Presence of β-cyanoalanine synthase in unimbibed dry seeds and its activation by ethylene during pre-germination

Evolution of HCN from both rice ( Oryza sativa ) and cocklebur ( Xanthium pennsylvanicum ) seeds increased during a pre-germination period and preceded the evolution of (C₂H₄). These two species were adopted as the representatives of starchy and fatty seeds, respectively. Ethylene promotes seed germination of many species. However, HCN evolution declined abruptly when the radicles emerged and before the peak in C₂H₄ evolution. More-over, both rice and soybean ( Glycine max ) seeds showed some activity of β-cyanoalanine synthase (CAS, EC 4.4.1.9) even in the unimbibed dry state. The activities of CAS in the lower seed of cocklebur and in soybean seeds increased rapidly after emergence of the radicle. However, the CAS of rice seeds, with high activity in the dry state, exhibited a bimodal change, gradually decreasing until radicle emergence had occurred, but then increaing. It is thus likly that HCN evolution during initial imbibition may be derived from cyanogenic reserves and controlled by both pre-existing and subsequently-developing CAS. The exogenous application of C₂H₄ stimulated the activities of CAS in both rice and upper cocklebur seeds and reduced their cyanogen contents. Therefore, the decline of HCN evolution after germination seems to be due to the increased activities of CAS by endogenously produced C₂H₄.     

β-Glucosidase activities and HCN liberation in unimbibed and imbibed seeds, and the induction of cocklebur seed germination by cyanogenic glycosides

In many seed species, the major source of HCN evolved during water imbibition is cyanogenic glycosides. The present investigation was performed to elucidate the role of endogenous cyanogenic glycosides in the control of seed germination and to examine the involvment of β-glucosidase in this process. All seed species used here contained some activities of β-glucosidase already in the dry state before imbibition. in the decreasing order of Malus pumila, Daucus carota, Hordeum vulgare, Chenopodium album and so on. β-Gluosidase activity in upper and lower seeds of cocklebur (Xanthium pennsylvanicum Wallr.) decreased with imbibition, and in lower seeds the activity disappeared when they germinated. On the contrary, in caryopses of rice (Oryza sativa L. cv. Sasanishiki) β-glucosidase increased during imbibition, and this increase continued even after germination. β-Glucosidase in cocklebur seeds was more active in the axial than in the cotyledonary tissue. Amygdalin, prunasin and linamarin could all serve as substrattes for the β-glucosidase(s) from both cocklebur and rice. Amygdalin, prunasin and linamarin as well as KCN, were effective in stimulating the germination of upper cocklebur seeds. The seeds evolved much more free HCN gas when they were exposed to the cyanogenic glycosides than when the glycosides were absent. Moreover, the application of the cyanogenic glycosides or of KCN caused accumulation of bound HCN in the seeds. Carbon monoxide, which stimulated cocklebur seed germination only slightly, did not cause accumulation of bound HCN. We suggest that a balance between the cytochrome and the alternative respiration pathways, which is adequate for germination (Esashi et al. 1987. Plant Cell Physiol. 28: 141–150), may be brought about by the action of endogenous HCN; a large portion of which is liberated from cyanogenic glycosides via the action of β-glucosidase. In addition to the partial suppression of the cytochrome path and unlike carbon monoxide, the HCN thus produced may act to supply cyanide group(s) to unknown compounds necessary for germination.     

Cyanogenic Lipids: Utilization during Seedling Development of Ungnadia speciosa

Large amounts of cyanogenic lipids (esters of 1 cyano-2-methylprop-2-ene-1-ol with C:20 fatty acids) are stored in the seeds of Ungnadia speciosa. During seedling development, these lipids are completely consumed without liberation of free HCN to the atmosphere. At the same time, cyanogenic glycosides are synthesized, but the total amount is much lower (about 26%) than the quantity of cyanogenic lipids formerly present in the seeds. This large decrease in the total content of cyanogens (HCN-potential) demonstrates that at least 74% of cyanogenic lipids are converted to noncyanogenic compounds. Whether the newly synthesized cyanogenic glycosides are derived directly from cyanogenic lipids or produced by de novo synthesis is still unknown. Based on the utilization of cyanogenic lipids for the synthesis of noncyanogenic compounds, it is concluded that these cyanogens serve as storage for reduced nitrogen. The ecophysiological significance of cyanolipids based on multifunctional aspects is discussed.     

