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American Journal of Food and Nutrition
ISSN (Print): 2374-1155 ISSN (Online): 2374-1163 Website: https://www.sciepub.com/journal/ajfn Editor-in-chief: Mihalis Panagiotidis
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American Journal of Food and Nutrition. 2021, 9(1), 16-22
DOI: 10.12691/ajfn-9-1-3
Open AccessArticle

Screening of Methionine-producing Bacillus Species from Nigerian Fermented Food Condiments and Effects of Some Cultural Parameters on Methionine Accumulation

Ajogwu Tobechukwu Maximilian Cajetan1, Ekwealor Chito Clare1, Mbah Anthonia Nkiruka1, Madukwe Ebelechukwu Judith2 and Ekwealor Ikechukwu Amechi1,

1Department of Applied Microbiology and Brewing, Nnamdi Azikiwe University, Awka, Anambra State, Nigeria

2Juhel Nigeria Limited (Parenteral Division), Awka Anambra State, Nigeria

Pub. Date: December 29, 2020
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Cite this paper:
Ajogwu Tobechukwu Maximilian Cajetan, Ekwealor Chito Clare, Mbah Anthonia Nkiruka, Madukwe Ebelechukwu Judith and Ekwealor Ikechukwu Amechi. Screening of Methionine-producing Bacillus Species from Nigerian Fermented Food Condiments and Effects of Some Cultural Parameters on Methionine Accumulation. American Journal of Food and Nutrition. 2021; 9(1):16-22. doi: 10.12691/ajfn-9-1-3

Abstract

Fermented food condiments are sources of proteins and vitamins and are added as spices or sauces to food for flavour or taste enhancers. The major fermenting microorganisms, Bacillus species, produce proteolytic enzymes that hydrolyze proteins and amino acids and peptides. Methionine is the most essential amino acid for chicken feeds and can be produced by Bacillus species. The screening of methionine-producing microorganisms from Nigerian fermented food condiments and the effect of some cultural parameters on methionine accumulation were conducted. Bacterial organisms isolated from fermented food condiments, ogiri and okpeye, were screened for methionine producers on minimal solid agar medium seeded with auxotrophic Escherichia coli and in submerged medium. The effects of medium to fermenter volume ratio, inoculum size, carbon and nitrogen sources on methionine accumulation by the isolates were investigated. Of the five methionine producers recovered, two of the active isolates identified as Bacillus pumilus and Bacillus amyloliquefaciens were used for methionine production. A 20.0ml fermentation medium and 5.0% inoculum size gave the highest methionine accumulation by the Bacillus species. At 8.0% glucose and 4.0% ammonium sulphate concentrations, methionine yields of 5.22mg/ml and 5.50mg/ml were accumulated in the broth cultures of B. pumilus and B. amyloliquefaciens respectively. B. pumilus and B. amyloliquefaciens recovered from Nigerian fermented food condiments were observed to produce methionine and the optimization of some cultural parameters enhanced methionine accumulation by the Bacillus species.

Keywords:
food condiments fermentation bacillus methionine optimization

Creative CommonsThis work is licensed under a Creative Commons Attribution 4.0 International License. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/

References:

[1]  Ugwuanyi, J. O. and Okpara, A. N. Current status of alkaline fermented foods and seasoning agents of Africa. in New Advances on Fermentation Processes, Edited by Rosa Maria, Martinez-Espinosa Intechopen Ltd UK. Nov. 2019.
 
[2]  Okpara, A. N. and Ugwuanyi, J. O. Evolving status of African food seasoning agents produced by fermentation. Soft Chemistry and Food Fermentation 2017, 465-505 Jan. 2017.
 
[3]  Olasupo, N. A. Fermentation Biotechnology of traditional food of Africa. in Food Biotechnology 2nd ed. Edited by Shetty, K., Pometto, A., Paliyath, G., Levi, R. E, revised and expanded ed. Boca Raton, New York: CRC Press, Taylor and Francis group. 1705-1739 Oct. 2006.
 
