Effect of bicarbonate on root growth and accumulation of organic acids in Zn-inefficient and Zn-efficient rice cultivars (Oryza sativa L.)

Bicarbonate has been regarded as a major factor for inducing Zn deficiency in lowland rice, but the mechanisms responsible for this effect are not yet fully understood. The objective of the present study was to test whether early effects of bicarbonate (HCO₃ ⁻)are inhibition of root growth due to the accumulation of organic acids induced by HCO₃ ⁻. Solution culture experiments were conducted using two rice cultivars differing in susceptibility to Zn deficiency, and four bicarbonate concentrations (0, 5, 10, 20 mM). Bicarbonate (5–20 mM) strongly inhibited root growth of the Zn-inefficient cultivar within 4 days of treatments. In contrast, root growth of the Zn-efficient cultivar was slightly stimulated with bicarbonate at 5–10 mM and not affected at 20 mM. The inhibitory effect of bicarbonate on root growth in the Zn-inefficient cultivar was mainly that of impairment of new root initiation rather than suppression of elongation of individual roots. Bicarbonate (5–20 mM) increased the concentrations of malate, succinate and citrate in the roots of both cultivars, but to a greater extent for the Zn-inefficient than for the Zn-efficient cultivars. The results suggest that the impairment of root growth was likely to be the initial action of bicarbonate in inducing Zn deficiency in lowland rice, and the inhibitory effect of bicarbonate on root growth of the Zn-inefficient cultivar might result from high accumulation and an insufficient compartmentation of organic acids in the root cells.     

Response of durum wheat cultivars to immature embryo culture,callus induction and in vitro salt stress

Response of twenty eight cultivars of durum wheat (Triticum turgidum var. durum) to immature embryo culture, callus production and in vitro salt tolerance was evaluated. For assessment of cultivars to salt tolerance, growing morphogenic calli were exposed to different concentrations of NaCl (0, 0.3, 0.6, 0.9, 1.2, 1.5, 1.8 and 2.1% w/v) added to the culture medium during two subsequent subcultures (4 weeks each). Comparison of cultivars for callus induction from immature embryo was based on callus induction frequency and fresh weight growth of callus (FWG). While, for salt tolerance, the relative fresh weight growth (RFWG) and necrosis percent of callus were used. There were significant differences among cultivars for potential of regeneration from immature embryo, and ‘Shahivandi’ a native durum wheat cultivar originating from western Iran was superior among the cultivars tested. The FWG distinguished cultivars more than callus induction frequency did for callus induction evaluation. Hence, a range of FWG from 1.23 to 14.65 g was observed in ‘Mexical-75’ and ‘Omrabi-5’ cultivars, respectively. Growing calli derived from cultivars ‘PI 40100’ and ‘Dipper-6’ showed superiority for tolerating salinity under in vitro conditions. This revised version was published online in June 2006 with corrections to the Cover Date.     

Field resistance of spring barley cultivars to powdery mildew in Lithuania

During vegetative period 2004–2005 powdery mildew (Erysiphe graminis DC. f. sp. hordei Em. Marchal) field resistance of spring barley cultivars was investigated at the Lithuanian Institute of Agriculture. The spring barley genotypes tested were Lithuania-registered cultivars, cultivars from genetic resources collection, and the new cultivars used for initial breeding. In total, 23 resistance genes were present in the 84 cultivars studied. Among mono-genes only mlo and 1-B-53 showed very high resistance. Slight powdery mildew necroses (up to 3 scores) formed on cultivars possessing these genes. The maximal powdery mildew (PM) severity reached a score of 8.5 and the area under disease progress curve (AUDPC) a value of 1216.8. The cultivars ‘Primus’, ‘Astoria’, ‘Power’, ‘Harrington’ and ‘Scarlett’ were the most resistant among the non mlo cultivars. Severity of PM on ‘Primus’ reached a score of 3.5 (3.0 of PM necrosis) in average, the other cultivars were diseased from 4.5 (3.0) to 5.0 (2.0). The AUDPC values for these cultivars except ‘Scarlett’ were the lowest (85.0–145.3) among the other cultivars. The highest contrast in development of the other leaf diseases was between highly resistant and susceptible to PM cultivar groups. The fast development of PM depressed development of the other diseases 4.7 times.     

