The 2-hydroxylation of trans-cinnamic acid by chloroplasts from Melilotus alba Desr

Chloroplasts isolated from sweetclover leaves contain an enzyme which converts trans-[3-¹⁴C]cinnamic acid to 2-hydroxy-trans-[3-¹⁴C]cinnamic (o-coumaric) acid. The identity of the product has been verified by recrystallization with unlabeled o-coumaric acid to constant specific activity, and by gas-liquid cochromatography of unlabeled o-coumaric acid and the radioactive product.The enzyme has an optimum of pH 7.0 and its activity can be enhanced ~ 4-fold by adding 4 mm glucose-6-phosphate to the reaction mixture. Light can replace glucose-6-phosphate, presumably as a source of reducing power required for the hydroxylation system. It was found that approximately 50% of the hydroxylase activity is bound to the lamellar membranes, from which it can be released by sonication.     

Intracellular Localization of Two Enzymes Involved in Coumarin Biosynthesis in Melilotus alba

The localization of phenylalanine ammonia-lyase [EC 4.3.1.5] within sweet clover (Melilotus alba) leaves was investigated. Apical buds and axillary leaves contained 15 to 30 times more enzyme activity than did mature leaves. Mesophyll protoplasts were prepared by digesting young leaves with Cellulysin and Macerase and were gently ruptured yielding intact chloroplasts. These chloroplast preparations exhibited neither phenylalanine ammonia-lyase nor o-coumaric acid O-glucosyltransferase activities. The general enzymic properties of sweet clover leaf phenylalanine ammonia-lyase were similar to those described for this enzyme isolated from other plant species. The conversion of l-phenylalanine to trans-cinnamic acid, which occurred at an optimum pH of about 8.7, was strongly inhibited by the metabolites trans-cinnamic and o-coumaric acids. In contrast, o-coumaric acid glucoside, coumarin, p-coumaric acid, and melilotic acid had no significant effect on the reaction rate.     

Investigation of Four Classes of Non-nodulating White Sweetclover (Melilotus alba annua Desr.) Mutants and Their Responses to Arbuscular-Mycorrhizal Fungi

The nitrogen-fixing symbiosis between Rhizobiaceae and legumes is one of the best-studied interactions established between prokaryotes and eukaryotes. The plant develops root nodules in which the bacteria are housed, and atmospheric nitrogen is fixed into ammonia by the rhizobia and made available to the plant in exchange for carbon compounds. It has been hypothesized that this symbiosis evolved from the more ancient arbuscular mycorrhizal (AM) symbiosis, in which the fungus associates with roots and aids the plant in the absorption of mineral nutrients, particularly phosphate. Support comes from several fronts: 1) legume mutants where Nod(-) and Myc(-) co-segregate, and 2) the fact that various early nodulin (ENOD) genes are expressed in legume AM. Both strongly argue for the idea that the signal transduction pathways between the two symbioses are conserved. We have analyzed the responses of four classes of non-nodulating Melilotus alba (white sweetclover) mutants to Glomus intraradices (the mycorrhizal symbiont) to investigate how Nod(-) mutations affect the establishment of this symbiosis. We also re-examined the root hair responses of the non-nodulating mutants to Sinorhizobium meliloti (the nitrogen-fixing symbiont). Of the four classes, several sweetclover sym mutants are both Nod(-) and Myc(-). In an attempt to decipher the relationship between nodulation and mycorrhiza formation, we also performed co-inoculation experiments with mutant rhizobia and Glomus intraradices on Medicago sativa, a close relative of M. alba. Even though sulfated Nod factor was supplied by some of the bacterial mutants, the fungus did not complement symbiotically defective rhizobia for nodulation.     

Microsatellite markers for the invasive plant species white sweetclover (Melilotus alba) and yellow sweetclover (Melilotus officinalis)

We describe specific primers that amplify nine microsatellite DNA loci from Melilotus alba and Melilotus officinalis, both invasive plant species (Fabaceae) throughout North America. Allelic diversity was slightly lower for M. alba than for M. officinalis, as was expected heterozygosity. For both species, heterozygote deficit was observed at several loci. Genotypic diversity was very high for both species; the 29 plant samples of each species all had different multilocus genotypes. These markers will be used to determine the origins of the sweetclover invasion in Alaska and to compare patterns of diversity between subarctic and lower latitude populations.     