[4]  Olasupo, N. A. and Okorie, P. C. African fermented food condiments: Microbiology impacts on their nutritional values. in Frontiers and New Trends in the Science of Fermented Food and Beverages, Edited by Rosa Lida Solis-'Oviedo and 'Angel de la Cruz Pech-Canul, Intechopen publishers, Feb. 2019.
 
[5]  Daeschel, M. A., Anderosn, R. E. and Fleming, H. E. Microbial ecology of fermenting plant materials. FEMS Microbiology Review 46(3): 357-367, Sept. 1987.
 
[6]  Ouoba, L. I. I., Diawara, B., Moa-Awua, W. K., Traore, A. S. and Moller P. L. Genotyping of starter cultures of Bacillus subtilis and Bacillus pumilus for fermentation of African locust bean (Parkia biglobosa) to produce Soumbala. International Journal of Food Microbiology 90(2): 197-205, Jan. 2004.
 
[7]  Ling, J, Wu, Q., Xu, Y. and Fan, W. Interaction between Bacillus licheniformis and Saccharomyces cerevisiae in fermentation of soy-sauce flavour liquor. Microbiology China 40: 2014-2021, 2013.
 
[8]  Achi, O. K. Microorganisms associated with natural fermentation of Prosopsis africana seed for the production of okpehe. Plant Foods for Human Nutrition 42: 304-309, 1992.
 
[9]  Odibo, F. J. C., Ugwu, D. A. and Ekeocha, D. C. Microorganisms associated with fermentation of Prosopsis seeds for ogiri-okpei production. Journal of Food Science and Technology 29: 306-307, 1992.
 
[10]  Sanni, A. I. Biochemical changes during production of okpehe-A Nigerian fermented food condiment. Chemical and Microbiological Technology Lebensmittel 15: 97-100, 1993.
 
[11]  Ouoba, L. I. I., Rechinger, K. B., Barkholt, B., Diawara, B., Traore, A. S. and Jakobson, M. Degradation of proteins during the fermentation of African locust bean (Parkia biglobosa) by strains of Bacillus subtilis and Bacillus pumilus for production of Soumbala. Journal of Applied Microbiology 94: 396-402, Feb. 2003.
 
[12]  Adebayo-Tayo, B., Elelu, T., Akinola G. and Oyinloye, I. Screening and production of mannanase by Bacillus strains isolated from fermented food condiments. Food Biotechnology 13: 53-62, Sept. 2013.
 
[13]  Odunfa, S. A. Microbiology and amino acid composition of ogiri- A food from fermented melon seeds. Die Nahrung 25(9): 811-816, Jan 1981
 
[14]  Ogbadu, C. O., Okagbue, R. N. and Amed, A. A. Glutamic acid production by Bacillus isolates from Nigerian fermented vegetable proteins. World Journal of Microbiology and Biotechnology 6: 377-382, Dec. 1990
 
[15]  Beaumont, M. Flavouring composition prepared by fermentation with Bacillus species. International Journal of food Microbiology 75(3): 189-196, May 2002.
 
[16]  Okafor, N. and Anike, N. Secretion of methionine by microorganisms associated with cassava fermentation. African Journal of Food Agriculture Nutrition and Development. 8(1): 77-90, March 2008.
 
[17]  Kinoshita, S., Udaka, S. and Shimono, M. Amino acid fermentation I. Production of L-glutamic acid by various microorganisms. Journal of General and Applied Microbiology 3: 193-205, 1957.
 
[18]  Kase, H. and Nakayama, K. L-Methionine production by methionine analog-resistant mutants of Corynebacterium glutamicum. Agricultural and Biological Chemistry 39 (1): 153-160, 1975
 
[19]  Banik, A. K. and Majunder, S. K. Studies on methionine fermentation part 1. Selection of mutants of Micrococcus glutamicus and optimum conditions for methionine production. Indian Journal of Experimental Biology 12:363-365, July, 1974.
 