Effects of nodulation on resistance to alfalfa sickness among ten alfalfa cultivars

Summary Ten alfalfa cultivars were used to study the effects of nodulation and variations in resistance to alfalfa sickness. The alfalfa seedlings were planted in sick soil with three treatment,,i.e.: pasteurized sick soil inoculated with Rhizobium ‘Nitragin’ which served as the control, the inoculated non-pasteurized sick soil and the non-inoculated non-pasteurized sick soil. None of the alfalfa cultivars were immune from the sickness. Cultivar ‘Anik’ fromMedicago falcata was among the most resistant cultivars. Three Phytophthora root rot resistant cultivars including ‘Agate’, ‘Apollo’ and ‘Ramsey’ were not resistant to the disease. Alfalfa inoculated with Rhizobium showed greatly improved seedling growth. Correlation coefficients showed that those alfalfa cultivars more resistant to alfalfa sickness produced more dry weight. Dry weight increase due to nodulation (82%) had more than compensated for the loss of dry weight due to alfalfa sickness (33%). The present study suggested that the poor growth of alfalfa on sick soil was attributed to both the soil borne pathogens and the poor nodulation of alfalfa, probably due to the absence of effective Rhizobium in sick soil. Highly significant differences were also obtained among olfalfa cultivars for plant dry weight in the inoculation treatment. Selection for effective Rhizobium strains and for alfalfa genotypes which are resistant to alfalfa sickness and are high in nitrogen fixation rates could improve alfalfa yield in sick soil.     

Differential susceptibility ofSclerotium cepivorum Berk. to some synthesized visnagin sulfonamide derivates

Twenty-five visnagin sulfonamide derivatives were testedin vitro against sclerotial germination, growth and cellulolytic activity ofSclerotium cepivorum Berk. The effectiveness of the derivatives depends on the concentration and the substituent introduced to the title compounds. The introduction of SO₂Cl₂ to C₉ of visnagin induced high toxicity than introducing SO₂NH₂. Compounds with sulfonyl piperidine or sulfonyl morpholine gave small toxicity only at 30 and 75 μg cm⁻³. Addition of N-aryl ring to visnagin-9-sulfonamide rendered the title compound to be more toxic. The substitution of the N-aryl ring bym-CH₃,m-Cl orp-Cl enhanced the toxicity, while its substitution witho-CH₃,p-CH₃,p-Br,o-OCH₃ orm-OCH₃ caused a drop in the toxicity as compared to compounds with unsubstituted aryl ring. Visnagin sulfonamide derivatives having azole rings were strongly inhibitory for sclerotial germination, growth, sclerotial formation and cellulolytic activity, even when applied at 4 μg cm⁻³. The most toxic one was that having dimethyl isoxazole. The cleavage of γ-pyrone ring led to a decline in the toxicity as compared with the other sulfonamide derivatives. Communicated by J. ŠPAK     

Antifungal activity of methanol extracts from spikes of Triticum spelta and Triticum aestivum genotypes differing in their response to Fusarium culmorum inoculation

The total concentrations of free phenolic compounds and peroxidase were determined in spikes (collected at the flowering stage) of some spelt and common wheat cultivars differing in their response to F. culmorum infection. The antifungal activity of methanol extracts obtained from spikes was also evaluated. The tested genotypes differed significantly in their response to inoculation. The most resistant were Torka and Zebra among common wheat cultivars, and Weisser Grannenspelz among spelt cultivars. The average content of free phenolic compounds in spikes of spelt and common wheat was 1246.56 μg g⁻¹ and 1236.58 μg g⁻¹, respectively. The cultivars whose spikes contained the largest amounts of phenols showed the weakest response to F. culmorum infection. No significant differences were observed with regard to peroxidase content, which was 5.22 U g⁻¹ in common wheat spikes and 5.14 U g⁻¹ in spelt spikes. Methanol extracts from spikes of all wheat cultivars contained antifungal substances. The extracts from spelt spikes inhibited the growth of F. culmorum on PDA to a lesser degree than the extracts from common wheat spikes. This corresponds to the results of field trials, in which T. spelta generally exhibited a stronger response to F. culmorum infection than common wheat. The high correlation (r = 0.816) between mycelium growth inhibition on the medium and F. culmorum infection indicates that an evaluation of the antifungal activity of extracts from spikes may be used for the selection of breeding materials directed towards increased resistance to Fusarium head blight.     

