Low-cost culture medium for biomass production of lactic acid bacteria with probiotic potential destined to broilers

Authors

  • Ayelen P. BERISVIL , ,
  • Diego M. ASTESANA , ,
  • Jorge A. ZIMMERMANN , ,
  • Laureano S. FRIZZO , ,
  • Eugenia ROSSLER , ,
  • Analía ROMERO-SCHARPEN , ,
  • Carolina R. OLIVERO , ,
  • María V. ZBRUN , ,
  • Marcelo L. SIGNORINI , ,
  • Gabriel J. SEQUEIRA , ,
  • Silvina DRAGO , ,
  • Lorena P. SOTO , ,

DOI:

https://doi.org/10.14409/favecv.v20i1.9978

Keywords:

probiotic, biomass production, Lactobaciullus salivarius, whey permeate

Abstract

The aim of this study was to evaluate different low-cost culture media for biomass production of 3 potential probiotic L. salivarius strains, which could be destined to broilers at farms. Different formulated media based on whey permeate (WP) supplemented with nitrogenous sources were evaluated: yeast extract (YE), whey hydrolysate (WH) and MnSO4.H2O (Mn), MgSO4.7H2O (Mg). The growth of each strain in the formulated media and the cost was compared with their growth and cost in commercial medium (MRS). L. salivarius DSPV008P did not grow adequately in any of the formulated media. On the other hand, addition of YE and Mn in the formulated media increased L. salivarius DSPV002P and L. salivarius DPSV011P growth. In contrast, WH and Mg addition increased the L. salivarius DSPV002P biomass only. L. salivarius DSPV011P was the only strain that had similar growth performance in MRS as in the selected medium: WP + YE 8g/l + Mn. In this sense, L. salivarius DSPV011P reached a biomass of 9.22 Log (CFU/ml) in the selected formulated medium, with a low-cost growth medium 12 times less than in MRS. Although the effect of supplements added to the culture medium on kinetic parameters are strain dependent, L. salivarius DSPV011P is the strain with the best technological characteristics, capable of growing in a medium based on a by-product of the dairy industry supplemented with YE and Mn and at a much less cost than in MRS medium.

References

Aguirre-Ezlcauriatza EJ, Aguilar-Yañes JM, Ramirez Medrano A, Alvarez MM. 2010. Producción of probiotic biomass (Lactobacillus casei) in goat milk whey: comparion of batch, continuous and fed-batch culture. Bioresour. Technol. 101: 2837-2844.

Altaf M, Naveena BJ, Gopal R. 2007. Use of inexpensive nitrogen sources and starch for L(+) lactic acid production in anaerobic submerged fermentation. Bioresour. Technol. 93: 498-503.

Amrane A, Prigent Y. 1998. Influence of yeast extract concentration on batch cultures of Lactobacillus helveticus: growth and production coupling. World J. Microb. Biot. 14: 529-534.

Bedford M. 2000. Removal of antibiotic growth promoters from poultry diets: implications and strategies to minimise subsequent problems. World Poultry Sci. J. 56: 347-365.

Blajman J, Gaziano C, Zbrun MV, Soto L, Astesana D, Berisvil A, Scharpen AR, Signorini M, Frizzo L. 2015. In vitro and in vivo screening of native lactic acid bacteria towards their selection as probiotic in broilers. Res. Vet. Sci. 101: 50-6.

Blajman JE, Olivero CA, Fusari ML, Zimmermann JA, Rossler E, Berisvil AP, Romero Scharpen A, Astesana D, Soto LP, Signorini ML, Zbrun, MV, Frizzo LS. 2017. Impact of lyophilized Lactobacillus salivarius DSPV 001P administration on growth performance, microbial translocation, and gastrointestinal microbiota of broilers reared under low ambient temperature. Res. Vet. Sci. 114: 388-394.

Cui F, Wan C, Li Y, Liu Z, Rajashekara G. 2012. Co-production of lactic acid and Lactobacillus rhamnosus cells from whey permeate with nutrient supplements. Food Bioprocess. Tech. 5: 1278-1286

Dąbrowska A, Babij K, Szołtysik M, Chrzanowska J. 2017. Viability and growth promotion of starter and probiotic bacteria in yogurt supplemented with whey protein hydrolysate during refrigerated storage. Postep. Hig. Med. Dosw. 71: 952-959.

