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21	Le pathosystème Lin (Linum usitatissimum) - Fusarium oxysporum : Impact du champignon et d'un agent de biocontrôle sur des réponses moléculaires de la plante et le développement de la fusariose / Flax (Linum usatissimum) - Fusarium oxysporum pathosystem : Impact of the pathogen and a biocontrol agent on plant molecular responses and Fusarium wilt development Planchon, Aline 18 December 2018 (has links) Le lin, principale plante à fibres cultivée en France possède un intérêt industriel pour la qualité de ses fibres. Les cultures de lin sont régulièrement attaquées par un champignon tellurique, Fusarium oxysporum f. sp. lini (Fol), responsable des plus grandes pertes dans les cultures de lin. Les PGPR (Plant Growth Promoting Rhizobacteria) sont des bactéries réputées pour leurs capacités à améliorer la croissance et le développement des plantes, mais également pour leur pouvoir compétiteur au sein de la rhizosphère et leur aptitude à induire une réponse immunitaire chez les plantes. Parallèlement, l’utilisation de SDP (Stimulateur des Défenses des Plantes), molécules capables d’éliciter les mécanismes de défenses des plantes est une autre alternative pour limiter l’utilisation des pesticides. Dans le cadre de ce projet mené sur deux variétés de lin, Aramis et Mélina, il a pu être montré que Fol induisait un remodelage de la paroi au niveau des racines et des tiges, impliquant les hémicelluloses et les pectines, seulement deux jours après inoculation avec le champignon. L’utilisation de la souche ATCC 6633 de Bacillus subtilis comme agent de biocontrôle a permis de réduire de façon significative l’apparition des symptômes de la fusariose. Il a également été montré qu’en plus d’avoir un effet fongicide sur Fol, cette bactérie est capable d’induire l’expression de deux gènes de défense (Pathogenesis-Related) codant pour une β-(1,3)-glucanase (PR-2) et codant pour une chitinase-like (CTL-10), de gènes impliqués dans la voie des phénylpropanoïdes (PHENYLALANINE AMONIA LYASES, PAL-3 et PAL-4) et dans le remodelage pariétal (PECTIN METHYLESTERASE-3, PME-3) au niveau racinaire. Des analyses biochimiques ont également permis de montrer que B. subtilis provoque des modifications se traduisant par un renforcement pariétal au niveau des tiges chez les deux variétés. Enfin, l’association de la PGPR avec une molécule élicitrice (pregnénolone sulfate) a eu un effet synergique sur l’expression de gènes de défense. / In France, flax (Linum usitatissumum) is a principal fibers crop. Fusarium oxysporum f sp lini (Fol), a soil-borne fungus, is responsible for the major losses in crop yield. PGPR (Plant Growth Promoting Rhizobacteria) are known for their abilities to promote plant growth and health. These bacteria are also good competitors in the rhizosphere and can induce a plant defense response. The use of compounds able to elicit plant defense mechanisms is also an alternative to limit the use of pesticides. In this project, it has been shown that F. oxysporum f. sp. lini induces only two days after inoculation cell wall remodeling in the root and the stem involving hemicelluloses and pectins on two flax varieties, Aramis and Mélina, . The use of the Bacillus subtilis strain ATCC 6633 as biocontrol agent significantly reduced fusarium wilt appearance. In addition to its antifungal effect against Fol, this bacteria is able to induce the expression of two Pathogenesis-Related genes coding for a β-(1,3)-glucanase (PR-2) and a chitinase-like (CTL-10), genes involved in the phenylpropanoid pathway (PHENYLALANINE AMONIA LYASES, PAL-3 and PAL-4) and also in cell wall remodeling (PECTIN METHYLESTERASE-3, PME-3) in the root. Biochemical analyses show that B. subtilis causes modifications resulting in cell wall reinforcement in the stem in both varieties. Finally, the association of B. subtilis with an elicitor (pregnenolone sulfate) had a synergistic effect on the expression of defense-related genes. Linum usitatissimum (lin) Plant Growth Promoting Rhizobacteria Bacillus subtilis Paroi cellulaire Gènes de défense Linum usitatissimum (flax) Plant Growth Promoting Rhizobacteria Bacillus subtilis Cell wall Defense genes Plant defense stimulator 632.96
