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Resumen El déficit hídrico constituye una severa limitación a la productividad agrícola. En el marco de la producción sostenible de cultivos, la biotecnología microbiana está cobrando relevancia para aumentar la tolerancia a la sequía y mejorar el rendimiento de los cultivos en condiciones adversas. El propósito de este trabajo fue comparar la acción de la cepa de Azospirillum argentinense Az19, con tolerancia in vitro a estresores abióticos, con la cepa Az39, utilizada ampliamente para la formulación de inoculantes comerciales, al inocularlas en plantas sometidas a déficit hídrico. Se realizaron ensayos de invernadero y de campo. En invernadero, la cepa Az19 evitó el impacto adverso del déficit hídrico en el estadio V2 sobre el crecimiento del maíz. Además, el porcentaje de plantas con espigas y el peso de la espiga disminuyó significativamente con la restricción hídrica aplicada en V2 y en floración en plantas inoculadas con la cepa Az39, pero no en las inoculadas con Az19. En el primer ensayo de campo con el maíz híbrido comercial DOW DS 515 PW las plantas inoculadas con Az19 fueron las que mejor toleraron la deficiencia hídrica. En el segundo ensayo de campo se utilizaron dos genotipos de maíz con sensibilidad diferencial a la sequía. La inoculación con Az19 condujo a una mayor tolerancia al déficit hídrico, con un efecto detectable en algunos componentes del rendimiento en el genotipo sensible. Sobre la base de estos resultados, proponemos el empleo de A. argentinense Az19 para la formulación de inoculantes basados en Azospirillum especialmente indicados para áreas agroecológicas que experimenten períodos de déficit hídrico.
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The demand for chemical fertilizers in agriculture has increased to deal with the present global population increase. However, the excessive use of chemical fertilizers can be reduced by applying biofertilizers as an eco-friendly tool. Plant growth-promoting rizobacteria (PGPR) has an essential need in terms of fertilizer savings and promoting plant yield. Here, we study the effect of using three (PGPR) bacterial strains “Bacillus nakamurai MSRH1, Bacillus pacificus MSRH3, Paenibacillus polymyxa MSRH5”, integrated with chemical fertilizers (40, 60, 80, 100% need based NPK) on vegetative growth, yield production, and quality of table grapes ‘Flam Seedless’ grown in sand soil during two successive seasons of 2020 and 2021, with a preliminary trial season in 2019. Our results show that amending grapes with NPK in combination with the consortium of three strains led to significant improvement in colonized vines compared to a single application of 100% NPK. Results showed that bacterial consortium combined with 80% and 60% NPK mineral fertilizer had more positive effects than un-inoculated vines in growth parameters, cluster characteristics, yield/vine and berry quality in the two growing seasons. Besides, N, P and K concentrations of leaf petiole, total leaf chlorophyll content, and carbohydrates in canes were significantly enhanced by bacteria consortium with 80% and 60% PK chemical fertilizers. PGPR significantly increased total bacterial count, N2-fixing, P- solubilizing and K-solubilizing bacteria in soil treated with the three strains of bacteria plus mineral fertilizer. In addition, dehydrogenase and phosphatase activity in the rhizosphere soil were also increased in treatments inoculated with strains plus mineral fertilizer. The field study results showed that PGPR approach has potential and can be considered as a crop management strategy to increase the yield and quality of grapes, reduce chemical fertilization and subsequent environmental pollution, and could be useful in terms of sustainable production.
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Two endophytic bacterial isolates were obtained from root nodules of clover plants grown in salt affected clay soil of Egypt. The isolates were closely linked to Stenotrophomonas maltophilia strains IPR-Pv696 and 262XG2 based on the sequencing and phylogenetic analysis of 16S rRNA genes, and deposited in GenBank with accession numbers OM980221.1 (AM1) and OM980223.1 (AM2) respectively. The isolates were evaluated for their potential to promote plant growth. The results revealed that the two isolates of S. maltophilia strains (IPR-Pv696 and 262XG2) respectively exhibited production for indole-3- acetic acid (30.26 & 31.15 µg/ml), exopolysaccharides (13.57 & 13.68 g/l), nitrogen fixation activity and they solubilize the phosphate (278 & 208 mg/l) and potassium (33.5 & 32.9 µg/ml). In a field trial, these two isolates increased clover plant growth, chlorophyll, carbohydrates content and nutrients uptake while lowering proline levels. Hence this highlights its application to be exploited as biofertilizer by leading to sustainable agriculture. This could be a promising inoculant for many other crops.