Hydraulic and Non-hydraulic Root-sourced Signals in Old and Modern Spring Wheat Cultivars in a Semiarid Area

Absract Non-hydraulic root-sourced signal (NRS) is so far affirmed to be a unique “early-warning” response to soil drying in plants, but little is known about the quantitative effect of this early-warning mechanism on crop production. To evaluate the link of NRS to a drought tolerance profile, a pot-culture study was carried out in a plant growth chamber with eight spring-wheat (Triticum aestivum L.) cultivars bred in semiarid China. The NRS was judged to begin when there was a significant lowering of stomatal conductance without any change in leaf relative water content (RWC), and the hydraulic root signal (HRS) was judged to begin when leaf RWC changed significantly. Soil water contents (SWC), at which the NRS and HRS were switched on, differed among the eight cultivars. For “Monkhead” and “Jinby,” representing “old” cultivars, the NRS and HRS were initiated successively at about 60% FWC (field water capacity) and 45% FWC, respectively. Conversely, “Longchun8139-2” and “Plateau 602” (recent cultivars) showed the NRS and HRS occurring between 70% FWC and 35% FWC, a much wider range. The events of the other four non-old cultivars were generally intermediate. This threshold range (TR) of soil FWCs between the onset of NRS and HRS also narrowed over the successive developmental stages from seedling to seed filling. Fewer survival days (SD), lower maintenance rate of grain yield (MRGY), and higher lethal leaf water potentials (LLWP) had been found in old cultivars. Widening TR was significantly correlated with increasing SD and MRGY (r = 0.8713** and 0.7318*, respectively), and with decreased LLWP (r = 0.8591**). This survey of different-decade cultivars suggests that advances in grain yield and drought tolerance would be made by targeted selection for a wider TR of root-sourced signals.     

Biomass yield and heterosis of crosses within and between European winter cultivars of turnip rape (<Emphasis Type="Italic">Brassica rapa</Emphasis> L.)

Because of its high growth rate at low temperatures in early spring, there is renewed interest in Brassica rapa as a winter crop for biomass production in Europe. The available cultivars are not developed for this purpose however. An approach for breeding bioenergy cultivars of B. rapa could be to establish populations from two or more different cultivars with high combining ability. The objective of this study was to evaluate the heterosis for biomass yield in the European winter B. rapa genepool. The genetic variation and heterosis of the biomass parameters: dry matter content, fresh and dry biomass yields were investigated in three cultivars representing different eras of breeding by comparing full-sibs-within and full-sibs-between the cultivars. Field trials were performed at two locations in Germany in 2005–2006. Mean mid-parent heterosis was low with 2.5% in fresh and 3.0% in dry biomass yield in full-sibs-between cultivars. Mean values of individual crosses revealed a higher variation in mid-parent heterosis ranging from 14.6% to −7.5% in fresh biomass yield and from 19.7% to −12.7% in dry biomass yield. The low heterosis observed in hybrids between European winter cultivars can be explained by the low genetic variation between these cultivars as shown earlier with molecular markers. In conclusion, a B. rapa breeding program for biomass production in Europe should not only use European genetic resources, but should also utilize the much wider worldwide variation in this species.     