22	Induced systemic resistance against Pythium aphanidermatum by plant growth-promoting rhizobacteria on cucumber (Cucumis sativus L.) Chen, Chunquan, 1958- January 1998 (has links) Cucumber root rot caused by Pythium aphanidermatum can be suppressed by introduced plant growth-promoting rhizobacteria (PGPR). Preliminary experiments clarified that this root disease could be suppressed by strains of Pseudomonas aureofaciens, P. corrugata, and P. fluorescens. To determine whether the mechanism was a systemic resistance induced by PGPR, a split root technique was employed on greenhouse cucumbers grown in soilless substrates. On the split roots, bacteria which were introduced into one side of the root were completely separated from pathogen challenged-inoculated roots-on the other side of the roots. Results from the series of experiments conducted with this design demonstrated that (i) the resistance against root rot induced by PGPR was systemic, (ii) germination of P. aphanidermatum zoospores was reduced in extracts from bacterized roots compared to non-treated control, and (iii) spread of Pythium mycelia was delayed and zoospore germination was inhibited on the distant induced root, compared to the non-bacterized control. Furthermore, enzyme analysis indicated that phenylalanine ammonia lyase, peroxidase and polyphenoloxidase increased on cucumber roots two days after they were bacterized with Pseudomonas strains 13 or 63--28. When the bacterized roots were challenged with P. aphanidermatum, these plant defense enzymes increased as the symptoms appeared, but this accumulation of enzymes was not any higher on roots induced with each of the Pseudomonas strains compared to the Pythium inoculated control. This enzyme stimulation was also systemically induced by PGPR or P. aphanidermatum on cucumber roots. The patterns of iso-peroxidase induced with the PGPR and P. aphanidermatum treatments were different. High levels of salicylic acid (SA) accumulated in bacteria-induced roots, as well as in pathogen-infected roots, which suggests that SA may be associated with cucumber resistance response. But exogenous application of SA did not induce any systemi Root rots. Plant growth-promoting rhizobacteria.
23	Biological control and plant growth promotion by selected trichoderma and Bacillus species. Yobo, Kwasi Sackey. January 2005 (has links) Various Trichoderma and Bacillus spp. have been documented as being antagonistic to a wide range of soilborne plant pathogens, as well as being plant growth stimulants. Successes in biological control and plant growth promotion research has led to the development of various Trichoderma and Bacillus products, which are available commercially. This study was conducted to evaluate the effect of six Trichoderma spp. and three Bacillus spp. and their respective combinations, for the biological control of Rhizoctonia solani damping-off of cucumber and plant growth promotion of dry bean (Phaseolus vulgaris L.). In vivo biological control and growth promotion studies were carried out under greenhouse and shadehouse conditions with the use of seed treatment as the method of application. In vitro and in vivo screening was undertaken to select the best Trichoderma isolates from 20 Trichoderma isolated from composted soil. For in vitro screening, dual culture bioassays were undertaken and assessed for antagonisms/antibiosis using the Bell test ratings and a proposed Invasive Ability rating based on a scale of 1-4 for possible mycoparasitic/hyperparasitic activity. The isolates were further screened in vivo under greenhouse conditions for antagonistic activity against R. solani damping-off of cucumber (Cucumis sativus L.) cv. Ashley seedlings. The data generated from the in vivo greenhouse screening with cucumber plants were analysed and grouped according to performance of isolates using Ward‟s Cluster Analysis based on a four cluster solution to select the best isolates in vivo. Isolates exhibiting marked mycoparasitism of R. solani (during ultrastructural studies) viz, T. atroviride SY3A and T. harzianum SYN, were found to be the best biological control agents in vivo with 62.50 and 60.06% control of R. solani damping-off of cucumber respectively. The in vitro mode of action of the commercial Trichoderma product, Eco-T®, and Bacillus B69 and B81 suggested the production of antimicrobial substances active against R. solani. In vitro interaction studies on V8 tomato juice medium showed that the Trichoderma and Bacillus