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Microorganisms in close association with the roots of plants can enhance plant growth, through nitrogen fixation (NF) and phosphorus solubilization (PS). Although the type of microbes in close association with different plants varies, their population and genetic capabilities is affected by several factors. Therefore, in this study, the plant growth promoting properties of rhizobacteria present in the rhizosphere of two cassava varieties (Sweet cassava US, bitter cassava ST) indigenous to Iyamho community was explored. The samples were analyzed for total culturable heterotrophic bacteria community and the obtained isolates were screened for NF and PS abilities using a semi-solid N-free medium and Pikovaskya agar respectively. The bacterial population in both agar medium varied, however, the bacterial counts on Luria Bertani (3.67 x 105, 3.35 x 106) was higher than Nutrient agar (2.73 x 105, 2.68 x 105) after incubation for 24 hours at 37oC for sweet and bitter cassava rhizosp here respectively. Also, isolates from sweet cassava had the highest bacteria count in both Nutrient agar and Luria Bertani agar. A total of sixteen isolates were obtained, six phosphate solubilizers, five nitrogen fixers, and five without traits for either NF or PS. The Gram-negative bacterial group was more dominant across all isolates while the dominant genus was Bacillus. This study indicates that the nitrogen fixers and phosphate solubilizers are major constituents of the rhizomicrobe of cassava plants although the distribution varies across cassava varieties. However, sweet cassava rhizosphere harbored more nitrogen-fixing bacteria while both varieties had the same amount of phosphate solubilizing rhizobacteria.
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Aloe vera is among the world's economically most important medicinal plants, but as the growth of this plant and, consequently, the accumulation of metabolites is slow, we tested the hypothesis that root endophytic bacteria isolated from A. vera plants can promote growth and increase the accumulation of aloin in the gel and latex. For this, we inoculate seedlings with four endophytic bacteria and a combination of them. We confirmed the hypothesis and identified two strains with potential for the formulation of inoculants to improve the cultivation of A. vera. The bacterium 149H Paraburkholderiasp. increases the number of leaves and the accumulation of biomass, but on the other hand, 35V Enterobacter ludwigii inoculation increased the content of aloin in the gel and in the latex. Further research should focus on the association of these two strains in a single inoculant, to both promote growth and increase the synthesis of metabolites.
Aloe vera se encuentra entre las plantas medicinales económicamente más importantes del mundo, pero como el crecimiento de esta planta y, en consecuencia, la acumulación de metabolitos es lento, probamos la hipótesis de que las bacterias endofíticas de raíces aisladas de las plantas de A. vera pueden promover el crecimiento y aumentar la acumulación de aloína en el gel y látex. Para ello, inoculamos plántulas con cuatro bacterias endofíticas y una combinación de ellas. Confirmamos la hipótesis e identificamos dos cepas con potencial para la formulación de inoculantes para mejorar el cultivo de A. vera. La bacteria 149H Paraburkholderia sp. aumenta el número de hojas y la acumulación de biomasa, pero, por otro lado, la inoculación con Enterobacter ludwigii 35V aumentó el contenido de aloína en el gel y en el látex. La investigación adicional debe centrarse en la asociación de estas dos cepas en un solo inoculante, tanto para promover el crecimiento como para aumentar la síntesis de metabolitos
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Aloe/crescimento & desenvolvimento , Endófitos/crescimento & desenvolvimento , Plantas Medicinais/crescimento & desenvolvimento , Aloe/parasitologiaRESUMO
Phloroglucinol or 2,4-diacetyl phloroglucinol (DAPG) is a polyketide compound produced by gram negative soil bacteria Pseudomonas. It shows broad spectrum antibacterial and antifungal properties against soil-borne plant pathogens. In Pseudomonas spp., genes for biosynthesis of 2,4-DAPG are localized in phlABCD operon. All the four genes in phlABCD operon are indispensable and DAPG synthesis is attenuated even in the absence of one of the genes. In the present study, we identified and cloned phlC gene from an Indian strain of Pseudomonas and analyzed its sequence. The structural details ofthe PHLC protein was generated by three-dimensional homology modelling. Additionally, stereo-chemical properties of PHLC were analyzed by Ramachandran plot analysis and the generated model was validated by PDBsum. Our results demonstrate that the cloned PHLC protein contains structural features typical of a condensing enzyme involved inpolyketide synthesis.
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Salinity in agricultural soil is a severe problem that affects the growth and production in numerous crops all over the world. The country's salt?affected land is estimated to be 6.74 million hectares. According to estimates, approximately 10% more land is becoming salinized each year, and by 2050, nearly half of all arable land will be contaminated by salt. Plants may have bacterial companions that shield them from the negative consequences of salt stress (SS). Plant growth?promoting bacteria (PGPR) can minimize the usage of agrochemicals while also improving plant production, nutrition, and biotic–abiotic stress tolerance. The enzyme 1? aminocyclopropane?1?carboxylic acid deaminase (ACCD) is found in certain bacteria and works by degrading ACC (ethylene precursor in higher plants) into ??ketobutyrate and ammonia (NH ), thereby reducing the ACC levels, thus, inhibits excessive biosynthesis of3 ethylene under numerous stress circumstances. This is one of the most effective methods for inducing plant tolerance to SS. The current review highlighted the recent works of ACCD under SS environment. Further, the relevance of reducing the negative effect of ROS and increasing plant development under SS were also discussed. We propose a path for the community to employ beneficial microorganisms to boost agricultural yield and achieve sustainable development by highlighting plant?microbe interactions in this review.