Antifungal and cytotoxic effects of cyanein derivatives

The effects of cyanein, tetrahydrocyanein and diacetyl-O-cyanein on the growth and morphology of fungi and HeLa cells were studied. The change of cyanein structure decreased its cytotoxic effect (HeLa cell) to approx. a half and the antifungal effect up to 100 times (Saccharomyces cerevisiae andEremothecium ashbyi). Cyanein caused characteristic changes in morphology ofBotrytis cinerea (“bulging effect”, branching of hyphae) andPaecilomyces viridis (branching of hyphase, yeast-like growth). Except for flexuose ofPaecilomyces viridis hyphae caused by diacetyl-O-cyanein the cyanein derivatives did not induce the above mentioned morphologic changes.     

Does exogenous application of 24-epibrassinolide ameliorate salt induced growth inhibition in wheat (Triticum aestivum L.)?

A greenhouse experiment was conducted to assess whether exogenously applied 24-epibrassionlide (24-epiBL) could alleviate the adverse effects of salt on wheat. Two hexaploid wheat (Triticum aestivum L.) cultivars, S-24 (salt tolerant) and MH-97 (moderately salt sensitive), were grown under control (0 mM NaCl in full strength Hoagland’s nutrient solution) or saline conditions (150 mM of NaCl in full strength Hoagland’s nutrient solution). After 41 days growth of wheat plants under saline conditions, 24-epiBL was applied as a foliar spray. Four levels of BR were used as 0 (water spray), 0.0125, 0.025, and 0.0375 mg l⁻¹. Application of 24-epiBL increased plant biomass and leaf area per plant of both cultivars under non-saline conditions. However, under saline conditions, improvement in growth due to exogenous 24-epiBL was observed only in S-24. Photosynthetic rate was reduced due to salt stress in both cultivars, but this inhibitory effect was ameliorated significantly by the exogenous application of 24-epiBL. Exogenously applied 24-epiBL also enhanced the photosystem-II efficiency in both cultivars measured as F _v /F _m ratio. Although the activities of antioxidant enzymes, Superoxide dismutase (SOD), Peroxidase (POD) and Catalase (CAT) were increased due to salt stress in both wheat cultivars, exogenously applied 24-epiBL had a varying effect on the antioxidant system. The activity of SOD remained unaffected in both cultivars due to 24-epiBL application, but that of POD and CAT was promoted in the salt stressed plants of cv. S-24 only. In conclusion, improvement in growth in both wheat cultivars due to foliar applied 24-epiBL was found to be associated with 24-epiBL-induced enhancement in photosynthetic capacity. The 24-epiBL-induced regulation of antioxidant enzymes or growth under saline conditions was cultivar specific.     

The use of growth retardants to improve microtuber formation by potato (Solanum tuberosum)

The growth retardant chlormequat stimulated microtuber formation by a recalcitrant cultivar of potato (Solanum tuberosum), but reduced microtuber fresh weight in a cultivar that tuberised readily in its absence. Inhibition of microtuber growth by high concentrations of chlormequat was confirmed using a different in vitro system where all cultivars tuberised in the absence of growth retardants.Alternative growth retardants were tested. Daminozide also had a detrimental effect on microtuber fresh weight, but ancymidol and paclobutrazol did not inhibit microtuber growth at the concentrations required for stimulation of tuberisation by recalcitrant cultivars. In addition, 10^-5 M ancymidol and paclobutrazol inhibited premature sprouting of microtubers in vitro.Abbreviations BA benzyladenine - DMSO dimethyl sulphoxide - FW fresh weight - PAR photosynthetically active radiation - SE standard error     

Improved Tolerance of Three Saudi Pearl Millet Cultivars (<i>Pennisetum spicatum</i>) to Salt Stress by Mycorrhiza

