Hostname: page-component-78c5997874-4rdpn Total loading time: 0 Render date: 2024-11-04T18:07:35.381Z Has data issue: false hasContentIssue false

Supplementation of diets with bovine colostrum influences immune function in dogs

Published online by Cambridge University Press:  18 June 2013

Ebenezer Satyaraj*
Affiliation:
Nestlé Purina Research, One Checkerboard Square, 2RS, Saint Louis, MO63164, USA
Arleigh Reynolds
Affiliation:
Nestlé Purina Research, One Checkerboard Square, 2RS, Saint Louis, MO63164, USA
Robyn Pelker
Affiliation:
Nestlé Purina Research, One Checkerboard Square, 2RS, Saint Louis, MO63164, USA
Jeff Labuda
Affiliation:
Nestlé Purina Research, One Checkerboard Square, 2RS, Saint Louis, MO63164, USA
Peifang Zhang
Affiliation:
Nestlé Purina Research, One Checkerboard Square, 2RS, Saint Louis, MO63164, USA
Peichuan Sun
Affiliation:
Nestlé Purina Research, One Checkerboard Square, 2RS, Saint Louis, MO63164, USA
*
*Corresponding author: Dr E. Satyaraj, fax +1 314 982 5857, email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

While the need for colostrum in neonates is well established, the systemic effect of feeding bovine colostrum (BC) to adult humans is gaining increasing attention. However, no systematic studies evaluating the immunomodulatory effect of BC in dogs have been reported. The aim of the present study was to evaluate the immunomodulatory effect of dietary supplementation of BC in dogs. The study was conducted in two phases: pre-test (8 weeks) and test (40 weeks), with twenty-four dogs (mean age 2·5 years) randomised into two groups. In the ‘pre-test’ phase, both groups were fed a nutritionally complete diet. At the end of the ‘pre-test’ phase, all dogs received a canine distemper virus (CDV) vaccine, and dogs in the ‘test group’ were switched to a diet supplemented with 0·1 % spray-dried BC. Response to the CDV vaccine was evaluated by measuring vaccine-specific plasma IgG levels. Gut-associated lymphoid tissue response was assessed by measuring faecal IgA levels. Gut microbiota were evaluated by the temporal temperature gel electrophoresis methodology. Dogs fed the BC-supplemented diet demonstrated a significantly higher vaccine response and higher levels of faecal IgA when compared with the control group. Supplementing diets with BC also resulted in significantly increased gut microbiota diversity and stability in the test group. In conclusion, diets supplemented with BC significantly influence immune response in dogs.

Type
Full Papers
Copyright
Copyright © The Authors 2013 

Colostrum (early milk produced during the first few days after parturition) not only meets the unique nutritional needs of neonates, but also transfers passive immunity and promotes the growth and development of the gastrointestinal tract(Reference Kelly and Coutts1, Reference Uruakpa, Ismond and Akobundu2). While the need for colostrum in neonates is well established, the systemic effect of feeding BC orally to adult humans is gaining increasing attention(Reference Alexieva, Markova and Nikolova3). Bovine colostrum (BC) contains several bioactive components(Reference Vacher and Blum4), including growth factors such as insulin-like growth factor-1, insulin-like growth factor-2, transforming growth factor β and epidermal growth factor, antimicrobial compounds such as lactoferrin, and immunomodulatory compounds such as Ig, transferrin and cytokines. The presence of these closely homologous bioactive ingredients in BC has led to its use in the treatment and prevention of diseases in humans and animals(Reference Uruakpa, Ismond and Akobundu2, Reference Hagiwara, Kataoka and Yamanaka5). In several studies, BC has been shown to be effective in treating gastrointestinal disorders (for a review, see Playford et al. (Reference Playford, MacDonald and Johnson6)) as well as helping athletes in endurance and speed training(Reference Shing, Peake and Suzuki7, Reference Mero, Kahkonen and Nykanen8). In human trials, BC containing specific antibodies has also been shown to be effective against enteropathogenic and enterotoxigenic Escherichia coli (Reference Mietens, Keinhorst and Hilpert9, Reference Tacket, Losonsky and Link10), Cryptosporidium (Reference Tzipori, Binion and Bostwick11), Helicobacter pylori (Reference Mehra, Marnila and Korhonen12), rotavirus(Reference Brussow, Hilpert and Walther13Reference Hilpert, Brussow and Meitens15) and Shigella flexneri (Reference Tacket, Binion and Bostwick16). However, no studies evaluating the immunomodulatory benefits of BC in dogs have been reported. The aim of the present study was to evaluate the immunomodulatory effect of BC in dogs.

