Influence of k-casein genotype on heat stability and cheese making properties of milk powder

Milk samples

Milk was obtained from cows of Holstein breed kept on the Mukhametshin farms (Republic of Tatarstan, Russia) and Russian State Agrarian University - Moscow Timiryazev Agricultural Academy (Moscow, Russia). Using DNA analysis of the biomaterial, 68 animals were genotyped for the κ-casein gene, of which 33 cows were identified with AA genotype, 21 - AB, 14 - BB. The occurance of allele A for the k-casein gene was 64 %, and allele B - 36 %. The design of the experiment is shown in Figure 1.

The milk obtained from genotyped cows was cleaned 1-2 hours after milking, cooled to 4±2 °C and sent to the laboratory, where it was heated to 40±5 °C, separated and skim milk samples (AA ⁰, BB ⁰, AB ⁰) were obtained.

In order to maximize the preservation of the native state of the skimmed milk components, it was spray (AA ¹, AB ¹, BB ¹) and freeze drying (AA ², AB ², BB ²) without heat treatment and condensation. The exclusion of these stages from the process of obtaining skimmed MP was based on the data (Lin et al., 2018; Schuck et al., 2013; Dumpler et al., 2020; Sobti et al., 2019), which reported that the main changes in the structure and functional properties of milk, both positive and negative, occur during heat treatment and condensation.

Figure 1. The design of the experiment

Spray drying was carried out on a laboratory setup (BIORUS-8000, Russia) using a two-flow spray nozzle and a unidirectional air and milk flow under the following modes:

Freeze drying was carried out using a TG-50 batch unit of periodic action (Hochvakuum, Germany) under the following modes:

The mass fraction of moisture in the spray and freeze dried skimmed milk was 3.0±0.5 %.

Samples of skimmed MP were stored in a refrigerator at a temperature of 4±2 °C in a hermetically sealed container until used in further studies.

On the basis of dried samples, model dry systems were prepared, ranked according to the ratio of homozygous AA and BB genotypes (100:0 %; 75:25 %; 50:50 %; 25:75 %; 0:100 %, respectively), which fundamentally imitate the combined MP.

Before the study 9 g of a model sample of skimmed MP was dissolved in distilled boiled water with a pH of 6.5±0.1 at 40±2 °C, bringing the total volume to 100 ml. Milk reconstitution was carried out using a laboratory magnetic stirrer at a speed of 500 rpm. The reconstituted milk was left for 15 minutes to remove air trapped during stirring and stabilize the milk system. Then the milk was cooled to 20±2 °C.

Before determining the heat stability, a special preparation of the reconstituted samples was carried out, contributing to a more complete understanding of the mechanism of protein destabilization and making it possible to minimize the effect of the values of active or titratable acidity on its stability when exposed to various methods used in the assessment of heat stability. For this, the pH was determined in the reconstituted samples and a model series of samples was made for each sample with pH values in the range from 6.0 to 7.0 (step 0.2) by potentiometric titration with 1 N HCl or 1  N NaOH.

Methods

Standardized and generally accepted methods of physical and chemical control of dairy products were used for research.

The total dry matter content was determined by the thermogravimetric reference method described in ISO 6731:2010[IDF 21:2010].

The fat content was determined using the Gerber acid method according to ISO 2446:2008[IDF 226:2008], ISO 11870:2009[IDF 152:2009].

The total protein content was determined according to ISO 1871:2009, ISO 8968-1:2014[IDF 20-1: 2014] using a protein analyser Kjeltec-2400 Auto Analyzer (Foss Electric, Denmark) by measuring the total nitrogen by the Kjeldahl method with its subsequent recalculation per protein using a conversion factor of 6.38.

The content of casein and serum proteins was determined using the reference method according to ISO 17997-1:2004[IDF 29-1:2004] by acid precipitation of casein and measuring the total nitrogen in the filtrate.

The lactose content was determined by an enzymatic method using the pH difference according to ISO 26462:2010[IDF 214:2010].

The freezing point was determined by a reference method using a Cryoscope (Advanced Instruments, USA) according to ISO 5764:2009[IDF 108: 2009].

The titratable acidity was determined by titration with 0.1 N NaOH solution in the presence of 1 % alcoholic solution of phenolphthalein indicator and expressed in Terner degrees (°T).

The pH was determined by a potentiometric method using a laboratory pH meter (InoLab pH Level 1, Germany).