isolates did not antagonise each other, indicating the possibility of using the two organisms together for biological control and plant growth promotion studies. Greenhouse studies indicated that combined inoculation of T. atroviride SYN6 and Bacillus B69 gave the greatest plant growth promotion (43.0% over the uninoculated control) of bean seedlings in terms of seedling dry biomass. This was confirmed during in vivo rhizotron studies. However, results obtained from two successive bean yield trials in the greenhouse did not correlate with the seedling trials. Moreover, no increase in protein or fat content of bean seed for selected treatments was observed. In the biological control trials with cucumber seedlings, none of the Trichoderma and Bacillus combinations was better than single inoculations of Eco-T®, T. atroviride SY3A and T. harzianum SYN. Under nutrient limiting conditions, dry bean plants treated with single and dual inoculations of Trichoderma and Bacillus isolates exhibited a greater photosynthetic efficiency that the unfertilized control plants. Bacillus B77, under nutrient limiting conditions, caused 126.0% increase in dry biomass of bean seedlings after a 35-day period. Nitrogen concentrations significantly increased in leaves of plants treated with Trichoderma-Bacillus isolates. However, no significant differences in potassium and calcium concentrations were found. Integrated control (i.e. combining chemical and biological treatments) of R. solani damping-off of cucumber seedlings proved successful. In vitro bioassays with three Rizolex® concentrations, viz., 0.01g.l-1, 0.1g.l-1 and 0.25g.l-1 indicated that the selected Trichoderma isolates were partly sensitive to these concentrations whereas the Bacillus isolates were not at all affected. In a greenhouse trial, up to 86% control was achieved by integrating 0.1g.l-1 Rizolex® with T. harzianum SYN, which was comparable to the full strength Rizolex® (1g.l-1) application. Irrespective of either a single or dual inoculations of Trichoderma and/or Bacillus isolates used, improved percentage seedling survival as achieved with the integrated system, indicating a synergistic effect. The results presented in this thesis further reinforce the concept of biological control by Trichoderma and Bacillus spp. as an alternative disease control strategy. Furthermore, this thesis forms a basis for Trichoderma-Bacillus interaction studies and proposes that the two organisms could be used together to enhance biological control and plant growth promotion. / Thesis (Ph.D.)-University of KwaZulu-Natal, Pietermaritzburg, 2005. Bacillus (Bacteria) Trichoderma. Seedlings--Diseases and pests. Growth (Plants) Plant growth-promoting rhizobacteria. Theses--Plant pathology.
24	Involvement of Beneficial Microbe-derived Cyclodipeptides (CDPs) in Promoting Plant Tolerance to Abiotic Stresses abdulhakim, fatimah 07 1900 (has links) Cyclodipeptides (CDPs) are the smallest, most stable cyclic peptides that are synthesized as secondary metabolites by bacteria. The aim of this study was to investigate the effect of the Pseudomonas argentinensis (SA190) and four (CDPs), named as cis-cyclo-(Pro-Phe) (Cyclo2), cis-cyclo-(Pro-Leu) (Cyclo3), cis-cyclo-(Pro-Tyr) (Cyclo4) and cis-cyclo-(Pro-Val) (Cyclo5), with three concentrations (1µM, 100nM, and 10nM), on the growth of Arabidopsis thaliana under normal plant growth conditions [1/2MS media], salt conditions [125 mM NaCl] and drought conditions [25% PEG]. Moreover, we determined the most effective CDPs with optimal concentration. It was found that cis-cyclo-(Pro-Tyr) (Cyclo4) at a concentration of 100nM had an effect on the plant growth and can mimic the effect of SA190 under normal [1/2MS media] conditions. Also, cis-cyclo-(Pro-Tyr) (Cyclo4) at a concentration of 1µM can mimic the effect of SA190 under salt conditions [125mM NaCl]. Finally, cis-cyclo-(Pro-Val) (Cyclo5) at a concentration of 1µM can mimic the effect of SA190 under drought conditions [25% PEG]. cyclodipeptides Cyclic dipeptides Beneficial microbes Pseudomonas argentinensis SA190 plant tolerance to abiotic stresses
25	Induced systemic resistance against Pythium aphanidermatum by plant growth-promoting rhizobacteria on cucumber (Cucumis sativus L.) Chen, Chunquan, 1958- January 1998 (has links) No description available. Plant growth-promoting rhizobacteria. Root rots.
