First report of Wilt on Lentil (Len culinaris Medik.) caused by Fusarium redolens in Tunisia

Lentil (Lens culinaris Medik.) is widely grown in arid and semi-arid regions of Tunisia. Low yields are often attributed to it being grown on marginal growing land. Since 2016, symptoms of wilt including yellowing and discoloration of the stem and root tissues were observed in lentils in several region of Tunisia. The annual mean incidence of infected plants ranged from 10% to 15%. In 2019-2020 growing seasons, symptomatic adult plants were randomly sampled from two fields located in south Tunisia (33°37’N; 11°4’E; N and 33°33’N; 11°2’E), and one field located in north west Tunisia (36°7’N; 8°43’E). Pieces were cut from roots and stem, surface sterilized, then plated on ¼ strength Potato Dextrose Agar (PDA) + 100 mg L-1 streptomycin sulfate (Burgess et al., 1994). Cultures were incubated for 5-6 days. Nine colonies with floccose mycelia, spare or abundant and white to violet color, morphologically similar to Fusarium redolens according to Leslie & Summerell (2006) were isolated from both roots and stems. They were single-spored (Burgess et al., 1994). Microconidia were formed in false heads on short monophialides. They were oval to elliptical or reniform and were 0-1 septate. Three-septate macroconidia with short apical cells were also observed. The strains were also deposited in the microbial ITEM Collection of Institute of Sciences of Food Production. Extraction of genomic DNA of Fusarium sp. strains was carried out according to Wizard® Magnetic DNA Purification System (Promega, Fitchburg, WI, USA). Molecular identification was carried out based on translation elongation factor (TEF) gene sequencing, as described in Fallahi et al. (2019). The TEF sequences were searched on GenBank database by using the Basic Local Alignment Tool (BLAST). The sequences of four strains (Z2P6, Z2P7, Z3P2 and Z3P5) on a total of nine, recovered from lentil roots from the two fields of south Tunisia showed 100% homology with TEF sequences of the epitype culture of F. redolens NRRL25600 (accession number MT409453) (Balmas et al. 2010; Gargouri et al. 2020). Sequences of the strains were submitted to GenBank with accession numbers MW393853, MW393854, MW393856 and MW393857. Pathogenicity of the four strains of F. redolens was evaluated on Kef lentil variety (Kharrat et al. 2007). Inoculum was produced on sterilized oat colonized with each strain. The colonized grains were air-dried on filter paper, ground in a laboratory mill, mixed at 10 % to soil (10 g of each isolate inoculum for 100 g of disinfected soil substrate) and potted. Three germinated lentil seeds were placed in each pot and irrigated periodically. The test was replicated four times. After 21 days, 60% (33-100%) of the plants inoculated with the four F. redolens strains showed symptoms of wilting, yellowing and rotting of roots and 17% died when inoculated by Z2P6 and Z2P7 strains. Non-inoculated plants showed no symptoms. F. redolens was isolated from 100% of the inoculated plants roots. This is the first report of F. redolens as a pathogen on lentil in Tunisia. This species has also been associated with lentil wilting in other regions of the world including Italy (Riccioni et al. 2008), Canada (Taheri et al. 2011) and Pakistan (Rafique et al. 2020). F. redolens was previously reported from wilted chickpea crops in Tunisia (Bouhadida et al. 2017). These findings are important for the Tunisian national legumes program and call for larger surveys to better understand the biology and ecology of this species and to prevent from disease spreading.

Effects of climate warming on the pine processionary moth at the southern edge of its range: a retrospective analysis on egg survival in Tunisia

In recent years, ectotherm species have largely been impacted by extreme climate events, essentially heatwaves. In Tunisia, the pine processionary moth (PPM), Thaumetopoea pityocampa, is a highly damaging pine defoliator, which typically lays eggs in summer. Its geographical range is expanding northwards in Europe while retracting from South Tunisia where summer temperatures can reach extremely high values. In this study, we aimed at exploring the effects of climate change on this species at its southern range edge. We investigated variations of fecundity and causes of egg mortality over time using historical and contemporary collections of egg masses from different Tunisian sites to seek relationships with regional climate change over three decades (1990-2019). Our results suggest negative effects of summer heat on egg survival, reflected in a decrease of hatching rate down to 0% in one site during a heatwave. Such a high hatching failure was found to result from both high egg sterility (our results did not allow distinguishing impeded mating success from failed egg maturation or early death of the embryo) and increased abortion of more developed embryos, but little effects of parasitism rate, thereby suggesting vulnerability to heat during embryonic development. We also observed decreasing female fecundity (i.e., number of eggs laid per female) in regions where data were available both in the 1990s and the 2010s, which was associated with a decrease in parasitism rate, while the climatic variability increased. This study investigated direct hatching failure in nature that may be related to the magnitude of warming in summer. Previous studies have confirmed the thermal sensitivity of early instars of the PPM to temperatures observed in the present work, including one population from South Tunisia. However, further work is required to evaluate the relative importance of warming summers among populations because the risk of heat stress depends on the phenology of sensitive instars, and populations from the warmest areas may not necessarily be the most vulnerable to climate change if they already evolved phenological heat avoidance. In addition to heat-induced mortality, the ultimate fitness of individuals that survive challenging heat stresses during early developmental stages should also be explored to determine potential carry-over effects on subsequent life stages.

