PCR detection of cows’ milk in water buffalo milk and mozzarella cheese

Polymerase chain reaction (PCR) has been applied for the specific detection of cows’ DNA in water buffalo milk and mozzarella cheese by using primers targeting the mitochondrial 12S ribosomal RNA gene. The use of specific primers for cow yielded a 346 bp fragment from cows’ milk DNA, whereas no amplification signal was obtained in sheep's, goats’ and water buffalo's milk DNA. Analysis of both buffalo milk and buffalo mozzarella cheese mixtures containing different percentages of cows’ milk or bovine mozzarella cheese, enabled the specific detection of cow's DNA with a sensitivity threshold of 0.1%. The proposed PCR assay represents a rapid and straightforward method for the detection of adulterations in water buffalo milk and mozzarella cheese.     

Identification of cow's milk in "buffalo" cheese by duplex polymerase chain reaction

A duplex polymerase chain reaction (PCR) was developed to identify the milk of bovine and buffalo species in cheese products, particularly in mozzarella cheese, a typical Italian cheese made from buffalo's milk. Two sets of primers were designed on the basis of the alignment of the sequence codifying mitochondrial cyt b available in the GenBank database. The primers proved to be species-specific, giving rise to 279-bp (bovine) and 192-bp (buffalo) amplified fragments. Since the amplification conditions for bovine and buffalo primers were identical, a duplex PCR was successfully applied to identify the two species in a single reaction step. This technique, when used to test cheese products from the retail trade, allowed the detection of partial or even total substitution of cow's milk for buffalo's milk, in some cases in samples of cheese misleadingly labeled "pure buffalo" mozzarella.     

Species origin of milk in Italian mozzarella and Greek feta cheese

Several animal species such as cattle, goats, sheep, and water buffalo provide milk for dairy products. We describe a simple procedure for detecting the species origin of milk used for cheese production. DNA was isolated from Italian mozzarella or Greek feta by sequential organic extractions and resin purification. This DNA was analyzed by polymerase chain reaction-restriction fragment length polymorphism as described previously for meat samples. This procedure differentiated mozzarella made from water buffalo milk and from less expensive bovine milk and also feta cheeses made from bovine, ovine, and caprine milk.     

High resolution melting analysis for quantitative detection of bovine milk in pure water buffalo mozzarella and other buffalo dairy products

Identification of buffalo dairy products has become an important issue to ascertain product quality, consumer rights and absence of food-borne allergic reactions. A polymerase chain reaction (PCR) followed by a high resolution melting (HRM) analysis was developed and applied for species specific detection of bovine milk in nine different commercial buffalo dairy products. A specific buffalo 12S rRNA and a bovine d-loop primer pair, targeting the mitochondrial genome, were employed in a duplex PCR assay. The analysis developed was found capable of identifying the presence of bovine milk down to 1% in commercial buffalo milk products and also of quantifying the ratio of bovine into buffalo milk. HRM was proven to be a fast and accurate technique for a routine authentication testing of mozzarella and other buffalo milk products.     

Evaluation of oxidative damage in mozzarella cheese produced from bovine or water buffalo milk

Technological processes are the main sources of protein and lipid oxidation in food. The oxidative status was determined in a soft Italian cheese, namely mozzarella, produced from water buffalo or bovine milk. The amount of protein-bound carbonyls, dityrosine and α-lactalbumin aggregates were measured to evaluate the extent of protein oxidation. The α-tocopherylquinone/α-tocopherol ratio and the trolox-equivalent antioxidant capacity were used as redox markers in the fat fraction. The levels of protein-bound carbonyls and α-lactalbumin aggregates were found significantly higher in bovine mozzarella than in buffalo mozzarella. On the other hand, higher amounts of redox markers were found in buffalo mozzarella. The levels of dityrosine aggregates were similar in the two types of cheese. The data suggest that protein and fat are more protected against oxidative structure alterations in buffalo mozzarella than in bovine mozzarella.     

A novel method for species identification in milk and milk-based products

This study describes a method for species-specific detection of animal DNA from different species (cattle, sheep, goat, water buffalo) in milk and dairy products. A primer set was designed in conserved region on the basis of the alignment of the sequence codifying the genomic kappa-casein gene in order to amplify all four species with a single primer pair. Polymorphisms were detected via minisequencing with extension primers designed in conserved sequences for haplotype determination that allow unambiguous assignment to each species. The method was successfully applied to the detection of raw and pasteurized milk from the four different species considered as well as to cheese products from the retail trade. Estimation of the limit of detection was carried out using a progression of dilutions of genomic DNA as well as DNA isolated from milk of a known number of somatic cells from different species in order to be able to achieve detection rates as low as 0.1% bovine milk mixed with buffalo milk.     

