Flavour precursor development in Cheddar cheese due to lactococcal starters and the presence and lysis of Lactobacillus helveticus.

The rapid release of intracellular enzymes due to autolysis of lactic acid bacteria in the cheese matrix has been shown to accelerate cheese ripening. The objective of this work was to investigate the evolution of the flavour precursors, individual free amino acids (FAAs), free fatty acids (FFAs) and volatile compounds that contribute to the sensory profiles of cheeses at 2, 6 and 8 months of ripening in Cheddar cheese manufactured using starter systems which varied with respect to their autolytic properties. Starter system A contained a blend of two commercial Lactococcus lactis strains (223 and 227) which had a low level of autolysis. System B was identical to A but also included a highly autolytic strain of Lactobacillus helveticus (DPC4571). System C contained only strain DPC4571. Levels of all individual FAAs were elevated in cheeses B and C relative to A after 2 months of ripening. By 8 months of ripening the main FAA were glutamate, leucine, lysine, serine, proline and valine. Levels of C_6:0, C_8:0, C_12:0 and C_18:0 fatty acids did not vary greatly over ripening, while levels of C_4:0, C_10:0, C_14:0, C_16:0 and C_18:1 were elevated in cheeses B and C. Principal component analysis of the headspace volatiles separated cheese A from cheeses B and C. Cheeses B and C had highest levels of dimethyl disulphide, carbon sulphide, heptanal, dimethyl sulphide, ethyl butanoate, 2-butanone, and 2-methyl butanal and were described as having a ‘caramel’ odour and ‘sweet’, ‘acidic’ and ‘musty’ flavour. Cheese A had highest levels of 2-butanol, 2-pentanone, 2-heptanone, 1-hexanol and heptanal and was described as having a ‘sweaty/ sour’ odour and ‘soapy’, ‘bitter’ and ‘mouldy’ flavour. The results highlight the impact of starter lactococci on flavour precursor development and the positive effect of Lb. helveticus and the lysis of this strain on enhancing levels of substrate and flavour precursors early during ripening resulting in early flavour development.     

Starter strain related effects on the biochemical and sensory properties of Cheddar cheese

A detailed investigation was undertaken to determine the effects of four single starter strains, Lactococcus lactis subsp. lactis 303, Lc. lactis subsp. cremoris HP, Lc. lactis subsp. cremoris AM2, and Lactobacillus helveticus DPC4571 on the proteolytic, lipolytic and sensory characteristics of Cheddar cheese. Cheeses produced using the highly autolytic starters 4571 and AM2 positively impacted on flavour development, whereas cheeses produced from the poorly autolytic starters 303 and HP developed off-flavours. Starter selection impacted significantly on the proteolytic and sensory characteristics of the resulting Cheddar cheeses. It appeared that the autolytic and/or lipolytic properties of starter strains also influenced lipolysis, however lipolysis appeared to be limited due to a possible lack of availability or access to suitable milk fat substrates over ripening. The impact of lipolysis on the sensory characteristics of Cheddar cheese was unclear, possibly due to minimal differences in the extent of lipolysis between the cheeses at the end of ripening. As anticipated seasonal milk supply influenced both proteolysis and lipolysis in Cheddar cheese. The contribution of non-starter lactic acid bacteria towards proteolysis and lipolysis over the first 8 months of Cheddar cheese ripening was negligible.     

Autolysis of selected Lactobacillus helveticus adjunct strains during Cheddar cheese ripening

Cheddar cheeses were manufactured on a pilot scale (500 L vats) with three different Lactobacillus helveticus strains, which showed varying degrees of autolysis, added as adjuncts to the starter. Autolysis of adjunct strains was monitored by reduction in cell numbers, level of intracellular enzymes released into the cheese, and by the consequent changes in the degree of proteolysis and concentration of free amino acids in the cheese. The flavour profiles of the cheeses at 6 months were also determined. Significant variation in viability of the Lb. helveticus strains, which showed a positive correlation with the indicators of autolysis, was observed. However, cheese manufactured with the most autolytic strain did not receive the highest flavour scores. The results indicate that whereas autolysis of adjunct strains is an important factor in Cheddar cheese flavour development, other factors also contribute to the overall flavour improvement observed.     