[20]  Mondal, S. and Chatterjee, S. P. Enhancement of methionine production by methionine analogue resistant mutants of Brevibacterium heali. Acta Biotechnology 14(2):199-204, 1994.
 
[21]  Mondal, S., Das, Y. B. and Chatterjee, S. P. Methionine production by microorganisms. Folia Microbiology 41: 465-472, 1996.
 
[22]  Gomes, J. and Kumar, D. Production of L-methionine by submerged fermentation: a review. Enzyme Microbial Technology 37(1): 3-18, June 2005.
 
[23]  Jankowski, J., Kubinska, M. and Zdunczyk, Z. Nutritional and immunomodulatory function of methionine in poultry diets- a review. Annals of Animal Science 14(1): 17-31, Feb. 2014.
 
[24]  Anusree, M. and Nampoothiri, K. M. White Biotechnology for Amino Acids. in Industrial Biorefineries and White Biotechnology, Edited by Pander, A., Hofer, R., Larroche, C., Tacherzadeh, M., Nampothiri, K. M., Elsevier, United Kingdom. 445-471. 2015.
 
[25]  Willkie, T. Methionine production- a critical review. Applied Microbiology and Biotechnology 98: 9893-9914, Nov. 2014
 
[26]  Figge, R., Soucaille, P., Barbier, G., Bestel-Corre, G., Boisart, C. and Chateau, M. Increasing methionine yield. European Patent (EP2573189A1), 2016.
 
[27]  Li, H., Wang, W. S., Li, Y. R., Zhang, L., Ding, Z. Y., Gu, Z. H. and Shi, G. Y. Metabolic engineering of Escherichia coli W3110 for the production of L-methionine. Journal of Industrial Microbiology and Biotechnology 44:75-88 Nov. 2017.
 
[28]  Zhuo, H. Y., Wu, W. J., Niu, K., Xu, Y. Y., Liu, Z. Q. and Zheng, Y. G. Enhanced L-methionine production by genetically engineered Escherichia coli through fermentation optimization. Biotechnology 9(3): 96 Feb. 2019.
 
[29]  Ganguly, S. and Satapathy, K. B. Microbial strain employed for L-methionine fermentation: An Extensive Review. International Journal of Advanced Research in Chemical Science 3(12 ): 7-8, Dec. 2016.
 
[30]  Ward, O. P. Fermentations raw material. in: Fermentation biotechnology: principles, processes and products. Saddle River, N. J. Prentice Hall; pp 59-71, 1989.
 
[31]  Ozulu, U. S., Nwanah, O. U., Ekwealor, C. C., Dike, S. K., Nwikpo, C. L. and Ekwealor, I. A. A new approach to screening for methionine-producing bacteria. British Microbiology Research Journal 2(1): 36-39, 2012.
 
[32]  Greenstein, J. P. and Wintz, M. Methionine. Chemistry of the amino acid, vol. 3. John Wiley & Sons New York. 2125-2155, 1961.
 
[33]  Chike-Mozie, L., Ekwealor, C. C., Ajogwu, T., Ekweanya, C. C. and Ekwealor, I. A. Fast screening method for detecting lysine-producing yeasts. Advances in Research 6(3): 1-4, Jan. 2016.
 
[34]  Oguntoyinbo, F. A., Sann, A. I., Franz, C. M. A. P. and Holzapfel, W. H. In-vitro fermentation studies for selection and evaluation of Bacillus strains as starter cultures for production of okpehe, a traditional African fermented condiment. International Journal of Food Microbiology 113(2): 208 -218, 2007.
 
