴C] acetate-[2-¹⁴C] and diaminopimelic acid-[1,(7)-¹⁴C] injected into the developing endosperm of maize revealed that the biosynthesis of lysine and other amino acids occurs in this organ. The data suggest that lysine is synthesized via the diaminopimelic acid pathway.     

Lipogenesis in Fatty Liver by Amino Acid Imbalance

Lipogenesis in the fatty liver of rat which was induced by feeding an amino acid-irnbalanced diet containing 8% casein supplemented with 0.3% dl-methionine has been investigated by measuring the incorporation of acetate-1-¹⁴C into various lipid fractions during in vitro incubation of liver slices.

In the incorporation of acetate-1-¹⁴C into the total lipid per one g of the slices, no significant difference for the imbalance group was observed. However, the total radioactivity of liver lipid per 100 g of the body and the incorporation into triglyceride in the lipids were significantly higher in the imbalance group than in the control group. Conversion of acetate-1-¹⁴C to CO₂ was not impaired in the imbalance group.

It is evident from these results that the induction of this type of fatty liver is due mainly to the synthesis of triglyceride.     

Nature of DNA and RNA Degradation in Escherichia coli Induced by Colicin E2

Lipogenesis in the fatty liver of rat, which was induced by feeding an amino acid unbalanced diet containing 8% casein supplemented with 0.3% dl-methionine, has been studied by measuring the incorporation of glycerol-1-¹⁴C, palmitate-1-¹⁴C, citrate-1,5-¹⁴C, pyruvate-1-¹⁴C and pyruvate-2-¹⁴C into various lipid fractions and ¹⁴CO₂ during in vitro incubation of liver slices.

The total radioactivity of liver lipid per 100 g of the body and the incorporation of each substrate into triglyceride in the lipid were significantly higher in the imbalance group than the control group. Conversion of each substrate to ¹⁴CO₂ was not imparied in the imbalance group.

It is evident from these results that the induction of this type of fatty liver is due mainly to the triglyceride synthesis by both the fatty acid synthesis and the transesterification of fatty acid.

These results are considered to support the previous assumption in which acetate-1-¹⁴C was used as a precursor.     

Lysine Biosynthesis in Barley (Hordeum vulgare L.)

Lysine biosynthesis in seedlings of barley (Hordeum vulgare L. var. Emir) was studied by direct injection of the following precursors into the endosperm of the seedlings: acetate-1-¹⁴C; acetate-2-¹⁴C; pyruvate-1-¹⁴C; pyruvate-2-¹⁴C; pyruvate-3-¹⁴C; alanine-1-¹⁴C; aspartic acid-1-¹⁴C; aspartic acid-2-¹⁴C; aspartic acid-3-¹⁴C; aspartic acid-4-¹⁴C; α-aminoadipic acid-1-¹⁴C; and α, ε-diaminopimelic acid-1-(7)-¹⁴C. The distribution of activity in the individual carbon atoms of lysine in the different biosynthetic experiments was determined by chemical degradation. The incorporation percentages and labeling patterns obtained are in agreement with the occurrence of the diaminopimelic acid pathway. The results do not fit the incorporation percentages and labeling patterns expected if the α-aminoadipic acid pathway was operating. However, the results show that barley seedlings are able to convert a small part of the α-aminoadipic acid administered directly to lysine.     

In vivo and in vitro studies on asparagine biosynthesis in soybean seedlings

The biosynthesis of asparagine in plants was investigated by feeding radioactive metabolites to soybean cotyledons and by extracting an asparagine synthetase from the same tissue. Soybean cotyledon slices were supplied with radioactive succinate, malate, or aspartate in the presence or absence of various unlabeled metabolites for periods of up to 80 min. Neither aspartate nor malate was rapidly converted to asparagine; labeled aspartate was converted largely to malate. Labeled succinate was rapidly converted to asparagine, and several lines of evidence suggested that fumarate, malate, and aspartate are intermediates. The results suggest that asparagine biosynthesis in plant cells is compartmentalized beginning with succinate. Although results were also consistent with asparagine formation via aspartate, metabolism of a mixture of [¹⁴C] plus [³H]succinate resulted in a lower ${}^{14}\text{C}{}^3\text{H}$ ratio in asparagine than aspartate, suggesting that some asparagine may be formed via another pathway. Demonstration of a glutamine-linked asparagine synthetase in soybean cotyledons supports the idea that asparagine is formed via aspartate. The enzyme requires aspartate (K_m = 2.2 mm), glutamine (K_m = 0.12 mm), ATP (K_m = 0.066 mm), magnesium ion, and sulfhydryl protection. It has a pH optimum of 7.7 and is not located in mitochrondria. A small amount of asparagine was formed when ammonium ion was substituted for glutamine, but the K_m of the enzyme for ammonium ion was about 25-fold greater than the K_m for glutamine suggesting that glutamine is the physiologically important substrate. Soybean cotyledons actively convert [¹⁴C]-cyanide to asparagine, apparently via β-cyanoalanine. However, malate was also rapidly labeled from [¹⁴C]cyanide and this result cannot be explained by known metabolic pathways.