The Use of Viable and Heat-shocked Lactobacillus helveticus DPC 4571 in Enzyme-Modified Cheese Production

The use of viable or attenuated Lactobacillus helveticus DPC 4571 for use in enzyme-modified cheese production was assessed. Optimal heat shocking conditions for attenuation of DPC 4571 were found to be 69°C for 25 sec. Enzyme-modified cheese was produced from an emulsion of pre-hydrolysed rennet curd, water, and butter fat. This substrate was heat-treated and inoculated with either an equivalent level of viable or attenuated cells of DPC 4571 and further incubated under controlled conditions. The heat-treated products produced using attenuated DPC 4571 had a preferred sensory character with strong cheesy savory notes, enhanced secondary proteolysis, and more key volatile flavor compounds than those produced with viable DPC 4571. However, prolonged incubation (>16 h) resulted in growth of advantageous enterococci, which adversely influenced the sensory profile.     

Invited review: Lactobacillus helveticus—A thermophilic dairy starter related to gut bacteria

The strain Lactobacillus helveticus DPC4571 has emerged as a promising flavor adjunct culture for Cheddar cheese given that it is consistently associated with improved flavor. The availability of the complete genome sequence of Lb. helveticus DPC4571 has enabled the search for the presence or absence of specific genes on the genome, in particular those of technological interest. Indeed, this analysis has facilitated a greater understanding into the functioning of lactic acid bacteria as a whole. The biochemical pathways of Lb. helveticus responsible for producing flavor compounds during cheese ripening are poorly understood but now with the availability of a complete genomic sequence are ripe for exploitation. Bioinformatic analysis of the genome of Lb. helveticus DPC4571 has revealed a plethora of genes with industrial potential including those responsible for key metabolic functions that contribute to cheese flavor development such as proteolysis, lipolysis, and cell lysis. In addition, it has been demonstrated that Lb. helveticus has the potential to produce bioactive peptides such as angiotensin converting enzyme inhibitory activity in fermented dairy products, demonstrating the therapeutic value of this species. A most intriguing feature of the genome of Lb. helveticus DPC4571 is the remarkable similarity in gene content with many intestinal lactobacilli, although originating from considerably different environments. Bioinformatic analysis demonstrated that 65 to 75% of genes were conserved between the commensal and dairy lactobacilli, which allowed key niche-specific gene sets to be described. This review focuses on the isolation, characterization, and exploitation of the Lb. helveticus species with particular emphesis on taking into consideration recent genome sequence data for Lb. helveticus and other Lactobacillus species.     

Characterisation of proteolysis profile of Argentinean sheep cheeses made by two different production methods

BACKGROUND: In this work the proteolysis profiles of Argentinean sheep cheeses made by two different production methods were studied in order to develop products with typical and defined features. Cheeses with a starter of Streptococcus thermophilus, curd cut to corn grain size, washed and heated to 43 °C (S cheeses) and cheeses with a mixed starter of Streptococcus thermophilus, Lactobacillus helveticus and Lactobacillus bulgaricus, curd cut to rice grain size, unwashed and heated to 47 °C (L cheeses) were manufactured. The cheeses were ripened at 12 °C and 80% relative humidity for 180 days and samples were taken throughout this period. RESULTS: Gross composition and primary proteolysis were similar for both types of cheeses. Streptococci counts diminished from 10⁹ to 10⁷ colony‐forming units g^?1 during ripening in both S and L cheeses. Lactobacilli counts in L cheeses decreased during ripening and disappeared at 180 days. L cheeses had significantly lower pH values and showed higher peptidolysis than S cheeses. Triangle sensory evaluation indicated important differences between the two types of cheeses. CONCLUSION: S cheeses had a low proteolysis level and a soft flavour, making them appropriate for consumption after a short ripening time. L cheeses had a higher proteolysis level and more intense sensory characteristics, making them appropriate for consumption after a longer ripening time. Copyright © 2009 Society of Chemical Industry     