Ca content was determined by titrimetric method according to ISO 12081:2010[IDF 36:2010].

The content of somatic cells was determined by fluorescence microscopy using a DCC analyser (DeLaval, Sweden); the microscopic method described in ISO 13366-1:2008[IDF 148-1:2008] was used as a reference method.

Genotyping of animals by the k-casein gene was performed using PCR-RFLP analysis. The process of isolating DNA from biological material of animals was carried out in accordance with the instructions for the set "DNA-sorb-SM" (Central Research Institute of Epidemiology, Federal State Budgetary Institution of Supervision of Consumer Rights Protection and Human Welfare, Russia) (Vafin et al., 2021). Amplification was carried out on a Tertsik thermocycler (Russia) with reaction mixture volumes of 20 μL (SibEnzim, Russia) containing 2 μL of dNTP mixture (0.25 mM each), 2 μL of Taq DNA polymerase buffer (1 ×), 0.2 μL Taq DNA polymerase (1 unit), 0.4 μL of primers JK5 (5 ^/-ATCATTTATGGCCATTCCACCAAAG-3 ^/) and JK3 (5 ^/-GCCCATTTCGCCTTCTCTGTAACAGA-3 ^/), 2 μl of DNA sample in the following modes: ×1: 94 ºС - 4 min; ×35: 94 ºС - 10 s, 63 ºС - 10 s, 72 ºС - 10 s; ×1: 72 ºС - 7 min; storage: 4 ºС. PCR samples (10 μL) were treated with 5 units of restriction enzyme HinfI in SE-buffer "O" (SibEnzyme, Russia) with incubation at 37 °C for 12 hours. The incubated PCR-RFLP samples were mixed with buffer for loading samples onto an agarose gel (4× Gel Loading Dye, Blue, ZAO "Evrogen", Russia) in ratio of 3:1. Coloured amplifiers were applied to the wells of a 2 % agarose gel prepared by melting of 2 g of agarose (Biotechnology Grade, Amresco, USA) in 100 ml of Tris-acetate electrode buffer (500 mL 1 × TAE buffer, 15 μL 1 % ethidium bromide solution). Detection was carried out by horizontal electrophoresis using a SE-2 camera (Helikon, Russia) and an Elf-4 power supply unit (DNA-Technology, Russia) (Gilmanov et al., 2020).

The determination of heat stability by an alcohol sample is based on the detection of denaturation of milk proteins in the presence of C ₂H ₅OH. 2 cm ³ of the reconstituted sample was added to a Petri dish, 2 cm ³ of an alcohol solution of a certain concentration (68 %, 70 %, 72 %, 75 %, 80 %, 85 %, 90 %) was added and the dish was stirred in a circular motion. After 2 min. the absence or presence of protein coagulation, manifested in the form of flakes, was visually fixed.

Determination of heat stability by an acid-boiling sample is based on the use of a complex impact of heat and acid as a denaturing protein factor. 0.5 cm ³, 0.8 cm ³ and 1.2 cm ³ of 0.1 N HCl solution were added, 10 cm ³ of reconstituted milk was added and mixed in three glass heat-resistant vials. The vials were placed in a boiling water bath at a temperature of 100±1 °C, kept for 3 min and cooled to a temperature of 20±1 °C. The contents of the vials were transferred to Petri dishes and visually assessed the stability of proteins in the samples, characterizing it by the amount of added acid. According to this method, milk is considered heat-resistant if it withstands acid-boiling impact with the addition of more than 0.8 cm ³ of acid.

The determination of heat stability by a thermal sample is based on determination of the duration of the absence of coagulation of protein fraction of milk exposed to heat at a temperature of 130±1 °C. For testing a UKT-150 ultrathermostat (BioPishcheMash, developed at All-Russian Dairy Research Institute, Russia) filled with glycerine was used.

