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121	Análise da expressão gênica diferencial causada pela interação de feijoeiros (Phaseolus vulgaris L.) e fungos micorrízicos arbusculares sob efeito de déficit hídrico / Differential gene expression analysis induced by the interaction between common beans (Phaseolus vulgaris L.) and arbuscular mycorrhizal fungi under drought Recchia, Gustavo Henrique 04 December 2015 (has links) A seca é um dos principais problemas que afetam a produção do feijoeiro. A despeito da importância de caracteres fenotípicos radiculares, muitos dos esforços de melhoramento genético da cultura tem focado na seleção de cultivares com maior produção de grãos. A simbiose estabelecida entre plantas e FMA aumentam o potencial de captação de água no solo através das extensas redes formadas pelas hifas e alteram vias metabólicas vitais para a manutenção das relações hídricas da planta. O modelo de interação feijoeiro (BAT 477) colonizado por uma mistura de FMA (Glomus clarum, Acaulospora scrobiculata e Gigaspora rosea) foi submetido a um déficit hídrico de 96 h durante o pré-florescimento. O transcritoma global de raízes inoculadas e não-inoculadas, sujeitas ou não à seca, foi comparado por RNA-Seq. Um conjunto de 71 transcritos foram induzidos por FMA durante a seca. Comparando-se os tratamentos estresse e controle, 12.086 unigenes foram regulados em plantas inoculadas e 11.938 em não-inoculadas, refletindo o alto potencial de tolerância da linhagem BAT 477 e indicando que a presença de FMA produz uma regulação fina no perfil de expressão de genes regularmente envolvidos na resposta da planta ao estresse. Foram selecionados 15 fatores de transcrição e seus perfis de expressão foram caracterizados por RT-qPCR tomando-se três períodos, 48, 72 e 96 h de déficit hídrico. Plantas inoculadas ativaram a expressão destes genes mais tardiamente (após 72 h), refletindo melhorias nas condições hídricas da planta que adiam a percepção do estresse. Adicionalmente, a expressão de 23 transcritos foi avaliada em três amostras teciduais diferentes obtidas por microscopia de microdissecção a laser. Glucan 1,3 ?-Glucosidase e PIP2,3, foram detectados somente em células do córtex radicular contendo arbúsculos indicando uma possível indução tecido específica dependente da presença dos fungos. Análises complementares apontaram a regulação de 171 unigenes envolvidos na resposta das FMA ao estresse. Estes resultados validam a hipótese inicial de que a inoculação com FMA altera os perfis de expressão de genes vitais para a resposta da planta ao déficit hídrico / Drought is one of the main problems that affect common bean\'s production. Despite the importance of root fenological characters, breeding efforts for the culture have focused on the selection of cultivars for grain yield. The symbiosis stablished between AMF and plants enhances the potential of water absorption from the soil through an extensive net formed by hyphae and alters vital metabolic pathways involved in the maintenance of the water relations in plants. The interaction model common bean (BAT 477) colonized by a mixture of AMF (Glomus clarum, Acaulospora scrobiculata and Gigaspora rosea) was exposed to a water deficit regime of 96 h during pre-flowering. Global transcriptome from inoculated and non-inoculated roots, exposed or not to drought, were compared through RNA-Seq. A set of 71 transcripts was induced by AMF during drought. Comparing both stress and control treatments, 12,086 unigenes were regulated in inoculated plants, and 11,938 in non-inoculated, reflecting the great tolerance potencial of the lineage BAT 477 and indicating that the presence of AMF produces a fine tune regulation on the expression of genes regularly involved on the drought response of the plant. It was selected 15 transcription factors and their expression profiles were characterized through RT-qPCR taking 3 periods, 48, 72 and 96 h of water deficit. AM plants activated earlier (after 72 h) the expression of these genes, reflecting improvements on the water conditions of the plant that delay the stress perception. Additionally, the expression of 23 transcripts was evaluated on three different tissue samples obtained through laser microdissection microscopy. Glucan 1,3 ?-Glucosidase and PIP2,3, were detected only in cortical cells containing arbuscules, pointing to a possible tissue specific induction dependent of the presence of the fungus. Additional analysis point to the regulation of 171 unigenes involved on the response of the AMF to drought. These results corroborate the initial hypothesis that the inoculation with AMF alters the gene expression profiles of genes that are vital for water deficit response in plants Arbuscular Mycorrhizal Fungi Drought Fungos micorrízicos arbuculares Phaseolus vulgaris Phaseolus vulgaris Seca Transcriptome Transcritoma
