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Whey protein dynamics in goat mammary secretions during colostrum and early lactation periods

Published online by Cambridge University Press:  08 April 2024

Raquel F. S. Raimondo*
Affiliation:
RuminAção – Teaching, Research and Extension in Ruminants, Faculty of Veterinary Medicine, Federal University of Rio Grande do Sul, Porto Alegre, Brazil Department of Internal Medicine, School of Veterinary Medicine and Animal Science, University of São Paulo, São Paulo, Brazil
Samantha I. Miyashiro
Affiliation:
Department of Internal Medicine, School of Veterinary Medicine and Animal Science, University of São Paulo, São Paulo, Brazil
Eduardo H. Birgel Junior
Affiliation:
Department of Veterinary Medicine, College of Animal Science and Food Engineering, University of São Paulo, São Paulo, Brazil
*
Corresponding author: Raquel F. S. Raimondo; Email: [email protected]
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Abstract

The protein composition in goat milk undergoes changes throughout the different lactation periods, displaying distinct characteristics that are influenced by the dynamic nature of protein composition and concentration during the transition from colostrum secretion to mature milk. To evaluate the dynamics of whey proteins of Saanen goats during the colostral phase and the first month of lactation, 110 milk samples from 11 healthy mammary halves of seven Saanen goats were selected through a clinical evaluation. Whey was obtained by rennet coagulation of the mammary secretion. The biuret method determined total protein concentration, and their fractions were identified by 12% dodecyl sulfate-polyacrylamide gel electrophoresis. Maximum concentrations of all protein fractions were observed in the first 12 h of lactation, reducing throughout the study. Modification of the protein predominance was also observed. The transition from colostrum secretion to milk occurred 5 or 7 d postpartum.

Type
Research Article
Copyright
Copyright © Universidade de São Paulo, 2024. Published by Cambridge University Press on behalf of Hannah Dairy Research Foundation

Extensive research has been conducted on the nutritional and functional properties of milk proteins. Recently, proteomic techniques have been employed to extend knowledge of minor proteins, including those in low abundance. Specifically, various studies have focused on the whey proteome of goat milk (Sun et al., Reference Sun, Wang, Sun and Guo2020). Investigations into the whey proteomes at different stages of lactation have been carried out in both bovine (Yang et al., Reference Yang, Cao, Wu, Liu, Ye, Yue and Wu2017; Raimondo et al., Reference Raimondo, Ferrão, Miyashiro, Ferreira, Saut, Birgel and Birgel Junior2018) and goat species (Raimondo et al., Reference Raimondo, Brandespim, Prina, Miyashiro, Saut, Mori, Pogliani and Birgel2013a; Sun et al., Reference Sun, Wang, Sun and Guo2020). Previous studies have also examined goat milk whey proteomes at different lactation stages (Raimondo et al., Reference Raimondo, Miyiashiro, Mori and Birgel Junior2013b; Hernández-Castellano et al., Reference Hernández-Castellano, Almeida, Castro and Argüello2014). A recent study in the dairy industry focused on the evaluation of whey proteins from goat colostrum and mature milk using proteomic techniques (Sun et al., Reference Sun, Wang, Sun and Guo2020). The same researchers evaluated the dynamics of whey protein concentration during the colostral and early lactation periods in cows, utilizing the polyacrylamide gel electrophoresis (SDS-PAGE) technique (Raimondo et al., Reference Raimondo, Ferrão, Miyashiro, Ferreira, Saut, Birgel and Birgel Junior2018). We wished to extend this to approach to goat milk, therefore, the research described here aimed to investigate the whey protein concentration in goat mammary secretions during the colostrum and early lactation periods using the SDS-PAGE technique.

Material and methods

110 samples from 11 healthy mammary halves of seven Saanen goats were obtained over 10 occasions within the first 30 d in milk (DIM), namely at 0–12 h, 12–24 h and then at 2, 3, 5, 7, 10, 15, 20 and 30 DIM. The animals were kept in pens with access to sunlight, fed hay twice a day and received concentrates containing 14% crude protein in the morning. They were machine milked twice daily.