The cheese making properties of the reconstituted samples were determined using a method based on assessing the ability of milk to coagulate under the influence of rennet and microorganisms of milk not exposed to temperature (rennet-fermentation test) in accordance with the method described in (Vafin et al., 2021). The study was carried out using a milk-clotting enzyme derived from microbial chymosin CHY-MAX M 2500 IMCU (Chr. Hansen, Denmark). The enzyme weighing 0.32 g was dissolved in 100 mL of distilled water at a temperature of 30±1 °C and kept for 30 min with constant stirring on a magnetic stirrer (300 rpm). 90 cm ³ of reconstituted skim milk, heated to a temperature of 38±1 °C, was measured into a glass and 3 cm ³ of an enzyme solution was added. The sample was incubated at 38±1 °C until a dense clot was formed. A visual assessment of the quality of the resulting clot was done, fixing the duration of rennet clotting, and the class of milk quality was established:

I (good) - the curd has a smooth surface, elastic to the touch, without eyes in the longitudinal section, floats in a transparent serum that does not stretch;

II (satisfactory) - the coagulum is soft to the touch, with single eyes (from 1 to 10 pieces), torn, but not swollen;

III (unsatisfactory) - the coagulum is spongy, soft to the touch, has numerous eyes, swollen, floated up or instead of a clot a flocculent mass is formed.

After classification of milk quality, the content of the glass was filtered through a lavsan fabric. The filtrate (serum) was thoroughly mixed and the protein content was determined.

Statistical analysis

All experiments were performed independently in triplicate. The results were processed by analysis of variance (ANOVA) with subsequent comparison of average values according to Student's t-test using Statistica 12.0 software with a significance level of 95 %.

The qualitative and quantitative composition of the source skimmed milk

Analysis of the parameters of skimmed milk obtained from cows with polymorphic genotypes for CSN3 showed the levelling of the factors of the mass fraction of fat and somatic cells in the process of sample preparation (Table 1).

Table 1. Physicochemical composition of skimmed milk samples

The difference in the mass fraction of protein between samples AA ⁰ and BB ⁰ was insignificant (2.82 % and 3.05 %, respectively) in contrast to sample AB ⁰, where the mass fraction of protein was at the level of 3.38 %. Considering the fractional composition of the protein of homozygous samples AA ⁰ and BB ⁰, a constant trend should be noted that the ratio of serum and casein fractions of proteins remains unchanged at the level of 27:73 %. The ratio of these fractions in the heterozygous AB ⁰ sample was 23:77 %. Sample AB ⁰ was characterised by an increased content of the mass fraction of lactose and dry substances in general, therefore, in further studies, this sample was considered as a reference.

k-casein genotype influence on heat stability of milk powder

One of the most important technological properties of MP is resistance to thermal effects after hydration (Kruchinin et al., 2020; Deshwal et al., 2020). Currently, scientists have not created a single agreed universal methodology for determining the milk heat stability, which is due to the lack of a thorough and deep understanding of the complex mechanism of milk system variability under temperature exposure, since it has a multifactorial nature and is associated with the protein cluster of milk, the concentration and ratio of mineral salts, acidity etc. (Kruchinin et al., 2020; Chandrapala et al., 2010; Huppertz et al., 2016; Dumpler et al., 2020). In this regard, to study the stability of casein micelles in reconstituted samples of skimmed milk by freeze and spray drying with k-casein polymorphism, an integrated approach was applied and from the whole variety of methods, the three most common ones were used, namely alcohol, acid-boiling, thermal samples (Kruchinin et al., 2020; Sikand et al., 2010).

The results of studying the heat stability of samples using an alcohol test are presented in Table 2.

Table 2. Heat stability by alcohol test of reconstituted model milk systems

The analysis outlined in Table 2 of the research results showed that lowering the pH below 6.6 leads to a decrease in heat stability and visible denaturation of the protein when adding the lowest concentrated alcohol solution (68 %) to all milk samples without exception. A change in the pH value to the alkaline side led to an increase in the milk heat stability. At the same time, there was a tendency to an increase in the milk heat stability with an increase in the milk content of cows with a homozygous AA CSN3 genotype in model systems, reaching a maximum value at pH 7.0 (the sample withstood the addition of a 90 % alcohol solution) with 100 % prevalence. Such heat stability of the samples may be associated with the milk genotypic origin (Mahmoudi et al., 2020). The milk of cows with AA CSN3 genotype contained, although not much, a smaller amount of protein, including casein fractions (by 7-8 %), in comparison with BB CSN3 milk with practically equal values of lactose (within the method error). However, this difference was sufficient to ensure the stability of the protein fraction. Model systems with a predominance of milk of AA CSN3 genotype (more than 50 %) are less susceptible to disruption of the hydration membrane as a result of exposure to 85 % and 90 % alcohol solution at pH 6.8 and 7.0. A comparison of the results of studies of reconstituted milk samples by freeze and spray drying showed almost identical values, which probably indicates the lack of objectivity of the method for determining heat stability by an alcohol test to identify factors of negative or positive impact that depend on the method of milk drying and affect the heat stability of the protein fraction.