122	Minhocas, fungos micorrízicos arbusculares e bactérias diazotróficas em mudas de Araucaria angustifolia / Interactions between invasive earthworms, arbuscular mycorrhizal fungi and diazotrophic bacteria and native araucaria pine seedling performance Priscila Trigo Martins Azevedo 10 May 2010 (has links) A Araucaria angustifolia possui alto valor madeireiro e resinífero, é fonte de alimento e espécie característica da Floresta Ombrófila Mista, um ecossistema rico em espécies endêmicas e detentor de alta diversidade. Devido à intensa exploração durante décadas, atualmente a araucária é considerada espécie em perigo crítico de extinção, sendo fundamental a compreensão deste ecossistema para sua preservação e regeneração. As minhocas, os fungos micorrízicos arbusculares (FMA) e as bactérias diazotróficas são organismos edáficos que desempenham funções essenciais no processo de ciclagem de nutrientes e podem favorecer o desenvolvimento vegetal. Muitos trabalhos avaliam o efeito de cada um destes organismos separadamente, mas o estudo das interações entre eles é escasso. Portanto, este trabalho teve como objetivo avaliar o efeito da inoculação de minhocas invasoras Amynthas corticis, do FMA Gigaspora rosea e de um isolado de bactéria diazotrófica sobre o desenvolvimento de mudas de araucária, considerando suas interações. O experimento foi realizado em vasos, em casa de vegetação, sob delineamento em blocos casualizados, em esquema fatorial 2x2x2, sendo: presença e ausência de minhoca (A. corticis), presença e ausência de FMA (G. rosea), e presença e ausência de bactéria diazotrófica (isolado S32274), com oito repetições cada, sendo que a metade dos vasos foi avaliada 150 dias após o transplantio (Época 1) e o restante aos 250 dias após o transplantio (Época 2) das mudas de araucária. Os parâmetros de avaliação foram: altura e diâmetro das plantas, massa seca das raízes e da parte aérea, concentração e conteúdo total de nitrogênio e fósforo da parte aérea, densidade de esporos de G. rosea no substrato, taxa de colonização radicular pelo FMA e sobrevivência, reprodução e massa fresca das minhocas. A biomassa e o conteúdo de N e P das plantas foram afetados pela interação dos organismos. A inoculação de G. rosea propiciou melhor desenvolvimento das mudas de araucária, entretanto, não houve efeito significativo da inoculação de somente diazotróficos. As plantas inoculadas com minhocas apresentaram tendência de menor biomassa e a sobrevivência das minhocas foi baixa. O estudo das interações de microrganismos e macrofauna deve ser considerado na pesquisa e desenvolvimento de práticas de manejo mais sustentáveis para reflorestamento e manutenção de florestas de araucária. / Araucaria angustifolia is a tree of high lumber and resin values, a source of food, and the most important tree in the Mixed Subtropical Ombrophilous forest, a rich ecosystem with many endemic species. However, due to intense exploration for decades, the Araucaria is presently considered a critically endangered species, and the understanding of this ecosystem is fundamental for conservation and regeneration purposes. Soil organisms such as earthworms, arbuscular mycorrhizal fungi (AMF) and diazotrophic bacteria play an essential role in nutrient cycling and can increase plant performance. Many studies have evaluated the impact of each of these organisms independently, but few have studied their interactions. Therefore, the aim of this study was to evaluate the inoculation effects of invasive earthworms (Amynthas corticis), AMF (Gigaspora rosea) and an isolated of diazotrophic bacteria, and the interactions between each of these, on the performance of A. angustifolia seedlings. The plants were grown in greenhouse conditions in a block-type randomized design with a factorial layout of 2x2x2, being: presence and absence of earthworms (A. corticis), presence and absence of AMF (G. rosea) and presence and absence of diazotrophic bacteria (isolated S32274), in eight replicates, evaluated at 150 and 250 d after transplanting. The following parameters were evaluated: plant height and diameter, shoot and root biomass, shoot nutrient content (P, N), number of AMF spores, root mycorrhizal colonization rate and earthworm survival, reproduction and fresh biomass. Plant biomass and shoot nutrient content were affected by the three-way interaction of earthworms, AMF and bacteria. AMF inoculation enhanced A. angustifolia performance, while bacterial inoculation alone had no significant effect on plants and earthworms had low survival rates and tended to reduce plant biomass. Microbial-faunal interactions can lead to important changes in plant growth and should be considered in future research and development of sustainable Araucaria forest management practices. Fixação de nitrogênio Florestas Fungos micorrízicos Oligochaeta Pinheiro Rizosfera. Forest Fungi Mycorrhizal Nitrogen fixation Oligochaeta Pine Rhizosphere.