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Abstract Quality evaluation of commercial inoculants is essential to warrant an adequate cropresponse to inoculation within a biosecurity framework. In this sense, this work is aimed at standardizing and validating the drop plate method for the enumeration of Azospirillum viable cellsas an alternative to the spread plate technique, which is currently proposed in the consensusprotocol of the REDCAI network. Between 14 and 25 private and public laboratories partici-pated in three independent trials. We obtained consistent and robust results that allowed toconfirm that both techniques are equivalent, concluding that the drop plate method is an alternative enumeration technique that is adequate to be included in the abovementioned consensusprotocol.
Resumen La evaluación de la calidad de los inoculantes comerciales es fundamental para garantizar una adecuada respuesta de los cultivos a la inoculación dentro de un marco de bioseguridad. En este sentido, el objetivo de este trabajo fue la estandarización y validación de la técnica de la microgota para la cuantificación de Azospirillum como metodología alternativa a la técnica de siembra en superficie, propuesta actualmente en el protocolo consenso de la Red de Calidad de Inoculantes, REDCAI. Entre 14 y 25 laboratorios, tanto privados como públicos, participaron de tres ensayos independientes. A partir de ellos se obtuvieron resultados reproducibles y robustos que permiten confirmar que ambas técnicas son equivalentes y concluir que la técnica de recuento por la microgota es una alternativa adecuada para ser incluida dentro del mencionado protocolo consenso.
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ObjectiveTo study the effects of different plant growth-promoting rhizobacteria (PGPR) on the growth of Paris polyphylla var. yunnanensis seedlings and the quality of its medicinal parts, in order to provide reference for the cultivation of high-quality P. polyphylla var. yunnanensis. MethodThe pot culture experiment at room temperature and the single-factor completely random design were employed for exploring the effects of five PGPR on physiological characteristics and inorganic elements of P. polyphylla var. yunnanensis. ResultThe results showed that the exogenous inoculation of different PGPR promoted the growth and development of P. polyphylla var. yunnanensis to varying degrees, delayed the senescence of leaves, and improved the medicinal value of new and old rhizomes. Compared with the non-inoculated control, the exogenous inoculation of compound microbial fertilizer (FH) and microbial agent Sanju Guanjin liquid (SJ) enhanced the root vigor, increased the content of photosynthetic pigments and the activities of anti-oxidant enzymes [superoxide dismutase (SOD), catalase (CAT), and peroxidase (POD)], and reduced the content of malondialdehyde (MDA) in leaves. Their inhibition rates against MDA were 10.46%-39.62% and 20.99%-53.12%, respectively. With the growth of P. polyphylla var. yunnanensis, the inhibition rate against MDA gradually increased, which effectively delayed the senescence of P. polyphylla var. yunnanensis leaves. In addition, the exogenous inoculation of different PGPR promoted the accumulation of nutrient elements in new and old rhizomes, lowered the heavy metal content to varying degrees, and improved the medicinal value of P. polyphylla var. yunnanensis rhizomes. ConclusionFH and SJ have exhibited the best promoting effect on the growth of P. polyphylla var. yunnanensis seedlings and also the best regulatory effect on the medicinal value of P. polyphylla var. yunnanensis rhizomes, which has provided reference for the application and promotion of PGPR in the growth of P. polyphylla var. yunnanensis.
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RESUMEN Los microorganismos son de gran interés porque colonizan todo tipo de ambiente, sin embargo, uno de los problemas al que nos enfrentamos para conocer su diversidad biológica es que no todos los microorganismos son cultivables. El desarrollo de nuevas tecnologías como la generación de vectores de clonación aunado al desarrollo de técnicas de secuenciación de alto rendimiento ha favorecido el surgimiento de una nueva herramienta llamada metagenómica, la cual nos permite estudiar genomas de comunidades enteras de microorganismos. Debido a que ningún ambiente es idéntico a otro, es importante mencionar que dependiendo del tipo de muestra a analizar será el tipo de reto al cual nos enfrentaremos al trabajar con metagenómica, en el caso específico del suelo existen diversas variantes como la contaminación del suelo con metales pesados o diversos compuestos químicos que podrían limitar los estudios. Sin embargo, pese a las limitaciones que el mismo ambiente presenta, la metagenómica ha permitido tanto el descubrimiento de nuevos genes como la caracterización de las comunidades microbianas que influyen positivamente en el desarrollo de plantas, lo cual en un futuro podría generar un gran impacto en la agricultura. En este artículo se realizó una revisión de diversas investigaciones que han empleado metagenómica, reportadas en las bases de datos de PudMed y Google Schoolar, con el objetivo de examinar los beneficios y limitaciones de las diversas metodologías empleadas en el tratamiento del ADN metagenómico de suelo y el impacto de la metagenómica en la agricultura.