In the course of further studies, the heat stability of the reconstituted model milk systems was analysed by the method of an acid-boiling sample (Table 3).

Table 3. Heat stability by acid-boiling sample of reconstituted model milk systems

« - » - negative result, i.e. the sample failed to withstand the addition of a minimum amount of 0.1 N HCl (0.5 cm ³)

* Quantity of 0.1 N HCl, which the reconstituted milk withstood, cm ³

Analysis of the samples subjected to an acid boiling test revealed some differences in the heat stability of model line milk according to CSN3, spray dried, which is clearly seen at pH values above 6.6 (Table 3). Sample AA ¹:BB ¹ (100:0 %) with pH 6.6 and 6.8 withstood the addition of 0.5 cm ³ of 0.1 N HCl and remained stable during heat treatment. There was also no coagulation of this sample at pH 7.0 even as a result of the addition of 0.8 cm ³ of 0.1 N HCl. At a pH of 6.8 and 7.0, the addition of 0.5 cm ³ of 0.1 N HCl followed by heating withstood the sample AA ¹:BB ¹ (0:100 %). Similarly, when adding 0.5 cm ³ of 0.1 N HCl, sample AB ¹ (control) retained its colloidal stability. None of the samples of model freeze-drying milk systems withstood the acid-boiling test even with a minimal amount of acid. Thus, according to the method used, only the sample AA ¹:BB ¹ (100:0 %) at pH 7.0, obtained by the method of spray drying, can be considered thermally stable. The data obtained indicate that as applied to the studied model systems the method for determining heat stability from an acid-boiling sample is not entirely representative.

The next stage of research was the study of the heat stability of reconstituted skimmed milk samples by the thermal test method, as the most common technique with greater reliability of results, as well as allowing to directly analyze the stability of MP under the influence of high temperatures without additional use of denaturing substances (Kruchinin et al., 2020; Sikand et al., 2010). The research results are presented in Table 4.

Table 4. Heat stability by thermal test of reconstituted model milk systems (±0.1 min.)

The research results presented in Table 4 showed that samples of spray and freeze dried milk have similar dependences of changes in heat stability both in the pH gradient and with an increase in the model systems of the content of milk of cows with AA CSN3 genotype. All samples could not withstand high-temperature exposure at pH 6.0 and 6.2. With an increase in pH to 6.4, an increase in the duration of heat stability occurred in all samples, particularly dramatic (by 20-30 times) in samples with a predominance of AA CSN3 genotype. Only samples with 100 % of milk content of cows with BB CSN3 genotype (1 min) and control samples (9 and 7 min) subjected to spray and freeze drying (respectively) were destabilized in a minimum time. Samples in the pH range from 6.6 to 7.0 withstood high-temperature processing, sufficient for the production of most types of dairy products, including sterilized. The observations obtained in the course of experiment confirm the results (Dumple et al., 2020) on the increase in the stability of casein micelles with increasing the pH. The authors claim that k-casein is mainly attached to the outer surface of micelles in the form of disulfide-bound oligomers and forms negatively charged sites that create electrostatic and steric barriers preventing aggregation with increasing temperature. A decrease in the pH leads to a weakening of the overall negative charge of the micelle, resulting in a reduction in the duration of heat stability.

Samples with a predominance (from 50 % to 100 %) of milk obtained from cows with AA CSN3 genotype were more heat stability. It should also be noted that even the minimal presence of such milk (25 %) maintained the protein cluster of model systems in a stable state, reaching maximum values for AA ¹:BB ¹ (44 and 36 min) and for AA ²:BB ² (51 and 38 min) at pH 6.6-6.8, which proves the effect of genotypic differences in k-casein on the milk technological properties.

Analysis of data revealed higher stabilization qualities of the protein when heated in pH ranges from 6.4 to 7.0 in freeze dried samples compared to spray drying (by 3-10 %) in dairy systems with milk from cows with AA CSN3 genotype with a fraction of 25 % to 100 %, which is due to the sparing temperature regimes of processing casein and whey fractions during lyophilization compared to spraying. However, with 100 % replacement for milk from cows with BB CSN3 genotype the results were levelling.

