Specificity of Lactococcus lactis subsp. cremoris SK11 Proteinase, Lactocepin III, in Low-Water-Activity, High-Salt-Concentration Humectant Systems and Its Stability Compared with That of Lactocepin I

Marked changes in the specificity of hydrolysis of α_s1-, β-, and κ-caseins by lactocepin III from Lactococcus lactis subsp. cremoris SK11 were found in humectant systems giving the equivalent water activity (a_w) and salt concentration of cheddar cheese. Correlations were noted between certain peptides produced by the activity of lactocepin III in the humectant systems and peptides found in cheddar cheese. The stability of lactocepin III was compared with that of lactocepin I from L. lactis subsp. cremoris HP in the humectant systems at different pHs. Significant differences between the stability of each of the lactocepin types were evident. The relationship between stability and humectant type, a_w, pH, and NaCl concentration was complex. Nevertheless, in those systems where a_w, pH, and NaCl concentration were equivalent to those in cheddar cheese, lactocepin I was generally more stable than lactocepin III. It was concluded that differences in the specificity and/or stability of various lactocepin types are likely to persist in cheese itself and therefore potentially contribute to differences in the peptide composition of ripened cheese.     

The autoproteolysis of Lactococcus lactis lactocepin III affects its specificity towards beta-casein

The effect of autoproteolysis of Lactococcus lactis lactocepin III on its specificity towards beta-casein was investigated. beta-Casein degradation was performed by using either an autolysin-defective derivative of L. lactis MG1363 carrying the proteinase genes of L. lactis SK11, which was unable to transport oligopeptides, or autoproteolyzed enzyme purified from L. lactis SK11. Comparison of the peptide pools by high-performance liquid chromatography analysis revealed significant differences. To analyze these differences in more detail, the peptides released by the cell-anchored proteinase were identified by on-line coupling of liquid chromatography to mass spectrometry. More than 100 oligopeptides were released from beta-casein by the cell-anchored proteinase. Analysis of the cleavage sites indicated that the specificity of peptide bond cleavage by the cell-anchored proteinase differed significantly from that of the autoproteolyzed enzyme.     

Comparative Study of Action of Cell Wall Proteinases from Various Strains of Streptococcus cremoris on Bovine alpha(s1)-, beta-, and kappa-Casein

Partially purified cell wall proteinases of eight strains of Streptococcus cremoris were compared in their action on bovine alpha(s1)-, beta-, and kappa-casein, as visualized by starch gel electrophoresis, sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and thin-layer chromatography. Characteristic degradation profiles could be distinguished, from which the occurrence of two proteinases, represented by strain HP and strain AM(1), was concluded. The action of the HP-type proteinase P(1) (also detectable in strains Wg(2), C(13), and TR) was established by electrophoretic methods to be directed preferentially towards beta-casein. The AM(1)-type proteinase P(III) (also detectable in strain SK(11)) was also able to degrade beta-casein, but at the same time split alpha(s1)- and kappa-casein more extensively than did P(I). Strain FD(27) exhibited mainly P(I) activity but also detectable P(III) degradation characteristics. The cell wall proteinase preparation of strain E(8) showed low P(I) as well as low P(III) activity. All proteinase preparations produced from kappa-casein positively charged degradation products with electrophoretic mobilities similar to those of degradation products released by the action of the milk-clotting enzyme chymosin. The differences between P(I) and P(III) in mode of action, as detected by gel electrophoresis and thin-layer chromatography, were reflected by the courses of the initial degradation of methyl-C-labeled beta-casein and by the effect of alpha(s1)- plus kappa-casein on these degradations. The results are discussed in the light of previous comparative studies of cell wall proteinases in strains of S. cremoris and with respect to the growth of this organism in milk.     

Substrate specificity of the cell envelope-located proteinase of Lactococcus lactis subsp. lactis NCDO 763.

1. The specificity of the cell envelope-located proteinase of Lactococcus lactis subsp. lactis NCDO 763 towards caseins has been submitted to a statistical study. Positive and negative relations have been evidenced between several amino acids and positions P6 to P'2 of the cleaved bonds. 2. Fragment 1-23 of alpha s1 and oxidized B chain of insulin are well cleaved by the proteinase while CMP (fragment 106-169 of kappa-casein) is a poor substrate. 3. Comparison with other cell envelope-located proteinase has been done. The enzyme of the strain 763 hydrolyses alpha s1-casein and fragment 1-23 of alpha s1-casein as the enzyme of the strain Sk11 and beta-casein as the enzyme of the strain Wg2. 4. The specificity of these proteinases and the comparison of their amino acid sequences let us postulate a more complex substrate binding area for these lactococcal proteinases than for the subtilisin.     