123	Biotic Filtering in Endophytic Fungal Communities Ricks, Kevin Daniel 01 June 2018 (has links) Plants can be colonized by complex communities of endophytic fungi. This thesis presents two studies, both of which investigate biotic filtering in endophytic fungal communities. Chapter 1. Endophytic fungi can be acquired horizontally via propagules produced in the environment such as in plant litters of various species. Given that litters from different plant species harbor distinct endophytic fungal communities and that endophytic fungi may be dispersal-limited, the structure of the endophytic fungal community of a given plant may be determined by proximity to particular inoculum sources. Community assembly may also be affected by biotic filtering by the plant. Therefore, a plant may be able to select particular fungal taxa from among the available pool. In that case, the structure of the endophytic fungal community in the plant could be somewhat independent of the structure of the inoculum community. We tested the hypothesis that biotic filtering of endophytic fungal communities occurs in Bromus tectorum by exposing it to a variety of inoculum sources including litters from several co-occurring plant species. The inoculum sources differed significantly from each other in the structures of the communities of endophytic fungi they harbored. We characterized the structures of the resulting leaf and root endophytic fungal communities in Bromus tectorum using high-throughput sequencing. All tested inoculum sources successfully produced complex communities of endophytic fungi in Bromus tectorum. There was significantly more variation in the structures of the communities of endophytic fungi among the inoculum sources than in the resultant endophytic fungal communities in the leaves and roots of Bromus tectorum. These results suggest that biotic filtering by Bromus tectorum played a significant role in the assembly of the endophytic fungal communities in tissues of Bromus tectorum. Because endophytic fungi influence plant fitness, it is reasonable to expect there to be selective pressure to develop a uniform, desirable endophytic fungal community even from disparate inoculum sources via a process known as biotic filtering. Chapter 2. Frequently one finds that different plant species harbor communities that are distinct. However, the nature of this interspecific variation is not clear. We characterized the endophytic fungal communities in six plant species from the eastern Great Basin in central Utah. Four of the species are arbuscular mycorrhizal (two in the Poaceae and two in the Asteraceae), while the other two species are nonmycorrhizal (one in the Brassicaceae and one in the Amaranthaceae). Our evidence suggests that both host mycorrhizal status and phylogenic relatedness independently influence endophytic fungal community structure. community assembly biotic filtering endophytic fungi mycorrhizal fungi natural selection phylogeny Biology
124	Relationship between organogenesis differentiation and histolocalization of selected alkaloids in duboisia myoporoides R. Br. Khanam, Nurussaba, University of Western Sydney, Faculty of Informatics, Science and Technology January 1999 (has links) The cultured tissues and organs of Duboisia myoporoides, an endemic medicinal plant of Australia, were investigated with the aim of establishing a relationship between organogenesis, differentiation and alkaloid localization. Histological analyses explained the relationship between cell arrangement in the cultured tissues and organs and the cytokinin/auxin combinations used at the callus induction stage. The cultured tissues and organs were analysed histochemically to localize alkaloids in different types of cells by using selected alkaloid colour reagents i.e., platinic chloride (5%) and iodoplatinate. The presence or absence of nicotine, hyoscyamine and scopolamine in the cultured tissues and organs was then confirmed by GC-MS analysis. This is the first work to show that tropane alkaloid formation in the separated cultured organs is related to xylem differentiation and tropane alkaloid formation in the calli cultured in suspension may allow commercial tropane alkaloid production without regenerating the organs. The roots of the D. myoporoides field-grown trees were colonized by the AM fungi and the mycorrhizal infection was ranged from 0-30% which indicates that the secondary metabolite atropine and scopolamine did not prevent AM fungal colonization. / Doctor of Philosophy (PhD) alkaloid xylem tropane duboisia myoporoides organogenesis calli fungi medicinal plant mycorrhizal infection
