Fate of genetically modified Rhizobium leguminosarum biovar viciae during long-term storage of commercial inoculants

Exploring the Role of Bacterial Extracellular Polymeric Substances for Sustainable Development in Agriculture

The incessant need to increase crop yields has led to the development of many chemical fertilizers containing NPK (nitrogen-phosphorous-potassium) which can degrade soil health in the long term. In addition, these fertilizers are often leached into nearby water bodies causing algal bloom and eutrophication. Bacterial secondary metabolites exuded into the extracellular space, termed extracellular polymeric substances (EPS) have gained commercial significance because of their biodegradability, non-toxicity, and renewability. In many habitats, bacterial communities faced with adversity will adhere together by production of EPS which also serves to bond them to surfaces. Typically, hygroscopic, EPS retain moisture in desiccating conditions and modulate nutrient exchange. Many plant growth-promoting bacteria (PGPR) combat harsh environmental conditions like salinity, drought, and attack of pathogens by producing EPS. The adhesive nature of EPS promotes soil aggregation and restores moisture thus combating soil erosion and promoting soil fertility. In addition, these molecules play vital roles in maintaining symbiosis and nitrogen fixation thus enhancing sustainability. Thus, along with other commercial applications, EPS show promising avenues for improving agricultural productivity thus helping to address land scarcity as well as minimizing environmental pollution.

Technologies for beneficial microorganisms inocula used as biofertilizers

The increasing need for environmentaly friendly agricultural practices is driving the use of fertilizers based on beneficial microorganisms. The latter belong to a wide array of genera, classes, and phyla, ranging from bacteria to yeasts and fungi, which can support plant nutrition with different mechanisms. Moreover, studies on the interactions between plant, soil, and the different microorganisms are shedding light on their interrelationships thus providing new possible ways to exploit them for agricultural purposes. However, even though the inoculation of plants with these microorganisms is a well-known practice, the formulation of inocula with a reliable and consistent effect under field conditions is still a bottleneck for their wider use. The choice of the technology for inocula production and of the carrier for the formulation is key to their successful application. This paper focuses on how inoculation issues can be approached to improve the performance of beneficial microorganisms used as a tool for enhancing plant growth and yield.

Risks and Precautions of Genetically Modified Organisms

Commercial potential of biotechnology is immense since the scope of its activity covers the entire spectrum of human life. The most potent biotechnological approach is the transfer of specifically constructed gene assemblies through various techniques. However, this deliberate modification and the resulting entities thereof have become the bone of contention all over the world. Benefits aside, genetically modified organisms (GMOs) have always been considered a threat to environment and human health. In view of this, it has been considered necessary by biosafety regulations of individual countries to test the feasibility of GMOs in contained and controlled environments for any potential risks they may pose. This paper describes the various aspects of risk, its assessment, and management which are imperative in decision making regarding the safe use of GMOs. Efficient efforts are necessary for implementation of regulations. Importance of the risk assessment, management, and precautionary approach in environmental agreements and activism is also discussed.

Long term evaluation of field-released genetically modified rhizobia

This is the report of the first open field release of genetically modified microorganisms (GMMs) in Italy. It covers ten years of monitoring, and follows in-field GMM dynamics from strain release to disappearance below detection limits, as well as assessment of impact on resident microorganisms. The bacteria released belong to the nitrogen fixing legume endosymbiont Rhizobium leguminosarum bv. viciae, and were engineered with non-agronomically-proficient traits, in order to assess their behavior and fate without GMM-specific positive feedback from the plant. A DNA cassette containing mercury resistance and ss-galactosidase genes was introduced in either plasmid-borne or chromosomally integrated versions, in order to test the resulting strain stability. A synthetic promoter was used to drive the lacZ gene, conferring high catabolic activity to the GMM. Two different wild-type Rhizobium backgrounds were tested, comparing a non-indigenous vs. an indigenous, highly competitive strain. The latter had much greater persistence, since it was able to survive and establish at technically detectable levels for over four years after release. Selection factors, such as reiterated presence of the plant host, or lactose substrate supply, enhanced long-term survival to different extents. The lactose treatment showed that even a single trophic supplementation can surpass the benefits of symbiotic interaction for a period of several years. Concerning impact, the GMMs did not alter substantially the other soil community general microbiota. However, there were some significant differences in microbiota as a consequence of the Rhizobium inoculation. This effect was observed with either the WT or GMM, and was more evident in the release of the indigenous Rhizobium. Moreover, as the indigenous GMM had its parental, dominant wild-type in the same soil, it was possible to evaluate to what extent the GMM version could result in parent displacement ("self-impact"), and how much the two rhizobia would additively contribute to nodulation.