26	Characterisation of rhizobacterial communities of Eucalyptus species and hybrids Patrick, Melanie January 2013 (has links) Thesis (M. Tech. (Agriculture)) -- Central University of Technology, Free State, 2013 / ntroduction: Good quality Eucalyptus is of importance to South Africa’s pulp and paper industry. Limited land is available for forestry, therefore Eucalyptus with genotypes for good pulp and paper qualities, particularly hybrids, are bred and cloned via cuttings. Although these Eucalyptus clones keep the favourable genotypes in the population, many have difficulty with rooting. Research has shown that rhizobacteria can improve rooting. Thus, one strategy to enhance the rooting of cuttings is to use rhizobacterial preparations. The aim of this study was to characterise rhizobacterial communities of Eucalyptus hybrid and species and identify possible plant-growth promoting rhizobacteria (PGPR). Materials and methods: Rhizospheric samples were collected from Eucalyptus hybrids and species. The rhizobacterial communities were characterised using fatty acid methyl esters (FAME) analysis and denaturing gradient gel electrophoresis (DGGE). DGGE fragments were further sequenced to identify rhizobacteria. Results and discussion: FAME analysis successfully achieved a broad characterisation of the Eucalyptus hybrid and species rhizobacterial communities based on their fatty acid composition. Myristic acid (C14:0) was the most abundant fatty acid. DGGE profiles gave a molecular profile of the Eucalyptus hybrid and species rhizobacterial communities based on their DNA composition. Nitrosomona eutropha was present in all samples which illustrates a nitrogen-rich environment. Adhaenbacter aquaticus was unique to the better rooting Eucalyptus hybrid GU111. Conclusion: This study provided some insight into the diversity of rhizobacterial communities of Eucalyptus hybrids and species. Possible PGPR were identified and the observation made that the nature of the soil environment changes with the aging of the associated host. These findings allow further investigation into the formulation of potential rhizobacterial preparations for rooting enhancement of Eucalyptus cuttings. Eucalyptus Breeding Eucalyptus - Clones Plant cuttings - Rooting Plant communities - Rhizobacteria Plant growth-promoting rhizobacteria
27	Evaluation of diazotrophic bacteria as biofertilizers. Kifle, Medhin Hadish. 22 September 2014 (has links) Inoculation with diazotrophic bacteria is well documented as a means to enhance growth and increase yields of various crops, especially when used as an alternative or a supplement to the use of nitrogenous fertilizers and agrochemicals for sustainable agriculture. Nitrogen is the most limiting nutrient for increasing crop productivity, and the use of chemical sources of N fertilizers is expensive, and may contribute to environmental pollution. Therefore, there is a need to identify diazotrophic inoculants as an alternative or supplement to N-fertilizers for sustainable agriculture. The search for effective diazotrophic bacterial strains for formulation as biofertilizers has been going on for over 40 years and a number of inoculant biofertilizers have been developed and are commercially available. In the current study, 195 free-living diazotrophic bacteria were isolated from soils collected from the rhizosphere and leaves of different crops in different areas within the KwaZulu-Natal Province, Republic of South Africa. Ninety five of the isolates were selected for further screening because they were able to grow on N-free media using different carbon sources. Isolates that were very slow to grow on N-free media were discarded. Of these, 95 isolates were screened in vitro for growth promotion traits tests including tests for ammonia production and acetylene reduction. The best 20 isolates that were also able to reduce acetylene into ethylene were selected for growth-promotion trials on maize under greenhouse conditions. Of the 20 isolates, ten isolates enhanced (P = 0.001) growth of maize above the Un-inoculated Control. Molecular tests were conducted to identify the ten most promising isolates selected in the in vitro study. In the greenhouse study, these diazotrophic isolates were screened for their ability to enhance various growth parameters of maize (Zea mays L.), following various inoculation techniques (drenching, seed treatment, foliar spray and combination of these). Inoculations with the five best diazotrophic isolates by various methods of application increased dry weight and leaf chlorophyll content (P < 0.001, P = 0.001), respectively, compared to the Untreated Control. Although, all methods