Materials and methods

Animals and diets

A total of twenty-four adult dogs (Husky crosses, 2–7 years, mean 2·5 years) were randomised into two groups balanced for sex, age and faecal IgA (which was used as a marker to evaluate immune status) and were fed one of two rations during the test phase of the trial. Dogs consumed fresh water ad libitum and were housed and fed individually. Dogs were exercised 3 d a week during the 40-week study, using a standard exercise protocol as part of their normal routine. Each exercise session involved sprint-racing as part of a team, in which dogs in harness pulled an unladen sledge for distances starting at 3 miles and gradually increasing to 14 miles per session. The trial protocol was conducted in strict accordance with the guidelines established by the Nestlé Purina Pet Care (NPPC) Advisory Committee.

The trial was conducted in two phases: ‘pre-test’ (8 weeks) and ‘test’ (40 weeks). During the ‘pre-test’ phase, both groups were fed a commercial, nutritionally complete and balanced extruded dry dog food ‘control diet’ (Nestlé Purina product: approximately 29 % protein, 36 % carbohydrate, 19 % fat and 1·4 % fibre; metabolisable energy 16 292·4 kJ/kg (3894 kcal/kg)). At the end of the ‘pre-test’ phase, all dogs received a canine distemper virus (CDV) booster vaccine (Intervet Pro Progard-5 Vaccine, Canine Distemper–Adenovirus Type 2–Parainfluenza–Parvovirus Vaccine) as part of normal veterinary care. Dogs in the control group continued to be fed the ‘control diet’, while dogs in the test group were fed the ‘control diet’ supplemented with 0·1 % commercially obtained spray-dried BC (Sterling Technology, Inc.). Dogs were fed their respective diets until the end of the study. Food intake was measured daily. At the conclusion of the trial, dogs were switched to a maintenance diet.

Every 4 weeks, 5 ml of jugular blood samples were collected (using BD Vacutainer™ with sodium citrate as the anticoagulant; Becton & Dickenson). To obtain plasma, blood samples were centrifuged at 10 000 rpm for 10 min at 6°C, and plasma was stored at − 80°C until assayed for immune markers. Faecal samples were processed every 4 weeks and immediately stored in a − 80°C freezer. Faecal scores were recorded daily during the trial using a seven-point scale with a score of 1 representing firm, hard faeces and a score of 7 representing liquid diarrhoea. On this scale, scores of 2 or 3 are ideal (Table S1, available online). Body weights of the dogs were recorded weekly.

Measurement of antibodies in plasma

Response to the CDV vaccine was evaluated by measuring CDV vaccine-specific IgG levels using a calibrated ELISA. Briefly, a ninety-six-well plate was coated overnight at 4°C with CDV antigen (VMRD, Inc.) in borate buffer (pH 7). Free binding sites were blocked with PBS containing 5 % fetal calf serum and 0·1 % Tween (ELISA buffer) for 2 h at 37°C. Plasma samples were placed in the wells and incubated for 2 h at 37°C, followed by several washes with PBS–0·1 % Tween. Horseradish peroxidase-conjugated rabbit anti-canine IgG (Bethyl Laboratories, Inc.) diluted in ELISA buffer was applied to the plate, and the plate was incubated for 1 h at 37°C and then washed with PBS–0·1 % Tween. Finally, colour development was done with 50 μl of the 3,3′,5,5′-tetramethylbenzidine (TMB) peroxidase substrate system (KPL, Inc.) according to the manufacturer's instructions. The reaction was stopped with 50 μl of 1 m-H2SO4. Colour development was read at 450 nm, and results are expressed as μg/ml using a canine IgG standard.