Construction of a Pseudomonas sp. derivative carrying the cry9Aa gene from Bacillus thuringiensis and a proposal for new standard criteria to assess entomocidal properties of bacteria

An isolate of Pseudomonas sp. (16S rDNA sequence 98% homologous to P. graminis and P. lutea) was isolated from the phyllosphere of black pine in northern Italy and used as a host for the gene encoding the Cry9Aa entomocidal toxin from Bacillus thuringiensis subsp. galleriae. An expression system featuring a synthetic highest-consensus promoter specifically tailored for the regulated induction of cloned genes over a broad range of Gram-negative bacteria was used to drive the production of the introduced toxin. The construct showed effective toxicity toward larvae of the greater wax moth (Galleria mellonella), which was also used as a model insect for establishing a number of newly proposed toxicity indices (LC50 cellular efficiency, toxin cellular efficiency, GMO efficiency, lethal cellular intake). These were devised in order to express toxicities of entomocidal bacteria in a standard fashion enabling the fine tuning of biocontrol treatments as well as the comparative evaluation of different reports.

Genetically modified bacteria in agriculture

Certain bacteria isolated from soils possess properties that allow them to exert beneficial effects on plants either by enhancing crop nutrition or by reducing damages caused by pathogens or pests. Some of them, such as rhizobia, azospirilla, and agrobacteria, have been traditionally released in fields as seed inoculants and they often lead to increases in the yield of different crops while the application of others, such as pseudomonads, often fails to give the expected results. Bacteria genetically modified to be easily traceable and/or to be improved in their expression of beneficial traits have been constructed and released with plants in a number of experimental field plots. With these releases, it has been possible to monitor the modified inoculant bacteria after their introduction in field ecosystems and to assess their impact on the resident microflora. Local environmental factors appeared as playing a crucial role in the survival and persistence of bacteria once released in fields and in the expression of the beneficial traits whether improved or not. The spread of inoculant bacteria from their point of dissemination was limited. Transient shifts in favour of the released bacteria and in disfavour of some members of the bacterial and fungal populations present in the plant rhizosphere might occur with certain released bacteria. The changes observed were, however, less important than those observed under usual agricultural practices. Gene transfer from resident population to introduced bacteria was detected in one case. The transconjugants were found only transiently in the phytosphere of plants but not in soils. No differences between the survival, spread, persistence in field and ecological impacts of genetically modified bacteria and of the corresponding unmodified parent strain could be detected.

Comparative strain typing of Rhizobium leguminosarum bv. viciae natural populations

372 natural isolates of Rhizobium leguminosarum bv. viciae, rescued from nodules of pea plants grown in an agricultural field in northern Italy, were analyzed by different methods. Three DNA-based fingerprinting techniques were lined up to compare their relative degree of resolution and possible advantages of each approach. The methods included (i) Eckhardt gel plasmid profiles, (ii) pulsed-field gel electrophoresis (PFGE) of genomic large fragment digests, and (iii) random amplified polymorphic DNA (RAPD) profiles, generated with arbitrary primers. The scheme also involved the isolation of a number of different isolates per nodule to estimate the level of intra-nodular variability. It was therefore possible to evaluate the frequency of double and multiple occupancies, and the proportion of the alternative profiles sharing the same nodule, generally resulting in a numerically dominant, main representative accompanied by a secondary one with a slightly different fingerprint. This finding revealed that the different profiles within a nodule are normally due to bacteria derived from the same single invader following genetic alterations possibly occurred during infection, e.g., by plasmid loss. The analysis of 31 nodules revealed 16 different patterns, representing the most frequently occurring nodulation-proficient isolates of the natural soil examined, five of which were found with frequencies around 15%. The sensitivity of the methods in differentiating isolates was compared. The relatedness of the different natural rhizobial isolates was investigated by densitometrical gel analysis of the fingerprints, allowing a comparison of the results. One of the most interesting conclusions was that the degree of information yielded by the plasmid gel profiling alone, carried out by simple visual inspection without software-aided analyses, was surprisingly high, as it enabled a placement of the isolates, whose accuracy, in terms of relatedness, was subsequently confirmed by each of the two genomic methods.

Aspects of Marker/Reporter Stability and Selectivity in Soil Microbiology

Based on several experiences of microbial release using genetically modified Rhizobium leguminosarum, we have highlighted a number of aspects related to the suitability of introduced markers such as resistance to mercury and b-galactosidase activity, the latter serving the function of high-expression level reporter gene obtained by the introduction of a synthetic promoter conferring strong inducible expression in Gram-negative bacteria. In vitro expression and in vivo performances of the chosen examples have been followed in model strains comparing gene dosage and expression levels. The technical possibility of unambiguously monitoring the marked GMM has been evaluated in medium- and long-term experiments carried out both in microcosms and soil, also including the presence of the plant symbiotic host. Marker stability, regardless the nature of the gene, was shown to be dependent on the location of the genetic modification and on its degree of gene expression regulation. Reporter strength was found to be an advantage allowing the distinction of marker-bearing bacteria while negatively affecting their genetic stability. Plasmid-borne regulated reporters were found to be stable up to the stages of rhizosphere colonization, but were more critically selected against upon symbiotic host invasion.