Seeds of three Saudi pearl millet cultivars (Pennisetum spicatum) from three regions (Madinah, Khulais and Jaizan) were inoculated with arbuscular mycorrhizal fungus Glomus mosseae obtained from the Agriculture Research Center of Giza, Egypt to enhance their salt tolerance. Five different NaCl concentrations (0, 30, 60, 90, and 120 mM) were used for treating cultivars with and without mycorrhiza. Growth rates, chlorophyll content, chlorophyll fluorescence (Fv/Fm), proline content and gas exchange were measured to determine the effect of salinity on these cultivars. The results indicated that compared to cultivars without mycorrhiza, all cultivars with mycorrhiza had enhanced growth and physiological parameters including shoot and root length, area and number of leaves, fresh and dry weights of shoots and roots, chlorophyll contents and gas exchanges at 0 and 30 mM of salinity. In addition, the measurements of the different growth rates showed higher growth performance of the cultivars from Madinah and Khulais than the cultivar from Jaizan. However, all cultivars with and without mycorrhiza showed significant reductions in growth rates, chlorophyll contents and gas exchanges at a salinity of 60 mM than those grown at 0 and 30 mM. Moreover, the values of Fv/Fm were significantly reduced in all cultivars with and without mycorrhiza grown at 60 mM than in those grown at 0 mM and 30 mM. Proline contents indicated a progressive increase with the elevation of NaCl concentration stress. The proline contents in the mycorrhiza-inoculated cultivars were significantly higher than those in the non-inoculated cultivars. On the other hand, all cultivars with and without mycorrhiza underwent senescence within four weeks of growth at salinity concentrations of 90 mM and 120 mM. Therefore, relatively low salinity must be maintained to achieve high growth rates and gas exchanges of these inoculated cultivars.     

Physiological and biochemical responses of tomato microshoots to induced salinity stress with associated ethylene accumulation

Physiological and biochemical responses of open-pollinated ‘Roma’ and dwarf F1 hybrid ‘Patio’ tomato (Lycopersicon esculentum Mill.) cultivars to in vitro induced salinity were examined in light of the possible contribution of ethylene to these symptoms. Salinity was induced by incorporating 0 (control), 50, 100, 150, or 200 mM NaCl into shoot culture media. Elevated salinity treatments significantly enhanced ethylene accumulation in the headspace and were accompanied by increased leaf epinasty in both cultivars. Growth, leaf cell sap osmolarity, leaf tissue viability and shoot soluble protein content were generally depressed with elevated salinity treatments, whereas electrolyte leakage, membrane injury, raffinose, and total sugars were concomitantly increased. Macronutrients N, P, K, Ca, Mg, and S decreased with elevated salinity in both cultivars and were accompanied by a significant increase in Na content and a sharp decrease in K/Na ratio. Tissue micronutrients, Fe, B, Zn, Mn, and Cu were generally decreased with elevated salinity especially at 100 mM or more. Incorporating ethylene inhibitors CoCl₂ or NiCl₂ at 5.0 or 10.0 mg/l into media supplemented with 100 mM NaCl significantly reduced ethylene accumulation in the headspace and prevented epinasty, but did not eliminate the negative impacts on growth and other physiological parameters caused by salinity treatment in either cultivar. Our results indicate that the increase in ethylene under salinity stress is not the primary factor contributing to salinity’s deleterious effect on tomato plant growth and physiology.     

Growth response of lentil and wheat to Glomus clarum NT4 over a range of P levels in a Saskatchewan soil containing indigenous AM fungi

 The growth responses of lentil (Lens esculenta L. cv. Laird) and two wheat cultivars (Triticum aestivum L. cv. Laura and Neepawa) to Glomus clarum NT4 in soil containing indigenous arbuscular mycorrhizal fungi (AMF) and fertilized with phosphorus at different (0, 5, 10, 20 ppm) levels was studied in a growth chamber. Soil was inoculated with a monospecific culture of G. clarum NT4 to provide an inoculant:indigenous AMF ratio of ca. 1 : 100. The shoot and root growth, and AMF colonization levels of NT4-inoculated lentil were significantly (P≤0.05) greater than the appropriate control plants in the unfertilized soil at 48 days after planting (DAP). At 95 DAP, NT4 inoculation had significantly increased the shoot dry weight (P≤0.08) and AMF colonization (P≤0.05) of lentil plants receiving 5 mg P kg^–1 soil, whereas 20 mg P kg^–1 soil reduced the shoot growth of NT4-inoculated plants. The NT4 inoculant had no effect (P≤0.05) on shoot P content, but increased (P≤0.08) the P-use efficiency of lentil plants receiving 5 mg P kg^–1 soil. In contrast to the inoculant's effect on lentil, NT4 generally had no positive effect on any of the parameters assessed for wheat cv. Laura at any P level at 48 or 95 DAP. Similarly, there was no positive effect of NT4 on shoot or root growth, or AMF colonization of wheat cv. Neepawa plants at any P level at 48 DAP. However, NT4 inoculation increased the grain yield of Neepawa by 20% (P≤0.05) when fertilized with 20 mg P kg^–1 soil. This yield increase was associated with a significant (P≤0.05) reduction in root biomass and a significant (P≤0.05) increase in the grain P content of inoculated plants. Thus, NT4 appears to have a preference for the Neepawa cultivar. Our results show that lentil was more dependent on mycorrhizae than wheat and responded to an AMF inoculant even in soil containing high levels of indigenous AMF. It might, therefore, be possible to develop mixed inoculants containing rhizobia and AMF for field production of legumes. Accepted: 22 February 1997     