Conversion of Lactococcus lactis cell envelope proteinase specificity by partial allele exchange

AIMS: To determine whether conversion of lactocepin substrate binding regions by gene replacement can alter lactocepin specificity in Lactococcus lactis starter bacteria without affecting other important strain properties. METHODS AND RESULTS: We utilized two-step gene replacement to convert substrate-binding determinants in the L. lactis prtP genes encoding group h (bitter) lactocepin in two industrial strains into the corresponding group b (nonbitter) variant. Analysis of lactocepin activity toward alpha(s1)-casein (f 1-23) by reversed-phase high-pressure liquid chromatography demonstrated enzyme specificity among isogenic derivatives had been altered in a manner that was consistent with predicted amino acid substitutions in substrate binding regions. Milk acidification properties of some mutants were not statistically different (P > 0.05) from wild-type parent strains, and strain propensity for autolysis was also not significantly (P > 0.05) changed. CONCLUSIONS: Conversion of lactocepin substrate binding regions by allele exchange can effectively alter lactocepin specificity in industrial strains of L. lactis without significantly affecting other important strain properties. SIGNIFICANCE AND IMPACT OF THE STUDY: Methodology outlined in this study can be used to alter lactocepin specificity in commercial starter cultures with a propensity for bitter flavour defect, and prtP derivatives developed by this approach should be suitable for commercial application.     

Contribution of Lactococcus lactis cell envelope proteinase specificity to peptide accumulation and bitterness in reduced-fat Cheddar cheese

Bitterness is a flavor defect in Cheddar cheese that limits consumer acceptance, and specificity of the Lactococcus lactis extracellular proteinase (lactocepin) is widely believed to be a key factor in the development of bitter cheese. To better define the contribution of this enzyme to bitterness, we investigated peptide accumulation and bitterness in 50% reduced-fat Cheddar cheese manufactured with single isogenic strains of Lactococcus lactis as the only starter. Four isogens were developed for the study; one was lactocepin negative, and the others produced a lactocepin with group a, e, or h specificity. Analysis of cheese aqueous extracts by reversed-phase high-pressure liquid chromatography confirmed that accumulation of alpha(S1)-casein (f 1-23)-derived peptides f 1-9, f 1-13, f 1-16, and f 1-17 in cheese was directly influenced by lactocepin specificity. Trained sensory panelists demonstrated that Cheddar cheese made with isogenic starters that produced group a, e, or h lactocepin was significantly more bitter than cheese made with a proteinase-negative isogen and that propensity for bitterness was highest in cells that produced group h lactocepin. These results confirm the role of starter proteinase in bitterness and suggest that the propensity of some industrial strains for production of the bitter flavor defect in cheese could be altered by proteinase gene exchange or gene replacement.     

Nucleotide sequence and characterization of the cell envelope proteinase plasmid in Lactococcus lactis subsp. cremoris HP

AIMS: The major cell envelope proteinase (lactocepin; EC 3.4.21.96) produced by Lactococcus lactis cheese starter bacteria is required for starter growth and acid production in milk. The aim of this study was to characterize a lactocepin plasmid from a L. lactis subsp. cremoris cheese starter strain. METHODS AND RESULTS: A restriction map of the lactocepin plasmid pHP003 from strain HP was constructed, fragments were cloned in Escherichia coli vectors, and the complete DNA sequence (13,433 bp) was determined. Among 120 industrial L. lactis starter strains screened, five contained the same specificity-type lactocepin as pHP003. The lactocepin gene in these strains was invariably linked with a partially-deleted abiB gene. CONCLUSION: The lactocepin specificity type of strain HP, conferred by a known configuration of key residues, is relatively uncommon. The gene is invariably linked with a partially deleted abiB gene on each lactocepin plasmid. SIGNIFICANCE AND IMPACT OF THE STUDY: This is the first complete sequence reported for a lactocepin plasmid, and provides the basis for better understanding, or manipulation, of lactocepin production.     