of application of diazotrophic inoculants used in this study resulted in increased dry weight and leaf chlorophyll content, combined methods of application (seed treatment + drenching) and sole application (seed treatment) were significantly more (P < 0.05) efficient. The best five most promising isolates were identified for growth promotion of maize under greenhouse conditions. They were also assessed for their effects on germination of wheat in vitro and were further tested in combination with various levels of nitrogenous fertilizer for growth-promotion of wheat (Triticum aestivum L.). These five isolates were also investigated for their potential to enhance growth and yields of maize and wheat crops in field trials, when combined with a low dose of nitrogenous fertilizer. These isolates were further studied for their contribution for enhancing plant growth through nitrogen fixation by predicting N content in leaves using a chlorophyll content meter (CCM-200) and correlated to extractable chlorophyll level at R2 = 0.96. In this study, relative to the Un-inoculated Control, the best five isolates enhanced growth of maize and wheat when combined with a 33% N-fertilizer levels for a number of growth parameters: increased chlorophyll levels and heights of maize, shoot dry weight of maize and wheat; and enhanced root and shoot development of these crops in both greenhouse and field conditions. The best contributions of diazotrophic bacteria was achieved by Isolate LB5 + 0% NPK (41%), V9 + 65% NPK (28.9%), Isolate L1 + 50% NPK (25%), Isolate L1 + 25%NPK (22%) and LB5 + 75% NPK (15%) undergreenhouse conditions. At 30 or 60 DAP, isolates with 33%N-fertilizer caused relatively higher dry weight than the 100%NPK. Inoculation of Isolate StB5 without 33N% fertilizer cuased significant (P<0.005) increases in stover dry weight. In field studies, inoculation of diazotrophic bacteria alone or with 33%N-fertilizer resulted in relatively greater increases of dry weight, stover dry weight, number of spikes and yield at different growth stages higher than the Un-inoculated or Unfertilized Control. However, the increases were not statistically significant. The use of microbial inoculants in combination with low doses of nitrogenous fertilizers can enhance crop production without compromising yields. The isolates obtained in this study can effectively fix nitrogen and enhance plant growth. The use of microbial inoculants can contribute to the integrated production of cereal crops with reduced nitrogenous fertilizer inputs, as a key component of sustainable agriculture. / Ph.D. University of KwaZulu-Natal, Pietermaritzburg 2013. Biofertilizers. Plant growth-promoting rhizobacteria. Microbial inoculants. Crops--Growth. Nitrogen--Fixation. Nitrogen fertilizers. Theses--Plant pathology. Biological nitrogen fixation. Plant growth-promotion. Diazotrophs. N-fertilizer.
28	Untersuchungen zum Einfluss spezieller Rhizosphärenbakterien auf Pflanzenwachstum und Fusarium spp.-Toleranz bei Spargel (Asparagus officinalis L.) Lord, Fritz 02 December 2002 (has links) Der Einfluss der Rhizosphärenbakterien Bacillus subtilis FZB 24, FZB 37, FZB 42, Bacillus pumilus RK 13 und Streptomyces graminofaciens und des Algenpräparates Goemar Fruton Spezial® (Ascophyllum nodosum) auf Wachstum, Ertrag und Toleranz gegenüber Fusarium spp. bei Spargel wurde untersucht. Es wurden mehrjährige Parzellenfeldversuche und Modellversuche unter kontrollierten Bedingungen mit natürlich Fusarium spp. belasteten Böden und mit speziellen Fusarium Erregern inokulierten Substraten durchgeführt. Die Analyse des verwendeten Nachbaubodens ergab eine wesentlich höhere Kontamination mit Fusarium spp. (56%) in Relation zum Fruchtfolgeboden (14%). F. oxysporum war die dominante Fusariumart. Desweiteren wurde eine ganze Reihe anderer Arten, wie z.B. F. acuminatum, F. culmorum, F. proliferatum und F. culmorum bestimmt, was die Komplexität der Wurzel- und Stängelfäuleerkrankung belegt. Analog zu diesem Ergebnis konnten im Vergleich zur Fruchtfolgevariante von den in dem Nachbauboden kultivierten Spargelpflanzen signifikant mehr Fusarium spp. (80%) isoliert werden. Das Wurzelwachstum war hier extrem reduziert. Unter diesen konduktiven Bedingungen gelang es durch Rhizombakterisierung (107 cfu/ml) mit B. subtilis FZB 42, eine signifikante Förderung des Wurzelwachstums relativ zur unbehandelten Kontrolle und zur B. subtilis FZB 37 Variante zu erzielen. In Pathogenitätstests konnten F. culmorum, F. oxysporum und F. proliferatum als bedeutende Spargelpathogene mit signifikant reduzierter Trieb- und Wurzelmasse nachgewiesen werden, während F. acuminatum nur geringe Symptome verursachte. Eine