ABSTRACT Microorganisms are of great interest because they colonize all types of environment, however, one of the problems we face in knowing biological diversity is that not all microorganisms are cultivable. The development of new technologies such as the generation of cloning vectors coupled with the development of high performance sequencing techniques, have favored the emergence of a new tool in science called metagenomics, which allows us to study genomes of entire communities. Since all environments are different, the type of challenge that we will face when working with metagenomics is going to change depending of the type of sample, in the specific case of soils, there are several variables, such as soil contamination with heavy metals or chemical compounds that could limit metagenomic studies. However, despite the limitations that the environment presents, with the help of metagenomics, both gene discovery and the characterization of microbial communities that positively influence plant development have been achieved, which could generate a greater impact on agriculture in the future. In this article a review of several investigations that have used metagenomics, reported in the PudMed and Google Schoolar databases was carried out, with the aim of examining the benefits and limitations of the various methodologies used in the treatment of metagenomic DNA from soil and the impact of metagenomics in agriculture.
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ABSTRACT Bacteria produce antimicrobial compounds to compete for nutrients and space in a particular habitat. Antagonistic interactions can be evaluated by several methodologies including the double-layer agar and simultaneous inhibition assays. Among the well-known inhibitory substances produced by bacteria are the broad-spectrum antibiotics, organic acids, siderophores, antifungal, and bacteriocins. The most studied bacterial genera able to produce these inhibitory substances are Enterococcus, Lactococcus, Streptomyces, Bacillus, Pseudomonas, Klebsiella, Escherichia, and Burkholderia. Some beneficial bacteria can promote plant growth and degrade toxic compounds in the environment representing an attractive solution to diverse issues in agriculture and soil pollution, particularly in fields with damaged soils where pesticides and fertilizers have been indiscriminately used. Beneficial bacteria may increase plant health by inhibiting pathogenic microorganisms; some examples include Gluconacetobacter diazotrophicus, Azospirullum brasilense, Pseudomonas fluorescens, Pseudomonas protegens, and Burkholderia tropica. However, most studies showing the antagonistic potential of these bacteria have been performed in vitro, and just a few of them have been evaluated in association with plants. Several inhibitory substances involved in pathogen antagonism have not been elucidated yet; in fact, we know only 1 % of the bacterial diversity in a natural environment leading us to assume that many other inhibitory substances remain unexplored. In this review, we will describe the characteristics of some antimicrobial compounds produced by beneficial bacteria, the principal methodologies performed to evaluate their production, modes of action, and their importance for biotechnological purposes.
RESUMEN Las bacterias producen compuestos antimicrobianos para competir por nutrientes y espacio en un hábitat particular. Las interacciones antagónicas pueden evaluarse mediante varias metodologías, incluido el agar de doble capa y los ensayos de inhibición simultánea. Las sustancias inhibidoras mejor conocidas producidas por bacterias incluyen antibióticos, ácidos orgánicos, sideróforos, antifúngicos y bacteriocinas. Entre los géneros bacterianos más estudiados que producen sustancias inhibidoras se incluyen Enterococcus, Lactococcus, Streptomyces, Bacillus, Pseudomonas, Klebsiella, Escherichia y Burkholderia. Algunas bacterias beneficiosas tienen la capacidad de promover el crecimiento de las plantas y degradar compuestos tóxicos en el ambiente, por lo que podrían incrementar el rendimiento de los cultivos y disminuir problemas de contaminación del suelo, especialmente donde los pesticidas y fertilizantes han sido utilizados indiscriminadamente. Algunas bacterias beneficiosas pueden aumentar la salud de las plantas al inhibir microorganismos patógenos, por ejemplo, Gluconacetobacter diazotrophicus, Azospirullum brasilense, Pseudomonas fluorescens, Pseudomonas protegens y Burkholderia tropica. Sin embargo, la mayoría de los estudios que muestran el potencial antagónico de estas bacterias se han realizado in vitro, y pocos de ellos se han evaluado en asociación con plantas. Varias sustancias inhibitorias implicadas en el antagonismo de los patógenos aún son desconocidas; de hecho, sabemos que solo se ha aislado el 1 % de la diversidad bacteriana en un ambiente natural, lo que sugiere que hay muchas otras sustancias inhibitorias que no han sido exploradas. En esta revisión describimos las características de algunos compuestos antimicrobianos producidos por bacterias beneficiosas, las principales metodologías usadas para evaluar su producción, modos de acción y su importancia para fines biotecnológicos.
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Introduction: The sustainable production of pastures has become a fundamental challenge for the livestock sector where research with plant growth-promoting rhizobacteria as a viable solution, has nearly not been reported. Objective: In this study, we aimed to examine the potential to stimulate growth in Pennisetum clandestinum grass using four isolated bacterial strains from soils obtained from a Colombian tropical silvopastoral system. Methods: We previously identified genetically the strains and characterized two plant growth promoting activities. In addition, we evaluated the growth-promoting effect of the strains in Kikuyo grass under greenhouse conditions. Results: We found that the four bacterial strains were phylogenetically associated with Klebsiella sp. (strains 28P and 35P), Beijerinka sp. (37L) and Achromobacter xylosoxidans (E37), based on partial 16S rRNA gene sequencing. Moreover, the in vitro biochemical assays demonstrated that the strains exhibited some plant growth promoting mechanisms such as 1-aminocyclopropane-1-carboxylic acid deaminase activity and indole compound synthesis. Notably, bacterial inoculation under greenhouse conditions showed a positive influence on P. clandestinum growth. We found a significant (P < 0.05) effect on root and shoot length and shoot dry weight. Shoot length increased by 52 % and 30 % with 37L and 35P compared to those without inoculation treatment. Similarly, the use of 37L and 28P raised shoot dry weight values by 170 % and 131 %, respectively. In root development, inoculation with strains 37L and E37 increased root length by 134 % and 100 %, respectively. Conclusion: Beijerinckia sp. 37L was the most effective of the four strains at increasing P. clandestinum biomass and length.