Interactions between hydrogen cyanide, gibberellin, abscisic acid and red light in germination of lettuce seeds

Germination of lettuce ( Lactuce sativa L. cy. Grand Rapids) seeds was promoted by red light and by pulse treatments with gibbercllie acid (GA₃) or hydrogen cyanide, whereas it was inhibited by short exposure of seeds to absusic acid (ABA). The eflects of unsalLirating red light and of 10 μ M GA₃ on lettuce germination were completely reversed the effect of ABA (100 μ M ). In contrast, hydrogen cyanide did not reverse the effect of 100 μ M ABA and only partly eliminated the effect of 10μ M ABA, independently of the sequence of treatments. Possible interactions between HCN GA₃, ABA and red light were discussed. It was concluded thai light GA₃ and HCN affect different mechanisms involved in lettuce germination: ABA counteracts the stimulatory action of all these faclors. being the most effective against cvanide Additional key words - Lactuca sativa, pholodormancy, phylohormoncs.     

Metabolism of [14C]ss-glucose and [14C]-acetate by lettuce embryos during early germination

The metabolism of ['⁴C]-labelled glucose and acetate has been investigated during the early germination - before radicle emergence - of lettuce ( Lactuca sativa L., cv. Val d'Orge) embryos. Similar amounts of radioactivity from both substrates were evolved as C., or incorporated into organic acids, amino acids and proteins. A large part of the [¹⁴C]-glucose was also incorporated into sucrose and polysaecharides, and a small part into the glycerol moiety of lipids. Acetate was massively incorporated into lipids, and only slightly into neutral compounds. These results show that both glucose and acetate can be utilized as respiratory substrates during early germination of lettuce embryos. Various biosynthetic pathways leading to amino acids, proteins, polysaecharides and lipids are active during this period.     

Cyanogenic glycosides and their metabolic enzymes in barley, in relation to nitrogen levels

The possible role for cyanogenic glycosides as nitrogen storage compounds was studied in barley, Hordeum vulgare (cv. Golf), cultivated under different nitrogen regimes. Cyanogenic glycosides were absent in seeds and roots but were synthesized in seedlings where they accumulated at a level of about 150 nmol shoot⁻¹ in control plants and 110 nmol shoot⁻¹ in nitrogen-starved plants. An enzyme involved in the breakdown of cyanogenic glycosides, β-glucosidase (EC 3.2.1.-) exhibited high activity in seeds and was also detected in roots and shoots. The activity of β-cyanoalanine synthase (EC 4.4.1.9), which is involved in the metabolism of HCN, was low in seeds but very high in roots and shoots. There was no correlation between the activities of the two enzymes and the content of cyanogenic glycosides or nitrogen. The relative content of nitrogen in cyanogenic glycosides never exceeded 0.3% of total nitrogen, and the amount of cyanogenic glycosides decreased at a low rate even at a stage when nitrogen limitation inhibited growth.     

The presence of two types of β-cyanoalanine synthase in germinating seeds and their responses to ethylene

