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Influence of the culture preparation and the addition of an adjunct culture on the ripening profiles of hard cheese

Published online by Cambridge University Press:  07 February 2019

Facundo Cuffia*
Affiliation:
Instituto de Lactología Industrial (INLAIN-UNL/CONICET), Santiago del Estero 2829, S3000AOM, Santa Fe, Argentina
Carina Viviana Bergamini
Affiliation:
Instituto de Lactología Industrial (INLAIN-UNL/CONICET), Santiago del Estero 2829, S3000AOM, Santa Fe, Argentina
Irma Verónica Wolf
Affiliation:
Instituto de Lactología Industrial (INLAIN-UNL/CONICET), Santiago del Estero 2829, S3000AOM, Santa Fe, Argentina
Erica Ruth Hynes
Affiliation:
Instituto de Lactología Industrial (INLAIN-UNL/CONICET), Santiago del Estero 2829, S3000AOM, Santa Fe, Argentina
María Cristina Perotti
Affiliation:
Instituto de Lactología Industrial (INLAIN-UNL/CONICET), Santiago del Estero 2829, S3000AOM, Santa Fe, Argentina
*
*Authors for correspondence: Facundo Cuffia, Email: fcuffia@unl.edu.ar

Abstract

The aim of this work was to evaluate the impact of two factors on the ripening profiles of hard cooked cheeses: (F1) the growth medium for the primary and adjunct cultures, constituted by autochthonous strains: Lactobacillus helveticus 209 (Lh209) and Lactobacillus paracasei 90 (Lp90), respectively, and (F2) the addition of L. paracasei Lp90 as adjunct culture. Four types of cheeses were made: W and M cheeses in which only Lh209 was added after its growth in whey and MRS, respectively; Wa and Ma cheeses in which both strains (Lh209 and Lp90) were added after their growth in whey and MRS, respectively. Physicochemical and microbial composition, proteolysis and profiles of organic acids and volatile compounds were analyzed. According to the methodology of the cultures preparation, W and Wa cheeses showed a higher level of secondary proteolysis and lower level of primary proteolysis (P < 0·05), lower content of citric and acetic acids and higher amount of propionic acid (P < 0·05), in comparison with M and Ma cheeses. The incorporation of Lp90 increased the secondary proteolysis (P < 0·05), decreased the citric acid (P < 0·05), and increased the propionic acid only when was added after their growth in whey (P < 0·05). Both factors significantly modified the percentages of the volatile compounds grouped in chemical families; in addition, for the half of the compounds detected, significant differences were found. Based on the obtained results, the use of Lp90 as an adjunct in hard cooked cheeses, and the preincubation of the cultures in whey are strategies to accelerate the cheese ripening and to enhance the production of some characteristic compounds of this type of cheeses, such as propan-2-one, hexan-2-one, 2- and 3-methyl butanal, heptan-2-ol, acetic and 3-methylbutanoic acids and 3-hydroxy butan-2-one.

Type
Research Article
Copyright
Copyright © Hannah Dairy Research Foundation 2019 

