Research Article

Green Synthesis of Zinc Oxide Nanoparticles by Bacillus subtilis and their Use in Various Applications

Mehwish Iqtedar*, Mahnoor Siddique, Asma Shahzad, Afshan Kaleem and Roheena Abdullah

Department of Biotechnology, Lahore College for Women University, Lahore. Pakistan.

Received | December 01, 2024; Accepted | December 22, 2024; Published | December 29, 2024

*Correspondence | Mehwish Iqtedar, Department of Biotechnology, Lahore College for Women University, Lahore. Pakistan; Email: [email protected]

Citation | Iqtedar, M., M. Siddique, A. Shahzad, A. Kaleem and R. Abdullah. 2024. Green Synthesis of zinc oxide nanoparticles by Bacillus subtilis and their use in various applications. Biologia (Lahore), 70(2): 66-74.

DOI | https://dx.doi.org/10.17582/journal.Biologia/2024/70.2.66.74

Keywords | Zinc oxide nanoparticles, Bacillus subtilis, Characterization, Antimicrobial activity, Photocatalytic activity

Copyright: 2024 by the authors. Licensee ResearchersLinks Ltd, England, UK.

This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).

Introduction

The term nano was described as being one billionth part of a meter (10-9 m) and it establishes a scale for molecules and structures that lie between 1 and 100 nanometers (nm) (Mansoori and Soelaiman, 2005). Lately, researchers have been emphasizing on the green route of synthesis for developing metal and their oxides nanoparticles (Kalaba et al., 2024). Bio-mediated nanoparticles show potential in a number of fields, such as microbiology, biotechnology, drug delivery, nanomedicine, nano-catalysis and biosensors (Aravind et al., 2021). Hence research on green method of producing metallic nanoparticles is increasing by utilizing different natural sources like plants, microorganisms (bacteria and fungi) together with varying metabolites. The green approach is in fact safer and eco-friendly without involving or generating high temperatures and pressures or releasing hazardous compounds. Many microbes most preferably bacteria, has been used to produce safe and hassle-free NPs and they are known for their significant antibacterial characteristics that can be applied in bio-medical sectors (Kalaba et al., 2024). They enable controlled production of biocompatible nanoparticles with uniform size and shape, enhancing their applicability as antimicrobial and photocatalytic agents Mehta et al. (2009).

Zinc is crucial for maintaining important physiological functions in a human body which chiefly includes DNA repair and DNA replication. ZnO-NPs have grabbed lot of attention due to their less toxicity and enhanced biocompatibility. Moreover according to reports they are great antibacterial agents and they possess significant anticancer and antioxidant properties (Kalaba et al., 2024). ZnO is a metal oxide that exhibits pyroelectric and piezoelectric properties that enables enhanced wound healing, anti-inflammatory benefits, and high catalytic activity. As a result, they are extensively utilized in the biomedical field (Agarwal et al., 2017). It was noted in another investigation that at remarkably low concentrations, biosynthesized zinc oxide nanoparticles exhibit significant antibacterial potential against both gram-negative and gram-positive bacteria. It was also described that these antibacterial properties are stronger than those of ZnO NPs made by chemical synthesis techniques (Venkatachalam et al., 2017).

Multiple techniques such as Field Emission Scanning Electron Microscopy (FESEM), Transmission Electron Microscopy (TEM), X-ray diffraction (XRD), UV-Vis absorption spectroscopy and Fourier Transform Infrared Spectroscopy (FTIR) can be employed to characterize and analyze the nanoparticles (Kundu et al., 2014).

This study focuses on green synthesis of ZnO NPs via Bacillus subtilis (CP002905.1), its characterization, antimicrobial properties and photocatalytic activity against dye. As the antibacterial resistance is building up these days, new alternatives need to be designed to tackle with the problem.

 

Materials and Methods

Microorganism

Bacillus subtilis (CP002905.1) strain was acquired from the research project lab, Department of Biotechnology and was revived in nutrient media and stored as 80% glycerol stocks for future use (Selvarajan and Mohanasrinivasan, 2013).

Synthesis of nanoparticles

The NPs were prepared according to the method described after modifications (Kalaba et al., 2024). After the preparation of cell free extract (CFE) 0.01M ZnSO4.7H2O solution was added for the development of the NPs and incubated at 37 oC for 4 days at 120 rpm agitation. After 4 days of incubation NPs formation was monitored and colour changes were noted.

