Your search keyword '"Seleiman MF"' showing total 3 results

1. Improved chickpea growth, physiology, nutrient assimilation and rhizoremediation of hydrocarbons by bacterial consortia.

Author

Ali MH, Khan MI, Amjad F, Khan N, and Seleiman MF

Subjects

Bacteria metabolism, Rhizosphere, Petroleum metabolism, Cicer microbiology, Cicer growth & development, Cicer metabolism, Biodegradation, Environmental, Microbial Consortia, Soil Pollutants metabolism, Hydrocarbons metabolism, Soil Microbiology

Abstract

Background: Soil pollution by petroleum hydrocarbons (PHCs) reduces yield by changing the physico-chemical properties of soil and plants due to PHCs' biotoxicity and persistence. Thus, removing PHCs from the soil is crucial for ecological sustainability. Microbes-assisted phytoremediation is an economical and eco-friendly solution. The current work aimed to develop and use bacterial consortia (BC) for PHCs degradation and plant growth enhancement in hydrocarbon-contaminated soil. Initially, the enriched microbial cultures (that were prepared from PHCs-contaminated soils from five distinct regions) were obtained via screening through microcosm experiments. Afterward, two best microbial cultures were tested for PHCs degradation under various temperature and pH ranges. After culture optimization, isolation and characterization of bacterial strains were done to construct two BC. These constructed BC were tested in a pot experiment for hydrocarbons degradation and chickpea growth in PHCs contaminated soil., Results: Findings revealed that PHCs exerted significant phytotoxic effects on chickpea growth and physiology when cultivated in PHCs contaminated soil, reducing agronomic and physiological traits by 13-29% and 12-43%, respectively. However, in the presence of BC, the phytotoxic impacts of PHCs on chickpea plants were reduced, resulting in up to 24 - 35% improvement in agronomic and physiological characteristics as compared to un-inoculated contaminated controls. Furthermore, the bacterial consortia boosted chickpea's nutritional absorption and antioxidant mechanism. Most importantly, chickpea plants phytoremediated 52% of the initial PHCs concentration; however, adding BC1 and BC2 with chickpea plants further increased this removal and remediated 74% and 80% of the initial PHCs concentration, respectively., Conclusion: In general, BC2 outperformed BC1 (with few exceptions) in promoting plant growth and PHCs elimination. Therefore, using multi-trait BC for PHCs degradation and plant growth improvement under PHCs stress may be an efficient and environmentally friendly strategy to deal with PHCs pollution and toxicity., (© 2024. The Author(s).)

Published

2024

2. Green synthesis of Zn-doped TIO 2 nanoparticles from Zanthoxylum armatum.

Author

Batool A, Azizullah A, Ullah K, Shad S, Khan FU, Seleiman MF, Aziz T, and Zeb U

Subjects

Green Chemistry Technology, Metal Nanoparticles chemistry, Nanoparticles chemistry, Anti-Bacterial Agents pharmacology, Anti-Bacterial Agents chemistry, Antifungal Agents pharmacology, Antifungal Agents chemistry, Titanium chemistry, Zinc chemistry, Zinc pharmacology, Zanthoxylum chemistry

Abstract

Green synthesis is an easy, safe, and environmentally beneficial nanoparticle creation method. It is a great challenge to simultaneously improve the capping and stabilizing agent carrier separation efficiency of photocatalysts. Herein, Zn-doped Titanium dioxide (TiO 2 ) nanoparticles with high exposure of 360 nm using a UV/visible spectrophotometer were prepared via a one-step hydrothermal decomposition method. A detailed analysis reveals that the electronic structures were modulated by Zn doping; thus, the responsive wavelength was extended to 600 nm, which effectively improved the visible light absorption of TiO 2 . We have optimized the different parameters like concentration, time, and temperature. The peak for TiO 2 is located at 600 cm- 1 in FTIR. A scanning electron microscope revealed that TiO 2 has a definite shape and morphology. The synthesized Zn-doped TiO 2 NPs were applied against various pathogens to study their anti-bacterial potentials. The anti-bacterial activity of Zn-doped TiO 2 has shown robust against two gram-ve bacteria (Salmonella and Escherichia coli) and two gram + ve bacteria (Staphylococcus epidermidis and Staphylococcus aureus). Synthesized Zn-doped TiO 2 has demonstrated strong antifungal efficacy against a variety of fungi. Moreover, doping TiO 2 nanoparticles with metal oxide greatly improves their characteristics; as a result, doped metal oxide nanoparticles perform better than doped and un-doped metal oxide nanoparticles. Compared to pure TiO 2 , Zn-doped TiO 2 nanoparticles exhibit considerable applications including antimicrobial treatment and water purification., (© 2024. The Author(s).)

Published

2024

3. Enhanced wheat productivity in saline soil through the combined application of poultry manure and beneficial microbes.

Author

Arshad MJ, Khan MI, Ali MH, Farooq Q, Hussain MI, Seleiman MF, and Asghar MA

Subjects

Animals, Soil Microbiology, Seedlings growth & development, Fertilizers analysis, Alcaligenes faecalis growth & development, Triticum growth & development, Manure, Soil chemistry, Salinity, Poultry

Abstract

Background: Soil salinity is one of the major menaces to food security, particularly in dealing with the food demand of the ever-increasing global population. Production of cereal crops such as wheat is severely affected by soil salinity and improper fertilization. The present study aimed to examine the effect of selected microbes and poultry manure (PM) on seedling emergence, physiology, nutrient uptake, and growth of wheat in saline soil. A pot experiment was carried out in research area of Institute of Soil and Environmental Sciences, University of Agriculture, Faisalabad, Pakistan. Saline soil (12 dS m - 1 w/w) was developed by spiking using sodium chloride, and used in experiment along with two microbial strains (i.e., Alcaligenes faecalis MH-2 and Achromobacter denitrificans MH-6) and PM. Finally, wheat seeds (variety Akbar-2019) were sown in amended and unamended soil, and pots were placed following a completely randomized design. The wheat crop was harvested after 140 days of sowing., Results: The results showed a 10-39% increase (compared to non-saline control) in agronomic, physiological, and nutritive attributes of wheat plants when augmented with PM and microbes. Microbes together with PM significantly enhanced seedling emergence (up to 38%), agronomic (up to 36%), and physiological (up to 33%) in saline soil as compared to their respective unamended control. Moreover, the co-use of microbes and PM also improved soil's physicochemical attributes and enhanced N (i.e., 21.7%-17.1%), P (i.e., 24.1-29.3%), and K (i.e., 28.7%-25.3%) availability to the plant (roots and shoots, respectively). Similarly, the co-use of amendments also lowered the Na + contents in soil (i.e., up to 62%) as compared to unamended saline control. This is the first study reporting the effects of the co-addition of newly identified salt-tolerant bacterial strains and PM on seedling emergence, physiology, nutrient uptake, and growth of wheat in highly saline soil., Conclusion: Our findings suggest that co-using a multi-trait bacterial culture and PM could be an appropriate option for sustainable crop production in salt-affected soil., (© 2024. The Author(s).)

Published

2024