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References

Beresford, T, Fitzsimons, N, Brennan, N & Cogan, T (2001) Recent advances in cheese microbiology. International Dairy Journal 11, 259274.Google Scholar
Bergamini, C, Peralta, G, Milesi, M & Hynes, E (2013) Growth, survival and peptidolytic activity of Lactobacillus plantarum I91 in a hard-cheese model. Journal of Dairy Science 96, 54655476.Google Scholar
Bradley, R, Arnold, E, Barbano, D, Semerad, R, Smith, D & Vines, B (1993) Chemical and physical methods. In Standard Methods for the Examination of Dairy Product, pp. 433532 (Ed. Marshall, R), Washington, DC: American Public Health Association (APHA).Google Scholar
Briggiler-Marcó, M, Capra, M, Quiberoni, A, Vinderola, C, Reinheimer, J & Hynes, E (2007) Nonstarter Lactobacillus strains as adjunct cultures for cheese making: in vitro characterization and performance in two model cheeses. Journal of Dairy Science 90, 45324542.Google Scholar
Bude-Ugarte, M, Guglielmotti, D, Giraffa, G, Reinheimer, J & Hynes, E (2006) Nonstarter lactobacilli isolated from Soft and Semihard Argentinean cheeses: genetic characterization and resistance to biological barriers. Journal of Food Protection 69, 29832991.Google Scholar
Buffa, M, Guamis, B, Saldo, J & Trujillo, A (2004) Changes in organic acids during ripening of cheeses made from raw, pasteurized or high-pressure-treated goats’ milk. LWT-Food Science and Technology 37, 247253.Google Scholar
Burns, P, Molinari, F, Beccaria, A, Páez, R, Meinardi, C, Reinheimer, J & Vinderola, G (2010) Suitability of buttermilk for fermentation with Lactobacillus helveticus and production of a functional peptide-enriched powder by spray-drying. Journal of Applied Microbiology 109, 13701378.Google Scholar
Candioti, M, Hynes, E, Quiberoni, A, Palma, S, Sabbag, N & Zalazar, C (2002) Reggianito Argentino cheese: influence of Lactobacillus helveticus strains isolated from natural whey cultures on cheese making and ripening processes. International Dairy Journal 12, 923931.Google Scholar
Crow, V, Curry, B & Hayes, M (2001) The ecology of non-starter lactic acid bacteria (NSLAB) and their use as adjuncts in New Zealand Cheddar. International Dairy Journal 11, 275283.Google Scholar
Fox, P, Guinee, T, Cogan, T & McSweeney, P (2000) Biochemistry of cheese ripening. In Fundamentals of Cheese Science, pp. 236281 (Ed. Fox, PF). Maryland: Aspen Publishers.Google Scholar
Gatti, M, Bottari, B, Lazzi, C, Neviani, E & Mucchetti, G (2014) Invited review: microbial evolution in raw-milk, long-ripened cheeses produced using undefined natural whey starters. Journal of Dairy Science 97, 573591.Google Scholar
García-Cayuela, T, Gómez de Cadiñanos, L, Peláez, C & Requena, T (2012) Expression in Lactococcus lactis of functional genes related to amino acid catabolism and cheese aroma formation is influenced by branched chain amino acids. International Journal of Food Microbiology 159, 207213.Google Scholar
Hickey, C, Auty, M, Wilkinson, M & Sheehan, J (2017) Influence of process temperature and salting methods on starter and NSLAB growth and enzymatic activity during the ripening of cheeses produced with Streptococcus thermophilus and Lactobacillus helveticus. International Dairy Journal 69, 918.Google Scholar
Hynes, E, Bergamini, C, Suárez, V & Zalazar, C (2003) Proteolysis on Reggianito Argentino cheeses manufactured with natural whey cultures and selected strains of Lactobacillus helveticus. Journal of Dairy Science 86, 38313840.Google Scholar
Irigoyen, A, Ortigosa, M, Juansaras, I, Oneca, M & Torre, P (2007) Influence of an adjunct culture of Lactobacillus on the free amino acids and volatile compounds in a Roncal-type ewes-milk cheese. Food Chemistry 100, 7180.Google Scholar
ISO (2004) Cheese and processed cheese – determination of the total solids content. (Reference method). ISO 5534-IDF 4. International Organization for Standardization, Geneva, Switzerland.Google Scholar
ISO (2008) Cheese – determination of fat content – Van Gulik method. ISO 3433-IDF 222. International Organization for Standardization, Geneva, Switzerland.Google Scholar
ISO (2011) Milk and milk products – determination of nitrogen content – part 1: Kjeldahl principle and crude protein calculation. ISO 8968-IDF 20. International Organization for Standardization, Geneva, Switzerland.Google Scholar