De Man, J.C., Rogosa, M., Sharpe, M.E. 1960. A medium for the cultivation of lactobacilli. J. Appl. Bacteriol. 23: 130-135.

Duarte, A. 1998. Introducción a la Ingeniería Bioquímica. Ed. Universidad Nacional de Colombia: Bogotá. 198pp.

FAO WHO. 2001. Evaluation of health and nutritional properties of probiotics in food, including powder milk with live lactic acid bacteria. Food and Agricultural Organization of United Nations and World Health Organization Expert Consultation Report. London, Ontario, Canadá.

Hammes WP, Hertel C. Genus I. Lactobacillus. In de Vos P., Garrity GM, Jones D, Krieg NR, Ludwig W, Rainey FA, Schleifer KH, Whitman WB. (Eds.). 2009. Bergey’s manual of systematic bacteriology (2nd ed.) 3: 465-511.

Hossain MI, Sadekuzzaman M, Ha SD. 2017. Probiotics as potential alternative biocontrol agents in the agriculture and food industries: A review. Food Res. Int. 100: 63-73.

Hu Y, Dun Y, Li S, Zhao S, Peng N, Liang Y. 2014. Effects of Bacillus subtilis KN-42 on growth performance, diarrhea and faecal bacterial flora of weaned piglets. Asian-Australas. J Anim. Sci. 27: 1131-40.

Hugo AA, Bruno F, Golowczyc MA. 2016. Whey permeate containing galacto-oligosaccharides as a medium for biomass production and spray drying of Lactobacillus plantarum CIDCA 83114. LWT - Food Sci. Technol. 69: 185-190.

Hung AT, Lin SY, Yang TY, Chou CK, Liu HC, Lu JJ, Wang B, Chen SY. 2012. Effects of Bacillus coagulans ATCC 7050 on growth performance, intestinal morphology, and microflora composition in broiler chickens. Anim. Prod. Sci. 52: 874-879.

Kareba O, Champagnea CP, Jeana J, Gomaa A, Aidera M. 2018. Effect of electro-activated sweet whey on growth of Bifidobacterium, Lactobacillus, and Streptococcus strains under model growth conditions. Food Res. Int. 103: 316-325.

Kwon S, Lee PC, Lee EG, Chang YK, Chang N. 2000. Production of lactic acid by Lactobacillus rhamnosus with vitamin-supplemented soybean hydrolizate. Enzym. Microb. Technol. 26: 209-215.

Lavari L, Ianniello R, Páez R, Zotta T, Cuatrin A, Reinheimer J, Parente E, Vinderola G. 2015. Growth of Lactobacillus rhamnosus 64 in whey permeate and study of the effect of mild stresses on survival to spray drying. LWT - Food Sci. Technol. 63: 322-330.

Lazzi C, Meli F, Lambertini F, Bottesini C, Nikolaev I, Gatti M, Sforza S, Koroleva O, Popov V, Neviani E, Dossena A. 2013. Growth pro¬motion of Bifidobacterium and Lactobacillus species by proteinaceous hydrolysates derived from poultry processing leftovers. Int. J. Food Sci. Technol. 48: 341-9.

León-de la O DI, Calderón-Yépez B, Martínez-Ballinas I, Sánchez-Herrera E.M, Zulatto-Lobato AC, Camacho-

Hernández I, Arredondo-Villanueva AL, Salgado-Brito R. 2013. Formulation and optimization of an economic broth culture for Lactobacillus with probiotic potential isolated from pulque. Investigación Universitaria Multidisciplinaria: Revista de Investigación de la Universidad Simón Bolívar 12: 133-144.

Lew LC, Gan CY, Liong MT. 2012. Growth optimization of Lactobacillus rhamnosus FTDC 8313 and the production of putative dermal bioactives in the presence of manganese and magnesium ions. J. Appl. Microbiol. 114: 526-535.

Liao SF, Nyachoti M. 2017. Using probiotics to improve swine health and nutrient utilization. Anim. Nutr. 3: 331–343.

Macedo MG, Lacroix C, Gardner NJ, Champagne CP. 2002. Effect of medium supplementation on exopolysaccharide production by Lactobacillus rhamnosus RW-9595M in whey permeate. Int. Dairy J. 5: 419-426.

Manca de Nadra MC. 2007. Nitrogen metabolism in lactic acid bacteria from fruits: A review. En: A. Méndez-Vilas, editor. Communicating current research and educational topics and trends in applied microbiology. Formatex. Pp. 500-510.