Evaluation of the peptide profile with a view to authenticating buffalo mozzarella cheese

Electrophoretic and chromatographic techniques were used to determine water‐soluble peptide profiles aiming to identify the adulteration of buffalo milk mozzarella cheese by the addition of cow's milk. Thus, cheeses were produced with contents of cow's milk varying from 0% to 100%, and the peptides extracted after production and after 20 days of refrigeration. Polyacrylamide gel electrophoresis under denaturing conditions in the presence of sodium dodecyl sulphate (SDS‐PAGE) identified a potential peptide marker of exclusively bovine origin with a size of about 21 kDa for the addition of cow's milk above 30%. Reverse‐phase high‐performance liquid chromatography (RP‐HPLC) indicated the existence of two potential peptides present in higher concentrations in buffalo milk and one exclusive for cow's milk, the latter making it possible to estimate the addition of cow's milk to buffalo milk. Six commercial brands of buffalo mozzarella cheese were evaluated, and indications of adulteration found in four of them.     

Diversity of Lactic Acid Bacteria Isolated from Brazilian Water Buffalo Mozzarella Cheese

The water buffalo mozzarella cheese is a typical Italian cheese which has been introduced in the thriving Brazilian market in the last 10 y, with good acceptance by its consumers. Lactic acid bacteria (LAB) play an important role in the technological and sensory quality of mozzarella cheese. In this study, the aim was to evaluate the diversity of the autochthones viable LAB isolated from water buffalo mozzarella cheese under storage. Samples were collected in 3 independent trials in a dairy industry located in the southeast region of Brazil, on the 28th day of storage, at 4 ºC. The LAB were characterized by Gram staining, catalase test, capacity to assimilate citrate, and production of CO₂ from glucose. The diversity of LAB was evaluated by RAPD‐PCR (randomly amplified polymorphic DNA‐polymerase chain reaction), 16S rRNA gene sequencing, and by Vitek 2 system. Twenty LAB strains were isolated and clustered into 12 different clusters, and identified as Streptococcus thermophilus, Enterococcus faecium, Enterococcus durans, Leuconostoc mesenteroides subsp. mesenteroides, Lactobacillus fermentum, Lactobacillus casei, Lactobacillus delbrueckii subsp. bulgaricus, and Lactobacillus helveticus. Enterococcus species were dominant and citrate‐positive. Only the strains of L. mesenteroides subsp. mesenteroides and L. fermentum produced CO₂ from glucose and were citrate‐positive, while L. casei was only citrate positive. This is the first report which elucidates the LAB diversity involved in Brazilian water buffalo mozzarella cheese. Furthermore, the results show that despite the absence of natural whey cultures as starters in production, the LAB species identified are the ones typically found in mozzarella cheese.     

Improvement of low fat mozzarella cheese properties using denatured whey protein

Mozzarella cheese was made from buffalo milk (6% fat) or from partially skimmed buffalo milk (2 and 4% fat) with 0.5 and 1% denatured whey protein. Adding whey protein to buffalo milk decreased rennet coagulation time and curd tension whereas increased curd synaeresis. Addition of whey protein to cheese milk increased the acidity, total solids, ash, salt, salt in moisture, also some nitrogen fractions. The meltability and oiling‐off values increased but the calcium values of mozzarella cheese decreased. The sensory properties of low fat mozzarella cheese were improved by addition of whey protein to the cheese milk.     

Molecular surveillance of Toxoplasma gondii in raw milk and Artisan cheese of sheep,goat, cow and water buffalo origin

This study is aimed at investigating the molecular prevalence of Toxoplasma gondii in raw milk and cheese of different animal species (sheep, goat, cow and water buffalo) in Kayseri Province, Türkiye, to provide a preliminary assessment for contamination risk. A total of 200 milk and cheese samples were analysed by real-time PCR. Toxoplasma gondii DNA was detected in two (8%) ewes and one (4%) goat raw milk sample, while none of the cheese samples were positive. These results indicated that the presence of T. gondii DNA in raw milk samples sold in Kayseri Province might be a risk factor for public health.     