A Temperature-Sensitive Chlorophyll b-Deficient Mutant of Sweetclover (Melilotus alba)

The ch4 mutant of sweetclover (Melilotus alba) has previously been demonstrated to be partially deficient in chlorophyll and to have a higher ratio of chlorophyll a to b than normal plants. We were able to substantiate these findings when plants were grown at 23°C and lower (permissive temperatures). However, when grown at 26°C (nonpermissive temperature) the plants produced small yellow leaves which exhibited one-twentieth the chlorophyll content of normal plants. Affected leaves did not increase their chlorophyll content when plants were incubated at permissive temperatures, but leaves which developed at the lower temperature contained increased amounts of chlorophyll. Similarly, only new leaves, not previously grown leaves, exhibited the yellow phenotype when the mutant plant was shifted from the permissive temperature to the nonpermissive temperature. Ribulose 1,5-bisphosphate carboxylase activity was decreased by half, relative to normal plants, in the mutant plants grown at the nonpermissive temperature, indicating that general protein synthesis was not greatly impaired and that the effect of the mutation was perhaps specific for chlorophyll content. HPLC analysis indicated that carotenoid content was not diminished to the same extent as chlorophyll and we have determined that the thylakoid protein kinase is not altered, as is the case for other chlorophyll b-deficient mutants. Experiments suggest that changes in photoperiod may be able to modulate the effect of temperature.     

Characterization and Subcellular Localization of Aminopeptidases in Senescing Barley Leaves

Four aminopeptidases (APs) were separated using native polyacrylamide gel electrophoresis of cell-free extracts and the stromal fractions of isolated chloroplasts prepared from primary barley (Hordeum vulgare L., var Numar) leaves. Activities were identified using a series of aminoacyl-β-naphthylamide derivatives as substrates. AP1, 2, and 3 were found in the stromal fraction of isolated chloroplasts with respective molecular masses of 66.7, 56.5, and 54.6 kilodaltons. AP4 was found only in the cytoplasmic fraction. No AP activity was found in vacuoles of these leaves. It was found that 50% of the l-Leu-β-naphthylamide and 25% of the l-Arg-β-naphthylamide activities were localized in the chloroplasts. Several AP activities were associated with the membranes of the thylakoid fraction of isolated chloroplasts. AP1, 2, and 4 reacted against a broad range of substrates, whereas AP3 hydrolyzed only l-Arg-β-naphthylamide. Only AP2 hydrolyzed l-Val-β-naphthylamide. Since AP2 and AP3 were the only ones reacting against Val-β-naphthylamide and Arg-β-naphthylamide, respectively, several protease inhibitors were tested against these substrates using a stromal fraction from isolated chloroplasts as the source of the two APs. Both APs were sensitive to both metallo and sulfhydryl type inhibitors. Although AP activity decreased as leaves senesced, no new APs appeared on gels during senescence and none disappeared.     

Induced symbiosis mutants of pea (Pisum sativum) and sweetclover (Melilotus alba annua)

Treatment of Pisum sativum (L.) cv. ‘Sparkle’ with ethylmethane sulfonic acid or γ or neutron radiation induced stable mutants which do not form nodules, or form few nodules. Six mutants were at the previously described sym 5 locus. Non-nodulating mutants of Melilotus alba annua (Desr.) cv. U389 were obtained by treatment with ethylmethane sulfonic acid (EMS) or neutron radiation, but not by γ radiation or azide.     