Characterization of ZnO NPs

Characterization of nanoparticles was conducted using UV-Visible spectrophotometer (OD200-600) (U28 Hitachi, USA) for verification of NPs formation whereas X-Ray Diffraction (XRD) (Madkour, 2023; Thongam et al., 2019) (D8 Discover Bruker, USA) was utilized for studying the nature of NPs while zeta sizer was used to assess size and zeta potential of the NPs. Additionally, Fourier Transform infrared spectrophotometer (FTIR) (Shimadzu IR Tracer, Japan) (Hidayat-Chai et al., 2018) was used for the evaluation of the functional groups and Scanning Electron Microscopy (SEM) (Zeiss EVO LS10, Germany) demonstrated shape of NPs at varying magnifications (Lin et al., 2013; Abdulgafour et al., 2010).

Antimicrobial potential

The antimicrobial properties of biosynthesized zinc oxide nanoparticles were measured against multi drug resistant bacteria (MDR) i.e., Escherichia coli (BTCB02), Staphylococcus aureus (BTCB03) and Salmonella typhimurium (BTCB23) respectively according to the method described (Hudzicki, 2012). Sterilized discs were loaded with NPs solution with different volumes ranging from 15 µL, 25 µL, 50 µL, 75µl, 100 µL and 125 µL. The inoculated plates were incubated for 24 h at 37oC and zones of inhibition (ZOI) were measured. As a control, ZnSO4.7H2O was also tested for its antibacterial susceptibility.

Photocatalytic degradation

Photocatalytic degradation potential of biosynthesized Zinc oxide nanoparticles was estimated by preparing the 2.5 ppm methylene blue (MB) dye solution as described (Golmohammadi et al., 2020). Different volumes of NPs were employed (1 mL, 2 mL, 3 mL, 4 mL and 5 mL). Solution containing methylene blue and nanoparticles were exposed to UV light of 50W intensity for 30 min. After every 10 min intervals sample was taken out of every flask. Then UV-Vis spectrum was measured for each sample. Then the rise or fall in characteristic absorbance peak of methylene blue was noted and the percentage of dye degradation was calculated as:

E (%) = (Co - Ct/Co) × 100

Where; initial concentration is represented by Co, final concentration of methylene blue in solution is denoted by Ct and E is the efficiency.

Statistical analysis

Statistical analysis was performed using SPSS on antimicrobial assay. ANOVA was applied to check significant (p≤0.05) difference between different volumes of nanoparticles against pathogen as well as between strains on same volume. Post Hoc Duncan’s multiple range test was also applied.

 

Results and Discussion

Synthesis of nanoparticles

The biosynthesis of zinc oxide nanoparticles involves a mechanism where the enzyme NADPH-dependent reductase plays a crucial role and facilitates reduction by transferring electrons from NADPH to NADP+. This results in their reduction leading to the formation of elemental zinc oxide nanoparticles (Madkour, 2023). In the current research the NPs were formed after the incubation of CFE of Bacillus subtilis (CP002905.1) and 0.01M ZnSO4.7H2O for the period of 4 days in dark condition in shaking incubator (120 rpm at 37 oC). A significant change in colour was noted which indicated the formation of nanoparticles. Transparent colour of ZnSO4.7H2O solution transitioned into milky colour confirming the development of NPs (Figure 1).

Characterization of ZnO nanoparticles

In the current study, Bacillus subtilis was used for the formulation of zinc oxide nanoparticles while some studies synthesized them by using B. licheniformis, Rhodococcus pyridinivorans and Aeromonas hydrophila (Mehta et al., 2009; Raliya and Tarafdar, 2013; Tripathi et al., 2014). The change in color of the mixture from transparent to white (Figure 1) indicated development of biosynthesized zinc oxide nanoparticles nevertheless the color change denotes reduction of zinc ions. Additionally, Surface Plasmon Resonance (SPR) phenomenon was also involved in colour transitions which was made possible by the production of bio-metabolites within ZnO NPs (Tripathi et al., 2014).