Authentication of carabeef (water buffalo, <Emphasis Type="Italic">Bubalus bubalis</Emphasis>) using highly specific polymerase chain reaction

In order to ensure consumer satisfaction and fraud detection, correct identification of meat animal species becomes significant. Buffalo being one of the major meat animal species in Asia, a species-specific polymerase chain reaction (PCR) was developed for the accurate identification of carabeef (water buffalo, Bubalus bubalis) targeting mitochondrial D-loop region. Unique diagnostic PCR developed in this study employed novel primers to yield a 534-bp buffalo-specific PCR product, and chances of cross-amplification were excluded by including as many as 25 animal species. Applicability of PCR was established in raw, cooked (60, 80 and 100 °C for 30 min), autoclaved (121 °C for 30 min) and microoven-processed meats with a sensitivity of detection of 0.1% adulteration (10 pg bubaline DNA). Keeping in view adulteration, socio-economic, religious, quality assurance, forensic and legal issues, the novel buffalo-specific PCR developed in this study was found highly promising in authenticating buffalo meat, ensuring consumer satisfaction and labeling process.     

DETECTION OF COW MILK IN BUFFALO "MOZZARELLA" BY POLYMERASE CHAIN REACTION (PCR) ASSAY

The authors used a polymerase chain reaction (PCR) assay on buffalo mozzarella, a typical Italian dairy product, from the Apulia markets to evaluate the presence of cow milk and verification of the mozzarella label. The results obtained from 30 mozzarella samples demonstrated the presence of the cow genome in 22/30 samples, highlighting contamination as probable fraudulent adding of cow's milk or use of the same equipments in both working cycles.     

一对同时鉴定8种动物源性成分的通用引物的制备及应用

肉类真假鉴定是食品检测工作的内容之一,目前已有多种基于PCR的肉类鉴定方法,但是鉴定种类和效率受限。本研究设计了一对基于普通PCR技术可同时鉴定8种动物源性成分的通用引物并建立了鉴定方法。该引物以线粒体DNA为靶标,利用扩增产物中不同物种间的插入缺失多态性片段大小即可鉴定山羊、绵羊、鹿、水牛、牛、牦牛、猪和骆驼8个物种,扩增后分别得到728 bp、704 bp、504 bp、453 bp、448 bp、431 bp、396 bp和326 bp的片段,每种PCR产物经SspI酶切后产生数量和大小不同的片段,可以进一步清晰鉴别8个物种。引物特异性测试表明和其他常见肉类动物DNA无交叉反应,DNA检测最低限度在0.01~0.05 ng。应用本方法对40份市场肉类及产品的检测表明,羊肉串、羊肉卷以及特色畜产品如驼肉、鹿肉和驴肉存在较多的掺假行为。与其他现有PCR检测方法相比,该方法具有简便易行和高通量的优点,可以作为肉类掺假筛选检测的常规方法。     

Determination of polychlorinated dibenzo-p-dioxins (PCDDs), polychlorinated dibenzo-p-furans (PCDFs) and polychlorinated biphenyls (PCBs) in buffalo milk and mozzarella cheese

The presence of polychlorinated dibenzo-p-dioxins (PCDDs), polychlorinated dibenzo-p-furans (PCDFs) and polychlorinated biphenyls (PCBs) in buffalo milk and mozzarella cheese has been investigated. In total 43 milk samples and 64 mozzarella cheese samples, coming from 40 creameries in the Caserta region of southern Italy, and 26 buffalo mozzarella cheese samples, purchased in Reggio Calabria's supermarkets have been analysed. The extraction and clean up method resulted in an efficient separation of PCDD/Fs and PCBs from other compounds that might interfere with the instrumental analysis. Analysis was carried out using an isotopic dilution method in conjunction with High Resolution Gas Chromatography-High Resolution Mass Spectrometry (HRGC-HRMS). Of the 90 mozzarella cheese samples analysed none exceeded toxicity values higher than the maximum limits requested by CE regulation CE No 2375/2001, 29/11/2001. Five of the 41 milk samples analysed showed toxicity values higher than the maximum law limits.     

A simultaneous triplex TaqMan real-time PCR approach for authentication of caprine and bovine meat,milk and cheese

Goat foodstuffs are considered as healthy foods with high nutritional value. This study demonstrated the development and validation of a triplex real-time PCR on the basis of species-specific and species-conservative TaqMan probes for the simultaneous identification of caprine and bovine DNA in meats, milk and cheeses with a prerequisite designed endogenous control. In this research, caprine and bovine meat, milk and cheese were specifically identified via developed primers and probes, and the limits of detection of this methodology were 0.005 and 0.01 ng DNA of milk and cheese from goat, and 0.01 and 0.05 ng DNA of milk and cheese from cow. Taken together, this approach was elaborated to address dairy adulteration issues to eliminate the fraud of economically motivated goat milk and cheese adulteration by adding cow milk.     