Firstly, the samples were submitted for microbiological examination. Three positive mammary halves on microbiological analysis were withdrawn from the study. The total protein was determined by infrared radiation. Whey was obtained from milk coagulation, and the determination of its protein was carried out through the Biureto method adopted by Raimondo et al. (Reference Raimondo, Mori, Miyiashiro and Junior2010). The fractionation of whey proteins was determined by 12% polyacrylamide gel electrophoresis (SDS PAGE) according to Raimondo et al. (Reference Raimondo, Miyiashiro, Mori and Birgel Junior2013b). An example electropherogram is given at Supplementary Figure S1.

A descriptive analysis of data was performed and mean, standard deviation, and respective intervals with 95% confidence were obtained. The percentage of each fraction related to whey protein was calculated to describe protein predominance. For the inferential analysis, we first confirmed the hypothesis that the data followed a normal distribution with Kolmogorov–Smirnov test. The measured data were analyzed taking into account the goat and the sampling time during early lactation period applying an ANOVA design with repeated measurements (P ≤ 0.05) by using the following model: Yij = + i + ̨j + eij (i = 1,…, 40; j = 1,…, 7) in which = mean of all data; i = is the effect of the ith goat; ̨j = is the effect of the jth moments during early lactation period (group); eij = represents the residual between quarters error. The means were compared with paired Student's t-test testing the paired differences between them. Casein was calculated as the difference between total protein content and whey protein content.

Results and discussion

The high concentration of whey protein in colostrum (Table 1), which peaked in the first 12 h of lactation, as well as the marked decrease of this concentration over the days observed in the present research, are in accordance with the reports of previous studies regardless of the technique used (Sanchez-Macias et al., Reference Sanchez-Macías, Moreno-Indias, Castro, Morales-de la Nuez and Argüello2014; Marziali et al., Reference Marziali, Guerra, Cerdán-Garcia, Segura-Carretero, Caboni and Verardo2018).

Table 1. Total milk protein, whey protein and various whey protein fractions in goat mammary secretions during the first month of lactation determined by SDS PAGE

Values are mean and sem.

Different letters on the same line mean P ⩽ 0.05, Students t test. nd, nondetectable; MW, molecular weight

The concentration of whey protein and the obtained fractions (Table 1) were also high 12 h postpartum. They decreased abruptly between 12 and 24 h of lactation and continued to decrease steadily until the end of the study period. This steady decline was different from what was observed in cows, where there was stability in whey protein concentration starting from the third day of lactation (Raimondo et al., Reference Raimondo, Ferrão, Miyashiro, Ferreira, Saut, Birgel and Birgel Junior2018). Using the same SDS-PAGE technique, these authors demonstrated that the transition from colostrum to milk began between 24 and 72 h postpartum in cows. We now show that the dynamics of whey proteins in goat milk during the physiological adaptation of the mammary gland for the transition from colostrum secretion to milk occur later compared to cows.

In the fractionation of the proteins by 12% SDS-PAGE during the colostral phase and the first month of lactation of Saanen goats, the following protein fractions were identified and quantified: lactoferrin (84.0 ± 4.0 kDa); albumin (66.0 ± 2.0 kDa); heavy chain immunoglobulin (52.0 ± 2.0 kDa); light chain immunoglobulin (26.0 ± 1.5 kDa); β -lactoglobulin (β-LG) (16.0 ± 1.0 kDa) and α-lactalbumin (α-LA) (12.0 ± 0.65 kDa). Identifying whey proteins through 12% SDS-PAGE using purified proteins has already been described as efficient in previous studies (Raimondo et al., Reference Raimondo, Brandespim, Prina, Miyashiro, Saut, Mori, Pogliani and Birgel2013a, Reference Raimondo, Miyiashiro, Mori and Birgel Junior2013b, Reference Raimondo, Ferrão, Miyashiro, Ferreira, Saut, Birgel and Birgel Junior2018).