Measurement of antibodies in the faecal samples

The effect of the test diet on the gut-associated lymphoid tissue (GALT) was assessed by evaluating secretory IgA levels in the faecal samples. Using 1·5 ml of the extraction buffer (50 mm-EDTA and 100 mg/l soybean trypsin inhibitor in PBS/1 % bovine serum albumin from Sigma), 0·5 g of faeces were vortexed. Phenylmethanesulphonyl fluoride (50 μl, 350 mg/l from Sigma) was added to each tube, and the samples were centrifuged at 10 000 g for 20 min. The supernatants were collected and frozen at − 80°C until assayed for IgA by ELISA as follows: a ninety-six-well plate was coated overnight at 4°C with a 1:100 dilution of mouse anti-canine IgA (Serotec) in 50 μl of borate buffer (6·2 g H3BO3/l, 9·54 g Na2B4O7.10H2O/l and 4·4 g NaCl/l, pH 7) and then washed with PBS–Tween-20. Free binding sites were blocked with 100 μl of PBS containing 5 % fetal calf serum and 0·1 % Tween-20 (ELISA buffer) for 1 h at 37°C. Duplicate faecal extracts were incubated with ELISA buffer (final volume 50 μl) for 2 h at 37°C and then washed with PBS–Tween-20. The plate was incubated with a 1:10 000 dilution of polyclonal goat anti-canine IgA conjugated with horseradish peroxidase (Serotec) in ELISA buffer (final volume 50 μl) for 1 h at 37°C, washed with PBS–Tween-20 and developed with 50 μl of the TMB peroxidase substrate system (KPL, Inc.) according to the manufacturer's instructions. The reaction was stopped with 50 μl of 1 m-phosphoric acid. Colour development was read at 450 nm, and results are expressed as μg/ml using a canine IgA standard.

Measurement of C-reactive protein

C-reactive protein (CRP) was measured as a general marker of inflammation to confirm that immune enhancement was not a result of or did not lead to a generalised inflammatory condition. Plasma CRP levels were measured in all dogs towards the end of the trial using a canine CRP kit (BD Canine CRP ELISA Kit; BD Bioscience) according to the manufacturer's directions.

Measurement of the effect of exercise on gut microbiota

During week 38, following a 2 d rest period, all dogs participated in a standard exercise protocol. In this event, dogs sprint-raced 10 miles in harness as part of a team pulling an unladen sledge. Each team contained roughly equal numbers of test and control dogs. The time to perform the task averaged 33 min and 30 s; there was less than a 30 s difference between the slowest team and the fastest team. The effect of BC on gut microbiota and its stability in response to exercise were evaluated by profiling changes in the gut microbiota. Rectal swabs were collected from the dogs 24 h before (‘pre’ sample) and 24 h after exercise protocol for temporal temperature gel electrophoresis (TTGE) (see below) assays. TTGE assays evaluate microbial profiles that consist of amplification products of the bacterial 16S rRNA gene, which are separated on the basis of sequence differences and yield a pattern of bands (gut microbiota profile). Each band, in theory, consists of one distinct 16S rRNA gene sequence and represents a major bacterial species of the gut microbiota (or very closely related species). ‘Pre’ samples collected before exercise were used to characterise baseline species diversity and ‘evenness’ (see below)(Reference Romeo, Jimenez-Pavon and Cervantes-Borunda17, Reference Shing, Peake and Ahern18). The effect of exercise on gut microbiota was evaluated by assessing the per cent similarity of ‘pre’- and ‘post’-exercise TTGE profiles. Similarity scores (see below) of the test groups were compared with those of the control group.

Temporal temperature gel electrophoresis

DNA extraction and purification for temporal temperature gel electrophoresis

Genomic DNA from the rectal swabs was obtained using a modified extraction method described by Tsai & Olson(Reference Tsai and Olson19). Rectal swabs were collected, and 0·5 g of faecal sample were suspended in 1·5 ml of PBS (0·85 % NaCl and 120 mm-NaH2PO4, pH 8·0), and after three freeze–thaw cycles, 1·5 μl of Proteinase K (Fisher) were added to each sample (final concentration 50 μg/ml) and incubated in a 37°C shaking water bath for 30 min with constant agitation. DNA was precipitated by adding 400 μl of ice-cold isopropanol (Sigma) containing 96 μl of 10·5 m-ammonium acetate (1·125–1·26 m final concentration) to 400 μl of the supernatant.

