Genotypic variation of nodules’ enzymatic activities in symbiotic nitrogen fixation among common bean (Phaseolus vulgaris L.) genotypes grown under salinity constraint

The effect of salt stress, under glasshouse conditions, was studied on plant biomass, nodulation, and activities of acid phosphatases (APase, EC 3.1.3.2) and trehalose 6-phosphate phosphatase (TPP, EC 3.1.3.12) in the symbiosis common bean (Phaseolus vulgaris L.)-rhizobia nodules. Four common bean recombinant inbred lines (147, 115, 104 and 83) were separately inoculated, with CIAT 899 or RhM11 strains and grown in hydroaeroponic culture. Two NaCl levels (0 and 25 mM NaCl plant^?1 week^?1 corresponding, respectively, to the control and the salt treatment) were applied and the culture was assessed during 42 days after their transplantation. The results showed that the nodulation of these lines was not affected by salinity except for the line 83 inoculated with CIAT 899, whose nodule dry weight decreased by 48.24 % compared with the corresponding controls. For the other symbiotic combinations, shoot and root biomasses were not significantly affected by salt constraint. Salinity stress generally reduced acid phosphatise and trehalose phosphate phosphatase activities in nodules that were less affected in plants inoculated with RhM11. Based on our data, it appears that nodule phosphatase activity may be involved in salinity tolerance in common beans and the levels of salt tolerance depend principally on specific combination of the rhizobial strain and the host cultivar.     

Oxidative stress in the root nodules of Phaseolus vulgaris is induced under conditions of phosphorus deficiency

One of the most adverse effects of phosphorus (P) deficiency on N₂-fixing legumes is the generation of harmful active oxygen species which cause oxidative stress. And although oxidative stress has been widely studied in roots and shoots of various plant species, it has not yet sufficiently been documented in bean nodules so far. In this study, two recombinant inbred lines RIL115 (P-deficiency tolerant) and RIL147 (P-deficiency sensitive) of common bean and Concesa (local variety) were inoculated separately with the reference strain R. tropici CIAT899, RhM₁₁ (R. gallicum) or RhM₁₄ (R. tropici); two local strains of the Marrakesh region of Morocco. Nodulated plants were grown under semi-hydroponic conditions with sufficient or deficient P supply and analyzed for their oxidative responses at the flowering stage. The results indicated that P-deficiency decreased the growth of shoots (48 %) and nodules (32 %), particularly with RhM₁₄ exhibiting the highest decrease (52 %) of nodulation. This constraint increased electrolyte leakage of nodules (40 %) as compared to leaves (20 %), especially for plants inoculated with RhM₁₄ and CIAT899. Moreover, high H₂O₂ and malondialdehyde contents were noticed in P-deficient nodules of RhM₁₄ and RhM₁₁. These variations were associated with peroxidase activity stimulation in P-deficient nodules induced by CIAT899 and RhM₁₄. In symbiosis with RIL115, these last strains exhibited the highest nodule phenol content. Overall, phenol content was mainly enhanced in P-deficient nodules (35 %) as compared to the leaves (16 %). It was concluded that the genotypes inoculated with CIAT899 and RhM₁₁ are relatively P-deficiency tolerant combinations as compared to those inoculated with RhM₁₄. Increase of oxidative stress in nodules rather than in leaves points to the need for further investigations of mechanisms that improve the root-nodule efficiency under adverse conditions.     

Essential Oil Variability and Biological Activities of Tetraclinis articulata (Vahl) Mast. Wood According to the Extraction Time

In the present work, the hydrodistillation (HD) and microwave‐assisted hydrodistillation (MAHD) kinetics of essential oil (EO) extracted from Tetraclinis articulata (Vahl ) Mast. wood was conducted, in order to assess the impact of extraction time and technique on chemical composition and biological activities. Gas chromatography (GC) and GC/mass spectrometry analyses showed significant differences between the extracted EOs, where each family class or component presents a specific kinetic according to extraction time, technique and especially for the major components: camphene, linalool, cedrol, carvacrol and α‐acorenol. Furthermore, our findings showed a high variability for both antioxidant and anti‐inflammatory activities, where each activity has a specific effect according to extraction time and technique. The highlighted variability reflects the high impact of extraction time and technique on chemical composition and biological activities, which led to conclude that we should select EOs to be investigated carefully depending on extraction time and technique, in order to isolate the bioactive components or to have the best quality of EO in terms of biological activities and preventive effects in food.     