Nodulin gene expression in effective root nodules of white sweetclover (Melilotus alba Desr.) and in ineffective nodules elicited by mutant strains of Rhizobium meliloti

Fifteen nodulins and several nodule-stimulated gene productswere expressed in effective, nitrogen-fixing root nodules ofwhite sweetclover (Melilotus alba Desr. cv. U389), as determinedby two-dimensional gel electrophoresis of in vitro translationproducts. The number and gel position of eight leghaemoglobin(Lb) products, as well as a product tentatively identified asnodule-stimulated glutamine synthetase (GS), was similar toprevious reports of alfalfa (Medicago sativa L. cv. Iroquois)nodulins. Three mutants of Rhizobium meliloti, including anexoH mutant, a lipopolysaccharide mutant, and a nifH mutant,elicited ineffective sweetclover nodules blocked at empty (bacteria-free),partially infected, or fully infected stages of nodule development,respectively. In these ineffective nodules, the nodulin Nma30and nodule-stimulated NSTma42 were expressed early in development,while a group of four nodulins and two nodule-stimulated productswere intermediate in order of expression. Lb, GS and the latenodulin Nmal2a were expressed later, following infection. TheexoH mutant, Rm7154, appeared to be a leaky mutant, as a smallpercentage of the plants developed nitrogen-fixing nodules about4 weeks after inoculation. The sequential expression of a largenumber of nodulins and nodule-stimulated products, as well asthe availability of sweetclover nodulation mutants indicatesthat sweetclover is a useful diploid system for analysis ofhost genes essential to the Rhizobium/legume symbiosis. Key words: Nitrogen fixation, nodulation mutants, nodulins     

Subcellular Localization of Asparaginase and Asparagine Aminotransferase in Pisum sativum Leaves

Protoplasts isolated from young and mature pea leaves (Pisum sativum L.) were broken and their contents fractionated by differential centrifugation or on sucrose-density gradients. Asparaginase was found only in the cytosol of young leaves. Asparagine aminotransferase was found in both young and mature leaves and was localized exclusively in the peroxisome. This corroborates the observation that asparagine transamination is catalyzed by the serine:glyoxylate aminotransferase.     

黄花草木樨提取物抑菌活性初探

采用离体和活体试验方法分别测定了黄花草木樨不同溶剂提取物对12种植物病原真菌的抑菌活性.结果表明:各溶剂提取物对12种植物病原真菌均具有不同程度的抑菌活性,其中以乙酸乙酯提取物的抑菌活性最高,对油菜菌核病菌、玉米大斑病菌和白菜黑斑病菌抑制菌丝生长的EC50分别为0.62、0.83、0.64g/L,对稻瘟病菌和玉米大斑病菌抑制孢子萌发的EC50分别为0.67、0.97g/L.离体组织法测定表明其乙酸乙酯提取物对番茄灰霉病菌具有较高的保护和治疗作用,在浓度为5.0g/L时,防治效果分别为75.41%和59.18%(6d).活体试验表明乙酸乙酯提取物对小麦白粉病和小麦条锈病也有一定的保护作用,在浓度为10.0g/L时,防治效果分别为73.39%和63.27%.     

Subcellular Localization of Proteases in Developing Leaves of Oats (Avena sativa L.)

The distribution and subcellular localization of the two major proteases present in oat (Avena sativa L. cv Victory) leaves was investigated. Both the acidic protease, active at pH 4.5, and the neutral protease, active at pH 7.5, are soluble enzymes; a few percent of the enzyme activity was ionically bound or loosely associated with organellar structures sedimenting at 1000g. On the average, 16% of the acidic protease could be washed out of the intercellular space of the leaf. Since isolated protoplasts contained correspondingly lower activities as compared to crude leaf extracts, part of the acidic activity is associated with cell walls. No neutral protease activity was recovered in intercellular washing fluid. Of the activities present in protoplasts, the acidic protease was localized in the vacuole, whereas the neutral protease was not. The localization of the acidic protease in vacuoles did not change during leaf development up to an advanced stage of senescence, when more than 50% of the leaf protein had been degraded. These observations indicate that protein degradation during leaf senescence is not due to a redistribution of acidic protease activity from the vacuole to the cytoplasm.     