Temporal temperature gel electrophoresis

TTGE was performed using a Bio-Rad D-Code system™. PCR fragments were separated on a 10 % polyacrylamide denaturing gel (7 m-urea). Running buffer was 1·25 ×  TAE buffer (50 mm-Tris acetate, pH 7·4, 25 mm-sodium acetate and 1·25 mm-Na2EDTA). Separation was accomplished using a temperature gradient ramping from 59 to 69°C at a rate of 0·6°C/h. Electrophoresis was performed at 50 V and lasted for 16 h 20 min. Bacterial standard ladders were constructed by individually PCR amplifying DNA extracted from predominant intestinal strains and combining the PCR products. Primers used for the construction of the ladders were labelled with 6-carboxyfluorescein. The ladders were loaded together with the sample in each lane and were used to map the gel contours and correct for differences in the length of migration within and among the gels. Gel images were captured using a Hitachi Fluorometer and digitised using the FMBIOII (version 1.1) software (Hitachi). Digitised images were analysed using the GelCompar II (version 3.0) gel analysis software (Applied Maths). Band classes were established, and band densities (on height and band surface) within each class were tabulated.

Species diversity

Molecular profiles of baseline samples (collected 24 h before exercise) were used to estimate the species diversity of gut microbiota. The Shannon–Wiener index of species diversity was used for examining overall community characteristics(Reference Deplancke, Hristova and Oakley20, Reference McCracken, Simpson and Mackie21). The Shannon–Wiener index starts at ‘0’ representing a single species and keeps increasing with a higher number representing a greater diversity.

Statistical analysis

Repeated-measures ANOVA was used to test for overall differences between the groups on all measures. Dunnett's test was used to adjust for multiple comparisons with the control group. Data are presented as means with their standard errors. For all tests, the level of significant difference was set at P <0·05.

Results

General physiological status

At the start of the trial, average body weights of dogs in the test group and the control group were 20·3 (sem 0·7) and 20·7 (sem 0·9) kg, respectively. Food intake (data not shown) and body weights did not differ between the two groups during the trial. No significant differences in faecal scores were observed between the control group and the test group (data not shown). Diets did not have an impact on blood cell counts and blood chemistry (data not shown). Levels of CRP, a marker of inflammation, measured towards the end of the trial were well within the normal range (0·8–16·4 μg/ml)(Reference Otabe, Ito and Sugimoto22) in both the groups (4·42 (sem 1·09) μg/ml in the test group; 3·69 (sem 1·81) μg/ml in the control group, P= 0·74).

Immune response in the gut

IgA was extracted from the faecal samples and assayed using a modified ELISA, and its concentration is expressed as μg/ml. As can be seen in Fig. 1, dogs fed the BC-supplemented diet had higher faecal IgA levels when compared with those fed the control diet (P< 0·05).

Fig. 1 Total IgA levels in the faecal samples collected at weeks 0 and 40 from dogs fed diets with or without bovine colostrum. Values are means, with their standard errors represented by vertical bars (n 12). * Mean values were significantly different from that of the control group (P< 0·05). , Control; □, colostrum.

Response to canine distemper virus vaccine

All dogs were administered a CDV booster vaccine at week ‘0’ before the ‘test’ phase of the trial. Blood samples were analysed every 8 weeks for CDV vaccine-specific IgG levels and data were normalised by dividing each value by the baseline value obtained at the start of the ‘test’ phase to eliminate dog-to-dog variation. As can be seen in Fig. 2, CDV antibody concentration gradually rose following the administration of the booster vaccine and reached a peak in 8 weeks in both the groups (indicating a response to the vaccination). In the control group, it declined to baseline values 16 weeks after the administration of the booster vaccine. However, in dogs fed the diet supplemented with BC, CDV antibody levels did not decline, but remained high until the end of the trial. Dogs fed the diet supplemented with colostrum exhibited a significantly higher vaccine response when compared with the control group (P< 0·5).

Fig. 2 Fold change over baseline in specific anti-canine distemper virus (CDV) IgG levels in plasma samples collected at weeks 0, 8, 16, 24 and 32 from dogs fed diets with or without bovine colostrum. Values are means, with their standard errors represented by vertical bars (n 12). * Mean values were significantly different from those of the control group (P< 0·05). , Control; , colostrum.

