Biosynthesis of a β-(1 → 4)-mannan in fenugreek seedlings

A particulate enzymatic preparation, extracted from fenugreek seedlings (Trigonella foenum-graecum) catalyses the transfer of mannose from guanosine diphosphate-[U-¹⁴C]mannose and its incorporation into an alkali-soluble polysaccharide. Chemical and enzymatic study of this polysaccharide reveals the presence of only one type of osidic linkage, namely β-(1 → 4)-s-mannopyranosyl. The influence of some factors on this biosynthesis was studied, as well as the MW of the polysaccharide and the existence of an endogenous acceptor.     

Action of red light on indole-3-acetic-acid status and growth in coleoptiles of etiolated maize seedlings

Brief irradiation of intact etiolated seedlings of maize (Zea mays L.) with red light (R; 30 W cm^-2, 10 min) reduces the amounts of diffusible and free (solvent-extractable) indole-3-acetic acid (IAA) obtainable from excised coleoptile tips. The effect is transient, the lowest level (30% of the dark control) occurring at about 3 h after irradiation. The free-IAA content of the whole coleoptile and the diffusible-IAA yield from the base of the same organ are similarly reduced, whereas the conjugated-IAA content of the coleoptile is not affected. These results support the view that R inhibits the production of IAA at the coleoptile tip. It is further shown that R inhibits biosynthesis of [³H]IAA from [³H]tryptophan supplied to the coleoptile tip. The shapes of the fluence-response curves obtained for the reduction of the diffusible-IAA yield by R and far-red light (FR) indicate the participation of two photoreactive systems. One has thresholds at 10^-3 W s cm² of R, five orders of magnitude less than the minimum required for the appearance of spectrophotometrically measurable far-red-absorbing form of phytochrome (Pfr) in vivo, and 10^-1 W s cm^-2 of FR; its response is linear to the logarithm of fluence exceeding five orders of magnitude. The other system is seen above 10² W s cm^-2 as an increase in the slope of the fluenceresponse curve; its response is FR reversible and related to the Pfr level of total photoreversible phytochrome. Both systems inhibit biosynthesis of IAA from tryptophan. Elongation of the coleoptile is stimulated by R; the stimulation is most apparent in the apical region, and is saturated with a fluence at which bo detectable pfr is formed. Farred light can also saturate this response. Since the endogenous IAA concentration in the coleoptile appears not to be in the inhibitory range, it is concluded that the stimulation of coleoptile elongation is not the result of changes in free-IAA levels.Abbreviations FR far-red light - IAA indole-3-acetic acid - Pfr phytochrome in the far-red-absorbing form - Pr phytochrome in the red-absorbing form - R red light     

Acetyl coenzyme A biosynthesis in the chloroplast

Acetyl coenzyme A (CoA) biosynthesis in spinach chloroplasts has been investigated by following the incorporation of bicarbonate and acetate into fatty acids under a variety of conditions. Both substrates were readily incorporated into fatty acids in a light-dependent manner by intact photosynthesising chloroplasts, but when the concentrations of these substrates were adjusted to those found in vivo, i.e. 200 M acetate, 10 M bicarbonate, then acetate was found to supply carbon atoms for fatty acids biosynthesis via acetyl CoA at forty times the rate of bicarbonate. It is proposed that extra-chloroplastic free acetate is the pricipal substrate for chloroplasts acetyl CoA biosynthesis in spinach.Abbreviations ACP acyl carrierprotein - CoASH coenzyme A     

The B-ring hydroxylation pattern of intermediates of anthocyanin synthesis in pelargonidin-and cyanidin-producing lines of Matthiola incana

In flowers of Matthiola incana, the B-ring hydroxylation pattern of anthocyanins is controlled by the locus b. Recessive genotypes produce pelargonidin and genotypes with wild-type alleles cyanidin as the aglycone. Supplementation experiments on acyanic flowers using extracts of pelargonidin-and cyanidin-producing flowers, respectively, showed not only the presence of compounds with a precursor function for anthocyanin synthesis in the cyanic flowers but also differences in the B-ring hydroxylation pattern of these compounds. Chromatographic investigations proved that flavanones and dihydroflavonols occur in extracts of cyanic flowers. Naringenin, dihydrokaempferol, and their 7-glucosides could be demonstrated in all flower extracts, but in extracts of cyanidin-producing flowers, dihydroquercetin and a further 3, 4-hydroxylated dihydroflavonol, tentatively identified as dihydroquercetin 3-glycoside, were additionally found. In no case, however, could eriodictyol be detected. From these results and from the ready hydroxylation of dihydrokaempferol to dihydroquercetin in a white mutant line of Matthiola incana, it can be concluded that introduction of the 3-hydroxyl group of anthocyanins is not achieved by specific incorporation of caffeic acid during synthesis of the flavonoid skeleton, but by hydroxylation at the dihydroflavonol stage.     