Introducción: La producción sostenible de pastos se ha convertido en un desafío fundamental para el sector ganadero, donde investigaciones con bacterias promotoras de crecimiento vegetal, como una solución viable, han sido poco reportadas. Objetivo: El objetivo de este estudio fue examinar el potencial para estimular el crecimiento del pasto Pennisetum clandestinum utilizando cuatro cepas bacterianas aisladas de suelos obtenidos de un sistema silvopastoril tropical colombiano. Métodos: Anteriormente identificamos genéticamente las cepas y caracterizamos dos actividades que promueven el crecimiento de las plantas. Además, evaluamos el efecto promotor del crecimiento de las cepas en el pasto Kikuyo en condiciones de invernadero. Resultados: Encontramos que las cuatro cepas bacterianas se asociaron filogenéticamente con Klebsiella sp. (cepas 28P y 35P), Beijerinka sp. (37L) y Achromobacter xylosoxidans (E37), basados en la secuenciación parcial del gen 16S rRNA. Además, los ensayos bioquímicos in vitro demostraron que las cepas exhibían algunos mecanismos que promueven el crecimiento de las plantas tales como la actividad de la enzima desaminasa del ácido 1-aminociclopropano-1- carboxílico, y la síntesis del compuesto indol. En particular, la inoculación bacteriana bajo condiciones de invernadero mostró una influencia positiva en el crecimiento de P. clandestinum. Encontramos un efecto significativo (P < 0.05) en la longitud de la raíz y el tallo, y el peso seco del tallo. La longitud del tallo aumentó en un 52 % y 30 % con 37L y 35P, respectivamente, en comparación con aquellos sin tratamiento de inoculación. Igualmente, el uso de las cepas 37L y 28P aumentó los valores de peso seco del tallo en un 170 y un 131 %, respectivamente. En el desarrollo de la raíz, la inoculación con las cepas 37L y E37 aumentó la longitud de la raíz en 134 y 100 %, respectivamente. Conclusión: Beijerinckia sp. 37L fue la más efectiva de las cuatro cepas al aumentar la biomasa y la longitud de P. clandestinum.
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El complejo Burkholderia cepacia está formado por 22 especies conocidas como patógenos oportunistas en personas inmunocomprometidas, especialmente en aquellas con fibrosis quística. También se aíslan de infecciones nosocomiales y son difíciles de erradicar debido a su capacidad intrínseca para resistir una gran variedad de antibióticos. En general, estas especies presentan genomas de gran tamaño (hasta 9 Mpb) divididos en 2-5 replicones. Esta característica aporta una gran versatilidad metabólica, que se considera importante para habitar el suelo, el agua, las plantas, incluso los nódulos en leguminosas. Algunas especies del complejo B. cepacia exhiben actividades benéficas, como biorremediación, biocontrol y promoción del crecimiento vegetal. No obstante, debido a su papel en infecciones de humanos, su uso en la agricultura está restringido. El complejo B. cepacia es un tema constante de estudio debido a su impacto en el sector salud y su potencial en la agricultura. En este trabajo se examina la historia del complejo B. cepacia y se revisa la información reciente relacionada con este grupo de bacterias.
The Burkholderia cepacia complex is a group of 22 species, which are known as opportunistic pathogens in immunocompromised people, especially those suffering from cystic fibrosis. It is also found in nosocomial infections and is difficult to eradicate due to intrinsic resistance to several antibiotics. The species have large genomes (up to 9 Mbp), distributed into 2-5 replicons. These features significantly contribute to genome plasticity, which makes them thrive in different environments like soil, water, plants or even producing nodules in legume plants. Some B. cepacia complex species are beneficial in bioremediation, biocontrol and plant-growth promotion. However, because the B. cepacia complex is involved in human infection, its use in agriculture is restricted. B. cepacia complex is being constantly studied due to the health problems that it causes and because of its agricultural potential. In this review, the history of B. cepacia complex and the most recently published information related to this complex are revised.