Species diversity

Molecular profiles of baseline samples (collected 24 h before exercise) were used to estimate the species diversity of gut microbiota. Dogs fed the BC-supplemented diet (3·01 (sem 0·11), P< 0·05) showed higher Shannon–Wiener index values (i.e. a greater species diversity in their gut microbiota) when compared with those fed the control diet (2·64 (sem 0·12)).

Effect of bovine colostrum on gut microbiota

When the ‘pre’-exercise microbiota pattern was compared with the ‘post’-exercise microbiota pattern, dogs fed the diet supplemented with BC had increased gut microbiota stability (82 (sem 13·1) % similarity v. 46 (sem 5·2) % similarity in the control group, P< 0·05).

Discussion

The present study shows for the first time that feeding a complete and balanced diet supplemented with BC enhances immune response as well as increases gut microbiota diversity and stability in dogs. No detectable side effects were observed in the dogs, as the BC-supplemented diet did not have an impact on food intake, body weight and blood composition including CRP, a marker of inflammation. A previous publication by Giffard et al. (Reference Giffard, Seino and Markwell23) has reported gut health benefits of BC, showing that puppies fed diets supplemented with BC demonstrated improved faecal scores when placed in a new environment that favoured stress-related diarrhoea. However, no immune benefits or other gut health benefits were documented in their study.

To study the effect of colostrum supplementation on the GALT, we measured IgA levels in the faecal samples. IgA, a key protein produced by the GALT, has an important protective role in the gut, helping to prevent microbial adherence and colonisation, blocking viral adhesion and neutralising toxins(Reference Kraehenbuhl and Neutra24Reference McGhee, Mestecky and Dertzbaugh26), and is hence used to show enhanced GALT activity. While at the outset both the groups exhibited similar levels of faecal IgA, at 40 weeks, dogs fed the diet supplemented with BC had significantly higher faecal IgA levels (P< 0·05; Fig. 1). These data show that BC supplementation enhanced GALT function, resulting in higher IgA production, suggesting that these dogs would experience a higher level of protection from gut pathogens.

Dogs included in the study were routinely vaccinated with CDV vaccine as part of their normal veterinary care. We, therefore, decided to measure the effect of feeding diets supplemented with BC on the systemic immune status, using CDV vaccine response as a marker. All dogs were administered a CDV booster vaccination immediately before the ‘test phase’ of the trial, and their response to the CDV vaccine was measured every 2 months during the trial and normalised to their baseline levels to eliminate dog-to-dog variability. There was a statistically significant increase (P< 0·05; Fig. 2) in specific anti-CDV IgG levels in dogs fed the diet supplemented with BC. These results suggest that the diet supplemented with BC increased priming of B-cell response to CDV vaccination. This enhanced response to CDV vaccine may enhance the effectiveness of the vaccine in preventing CDV infections. It has been shown previously that CDV-specific antibodies are very effective in neutralising extracellular CDV and preventing the intercellular spread of the virus in vitro (Reference Ho and Babiuk27). Vaccine responses demonstrate clinically relevant alterations in an immune response to a challenge under well-controlled conditions and therefore are often used as a surrogate for responses to an infectious challenge. In human studies, for example, individuals who respond poorly to vaccines have greater susceptibility to infectious agents when compared with those with better vaccine responses(Reference Burns, Lum and Seigneuret28, Reference Patriarca29). These data suggest that dogs fed a diet supplemented with BC are likely to respond better to vaccines that are administered as part of routine veterinary care and will, therefore, be more effective in protecting themselves from naturally occurring infectious agents.

In addition to the immune measures, plasma samples were assayed for CRP. CRP is an acute-phase protein that is produced by the liver in response to inflammation(Reference Marnell, Mold and Du Clos30). CRP is normally measured during routine clinical examination to rule out any ongoing inflammation in the subject, in both human and veterinary medicine(Reference Golbasi, Ucar and Keles31). Normal levels of plasma CRP in dogs are between 0·8 and 16·4 μg/ml(Reference Otabe, Ito and Sugimoto22, Reference Otabe, Sugimoto and Jinbo32). Dogs suffering with inflammatory conditions tend to have much higher levels. For example, in a published study, it has been observed that dogs with pancreatitis had CRP levels of 56·4 μg/ml(Reference Nakamura, Takahashi and Ohno33). Clearly, all dogs in the study had CRP levels well within the normal range, showing that BC did not negatively influence the immune system.