The colostral phase strongly influenced the dynamics of goat milk proteins. In percentages (Fig. 1), within the first 24 h of lactation, whey protein represented over 80% of the total protein content, declining to approximately 30% by the 5th day. During full lactation, goat milk exhibited an approximate protein ratio 20:80 for whey proteins and casein (Selvaggi et al., Reference Selvaggi, Laudadio, Dario and Tufarelli2014). Regarding the obtained fractions, immunoglobulins prevailed in the early lactation hours (41% within the first 12 h and 36% on the 1st day). In contrast, the concentration of the major whey proteins, β-LG (12 h: 26%; 24 h: 27%) and α-LA (12 h: 9%; 24 h: 12%) accounted for 35% within the first 12 h and 39% on the 1st day of lactation. Chen et al. (Reference Chen, Chang, Peh and Chen1998) observed that in the first colostrum collected from goats, approximately 50% of the total proteins consisted of immunoglobulins. This proportion decreased to 30% of the total protein by the end of the first day. In cows, immunoglobulins were the predominant protein, comprising 48% in the first 12 h and 47% between 12 and 24 h of lactation in the total whey protein fraction (Raimondo et al., Reference Raimondo, Ferrão, Miyashiro, Ferreira, Saut, Birgel and Birgel Junior2018). These authors noted that on the 3rd day of lactation, immunoglobulins accounted for 37%, while the major whey proteins β-LG and α-LA began to predominate, representing 47% of the total whey protein.

Figure 1. Radar graph showing the percentage of whey protein and casein (obtained by difference between total protein and whey protein) in the total milk protein of goats during the first month of lactation.

On the 5th day of lactation, the protein profile underwent a shift, with the significant whey protein fractions, β-LG (30%) and α-LA (21%), accounting for a combined 51%, while immunoglobulins represented 29%. This dominance was maintained until the end of the study, where β-LG and α-LA remained as the predominant fractions, comprising 57%, while immunoglobulins contributed 23%. In this study, the transition of goat colostrum to milk was considered complete after 5 or 7 d, as all measured parameters fell within the normal ranges reported in the literature for goat milk (Supplementary Figure S2). From day 1 to day 5, the secretion can be classified as transitional goat milk (Sanchez-Macías et al., Reference Sanchez-Macías, Moreno-Indias, Castro, Morales-de la Nuez and Argüello2014).

Colostrum is mainly characterized by its very high level of IgG, essentially of the IgG1 subclass, which is actively passed from the serum to the mammary gland during the last weeks before parturition with the function of contributing to neonatal passive immunity (Levieux et al., Reference Levieux, Morgan, Geneix, Masle and Bouvier2002). Due to their importance, immunoglobulins are the most studied colostrum proteins through several evaluation methods. Regardless of the method used, there is a consensus about the maximum concentration of immunoglobulin in colostrum and its decrease with the advancement of lactation (Table 1), which was also observed in the present research and a previous study performed on colostrum from cows (Raimondo et al., Reference Raimondo, Ferrão, Miyashiro, Ferreira, Saut, Birgel and Birgel Junior2018).

The concentrations of β-LG were higher than those of α-LA throughout the entire period, and their behavior differed. The levels of β-LG decreased abruptly in the first 48 h of lactation, while the decrease in α-LA was slower and more gradual. Others have observed that the concentrations of α-LA and β-LG remain stable in goats during the first five days of lactation and increase as the levels of immunoglobulins decrease (Chen et al., Reference Chen, Chang, Peh and Chen1998). These major whey proteins, α-LA and β-LG, are crucial in determining the nutritional value and functional properties of whey and whey products.

The importance of the increased content of β-LG relates to the fact that it is a significant protein in the whey of ruminant milk and may play important functions in the binding and transport of hydrophobic ligands such as retinoids, alkenes, and fatty acids in addition to being an important source of amino acids for the offspring (Kontopidis et al., Reference Kontopidis, Holt and Sawyer2004). α-LA is a small, acidic-cation binding milk protein, which is very important from several points of view being an essential enzyme component for lactose synthesis, a model Ca2+ binding protein, classic molten globule and possessing important biological and functional properties (Stănciuc and Râpeanu, Reference Stănciuc and Rapeanu2010).