Germinating seeds of many species contain two types of β-cyanoalanine synthase (CAS, EC 4.4.1.9) that convert HCN to β-cyanoalanine. One is cytoplasmic CAS (cyt-CAS), which is precipitated by 50 to 60% (NH₄)₂SO₄ and has a pH optimum of 10.5. Cytoplasmic CAS is present at high levels in dry seed and its activity does not increase during imbibition. The activity of cyt-CAS is not affected by exogenously applied ethylene (C₂H₄), except in rice ( Oryza sativa cv. Sasanishiki). The second type of CAS found in seed is mitochondrial CAS (mit-CAS), which is precipitated by 60 to 70% (NH₄)₂SO₄ and has a pH optimum of 9.5. Mitochondrial CAS is present at low levels in dry seed, and its activity increases greatly during imbibition in the seeds of all species tested. Exposure to C₂H₄ stimulated mit-CAS activity in seeds of rice, barley ( Hordeum vulgare cv. Hadakamugi). cucumber ( Cucumis sativus cv. Kagafushinari) and cocklebur ( Xanthium pennsylvanicum ). The increase in the mit-CAS activity in cocklebur in response to C₂H₄ commenced alter a lag period of 2 to 3 h when the duration of soaking was short (16 h), but commenced without a lag period when the seeds were soaked for three months. Application of both chloramphenicol and cycloheximide to the axial and cotyledonary tissues of cocklebur seeds strongly inhibited growth as well as the increase in mit-CAS activity. It is postulated that the mit-CAS is synthesized de novo during imbibition and that its activity is regulated by C₂H₄, CO₂ which also promotes seed germination in some species, was ineffective m stimulating mit-CAS activity in cocklebur seeds.     

Cyanogenic Eucalyptus nobilis is polymorphic for both prunasin and specific beta-glucosidases

Cyanogenesis (i.e. the evolution of HCN from damaged plant tissue) requires the presence of two biochemical pathways, one controlling synthesis of the cyanogenic glycoside and the other controlling the production of a specific degradative beta-glucosidase. The sole cyanogenic glycoside in Eucalyptus nobilis was identified as prunasin (D-mandelonitrile beta-D-glucoside) using HPLC and GC-MS. Seedlings from three populations of E. nobilis were grown under controlled conditions and 38% were found to be acyanogenic, a proportion far greater than reported for any other cyanogenic eucalypt. A detailed study of the acyanogenic progeny from a single open-pollinated parent found that 23% lacked a cyanogenic beta-glucosidase, 32% lacked prunasin and 9% lacked both. Of the remaining seedlings initially identified as acyanogenics, 27% contained either trace amounts of beta-glucosidase or prunasin, while 9% contained trace amounts of both. Results support the hypothesis that the two components necessary for cyanogenesis are inherited independently. Trace amounts are likely to result from the presence of non-specific beta-glucosidases or the glycosylation of the cyanohydrin intermediate by non-specific UDP glycosyl transferases.     

Influence of two selective factors on cyanogenesis polymorphism ofTrifolium repens L. in Darjeeling Himalaya

Cyanogenesis-the production of toxic hydrogen cyanide (HCN) by damaged tissue-inTrifolium repens L. (white clover), a type of most important pasture legume, has been studied at different elevations of Darjeeling Himalaya (latitude-27° 2′ 57″ N, longitude-88° 15′ 45″ E). Release of HCN takes place due to reaction between cyanogenic glucosides stored in vacuoles of the leaf cell and the corresponding enzyme β-glucosidase present in another compartment, often cell wall. Cyanogenesis, a defense system in plant, protects the clover from herbivore and inhibits grazing. Biochemical analysis showed the presence and absence of the cyanogenesis trait within the population in different proportions at different elevations. Acyanogenic individuals also showed variations with respect to presence or absence of either cyanogenic glucosides or β-glucosidase enzyme or both. The distribution of cyanogenic and acyanogenic plants was found in all places, but at lower altitudes (2084–2094 m) the dominating plants were cyanogenic whereas in higher altitude (2560 m) the dominating plants were acyanogenic. It was observed that blister beetle (Mylabris pustalata Thunb.) and the mollusc (Macrochlamys tusgurium Benson.) were the most common consumer of leaflets ofT. repens. Six categories of damage on white clover leaf by these animals were recorded. Our results suggest that the two selective factors or forces i.e. very cold temperature (harmful to cyanogenic plants) at higher altitude as well as indiscriminate but preferential predation (harmful to acyanogenic plants) interact to affect the system of cyanogenesis and also to cause the stable and protective polymorphism inT. repens rather than genotypic differences present among the plants.     