In addition to the immune measures, we also evaluated the effect of BC on gut microbiota. While enhanced mucosal and systemic immunity is likely to promote healthy gut microbiota, natural antibodies and other bioactives in the colostrum have been shown to help balance beneficial and potentially harmful intestinal bacteria(Reference Kraehenbuhl and Neutra24). We characterised the gut microbiota using the Shanon–Wiener index. The Shannon–Wiener index is a widely used species diversity index for examining overall community characteristics(Reference Deplancke, Hristova and Oakley20, Reference McCracken, Simpson and Mackie21). Species diversity is an expression of the number and variety of species found in a given microbial community. A community has a high species diversity if many equally or nearly equally abundant species are present. Species diversity is used as a measure of community stability in which a low or changing species diversity may indicate a stressed or unstable environment(Reference Mai, Braden and Heckendorf34). Establishment of mucosal and/or luminal colonisation is the first step in the pathogenesis of many gastrointestinal bacterial pathogens. The pathogen must be able to establish itself in the face of competition from the complex microbial community that is already in place. A greater level of species diversity reduces the opportunity for potential pathogens to colonise the gut(Reference Kuehl, Wood and Marsh35). The Shannon–Wiener index starts at ‘0’ representing a single species and keeps increasing with a higher number representing a greater diversity. Dogs fed the BC-supplemented diet showed higher Shannon–Wiener index values when compared with those fed the control diet, showing that the BC-supplemented diet encouraged greater gut microbiota species diversity. This suggests that dogs fed diets supplemented with BC would potentially be able to better resist infections or colonisation by gut pathogens.

Stress, both physical and mental, has a significant negative impact on the immune system, irrespective of age(Reference Satyaraj36). The health of the immune system can be evaluated by how subjects respond to exercise(Reference Romeo, Jimenez-Pavon and Cervantes-Borunda17, Reference Shing, Peake and Ahern18) and can be helpful in assessing how they would respond to stress. The immune system plays an important role in the maintenance of a healthy gut microbiota balance(Reference Das37). Exercise can temporarily lower immune status, and this is often reflected in changes in the gut microbiota. A subject with a healthy immune system is able to prevent this drift in the gut microbiota, and this can be used as an indirect measure of the health of the immune system. At 38 weeks, all dogs participated in an exercise protocol involving a 2 d rest period followed by a 10-mile sledge run. The effect of BC on gut microbiota diversity and stability during exercise was evaluated by TTGE profile changes in the gut microbiota. The effect of exercise on gut microbiota was measured by assessing the per cent similarity of the ‘pre’- and ‘post’-exercise TTGE profiles. Similarity scores of the test groups were then compared with those of the control group. Dogs fed the diet supplemented with BC exhibited much greater similarity between the ‘pre’- and ‘post’-exercise microbial patterns when compared with those fed the control diet (P< 0·05). Dogs fed the BC-supplemented diet handled the ‘exercise challenge’ significantly better than the non-supplemented dogs as reflected in their ability to prevent changes in microbiota after exercise. Clearly, supplementing diets with BC enabled this group of dogs to handle ‘exercise challenge’ better when compared with the control group.

In conclusion, the results reported in the present study show that diets supplemented with BC influence immune response in dogs at both the mucosal and systemic levels and enhance gut microbiota diversity and stability. These findings could be relevant for improving protective immune and gut responses to various stress factors including infections.

Supplementary material

To view supplementary material for this article, please visit http://dx.doi.org/10.1017/S000711451300175X

Acknowledgements

The present study was entirely funded by Nestlé Purina Research. The authors acknowledge Amy Dunlap and Yvonne Leavitt in supporting the feeding study, Julie Spears for helping analysing the microbiota data and Wendell Kerr for the statistical analysis. E. S. and A. R. designed the study, interpreted the results and prepared the manuscript. P. Z. helped with the initial study design. R. P., J. L. and P. S. carried out the assays described in the study. E. S. and A. R. had primary responsibility for the final content. All authors read and approved the final manuscript. None of the authors has any conflicts of interest associated with the present study.