bakterielle Saatgutbeizung (108 cfu/ml) und zusätzliche präinfektionelle Gießapplikation (107 cfu/ml) konnte eine Infektion mit F. oxysporum f.sp. asparagi nicht verhindern. Dennoch waren die negativen Effekte im Vergleich mit der nicht bakterisierten Kontrolle in den B. subtilis Varianten FZB 24 und vor allem bei FZB 42 deutlich kompensiert. Diese Ergebnisse lassen vermuten, dass eine Resistenz- bzw. Toleranzinduktion ein potentieller Wirkmechanismus der Bakterien ist. In den Feldversuchen erbrachte eine Bakterisierung einjähriger Rhizome (107 cfu/ml) zur Pflanzung und ergänzende Gießbehandlungen (108 cfu/ml/1l/m) in den folgenden 2 Jahren eine tendenzielle Reduzierung der Trieblänge und des Triebdurchmessers, insbesondere in Kombination mit dem Algenpräparat. Einen eindeutigen Einfluss auf das Sortierungsergebnis konnte nicht nachgewiesen werden. Im Gegensatz hierzu resultierte eine Saatgutbakterisierung mit B. subtilis FZB 24 in einem generell geförderten Triebwachstum und einer signifikant gesteigerten Wurzelentwicklung. Auch die anderen Mikroorganismen erbrachten eine tendenzielle Wuchsförderung. Es konnte eine gesicherte Korrelation zwischen Wurzelmasse und Knospenanzahl ermittelt werden. Blattapplikationen mit Goemar Fruton Spezial® während der Hauptvegetationsphase hatten keinen Einfluss auf das Pflanzenwachstum. / The effects of the rhizobacteria Bacillus subtilis, Strain FZB 24, FZB 37and FZB 42, Bacillus pumilus RK 13, Streptomyces graminofaciens N6 and the alga Ascophyllum nodosum (Goemar Fruton Spezial®) on plant growth, yield and Fusarium spp. tolerance of Asparagus officinalis (L.) were investigated. The trials were carried out under field conditions over sev-eral years by sawing and planting and as pot trials in the greenhouse and climate chamber with soil naturally infested with Fusarium spp. and with steamed substrates inoculated with particularly Fusarium species. Asparagus replant soil was considerable higher infested with Fusarium spp. (56 %) than fresh soil without asparagus history (14 %). F. oxysporum was the most determined Fusarium species followed by F. redolens, F. acuminatum, F. culmorum, F. proliferatum, F. solani a.o.. That indicates the complex character of root and crown rot of asparagus. From asparagus plants cultivated in replant soil a significant higher rate of Fusarium isolations (80 %) could be worked out compared to the fresh soil treatment. The root growth in the contaminated soil was extremely reduced. In these conductive situation bacterial treatments with B. subtilis FZB 42 done as rhizom soaking (107cfu/ml) resulted in significantly increased root growth up to 32, 9 % related to the non treated control. B. subtilis FZB 37 was ineffective. F. oxysporum, F. culmorum and F. proliferatum showed a high pathogenicity to asparagus seedlings, manifested in significantly reduced fresh and dry weights of shoots and roots, while F. acuminatum caused only slight symptoms. None of the tested microorganisms applicated as seed coating (108 cfu/ml) and substrate drenching before pathogen inoculation (107 cfu/ml) could prevent seedlings from being infected by F. oxysporum f. sp. asparagi. The negative effects of infection are significantly compensated by Bacillus subtilis FZB 42 and FZB 24. The results support the conclusion, that induced tolerance is a potential mechanism of bacterial mode of action. Under field conditions rhizom bacterization of one year old asparagus plants (107 cfu/ml) before planting and additional soil drenching (108 cfu/ml/1,5l/m) during the following two years reduced shoot length, shoot diameter and yield, especially in combination with Goemar Fruton Spezial®. There was no remarkable influence on spear quality. Seed coating with B. subtilis FZB 24 (108 cfu/ml) and a soil drenching (108 cfu/ml/1l/m) in summer however re-sulted in higher shoots and significantly increased fresh weight and dry substance of roots. But also the other tested microorganisms showed a plant growth promoting trend. There was a significant positive correlation between root fresh weight and number of buds. By spraying the phylloclads four times during the main vegetation season the alga application only gave a slight improvement of plant growth in the field trials. Rhizosphärenbakterien Bacillus subtilis Spargel Bacillus pumilus Streptomyces Fusarium Bacillus subtilis Asparagus Bacillus pumilus Streptomyces Fusarium Plant Growth Promoting Rhizobacteria 630 Landwirtschaft, Veterinärmedizin 39 Landwirtschaft, Garten ddc:630