Following the same pattern as the other fractions, the concentrations of albumin and lactoferrin (Table 1) were also influenced by the colostral phase. They reached their maximum concentrations within the first 12 h and underwent a sharp decrease on the 1st day of lactation. These proteins play an essential role in the immunity of the mammary gland, and the increase in their concentration coincides with the higher susceptibility to intramammary infections. It may signify an organic reaction that precedes disease, considering that the evaluated glands in the present study were healthy.

According to Shamay et al. (Reference Shamay, Homans, Fuerman, Levin, Barash, Silanikove and Mabjeesh2005), albumin synthesis occurs in mammary tissue, and situations involving inflammatory processes, such as mastitis and the dry period, could substantially increase its secretion by the mammary gland. The elevation of albumin levels in milk reflects udder inflammation during the postpartum period and an increase in vascular permeability (Zhang et al., Reference Zhang, Wang, Yang, Bu, Li and Zhou2011). In similar fashion, lactoferrin plays a crucial role in the defense of the mammary gland (McGrath et al., Reference McGrath, Fox, Mcsweeney and Kelly2016). Its high concentration during the first days of lactation may be related to a possible function in preventing infections.

In addition to the commonly observed whey proteins in goat milk, unidentified protein fractions were detected and presented based on their molecular weights. These protein fractions appeared before the lactoferrin fraction, with molecular weights ranging from 132 to 244 kDa and between the heavy chain immunoglobulins and light chain immunoglobulins, 29 to 43 kDa. These same protein fractions were observed in a previous study involving cow colostrum (Raimondo et al., Reference Raimondo, Ferrão, Miyashiro, Ferreira, Saut, Birgel and Birgel Junior2018). The authors attributed this finding to the increased blood flow in the mammary gland during the preparatory phase of parturition, resulting in physiological inflammation and increased vascular permeability, allowing serum proteins to pass into the mammary gland.

The behavior of these unidentified protein fractions was like the other whey proteins (Table 1). The fraction with a molecular weight between 132 and 244 kDa exhibited the highest average levels within the first 12 h of lactation and decreased abruptly in samples collected at 24 h, no longer being observed after that. No studies were found in the reviewed literature that mentioned the presence of these fractions, except for the survey conducted on cow colostrum by the same researchers (Raimondo et al., Reference Raimondo, Ferrão, Miyashiro, Ferreira, Saut, Birgel and Birgel Junior2018).

The proteins with a molecular weight between 30 and 50 kDa showed peak concentrations within the first 12 h of lactation (Table 1). These levels declined rapidly within five days, stabilized on the 15th day of lactation, and were no longer observed in samples collected from 20 d onwards.

In conclusion, we have confirmed that the whey protein fractions in goat milk exhibit maximum concentrations within the first 12 h of lactation, followed by a gradual decrease over the first month. This pattern reflects the nutritional and immunological quality of the colostral secretion in goats. The transition from colostrum to milk in goats is typically achieved after 5 or 7 d, as indicated by all measured parameters falling within the normal ranges described in the existing literature for goat milk. The percentage distribution of protein fractions plays a significant role in shaping whey protein profile. A predominant presence of immunoglobulins characterizes colostrum, while β-LG and α-LA become the predominant fractions from the 2nd day onwards.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S002202992400013X

