Towards a new biological control approach for Photorhabdus temperata bioinsecticide production through the bioconversion of Tunisian industrial wastewater

Sahar Keskes; Wafa Jallouli; Emna Sahli; Sami Sayadi; Slim Tounsi

doi:10.1186/s40643-020-00313-x

Bioresources and Bioprocessing ›› 2020, Vol. 7 ›› Issue (1) : 26 DOI: 10.1186/s40643-020-00313-x

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Towards a new biological control approach for Photorhabdus temperata bioinsecticide production through the bioconversion of Tunisian industrial wastewater

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Abstract

A novel bioconversion approach of Tunisian wastewater to low-cost Photorhabdus temperata bioinsecticide is presented in this study. Our results showed that when cultured on the food industry wastewater (WS4), P. temperata cells exhibited oral toxicity of about 42%, which is the same as those cultured in complex medium (CM), used as control. Moreover, variants small colony polymorphism (Vsm) of the strain K122 was completely avoided after a prolonged incubation. However, viable but non-culturable (VBNC) state was enhanced with the maximum colony-forming units (CFU) count of 9 × 10⁶ cells/mL obtained after 48 h of incubation in the WS4. According to flow cytometry analysis, almost 100% of P. temperata cells were viable until 48 h of incubation. The appearance of propidium iodide (PI) positively stained cells was observed after a prolonged incubation with a maximum of 17% of damaged cells in WS1. In order to follow the progress of P. temperata fermentation process carried out in industrial wastewater, we established for the first time, the mathematical relationship between total cell counts, CFU counts and oral toxicity of P. temperata strain K122. Indeed, irrespective of the medium used, the relationship between CFU count and total cell count followed a power law. Additionally, when plotting CFU count, or total cell count against toxicity, a semi-log linear relationship was obtained. Our results proved the efficiency of this bioconversion approach to produce bioinsecticide based on the entomopathogenic bacterium P. temperata, with practical benefits in terms of cost production and wastewater management.

Keywords

Photorhabdus temperata strain K122 / Tunisian industrial wastewater / Mathematical relation / Toxicity, flow cytometry / Viable but non-culturable state

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Sahar Keskes, Wafa Jallouli, Emna Sahli, Sami Sayadi, Slim Tounsi. Towards a new biological control approach for Photorhabdus temperata bioinsecticide production through the bioconversion of Tunisian industrial wastewater. Bioresources and Bioprocessing, 2020, 7(1): 26 DOI:10.1186/s40643-020-00313-x

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	APHA, AWWA, WPCF (1992) Standard methods for the examination of water and wastewater. 18: 518–523

[2]	Babich H, Stotzky G. Environmental factors that influence the toxicity of heavy metal and gaseous pollutants to microorganisms. Crit Rev Microbiol, 1980, 8: 99-145.

[3]	Ben Abdallah S, Neubert S. La réutilisation des eaux usées traitées en Tunisie études et rapports d’expertise, 2003, GTZ: Institut Allemand de développement.

[4]	Ben Rebah F, Tyagi RD, Prevost D. Wastewater sludge as a substrate for growth and carrier for Rhizobia: the effect of storage conditions on survival of Sinorhizobium meliloti. Bioresour Technol, 2002, 83: 145-151.

[5]	Brar SK, Verma M, Tyagi RD, Valéro JR, Surampalli RY. Entomotoxicity, protease and chitinase activity of Bacillus thuringiensis fermented wastewater sludge with a high solids content. Bioresour Technol, 2009, 100: 4317-4325.

[6]	Daborn PJ, Waterfield N, Silva CP, Au CPY, Sharma S. A single Photorhabdus gene, makes caterpillars floppy (mcf), allows Escherichia coli to persist within and kill insects. Proc Natl Acad Sci, 2002, 99: 10742-10747.

[7]	Epstein W. The roles and regulation of potassium in bacteria. Prog Nucleic Acid Res Mol Biol, 2003, 75: 293-320.

[8]	Eroglu C, Cimen H, Ulug D, Karagoz M, Hazir S, Cakmak I. Acaricidal effect of cell-free supernatants from Xenorhabdus and Photorhabdus bacteria against Tetranychus urticae (Acari: Tetranychidae). J Invertebr Pathol, 2019, 160: 61-66.

[9]	Gupta S, Pawar SB, Pandey RA. Current practices and challenges in using microalgae for treatment of nutrient rich wastewater from agro-based industries. Sci Total Environ, 2019, 687: 1107-1126.

[10]	Hughes MN, Poole RK. Metal speciation and microbial growth-the hard (and soft) facts. J Gen Microbiol, 1991, 137: 725-734.

[11]	Jallouli W, Hammami W, Zouari N, Jaoua S. Medium optimization for biomass production and morphology variance overcome of Photorhabdus temperata ssp. temperata strain K122. Process Biochem, 2008, 43: 1338-1344.