IDENTIFICATION OF POULTRY MEAT FROM PORK AND BEEF ON THE BASIS OF THE TITIN PEVK REGION USING PCR

The possibility of distinguishing three kinds of meat species (chicken, porcine and bovine) alone or in two-component meat mixtures was investigated using the polymerase chain reaction. The contribution of each component in the meat mixtures ranged from 1 to 100%. The identification of meat was performed on the basis of the sequence coding the PEVK region of titin and by employing polymerase chain reaction. DNA was isolated from raw, fresh and chilled meat. The data presented in this study suggest that it is possible to detect chicken meat, pork and beef in meat mixtures on the basis of PEVK region by using PCR.

PRACTICAL APPLICATIONS

The polymerase chain reaction (PCR) is a precise and quick technique that has many practical applications. Using PCR with primer sets designed on the basis of the PEVK region present in titin can be a convenient tool for species identification, especially for chicken meat mixed with pork and beef meat in two-component meat mixtures. Reliable and sensitive methods for species differentiation can give consumers confidence about authentic meat product composition.     

Differentiation of cattle species in beef by PCR-RFLP of mitochondrial and satellite DNA

Methods currently used for the identification of the species origin of meat or tissue samples have not been validated for other bovine species than taurine cattle or water buffalo. These methods also do not discriminate between the different bovine species that are used as source of beef. Here, we describe two complementary methods for detection and differentiation of bovine species, which are based on mutations in mitochondrial DNA and centromeric satellite DNA, respectively. The analysis of satellite DNA is especially relevant for the identification of animals that are of hybrid origin.     

Detection of buffalo milk adulteration with cow milk by capillary electrophoresis analysis

The addition of cow milk during the production of buffalo mozzarella is a common fraud in dairy industries because of the lower price and greater availability of cow milk throughout the year. The aim of this study was to develop a new, rapid, and robust capillary electrophoresis method for detecting and quantifying cow milk in buffalo milk by exploiting cow α-lactalbumin as a marker of adulteration. In particular, a linear calibration curve was generated, using a training set of calibrators consisting of 7 series of 17 buffalo/bovine whey mixtures, obtained after casein precipitation, with increasing percentages of cow whey. The capillary electrophoresis method showed high linearity (R² = 0.968), repeatability [relative standard deviation (RSD) = 2.11, 3.02, 4.38, and 1.18%, respectively for 5, 10, 20, and 50% of buffalo/bovine whey mixtures], and intermediate precision (RSD = 2.18, 2.49, 5.09, and 3.19%, respectively, for 5, 10, 20, and 50% buffalo/bovine whey mixtures). Moreover, the minimum amount of detectable fraudulent cow milk was 1%, and the limit of quantification was 3.1%.     

Differentiation of animal species in food by oligonucleotide microarray hybridization

Oligonucleotide microarray hybridization analysis of polymerase chain reaction (PCR) products from the mitochondrial cytochrome b gene DNA was applied to identify different animal species in meat and cheese food samples. A pair of universal primers binding to conserved regions of the vertebrate mitochondrial cytochrome b gene was used to amplify a 377 bp fragment with internal regions of high inter-species variability. PCR products of cattle, pig, chicken, turkey, sheep and goat were unequivocally identified by hybridization with species-specific probe sequences immobilized on an oligonucleotide microarray. In meat samples, 0.1% admixtures of beef or chicken meat were still detectable. By using this new PCR-based DNA chip hybridization for the analysis of 24 commercial food samples from routine control, the simultaneous species composition of mixtures with up to four different species could be determined in a single experiment. The results agreed well with those from the reference methods performed at the local food control authority, which are a combination of enzyme-linked immunosorbent assay (ELISA), species-specific PCR and PCR–RFLP (restriction fragment length polymorphism). Thus, the DNA chip hybridization analysis of cytochrome b PCR products offers a new way for rapid and sensitive species differentiation in food.     

Simultaneous detection of cow and buffalo species in milk from China, India, and Pakistan using multiplex real-time PCR

Asian countries are major producers of cow and buffalo milk. For quality and authenticity purposes, a multiplex real-time PCR assay was developed to specifically and simultaneously detect DNA from these 2 bovine species. Targeting the cytochrome b gene of mitochondrial DNA, common PCR primers amplified a 105-bp fragment, and 2 fluorescent probes specific to either cow or buffalo were designed for their identification. Specificity was successfully tested on 6 other species, including sheep and goat, and sensitivity reached 1% of cow DNA in buffalo DNA and vice versa. As an evaluation, the method was tested using 119 freeze-dried Asian milk samples from regional industrial milk facilities. Although these samples did not cover the entire Asian zone, the multiplex assay indicated that approximately 20% of the samples (mainly from India) showed high levels of cross-contamination of cow milk by buffalo milk, and vice versa. Fast, sensitive, and straightforward, this method is fit-for-purpose for the authenticity control of Asian milk.