Wheat Resistance to Spot Blotch Potentiated by Silicon

Spot blotch, caused by the fungus Bipolaris sorokiniana, is one of the most important diseases on wheat. The effects of silicon (Si) on this wheat disease were studied. Plants of wheat cultivars BR‐18 and BRS‐208 were grown in plastic pots containing Si‐deficient soil amended with either calcium silicate (+Si) or calcium carbonate (?Si). The content of Si in leaf tissue was significantly increased by 90.5% for the +Si treatment. There was no significant difference between Si treatments for calcium content, so variations in Si accounted for differences in the level of resistance to spot blotch. The incubation period was significantly increased by 40% for the +Si treatment. The area under spot blotch progress curve, number of lesions per cm² of leaf area, and real disease severity significantly decreased by 62, 36 and 43.5% in +Si treatment. There was no significant effect of Si on lesion size. The role played by total soluble phenolics in the increased resistance to spot blotch of plants from both cultivars supplied with Si was not clear. Plants from cultivar BR‐18 supplied with Si showed the highest values for concentration of lignin‐thioglycolic acid derivatives during the most advanced stages of fungus infection. Chitinase activity was high at the most advanced stages of fungus infection on leaves from both cultivars supplied with Si and may have had an effect on fungus growth based on the reduction of the components of resistance evaluated. Peroxidase activity was found to be high only at 96 h after inoculation of both cultivars supplied with Si. Polyphenoloxidase activity had no apparent effect on resistance regardless of Si treatments. Results revealed that supplying Si to wheat plants can increase resistance against spot blotch.     

The influence of plant growth regulators and storage on root induction and growth in <Emphasis Type="Italic">Pelargonium zonale</Emphasis> cuttings

The effects of post harvest application of ethylene, abscisic acid (ABA), indole-3-butyric acid (IBA) treatments or dark storage on root induction and continued growth of regenerated roots in Pelargonium cuttings were investigated using hydroponics in the greenhouse. Ethylene markedly increased rooting percentage in ‘Greco’ and ‘Surfing’, reduced the number of roots per cutting in ‘Surfing’ and had no effect on the total root lengths in the two cultivars. Ethylene treatment reduced fresh root mass in ‘Surfing’, increased dry root mass and reduced root water content in both cultivars. ABA (50 μM) enhanced rooting percentage in ‘Greco’, reduced the number of roots per cutting, reduced total root lengths and fresh root mass in both cultivars. ABA increased dry root mass and reduced root water content in ‘Surfing’ but this effect was not apparent in ‘Greco’. Storing cuttings in the dark for 4 days had no effect on rooting percentage and number of roots per cutting in ‘Greco’ and ‘Surfing’. However, dark storage reduced total root lengths in ‘Surfing’ and reduced fresh root mass in ‘Greco’. Dark storage had no effect on dry root mass and water content in both cultivars. Applying 4 μl l⁻¹ IBA in the rooting solution induced maximum (100%) root induction in ‘Surfing’. However, IBA reduced the number of roots per cutting in ‘Greco’, reduced total root lengths and fresh root mass in the two cultivars. IBA treatment profoundly increased and reduced dry root mass and root water content, respectively, in ‘Greco’ and ‘Surfing’. The enhanced root induction observed after IBA and ABA applications could be ascribed to their influence on ethylene biosynthesis, since ethylene treatment increased rooting percentage in both cultivars. However, high ABA (100 μM) and IBA (12 μl l⁻¹) levels or dark storage reduced the ability of induced roots to continue growth. We attribute our results to plant stress-response mechanism and ethylene appears to play an important role in the process of root initiation and root growth in Pelargonium cuttings.     