125	Role of the ericoid mycorrhizal fungus Hymenoscyphus ericae in arsenate resistance of Calluna vulgaris at contaminated mine sites Sharples, Jade, University of Western Sydney, Nepean, Faculty of Science and Technology, School of Science January 2000 (has links) Calluna vulgaris L.Hull readily colonises arsenate contaminated mine spoil soils in south-west(SW)England.At these sites, it forms mycorrhizal association with the ericoid ascomycete fungus Hymenoscyphus ericae. The initial aim of this study was to investigate the physiological response of H.ericae populations to arsenate.Mine site populations were found to have evolved arsenate resistance in comparison to the heathland population.This research demonstrates the evolution of arsenate resistance through an enhanced arsenite efflux in populations of H.ericae from As contaminated mine spoil soils. H.ericae also confers arsenate resistance to C.vulgaris. The ecological significance of these findings is discussed. / Doctor of Philosophy (PhD) molecular biology mycorrhizal fungi Hymenoscyphus ericae arsente resistance Calluna vulgaris contamination of mine sites (England)
126	Pinus elliottii var. densa Seedling Performance Reflects Ectomycorrhizas, Soil Nutrient Availability and Root Competition Wyss Lozano Hoyos, Tania 15 December 2010 (has links) Ectomycorrhizas generally improve seedling mineral nutrition and growth, so I hypothesized that decline of the Florida native pine variety Pinus elliottii var. densa Little & Dorman is related to deficiency of appropriate ectomycorrhizal (ECM) fungi in the pine's native flatwoods. At Archbold Biological Station I examined how quickly ECM fungi colonize P. elliottii var. densa seedlings and I compared the effect of local absence versus presence of adult pines on ECM colonization and pine seedling performance. Under controlled greenhouse conditions, I investigated how a wide range of ECM colonization and spread of extraradical mycelium throughout a large volume of relatively infertile, flatwoods soil enhance the mineral nutrition and growth of pine seedlings. In a field bioassay, I transplanted two-month-old pine seedlings to three flatwoods sites with low (4 pines/400 square m), medium (9 pines/400 square m), and high (19 pines/400 square m) adult pine densities. I subsequently excavated seedlings every two weeks for four-and-a-half months and determined their ECM colonization, response to shade, and response to surrounding grass density. Across all sites, pine seedlings in high shade had a higher mean chlorophyll concentration and lower stem dry weight than in full sun. Competition with grass reduced seedling survival and stem dry weight. Initial colonization was rapid and not different among sites, with 5.4 % of roots colonized 15 days after transplant. Pine seedlings had midpoint means of 29.5 %, 18.1 % and 21.3 % ECM root tips in low, medium and high adult pine density sites, respectively, suggesting that pine seedlings establishing in flatwoods encounter sufficient ECM fungi to support their growth, regardless of adult pine density. In a field experiment, I determined in the presence versus absence of adult pines if pine seedlings had higher ECM colonization and consequent improved survival, mineral nutrition, and growth. Within and beyond pine stands, I transplanted seedlings into intact or drilled, hyphae in-growth pipes buried in the ground. I placed autoclaved or fresh ECM root inoculum in two sets of intact pipes, and autoclaved inoculum in drilled pipes into which mycorrhizal hyphae could extend from the surrounding vegetation. Seven-and-a-half months after transplant, ECM hyphae had penetrated the drilled pipes and colonized pine seedlings, but roots from the surrounding vegetation also penetrated pipes. Extraneous roots reduced the survival of seedlings both within and beyond pine stands, but extraneous roots reduced seedling growth only beyond pine stands. Because percentage ECM root tips was higher in the presence (53 %) than in the absence (38.8%) of adult pines, pine stands might benefit the competitive ability of seedlings by increased ECM colonization and possibly by common mycorrhizal networks connecting seedlings to adults. Because beneficial effects of ECM in the field were small, I also examined ECM effects on pine seedlings in a greenhouse experiment. I manipulated ECM fungus colonization and the volume of flatwoods soil to which extraradical mycelium had access. In a small volume of soil (220 mL), fresh ECM root inoculum promoted the mycorrhizal colonization of seedlings versus those receiving autoclaved roots, but seedling growth and uptake of Mg, Ca, and Zn was lower with fresh than with autoclaved root inoculum. Growth and mineral nutrient uptake likely was enhanced by a pulse of nutrients from autoclaved roots, but for inoculated plants may have been reduced because of nutrient