An optimal price for sustainable irrigated agriculture in central-eastern Tunisia

International audienceIncreasing pressures on water resources are causing many countries in Mediterranean to (re)consider various mechanisms to improve water use efficiency for agricultural like Tunisia country. The price mechanism remains the most appropriate instrument to allocate this water resource, but the search for the optimal price of water that reconciles different aspects economic and environmental is the most important issue to rise. In this paper, we will show that the search for a compromise between farm income and water consumption is possible through an optimal price applying both the entropy maximization approach and the multiobjective optimization. The results show that the use of Generalised Maximum Entropy (GME) approach is able to calibrate the model. Once the model is calibrated, a Multi-Objective Programming (MOP) was used to determine the optimal price using the compromise method. This optimal price determined has resulted to a slight economic decline in agricultural income against an immediate environmental gain of water saving. This compromise is a way to ensure the sustainability of irrigated agriculture and the preservation of water resources in Tunisia

Bio-economic modelling to assess the impact of water pricing policies at the farm level in the Oum Zessar watershed, southern Tunisia

For integrated assessment at farm level, the Farm System SIMulator model (FSSIM) was used. FSSIM is a bio-economic model developed for the European context, and was adapted and tested for Tunisian conditions to assess, ex-ante, impacts of water pricing policies at the farm level to the year 2015. The results show that all farm types are strongly dependent on the water pricing policy. Farmers that have private irrigation systems and pay for pumping mainly, are more sensitive to the progressive increase of irrigation water costs compared to farms that obtain water from public irrigation systems, who pay for the amount of water received. A sensitivity analysis showed that increasing the water price with more than 17% is not advisable to local decision makers, because the net income continued to decline, while the water consumption remained stable with further increases. Hence, there is no further gain in terms of water saving. Overall, intensive agricultural systems with private irrigation systems seem more vulnerable and unsustainable and therefore the extension of public irrigation systems and semi-intensive agriculture is recommendable to improve the sustainability of agriculture in this arid zone

Diverse bacteria associated with root nodules of spontaneous legumes in tunisia and first report for nifH-like gene within the genera Microbacterium and Starkeya

We characterized 34 endophytic bacterial isolates associated to root nodules collected from spontaneous legumes in the arid zone of Tunisia by 16S rDNA polymerase chain reaction (PCR)-restriction fragment length polymorphism, whole cell protein sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), 16S rDNA and 16S-23S rDNA internal transcribed spacer sequencing. Phylogenetically, these isolates belong to the branches containing the genera Inquilinus, Bosea, Rhodopseudomonas, Paracraurococcus, Phyllobacterium, Ochrobactrum, Starkeya, Sphingomonas, Pseudomonas, Agromyces, Microbacterium, Ornithinicoccus, Bacillus, and Paenibacillus. These strains did not induce any nodule formation when inoculated on the wide host spectrum legume species M. atropurpureum (Siratro) and no nodA gene could be amplified by PCR. However, nifH sequences, most similar to those of Sinorhizobium meliloti, were detected within strains related to the genera Microbacterium, Agromyces, Starkeya and Phyllobacterium

Etude de la nodulation des légumineuses autochtones ùes régions arides de Tunisie

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Diversité taxonomique et propriétés symbiotiques de rhizobia nodulant Acacia raddiana au nord et au sud du Sahara

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Diversité taxonomique et propriétés symbiotiques des rhizobia nodulant Acacia raddiana au nord et au sud du Sahara

Nous avons étudié une collection de 76 nouveaux isolats bactériens de nodules obtenus par piégeage sur plantes d'Acacia tortilis subsp. raddiana in vitro, inoculées avec des suspensions de sols prélevés dans divers sites au nord (Tunisie) et au sud (Sénégal, Mauritanie) du Sahara, en comparaison avec 54 souches de références. L'analyse des nouveaux isolats par RAPD et SDS-PAGE a montré une grande diversité taxonomique parmi les isolats d'A. tortilis subsp. raddiana. En effet, bien que toutes les souches puissent être qualifiées de « rhizobium à croissance rapide », elles se répartissent en au moins 9 groupes différents, dont plusieurs ne correspondent à aucun des groupes de rhizobia déjà décrits. Aucune relation entre la position taxonomique des souches, leur origine géographique, les conditions édaphiques ou la profondeur d'isolement n'a pu être établie. La caractérisation symbiotique des souches d'A. tortilis subsp. raddiana a, au contraire, montré une grande homogénéité des caractéristiques symbiotiques majeures. Toutes les souches nodulent également A. Senegal, Prosopis julifora et Leucaena leucocephala, qui constituent avec A. tortilis subsp. raddiana un groupe d'inoculation. L'analyse des profils chromatographiques des facteurs Nod (FN) d'une quinzaine de souches réparties dans les différents groupes taxonomiques montre qu'ils sont très similaires. L'homogénéité structurale des FN des souches d'A. tortilis subsp. raddiana a été confirmée par la détermination de la structure des FN de quelques souches représentatives. Cette étroite relation entre FN et plante d'isolement/spectre d'hôte indépendamment de la taxonomie des souches suggère l'existence d'une forte pression de sélection de la part de la plante hôte et confirme nos observations précédentes, à savoir que les facteurs Nod sont de bons indicateurs du potentiel de nodulation d'un rhizobium donné.We studied a collection of 76 new bacterial isolates from nodules developed on Acacia tortilis subsp. raddiana plants inoculated in vitro with soil suspensions harvested in different sites in North (Tunisia) and South (Senegal, Mauritania) parts of Sahara. RAPD and SDS-PAGE analyses in comparison with 54 reference strains from diverse origins showed great taxonomie diversity among the new isolates. All of them are fast-growing and form at least 9 different groups, several of which could correspond to undescribed groups. No relationship could be established between taxonomie groups, geographical origin (North/South of Sahara) of the strains, edaphic conditions, or depth of soil sampling (down to - 32 m). Opposite to their taxonomie diversity, the new isolates share identical main symbiotic properties. All strains nodulating A. tortilis subsp. raddiana can also nodulate Prosopis juliflora, Acacia Senegal and Leucaena leucocephala, these four plants then constituting a cross-inoculation group. By thin-layer chromatography, we showed that 20 A. tortilis subsp. raddiana strains, representative of the different taxonomie groups, share very similar Nod factor (NF) profiles, independently from their geographical origins. NF structure homogeneity was confirmed by NF structure determination of some representative strains. The consistency between NF and plant of isolation/nodulation spectrum, independently of the taxonomie position of the strains suggests a high selection pressure from the plant, and confirms our previous observations that NF are good markers for predicting the nodulation potential of a given rhizobial strain