Characterization of the pattern of alphas1- and beta-casein breakdown and release of a bioactive peptide by a cell envelope proteinase from Lactobacillus delbrueckii subsp. lactis CRL 581

The cell envelope-associated proteinases (CEPs) of the lactobacilli have key roles in bacterial nutrition and contribute to the development of the organoleptic properties of fermented milk products as well, as they can release bioactive health-beneficial peptides from milk proteins. The influence of the peptide supply, carbohydrate source, and osmolites on the CEP activity of the cheese starter Lactobacillus delbrueckii subsp. lactis CRL 581 was investigated. The CEP activity levels were controlled by the peptide content of the growth medium. The maximum activity was observed in a basal minimal defined medium, whereas in the presence of Casitone, Casamino Acids, or yeast extract, the synthesis of CEP was inhibited 99-, 70-, and 68-fold, respectively. The addition of specific di- or tripeptides containing branched-chain amino acids, such as leucylleucine, prolylleucine, leucylglycylglycine, or leucylproline, to the growth medium negatively affected CEP activity, whereas dipeptides without branched-chain amino acids had no effect on the enzyme's production. The carbon source and osmolites did not affect CEP activity. The CEP of L. delbrueckii subsp. lactis CRL 581 exhibited a mixed-type CEP(I/III) variant caseinolytic specificity. Mass-spectrometric screening of the main peptide peaks isolated by reverse-phase high-pressure liquid chromatography allowed the identification of 33 and 32 peptides in the alpha(s1)- and beta-casein hydrolysates, respectively. By characterizing the peptide sequence in these hydrolysates, a pattern of alpha(s1)- and beta-casein breakdown was defined and is reported herein, this being the first report for a CEP of L. delbrueckii subsp. lactis. In this pattern, a series of potentially bioactive peptides (antihypertensive and phosphopeptides) which are encrypted within the precursor protein could be visualized.     

Resolution and characterisation of multiple isoforms of bovine kappa-casein by 2-DE following a reversible cysteine-tagging enrichment strategy

Visualisation of multiple isoforms of kappa-casein on 2-D gels is restricted by the abundant alpha- and beta-caseins that not only limit gel loading but also migrate to similar regions as the more acidic kappa-casein isoforms. To overcome this problem, we took advantage of the absence of cysteine residues in alpha(S1)- and beta-casein by devising an affinity enrichment procedure based on reversible biotinylation of cysteine residues. Affinity capture of cysteine-containing proteins on avidin allowed the removal of the vast majority of alpha(S1)- and beta-casein, and on subsequent 2-D gel analysis 16 gel spots were identified as kappa-casein by PMF. Further analysis of the C-terminal tryptic peptide along with structural predictions based on mobility on the 2-D gel allowed us to assign identities to each spot in terms of genetic variant (A or B), phosphorylation status (1, 2 or 3) and glycosylation status (from 0 to 6). Eight isoforms of the A and B variants with the same PTMs were observed. When the casein fraction of milk from a single cow, homozygous for the B variant of kappa-casein, was used as the starting material, 17 isoforms from 13 gel spots were characterised. Analysis of isoforms of low abundance proved challenging due to the low amount of material that could be extracted from the gels as well as the lability of the PTMs during MS analysis. However, we were able to identify a previously unrecognised site, T(166), that could be phosphorylated or glycosylated. Despite many decades of analysis of milk proteins, the reasons for this high level of heterogeneity are still not clear.     

Chelator,metal ion and buffer studies for protein C separation

Protein C (PC) is the pivotal anticoagulant and antithrombotic in the human coagulation cascade. PC deficiency can result in major medical problems such as deep vein thrombosis (DVT), leading to tissue oxygen deprivation. PC treatment has no bleeding or skin necrosis problems because it circulates in the blood as a zymogen and is only activated when and where it is needed. One source of PC is transgenic animal milk. The major components in the milk, such as alpha-casein, beta-casein, kappa-casein, alpha-lactalbumin and beta-lactoglobulin, are proteins that must be separated from PC. Immobilized metal affinity chromatography (IMAC) is an inexpensive separation technology with relatively high specificity, and it has great potential for difficult protein separations. After systematic studies of different chelator, metal ion and buffers, the combination of iminodiacetic acid (IDA) and Fe was found to be effective to separate PC from major milk components. alpha-Lactalbumin and beta-lactoglobulin fell through the column in the starting buffer. PC was eluted. alpha-Casein, beta-casein, kappa-casein remained bound in the column after PC elution. This technology might be applied for PC separation from transgenic animal milk. It is very important for PC production in large quantities and at low cost to treat PC-deficient patients.     