[12]	Jallouli W, Zouari N, Jaoua S. Involvement of oxidative stress and growth at high cell density in the viable but non culturable state of Photorhabdus temperata ssp. temperata strain K122. Process Biochem, 2010, 45: 706-713.

[13]	Jallouli W, Jaoua S, Zouari N. Overcoming the production limitations of Photorhabdus temperata ssp. temperata strain K122 bioinsecticides in low-cost medium. Bioprocess Biosyst Eng, 2011, 34: 1039-1047.

[14]	Jallouli W, Abdelkefi ML, Tounsi S, Jaoua S, Zouari N. Potential of Photorhabdus temperata K122 bioinsecticide in protecting wheat flour against Ephestia kuehniella. J Stored Prod, 2013, 53: 61-66.

[15]	Jang EK, Ullah I, Kim MS, Lee KY, Shin JH. Isolation and characterisation of the entomopathogenic bacterium, Photorhabdus temperata producing a heat stable insecticidal toxin. Plant Dis Res, 2011, 118: 178-184.

[16]	Kjeldahl J. A new method for the determination of nitrogen in organic matter. Anal Chem, 1883, 22: 366.

[17]	Lachhab K, Tyagi RD, Valéro JR. Production of Bacillus thuringiensis biopesticides using wastewater sludge as a raw material: effect of inoculum and sludge solids concentration. Process Biochem, 2001, 37: 197-208.

[18]	Montiel MDLT, Tyagi RD, Valero JR. Wastewater treatment sludge as a raw material for the production of Bacillus thuringiensis based biopesticides. Water Res, 2001, 35: 3807-3816.

[19]	Norris V, Chen M, Goldberg M, Voskuil J, MoGurk G, Holland B. Calcium in bacteria: a solution to which problem?. Mol Microbiol, 1991, 5: 775-778.

[20]	Rezapour S, Atashpaz B, Moghaddam SS, Damalas CA. Heavy metal bioavailability and accumulation in winter wheat (Triticum aestivum L.) irrigated with treated wastewater in calcareous soils. Sci Total Environ, 2019, 656: 261-269.

[21]	Sambrook J, Fritsch EF, Maniatis T. Molecular cloning: a laboratory manual, 1989, Cold Spring Harbor: Cold Spring Harbor Laboratory Press.

[22]	Shrestha YK, Lee KY. Oral toxicity of Photorhabdus culture media on gene expression of the adult sweetpotato whitefly, Bemisia tabaci. J Invert Pathol, 2012, 109: 91-96.

[23]

Stock SP, Griffin CT, Burnell AM. Morphological characterisation of three isolates of Heterorhabditis Poinar, 1976 from the ‘Irish group’ (Nematoda: Rhabditida: Heterorhabditidae) and additional evidence supporting their recognition as a distinct species, H. downesi n. sp. Syst Parasitol, 2002, 51: 95-106.

[24]	Ullah I, Jang EK, Kim MS, Shin JH, Park GS, Khan AR, Kwak Y. Identification and characterization of the insecticidal toxin “makes caterpillars floppy” in Photorhabdus temperata M1021 using a cosmid library. Toxins, 2014, 6: 2024-2040.

[25]	Ullah I, Anwar Y, Al-Ghamdi K, Firoz A, Shin JH. Assessment of agriculturally important metabolites from the entomopathogenic bacterium, Photorhabdus temperata M1021. J Exp Biol Agric Sci, 2017, 5: 907-914.

[26]	Vidyarthi AS, Tyagi RD, Valero JR, Surampalli RY. Studies on the production of B. thuringiensis based biopesticides using wastewater sludge as a raw material. Water Res, 2002, 36: 4850-4860.

[27]	Vu KD, Tyagi RD, Surampalli RY, Valero JR. Mathematical relationships between spore concentrations, delta-endotoxin levels, and entomotoxicity of Bacillus thuringiensis preparations produced in different fermentation media. Bioresour Technol, 2012, 123: 303-311.

[28]	Wakeman CA, Goodson JR, Zacharia VM, Winkler WC. Assessment of the requirements for magnesium transporters in Bacillus subtilis. J Bacteriol, 2014, 196: 1206-1214.

[29]	Waterfield NR, Bowen DJ, Fetherston JD, Perry RD. The tc genes of Photorhabdus: a growing family. Trends Microbiol, 2001, 9: 185-191.

[30]	Yezza A, Tyagi RD, Valero JR, Surampalli RY. Bioconversion of industrial wastewater and wastewater sludge into Bacillus thuringiensis based biopesticides in pilot fermentor. Bioresour Technol, 2006, 97: 1850-1857.

[31]	Zouari M, Souguir D, Bloem E, Schnug E, Hanchi B, Hachicha M. Saline soil reclamation by agroforestry species under Kalaat Landelous conditions and irrigation with treated wastewater in Tunisia. Environ Sci Pollut Res Int, 2019, 26: 28829-28841.