Percorrer por autor "Essadki, Yasser"
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- Bibliometric analysis towards industrial-scale use of Marine Algae and Lichens as soil amendments and plant biofertilizers for sustainable agriculturePublication . Ouala, Oumaima; Essadki, Yasser; Oudra, Brahim; Khalloufi, Fatima El; Martins, Rosário; Martins, RosarioThe nutrient-rich composition of seaweeds and lichens makes them well-suited for agricultural applications. Their use as alternatives to synthetic fertilizers contributes to sustainable agricultural production, enabling farmers to adopt ecological practices while maintaining or increasing crop productivity. This review aims to highlight the status and trends of research, along with a literature analysis on the application of these biomasses in sustainable agriculture. A bibliometric analysis was performed based on two databases (Scopus and Web of Science) to overview the main research topics regarding the use of biomasses studied in agriculture, thus providing useful information for future research. The biochemical composition and agricultural applications of these biomasses have been highlighted. The analysis shows that these biomasses are rich of nutrient compounds, revealing their roles and mechanisms of action on the chemical, nutritional properties, and soil microbial activities and their effect on plant growth, using various extraction and application methods. It also highlighted the potential of seaweeds for protection against biotic and abiotic stresses. In light of all the data presented in this review, it is possible to stimulate farmers’ interest in using seaweeds and lichens as natural fertilizers, with a focus on sustainable and ecological agriculture mainly in developing countries.
- In vitro antimicrobial activity of volatile compounds from the Lichen Pseudevernia furfuracea (L.) Zopf. against multidrug-resistant bacteria and fish pathogensPublication . Essadki, Yasser; Hilmi, Adel; Cascajosa-Lira, Antonio; Girão, Mariana; Darrag, El Mehdi; Rosário Martins, Maria; Romane, Abderrahmane; Zerrifi, Soukaina El Amrani; Mugani, Richard; Tazart, Zakaria; Redouane, El Mahdi; Jos, Angeles; Cameán, Ana M.; Vasconcelos, Vitor; Campos, Alexandre; Khalloufi, Fatima El; Oudra, Brahim; Barakate, Mustapha; Carvalho, Maria de FátimaLichens are symbiotic organisms with unique secondary metabolism. Various metabolites from lichens have shown antimicrobial activity. Nevertheless, very few studies have investigated the antimicrobial potential of the volatile compounds they produce. This study investigates the chemical composition and antimicrobial properties of volatile compounds from Pseudevernia furfuracea collected in two regions of Morocco. Hydrodistillation was used to obtain volatile compounds from samples collected in the High Atlas and Middle Atlas. Gas chromatography–mass spectrometry (GC-MS) analysis identified phenolic cyclic compounds as the primary constituents, with atraric acid and chloroatranol being the most abundant. Additionally, eight compounds were detected in lichens for the first time. The antimicrobial activity of these compounds was assessed using disc diffusion and broth microdilution methods. Both samples demonstrated significant antimicrobial effects against multidrug-resistant human bacteria, reference microorganisms, fish pathogens, and Candida albicans, with minimum inhibitory concentrations (MICs) ranging from 1000 µg/mL to 31.25 µg/mL. This study provides the first report on the volatile compounds from Pseudevernia furfuracea and their antimicrobial effects, particularly against fish pathogens, suggesting their potential as novel antimicrobial agents for human and veterinary use. Further research is warranted to explore these findings in more detail.
- Lichen extracts containing volatile compounds induce oxidative stress and modulate the growth of Microcystis aeruginosa and Chlorella sorokinianaPublication . Essadki, Yasser; Darrag, El Mehdi; Zerrifi, Soukaina El Amrani; Haida, Mohamed; Krimech, Aafaf; Martins, Rosário; Campos, Alexandre; Vasconcelos, Vitor; Bouaïcha, Noureddine; Baçaoui, Abdelaziz; Meddich, Abdelilah; Oudra, Brahim; Tazart, Zakaria; El Khallouf, Fatima; Martins, RosarioThis study evaluates volatile extracts (HE1 and HE2) from the lichen Pseudevernia furfuracea as eco-friendly agents to control algal proliferation, specifically targeting the cyanobacterium Microcystis aeruginosa and the green microalga Chlorella sorokiniana. Both extracts exhibited potent anti-microalgal activity against the two species with a minimum inhibitory concentration (MIC) ranging from 375 to 750 µg/mL. Furthermore, both extracts reduced cell density by more than 98% after eight days of treatment. Chlorophyll a and protein levels decreased significantly (>80%) in both species, indicating suppression of pigment synthesis. However, their physiological responses were distinct: M. aeruginosa underwent early acute oxidative stress and severe membrane damage, while C. sorokiniana exhibited delayed oxidative activation and a negative growth rate, suggesting non-lytic metabolic inhibition. An in silico study by molecular docking of the most abundant compounds identified in these volatile extracts, such as terpenoids (abietatriene, δ-cadinene) and a phenolic compound (atraric acid), showed that these compounds interact with vital cellular targets in M. aeruginosa and C. sorokiniana and likely contribute to the effects observed in these two species. Predictive toxicity by applying the ADMET framework confirmed the favorable bioavailability and low acute toxicity of these volatile compounds. Therefore, P. furfuracea volatiles are promising, species-specific, and environmentally safe candidates for mitigating aquatic algal proliferation through targeted oxidative and metabolic interference.