Glycogen synthase kinases. Classification of a rabbit liver casein and glycogen synthase kinase (casein kinase-1) as a distinct enzyme

A protein kinase, able to phosphorylate casein, phosvitin, and glycogen synthase, was purified approximately 9000-fold from rabbit liver, and appeared analogous to an enzyme studied by Itarte and Huang (Itarte, E., and Huang, K.-P. (1979) J. Biol. Chem. 254, 4052-4057). This enzyme, designated here casein kinase-1, was shown to be a distinct glycogen synthase kinase and in particular to be different from the protein kinase GSK-3 (Hemmings, B.A., Yellowlees, D., Kernohan, J.C., and Cohen, P. (1981) Eur. J. Biochem. 119, 443-451). Casein kinase-1 had native molecular weight of 30,000 as judged by gel filtration. The enzyme phosphorylated beta-casein A or B better than kappa-casein or alpha s1-casein, and modified only serine residues in beta-casein B and phosvitin. The apparent Km for ATP was 11 microM, and GTP was ineffective as a phosphoryl donor. The phosphorylation of glycogen synthase by casein kinase-1 was inhibited by glycogen, half-maximally at 2 mg/ml, and by heparin, half-maximally at 0.5-1.0 microgram/ml, but was unaffected by Ca2+ and/or calmodulin, or by cyclic AMP. Phosphorylation of muscle glycogen synthase proceeded to a stoichiometry of at least 6 phosphates/subunit with reduction in the +/- glucose-6-P activity ratio to less than 0.4. Phosphate was introduced into both a COOH-terminal CNBr fragment (CB-2) as well as a NH2-terminal fragment (CB-1). At a phosphorylation stoichiometry of 6 phosphates/subunit, 84% of the phosphate was associated with CB-2 and 6.5% with CB-1. The remainder of the phosphate was introduced into another CNBr fragment of apparent molecular weight 16,500. Phosphorylation by casein kinase-1 correlated with reduced electrophoretic mobilities, as analyzed on polyacrylamide gels in the presence of sodium dodecyl sulfate, of the intact glycogen synthase subunit, as well as the CNBr fragments CB-1 and CB-2.     

Kinetic study of the action of bovine chymosin and pepsin A on bovine kappa-casein

A study was carried out to determine the Michaelian parameters relative to the action of chymosin and pepsin A on bond Phe105-Met106 of bovine kappa0-casein (carbohydrate-free fraction in micellar state). The reaction was performed in citrate buffer, pH 6.2, at 30 degrees C. The reaction mixture was analysed by reverse phase HPLC. Dosages of peptide 106-169 (caseino macropeptide) at different reaction times from recordings of its absorbance at 220 nm gave the initial rates of reaction at each substrate concentration. From these values the following parameters were determined: kcat = 68.5 s-1, Km = 0.048 mM, kcat/Km = 1,413 mM-1 s-1 for chymosin, and kcat = 45 s-1, Km = 0.018 mM, kcat/Km = 2,439 mM-1 s-1 for pepsin A. For chymosin they are similar to those obtained previously in dimethyl glutarate buffer, pH 6.6, at 30 degrees C, using fragment 98-111 of kappa-casein as substrate. It can thus be concluded that neither the micellar state nor the presence of the whole peptide chain of kappa-casein (our conditions) significantly affect the action of chymosin on fragment 98-111, which seems to contain all information that makes bond 105-106 highly sensitive to chymosin. For pepsin A, only the information contained in fragment 103-108 appears to be required.     

Cell-wall-bound proteinase of Lactobacillus delbrueckii subsp. lactis ACA-DC 178: characterization and specificity for beta-casein

Lactobacillus delbrueckii subsp. lactis ACA-DC 178, which was isolated from Greek Kasseri cheese, produces a cell-wall-bound proteinase. The proteinase was removed from the cell envelope by washing the cells with a Ca2+-free buffer. The crude proteinase extract shows its highest activity at pH 6.0 and 40 degrees C. It is inhibited by phenylmethylsulfonyl fluoride, showing that the enzyme is a serine-type proteinase. Considering the substrate specificity, the enzyme is similar to the lactococcal PI-type proteinases, since it hydrolyzes beta-casein mainly and alpha- and kappa-caseins to a much lesser extent. The cell-wall-bound proteinase from L. delbrueckii subsp. lactis ACA-DC 178 liberates four main peptides from beta-casein, which have been identified.     