Characterisation of Gouda cheeses based on sensory,analytical and high-field 1H nuclear magnetic resonance spectroscopy determinations: Effect of adjunct cultures and brine composition on sodium-reduced Gouda cheese

This study aimed at the interception of flavour deviations of salt-reduced Gouda-type cheeses, salted in sodium-reduced brines (NaCl + KCl brine) compared with a reference brine (NaCl brine), by the addition of adjunct strains of Lactobacillus helveticus and Lactobacillus paracasei, next to the common mixed-strain starter culture for Gouda. A multiphasic analysis of carbohydrates, organic acids, amino acids, and volatile flavour compounds was performed. After 56 days of ripening, the sensory characteristics of the cheeses were evaluated. Trained taste panel analysis determined some significant differences (P < 0.05) in saltiness, bitterness, texture and preference. The selected chemical fingerprint techniques, combined with multivariate data analysis, could be used to characterise Gouda cheeses that varied in ripening time and to which adjunct cultures were added. The variations were related to proteolysis and metabolic processes during ripening. There were no significant differences in the chemometric results between the reference NaCl-brined cheeses and the NaCl + KCl-brined cheeses.     

Effect of a hygienized rennet paste and a defined strain starter on proteolysis,texture and sensory properties of semi-hard goat cheese

A hygienized rennet paste (HRP) and a defined strain starter culture, including Lactobacillus casei subsp. casei IFPL as adjunct, were considered for manufacturing Majorero cheese, a Spanish traditional variety made from goat milk. Influence of both factors on physicochemical characteristics, proteolysis, rheological and sensory properties, was evaluated throughout the ripening. Cheeses produced either industrially (IL) or in artisanal manner (AL) were compared with the experimental lot (EL), which included HRP and IFPL starter in its manufacture. Results showed a low level of primary proteolysis, expressed by a low content of non-casein nitrogen (NCN), in experimental cheeses. Despite the slightly poor texture (hard and crumbly) related to the high TS and salt contents, a good general acceptability was attained for EL, with the best scores for aroma and flavour intensities achieved at 30 ripening days. In fact, the sensory panel detected the “piquant” flavour (typical of the artisanal cheese variety) in EL after 15 days of ripening.     

Application of selected lactic acid bacteria and coagulant for improving the quality of low-salt Cheddar cheese: Chemical,microbiological and rheological evaluation

With the aim of counteracting adverse sensory characteristics of salt reduction in Cheddar cheese, use of a glutamate decarboxylase-negative starter, camel chymosin as coagulant and Lactobacillus helveticus CHCC 4481 and Lactobacillus pentosus CHCC 13992 as adjuncts were investigated. Chemical, microbiological and rheological changes in low-salt (0.85%)/normal-moisture (37.7%) content cheeses were determined. Camel chymosin showed a large capacity for decreasing bitter peptide formation and Lb. helveticus CHCC 4481 for increasing bitter peptide degradation and for the release of flavour enhancing amino acids. An additional small amount of free Glu was gained from the use of the glutamate decarboxylase-negative starter. Lb. pentosus CHCC 13992 successfully converted all residual citrate into the flavour enhancer, succinate after 150 days of ripening. Rheological effects as determined by fracture strain (ε_H,f) and Young's modulus (E) appeared of secondary relevance in terms of quality recovery as none of the low-salt cheeses deviated from normal-salt ranges.     