Zur Kompartimentierung der Synthese von Mono- und Sesqui-Terpenen des ätherischen Öls beiPoncirus trifoliata

Zusammenfassung In der Frucht vonPoncirus trifoliata liegen in der Außenschale Drüsenzellkomplexe, die ein monoterpenreiches ätherisches Öl mit geringem Anteil an Sesquiterpenen und O-haltigen Substanzen produzieren. Ähnlich aussehende Exkretzellkomplexe aus den Saftschläuchen enthalten hauptsächlich Sesquiterpenkohlenwasserstoffe (STKW) und O-haltige Komponenten und sehr wenig Monoterpenkohlenwasserstoffe (MTKW). Im Schalenöl konnten nach gaschromatographischer Trennung mit Hilfe der Massenspektrometrie 19 Komponenten identifiziert werden, im Saftschlauchöl 25.Elektronenmikroskopische Aufnahmen der jüngsten Drüsenzellen beider Drüsenkomplexe lassen erkennen, daß beide Terpenklassen wahrscheinlich hauptsächlich bzw. ausschließlich plastidär entstehen.Exogen angebotenes¹⁴CO₂ wird zunächst überwiegend in die MTKW eingebaut, erst später nimmt die Markierung der STKW und O-haltigen Komponenten stark zu. Über den Ferntransportweg angebotenes¹⁴C-Leucin führt anfangs zu einer starken Markierung der STKW und O-haltigen Komponenten, erst später verschiebt sich der Einbau etwas mehr in Richtung MTKW. Als Hauptursache für den differenten Einbau wird das Vorhandensein zweier Typen von Drüsenzellkomplexen mit unterschiedlichen Syntheseleistungen angesehen.Die aus dem¹⁴CO₂ in der Außenrinde gebildeten Assimilate werden zuerst in das MTKW-reiche Öl der Schalenexkretbehälter eingebaut. Die überwiegend STKW erzeugenden Saftschlauchbehälter werden erst später beliefert. Beim Leucinangebot über die Fruchtstiele scheint es gerade umgekehrt zu verlaufen. Die aufeinanderfolgenden Maxima der Ölproduktion in den beiden Drüsenzellkomplex-Typen und die Änderung des Komponentenspektrums ihres ätherischen Öls im Verlauf der Vegetationsperiode tragen ebenfalls zu einem je nach Jahreszeit unterschiedlichen Einbau in die MTKW und STKW bei.

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Compartmentation of mono- and sesqui-terpene biosynthesis of the essential oil inPoncirus trifoliata

Summary The fruit ofPoncirus trifoliata shows glandular cell complexes in the exocarp, which produce a volatile oil rich in monoterpenes but poor in sesquiterpenes and oxigenated compounds. The juice vesicles of the endocarp possess similar cell complexes mainly containing sesquiterpenes and oxigenated compounds, whereas monoterpenes only occur in small amounts. By the use of combined gas chromatography-mass spectrometry 19 components of the rind oil and 15 compounds of the endocarp oil could be identified.As demonstrated by electron microscopy the terpenes most probably are synthesized predominantly, if not exclusively in plastids. As shown by gasradiochromatography radioactive precursors (¹⁴CO₂ and¹⁴C-leucine) are incorporated into mono- and sesqui-terpenes to a different extent.This is due to two gland types producing essential oils of different composition with regard to their mono- and sesqui-terpene percentage. In fruit development the exocarp glands differentiate earlier than the endocarp glands do. The activity of exogenously applied¹⁴CO₂ first reaches the peripheral glands and later on appears in the interior glands. Depending upon the growth season, labelled leucine transported by the conducting tissues from lower plant parts leads to a high specific activity of the sesqui-terpenes and oxigenated compounds. It could be argued that in this instance the glands of the pulp are better provided with precursors than the exocarp glands. The successive maxima of essential oil production in both glandular complexes, and the changes in the concentration of individual oil constituents during the ontogeny of the fruit also contribute to different incorporation ratios of radioactive precursors into mono- and sesqui-terpenes.

     

Genetic control of chalcone isomerase activity in anthers of Petunia hybrida

The gene Po in pollen of Petunia hybrida Vilm. controls a discrete step in flavonoid biosynthesis. In recessive genotypes, naringenin-chalcone (4, 2,4,6-tetrahydroxychalcone) is accumulated, whereas, under the influence of the wild-type allele flavonols and anthocyanins are formed. Enzymic investigations on anthers of four genetically defined lines with different pollen colouration revealed a clear correlation between accumulation of naringenin-chalcone and deficiency of chalcone isomerase (EC 5.5.1.6). The results allow the conclusion that chalcone is the first product of the flavanone synthase reaction in anthers of Petunia hybrida and that chalcone isomerase is essential for the formation of flavonols and anthocyanins. These results were similar to those previously obtained with Callistephus chinensis (L.) Nees.Abbreviations EGME ethylen glycol monomethyl ether - MeOH methanol - CI chalcone isomerase - HOAc acetic acid - TLC thinlayer chromatography     

Post-translational processing of 7S and 11S components of soybean storage proteins