Cyanogenic glycosides in Lotus corniculatus

Summary Two genotypes (one cyanogenic and the other acyanogenic) of birds-foot trefoil, Lotus corniculatus L., were used to study the effects of cyanogenic glycosides in leaf tissues upon a polyphagous herbivore, the southern armyworm, Spodoptera eridania Cram. (Lepidoptera). No differences were observed in consumption rate, assimilation efficiency, utilization of plant biomass, or metabolic costs in terms of expended calories between larvae fed acyanogenic or cyanogenic leaves. Similarly no differences were seen in the nitrogen or caloric utilization efficiencies, or in the nitrogen accumulation rate or growth rate of larvae on cyanogenic versus acyanogenic plants. Larval performance and growth on 20-week old plants was generally poorer than on 4 week old plants, however. This was reflected in slower growth, smaller pupal weights, lower nitrogen utilization efficiencies (N.U.E.) and biomass assimilation efficiencies (A.D.) on both the cyanogenic and acyanogenic plants.Although useful as a deterrent to some herbivores, cyanogenesis does not seem to provide an effective defense against this adapted herbivore. This study supports current hypotheses of insect/plant coevolution, and suggests that the metabolic costs of processing cyanogenic plant biomass are small in comparison to those imposed by the nutritional status of the plant leaves.     

Interaction of triacontanol with gibberellin in control of lettuce seed germination

Triacontanol at concentrations from 2.3 × 10^-9 M to 2.3 × 10^-7 M did not affect the germination of lettuce ( Lactuca sativa L., cv. Grand Rapids) seeds in darkness, stimulated by light at 25°C or by benzyladenine at 31°C. Stimulation of seed germination by gibberellin A₃ (10^-5 M ) was significantly inhibited by triacontanol; the most effective concentration was 4.6 × 10^-8 M. Pulse experiments demonstrated that triacontanol was ineffective when applied later than gibberellin, whereas an inverse sequence of treatment caused an inhibition comparable to that resulting from continuous treatment of seeds with both factors. Possible interaction of triacontanol with gibberellin receptor is discussed.     

Cyanogenesis of Hevea brasiliensis during Infection with Microcyclus ulei1)

Eight Hevea species have been shown to be cyanogenic. They all liberated HCN following mechanical tissue injury. Infection of Hevea leaves with conidia of the plant pathogen Microcyclus ulei leads to a large reduction of hydrocyanic acid potential, while only small amounts of HCN are set free from the leaves into the atmosphere. HCN production by infected leaves follows a reproducible pattern with a maximum between 40 and 60 hours after infection. During the entire time of infection free HCN can be detected in the leaves. From leaves of susceptible clones high amounts of HCN are liberated whereas from resistant clones only very little HCN is released. In Hevea infections with M. ulei, cyanogenesis does not lead to defense of the fungal pathogen but impairment of the resistance reaction.     

Effects of cyanogenesis in bracken fern (Pteridium aquilinum) on associated insects

Abstract. 1. The relationship between cyanogenesis in bracken fern and the insect fauna feeding on the plant was investigated over a 3 year period. The most common insects between May and July, while cyanide levels were high, were the sawflies Strongylogaster impressata Provancher, S.multicincta Norton, Aneug-menus fzavipes (Norton), the aphid Macrosiphum euphorbiae (Thomas) and a microlepidopteran species of Monochroa .
2. Collections of insects from cyanogenic and acyanogenic fronds showed significantly fewer sawflies on the cyanogenic fronds. The aphid and the microlepidopteran were randomly distributed with respect to cyanogenicity.
3. Feeding tests for two of the sawfly species ( Simpressata and Smulticincta ) showed that larvae grew more slowly and had a higher mortality when raised on cyanogenic fronds than on acyanogenic ones.
4. Field collected cyanogenic bracken fronds were found to have sustained less damage from chewing herbivores compared with acyanogenic fronds.     