Utilisation of microfluidisation to enhance enzymatic and metabolic potential of lactococcal strains as adjuncts in Gouda type cheese

Lactococcal strains were selected based on the release of key intracellular enzyme activities post-attenuation by microfluidisation. Attenuated strains were evaluated as adjuncts with commercial lactococcal starter and compared with a control without adjunct, and to a commercial Lactobacillus helveticus (FLAV54) adjunct in a mini vat Gouda type cheese system. No significant differences were noted in compositional parameters apart from a lower pH in one cheese, but differences were evident for proteolysis, volatile and sensory attributes after 12 weeks ripening. The effectiveness of adjuncts to augment cheese flavour was strain specific, and the influence of the starter in terms of release of intracellular enzymes was affected by the choice of adjunct. The sensory character of one attenuated lactococcal strain was similar to FLAV54. This study has highlighted the potential of microfluidisation to enhance enzymatic and metabolic performance of adjuncts in the development of cheese flavour.     

Biogenic amine content and proteolysis in Manchego cheese manufactured with Lactobacillus paracasei subsp. paracasei as adjunct and other autochthonous strains as starters

Two different autochthonous strain starter cultures, in which the acidifying starter was composed of strains of Lactococcus lactis, were used for the manufacture of pasteurised milk Manchego cheese. Proteolysis parameters, biogenic amines and sensory characteristics were evaluated and compared with those of commercial starter Manchego cheese and raw milk Manchego cheese manufactured without starter. Autochthonous starter cheeses, and especially those including Lactobacillus paracasei subsp. paracasei as adjunct, presented higher levels of proteolysis than in commercial starter cheese. The concentrations of total biogenic amines in autochthonous starter cheeses were much lower than in raw milk cheese and even lower than in commercial starter cheese. Cheese manufactured with the adjunct strain gave the best results for both flavour intensity and flavour quality, and was the most preferred by panellists. The results suggest that the culture containing Lb. paracasei subsp. paracasei as adjunct could be used for the manufacture of industrial Manchego cheese.     

Employment of autochthonous microflora in Pecorino Sardo cheese manufacturing and evolution of physicochemical parameters during ripening

The isolation and identification of lactic acid bacteria (LAB) from raw ewes’ milk and traditional Pecorino Sardo cheese made from this milk without the addition of starter culture was carried out to define the autochthonous lactic microflora present in milk and the evolution of LAB during cheese ripening. Isolation of 275 strains belonging to different Lactococcus, Lactobacillus, Streptococcus and Enterococcus species was achieved. Coccal-shaped LAB were found to predominate during cheese fermentation, while lactobacilli were preponderate during the latter phase of ripening. The technological selection of a total of 174 LAB strains belonging to the species Lactococcus lactis, Streptococcus thermophilus, Lactobacillus helveticus and Lb. casei allowed an experimental starter to be prepared, in which a potentially probiotic species, Lb. casei was used. The suitability of the autochthonous starter culture was tested in cheese-making trials, using thermised ewes’ milk, by comparing experimental Pecorino Sardo cheese with a control cheese produced at industrial scale using a whey starter culture from previous batches of manufacture. In particular, microbiological and physicochemical parameters were determined over 210 days of cheese ripening. Although sensory evaluation did not show any significant difference between experimental and control Pecorino Sardo cheeses, the use of the selected autochthonous starter allowed the production of experimental cheese with a significantly higher level of free amino acids, in particular essential amino acids, in comparison with the Pecorino Sardo control cheeses.     