References

1Kelly, D & Coutts, AGP (2000) Early nutrition and the development of immune function in the neonate. Proc Nutr Soc 59, 177185.Google Scholar
2Uruakpa, FO, Ismond, MAH & Akobundu, ENT (2002) Colostrum and its benefits: a review. Nutr Res 22, 755767.Google Scholar
3Alexieva, B, Markova, T & Nikolova, E (2004) Bovine colostrum – the promising nutraceutical. Czech J Food Sci 22, 7379.Google Scholar
4Vacher, PY & Blum, JW (1993) Age dependency of insulin like growth factor 1, insulin protein and immunoglobulin concentrations and gamma glutamyl transferase activity in first colostrum of dairy cows. Milchwissenschaft 48, 423425.Google Scholar
5Hagiwara, K, Kataoka, S, Yamanaka, H, et al. (2000) Detection of cytokines in bovine colostrum. Vet Immunol Immunopathol 76, 183190.Google Scholar
6Playford, RJ, MacDonald, CE & Johnson, WS (2000) Colostrum and milk-derived peptide growth factors for the treatment of gastrointestinal disorders. Am J Clin Nutr 72, 514.CrossRefGoogle ScholarPubMed
7Shing, CM, Peake, J, Suzuki, K, et al. (2007) Effects of bovine colostrum supplementation on immune variables in highly trained cyclists. J Appl Physiol 102, 11131122.CrossRefGoogle ScholarPubMed
8Mero, A, Kahkonen, J, Nykanen, T, et al. (2002) IGF-I, IgA, and IgG responses to bovine colostrum supplementation during training. J Appl Physiol 93, 732739.Google Scholar
9Mietens, C, Keinhorst, H, Hilpert, H, et al. (1979) Treatment of infantile E. coli gastroenteritis with specific bovine anti-E. coli milk immunoglobulins. Eur J Ped 132, 239252.Google Scholar
10Tacket, CO, Losonsky, G, Link, H, et al. (1988) Protection by milk immunoglobulin concentrate against oral challenge with enterogenic Escherichia coli. Eng J Med 12401241.CrossRefGoogle Scholar
11Tzipori, CO, Binion, SB, Bostwick, E, et al. (1986) Remission of diarrhea due to cryptosporidiosis in an immunodeficient child treated with hyperimmune bovine colostrum. Br Med J 293, 12761277.Google Scholar
12Mehra, R, Marnila, P & Korhonen, H (2006) Milk immunoglobulins for health promotion. Int Dairy J 16, 12621271.Google Scholar
13Brussow, H, Hilpert, H, Walther, J, et al. (1987) Bovine milk immunoglobulins for passive immunity to infantile rotavirus gastroenteritus. J Clin Microbiol 25, 982986.Google Scholar
14Ebina, T, Sato, A, Umezu, K, et al. (1985) Prevention of rotavirus infection by oral administration of cow colostrum containing antihuman rotavirus antibody. Med Microbiol Immunol 174, 177185.Google Scholar
15Hilpert, H, Brussow, H, Meitens, C, et al. (1987) Use of bovine milk concentrate containing antibody to rotavirus to treat rotavirus gastroenteritis in infants. J Infect Dis 156, 158166.CrossRefGoogle ScholarPubMed
16Tacket, CO, Binion, SB, Bostwick, E, et al. (1992) Efficacy of bovine milk immunoglobulin concentrate in preventing illness after Shigella flexneri challenge. Am J Trop Med Hyg 47, 276283.Google Scholar
17Romeo, J, Jimenez-Pavon, D, Cervantes-Borunda, M, et al. (2008) Immunological changes after a single bout of moderate-intensity exercise in a hot environment. J Physiol Biochem 64, 197204.Google Scholar
18Shing, CM, Peake, JM, Ahern, SM, et al. (2007) The effect of consecutive days of exercise on markers of oxidative stress. Appl Physiol Nutr Metab 32, 677685.CrossRefGoogle ScholarPubMed
19Tsai, YL & Olson, BH (1992) Rapid method for separation of bacterial DNA from humic substances in sediments for polymerase chain reaction. Appl Environ Microbiol 58, 22922295.Google Scholar
20Deplancke, B, Hristova, KR, Oakley, HA, et al. (2000) Molecular ecological analysis of the succession and diversity of sulfate-reducing bacteria in the mouse gastrointestinal tract. Appl Environ Microbiol 66, 21662174.Google Scholar