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Complexo Burkholderia cepacia/classificação , Complexo Burkholderia cepacia/patogenicidade , Perfil Genético , Fenótipo , Infecções Oportunistas/microbiologia , Análise de Sequência de DNA/métodos , Infecções por Burkholderia/epidemiologiaRESUMO
Se produjo biomasa de Pseudomonas sp. LMTK32 a partir de la modificación del medio de cultivo Caldo Extracto de Levadura Manitol (LMC) con el objetivo de incrementar el número de células viables con capacidad de promover la germinación de semillas de maca peletizadas y reducir los costos de producción. En el proceso de optimización, los componentes extracto de levadura y manitol del medio de cultivo LMC fueron reemplazados por fuentes comerciales de sacarosa y glutamato, cuyas concentraciones fueron determinadas en matraces mediante el diseño estadístico de Box-Behnken; además, se determinó el efecto del porcentaje de inóculo en el tiempo de producción de biomasa. Posteriormente se determinó a nivel de biorreactor que 28.57 h-1 fue el valor adecuado del coeficiente volumétrico de transferencia de oxigeno (kLa) a 600 rpm, produciendo 1.28x1011 UFC/mL. En el medio modificado M1, empleando 12.06 g/L-1 de sacarosa, 11.50 g/L-1 de glutamato de sodio y 10.9% de inoculante se obtuvo 15x108 UFC/mL, superando en 52% más el número de células viables con respecto al tratamiento control LMC (7.8x108 UFC/mL). A nivel in vitro, la peletización de semillas de maca con Pseudomonas sp. LMTK32 producidas en biorreactor y en el medio modificado M1 favoreció su germinación. A partir de sustratos orgánicos comerciales se puede producir inoculantes bacterianos eficientes en el desarrollo de cultivos de maca, sin alterar su capacidad de promover el crecimiento vegetal
Biomass of Pseudomonas sp. LMTK32 was produced from modification of culture media Yeast Extract Mannitol Broth (YEMB) with the aim of increasing the number of viable cells with the ability to promote the germination of maca seeds pelleted with the bacteria and reduce production costs. In the optimization process, the yeast extract and mannitol components of the LMC culture media were replaced by commercial sources of sucrose and glutamate, whose concentrations were determined in flasks by statistical design from Box-Behnken; in addition, the effect of the inoculum percentage on the time of biomass production was determined. Subsequently, it was determined at the bioreactor level that 28.57 h-1 was the adequate value of the volumetric oxygen transfer coefficient (kLa) at 600 rpm, producing 1.28 x 10 11 CFU / mL. In the LMC M1 modified media, using 12.06 g / L-1 of sucrose, 11.50 g / L-1 of sodium glutamate and 10.9% of inoculant obtained 15x108 CFU / mL, increasing in 48% the number of viable cells with respect to the YEMB control treatment (7.8x10 8 CFU / mL). At the in vitro level, the pelleting of maca seeds with Pseudomonas sp. LMTK32 produced in bioreactor and in the modified media M1 favored its germination. From commercial organic substrates, efficient bacterial inoculants can be produced in the development of maca crops, without altering their ability to promote plant growth
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ABSTRACT This work aimed to characterize 20 isolates obtained from upland rice plants, based on phenotypic (morphology, enzymatic activity, inorganic phosphate solubilization, carbon source use, antagonism), genotypic assays (16S rRNA sequencing) and plant growth promotion. Results showed a great morphological, metabolic and genetic variability among bacterial isolates. All isolates showed positive activity for catalase and protease enzymes and, 90% of the isolates showed positive activity for amylase, catalase and, nitrogenase. All isolates were able to metabolize sucrose and malic acid in contrast with mannitol, which was metabolized only by one isolate. For the other carbon sources, we observed a great variability in its use by the isolates. Most isolates showed antibiosis against Rhizoctonia solani (75%) and Sclerotinia sclerotiorum (55%) and, 50% of them showed antibiosis against both pathogens. Six isolates showed simultaneous ability of antibiosis, inorganic phosphate solubilization and protease activity. Based on phylogenetic analysis of the 16S rRNA gene all the isolates belong to Bacillus genus. Under greenhouse conditions, two isolates (S4 and S22) improved to about 24%, 25%, 30% and 31% the Total N, leaf area, shoot dry weight and root dry weight, respectively, of rice plants, indicating that they should be tested for this ability under field conditions.