References

Chen, JC, Chang, CJ, Peh, HC and Chen, SY (1998) Total protein and gamma-globulin contents of mammary secretion during the early post-partum period of Nubian goats in Taiwan. Small Ruminant Research 31, 6773.Google Scholar
Hernández-Castellano, LE, Almeida, AM, Castro, N and Argüello, A (2014) The colostrum proteome, ruminant nutrition, and immunity: a review. Current Protein & Peptide Science 15, 6474.Google ScholarPubMed
Kontopidis, G, Holt, C and Sawyer, L (2004) Invited review: β-lactoglobulin: binding properties, structure, and function. Journal of Dairy Science 87, 785796.CrossRefGoogle ScholarPubMed
Levieux, D, Morgan, F, Geneix, N, Masle, I and Bouvier, F (2002) Caprine immunoglobulin G, β-lactoglobulin, α-lactalbumin and serum albumin in colostrum and milk during the early postpartum period. Journal of Dairy Research 69, 391399.CrossRefGoogle Scholar
Marziali, S, Guerra, E, Cerdán-Garcia, C, Segura-Carretero, A, Caboni, MF and Verardo, V (2018) Effect of early lactation stage on goat colostrum: assessment of lipid and oligosaccharide compounds. International Dairy Journal 77, 6572.CrossRefGoogle Scholar
McGrath, BA, Fox, PF, Mcsweeney, PLH and Kelly, L (2016) Composition and properties of bovine colostrum: a review. Dairy Science & Technology 96, 133158.CrossRefGoogle Scholar
Raimondo, RFS, Mori, CS, Miyiashiro, SI and Junior, EHB (2010) Standardization of the Biuret Method for determining the whey proteins. Page 119 in World Buiatrics Congress. Proc., Santiago. Santiago: World Association for Buiatrics.Google Scholar
Raimondo, RFS, Brandespim, FB, Prina, APM, Miyashiro, SI, Saut, JPE, Mori, CS, Pogliani, FC and Birgel, EH (2013a) Dynamic in the concentration of whey proteins in the mammary secretion of goats during the dry period. Small Ruminant Research 113, 239246.CrossRefGoogle Scholar
Raimondo, RFS, Miyiashiro, SI, Mori, CS and Birgel Junior, EH (2013b) Proteínas do soro lácteo de vacas da raça Jersey durante a lactação. Pesquisa Veterinária Brasileira 33, 119125.CrossRefGoogle Scholar
Raimondo, RF, Ferrão, JS, Miyashiro, SI, Ferreira, PT, Saut, JPE, Birgel, DB and Birgel Junior, EH (2018) The dynamics of individual whey protein concentrations in cows’ mammary secretions during the colostral and early lactation periods. Journal of Dairy Research 86, 8893.CrossRefGoogle ScholarPubMed
Sanchez-Macías, D, Moreno-Indias, I, Castro, N, Morales-de la Nuez, A and Argüello, A (2014) From goat colostrum to milk: physical, chemical, and immune evolution from partum to 90 days postpartum. Journal of Dairy Science 97, 1016.CrossRefGoogle ScholarPubMed
Selvaggi, M, Laudadio, V, Dario, C and Tufarelli, V (2014) Major proteins in goat milk: an updated overview on genetic variability. Molecular Biology Reports 41, 10351048.CrossRefGoogle ScholarPubMed
Shamay, A, Homans, R, Fuerman, Y, Levin, I, Barash, H, Silanikove, N and Mabjeesh, SJ (2005) Expression of albumin in nonhepatic tissues and its synthesis by the bovine mammary gland. Journal of Dairy Science 88, 569576.CrossRefGoogle ScholarPubMed
Stănciuc, N and Rapeanu, G (2010) An overview of bovine α-lactalbumin structure and functionality The Annals of the University Dunarea de Jos of Galati. Fascicle VI-Food Technology 34, 8293.Google Scholar
Sun, Y, Wang, C, Sun, X and Guo, M (2020) Proteomic analysis of whey proteins in the colostrum and mature milk of Xinong Saanen goats. Journal of Dairy Science 103, 11641174.CrossRefGoogle ScholarPubMed
Yang, M, Cao, X, Wu, R, Liu, B, Ye, W, Yue, X and Wu, J (2017) Comparative proteomic exploration of whey proteins in human and bovine colostrum and mature milk using iTRAQ-coupled LCMS/ MS. International Journal of Food Sciences and Nutrition 68, 671681.CrossRefGoogle Scholar
Zhang, LY, Wang, JQ, Yang, YX, Bu, DP, Li, SS and Zhou, LY (2011) Comparative proteomic analysis of changes in the bovine whey proteome during the transition from colostrum to milk. Asian-Australasian Journal of Animal Sciences 24, 272278.CrossRefGoogle Scholar
Figure 0

Table 1. Total milk protein, whey protein and various whey protein fractions in goat mammary secretions during the first month of lactation determined by SDS PAGE

Figure 1

Figure 1. Radar graph showing the percentage of whey protein and casein (obtained by difference between total protein and whey protein) in the total milk protein of goats during the first month of lactation.

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