Streptococcus thermophilus in Cheddar cheese – production and fate of galactose

VALÉRIE MICHEL; FRANK G. MARTLEY

doi:10.1017/S0022029901004812

Abstract

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The behaviour of Streptococcus thermophilus in combination with Lactococcus lactis subsp. cremoris or subsp. lactis mesophilic starters in experimental Cheddar cheese is reported. In a standard manufacturing procedure employing a 38 °C cook temperature, even very low levels (0·007%) of Str. thermophilus combined with normal levels of the mesophilic starter (1·7%) resulted in increased rates of acid production, the formation of significant amounts of galactose (∼ 13 mmol/kg cheese), and populations nearly equivalent to those of the mesophilic lactic starter in the curd before salting. At a 41 °C cook temperature, the Str. thermophilus attained a higher maximum population (∼ log 8·2 colony forming units (cfu)/g) than the Lc. lactis subsp. cremoris (∼ log 6·8 cfu/g) and formed more galactose (∼ 28 mmol/kg). Lactobacillus rhamnosus, deliberately added to a cheese made using Str. thermophilus starter and which contained 24 mmol galactose/kg at day one, utilized all the galactose during the first 3 months of cheese ripening. Adventitious non-starter lactic acid bacteria had the potential to utilize this substrate too, and a close relationship was demonstrated between the increase in this flora and the disappearance of the galactose. Some possible consequences for cheese quality of using Str. thermophilus as a starter component are discussed.

Crossref Citations

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Milesi, María Mercedes Vinderola, Gabriel Sabbag, Nora Meinardi, Carlos Alberto and Hynes, Erica 2009. Influence on cheese proteolysis and sensory characteristics of non-starter lactobacilli strains with probiotic potential. Food Research International, Vol. 42, Issue. 8, p. 1186.

Champagne, C.P. Gagnon, D. St-Gelais, D. and Vuillemard, J.C. 2009. Interactions between Lactococcus lactis and Streptococcus thermophilus strains in Cheddar cheese processing conditions. International Dairy Journal, Vol. 19, Issue. 11, p. 669.

St-Gelais, D. Lessard, J. Champagne, C.P. and Vuillemard, J.-C. 2009. Production of fresh Cheddar cheese curds with controlled postacidification and enhanced flavor. Journal of Dairy Science, Vol. 92, Issue. 5, p. 1856.

Neves, Ana R. Pool, Wietske A. Solopova, Ana Kok, Jan Santos, Helena and Kuipers, Oscar P. 2010. Towards Enhanced Galactose Utilization by Lactococcus lactis . Applied and Environmental Microbiology, Vol. 76, Issue. 21, p. 7048.

Bertolino, Marta Dolci, Paola Giordano, Manuela Rolle, Luca and Zeppa, Giuseppe 2011. Evolution of chemico-physical characteristics during manufacture and ripening of Castelmagno PDO cheese in wintertime. Food Chemistry, Vol. 129, Issue. 3, p. 1001.

Hickey, D.K. Guinee, T.P. Hou, J. and Wilkinson, M.G. 2013. Effects of variation in cheese composition and maturation on water activity in Cheddar cheese during ripening. International Dairy Journal, Vol. 30, Issue. 1, p. 53.

Stulova, Irina Kabanova, Natalja Kriščiunaite, Tiina Taivosalo, Anastassia Laht, Tiiu-Maie and Vilu, Raivo 2013. Fermentation of reconstituted milk by Streptococcus thermophilus: Effect of irradiation on skim milk powder. International Dairy Journal, Vol. 31, Issue. 2, p. 139.

Martinussen, Jan Solem, Christian Holm, Anders Koefoed and Jensen, Peter Ruhdal 2013. Engineering strategies aimed at control of acidification rate of lactic acid bacteria. Current Opinion in Biotechnology, Vol. 24, Issue. 2, p. 124.

Van Calcar, Sandra C. Bernstein, Laurie E. Rohr, Frances J. Yannicelli, Steven Berry, Gerard T. and Scaman, Christine H. 2014. Galactose Content of Legumes, Caseinates, and Some Hard Cheeses: Implications for Diet Treatment of Classic Galactosemia. Journal of Agricultural and Food Chemistry, Vol. 62, Issue. 6, p. 1397.