Further characterization of biosynthesized ZnO nanoparticles was performed by UV-Vis spectrophotometer, FTIR, Zeta sizer, (size and zeta potential), XRD and SEM. A characteristic absorption peak was observed at 275 nm which is characteristic peak of ZnO nanoparticles (Figure 2a). Previous study on intracellular ZnO nanoparticles reported almost similar characteristic peak at 270- 365 nm range which corroborate with our findings (Madkour, 2023). Likewise, extracellular synthesis of ZnO NPs from Bacillus cereus exhibited a peak at 352 nm (Iqtedar et al., 2020). Similarly, in another study, ZnO NPs produced using Aeromonas hydrophila gave a characteristic peak at 374 nm (Jayaseelan et al., 2012). Zeta sizer analysis showed that ZnO NPs were of 451 nm in size (Figure 2b) while the zeta potential of biosynthesized ZnO NPs was -47.5 mV (Figure 2c) with Polydispersity index (PDI) of 1.0. Yet in another study, size of extracellular ZnO nanoparticles was reported to be approximately 500 nm (Safar et al., 2019) whereas a size of 386.4 nm was also reported Hidayat Chai et al. (2018). We can see in the current study ZnO NPs seem to be quiet stable and the long-term steadiness of these biosynthesized nanoparticles is due to the presence of several biomolecules that prevent aggregation on its surface (Ovais et al., 2018; Thongam et al., 2019). This directs that a potential greater than -30 mV is indicative of improved colloidal stability for the nanofluid (Hidayat-Chai et al., 2018).

Additionally, FTIR analysis of biosynthesized ZnO NPs was also carried out and spectra revealed different peaks at varying wave number. Peak at wavelength 497.18 cm-1 is the characteristic peak showing the ZnO bond whereas the peak at wavelength 692.07 cm-1 corresponds to H-Br stretching and represents the alkyl halide class. The bands at 1032.73 cm-1, 1272.89 cm-1, 1471.61 cm-1 and 1646.54 cm-1 corresponds to C‒O, C‒N, C‒C and ‒C=C‒ stretching. While peak at 3375.19 cm-1 represents the –NH stretching and 3609.53cm-1 represents –OH stretching (Figure 2d). A related study using Enterobacter cloacae exhibited similar peaks at 1651 and 3304 cm-1 corresponding to O-H group and another at 2353 cm-1 corresponding to C = O group. Additionally, a peak at 1312 cm-1 was displayed that exposed C–H group. A distinct peak developed at 463 cm-1 showing Zn–O bond which is accordance with our findings (Shabani et al., 2024). Similarly, other studies also reported peak between ranges of 421-559 cm-1 for zinc oxide bond (Thongam et al., 2019). Similar investigations showed peaks at 466.77 cm−1, 482 cm−1, 513 cm−1, 515 cm−1, 584 cm−1 and 612 cm−1 (Dobrucka and Dlugaszewska, 2016; Maruthupandy et al., 2016; Kavitha et al., 2017; Awwad et al., 2020). The slight variation in a peak might be due to the strain used to produce the nanoparticles and protocol adopted for synthesis.

The morphology of the biosynthesized nanoparticles in the current study was examined at magnifications of 500X (Figure 3a), 1000X (Figure 3b) and 2000X (Figure 3c) by SEM analysis. The outcome showed that the zinc oxide nanoparticles revealed nanoflowers assembly. Other studies also reported a variety of shapes with ZnO NPs such as nanoflower, hexagonal and spherical cluster (Abdulgafour et al., 2010; Raliya and Tarafdar, 2013; Selvarajan and Mohanasrinivasan, 2013). XRD analysis (Figure 3d) was also conducted in the current study that showed the synthesized nanoparticles were amorphous in nature. This outcome is supported by another finding that in nature, the nanostructures of ZnO are amorphous (Lin et al., 2013; Mohan and Renjanadevi, 2016; Ngom et al., 2019).