29	Acessando o microbioma da rizosfera de cana-de-açúcar em cultivo orgânico comparado ao convencional / January 2019 (has links) Resumo: O cultivo intensivo agrícola, apesar de altamente produtivo, possui diversos pontos questionáveis, como suplementação acentuada de insumos sintéticos, além da aplicação de defensivos para o controle de pragas que muitas vezes são danosos ao meio ambiente. Como alternativa, a agricultura orgânica propõe uma forma de manejo menos agressiva, que promove o uso sustentável dos recursos naturais renováveis, como o aproveitamento de resíduos orgânicos, além de possuir um maior valor agregado no produto final. No presente estudo, investigamos por meio de uma abordagem metagenômica os efeitos do manejo (orgânico ou convencional) na microbiota da rizosfera de cana-de-açúcar, região da planta que notoriamente causa um grande impacto no seu desenvolvimento e produtividade. Identificamos a abundância maior na rizosfera com manejo orgânico de porções genômicas que codificam enzimas associadas ao metabolismo do nitrogênio e enxofre, sendo que estes são nutrientes fundamentais para o sucesso da planta e assim, seu desenvolvimento e produtividade em campo. Contraditoriamente, encontramos também que os genomas da microbiota orgânica possuem conteúdo ligado a um potencial mais acentuado para a degradação de compostos xenobióticos, que são ativamente aplicados no manejo convencional. De acordo com nossa predição, os microrganismos dessa microbiota poderiam realizar sua completa mineralização, o que é muito favorável na remoção desses resíduos no ambiente. Esses achados indicam que há um potencia... (Resumo completo, clicar acesso eletrônico abaixo) / Abstract: Modern industrialized agriculture although highly productive, has several sustainability problems such as the for intense supplementation of synthetic inputs, beyond the application of pesticides for pest control. Which are often harmful to environment. As an alternative to this system, organic agriculture is considered more environmentally progressive, having several characteristics favorable to the crop producer, promotes sustainable use of renewable natural resources, such as the use of organic waste, besides that a higher aggregated value in the final product. This study investigates the changes that an organic system brings when compared to conventional management for the sugarcane rhizosphere microbiome, a plant region known to be determinant of plant development and associated with net productivity, using a metagenomic approach. We identified a higher abundance of genomic portions which encode enzymes associated with nitrogen and sulphur metabolism, which are fundamental nutrients for plant success and subsequently, crop productivity. Conversely, we also found that genomes of the organic microbiome contain higher portions linked to xenobiotic degradation, compounds that are actively applied in conventional management. Microorganisms from this sequenced microbiome could perform complete mineralization of these damaging compounds, which is desirable in their removal from the environment. These findings indicate that there is a unique potential for exploitation of organic... (Complete abstract click electronic access below) / Mestre Metagenômica. Rizosfera. Cana-de-açúcar. Ecologia microbiana. Whole-metagenome shotgun plant-associated microbiome plant growth promoting rhizobacteria
30	Evaluation of selected free-living diazotrophic bacteria for plant growth promotion and biological control of damping-off fungi. Otanga, R.R.N. 21 November 2013 (has links) Inoculation with free-living diazotrophic bacteria is well documented to enhance vegetative growth and yield increases of various crops coupled with suppression of sublethal pathogens. The use of microbial inoculants has been identified as an alternative or supplement to use of nitrogenous fertilizers and agrochemicals for sustainable agriculture. The search for effective free-living diazotrophic bacterial strains for formulation as biofertilizers has been on going since the 1970’s and a number of inoculant biofertilizers have been developed and are commercially available. In the current study, 250 free-living diazotrophic bacteria were isolated from soils collected from the rhizosphere and leaves of different crops in different areas within KwaZulu-Natal, province, Republic of South Africa. These were evaluated for plant growth-promotion and biological control of damping-off fungi initially by in vitro screening. The growth promotion traits tested included, phosphate-solubilization, production of indole-3-acetic acid, production of ammonia and acetylene reduction. Biocontrol traits evaluated included siderophore-production, antibiosis, and production of hydrogen cyanide (HCN). Biochemical and molecular bioassay tests were conducted