Ion movements during stomatal opening in darkness after illumination under nitrogen

In Zea mays L., Bryophylum laxiflorum Bak., Gossypium hirsutum L., Helianthus annuus L., Oryza sativa L. and Vigna radiata L., a pre-illumination in nitrogen causes transient stomatal opening upon returning the plant to darkness and normal air. In Zea mays L. hybrid INRA 508, K⁺ and Cl⁻ fluctuations in the stomatal complex during this stomatal opening in darkness were similar to those observed during a light-induced opening in normal air. These results are consistent with a two-phase mechanism for stomatal opening: a light phase that may occur in the absence of oxygen and carbon dioxide, and a dark phase during which oxygen is necessary for ion accumulation and other mechanisms of osmotic adjustment.     

Cyanogenesis by the entomopathogenic bacterium Pseudomonas entomophila

Aims:  To investigate whether the entomopathogenic bacterium Pseudomonas entomophila can synthesize hydrogen cyanide (HCN).
Methods and Results:  Cyanide production was assayed for during the growth of P. entomophila in liquid culture and during colonial growth. Pseudomonas entomophila produced HCN at a concentration of up to 40 μmol l⁻¹ during growth in liquid cultures and its production was found to be affected by oxygen availability, with levels increasing as the oxygen-transfer coefficient decreased. Pseudomonas entomophila made HCN during colonial growth at levels greater (approximately threefold) than those made by the well studied cyanogenic bacterium Pseudomonas aeruginosa .
Conclusions:  This study demonstrated unequivocally that P. entomophila can synthesize HCN, placing it among the small number of cyanogenic bacteria. Our data indicate that HCN production in P. entomophila is regulated by oxygen availability.
Significance and Impact of the Study:  Pseudomonas entomophila was recently identified to be the only pseudomonad that naturally infects and induces lethality of Drosophila melanogaster . The virulence factors which contribute to entomopathogenicity exerted by this species are largely unknown. In this study, we demonstrate that P. entomophila produces HCN, a secondary metabolite implicated in biocontrol properties and pathogenicity exerted by other bacteria.     

α-Hydroxynitrile lyase in Hevea brasiliensis and its significance for rapid cyanogenesis

The hydroxynitrile lyase (HNL, EC 4.2.1.-) of Hevea brasiliensis (Muell.-Arg.) catalyzes the dissociation of acetone cyanohydrin and mandelonitrile, but shows higher activity towards the natural substrate acetone cyanohydrin. The ratio between the activities of linamarase (β-glycosidase, EC 3.2.1.21) to HNL was screened for more than 30 Hevea plants. In mixed-enzyme incubations various ratios of HNL to β-glucosidase were analyzed for the rapidity of HCN liberation. Addition of HNL increased the rate of HCN liberation up to 20-fold, thus demonstrating the significance of the HNL for rapid cyanogenesis. Its physiological importance is shown by the fact that only plants possessing high HNL activity are able to liberate HCN efficiently. Cyanogenic plants have been described as being weakly or strongly cyanogenic depending on the total amount of HCN which is potentially liberated. The data presented in this paper suggest that cyanogenic plants should also be differentiated as fast or slow cyanogenic according to the observed velocity of HCN liberation. Thus, for evaluating the repellent action of cyanogenic plants not only the final level of the HCN liberated is important but rather the rate with which this level is reached.     

Biosynthesis of the nitrile glucosides rhodiocyanoside A and D and the cyanogenic glucosides lotaustralin and linamarin in Lotus japonicus