Antimicrobial activity of biosynthesized ZnO NPs against multidrug resistance bacteria

Various bacterial strains were tested against ZnO NPs at volumes ranging from 15 to 125 µL. However, a volume of 15 µL, 25 µL, 50 µL, 75 µL, 100 µL and 125 µL gave ZOI of 10 mm, 11 mm, 12 mm, 13 mm, 14 mm and 15 mm, against S. aureus (BTCB02) respectively (Figure 4). Significant (p ≤ 0.05) difference was obtained between the zones obtained at different volumes test against S. aureus whereas ZnSO4.H2O alone gave ZOI of diameter 9 mm against S. aureus (Figure 4). The results showed that against S. typhimurium (BTCB23), ZnO NPs at a volume of 15 µL, 25 µL, 50 µL, 75 µL, 100 µL and 125 µL gave zone of inhibition of diameter 10 mm, 10 mm, 11 mm, 12 mm, 13 mm and 14 mm, respectively. Significant (p ≤ 0.05) difference was obtained between the zones obtained at different volumes test against S. typhimurium. ZnSO4. H2O alone gave zone of inhibition of diameter 8 mm against S. typhimurium which shows the ZnO NPs were better antimicrobial agents than the metallic salt. The results demonstrated that for Escherichia coli (BTCB03), ZOI of 10 mm, 11 mm, 11 mm, 12 mm, 12 mm and 13 mm were established at ZnO NPs volume of 15 µL, 25 µL, 50 µL, 75 µL, 100 µL and 125 µL, respectively. Significant (p ≤ 0.05) difference was obtained between the zones obtained at different volumes test against E. coli while a ZOI of 10 mm was produced by ZnSO4.H2O (standard). Results also revealed that the antimicrobial potential increased with the increase in volume of NPs. S. aureus, S. typhimurium and E. coli established highest ZOI at 125 µL volume of NPs and a maximum ZOI of 15 mm was observed against S. aureus.

A related study also tested ZnO NPs synthesized with Calendula officinalis extract against S. aureus, Klebsiella pneumoniae and E. coli. Highest ZOI was displayed at 35.2 mm with S. aureus whereas minimum resistance was visible at 23.6 mm and 13.5 mm against Klebsiella pneumoniae and E. coli respectively. This shows that S. aureus possesses significant antibacterial properties against ZnO NPs (Tiwari et al., 2024). The current study showed that S. aureus was more sensitive towards ZnO than E. coli which could be due to the difference in their cell wall composition and structure, that explains its enhanced sensitivity. Moreover, S. aureus possess thicker peptidoglycan layer that may interact with ZnO more efficiently, increasing its antimicrobial activity (Reddy et al., 2007). It was also explained that Gram negative bacteria are more resistant to NPs because of their extra outer membrane (El-Masry et al., 2022).

The current results showed that the increasing concentration of nanoparticles causes the increase in inhibition of growth of pathogenic bacteria resulting in bigger zones. This result is supported by the report which states that the zone of inhibition expands as zinc oxide nanoparticle concentration rises (Zhou et al., 2023). Another theory suggests that ZnO NPs mainly restrict transport channels physically and cause abrasion induced damage to harmful bacteria cell membranes as part of its antibacterial action. This causes cellular processes to be disturbed and nutrition intake to be hindered, ultimately resulting in bacterial cell death. Reactive oxygen species (ROS), which further contribute to the cell damage and the overall antimicrobial impact, can also be produced by ZnO NPs (Zhang et al., 2010). An electromagnetic attraction is created between the surface of the negatively charge microorganism and the positive surface of metal oxides. As a result of this interaction, ZnO and other metal oxide NPs stick better to the bacterial cell membrane. Once bonded, these nanoparticles have the capacity to cause oxidative stress, which produces ROS. The oxidation and eventual death of the microorganism are caused by the ROS, which also seriously damage lipids, proteins, and DNA within the cell. The dual mechanism of physical adhesion and subsequent chemical destruction is a crucial component of metal oxide nanoparticles antibacterial effectiveness (Zhang and Chen, 2009).