The synthesis and processing of the major storage proteins in soybean cotyledons was studied both in vivo and in vitro. The and subunits of 7S as well as the 11S proteins are synthesized as higher molecular weight-precursors on membrane-bound polysomes. The initial translation products of the 7S are proteolytically cleaved during translation suggesting the removal of a signal peptide as evidenced by the presence of 2 and 2 peptides immunoreactive with 7S antibody in the in vitro chain completion products of the membrane-bound polysomes. This is followed or accompanied by cotranslational glycosylation, which increases their size equivalent to that of initially-synthesized precursors. In vivo pulse-labelled 7S and products are of slightly higher molecular weights than the immunoprecipitable chain-completion products, indicating further post-translational modifications. A slow post-translational processing during a period of 1.5 to 16 h yields the final 7S and glycoproteins.Acidic and basic subunits of the 11S protein appear to be synthesized from common large molecular weight (60K-59K) precursors. Antibodies to the 11S acidic component recognize both acidic and basic domains in the precursor while those raised against basic subunits appear to be specific for that region only. The processing of the 11S precursor is also very slow and occurs post-translationally. This slow rate of processing, coupled with a temporal difference in the synthesis of 7S and 11S components, suggests a highly coordinated mechanism for synthesis and packaging of these proteins into protein bodies during seed development.     

Ultrastructural localization of juvenile hormone biosynthesis by insect corpora allata

Summary The conversion of exogenous ³H-farnesenic acid to ³H-methyl farnesoate and ³H-C₁₆ juvenile hormone (JH) has been followed in the corpus allatum (CA) cells of the desert locust Schistocerca gregaria by means of electron microscopic autoradiography. Aerobic and anaerobic chase incubations have been used to modify the quantities of these three compounds within the CA cells. Under all incubation conditions, radiolabel is found associated almost exclusively with the subcellular membrane systems — smooth endoplasmic reticulum (SER) and Golgi elements —and with the mitochondria. CA cells are probably similar to vertebrate steroid-synthesizing cells in that the secretory product is synthesized in the SER and mitochondria.Radiolabel was found to be present in all cells of the CA suggesting that all cells are capable of at least the final two stages of JH biosynthesis (the esterification and epoxidation of ³H-farnesenic aid). This indicates that JH biosynthesis may be regulated through changes in the biosynthetic capabilities of individual cells rather than through changes in the total number of cells engaged in biosynthesis. Radiolabel was not observed to be associated with any distinctive cellular product, a result which provides additional evidence for the suggestion that the release of JH from the CA is governed by laws of simple physical diffusion.Supported by operating grants from the National Research Council of Canada to SST and ASMS. ³H-farnesenic acid was supplied by the late Dr. A.F. White of the Unit of Invertebrate Chemistry and Physiology, A.R.C., University of Sussex. We thank Dr. G.E. Pratt for helpful discussions     

Biosynthesis of pterocarpan phytoalexins in Trifolium pratense

Feeding experiments have demonstrated that 7,2′-dihydroxy-4′-methoxy-isoflavone-[¹⁴C-Me] and -isoflavanone-[¹⁴C-Me] are extremely efficient precursors of the phytoalexin demethylhomopterocarpin in Cu²⁺-treated red clover seedlings. Neither of these compounds, nor demethylhomopterocarpin-[¹⁴C-Me], was incorporated into a second pterocarpan phytoalexin, maackiain. 3-Hydroxy-9-methoxypterocarp-6a-ene-[¹⁴C-Me] was a poor precursor of both pterocarpans. A biosynthetic pathway to demethylhomopterocarpin via 2′-hydroxylation of formononetin (7-hydroxy-4′-methoxyisoflavone) and subsequent reduction to the isoflavanone is proposed. The conversion of this isoflavanone into the pterocarpan may involve the corresponding isoflavanol and a carbonium ion intermediate. The branch-point to maackiain is probably at the formononetin stage. The presence of two coumestans, 9-O-methylcoumestrol and medicagol, previously unreported in red clover, is demonstrated. Biosynthetic implications are discussed.     

Chemical induction of β-carotene biosynthesis

Marsh white seedless grapefruit were treated with the 2-diethylaminoethanol esters of the following acids: benzoic, phenylacetic, hydrocinnamic, 4-phenylbutyric, 5-phenylvaleric, valeric, hexanoic, heptanoic, octanoic, nonanoic, 5-chlorovaleric, cyclohexanecarboxylic, phenoxyacetic, p-chlorophenoxyacetic, 3-phenoxypropionic, cinnamic and p-chlorocinnamic. Several of these esters, in particular the hexanoate, 4-phenylbutyrate and cinnamate, caused the accumulation of large amounts of β-carotene. The effects of the hexanoate and of 2-phenoxytriethylamine, which causes only lycopene accumulation, were studied as functions of time. The hexanoate caused the rapid accumulation of lycopene during the first day. The amount of lycopene then began to decrease and that of β-carotene increased until, after 14 days, β-carotene was the major pigment. 2-Phenoxytriethylamine caused rapid lycopene accumulation during the first day and a slow steady increase afterwards. Thus, the mode of action of the β-carotene inducers may be similar to that of the lycopene inducers except that the former are probably rapidly hydrolysed by the esterase(s) in the flavedo, so that they no longer inhibit the cyclase(s), and β-carotene is accumulated at the expanse of lycopene.