Jensen, M & Ardö, Y (2010) Variation in aminopeptidase and aminotransferase activities of six cheese related Lactobacillus helveticus strains. International Dairy Journal 20, 149155.Google Scholar
Milesi, M, Vinderola, G, Sabbag, N, Meinardi, C & Hynes, E (2009) Influence on cheese proteolysis and sensory characteristics of non-starter lactobacilli strains with probiotic potential. Food Research International 42, 11861196.Google Scholar
Milesi, M, Wolf, I, Bergamini, C & Hynes, E (2010) Two strains of nonstarter lactobacilli increased the production of flavor compounds in soft cheeses. Journal of Dairy Science 93, 50205031.Google Scholar
Pedersen, T, Ristagno, D, McSweeney, P, Vogensen, F & Ardö, Y (2013) Potential impact on cheese flavour of heterofermentative bacteria from starter cultures. International Dairy Journal 33, 112119.Google Scholar
Peralta, G, Wolf, I, Perotti, M, Bergamini, C & Hynes, E (2016) Formation of volatile compounds, peptidolysis and carbohydrate fermentation by mesophilic lactobacilli and streptoccocci cultures in a cheese extract. Dairy Science and Technology 96, 603621.Google Scholar
Peralta, G, Bergamini, C, Audero, G, Páez, R, Wolf, I, Perotti, M & Hynes, E (2017) Spray-dried adjunct cultures of autochthonous non-starter lactic acid bacteria. International Journal of Food Microbiology 255, 1724.Google Scholar
Perotti, M, Bernal, S, Meinardi, C & Zalazar, C (2005) Free fatty acid profiles of Reggianito Argentino cheese produced with different starters. International Dairy Journal 15, 11501155.Google Scholar
Poveda, J, Nieto-Arribas, P, Seseña, S, Chicón, R, Castro, L, Palop, L & Cabezas, L (2014) Volatile composition and improvement of the aroma of industrial Manchego cheese by using Lactobacillus paracasei subsp. paracasei as adjunct and other autochthonous strains as starters. European Food Research Technology 238, 485494.Google Scholar
Reinheimer, J, Suárez, V, Bailo, N & Zalazar, C (1995) Microbiological and technological characteristics of natural whey cultures for Argentinean hard cheese production. Journal of Food Protection 54, 796799.Google Scholar
Reinheimer, J, Quiberoni, A, Tailliez, P, Binetti, A & Suárez, V (1996) The lactic acid microflora of natural whey starters used in Argentina on hard cheese production. International Dairy Journal 6, 869879.Google Scholar
Rossetti, L, Fornasari, M, Gatti, M, Lazzi, C, Neviani, E & Giraffa, G (2008) Grana Padano cheese whey starters: microbial composition and strain distribution. International Journal of Food Microbiology 127, 168171.Google Scholar
Thage, B, Broe, M, Petersen, MH, Petersen, MA, Bennedsen, M & Ardö, Y (2005) Aroma development in semihard reduced-fat cheese inoculated with Lactobacillus paracasei strains with different aminotransferase profiles. International Dairy Journal 15, 795805.Google Scholar
van Kranenburg, R, Kleerebezem, M, van Hylckama Vlieg, J, Ursing, B, Boekhorst, J, Smit, B, Ayad, E, Smit, G & Siezen, R (2002) Flavour formation from amino acids by lactic acid bacteria: predictions from genome sequence analysis. International Dairy Journal 12, 111121.Google Scholar
Vélez, M, Perotti, M, Wolf, I, Hynes, E & Zalazar, C (2010). Influence of milk pre-treatment on production of FFA and volatile compounds in hard cheeses: heat treatment and mechanical agitation. Journal of Dairy Science 93, 45454554.Google Scholar
Vélez, M, Perotti, M, Rebechi, S, Meinardi, C, Hynes, E & Zalazar, C (2011) Effect of mechanical treatments applied to milk fat on fat retention and lipolysis in minicurds. International Journal of Dairy Technology 64, 227231.Google Scholar
Wolf, I, Perotti, M, Bernal, S & Zalazar, C (2010) Study of the chemical composition, proteolysis, lipolysis and volatile compounds profile of commercial Reggianito Argentino cheese: characterization of Reggianito Argentino cheese. Food Research International 43, 12041211.Google Scholar
Yvon, M (2006) Key enzymes for flavor formation by lactic acid bacteria. Australian Journal of Dairy Technology 61, 1624.Google Scholar
Yvon, M, Chambellon, E, Bolotin, A & Roudot-Algaron, F (2000) Characterization and role of the branched-chain aminotransferase (BcaT) isolated from Lactococcus lactis subsp. cremoris NCDO 763. Applied and Environmental Microbiology 66, 571577.Google Scholar