Margarita Carú

Genetic Diversity of Nostoc Microsymbionts from Gunnera tinctoria Revealed by PCR-STRR Fingerprinting

The cyanobacteria belonging to the genus Nostoc fix atmospheric nitrogen, both as free-living organisms and in symbiotic associations with a wide range of hosts, including bryophytes, gymnosperms (cycads), the small water fern Azolla (Pteridophyte), the angiosperm genus Gunnera, and fungi (lichens). The Gunnera–Nostoc symbiosis is the only one that involves a flowering plant. In Chile, 12 species of Gunnera have been described with a broad distribution in the temperate region. We examined the genetic diversity of Nostoc symbionts from three populations of Gunnera tinctoria from Abtao, Chiloé Island, southern Chile, and microsymbionts from other two species of Gunnera from southern Chile, using PCR amplification of STRR (short tandemly repeated repetitive) sequences of the Nostoc infected tissue. To our knowledge, this is the first report of PCR fingerprinting obtained directly from symbiotic tissue of Gunnera. Genetic analyses revealed that Nostoc symbionts exhibit important genetic diversity among host plants, both within and between Gunnera populations. It was also found that only one Nostoc strain, or closely related strains, established symbiosis with an individual plant host.

Characterization of native Frankia strains isolated from chilean shrubs (Rhamnaceae)

Nine native Frankia strains were isolated from root nodules of four chilean actinorhizal plants (Rhamnaceae). The strains were designated as ChI1, ChI2, ChI3 and ChI4 from Colletia hystrix; ReI4 and ReI6 from Retanilla ephedra; TqI12 and TqI15 from Talguenea quinquinervis and TtI42 from Trevoa trinervis. By scanning electron microscopy, all the strains exhibited similar actinomycetal structures: hyphae, sporangia and vesicles. The growth patterns of the isolates in BAP medium were similar. All showed a lag phase of approximately 6–7 days, then exhibited a logarithmic phase, except the ReI4 strain which seems to follow a linear growth pattern. A common feature of all the strains was a rapid loss of biomass at the end of the growth phase. All native strains grew on BAP medium supplemented with glucose. In six out of nine strains, the glucose was the best of the carbon sources tested. However, the strains differed in their ability to use other carbon sources such as arabinose, mannitol, maltose, succinate, sucrose, pyruvate, propionate and galactose. The isolates were sensitive to six antibiotics assayed (ampicillin, penicillin G, rifampicin, chloramphenicol, erythromycin and kanamycin). Using the acetylene reduction assay, the nitrogenase activity of the strains was determined. All strains grown in BAP medium lacking a combined nitrogen source were able to reduce acetylene ‘in vitro’.

Isolation of infective and effective Frankia strains from root nodules of Alnus acuminata (Betulaceae).

Two Frankia strains were isolated from root nodules of Alnus acuminata collected in the Tucumano-oranense forest, Argentina. Monosporal cultures were obtained by plating a spore suspension of each strain and isolating a single colony. The strains (named AacI and AacIII) showed branched mycelia with polymorphic sporangia and NIR-vesicles. They differed in their ability to use carbon sources: the AacI strain grew well on pyruvate, while the AacIII strain grew on mineral medium supplemented with glucose or, alternatively, with sucrose. The two strains were sensitive to oleandomycin, erythromycin, kanamycin, penicillin G, streptomycin and chloramphenicol at 5 μg/ml. The AcIII strain exhibited a moderate resistance to rifampicin, ampicillin and vancomycin. The nitrogenase activity in vitro of the strains was significantly higher in basal medium without nitrogen than that determined in the presence of ammonium chloride. Both strains were infective on seedlings of Alnus glutinosa, inducing an approximately similar percentage of nodulated plants (80%), although strain AacIII produced a higher number of nodules per plant (≤15) than strain AacI (≤6). They were also effective for nitrogen fixation in planta, determined by the acetylene reduction assay.