Summarizing the conducted studies on the heat stability of the samples it should be noted that the results of the acid-boiling test do not correlate with the results of the alcohol and heat tests. This indicated the absence of grounds for its application to these findings. At the same time alcohol and heat tests are indicative and in most cases are correlated with each other. However, only the use of a thermal test made it possible to reveal differences in the heat stability of model samples.

Influence of the k-casein genotype on the cheese making properties of milk powder

At the next stage of research, experiments were carried out to determine the cheese making properties of model milk systems. The ability of dairy raw material, including powder milk after its reconstitution, to form an elastic and dense coagulum under the action of milk-clotting enzymes should be considered as the most important factor in the production of cheese and cottage cheese. The research results are presented in Table 5.

Table 5. Cheese making properties according to the rennet-fermentation sample of reconstituted model milk systems

^{a, b, c, d} Мeans followed by different lowercase letter in column differ significantly by ANOVA; significance level of 5%

Analysis of the experimental data showed that with an increase in the proportion of milk from cows with BB CSN3 genotype from 0 % to 100 % in model systems the duration of rennet coagulation decreases for all samples, regardless of the drying method. The period of clot formation decreased by 40 % and 24 % in the samples of spray and freeze drying, reaching practically the same (within the margin of error) minimum values of 160 and 165 min (respectively) with maximum replacement. The regularities of an increase in the protein transition of serum with an increase in the milk content of cows with BB CSN3 genotype in model systems were also noted. Most likely, this fact is associated to the size of the casein micelles forming the coagulum. Milk with smaller casein micelles size forms a curd with a higher density and hardness than milk with larger micelles size. However, the higher content of small micelles appears to contribute to increased protein loss when separating the serum from the curd. The results obtained are consistent with studies (Bijl et al., 2014) which showed that milk with BB CSN3 genotype has an average casein micelle size less than that of AA CSN3 genotype (173.0±9.7 nm and 201.2±10.3 nm, respectively).

At the same time, there are differences in the quality of clots obtained from spray and freeze dried milk (Figure 2).

Figure 2. Quality of clots obtained from model samples by spray and freeze drying methods

When using freeze drying, coagulum of all model samples were assigned to class I, while during spray drying only samples AA ¹:BB ¹ (25:75 %) and AA ¹:BB ¹ (0:100 %) corresponded to this category which is consistent with the results of Zambrano-Burbano et al. (2010) on a greater resistance to heating and freezing of milk with BB CSN3 genotype, as well as a shorter duration of coagulation with the formation of clots of a denser structure and a higher yield of cottage cheese and cheese than milk with AA CSN3 genotype.

Sažetak

U ovom istraživanju je ispitivan učinak polimorfizma gena za k-kazein na tehnološke karakteristike mlijeka u prahu dobivenog sušenjem raspršivanjem (AA ¹: BB ¹) i liofilizacijom (AA ²: BB ²). Korištene su standardne i općeprihvaćene metode fizikalno-kemijskih analiza mliječnih proizvoda, kao i metode za procjenu toplinske stabilnosti i prikladnosti mlijeka za proizvodnju sira. Najveću stabilnost naspram toplinskih tretmana pokazali su uzorci mlijeka u kojima je prevladavalo mlijeko krava s genotipom AA CSN3, pri pH od 6,4 do 7,0 (36-91 minuta za AA ¹: BB ¹ i 37-101 minuta za AA ²: BB ²). U modelnim sustavima s 25 % do 100 % mlijeka krava s genotipom AA CSN3 dobivenim liofilizacijom utvrđena je su veća (za 3-10 %) termostabilnost proteina u rasponu pH od 6,4 do 7,0 u usporedbi s uzorkom dobivenim sušenjem raspršivanjem. Analiza rezultata vezanih uz prikladnost mlijeka za proizvodnju sira pokazala je da se s porastom udjela mlijeka krava s genotipom BB CSN3 od 0 % do 100 % u modelnim sustavima, trajanje koagulacije sirilom smanjuje za sve uzorke, bez obzira na metodu sušenja mlijeka. Utvrđeno je da su korištenjem liofilizacije koagulumi svih uzoraka svrstani u najvišu kvalitetu mlijeka u pogledu prikladnosti za proizvodnju sira, dok su kod uzoraka dobivenih sušenja raspršivanjem u ovu kategoriju bili svrstani samo oni koji se sastoje od min. 75 % mlijeka dobivenog od krava s genotipom BB CSN3.

Ključne riječi: mlijeko u prahu; k-kazein; toplinska stabilnost; prikladnost mlijeka za proizvodnju sira