- Microcystin-degrading bacteria reduce bioaccumulation in Fragaria vulgaris and enhance fruit yield and qualityPublication . Haida, Mohammed; Khalloufi, Fatima El; Essadki, Yasser; Alexandrino, Diogo A. M.; Mugani, Richard; Hejjaj, Abdessamad; Campos, Alexandre; Vasconcelos, Vitor; Carvalho, Maria F.; Díez‑Quijada, Leticia; Cameán, Ana M.; Oudra, Brahim; Alexandrino, DiogoIn Morocco, red fruit production has thrived, primarily utilizing hydroponic methods to control crops, increase fruit yield and quality, and avoid soil-related problems. However, the irrigation of these expansive hydroponic farms relies heavily on water sourced from dams, many of which are contaminated with Microcystins (MCs). To address this contamination issue, ongoing research is focused on discovering effective and cost-efficient biological solutions for eliminating MCs. In this study, we isolate and identify bacterial strains capable of degrading MCs, evaluate the rate of degradation, and investigate how soil inoculated with these bacteria affects the accumulation of MCs in plant tissue. The partial 16S rRNA analyses of three bacterial sequences were conducted, identifying them through NCBI as follows: Ensifer sp. (B1) isolated from soil, Shinella sp. (B2) from a cyanobacterial bloom, and Stutzerimonas sp. (B3) from water. These bacteria exhibited the ability to degrade MCs, with approximately 34.75%, 73.75%, and 30.1% of the initial concentration (20 µg/L) being removed after a 6-day period for B1, B2, and B3, respectively. Moreover, strawberry plants were cultivated hydroponically in a greenhouse for a duration of 90 days. These plants were subjected to extracts of cyanobacteria containing 10 and 20 µg/L of Microcystins (MC), as well as water from an artificial lake contaminated with MC, both with and without the presence of isolated bacterial strains. Among these strains, Shinella sp. exhibited the highest efficacy in mitigating MC accumulation. Specifically, it resulted in a reduction of approximately 1.159 µg of MC per kilogram of root dry weight, leading to complete elimination in the leaves and fruits. The findings also indicated that the inoculation of perlite with the three MC-degrading bacterial strains significantly enhanced growth, photosynthetic pigments, yield, biochemical constituents, and quality attributes of strawberries (p≤0.05). These promising outcomes suggest the potential of this approach for addressing the adverse impacts of crops irrigated with MC-contaminated water in future agricultural practices.
- Unveiling Lichen’s Hidden Arsenal against multidrug resistance: A Systematic Review of their essential oils, volatile compounds and extracts with antimicrobial applicationsPublication . Essadki, Yasser; El Amrani Zerrifi, Soukaina; Carvalho, Maria de Fátima; Barros, Lillian; Vasconcelos, Vitor; Campos, Alexandre; El Khalloufi, Fatima; Oudra, Brahim; Martins, Rosário; Martins, RosarioThe increase in multidrug resistance in microorganisms and the rise of emergent infectious diseases worldwide is a threat to human and animal health. Therefore, research on new molecules with antibiotic potential is a priority. Lichens have a unique secondary metabolism with relatively untapped potential, yet their essential oils (EOs) and volatile organic compounds (VOCs) remain a relatively untapped resource. This systematic review was conducted following PRISMA 2020 guidelines, with a comprehensive search performed in the Web of Science database for studies published up to 2023. From 254 identified records, six studies involving nine lichen species (Evernia prunastri, Evernia divaricata, Cladonia rangiformis, Cladonia furcata, Parmotrema perlatum, Lichina pygmaea, Parmelia perlata, Hypogymnia physodes, and Parmelia sulcata) met the eligibility criteria. The synthesized data show that these volatile fractions possess significant antimicrobial potential, with minimum inhibitory concentrations (MICs) generally lower than 1 mg/mL. Major bioactive constituents identified include atraric acid, orsellinates, and various sesquiterpenes. While the current evidence highlights a strong potential of lichen volatiles against pathogens, research is limited to a small fraction of known species. This review identifies a critical gap in testing these compounds directly against MDR clinical isolates and suggests that future research should focus on high-biomass species and the heterologous expression of lichen biosynthetic genes to develop sustainable antimicrobial applications.