Diversity and Activity of Denitrifiers of Chilean Arid Soil Ecosystems

The Chilean sclerophyllous matorral is a Mediterranean semiarid ecosystem affected by erosion, with low soil fertility, and limited by nitrogen. However, limitation of resources is even more severe for desert soils such as from the Atacama Desert, one of the most extreme arid deserts on Earth. Topsoil organic matter, nitrogen and moisture content were significantly higher in the semiarid soil compared to the desert soil. Although the most significant loss of biologically preferred nitrogen from terrestrial ecosystems occurs via denitrification, virtually nothing is known on the activity and composition of denitrifier communities thriving in arid soils. In this study we explored denitrifier communities from two soils with profoundly distinct edaphic factors. While denitrification activity in the desert soil was below detection limit, the semiarid soil sustained denitrification activity. To elucidate the genetic potential of the soils to sustain denitrification processes we performed community analysis of denitrifiers based on nitrite reductase (nirK and nirS) genes as functional marker genes for this physiological group. Presence of nirK-type denitrifiers in both soils was demonstrated but failure to amplify nirS from the desert soil suggests very low abundance of nirS-type denitrifiers shedding light on the lack of denitrification activity. Phylogenetic analysis showed a very low diversity of nirK with only three distinct genotypes in the desert soil which conditions presumably exert a high selection pressure. While nirK diversity was also limited to only few, albeit distinct genotypes, the semiarid matorral soil showed a surprisingly broad genetic variability of the nirS gene. The Chilean matorral is a shrub land plant community which form vegetational patches stabilizing the soil and increasing its nitrogen and carbon content. These islands of fertility may sustain the development and activity of the overall microbial community and of denitrifiers in particular.

Gibberellin oxidase activities in Bradyrhizobium japonicum bacteroids

Bradyrhizobium japonicum bacteroids isolated from root nodules of soybean (Glycine max.) plants converted the gibberellin (GA) precursor [(14)C1]GA12 into several products identified by combined gas chromatography-mass spectrometry as [(14)C1]GA24, [(14)C1]GA9, [(14)C1]GA15, GA9 17-nor-16-one and unidentified products. The oxidation of GA12, catalyzed by the GA 20-oxidase, was present in symbiotic bacteroids from plants around flowering, but not in bacteroids from plants at either an early vegetative stage or at late growth stages. Expression of cps and ks genes, involved in ent-kaurene biosynthesis, was also demonstrated in bacteroids from soybean plants around flowering. Earlier precursors of the GA pathway, ent-[(14)C1]kaurenoic acid or [(14)C4]GA12-aldehyde, were efficiently utilized by B. japonicum bacteroids to give labelled GA9 plus intermediates partially oxidized at C-20, as well as GA9 17-nor-16-one and an unidentified product. No 3β or 13-hydroxylated [(14)C]GAs were detected in any of the incubations. Moreover the C19-GAs [(14)C1]GA4 or [(14)C1]GA20 were recovered unconverted upon incubation with the bacteroids which supports the absence of GA 3β-hydroxylase activity in B. japonicum. The bacterial 20-oxidase utilized the 13-hydroxylated substrates [(14)C1]GA53, [(14)C1]GA44 or [(14)C1]GA19, although with less efficiency than [(14)C1]GA12 to give [(14)C1]GA20 as final product, while the 3β-hydroxylated substrate [(14)C1]GA14 was converted to [(14)C1]GA4 to a very small extent. Endogenous GA9 and GA24 were identified by GC-MS in methanolic nodule extracts. These results suggest that B. japonicum bacteroids would synthesize GA9 under the symbiotic conditions present in soybean root nodules.