Murtaza, Mian Anjum Ur-Rehman, Salim Anjum, Faqir Muhammad Huma, Nuzhat and Hafiz, Iram 2014. Cheddar Cheese Ripening and Flavor Characterization: A Review. Critical Reviews in Food Science and Nutrition, Vol. 54, Issue. 10, p. 1309.

Umamaheswari, Thiyagamoorthy Anbukkarasi, Kaliyaperumal Singh, Prashant Tomar, Sudhir K and Singh, Rameshwar 2014. Streptococcus thermophilus strains of plant origin as dairy starters: Isolation and characterisation. International Journal of Dairy Technology, Vol. 67, Issue. 1, p. 117.

Ortakci, Fatih Broadbent, Jeffery R. Oberg, Craig J. and McMahon, Donald J. 2015. Late blowing of Cheddar cheese induced by accelerated ripening and ribose and galactose supplementation in presence of a novel obligatory heterofermentative nonstarter Lactobacillus wasatchensis. Journal of Dairy Science, Vol. 98, Issue. 11, p. 7460.

Ortakci, Fatih Broadbent, Jeffery R. Oberg, Craig J. and McMahon, Donald J. 2015. Growth and gas production of a novel obligatory heterofermentative Cheddar cheese nonstarter lactobacilli species on ribose and galactose. Journal of Dairy Science, Vol. 98, Issue. 6, p. 3645.

Ortakci, Fatih Broadbent, Jeffery R. Oberg, Craig J. and McMahon, Donald J. 2015. Growth and gas formation by Lactobacillus wasatchensis, a novel obligatory heterofermentative nonstarter lactic acid bacterium, in Cheddar-style cheese made using a Streptococcus thermophilus starter. Journal of Dairy Science, Vol. 98, Issue. 11, p. 7473.

Wu, Qinglong Cheung, Christine K.W. and Shah, Nagendra P. 2015. Towards galactose accumulation in dairy foods fermented by conventional starter cultures: Challenges and strategies. Trends in Food Science & Technology, Vol. 41, Issue. 1, p. 24.

Bancalari, Elena Bernini, Valentina Bottari, Benedetta Neviani, Erasmo and Gatti, Monica 2016. Application of Impedance Microbiology for Evaluating Potential Acidifying Performances of Starter Lactic Acid Bacteria to Employ in Milk Transformation. Frontiers in Microbiology, Vol. 7, Issue. ,

Hou, Jia Hannon, John A. McSweeney, Paul L.H. Beresford, Thomas P. and Guinee, Timothy P. 2017. Effect of galactose metabolising and non-metabolising strains of Streptococcus thermophilus as a starter culture adjunct on the properties of Cheddar cheese made with low or high pH at whey drainage. International Dairy Journal, Vol. 65, Issue. , p. 44.

Pham, Nguyen-Phuong Layec, Séverine Dugat-Bony, Eric Vidal, Marie Irlinger, Françoise and Monnet, Christophe 2017. Comparative genomic analysis of Brevibacterium strains: insights into key genetic determinants involved in adaptation to the cheese habitat. BMC Genomics, Vol. 18, Issue. 1,

Martínez-Carmona, Marina Gun’ko, Yurii K. and Vallet-Regí, María 2018. Mesoporous Silica Materials as Drug Delivery: “The Nightmare” of Bacterial Infection. Pharmaceutics, Vol. 10, Issue. 4, p. 279.

Münger, Linda H Garcia-Aloy, Mar Vázquez-Fresno, Rosa Gille, Doreen Rosana, Albert Remus R Passerini, Anna Soria-Florido, María-Trinidad Pimentel, Grégory Sajed, Tanvir Wishart, David S Andres Lacueva, Cristina Vergères, Guy and Praticò, Giulia 2018. Biomarker of food intake for assessing the consumption of dairy and egg products. Genes & Nutrition, Vol. 13, Issue. 1,

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Streptococcus thermophilus in Cheddar cheese – production and fate of galactose

Abstract

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This article has been cited by the following publications. This list is generated based on data provided by Crossref.

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Streptococcus thermophilus in Cheddar cheese – production and fate of galactose

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