Madigan MT, Martinko JM, Parker J. 2004. Biología de los microorganismos. 10a ed. Prentice Hall. Madrid, España. 991 pp.

Mikelsaar M, Sepp E, Štšepetova J, Hütt P, Zilmer K, Kullisaar T, Zilmer M. 2015. Regulation of plasma lipid profile by Lactobacillus fermentum (probiotic strain ME-3 DSM14241) in a randomised controlled trial of clinically healthy adults. BMC Nutr. 1: 1-27.

Niba AT, Beal JD, Kudi AC, Brooks PH. 2009. Bacterial fermentation in the gastrointestinal tract of non-ruminants: influence of fermented feeds and fermentable carbohydrates. Trop. Anim. Health Pro. 41: 1393–1407.

Nielsen PM, Petersen D, Dambmann, C. 2001. Improved method for determining food protein degree of hydrolysis. J. Food Sci. 66: 642-646.

Raccach M. 1985. Manganese and lactic acid bacteria. J. Food Protect. 48: 895-898.

Remely M, Aumueller E, Jahn D, Hippe B, Brath H, Haslberger AG. 2014. Microbiota and epigenetic regulation of inflammatory mediators in type 2 diabetes and obesity. Benef. Microbes 5: 33-43.

Scallan E, Hoekstra RM, Angulo FJ, Tauxe RV, Widdowson MA, Roy SL, Jones JL, Griffin PM. 2011. Foodborne illness acquired in the United States—major pathogens. Emerg. Infect. Dis. 17: 7-15.

SENASA. Resolución 294/2015. 2015. http://www.senasa.gov.ar/senasa-comunica/noticias/nuevas-pautas-tecnicas-para-la-elaboracion-de-productos destinados-la-alimentación-de-animales.

Shenderov BA. 2012. Gut microbiota indígena y epigenética. Microbial Ecol. Health Dis. 23: 75-85.

Soto LP, Drago SR, Frizzo LS, Diaz A, Gonzalez R, Rosmini MR. 2006. Efecto de hidrolizados proteicos sobre el crecimiento de Lactobacillus casei DSPV 318T. II Simposio Internacional de Bacterias Lácticas. Primer encuentro Red BAL Argentina, San Miguel de Tucumán, Argentina.

Trigueros DEG, Fiorese ML, Kroumov AD, Hinterholz CL, Nadai BL, Assuncao GM. 2016. Medium optimization and kinetics modeling for the fermentation ofhydrolyzed cheese whey permeate as a substrate for Saccharomycescerevisiae var. boulardii. Biochem. Eng. J. 110:71-83.

Vázquez S, Crosa MJ, Rey F, Lopretti M. 2009. Viabilidad del uso de suero de quesería como base del medio de cultivo de la cepa nativa probiótica Lactobacillus paracasei HA9-2. INNOTEC 4: 10-4.

Vinderola CG, Bailo N, Reinheimer JA. 2000. Survival of probiotic microflora in Argentinian yoghurts during refrigerated storage. Food Res. Int. 33: 97-102.

Weymarn N, Hujanen M, Leisola M. 2002. Production of D-mannitol by heterofermentative lactic acid bacteria. Process. Biochem. 37:1207–13.

Wood BJB, Holzapfel WH. 1995. The genera of lactic acid bacteria. 1st Edition. Blackie Academic & professional. 398 pp.

Zacharof MP, Lovitt RW, Ratanapongleka K. 2009. Optimization of Growth Conditions for Intensive Propagation, Growth Development and Lactic Acid Production of Selected Strains of 'Lactobacilli'. In: Engineering Our Future: Are We up to the Challenge?: 27 - 30 September 2009, Burswood Entertainment Complex. Barton, ACT: Engineers Australia

Zapata JE, Hoyos M, Quinchía LA. 2005. Kinetic parameters of growth of Saccharomyces cerevisiae affected by a varying magnetic field of low intensity and high frequency. Vitae 12: 39-44.

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Published

2020-12-23

Issue

Vol. 20 No. 1 (2021): FAVE Sección Ciencias Veterinarias

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Original articles

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How to Cite

Low-cost culture medium for biomass production of lactic acid bacteria with probiotic potential destined to broilers. (2020). FAVE Sección Ciencias Veterinarias, 20(1), 1-9. https://doi.org/10.14409/favecv.v20i1.9978

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