Increases in alginate production and transcription levels of alginate lyase (alyA1) by control of the oxygen transfer rate in Azotobacter vinelandii cultures under diazotrophic conditions

BACKGROUND: Alginates are polysaccharides used in a wide range of industrial applications, with their functional properties depending on their molecular weight. In this study, alginate production and the expression of genes involved in polymerization and depolymerization in batch cultures of Azotobacter vinelandii were evaluated under controlled and noncontrolled oxygen transfer rate (OTR) conditions. RESULTS: Using an oxygen transfer rate (OTR) control system, a constant OTR (20.3 ± 1.3 mmol L 1 h 1 ) was maintained during cell growth and stationary phases. In cultures subjected to a controlled OTR, alginate concentrations were higher (5.5 ± 0.2 g L 1 ) than in cultures under noncontrolled OTR. The molecular weight of alginate decreased from 475 to 325 kDa at the beginning of the growth phase and remained constant until the end of the cultivation period. The expression level of alyA1, which encodes an alginate lyase, was more affected by OTR control than those of other genes involved in alginate biosynthesis. The decrease in alginate molecular weight can be explained by a higher relative expression level of alyA1 under the controlled OTR condition. CONCLUSIONS: This report describes the first time that alginate production and alginate lyase (alyA1) expression levels have been evaluated in A. vinelandii cultures subjected to a controlled OTR. The results show that automatic control of OTR may be a suitable strategy for improving alginate production while maintaining a constant molecular weight.

Respiration in Azotobacter vinelandii and its relationship with the synthesis of biopolymers

Azotobacter vinelandii is a gram-negative soil bacterium that produces two biopolymers of biotechnological interest, alginate and poly(3-hydroxybutyrate), and it has been widely studied because of its capability to fix nitrogen even in the presence of oxygen. This bacterium is characterized by its high respiration rates, which are almost 10-fold higher than those of Escherichia coli and are a disadvantage for fermentation processes. On the other hand, several works have demonstrated that adequate control of the oxygen supply in A. vinelandii cultivations determines the yields and physicochemical characteristics of alginate and poly(3-hydroxybutyrate). Here, we summarize a review of the characteristics of A. vinelandii related to its respiration systems, as well as some of the most important findings on the oxygen consumption rates as a function of the cultivation parameters and biopolymer production.

Inoculantes microbianos incorporados al cultivo de Ipomoea batatas L. en el Valle del Sinú / Microbial inoculants incorporated in Ipomoea batatas L. crop in the Sinú Valley

RESUMEN La batata (Ipomoea batatas L.) se cultiva en todo el mundo como fuente de carbohidratos, y su producción comercial requiere un alto aporte de fertilizantes químicos, lo cual eleva los costos de producción. Los inoculantes microbianos, se emplean como una fuente alternativa de nutrición vegetal. El objetivo de esta investigación fue evaluar el efecto de Pseudomonas denitrificans IBVS2 y Azotobacter vinelandii IBVS13 con diferentes niveles fertilización química nitrogenada en el cultivo de batata en la microrregión del Valle del Sinú en el Caribe Colombiano. Para los montajes de los experimentos se utilizó un diseño completamente aleatorizado, ocho tratamientos y tres repeticiones usando como material vegetal plántulas obtenidas in vitro endurecidas en invernadero. Los resultados demostraron que la cepa Azotobacter vinelandii IBVS13 con un 75% de fertilización nitrogenada (FN) mejoró la capacidad de acumulación de materia seca en los tubérculos de batata, generando incrementos de 6,65 t/ha respecto al testigo químico y 3,18 t/ha en relación con el testigo absoluto, garantizando un incremento del rendimiento. Así mismo, el contenido de proteína bruta aumentó 13,93% al realizar la inoculación de las plantas con esta cepa. En el mismo sentido, la cepa Pseudomonas denitrificans IBVS2+ fertilización nitrogenada 50% presentó aumentos en la variable de fibra cruda 31,75% respecto al testigo absoluto, contribuyendo de manera eficaz como bioestimulante microbiano en la agricultura.

ABSTRACT Sweet potatoes (Ipomoea batatas L.) are grown worldwide as a source of carbohydrates, and their commercial production requires a high contribution of chemical fertilizers, which increases production costs. Microbial inoculants are used as an alternative source of plant nutrition. The objective of this research was to evaluate the effect of Pseudomonas denitrificans IBVS2 and Azotobacter vinelandii IBVS13 with different levels of nitrogen chemical fertilization in the sweet potato crop in the microregion of the Sinú Valley in the Colombian Caribbean. A completely randomized design was used for the experiment development, eight treatments was evaluated and three repetitions were carried out. In vitro hardened seedlings was used as a plant material. The results showed that the Azotobacter vinelandii IBVS1 3 strain with 75% nitrogen fertilization (FM) improved the accumulation capacity of dry matter in sweet potato roots, generating increases of 6.65 t / ha compared to the chemical control and 3.18 t / ha in relation to the absolute control, guaranteeing an increase in yield. The crude protein content was increased in 13.93% when inoculating the plants with this strain. In the same way, with the inoculation of strain Pseudomonas denitrificans IBVS2 + 50% nitrogen fertilization the crude fiber variable was increased in 31.75% compared to the absolute control, contributing effectively as a microbial biostimulant in agriculture.