Lotus japonicus was shown to contain the two nitrile glucosides rhodiocyanoside A and rhodiocyanoside D as well as the cyanogenic glucosides linamarin and lotaustralin. The content of cyanogenic and nitrile glucosides in L. japonicus depends on plant developmental stage and tissue. The cyanide potential is highest in young seedlings and in apical leaves of mature plants. Roots and seeds are acyanogenic. Biosynthetic studies using radioisotopes demonstrated that lotaustralin, rhodiocyanoside A, and rhodiocyanoside D are derived from the amino acid l-Ile, whereas linamarin is derived from Val. In silico homology searches identified two cytochromes P450 designated CYP79D3 and CYP79D4 in L. japonicus. The two cytochromes P450 are 94% identical at the amino acid level and both catalyze the conversion of Val and Ile to the corresponding aldoximes in biosynthesis of cyanogenic glucosides and nitrile glucosides in L. japonicus. CYP79D3 and CYP79D4 are differentially expressed. CYP79D3 is exclusively expressed in aerial parts and CYP79D4 in roots. Recombinantly expressed CYP79D3 and CYP79D4 in yeast cells showed higher catalytic efficiency with l-Ile as substrate than with l-Val, in agreement with lotaustralin and rhodiocyanoside A and D being the major cyanogenic and nitrile glucosides in L. japonicus. Ectopic expression of CYP79D2 from cassava (Manihot esculenta Crantz.) in L. japonicus resulted in a 5- to 20-fold increase of linamarin content, whereas the relative amounts of lotaustralin and rhodiocyanoside A/D were unaltered.     

Natural 15N enrichment of amide-exporting legume nodules

The natural ¹⁵N abundance of amide-exporting nodules was compared to that of shoots in 12 plant species. Nodules were statistically less abundant in ¹⁵N than shoots in one of three cultivars of Pisum sativum L., in Vicia faba L. and in Medicago sativa L., but the ¹⁵N depletion of nodules was very samall. Nodules were statistically more abundant in ¹⁵N than shoots in Trifolium pratense L., depending on time during the growing season, Cyamopsis tetragonaloba L. Taub. and 7 Lupinus species, but the enrichment was small except for C. tetragonalova and 6 Lupinus species. Nodules of 3 Lupinus species infected with Rhizobium lupini isolated from Lupinus subcarnosa Hook, were only slightly enriched in ¹⁵N, but nodules of two of these species were substantially enriched in ¹⁵N when infected with a mix of other Rhizobium lupini strains. The third species, L. texensis Hook., was not infected by this mix of strains. Differences in ¹⁵N abundance between nodules and other tissues of amide-exporting and ureide-exporting nodules from several studies are tabulated. All ureide-exporting nodules in this tabulation are enriched in ¹⁵N. Amide-exporting nodules are considerably more variable in this regard. These results confirm that events associated with ureide synthesis or transport cannot be the sole cause of the substantial ¹⁵N enrichment seen in nodules.     

Metabolization of cyanogenic glucosides inHevea brasiliensis

Over 90% of the cyanogenic precursors ofHevea seeds is stored in the endosperm tissue. During seedling development most of the cyanogenic material is consumed to form noncyanogenic compounds. No gaseous HCN is liberated in the course of this process. The -glucosidase, responsible for the cleavage of cyanogenic glucosides and the key enzyme for cyanogenesis is widely distributed over all tissues. The highest enzyme activity of the HCN-metabolizing -cyanoalaninesynthase is found in young seedling tissues. It is concluded, that the cyanogenic glucosides must be transported and metabolized in the young, growing tissues.Lecture held at the Tagung der Deutschen Botanischen Gesellschaft in Vienna, September 1984.     

Evaluation of Cyanogenic Potentials of Local Cassava Species and Residual Cyanide Contents of Their Locally Processed Food Products in Southeast Nigeria

The cyanogenic potentials and residual cyanide contents of local cassava parenchyma and their locally processed food products in southeastern Nigeria were studied. Seven species of cassava locally grown and four main food products from them were analyzed colorimetrically for their cyanide contents. Results of the analyses indicated that five of the species contain cyanide potentials between 50 and 100 mg HCN/kg fresh weight while only one contains cyanogens level greater than 100 mg HCN/kg fresh weight. Of the cassava products analyzed, two contained cyanide above the level recommended by the WHO/FAO (10 mg HCN/kg). The result raises concern as these cassava products constitute about 80–90% of the diet of the local people and the facts known about cyanide poisoning from intake of high cyanide containing food.