retention by saprotrophic microorganisms degrading fresh ECM roots and because of mineral nutrient retention by ECM fungi. Ectomycorrhizal seedlings with extraradical mycelium access to a large soil volume had higher mean chlorophyll concentration than those in a small soil volume. Weekly disturbance of the extraradical mycelium, however, reduced foliar contents of Mn, K, P, N, and Zn by one-third to one-half, and reduced needle dry weight of seedlings by one-third, demonstrating the importance of extraradical mycelium accessing a large volume of soil when it is nutrient-poor. My research demonstrates that ECM fungi are widespread in flatwoods and rapidly colonize pine seedlings. ECM fungus inocula are greater in the presence than in the absence of adult pines, and ECM or seedlings' connections to a common mycorrhizal network improve seedlings' belowground competitive ability. ECM especially enhance seedling mineral nutrition and growth when undisturbed, extraradical mycelium extends throughout a large volume of soil. Populations of Pinus elliottii var. densa might best regenerate in flatwoods if seedlings recruit near adult pines and where there is little competition for light, water, and mineral nutrients. Rotated In-growth Core South Florida Slash Pine Mutualism Mycorrhizal Inoculum Potential
127	Morphology and diversity of arbuscular mycorrhizal fungi colonizing roots of dandelion and chive Li, Yang 22 January 2008 Arbuscular mycorrhizas (AM) are the plant root-fungus interactions that are most widespread mycorrhiza in nature. As classically defined, there are two major AM morphologies named after the plant genera in which they were first described: Arum- (intercellular hyphae with arbuscules mainly in inner root cortex), Paris- (extensive hyphal coils in outer root cortex), as well as intermediate morphotypes. In this study, dandelions and chives harvested in Saskatoon (SK, Canada) were examined for AM colonization and morphological types. A Multiple Quantitation Method (MQM) was used for assessing fungal colonization intensity using magnified epifluorescence images of lactofuchsin stained roots, plus details analyzed by high-resolution confocal fluorescence imaging. The results showed that host plants harbored diverse endorhizal fungi, including arbuscular mycorrhizal fungi (AMF), septate endophytes (SE) and fine endophytes (FE), with varying abundances. The soil properties were assessed with respect to P status, organic matter and pH, but there was no correlation with the fungal abundance in this study. Both dandelion and chive roots had Arum- and Paris-type AM. In order to assess the applicability of a current model, I studied quantitative relationship between the cell packing pattern and AM morphotype. Cross sections of host roots were analyzed with Image J software to calculate the proportion of air spaces. The abundance of arbuscules (Arum-type) and hyphal coils (Paris-type) were significantly different in chive and dandelion roots. However, there was no difference in the proportion of air spaces in the inner or outer cortex. Therefore, host root cell packing does not appear to influence AM morphotype at least in the samples in this study. AM fungal diversity was preliminarily investigated by nested PCR with group specific primers, showing multiple PCR bands within root samples, and indicating the potential complexity of AMF groups. Further work to sequence the PCR products is needed to elucidate the AMF groups present. Arum- Paris- Arbuscular mycorrhizal fungi root cell packing confocal epifluorescence microscopy
128	Optimal seeding rates for organic production of field pea and lentil Baird, Julia 30 August 2007 There are no seeding rates established for organic production of field pea and lentil in Saskatchewan and organic producers must rely upon rates recommended for conventional production of these crops. These seeding rates may not be suitable for organic production as the two systems differ in the use of inputs and in pest management. The objectives of this study were to determine an optimal seeding rate for organic production of field pea and lentil in Saskatchewan considering a number of factors, including yield, weed suppression, soil nitrogen (N) and phosphorus (P) concentrations, soil water storage, colonization of crop roots by arbuscular mycorrhizal fungi (AMF), plant P uptake, and profitability. A field experiment was conducted to determine the optimal seeding rates of field pea and lentil. Field pea seeding rates were 10, 25, 62, 156 and 250 plants m-2 and lentil seeding rates were 15, 38, 94, 235 and 375 plants m-2. Sites were established at Vonda, Vanscoy and Delisle, SK using a randomized complete block designs with summerfallow and green manure treatments