Efecto biofertilizante del preparado: residuos vegetales - bacteria nativa diazótrofa, sobre las variables biométricas en plántulas de Rhapanus sativus / Biofertilizer effect of the prepared from vegetales wastes - diazotroph native bacterium on biometrics variables of Rhapanus sativus seedlings

El uso de bioinoculantes a base de microorganismos con potencial biofertilizante representa una alternativa económicamente viable y de producción limpia para el sector agrícola. El objetivo del presente trabajo fue evaluar el efecto biofertilizante de un preparado elaborado con residuos sólidos vegetales (RSV) procedentes del mercado y la bacteria nativa diazótrofa Azotobacter A15M2G. Se elaboraron biopreparados utilizando diferentes concentraciones de bacteria (106, 107 y 108 UFC) en un medio de cultivo obtenido a partir del 25% p/v de cada uno de los siguientes RSV: Brassica oleracea (repollo), Lactuca sativa (lechuga) y Allium fistulosum (cebollín). Los biopreparados fueron evaluados en plantas de rábano (Rhapanus sativus) en invernadero, utilizando un diseño estadístico completamente al azar de 5 tratamientos con 3 repeticiones: T1, control; T2, semillas pregerminadas tratadas con RSV al 25% p/v; T3, semillas pregerminadas con bioinoculante de 106 UFC; T4, semillas pregerminadas con bioinoculante de 107 UFC; T5, semillas pregerminadas con bioinoculante de 108 UFC. Se evaluó: número de hojas, área foliar, longitud de la planta, longitud de la raíz y peso seco de toda la planta (ensayos por triplicado). Se observó un incremento altamente significativo en peso seco para T5 (0,88 g) y T4 (1,10 g); y diferencias significativas en el área foliar, para los mismos tratamientos, con un valor superior a 2000 cm2. El biopreparado con bacterias nativas y RSV mejoró el crecimiento y desarrollo de las plantas de rábano, pudiéndose dar un valor agregado a estos residuos y de esta manera obtener un biofertilizante potencialmente utilizable en otros cultivos.

The use of bioinoculantes from microorganisms with biofertilizer potential, represents an economically viable alternative and of clean production for the agricultural sector. The aim of this study was to evaluate the effect of biofertilizer preparation obtained from vegetable solid waste (RSV) of the market and the native bacteria Azotobacter A15M2G diazotroph.Biological cultures were prepared using different inoculum concentrations, 106, 107 y 108 UFC in a culture medium obtained from 25% w / v of each of the following substrates: Brassica oleracea (cabbage), Lactuca sativa (lettuce) and Allium fistulosum (chives). The microbial inoculants were evaluated in radish plants (Rhapanus sativus) in greenhouse using a completely randomized design of 5 treatments with 3 replicates: T1, pre-germinated seeds without any treatment; T2, pre-germinated seeds treated with the dye waste vegetables 25% w / v; T3, pre-germinated seeds treated with bacterial concentration bioinoculants to 106 UFC; T4, pre-germinated seeds treated with bacterial concentration bioinoculants to 107 UFC, and T5, pre-germinated seeds treated with bacterial concentration bioinoculants to 108 UFC. Assessed variables were: number of leaves, leaf area, plant length, root length and dry weight of the entire plant (all assays in triplicate). The results showed a highly significant increase in dry weight, for T5 (0.88 g) and T4(1.10 g); and significant differences in leaf area for the same treatments, with a value greater than 2000 cm2, compared to others. The biopreparado from native bacteria and RSV improved the growth and development of the radish plants, being able to give a added value to these residues and to obtain a potentially usable biofertilizer in other cultures.

[Detection of anti-Azotobacter antibodies in sera from tumor patients]. / Detección de anticuerpos anti-azotobacter en sueros humanos procedentes de enfermos tumorales.

Employing the agar-gel double immunodiffusion technique, the authors describe the presence of antibodies to a protein fraction existing in the supernatant of Azotobacter chroococcum cultures in a high percentage of blood sera from cancer patients. The small number of false positive results makes them think of the convenience of increasing the sensitivity of the procedure to valorate its usefulness for the early diagnosis of malignant tumors.

Bacterial polysaccharide which binds Rhizobium trifolii to clover root hairs.