Subcellular Localization of Oxaloacetate Decarboxylase and Its Isolation from Maize Leaves

The activity of oxaloacetate decarboxylase was revealed in leaves of a C₄ plant, maize (Zea mays L.). This activity was unrelated to decarboxylase activities of other enzymes, e.g., NAD-malate dehydrogenase (EC 1.1.1.38) or NADP-malate dehydrogenase (EC 1.1.1.40), and was located in chloroplasts (83.1%). Using a four-step purification procedure, an electrophoretically pure enzyme preparation of oxaloacetate decarboxylase was obtained from maize leaves. The specific activity of the enzyme was 3.150 EU/mg protein, the factor of purification was 40.4, and the yield was 11.0%. The enzyme exhibited Michaelis–Menten kinetics with K _m for oxaloacetate 30 ± 5 M and pH optimum 7.1 ± 0.5. The metabolite-mediated regulation of oxaloacetate decarboxylase activity has been investigated. It is found that sodium chloride (1.0 mM) activates the enzyme, whereas ATP inhibits the enzyme activity.     

Functional Implications of the Subcellular Localization of Ethylene-Induced Chitinase and [beta]-1,3-Glucanase in Bean Leaves

Plants respond to an attack by potentially pathogenic organisms and to the plant stress hormone ethylene with an increased synthesis of hydrolases such as chitinase and [beta]-1,3-glucanase. We have studied the subcellular localization of these two enzymes in ethylene-treated bean leaves by immunogold cytochemistry and by biochemical fractionation techniques. Our micrographs indicate that chitinase and [beta]-1,3-glucanase accumulate in the vacuole of ethylene-treated leaf cells. Within the vacuole label was found predominantly over ethylene-induced electron dense protein aggregates. A second, minor site of accumulation of [beta]-1,3-glucanase was the cell wall, where label was present nearly exclusively over the middle lamella surrounding intercellular air spaces. Both kinds of antibodies labeled Golgi cisternae of ethylene-treated tissue, suggesting that the newly synthesized chitinase and [beta]-1,3-glucanase are processed in the Golgi apparatus. Biochemical fractionation studies confirmed the accumulation in high concentrations of both chitinase and [beta]-1,3-glucanase in isolated vacuoles, and demonstrated that only [beta]-1,3-glucanase, but not chitinase, was present in intercellular washing fluids collected from ethylene-treated leaves. Based on these results and earlier studies, we propose a model in which the vacuole-localized chitinase and [beta]-1,3-glucanase are used as a last line of defense to be released when the attacked host cells lyse. The cell wall-localized [beta]-1,3-glucanase, on the other hand, would be involved in recognition processes, releasing defense activating signaling molecules from the walls of invading pathogens.     

Five Nodulation Mutants of White Sweetclover (Melilotus alba Desr.) Exhibit Distinct Phenotypes Blocked at Root Hair Curling,Infection Thread Development,and Nodule Organogenesis

Flavonol aglycones are required for pollen germination in petunia (Petunia hybrida L.). Mutant plants lacking chalcone synthase (CHS), which catalyzes the first committed step in flavonoid synthesis, do not accumulate flavonols and are self-sterile. The mutant pollen can be induced to germinate by supplementing it with kaempferol, a flavonol aglycone, either at the time of pollination or by addition to an in vitro germination system. Biochemical complementation occurs naturally when the mutant, flavonol-deficient pollen is crossed to wild-type, flavonoid-producing stigmas. We found that successful pollination depends on stigma maturity, indicating that flavonol aglycone accumulation may be developmentally regulated. Quantitative immunoblotting, in vitro and in vivo pollen germination, and high-performance liquid chromatographic analyses of stigma and anther extracts were used to determine the relationship between CHS levels and flavonol aglycone accumulation in developing petunia flowers. Although substantial levels of CHS were measured, we detected no flavonol aglycones in wild-type stigma or anther extracts. Instead, the occurrence of a conjugated form (flavonol glycoside) suggests that a mechanism may operate to convert glycosides to the active aglycone form.     