Role of auxins, polyamines and ethylene in root formation and growth in sweet orange

The primary objective of this work was to investigate the role of polyamines (PAs) on root formation and growth in two sweet orange (Citrus sinensis L. Osb.) cultivars Pineapple and Pêra. Adventitious shoots (30-d-old) derived from epicotyl explants were transferred to root induction medium containing Murashige and Skoog salts at different strengths and supplemented with different concentrations and combinations of auxins. Root formation and development decreased in both sweet orange cultivars concomitant with the reduction of medium strength. The α-naphtaleneacetic acid was important during the root differentiation phase, but its combination with indole-3-butyric acid was essential for root elongation. The addition of PAs significantly improved root formation and/or growth, depending on their concentration, whereas the presence of inhibitor of PAs biosynthesis α-difluoromethylornithine (DFMO) inhibited these processes. The rooting impairment caused by DFMO was partially reversed by the supplementation of putrescine. Aminoethoxyvinylglycine AVG and AgNO₃ also inhibited in vitro rooting in both sweet orange cultivars, indicating that ethylene was likewise important for rhizogenesis in sweet orange.     

Results of long-term field studies into the effect of strobilurin containing fungicides on the production of mycotoxins in several winter wheat varieties

In total, 23 field trials have been performed during the past 5 years to assess the effect of strobilurin containing fungicides on mycotoxin production in winter wheat. In 85% of the plots, the treatment with strobilurins at growth stages before blossom increased the content of deoxynivalenol in comparison with untreated controls. This effect was intensified by treatments at BBCH stage 45–49 and could be demonstrated in a great number of various cultivars. Application of strobilurin containing fungicides at early growth stages seems to be a risk factor for mycotoxin formation in wheat, especially under favourable conditions forFusarium infections. Presented at the 26^th Mykotoxin-Workshop in Herrsching. Germany, May 17–19, 2004     

Synthesis and antituberculosis activity of derivatives of <Emphasis Type="Italic">Stevia rebaudiana</Emphasis> glycoside steviolbioside and diterpenoid isosteviol containing hydrazone,hydrazide, and pyridinoyl moieties

Conjugates of the antituberculosis drug isoniazid (isonicotinyl hydrazine) and isomeric hydrazides of nicotinic and α-picolinic acid with glycoside steviolbioside from the Stevia rebaudiana plant and the product of its acid hydrolysis, diterpenoid isosteviol, were synthesized. In addition, isosteviol hydrazide and hydrazone derivatives as well as conjugates containing two isosteviol moieties joined by a dihydrazide linker were obtained. The parental compounds and their synthetic derivatives were found to inhibit the in vitro growth of Mycobacterium tuberculosis (H₃₇R_V). The measured minimal concentrations of stevio-side and steviolbioside, at which the growth of M. tuberculosis was inhibited by 100% (MIC), were 7.5 and 3.8 μg/ml, respectively. MIC values for steviolbioside and isosteviol conjugates with hydrazides of pyridine carbonic acid were within the ranges of 5–10 and 10–20 μg/ml, respectively. The maximal inhibitory effect against M. tuberculosis was shown by the isosteviol conjugates with adipic acid dihydrazide (MIC 1.7 and 3.1 μg/ml). Antituberculosis activities of the tested compounds were higher than the activity of antituberculosis drug Pyrizanamide (MIC 20 μg/ml) but lower than that of antituberculosis drug isoniazid (MIC 0.02–0.04 μg/ml).