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Bactérias/isolamento & purificação , Chryseobacterium/genética , Oryza/crescimento & desenvolvimento , Microbiologia do Solo , Antibiose , Fenômenos Fisiológicos Bacterianos , Bactérias/classificação , Bactérias/genética , Composição de Bases , Sequência de Bases , Chryseobacterium/classificação , Chryseobacterium/efeitos dos fármacos , Chryseobacterium/isolamento & purificação , DNA Bacteriano/genética , Dados de Sequência Molecular , Oryza/microbiologia , FilogeniaRESUMO
Background: Salinity is one of the major factors affecting agriculture. To grow in saline environments, bacteria and plants have to adjust their turgor pressure by accumulating compatible solutes as glycine betaine and proline. Inoculation of plants of economic interest, mainly wheat, by Plant Growth Promoting Rhizobacteria such as Pseudomonas species is an effective biological approach for the recovery of soils affected by salt. Methodology: The halotolerance of indigenous Pseudomonas strains was tested in the presence of high salt concentrations. Under these stress conditions, the effect of natural osmoprotectant molecules elaborated by the halophyte A. halimus was observed. Results: In this study, 3 Fluorescent pseudomonads were isolated from wheat rhizosphere and one from the endophyte of Atriplex halimus. They were identified as P. putida AF2, P. aeruginosa RB5, P. fluorescensRB13 and P. aeruginosa EH4; they exhibited good PGPR activities. The growth of the strains was stimulated in the presence of 100 and 300 mM of NaCl. P. fluorescens CHA0 was inhibited at 500 mM; the remaining strains were affected by 800 mM. Exogenous supply of glycine betaine and proline alleviated the stress. The extract of the halophyte A. halimus restored the growth of 3 strains. NaCl/ 900 mM was strongly inhibitor of all bacteria. The restoration of the growth of P. aeruginosa RB5 and P. aeruginosa EH4 by glycine betaine or proline was significant. No osmoprotectant molecule could overcome stress imposed by 1000 mM. Conclusion: On the basis of their halotolrance and their ability to use natural osmoprotectant to restore their growth, the PGP fluorescent pseudomonads strains tested could be applied as inoculants of wheat for sustainable agriculture in salty soils.
RESUMO
Abstract Plant growth promoting rhizobacteria increase plant growth and give protection against insect pests and pathogens. Due to the negative impact of chemical pesticides on environment, alternatives to these chemicals are needed. In this scenario, the biological methods of pest control offer an eco-friendly and an attractive option. In this study, the effect of two plant growth promoting rhizobacterial strains (Bacillus sp. strain 6 and Pseudomonas sp. strain 6K) on aphid population and wheat productivity was evaluated in an aphid susceptible (Pasban-90) and resistant (Inqlab-91) wheat cultivar. The seeds were inoculated with each PGPR strain, separately or the combination of both. The lowest aphid population (2.1 tiller1), and highest plant height (85.8 cm), number of spikelets per spike (18), grains per spike (44), productive tillers (320 m2), straw yield (8.6 Mg ha1), and grain yield (4.8 Mg ha1) were achieved when seeds were inoculated with Bacillus sp. strain 6 + Pseudomonas sp. strain 6K. The grain yield of both varieties was enhanced by 35.538.9% with seed inoculation with both bacterial strains. Thus, the combine use of both PGPR strains viz. Bacillus sp. strain 6 + Pseudomonas sp. strain 6K offers an attractive option to reduce aphid population tied with better wheat productivity.
RESUMO
Abstract Plant growth promoting rhizobacteria increase plant growth and give protection against insect pests and pathogens. Due to the negative impact of chemical pesticides on environment, alternatives to these chemicals are needed. In this scenario, the biological methods of pest control offer an eco-friendly and an attractive option. In this study, the effect of two plant growth promoting rhizobacterial strains (Bacillus sp. strain 6 and Pseudomonas sp. strain 6K) on aphid population and wheat productivity was evaluated in an aphid susceptible (Pasban-90) and resistant (Inqlab-91) wheat cultivar. The seeds were inoculated with each PGPR strain, separately or the combination of both. The lowest aphid population (2.1 tiller−1), and highest plant height (85.8 cm), number of spikelets per spike (18), grains per spike (44), productive tillers (320 m−2), straw yield (8.6 Mg ha−1), and grain yield (4.8 Mg ha−1) were achieved when seeds were inoculated with Bacillus sp. strain 6 + Pseudomonas sp. strain 6K. The grain yield of both varieties was enhanced by 35.5-38.9% with seed inoculation with both bacterial strains. Thus, the combine use of both PGPR strains viz. Bacillus sp. strain 6 + Pseudomonas sp. strain 6K offers an attractive option to reduce aphid population tied with better wheat productivity.
Assuntos
Animais , Afídeos/crescimento & desenvolvimento , Pseudomonas/fisiologia , Bacillus/fisiologia , Triticum/crescimento & desenvolvimento , Doenças das Plantas/parasitologia , Doenças das Plantas/prevenção & controle , Microbiologia do Solo , Triticum/microbiologia , Triticum/parasitologia , Controle Biológico de Vetores , Dinâmica PopulacionalRESUMO
The aim of this research was to evaluate whether the application of two plant growth-promoting (rhizo)bacteria might reduce nitrogen fertilization doses in cotton. We used strains Azotobacter chroococcum AC1 and AC10 for their proven ability to promote seed germination and cotton growth. These microorganisms were characterized by their plant growth-promoting activities. Then, we conducted a glasshouse study to evaluate the plant growth promoting ability of these strains with reduced doses of urea fertilization in cotton. Results revealed that both strains are capable of fixing nitrogen, solubilizing phosphorus, synthesizing indole compounds and producing hydrolytic enzymes. After 12 weeks, the glasshouse experiment showed that cotton growth was positively influenced due to bacterial inoculation with respect to chemical fertilization. Notably, we observed that microbial inoculation further influenced plant biomass (p<0.05) than nitrogen content. Co-inoculation, interestingly, exhibited a greater beneficial effect on plant growth parameters compared to single inoculation. Moreover, similar results without significant statistical differences were observed among bacterial co-inoculation plus 50% urea and 100% fertilization. These findings suggest that coinoculation of A. chroococcum strains allow to reduce nitrogen fertilization doses up to 50% on cotton growth. Our results showed that inoculation with AC1 and AC10 represents a viable alternative to improve cotton growth while decreasing the N fertilizer dose and allows to alleviate the environmental deterioration related to N pollution.