to identify the twenty most promising isolates selected in the in vitro study. The twenty isolates were further tested in combination with various levels of nitrogenous fertilizer for growth-promotion of maize (Zea mays L.) and wheat (Triticum aestivum L.) under greenhouse conditions. The five most promising isolates identified for growth promotion under greenhouse conditions for each crop were assessed for their effects on the germination of maize in vitro and growth and yields of two maize and two wheat cultivars, when combined with a low dose of nitrogenous fertilizer in field trials. The five Bacillus subtilis (Ehrenberg) Cohn isolates that suppressed the growth of a wide range of pathogenic fungi in vitro were tested for their efficacy against damping-off of wheat caused by Rhizoctonia solani Kühn in the greenhouse. These isolates were further studied for their modes of action against R. solani in vitro. The modes of action tested included antibiosis, production of siderophores, extracellular enzymes, production of hydrogen cyanide (HCN) and antibiotic resistance. The twenty most promising bacterial isolates identified from the in vitro screening reduced acetylene to ethylene, produced indole-3-acetic acid and siderophores, one isolate solubilized phosphate, and 9 inhibited the growth of R. solani. These twenty isolates enhanced growth of maize and wheat above the Uninoculated Control under greenhouse conditions. The growth enhancements varied with bacterial isolate x crop species interactions, which identified five different isolates for each of the two crops. Relative to the Uninoculated Control, the best five isolates significantly (P = 0.001) enhanced the growth of maize and wheat at all fertilizer levels for a number of growth parameters: increased chlorophyll levels and heights of maize, shoot dry biomass of maize and wheat, and enhanced root development of maize in the greenhouse. Inoculation of maize and wheat with the two most promising isolates identified from the field trial for each crop, in combination with 65% and 50% of the recommended amount of nitrogenous fertilizer for maize and wheat, respectively, caused the same increases in shoot biomass as the Fully Fertilized Control. Application of a combination of the best bacterial isolates and 35% nitrogenous fertilizer resulted in the same or greater shoot dry biomass and yields of both maize and wheat under field conditions. Shoot dry biomass of wheat increased by 75% above the Uninoculated Control and 30% above the Fully Fertilized Control. The wheat yield increased by 95% above the Uninoculated Control and 43% above the Fully Fertilized Control. Seed inoculation with the best isolates combined with 35% N increased yields of maize by 41% above the Uninoculated Control and 15% above the Fully Fertilized Control. The best isolates significantly (P < 0.001) increased plant height, chlorophyll levels and shoot biomass of maize relative to the Uninoculated Control. There was a positive correlation between chlorophyll level and yield, chlorophyll level and shoot dry biomass, height and shoot dry biomass and height and yield of maize at P = 0.01 with r values of 0.87, 0.77, 0.92 and 0.81, respectively. The isolates that exhibited multiple plant-growth promoting traits in vitro, increased shoot biomass of both maize and wheat in the greenhouse and field, and caused yield increases in the two crops under field conditions. Five B. subtilis isolates inhibited the growth of some of the pathogenic fungi tested in vitro up to 95%. Seed inoculation with the same isolates significantly (P = 0.001) suppressed R. solani damping-off of wheat under greenhouse conditions and exhibited multiple mechanisms of disease control in vitro. The use of microbial inoculants in combination with low doses of nitrogenous fertilizers can enhance crop production without compromising the yields. The B. subtilis isolates obtained in this study can effectively control R. solani damping-off of wheat, fix nitrogen and enhance plant growth. The use of microbial inoculants can contribute to the integrated production of cereal crops with reduced nitrogenous fertilizer inputs, as a key component of sustainable agriculture. Key words: Free-living bacteria; plant growth-promotion; diazotrophs; biological nitrogen fixation; phosphate-solubilization; siderophores; indole-3-acetic acid; biocontrol; damping-off / Thesis (Ph.D.)-University of KwaZulu-Natal, Pietermaritzburg, 2013. Growth (Plants) Plant growth-promoting rhizobacteria. Biofertilizers. Bacillus subtilis. Rhizoctonia solani. Damping-off diseases. Theses--Plant pathology.

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