Tecnologías disponibles para la Purificación de Biogás usado en la Generación Eléctrica

Resumen Se resume y analiza algunas tecnologias que se han implementado para la purificacion de biogas usado en la generacion electrica. Se sabe que el biogas puede contener algunas impurezas y elementos traza que deben ser removidas antes de su uso en la matriz energetica. Las tecnologias tradicionales para la purificacion de biogas estan basadas fundamentalmente en el empleo de metodos fisicos y quimicos, los cuales, ademas de generar contaminantes secundarios, a menudo tienen un alto costo. Como una alternativa, la purificacion de biogas mediante procesos biologicos utilizando microorganismos parece atractiva. Los microorganismos pueden remover las sustancias consideradas contaminantes, especialmente para la eliminacion de sulfuro de hidrogeno. Ser concluye que se trata de un metodo economico, con bajos gastos energeticos e inocuo para el medio ambiente y la salud humana. Palabras clave: purificacion, bioprocesos, biogas, biometano, biofiltros Available Technologies for Purification of Biogas used in Power Generation

Phylogenetic Diversity of Peltigera Cyanolichens and Their Photobionts in Southern Chile and Antarctica

The lichen genus Peltigera has been mainly revised in the Northern Hemisphere, with most species being recorded in Europe and North America. This study assessed the phylogenetic diversity of the mycobionts and cyanobionts of Peltigera cyanolichens collected in Southern Chile and Antarctica, areas in which lichens are extremely diverse but poorly studied. The operational taxonomic units (OTUs) of each symbiont were defined by analyzing the genetic diversity of the LSU and SSU rDNA of the mycobionts and cyanobionts, respectively, and a phylogenetic approach was used to relate these OTUs with sequences previously reported for Peltigera and Nostoc. Among the 186 samples collected, 8 Peltigera and 15 Nostoc OTUs were recognized, corresponding to sections Peltigera, Horizontales, and Polydactylon, in the case of the mycobionts, and to the Nostoc clade II, in the case of the cyanobionts. Since some of the OTUs recognized in this study had not previously been described in these areas, our results suggest that the diversity of Peltigera reported to date in the regions studied using traditional morphological surveys has underestimated the true diversity present; therefore, further explorations of these areas are recommended.

Infectivity and effectivity of Frankia strains from the Rhamnaceae family on different actinorhizal plants

Ten strains of Frankia isolated from root nodules of plant species from five genera of the host family Rhamnaceae were assayed in cross inoculation assays. They were tested on host plants belonging to four actinorhizal families: Trevoa trinervis (Rhamnaceae), Elaeagnus angustifolia (Elaeagnaceae), Alnus glutinosa (Betulaceae) and Casuarina cunninghamiana (Casuarinaceae). All Frankia strains from the Rhamnaceae were able to infect and nodulate both T. trinervis and E. angustifolia. Strain ChI4 isolated from Colletia hystrix was also infective on Alnus glutinosa. All nodules showed a positive acetylene reduction indicating that the microsymbionts used as inoculants were effective in nitrogen fixation. The results suggest that Frankia strains from Rhamnaceae belong to the Elaeagnus-infective subdivision of the genus Frankia.

Spore germination of Frankia strains isolated from Colletia hystrix and Retanilla ephedra (Rhamnaceae)

Two Frankia strains, ChI1 from Colletia hystrix and ReI6 from Retanilla ephedra, were assayed to determine the germinability of their spores and the stages of the life cycle in different media. In BAP medium, both strains showed approximately 18% spore germination. However, in BAP medium lacking micronutrients and FeEDTA, strain ChI1 spores exhibited approximately 53% germination and strain ReI6 spores about 42%. The survey also showed that the spores were not heat-resistant, the ReI6 spores being more sensitive than ChI1 spores. Both strains exhibited a small increase in their percentage of germination with a 15-pulse ultrasonic treatment.

Isolation and characterization of the symbiotic phenotype of antibiotic-resistant mutantsof Frankia from Rhamnaceae

Induced rifampicin-resistant mutants of Frankia were isolated by treatment of spores from strain ChI1 with 2 mg/ml of nitrosoguanidine. The mutagenic treatment was followed by growth for 72 h on non-selective medium to allow the expression of the mutation, before plating on selective medium. Spontaneous rifampicin-resistant mutants were isolated from strain ReI4 and chloramphenicol-resistant mutants were derived from strains ReI6 and TtI42. The mutants grew in medium containing up to 20 μg/ml of antibiotics. They showed similar morphology and growth pattern compared with their parent strains. However, they exhibited differences in symbiotic properties, such as infectivity and nitrogenase activity, from their parent strains.