Production of peptides and free amino acids in a sterile extract describes peptidolysis in hard-cooked cheeses

Hard cooked cheeses are mostly manufactured with lactic starters of Lactobacillus helveticus, which constitute a major proteolytic agent in the food. In this work, we assessed the proteolysis produced by enzymes of two strains of L. helveticus in a new cheese model, which consisted of a sterile substrate prepared with hard-cooked cheeses, and identified the time of ripening when main changes in proteolysis are produced. The extract, a representative model of the aqueous phase of the cheeses, was obtained from Reggianito cheeses of different ripening times (3, 90, and 180 days) made with starters composed of the strains tested, either SF138 or SF209. To obtain the substrate, the cheese was extracted with water, then centrifuged and the aqueous phase was sterilized by filtration through membrane (0.45 ??m). The substrates were incubated at 34 °C during 21 days; samples were taken at 0, 3, 7, 14, and 21 days. Sterility was verified by plating samples on skim milk agar and incubating at 37 °C for 48 h. Proteolysis was determined by liquid chromatography of soluble peptides and free amino acids. Great variation in peptide profiles was found as incubation progressed in cheese extracts, which evidenced that proteases and peptidases from the starter were active and able to degrade the proteinaceous material available in the extracts. The extracts derived from cheeses with L. helveticus SF138 showed low production of peptides and a notable increase in free amino acids content during incubation. L. helveticus SF209, on the contrary, caused an increase on soluble peptides, but the free amino acids accumulation was lower than in the first case, which suggested that L. helveticus SF209 had either a low peptydolitic activity or produced an intense amino acids breakdown. This trend was more evident for extracts prepared with 90-day-old cheeses. It was concluded that the strains of L. helveticus assayed showed potentially complementary proteolytic abilities, as SF209 was able to provide a continuous replenishment of peptides during incubation, while SF138 increased their hydrolysis to free amino acids. The extract was an appropriate medium to model hard cooked cheese ripening in short periods of time.     

Influence of exopolysaccharide‐producing cultures on the volatile profile and sensory quality of low‐fat Tulum cheese during ripening

The objective of this investigation was to compare the composition and changes in the concentration of volatiles in low‐fat and full‐fat Tulum cheeses during ripening. Tulum cheese was manufactured from low‐ or full‐fat milk using exopolysaccharide (EPS)‐producing or non‐EPS‐producing starter cultures. A total of 82 volatile compounds were identified belonging to the following chemical groups: acids (seven), esters (21), ketones (14), aldehydes (six), alcohols (14) and miscellaneous compounds (20). The relative amounts of acids, alcohols and aldehydes increased in the cheeses made with EPS‐producing cultures during 90 days of ripening. Differences were found in the volatile profile of full‐fat Tulum cheese compared with the low‐fat variant, especially after 90 days of ripening. Exopolysaccharide‐producing cultures changed the volatile profile, and the EPS‐producing cultures including Streptococcus thermophilus + Lactobacillus delbrueckii subsp. bulgaricus + Lactobacillus helveticus (LF‐EPS2) produced cheese with higher levels of methyl ketones and aldehydes than the non‐EPS cultures. In the sensory analysis, full‐fat Tulum cheeses and the cheese produced with the EPS‐producing culture containing Lb. helveticus (LF‐EPS2) were preferred by the expert panel. It was concluded that the use of EPS‐producing starter cultures in the manufacture of low‐fat Tulum cheese had the potential to improve the flavour.     

The performance of Streptococcus macedonicus ACA-DC 198 as starter culture in Kasseri cheese production

Streptococous macedonicus ACA-DC 198 was used both as an adjunct (Cheese B) and as sole starter (Cheese C) in Kasseri cheese production. Control cheese (Cheese A) was prepared using a commercial starter culture. In all cheeses, numbers of all microbial groups examined initially increased, but declined after Baski scalding and remained practically stable up to day 90. The presence of S. macedonicus was confirmed until the end of ripening (Cheeses B and C); this was also the case for the bacteriocin produced by S. macedonicus ACA-DC 198. X-propyl-dipeptidyl-aminopeptidase activity was detected in all cheeses after day 15. The physicochemical characteristics of the mature Cheese C were in agreement with those defined by the Greek legislation. The sensory properties of all mature cheeses corresponded with the ones characterizing the traditional Kasseri cheese. It was concluded that S. macedonicus ACA-DC 198 can be used as an adjunct in Kasseri cheese production.     