[35]  Roy, S. K., Mishra, A. K. and Nanda, G. Extracellular production of L-methionine by Bacillus megaterium B71 isolated from soil. Current Science 53(24): 1296-1297, 1984
 
[36]  Kumar, D., Garg, S., Bisaria, V. S., Sreekrishnan, T. R. and Gomes, J. Production of methionine by multi-analogues resistant mutant of Corynebacterium lilium. Process Biochemistry 38: 1165-1171, 2003.
 
[37]  Dike, K. S. and Ekwealor, I. A. Studies on process and physical parameters for the production of L-methionine from newly isolated Bacillus cereus strains. Asian Journal of Biological Science 5: 96- 104, May 2012
 
[38]  Anakwenze, V. N., Ezemba, C. C. and Ekwealor, I. A. Optimization of fermentation conditions of Bacillus thuringensis EC1 for enhanced methionine production. Advances in Microbiology. 4(7): 344-352, May 2014.
 
[39]  Zhou, H. Y., Wu, W. J., Xu, Y. Y., Zhou, B., Niu, K., Liu. Z. Q. and Zheng, Y. G. Calcium Carbonate addition improves L-methionine biosynthesis by metabolically engineered Escherichia coli W3110-BL. Frontiers in Bioengineering and Biotechnology 8: 300, April 2020.
 
[40]  Pharm, C. B., Galvez, F. C. and Padolina, W. G. Methionine production by batch fermentations from various carbohydrates. ASEAN Food Journal 7(1): 34-37, 1992.
 
[41]  Venkata, N. A. and Swamy, A. V. N. Optimization of fermentation and nutritional parameters for the production of L-methionine by Corynebacterium glutamicum MTCC 2745 using agricultural products. Journal of Pharmaceutical Sciences and Research 9(6): 850-856, 2017.
 
[42]  Ganguly, S. and Banik, A. K. Induced mutation and selection of high yielding strains of Micrococcus glutamicus for glutamic acid production. Journal of the Indian Chemical Society 87(6): 717- 721, June 2010.
 
[43]  Bisht, S. D., Yadav, S. K. and Darmwal, N. S. Enhanced production of extracellular alkaline lipase by an improved strain of Pseudomonas aeruginosa MTCC 10,055. American Journal of Applied Sciences 9(2): 158-167, Jan. 2012.
 
[44]  Anakwenze, V. N., Ezemba, C. C. and Ekwealor, I. A. Improved cultural conditions for methionine accumulation in submerged cultivation of Bacillus cereus S8. Microbiology Research Journal International 4(8): 885-895, Aug. 2014.
 
[45]  Rahman, R. N., Geok, P. L., Basri, M. and Salleh, A. B. Physical factors affecting the production of organic solvent-tolerant protease by Peudomonas aeruginosa starin K. Bioresource Technology 96(4): 429-436, March 2005.
 
[46]  Nadeem, S., Niaz, B., Muzanamil, H. M., Rana, S. M., Rajoka, M. I. and Shakoori, A. R. Optimizing carbon and nitrogen sources for L-glutamic acid production by Brevibacyterium strain NIAR SS-67. Pakistan Journal of Zoology 43(2): 285-290, Jan. 2011.
 
[47]  Nand L., Jeevan, J. and Priti S. Optimization of carbon sources for amylase production and growth of Bacillus licheniformis JAR-26 under submerged fermentation. Indian Journal of Biology 4(1): 31-36, April 2017
 
[48]  Chattopadhyay, M. K., Sengupta, D. and Sengupta, S. Fermentative production of methionine by 5-bromouracil resistant mutants of Escherichia coli K-12. Medical Science Research 23:775, 1995.
 
[49]  Tani, Y, Lim, W. J. and Yang, H. C. Isolation of L-methionine enriched mutants of a methylotrophic yeast, Candida boidinii No2201. Journal of Fermentation Technology 66(2): 153-158, 1988.
 
[50]  Ghosh, B. B. and Banerjee, A. K. Production of methionine and glutamic acid from n-alkanes by Serratia marcescens var Kiliensis. Folia Microbiology 31(2): 106-112, Jan 1986.
 
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