Tissue Distribution and Subcellular Localization of Prephenate Aminotransferase in Leaves of Sorghum bicolor

The tissue and subcellular distribution of prephenate aminotransferase, an enzyme of the shikimate pathway, was investigated in protoplasts from leaves of Sorghum bicolor. Activity was detected in purified epidermal and mesophyll protoplasts, and in bundle sheath strands. After fractionation of mesophyll and epidermal protoplasts by differential centrifugation, 92% of the total prephenate aminotransferase activity was detected in the plastid fraction.     

Structure of the endosperm in the mature seed of Melilotus alba]

The results of the exam at the light, the fluorescence and the scanning electron microscope of the endosperm of Melilotus alba mature impermeable seeds are reported. Cryostat sections, semithin sections and squashes are observed. Melilotus alba endosperm is variable in thickness and envelopes cotyledons and radicle. Its "aleurone" layer is one-cell thick, while the number of layers of its internal cells varies in relation to the location in the seed. In the aleurone cells, the cytoplasm and the outer portion of the wall are autofluorescent; tannic acid-ferric chloride stains the outer portion of the wall and allows to see clearly the inner thickenings, DAPI and haematoxylin demonstrate the presence of the nucleus. The cytoplasm of these cells is coloured by Sudan black b, and its fluorescence is enhanced by auramine and calcofluor white. Calcofluor white enhances the fluorescence of the outer portion of these walls, too, but is without effect on the non-autofluorescent thickening, indicating presence of cellulose only in the first case. Callose is absent. Also the thin autofluorescent walls of the endosperm inner cells react positively to calcofluor. These cells are very large, almost completely filled with "gelatinous" substances--the galactomannans--and very rarely contain a nucleus.     

Temperature sensitivity as a general phenomenon in a collection of chlorophyll-deficient mutants of sweetclover (Melilotus alba)

A collection of chlorophyll (Chl)-deficient mutants of sweetclover (Melilotus alba) with defects in eight nuclear loci were grown at 17 or 26° C. Plants grown at either temperature were examined for Chl content, Chla/b ratio, expression of the light-harvesting complex II (LHC-II) apoproteins, and protochlorophyllide (Pchlide) biosynthetic capacity. Except for thech4 mutant, the parental strain and all mutants accumulate more Chl when grown at 26° C than at 17° C. Thech5 mutants, lacking Chl b under any growth condition, and thech12 mutant showed little temperature-dependent phenotypic plasticity, whereas this was a marked phenomenon in the other mutants. Thech10 andch11 mutants demonstrated extreme temperature sensitivity with regard to the production of Chlb and the Chlb-binding LHC-II apoproteins. When excised trifoliolates were supplemented with exogenously supplied -aminolevulinic acid, only thech4 mutant was markedly impaired in the ability to produce Pchlide. These data indicate that temperature-sensitive phenotypic plasticity is a common phenomenon of chlorophyll-deficient mutants and substantiate that only a minority of Chl-deficient mutants is impaired in the biosynthesis of Chl.This research was supported by Grants GM84-CRCR-1-1479 (J.C.O.) and 89-00641 (J.M.) of the United States Department of Agriculture and by National Science Foundation Grant DMB87-03100 (J.M.). This is paper No. 8971, Nebraska Agricultural Research Division.     

Genetic regulation of flavonoid content in seeds and seedlings of Melilotus alba

Chemical analysis of seeds and seedlings of the CC and cc genotypes in Melilotus alba indicated that these alleles affect flavonoid biosynthesis. The CC seed coats contained orientin and iso-orientin, which were absent in the cc seed coats. The pigment responsible for the red pigmentation of young seedlings of CC genotypes was a cyanidin glycoside. The embryos of seeds of both the CC and cc genotypes contained a flavonoid tentatively identified as a 6,8-di-C-pentosylapigenin. The observation that 3′,4′-dihydroxyflavonoids were absent in the cc genotype and that 4′-hydroxyflavonoids were present in both genotypes indicated that the C/c alleles controlled the 3′-hydroxylation of flavonoids. The C/c alleles did not, however, control 3′-hydroxylation of cinnamic acids since caffeic acid was detected in both genotypes.