Effect of Nutrient Sources on the Alginate Accumulation in the Culture Liquid of Azotobacter vinelandii D-05 and Obtaining Biocomposite Materials

ABSTRACT Using the classic biotechnological methods, the dependence of A. vinelandii D-05 culture alginate production from the media carbon and nitrogen content was investigated. The maximal alginate production was observed during cultivation bacterium in the medium with 2 to 4% of sucrose, but the maximal growth was found in the medium with 4% glucose. It was found that for the alginate production the optimal nitrogen contents could take from 0.05% yeast extract (carbon: nitrogen ratio 168:1). For the first time we demonstrated possibility the A. vinelandii growth during the cultivation in a medium with molasses (a by-product of sugar production) and the significant polysaccharide production (16.6 g/l) was obtained. It was established, that A. vinelandii culture broth could be used as a biological binder for obtaining the biocomposite materials.

Identification and production of Azotobacter vinelandii and its antifungal activity against Fusarium oxysporum.

The phytopathogenic Fusarium species are one of the leading causes of loss in agricultural productivity. In search of an efficient bacterial antagonist, 19 soil isolates of Azotobacter sp. were screened for antagonistic activity against Fusarium oxysporum by agar well diffusion assay. The potential strain was identified as Azotobacter vinelandii by 16S rRNA sequencing. Optimum conditions for culturing A. vinelandii to obtain maximum antifungal activity were determined by varying temperature, pH, incubation period and NaCl and sucrose concentration. Maximum inhibition of F. oxysporum was observed at pH 7 and 8, 1% NaCl and 2% sucrose concentration and after 72 hr of incubation at 30°C temperature. A. vinelandii showed 44% higher yield of antifungal metabolite under optimized conditions. The minimum inhibitory concentration was 10 µg ml-1 for F. oxysporum. The FTIR analysis of purified metabolite showed presence of aldehyde, C-N, ester, aromatic ring, P-H stretch, and C-N stretch of alkyl amine in the structure. The purified antifungal metabolite of A. vinelandii showed effect on spore germination and mycelia morphology of F. oxysporum. The study revealed significance of A. vinelandii in controlling F. oxysporum and its promising application as a biocontrol agent in agriculture.

THE CONSTRUCTION AND ANALYSIS OF A nifS DISRUPTION MUTANT / 微生物学通报

A central portion of nifS, designated nifS', was amplified from Azotobacter vinelandii. The nifS' was cloned into pUC18 to make pUCS. Then pUCS was integrated into Azotobacter vindandii chromosome DNA by homologous recombination. This nifS disruption mutants were generated by single cross-over event and selected by Amp resistence on BBGN medium. The nifS disruption mutant (named SU1) was affirmed by southern blot and PCR amplification. SU1 grows rapidly on BBGN, but very slowly on Burk's N-free medium. This phenomenon showes that SU1 nearly lost its nitrogen fixation ability because of the disruption of nifS. The successful construction of SU1 is helpful for further research on the effect of nifS on the structure and function of nitrogenase component-Ⅰ and Ⅱ.

Cloning of ferredoxin I gene from Azotobacter vinelandii using synthetic oligonucleotide probes.

Two synthetic oligonucleotide probe mixtures, whose sequences were inferred from two separate stretches of amino acids, one closer to the carboxy terminal and the other closer to the amino terminal, of ferredoxin I protein of Azotobacter vinelandii, were used to select ferredoxin I gene clones from a cosmid gene library of Azotobacter vinelandii. Restriction analysis revealed that 7 out of 10 selected clones were of the same type. All these clones were found to hybridize with fixABCX genes of Rhizobium meliloti.

Expression from symbiotic promoters of Rhizobium meliloti in Azotobacter vinelandii and Azospirillum brasilense.

In Rhizobium meliloti, the promoter P1 of the nif HDK operon, and also the promoter P2, have earlier been shown to be active in the bacteria present in alfalfa root nodules, but not in the bacteria grown aerobically in culture. Here we have looked at the expression from P1 and P2 in two non-symbiotic nitrogen-fixing bacteria, Azotobacter vinelandii and Azospirillum brasilense, using constructions in which the promoters are fused upstream of the ß-galactosidase gene. The promoter P1, but not P2, is active in A. vinelandii, while neither P1 nor P2 is active in Azospirillum brasilense.

Use of the plasmid pRK 2013 as a vehicle for transposition in Azotobacter vinelandii.

Plasmid stability in Azotobacter vinelandii has been determined and a way to introduce transposon into these cells using the plasmid pRK 2013 has been devised. Transposition of both Tn3 and Tn10 has been attained.

Ammonium ions prevent methylation of uridine to ribothymidine in Azotobacter vinelandii tRNA.

It was shown that tRNA from Azotobacter vinelandii grown in the presence of ammonium chloride lacks ribothymidine while that grown in the absence of the ammonium salt contains this modified nucleoside. [32P]-Labelled tRNA from this organism grown in a medium containing the ammonium salt was digested with RNase T1 and the pseudouridinecontaining tetranucleotide, common to all tRNAs was isolated and analysed for the nucleoside replacing the ribothymidine. It was found to be uridine. Cells previously labelled with [32P]- phosphate in the ammonium salt medium were washed and incubated in the ammonium saltfree medium to test whether ribothymidine would be formed upon removal of the ammonium ions. Methylation of the uridine did not take place.