21McCracken, VJ, Simpson, JM, Mackie, RI, et al. (2001) Molecular ecological analysis of dietary and antibiotic-induced alterations of the mouse intestinal microbiota. J Nutr 131, 18621870.Google Scholar
22Otabe, K, Ito, T, Sugimoto, T, et al. (2000) C-reactive protein (CRP) measurement in canine serum following experimentally-induced acute gastric mucosal injury. Lab Anim 34, 434438.Google Scholar
23Giffard, CJ, Seino, MM, Markwell, PJ, et al. (2004) Benefits of bovine colostrum on fecal quality in recently weaned puppies. J Nutr 134, 2126S2127S.CrossRefGoogle ScholarPubMed
24Kraehenbuhl, JP & Neutra, MR (1992) Molecular and cellular basis of immune protection of mucosal surfaces. Physiol Rev 72, 853879.CrossRefGoogle ScholarPubMed
25Holmgren, J, Czerkinsky, C, Lycke, N, et al. (1992) Mucosal immunity: implications for vaccine development. Immunobiology 184, 157179.Google Scholar
26McGhee, JR, Mestecky, J, Dertzbaugh, MT, et al. (1992) The mucosal immune system: from fundamental concepts to vaccine development. Vaccine 10, 7588.CrossRefGoogle ScholarPubMed
27Ho, CK & Babiuk, LA (1979) Immune mechanisms against canine distemper. II. Role of antibody in antigen modulation and prevention of intercellular and extracellular spread of canine distemper virus. Immunology 38, 765772.Google Scholar
28Burns, EA, Lum, LG, Seigneuret, MC, et al. (1990) Decreased specific antibody synthesis in old adults: decreased potency of antigen-specific B cells with aging. Mech Ageing Dev 53, 229241.CrossRefGoogle ScholarPubMed
29Patriarca, PA (1994) A randomized controlled trial of influenza vaccine in the elderly. Scientific scrutiny and ethical responsibility. JAMA 272, 17001701.Google Scholar
30Marnell, L, Mold, C & Du Clos, TW (2005) C-reactive protein: ligands, receptors and role in inflammation. Clin Immunol 117, 104111.Google Scholar
31Golbasi, Z, Ucar, O, Keles, T, et al. (2002) Increased levels of high sensitive C-reactive protein in patients with chronic rheumatic valve disease: evidence of ongoing inflammation. Eur J Heart Fail 4, 593595.Google Scholar
32Otabe, K, Sugimoto, T, Jinbo, T, et al. (1998) Physiological levels of C-reactive protein in normal canine sera. Vet Res Commun 22, 7785.CrossRefGoogle ScholarPubMed
33Nakamura, M, Takahashi, M, Ohno, K, et al. (2008) C-reactive protein concentration in dogs with various diseases. J Vet Med Sci 70, 127131.CrossRefGoogle ScholarPubMed
34Mai, V, Braden, CR, Heckendorf, J, et al. (2006) Monitoring of stool microbiota in subjects with diarrhea indicates distortions in composition. J Clin Microbiol 44, 45504552.Google Scholar
35Kuehl, CJ, Wood, HD, Marsh, TL, et al. (2005) Colonization of the cecal mucosa by Helicobacter hepaticus impacts the diversity of the indigenous microbiota. Infect Immun 73, 69526961.Google Scholar
36Satyaraj, E (2011) Emerging paradigms in immunonutrition. Top Companion Anim Med 26, 2532.Google Scholar
37Das, UN (2010) Obesity: genes, brain, gut, and environment. Nutrition 26, 459473.Google Scholar
Figure 0

Fig. 1 Total IgA levels in the faecal samples collected at weeks 0 and 40 from dogs fed diets with or without bovine colostrum. Values are means, with their standard errors represented by vertical bars (n 12). * Mean values were significantly different from that of the control group (P< 0·05). , Control; □, colostrum.

Figure 1

Fig. 2 Fold change over baseline in specific anti-canine distemper virus (CDV) IgG levels in plasma samples collected at weeks 0, 8, 16, 24 and 32 from dogs fed diets with or without bovine colostrum. Values are means, with their standard errors represented by vertical bars (n 12). * Mean values were significantly different from those of the control group (P< 0·05). , Control; , colostrum.

Supplementary material: File

Satyaraj Supplementary Material

Appendix

Download Satyaraj Supplementary Material(File)
File 21.5 KB