Purification and partial characterization of azoreductase from Enterobacter agglomerans

Azoreductase, an enzyme catalyzing the reductive cleavage of the azo bond of methyl red (MR) and related dyes, was purified to electrophoretic homogeneity from Enterobacter agglomerans. This bacterial strain, isolated from dye-contaminated sludge, has a higher ability to grow, under aerobic conditions, on culture medium containing 100mg/L of MR. The enzyme was purified approximately 90-fold with 20% yield by ammonium sulfate precipitation, followed by three steps of column chromatography (gel-filtration, anion-exchange, and dye-affinity). The purified enzyme is a monomer with a molecular weight of 28,000 Da. The maximal azoreductase activity was observed at pH 7.0 and at 35 degrees C. This activity was NADH dependent. The K(m) values for both NADH and MR were 58.9 and 29.4 microM, respectively. The maximal velocity (V(max)) was 9.2 micromol of NADH min(-1)mg(-1). The purified enzyme is inhibited by several metal ions including Fe(2+) and Cd(2+).     

Insight into the denaturation transition of DNA

DNA undergoes a helix-to-coil transition (also called denaturation transition) upon heating. This transition can also be facilitated by using solvent mixtures (for example water–alcohol). An increase in the hydrophobic tail of the second solvent molecule first decreases then increases the melting temperature appreciably. Measurement on 4% DNA in a series of water–alcohol mixtures shows that the helix-to-coil melting transition is driven by the solvent ability to cross the hydrophobic sugar-rich region. DNA is behaving like a cylindrical micelle.     

The Calcium-Dependent Interaction between S100B and the Mitochondrial AAA ATPase ATAD3A and the Role of This Complex in the Cytoplasmic Processing of ATAD3A