Influence of the starter culture on the microbiological and sensory characteristics of ewe's cheese

Changes which take place in the sensory characteristics of cheeses during ripening are influenced by different factors, involving rennet, starter culture and adventitious contamination of the cheese by non-starter lactic acid bacteria. The objective of this work was to study the influence of the starter on sensory and microbiological ewe's cheese properties during ripening time. Four batches (two with starter added and two without) were manufactured. Milk and cheeses at different stages of ripening were analysed. Cheeses manufactured without adding starter showed a significantly higher level of mesophilic aerobic microflora, lactobacilli, facultatively heterofermentative lactobacilli and enterococci (indigenous microflora) than cheeses manufactured with starter. This study has also shown that adding or not adding starter affects the flavour profile of the cheese. Cheeses with starter added showed greater intensity of the following attributes: refreshing, astringent, sweet; and received lower scores on bitterness. With respect to texture, the said cheeses develop a more homogenous texture and greater elasticity throughout ripening.     

Utilization of freeze-shocked lactobacilli for enhancing flavour development of Ras cheese

Freeze-shocked cultures of Lactobacillus helveticus or Lactobacillus casei were added at levels of 1% and 2% to Ras cheese milk prior to renneting as an adjunct starter to enhance flavour development of cheese. These additives did not affect the gross chemical composition of the cheeses but increased the formation of soluble nitrogenous compounds, free volatile fatty acids, the flavour intensity and improved the body characteristic. Also, the counts of bacterial groups (total, proteolytic and lipolytic) of the cheese treated with freeze-shocked lactobacilli were higher than in the control. Moreover, the ripening period was reduced to be 2 months compared with 4 months required for the control cheese. Also, using freeze-shocked culture of L. helveticus was the most effective in this respect.     

The design of a three strain starter system for Cheddar cheese manufacture exploiting bacteriocin-induced starter lysis

A three strain starter system was developed for increasing the level of starter cell lysis during cheese manufacture and ripening. The composition of this starter combination includes a bacteriocin (lactococcin A, B and M) producer which causes the lysis of a second strain (sensitive to bacteriocin activity) during cheese manufacture, and a third strain resistant to bacteriocin activity. The latter strain plays an essential role in ensuring acid production during cheese manufacture. Cheeses manufactured at pilot-scale (450 L vats), with the three strain starter combination were assessed for levels of the intracellular enzyme, lactate dehydrogenase, released into the cheese matrix during ripening. Experimental cheeses, manufactured with the bacteriocin-producing adjunct, exhibited higher levels of free amino acids and greater release of intracellular LDH than control cheeses manufactured in its absence. Cheese was subject to sensory analysis which revealed that experimental cheese showed a decrease in bitterness over cheeses manufactured without the bacteriocin-producing adjunct. Thus, this three strain system offers manufacturers a reliable starter system exhibiting increased lysis with concomitant improvements in cheese flavour.     

Evaluation of isolated starter lactic acid bacteria in Ras cheese ripening and flavour development

Eighteen cultures of starter lactic acid bacteria with or without added adjunct cultures, isolated from Egyptian dairy products, were evaluated in experimental Ras cheese for flavour development. Chemical composition of experimental cheeses was within the legal limit for Ras cheese in Egypt. All cultures used in this study had no effect on chemical composition of Ras cheese. Very significant variations in free amino acids, free fatty acids and sensory evaluation have been found among the cultures used in Ras cheesemaking. The levels of free amino acids and free fatty acids were correlated well with flavour development in Ras cheese. Seven of the tested cultures produced acceptable flavour and texture of Ras cheese. The highest overall score of flavour intensity, flavour and texture acceptability were in cheese made using YY47 lactic culture in addition to adjunct culture of Lactobacillus helveticus, Lactobacillus paracasei subsp. paracasei, Lactobacillus delbrueckii subsp. lactis and Enterococcus faecium. This culture can be recommended for Ras cheese manufacture using pasteurized milk.