Cloning and expression of the Lactococcus lactis subsp. cremoris SK11 gene encoding an extracellular serine proteinase

The Lactococcus lactis subsp. cremoris SK11 plasmid-located prtP gene, encoding a cell-envelope-located proteinase (PrtP) that degrades alpha s1-, beta- and kappa-casein, was identified in a lambda EMBL3 gene library in Escherichia coli using immunological methods. The complete prtP gene could not be cloned in E. coli and L. lactis on high-copy-number plasmid vectors. However, using a low-copy-number vector, the complete prtP gene could be cloned in strains MG1363 and SK1128, proteinase-deficient derivatives of L. lactis subsp. lactis 712 and L. lactis subsp. cremoris SK11, respectively. The proteinase deficiency of these hosts was complemented to wild-type (wt) levels by the cloned SK11 prtP gene. The caseinolytic specificity of the proteinase specified by the cloned prtP gene was identical to that encoded by the wt proteinase plasmid, pSK111. The expression of recombinant plasmids containing 3' and 5' deletions of prtP was analyzed with specific attention directed towards the location of the gene products. In this way the expression signals of prtP were localized and overproduction was obtained in L. lactis subsp. lactis. Furthermore, a region at the C terminus of PrtP was identified which is involved in cell-envelope attachment in lactococci. A deletion derivative of prtP was constructed which specifies a C-terminally truncated proteinase that is well expressed and fully secreted into the medium, and still shows the same capacity to degrade alpha s1-, beta- and kappa-casein.     

Contribution of Lactococcus lactis Cell Envelope Proteinase Specificity to Peptide Accumulation and Bitterness in Reduced-Fat Cheddar Cheese

Bitterness is a flavor defect in Cheddar cheese that limits consumer acceptance, and specificity of the Lactococcus lactis extracellular proteinase (lactocepin) is widely believed to be a key factor in the development of bitter cheese. To better define the contribution of this enzyme to bitterness, we investigated peptide accumulation and bitterness in 50% reduced-fat Cheddar cheese manufactured with single isogenic strains of Lactococcus lactis as the only starter. Four isogens were developed for the study; one was lactocepin negative, and the others produced a lactocepin with group a, e, or h specificity. Analysis of cheese aqueous extracts by reversed-phase high-pressure liquid chromatography confirmed that accumulation of α_S1-casein (f 1-23)-derived peptides f 1-9, f 1-13, f 1-16, and f 1-17 in cheese was directly influenced by lactocepin specificity. Trained sensory panelists demonstrated that Cheddar cheese made with isogenic starters that produced group a, e, or h lactocepin was significantly more bitter than cheese made with a proteinase-negative isogen and that propensity for bitterness was highest in cells that produced group h lactocepin. These results confirm the role of starter proteinase in bitterness and suggest that the propensity of some industrial strains for production of the bitter flavor defect in cheese could be altered by proteinase gene exchange or gene replacement.     

Comparison of casein of cynomolgus monkey (Macaca fascicularis) with human casein

Casein of cynomolgus monkey was compared with those from human and bovine milk. Cynomolgus monkey casein showed similar electrophoretical patterns to those of human casein on Disc- and SDS-electrophoresis. It consisted of beta- and kappa-casein-like components. The component corresponding to bovine alpha s1-casein was not detected. The beta-casein-like fraction of cynomolgus monkey showed 9 bands on Disc-PAGE. These were suggested to be the same protein binding different levels of phosphorus by dephosphorylation experiment using an acid phosphatase. The kappa-casein-like component of cynomolgus monkey was highly glycosylated (about 50% carbohydrate) similarly as human kappa-casein and the constituent carbohydrates were same as those detected in human kappa-casein (galactose, fucose, N-acetylgalactosamine, N-acetylglucosamine, and sialic acid). Amino acid composition of cynomolgus monkey kappa-casein bore a resemblance to those of both human and bovine kappa-caseins. Amino acid composition of cynomolgus monkey beta-casein was also similar to those of human and bovine beta-caseins.     