Draft Genome Sequences of Nitrogen-Fixing Bradyrhizobia Isolated from Root Nodules of Peanut, Arachis hypogaea, Cultivated in Southern Tunisia

Here, we report the draft genome sequences of two nitrogen-fixing symbionts, Bradyrhizobium sp. strain sGM-13 and Bradyrhizobium sp. strain sBnM-33, isolated from root nodules of peanut grown on soil samples collected from two regions in South Tunisia. The draft genome sizes of these two strains are 8.31 × 106 bp and 8.97 × 106 bp, respectively.

First records of Cuvier’s beaked whale (Ziphius cavirostris, G. Cuvier 1823) strandings along the Tunisian coast

The Cuvier’s beaked whale (Ziphius cavirostris) is the only member of the Ziphiidae family with a regular occurrence in the Mediterranean Sea. Much of the knowledge of this species in the Mediterranean has come from stranding data. This note reports the first records of strandings of Cuvier’s beaked whales along the Tunisian coast. The two strandings described are about two specimens, likely adult animals. The first specimens was 530 cm long and beached at El Hicha (Gulf of Gabès, south Tunisia) on March 5th, 2019. The second specimens was 630 cm long and it was reported in Ras Angla (Bizerte, north Tunisia) on June 6th, 2019. Since this species faces multiple threats in the Mediterranean basin, this contribution is intended to extend previous knowledge of this species in the region and to push towards major efforts to be undertaken to fill the knowledge gaps regarding occurrence of Cuvier’s beaked whale along northern Tunisia.

Study of a solar chimney characterized by a convergent collector output and a divergent chimney bottom

The solar chimney power plant (SCPP) is a solution to convert solar radiation into electrical energy. The optimization of the SCPP setup is essential to obtain a good ratio between the cost of the installation and the generated power. This paper presents a new design of a solar chimney power plant which is characterized by a combination of a convergent collector output and a divergent chimney bottom. This technical solution favors the overall performance and boosts the produced power of the SCPP. Comparing the proposed designs with a conventional prototype, the generated power could be raised by 32%. Indeed, this paper presents the performance of the solar chimney power plant while varying the chimney diameter. For each configuration, the features of the air flow characteristics such as the air temperature, the air velocity are illustrated and disputed. Results showed that the diameter of the chimney is an influential parameter in the optimization of the SCPP, since the diameter of the collector is restraint by the allowed space. Computational findings are confirmed by the use of experimental measurements which were recorded in South Tunisia, North Africa.

The ACC-Deaminase Producing Bacterium Variovorax sp. CT7.15 as a Tool for Improving Calicotome villosa Nodulation and Growth in Arid Regions of Tunisia

Calicotome villosa is a spontaneous Mediterranean legume that can be a good candidate as pioneer plants to limit regression of vegetation cover and loss of biodiversity in Tunisian arid soils. In order to grow legumes in such soils, pairing rhizobia and nodule associated bacteria (NAB) might provide numerous advantages. In this work, cultivable biodiversity of rhizobial symbionts and NAB in nodules of C. villosa plants growing in five arid regions of south Tunisia was characterized. Phylogenetic analysis using 16S rDNA gene, dnak, recA and nodD sequences separated nodule-forming bacteria in six clades associated to genera Ensifer, Neorhizobium, Phyllobacterium and Rhizobium. Among NAB, the strain Variovorax sp. CT7.15 was selected due to its capacity to solubilise phosphate and, more interestingly, its high level of aminocyclopropane-1-carboxylate deaminase (ACC deaminase) activity. C. villosa plants were inoculated with representative rhizobia of each phylogenetic group and co-inoculated with the same rhizobia and strain CT7.15. Compared with single rhizobia inoculation, co-inoculation significantly improved plant growth and nodulation, ameliorated plant physiological state and increased nitrogen content in the plants, independently of the rhizobia used. These results support the benefits of pairing rhizobia and selected NAB to promote legume growth in arid or degraded soils.