included for each crop. Seed yield increased with increasing seeding rate for both crops, up to 1725 kg ha-1 for field pea and 1290 kg ha-1 for lentil. Weed biomass at physiological maturity decreased with increasing seeding rate for both crops. In field pea, weeds were reduced in weight by 68%, while lentil reduced weed biomass by 59% between the lowest and highest seeding rates. <p>Post-harvest soil phosphate-P levels did not change consistently between treatments, indicating that there was no trend in soil P concentration with seeding rate. Post-harvest soil inorganic N, however, was higher for the summerfallow and green manure treatments than for the seeding rate treatments in both crops. Inorganic N was higher at some sites for the highest two seeding rates in field pea. Soil water storage following harvest was not affected by treatment.<p>Colonization of crop roots by AMF increased for lentil with increasing seeding rate, but the same trend was not observed in field pea. A growth chamber experiment to study the rate of colonization of field pea between 10 and 50 d after emergence did not show any differences in AMF colonization between seeding rates. Colonization levels were high (70 to 85%) for both crops in both the field and growth chamber. Arbuscular mycorrhizal fungi colonization and seeding rate had no effect on plant P concentration for either field pea or lentil. Both crops became increasingly profitable as seeding rate increased. Field pea reached a maximum return at 200 plants m-2 and lentil return increased to the highest seeding rate of 375 plants m-2. Organic farmers should increase seeding rates of these crops to increase returns and provide better weed suppression. soil inorganic nitrogen organic farming soil phosphorus arbuscular mycorrhizal fungi weed management phosphorus uptake
129	Effect of <i>Arbuscular mycorrhizal</i> fungi and plant growth-promoting rhizobacteria on glomalin production Adeleke, Adekunbi Basirat 15 September 2010 There is accumulating evidence that arbuscular mycorrhizal fungi (AMF) produce a glycoprotein called glomalin, which has the potential to increase soil carbon (C) and nitrogen (N) storage, thereby reducing soil emissions of carbon dioxide (CO2) and nitrous oxide (N2O) into the atmosphere. However, other soil microorganisms such as plant growth-promoting rhizobacteria (PGPR) that interact with AMF could indirectly influence glomalin production. The objectives of this study were to determine the effects of AMF and PGPR interactions on glomalin production and identify possible combinations of these organisms that could enhance C and N storage in the rhizosphere. The effects of AMF and PGPR interactions on pea (Pisum sativum L.) growth and correlations between glomalin production and plant growth also were assessed.<p> A series of growth chamber and laboratory experiments were conducted to examine the effect of fungal and host plant species on glomalin production by comparing the amounts of glomalin produced by Glomus clarum, G. intraradices, and G. mosseae in association with corn (Zea mays L.), in addition to examining differences in the ability of corn, pea, and wheat (Triticum aestivum L.) to support glomalin production by G. intraradices. There were no significant differences in glomalin production [measured in the rhizosphere as Bradford-reactive soil protein (BRSP)] by the three AMF species, whereas host plant significantly affected glomalin production. Specifically, higher BRSP concentrations were found in the rhizosphere of corn as compared to pea and wheat.<p> Additionally, the effect of long-term storage on the growth promoting traits of the PGPR strains selected; namely, Pseudomonas cepacia R55 and R85, P. aeruginosa R75, P. putida R105, and P. fluorescence R111 were investigated. These bacterial strains previously had been identified as PGPR, but had since undergone approximately twenty years of storage at -80¢ªC; thus, it was necessary to confirm that these strains had retained their plant growth promoting characteristics. Apparently, long-term storage had no significant adverse effect on the PGPR strains as all strains increased the total biomass of wheat significantly and demonstrated antagonism against fungal pathogens.<p> The possibility that spore-associated bacteria (SAB) could influence AMF associations, thereby affecting glomalin production, and subsequent crop yield potential was assessed. This was achieved by first isolating bacteria from disinfested spores of the AMF species and determining their potential as PGPR for wheat. According to fatty acid methyl ester (FAME) profiles, four genera of bacteria were isolated from AMF spores namely; Arthrobacter, Bacillus, Micrococcus, and Paenibacillus, of which Bacillus species were the most common SAB. None of these isolates, however, showed growth promoting abilities on wheat.