S100 proteins comprise a multigene family of EF-hand calcium binding proteins that engage in multiple functions in response to cellular stress. In one case, the S100B protein has been implicated in oligodendrocyte progenitor cell (OPC) regeneration in response to demyelinating insult. In this example, we report that the mitochondrial ATAD3A protein is a major, high-affinity, and calcium-dependent S100B target protein in OPC. In OPC, ATAD3A is required for cell growth and differentiation. Molecular characterization of the S100B binding domain on ATAD3A by nuclear magnetic resonance (NMR) spectroscopy techniques defined a consensus calcium-dependent S100B binding motif. This S100B binding motif is conserved in several other S100B target proteins, including the p53 protein. Cellular studies using a truncated ATAD3A mutant that is deficient for mitochondrial import revealed that S100B prevents cytoplasmic ATAD3A mutant aggregation and restored its mitochondrial localization. With these results in mind, we propose that S100B could assist the newly synthesized ATAD3A protein, which harbors the consensus S100B binding domain for proper folding and subcellular localization. Such a function for S100B might also help to explain the rescue of nuclear translocation and activation of the temperature-sensitive p53val135 mutant by S100B at nonpermissive temperatures.The S100 proteins comprise a multigene family of low-molecular-weight EF-hand calcium binding and zinc binding proteins (5, 13, 16, 24, 33). To date, 19 different S100 proteins have been assigned to this protein family, and they show different degrees of similarity, ranging from 25 to 56% identity at the amino acid level. With S100B, S100P, and S100Z being the exceptions, the majority of the S100 genes are clustered on human chromosome 1q21 (33). Most S100 proteins serve as calcium sensor proteins that, upon activation, regulate the function and/or subcellular distribution of specific target proteins (13, 33, 47), and they are characterized by common structural motifs, including two low-affinity (K_D [equilibrium dissociation constant] of ∼10 μM to 100 μM) helix-loop-helix calcium binding domains (EF hands) that are separated by a hinge region and flanked by amino- and carboxy-terminal domains. The carboxy-terminal domain is variable among S100 proteins, and it typically is the site that is responsible for the selective interaction of each individual S100 protein with specific target proteins (30). S100 proteins are often upregulated in cancers, in inflammation, and in response to cellular stress (14, 16), suggesting that they function in cell responses to stress situations. Consistent with this hypothesis, stress situations were necessary to reveal phenotypes associated with the S100 knockout in mice (11, 14, 33, 56). Moreover, recent observations revealed a new function for the S100 protein family that included their ability to assist and regulate multichaperone complex-ligand interactions (41, 50, 51).One member of the S100 protein family, S100B, has attracted much interest in the past few years because, like other proteins implicated in neurodegeneration (e.g., amyloid, superoxide dismutase, and dual-specificity tyrosine phosphorylation-regulated kinase 1A), its gene is located within a segment of chromosome 21, which is trisomic in Down''s syndrome (DS). Its expression in the brain of mammals coincides with defined periods of central nervous system (CNS) maturation and cell differentiation (43). In oligodendrocyte progenitor cells (OPC), S100B expression is associated with differentiation, and S100B contributes to OPC differentiation in response to demyelinating insult (11). To understand the contribution of S100B to OPC differentiation, we searched for high-affinity S100B target proteins in this cell type by using far-Western analysis. A major and highly specific S100B target protein was identified, the mitochondrial ATAD3A protein.ATAD3A belongs to a new family of eukaryote-specific mitochondrial AAA⁺ ATPase proteins (17). In the human genome, two genes, Atad3A and Atad3B, are located in tandem on chromosome 1p36.33. The Atad3A gene is ubiquitous among multicellular organisms but absent in yeast. The Atad3B gene is specific to the human genome (27). ATAD3A is a mitochondrial protein anchored into the mitochondrial inner membrane (IM) at contact sites with the outer membrane (OM). Thanks to its simultaneous interaction with the two membranes, ATAD3A regulates mitochondrial dynamics at the interface between the inner and outer membranes and controls diverse cell responses ranging from mitochondrial metabolism, cell growth, and mitochondrial fission 20a, 25). The ATAD3A protein has also been identified as a mitochondrial DNA binding protein (23) and as a cell surface antigen in some human tumors (20, 21). The plasma membrane localization of ATAD3A in tumor cells is suggestive that ATAD3A mitochondrial routing can be compromised in pathological situations such as cancer. To understand the functional response resulting from the interaction between S100B and ATAD3A, we first characterized the minimal interaction domain on ATAD3A for S100B binding using thermodynamic studies of wild-type and ATAD3A variants as well as via nuclear magnetic resonance (NMR) spectroscopy techniques. These studies allowed us to further refine the consensus S100B binding motif, which is conserved in several other S100B target proteins, including the p53 protein and several newly discovered target proteins associated with the cell translational machinery. We next analyzed the cellular interaction of S100B with truncated ATAD3A mutants that harbor the S100B binding domain but that are deficient for mitochondrial import. These studies revealed that S100B could assist ATAD3A mutant proteins during cytoplasmic processing by preventing dysfunctional aggregation events. Our results are discussed in light of the possible function of S100B in assisting the cytoplasmic processing of proteins for proper folding and subcellular localization.     

A conceptual framework for the evolution of ecological specialisation

Ecology Letters (2011) 14: 841-851 ABSTRACT: Ecological specialisation concerns all species and underlies many major ecological and evolutionary patterns. Yet its status as a unifying concept is not always appreciated because of its similarity to concepts of the niche, the many levels of biological phenomena to which it applies, and the complexity of the mechanisms influencing it. The evolution of specialisation requires the coupling of constraints on adaptive evolution with covariation of genotype and environmental performance. This covariation itself depends upon organismal properties such as dispersal behaviour and life history and complexity in the environment stemming from factors such as species interactions and spatio-temporal heterogeneity in resources. Here, we develop a view on specialisation that integrates across the range of biological phenomena with the goal of developing a more predictive conceptual framework that specifically accounts for the importance of biotic complexity and coevolutionary events.     

Threats to and conservation of North African wetlands: the case of the Ramsar site of Beni-Belaid (NE Algeria)

Because of their biogeographical and geomorphological context, the northeastern Algeria wetlands present high species and community richness. The vegetation study of the Ramsar site of Beni-Belaid (Kabylia) showed the existence of four main communities, distributed along gradients of hydrology and disturbance. The obtained results reveal worrying threats on short term: overgrazing results in the lake invasion by the sand eroded from the coastal dune; agriculture induces illegal cutting, water pollution and excessive groundwater pumping; finally, hunting and fishing are illegally practiced into the Ramsar site. The awareness of public authorities is needed in order: (1) to completely protect the wetland with the aim of restoring a riparian forest belt; and (2) to initiate a campaign for increasing the local population awareness, and its involvement in conservation programs.