Immunofluorescence, quantitative immunoprecipitation, and inhibition of bacterial agglutination and passive hemagglutination indicate that cross-reactive antigenic determinants are present on the surface of Rhizobium trifolii and clover roots. These determinants are immunochemically unique to this Rhizobium-legume cross-inoculation group. The multivalent lectin trifoliin and antibody to the clover root antigenic determinants bind competitively to two acidic heteropolysaccharides isolated from capsular material of R. Trifolii 0403. The major polysaccharide is an antigen which lacks heptose, 2-keto-3-deoxyoctulosonic acid, and endotoxic lipid A. The minor polysaccharide in the capsular material of R. Trifolii 0403 contains the same antigen in addition to heptose, 2-keto-3-deoxyoctonate, and lipid A. The acidic polysaccharides of two strains of R. trifolii share the clover r-ot cross-reactive antigenic determinant despite other differences in their carbohydrate composition. Studies with monovalent antigen-binding fragments of anti-clover root antibody and Azotobacter vinelandii hybrid transformants carrying the unique antigenic determinant suggest that these polysaccharides bind R. trifolii to the clover root hair tips which contain trifoliin.

Transfer from Rhizobium japonicum to Azotobacter vinelandii of genes required for nodulation.

A mutant strain of Azotobacter vinelandii that is unable to fix N2 (Nif-) was transformed to Nif+ with DNA from Rhizobium japonicum. Of 50 Nif+ transformants tested, 3 contained the O antigen-related polysaccharide that is present on the cell surface of a nodulating R. japonicum strain, but is absent from a non-nodulating mutant strain.

Intergeneric transfer of genes involved in the Rhizobium-legume symbiosis.

Genes that seem to be involved in the initial steps of infection of a legume by Rhizobium have been transferred, by transformation, to mutant strains of Azotobacter vinelandii that are unable to fix nitrogen. These genes code for a surface antigen that binds specifically to a protein from the host plant.

Application of the fluorescent antibody technique to the study of an isolate of Beijerinckia in soil.

Fluorescent antibody was prepared against a temperate-soil isolate of Beijerinckia obtained from a rhizosphere of rice growing in Camargue (France). The antibody did not cross-react with any of 6 species of Azotobacter, 4 species of Beijerinckia, or 44 unidentified soil bacteria isolated from a spectrum of rhizospheres, but strongly stained the homologous Beijerinckia isolate. The isolate grew well in autoclave Camargue soil, but increased in numbers only slightly in nonsterile soil during 9 days. Preliminary examination of rice plants grown in the laboratory in soil from which the Beijerinckia was originally isolated did not show detectable Beijerinckia in the rhizosphere. The fluorescent antibody was sufficiently sensitive and specific to permit more extensive study of Beijerinckia in relation to nitrogen fixation in the rhizospher of rice.

Glucan common to the microcyst walls of cyst-forming bacteria.

Chemical analysis indicated that D-glucose is tha major neutral monosaccharide present in the microcysts of a range of gram-negative bacteria. Varying amounts of other neutral sugars were found. The glucose was mainly present as a glucan that could be extracted from microcysts of representative strains with alkali or mild acid treatment. The glucan could be identified as an alpha-1,3-linked polymer on the basis of (i) periodate resistance of the extracted polymer and the material present in microcysts; (ii) lectin agglutination of the microcysts; (iii) lectin precipitation of the extracted glucans; and (iv) susceptibility of the glucan either in the walls or after extraction to a specific alpha-1,3-glucanase from Aspergillus nidulans, yielding glucose as the sole hydrolysis product. The galactosamine found in microcysts of Myxococcus xanthus by other workers is clearly a component of another polymer, distinct from the glucan. The presence of an alpha 1,3-linked glucan, common to microcyst walls of various bacterial genera, probably contributes to the rigidity of the walls of these forms and, inter alia, to their resistance to ultrasonic treatment. Preliminary experiments indicate that the gulcan is discarded on germination of the microcysts rather than being broken down by specific enzymes.

Activation of inactive nitrogenase by acid-treated component I.

When Azotobacter vinelandii was derepressed for nitrogenase synthesis in a N-free medium containing tungstate instead of molybdate, an inactive component I was synthesized. Although this inactive component I could be activated in vivo upon addition of molybdate to the medium, it could not be activated in vitro when molybdate was added to the extracts. Activation occurred, however, when an acid-treated component I was added to extracts of cells derepressed in medium containing tungstate. Acid treatment completely abolished component I activity. Mutant strains UW45 and UW10 were unable to fix N(2). Both strains synthesized normal levels of component II but produced inactive component I. Acid-treated component I activated inactive component I in extracts of mutant strain UW45 but not mutant strain UW10. This activating factor could be obtained from N(2)-fixing Klebsiella pneumoniae, Clostridium pasteurianum, and Rhodospirillum rubrum.