<p> Based on the preliminary findings, the combined effects of the three AMF species and the five PGPR strains were examined on plant growth and glomalin production under gnotobiotic conditions using pea as the host plant. Interactions between G. intraradices and R75, R85, or R105 resulted in increased BRSP concentration in the mycorrhizosphere of pea. Additionally, significant interactions were observed between the AMF species and PGPR strains on BRSP concentration in pea rhizosphere under non-sterile conditions. As observed under sterile conditions, the co-inoculation of pea with G. intraradices and R75 or R85 increased BRSP concentrations in the rhizosphere of pea grown in non-sterile soil, although interaction effects were not significantly different from the control or when G. intraradices was applied alone. Significant AMF and PGPR interactions were observed to affect AMF colonization; however, the combination of these organisms did not significantly affect pea growth, nutrient uptake, and C and N storage in the plant rhizosphere. No correlations were detected between glomalin-related soil protein (GRSP), pea growth, nutrient concentrations in the plant tissue, and soil organic C and N content. This study demonstrated that although the potential exists to manipulate certain AMF and PGPR to enhance glomalin production, co-inoculation of AMF and PGPR did not enhance plant growth or C and N storage beyond that achieved by inoculation of either organism. glomalin-related soil protein arbuscular mycorrhizal fungi plant growth-promoting rhizobacteria
130	Optimal seeding rates for organic production of field pea and lentil Baird, Julia 30 August 2007 (has links) There are no seeding rates established for organic production of field pea and lentil in Saskatchewan and organic producers must rely upon rates recommended for conventional production of these crops. These seeding rates may not be suitable for organic production as the two systems differ in the use of inputs and in pest management. The objectives of this study were to determine an optimal seeding rate for organic production of field pea and lentil in Saskatchewan considering a number of factors, including yield, weed suppression, soil nitrogen (N) and phosphorus (P) concentrations, soil water storage, colonization of crop roots by arbuscular mycorrhizal fungi (AMF), plant P uptake, and profitability. A field experiment was conducted to determine the optimal seeding rates of field pea and lentil. Field pea seeding rates were 10, 25, 62, 156 and 250 plants m-2 and lentil seeding rates were 15, 38, 94, 235 and 375 plants m-2. Sites were established at Vonda, Vanscoy and Delisle, SK using a randomized complete block designs with summerfallow and green manure treatments included for each crop. Seed yield increased with increasing seeding rate for both crops, up to 1725 kg ha-1 for field pea and 1290 kg ha-1 for lentil. Weed biomass at physiological maturity decreased with increasing seeding rate for both crops. In field pea, weeds were reduced in weight by 68%, while lentil reduced weed biomass by 59% between the lowest and highest seeding rates. <p>Post-harvest soil phosphate-P levels did not change consistently between treatments, indicating that there was no trend in soil P concentration with seeding rate. Post-harvest soil inorganic N, however, was higher for the summerfallow and green manure treatments than for the seeding rate treatments in both crops. Inorganic N was higher at some sites for the highest two seeding rates in field pea. Soil water storage following harvest was not affected by treatment.<p>Colonization of crop roots by AMF increased for lentil with increasing seeding rate, but the same trend was not observed in field pea. A growth chamber experiment to study the rate of colonization of field pea between 10 and 50 d after emergence did not show any differences in AMF colonization between seeding rates. Colonization levels were high (70 to 85%) for both crops in both the field and growth chamber. Arbuscular mycorrhizal fungi colonization and seeding rate had no effect on plant P concentration for either field pea or lentil. Both crops became increasingly profitable as seeding rate increased. Field pea reached a maximum return at 200 plants m-2 and lentil return increased to the highest seeding rate of 375 plants m-2. Organic farmers should increase seeding rates of these crops to increase returns and provide better weed suppression. soil inorganic nitrogen organic farming soil phosphorus arbuscular mycorrhizal fungi weed management phosphorus uptake

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