OC-IΔD86 (Oryzacystatin-IΔD86)基因的原核表达及活性分析

根据OC-IΔD86基因序列, 设计合成了7条寡核苷酸片段, 通过重叠延伸PCR技术合成了OC-IΔD86基因, 利用设计好的BamH I/ Xho I酶切位点将OC-IΔD86基因克隆到原核表达载体pet21b中, 在1 mmol/L的IPTG 诱导后5 h, OC-IDD86融合基因在大肠杆菌中得到表达, 表达产物处于可溶状态, 其表达量占总蛋白的11.4%, 可溶性蛋白的16.4%; 利用Ni-NTA系统纯化该蛋白并经PEG20000浓缩后, 活性分析表明该蛋白酶抑制剂在体外表现出对木瓜蛋白酶明显的抑制作用。这为转OC-IΔD86基因的抗根结线虫植物基因工程抗体制备, 以及进一步体内的抗根结线虫研究奠定了基础。     

Isolation and properties of human kappa-casein

Human kappa-casein was isolated from human whole casein by gel filtration with Sephadex G-200 and hydroxylapatite chromatography in the presence of sodium dodecyl sulfate (SDS). The kappa-casein was calcium-insensitive and did stabilize human beta-casein and bovine alpha s1-casein against precipitation by calcium ions. Formation of micelles from human beta- and kappa-caseins, and calcium ions was confirmed by electron microscopic observation. On SDS-polyacrylamide gel electrophoresis (SDS-PAGE), a single band was obtained. The formation of para-kappa-caseins by chymosin was confirmed by SDS-PAGE. Two para-kappa-caseins with apparent molecular weights of 13,000 and 11,000 appeared. The molecular weight of intact human kappa-casein was estimated to be approximately 33,000. The human kappa-casein contained about 40% carbohydrate (15% galactose, 3% fucose, 15% hexosamines, and 5% sialic acid) and 0.10% (1 mol/mol) phosphorus. Its amino acid composition was similar to that of bovine kappa-casein except for serine, glutamic acid, and lysine contents.     

Analysis of polymorphism in the bovine casein genes by use of the polymerase chain reaction

Methods have been devised for detecting polymorphisms in the bovine beta- and kappa-casein genes using the polymerase chain reaction (PCR) followed either by restriction enzyme digestion (to reveal a restriction fragment length polymorphism (RFLP] or by hybridization of an allele-specific oligonucleotide. These methods, as well as being faster and more sensitive than traditional RFLP methods, are of more general applicability since they can detect any change in DNA sequence. They require only a small sample of blood or semen and are applicable to animals of any age or sex. These methods make possible large-scale screening and thus selection for alleles at these loci. Typing of blood DNA can give erroneous results when the animal concerned is a twin; however, this can be overcome by retesting using milk or semen. Analysis of the kappa-casein genotype of Holstein-Friesian bulls gives frequencies for the A and B alleles of 0.80 and 0.20 respectively. Selection in favour of the B allele, which is superior for cheese production, could thus have a large effect. The A3 and B alleles at the beta-casein locus have been shown to be rare in the Holstein-Friesian population. Linkage disequilibrium exists between beta-casein B and kappa-casein B.     

Genotyping the bovine kappa-casein locus using polymerase chain reaction]

Polymerase chain reaction (PCR) was used for detecting kappa-casein (kappa-casein) genotype in the synthetic breed (Jersey x Black and White x Holstein-Friesian) dairy cattle. The amplified 228 bp fragment includes a region, where relevant mutations lead to both the appearance of different kappa-casein alleles associated with amino acid substitutions and the appearance of new TaqI and HindIII restriction sites in ae-casein B gene. The specificity of the kappa-casein gene fragment amplification was supported by restriction analysis and Southern blot hybridization. Digestion of amplified fragment with endonucleases PstI, HindIII and/or TaqI allows detection of AA-, AB- and BB genotypes of kappa-casein. A total of 32 animals with known (18 samples) and unknown (14 samples) kappa-casein phenotypes were tested using PCR and blot hybridization. In all known cases the detected genotype confirmed the phenotype. Frequencies of the B allele and of the AB genotype in the breeding population are rather high (53.1 +/- 8.8 and 43.7%, respectively). The possibility of effective use of the PCR analysis for genotyping kappa-casein locus in bulls and their offspring has been shown. The advantages of the PCR method in large breeding programs and linkage analysis have been discussed.