Photocatalytic of biosynthesized ZnO nanoparticles

Photocatalytic performance of ZnO NPs against synthetic dye i.e., methylene blue was determined by exposing a sample containing dye solution along with biosynthesized nanoparticles to UV light of strength of 25W in laminar air flow chamber and measuring their absorbance by using spectrophotometer. By calculating the percentage degradation of methylene blue (Figure 5a-e), maximum degradation was observed in sample containing 2.5 ppm MB and 5 mL of biosynthesized ZnO NPs of 80.1%. The percentage degradation of MB in solution containing 2.5 ppm MB and 1 mL of ZnO NPs were 47.9%, 50.6% and 52.2% at intervals of 10 min, 20 min and 30 min, respectively. The percentage degradation of MB in solution containing 2.5 ppm MB and 2 mL of ZnO NPs were 53.6%, 56.3% and 61.2% at intervals of 10 min, 20 min and 30 min, respectively. The percentage degradation of MB in solution containing 2.5 ppm MB and 3 mL of ZnO NPs were 62.4%, 63.2% and 64% at intervals of 10 min, 20 min and 30 min, respectively. The percentage degradation of MB in solution containing 2.5 ppm solution of MB and 4 mL of ZnO NPs were 68.1%, 72.9% and 73.1% at intervals of 10 min, 20 min and 30 min., respectively. The percentage degradation of MB in solution containing 2.5 ppm MB (Figure 5f) and 5 mL of ZnO NPs were 64.2%, 67.6% and 80.1% at intervals of 10 min, 20 min and 30 min, respectively. Results showed that maximum degradation of methylene blue dye solution occurred at 30min time interval under UV irradiation of sample containing 5 mL of ZnO NPs that is 80.1% whereas minimum degradation was noted after 10 min under UV irradiation with sample containing 1 mL of ZnO NPs.

Photocatalytic efficacy of ZnO nanoparticles was also investigated in current study and under 30 min UV irradiation sample containing 5 mL nanoparticles showed maximum degradation of methylene blue dye up to 80.1%. This result is supported by another study in which ZnO nanoflowers were produced using Bacillus licheniformis under room temperature, followed by their photocatalytic potential evaluation. Then deterioration of methylene blue dye under UV radiation was examined (Tripathi et al., 2014). Furthermore, photocatalytic efficacy of zinc nanostructures was also investigated in study which reported that Jujube fruit extract was used as a reducing agent as well as stabilizer during the green technique of synthesis of zinc oxide nanoparticles. After that, the ability of these nanoparticles to break down two organic dyes, methylene blue and eriochrome black-T, in the presence of sunlight was examined.

Significant degradation efficiencies i.e., with 72% of methylene blue and 86% of eriochrome black-T degrading in five hours of exposure (Golmohammadi et al., 2020). According to the reported mechanism, the electrons of nanoparticles are triggered in the conduction band after leaving valence band by UV irradiation. Pairs of electron-hole are produced by this process, with the conduction band having free electrons and with holes in the valance band. After interacting with oxygen (O₂) or water (H₂O) molecules, these electron-hole pairs can create reactive oxygen species, including hydrogen peroxide, superoxide radicals and hydroxyl radicals. Because of their extreme reactivity, these ROS are essential to the photocatalytic destruction of dye molecules (Muthuvel et al., 2020).

 

Conclusions and Recommendations

Conclusively the bio-synthesized ZnO NPs by Bacillus subtilis (CP002905.1) was a low-cost, green and efficient approach. The UV-Vis spectrum displayed a distinctive peak at 275 nm where as a size of 451 nm with a zeta potential of -47.5 mV was revealed by Zeta sizer. The SEM analysis of NPs indicated nanoflower-shaped arrangement. The ZnO NPs had antimicrobial activity against different multidrug resistant pathogens. Additionally intracellular ZnO NPs also showed photocatalytic activity against commercial dye. Hence the study shows safer and cost-effective way of NPs synthesis and highlights their application in environmental remediation processes. The outcome ensures that ZnONPs exhibited potent antimicrobial property and proved to be an efficient photocatalyst. In future, further steps must be considered to improve and control the size and syntheis of NPs to further improve their applications.

 

Acknowledgements

The authors are thankful to the Central Laboratory Facility at Lahore College for Women University, Pakistan.

Novelty Statement

Intracellular ZnO NPs were produced via Bacillus subtilis that is a cost-effective and an eco-friendly technique with antibacterial and photocatalytic characteristics.

Author’s Contribution

Mehwish Iqtedar, Mahnoor Siddique and Asma Shahzad: Data curation, conceptualization, methodology, formal analysis, supervision, writing original draft, editing.

Afshan Kaleem and Roheena Abdullah: Methodology, review and editing.

Conflict of interest

The authors have declared no conflict of interest.

 

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