El objetivo de esta investigación fue evaluar si la aplicación de 2 (rizo)bacterias promotoras del crecimiento vegetal podría reducir la dosis de fertilizante nitrogenado en el cultivo de algodón. Se usaron las cepas Azotobacter chroococcum AC1 y AC10 por su habilidad para promover la germinación de semillas y el crecimiento del algodonero. Estos microorganismos fueron caracterizados sobre la base de sus actividades de promoción del crecimiento vegetal. Luego se realizó un estudio de invernadero con plantas de algodón para evaluar la capacidad de promoción del crecimiento vegetal de dichas cepas con dosis reducidas de urea. Los resultados revelaron que ambas cepas son capaces de fijar nitrógeno, solubilizar fósforo, sintetizar compuestos indólicos y producir enzimas hidrolíticas. Después de 12 semanas, el experimento de invernadero permitió observar que el crecimiento del algodón fue influido positivamente por la inoculación bacteriana con respecto a la fertilización química. En particular, se evidenció que la inoculación microbiana impactó más en la biomasa vegetal (p<0,05) que en el contenido de nitrógeno. Curiosamente, la coinoculación exhibió un mayor efecto positivo sobre los parámetros de crecimiento en comparación con la inoculación simple. Además, se observaron resultados similares, sin diferencias estadísticamente significativas, entre la coinoculación bacteriana más del 50% de urea y el 100% de fertilización. Estos hallazgos indican que la coinoculación de las cepas de A. chroococcum AC1 y AC10 permitiría reducir las dosis de fertilización nitrogenada del cultivo de arroz en hasta el 50% y aliviar, de esta manera, el deterioro ambiental relacionado con la contaminación por N.
Assuntos
Azotobacter , Gossypium , Fertilizantes , Bactérias , Gossypium/crescimento & desenvolvimento , NitrogênioRESUMO
Resumen El uso de Rizobacterias promotoras de crecimiento vegetal (PGPR, por sus siglas en ingles) constituye una alternativa al uso de fertilizantes químicos favoreciendo el rendimiento de los cultivos. La presente investigación tuvo como objetivo la búsqueda, selección y caracterización de PGPB de los géneros Azotobacter, Azospirillum y Pseudomonas nativas de la rizósfera de cultivos de Ipomoea batatas de zonas productoras representativas del Caribe Colombiano. Los aislados seleccionados se caracterizaron molecularmente y realizaron pruebas de solubilización de fósforo, producción de índoles y reducción de acetileno. Las cepas fueron probadas a nivel de invernadero en plántulas de Ipomoea batatas producidas in vitro en las que se evaluó la altura, longitud radicular, masa seca de la parte aérea y radicular. Asociada a la rizósfera de Ipomoea batatas se obtuvieron cepas de Azotobacter vinelandii, Azotobacter chroococcum, Azospirillum lipoferum, Azospirillum brasilense y Pseudomonas denitrificans, las cepas fueron capaces de solubilizar fósforo, producir índoles y reducir acetileno. Se obtuvo incrementos en parámetros de crecimiento como longitud radicular, altura, peso seco aéreo y radicular en plántulas de Ipomoea batatas en invernadero con la inoculación de las bacterias seleccionadas frente a plántulas sin inocular. Los resultados catalogan a los aislados obtenidos como posibles microorganismos con potencial como biofertilizantes en batata.
Abstract The use of plant growth promoting Rhizobacteria (PGPR) is an alternative to replace chemical fertilizers for the cultivation of agricultural crops. The aim of this research was to search, selection and characterization of PGPR from the genus Azotobacter, Azospirillum and Pseudomonas natives from sweet potato (Ipomoea batatas) plants and rhizosphere of representative production regions of the Colombian Caribbean. Selected isolates were identified by molecular methods and they were screenedin vitrofor activities related to plant growth such as phosphate solubilization, indole production and acetylene reduction. The strains were tested in the greenhouse on plants of Ipomoea batatas produced in vitro. The height, root length, dry mass of the shot and root were evaluated. Associated with sweet potato crop us finded strains identificated as Azotobacter vinelandii, Azotobacter chroococcum, Azospirillum lipoferum, Azospirillum brasilense and Pseudomonas denitrificans. The strains were able to solubilize phosphate, synthesize indole-3-acetic acid (IAA) and reduce acetylene. The inoculation of bacteria selected increased growth parameters such as root length, height, dry weight root and shoot in plants of sweet potato in greenhouse. Those results catalog to the isolated obtained as possible microorganisms with potential as biofertilizers in sweet potato.