Effects of Probiotic and Prebiotic on Average Daily Gain, Fecal Shedding of Escherichia Coli, and Immune System Status in Newborn Female Calves

Article information

Asian-Australas J Anim Sci. 2012;25(9):1255-1261
*Corresponding Author: Pezhman Mohamadi Roodposhti. Tel: +982616601487, Fax: +982616601487, E-mail: pezhman_mrp@yahoo.com
Department of Animal Science, Karaj Branch, Islamic Azad University, Karaj, Iran
Received 2011 August 29; Accepted 2011 October 19; Revised 2012 January 24.


Thirty two Holstein female calves (initial body weight = 40±3.0 kg) were used to investigate the effects of probiotic and prebiotic on average daily gain (ADG), fecal E. coli count, white blood cell count, plasma IgG1 level and cell-mediated immune response to injection of phytohemagglutinin in suckling female calves. Calves were assigned randomly to one of the four treatments, including whole milk without additives (control), whole milk containing probiotic, whole milk containing prebiotic and whole milk containing probiotic and prebiotic (synbiotic). Average daily gain was greater in calves fed probiotic, prebiotic and synbiotic at weeks 6, 7 and 8 (p<0.05). E. coli count was significantly lower in calves fed probiotic, prebiotic and synbiotic on d 56 (p<0.05). There was no significant difference between treatments in blood samples and cell-mediated response. This study showed that addition of probiotic, prebiotic and combination of these additives to milk enhanced ADG and reduced fecal E. coli count in preruminant calves.


Before weaning, dairy calves are susceptible to many pathogens and nutritional problems. For several years antibiotics have been used to overcome these problems also to obtain economic benefits in terms of improved calves performance and reduced medication costs. However, the use of antibiotics in animal husbandry is in question because of antibiotic resistance of microorganisms. Research shows an association between the use of sub-therapeutic dose of antibiotics and antibiotic-resistance organisms (Amabile-Cuevas, 1995; Fevier et al., 1955; Piddock, 1996). In an effort to replace antibiotics from animal feeds, many additives have been proposed. Probiotic, prebiotics and combination of probiotic and prebiotic (synbiotics) are examples of these additives (Heinrich et al., 2003; Morill et al., 1995). Probiotics are live microbial feed supplements which beneficially affect the host animal by improving its microbial balance (Fuller, 1989). Probiotics have been shown to have many function, including protecting young animal against enteropathic disorders (Windschitle et al., 1991; Timmerman et al., 2005), increasing feed efficiency and weight gain (Cruywagen et al., 1995; Lesmiester et al., 2004) and improve immune system (Yoon et al., 1995; Timmerman et al., 2005). Although the mechanisms of action of probiotics have not been identified clearly, lactic acid bacteria are thought to inhibit the growth of pathenogenic bacteria through decreasing pH in large intestine by production of lactic acid and through competitive attachment (Riddell et al., 2010). Most of probiotic studies that were reported in the literatures used single or two strains probitics rather that multi strains bacteria, but Rolfe (2000) suggested that multi-strain probiotic may be more useful than a single strain because they can proliferate more lactic acid bacteria than single strain probiotic.

Prebiotics are non-digestible carbohydrates which are not metabolized in the small intestine and fermented in large intestine. Mannanoligosaccharides and β-glucan are prebiotics which derived from saccharomyeces cereviciae cell wall and are able to block fimbriae of patheno genic bacteria, and thus prevent their adhesion to the mucous epithelium (Kogan and Kocher, 2007). The administration of prebiotic to calves can decrease coliform population of large intestine and colon of calves and pigs (Miguel et al., 2004). More recently, prebiotics have been shown to have immune-enhancing characteristics (Okomato et al., 2003; Fleige et al., 2009). Tang et al. (2005), showed that oligosacchrides such as chitosan and galacto-manannan-oligosaccharides may improve growth and feed efficiency by increasing growth hormone and insulin-like growth factor-I levels, in the early-weaned piglets. Huang et al. (2005), reported that dietary chitosan oligosaccharides supplementation was effective in increasing the ileal digestibilities of nutrients and feed efficiency in broilers. Huang et al. (2007), also reported that broilers fed diet supplemented with oligochitosan prebiotic had higher serum IgG, IgM and IgA concentration compared with broiler fed control diet. Dietary supplementation with Chinese herbal ultra-fine 3 powder as a prebiotic enhances cellular and humoral immunity in early weaned piglets (Deng et al., 2007). Kong et al. (2007), in an experiment used a Chinese herbal ultra-fine powder as a prebiotic supplementation for piglets. They reported that the powder increased ADG and feed efficiency, and reduced the incidence of diarrhea in the weaned piglets. Deng et al. (2007), reported that polysaccharides of cassiae seed can be used as a prebiotic to improve intestinal microflora. They showed that dietary inclusion of this prebiotic increased lactobacillus count, and reduced E. coli counts in digesta of ileum, cecum and colon of piglets.

The objective of the current experiment was to study the effects of feeding milk containing probiotic, prebiotic and probiotic+prebiotic (synbiotic) on average daily gain, fecal E. coli count and immune status of female suckling calves.


Animals, diets, and experimental design

Thirty two Holstein female calves (initial body weight = 40±3.0 kg) were grouped based on body weight. Calves were removed from their dams and housed individually in calf house with separated pens, each of which was equipped with feeding and watering trough as required for calves. All pens were located in the same calf house and the calves were randomly allocated. The calf house was equipped with controlled ventilation and the bedding in the pens was chopped straw. Manure was removed daily and chopped straw was given to all pens again. Temperature and air humidity were monitored. Average temperature was 15.5±2.0°C and relative humidity was 75.0±5.0%.

Calves fed 1/5 L of fresh colostrum by nipple bottle at birth, and again after 4 h, and every 12 h thereafter. Calves were fed colostrums for 3 d then switched to milk until the end of trail (8 week). Calves were assigned randomly at birth to one of four treatments. Treatments included: whole milk with no additives (control), whole milk containing probiotic at 1 g Protexin® (multi-strain probiotic contains 7 bacteria strains and 2 yeast strains with 2× 109 cfu/g) per day, whole milk containing prebiotic at 4 g Tipax® (polysaccharides of saccharomyces cereviciae cell wall) per day, whole milk containing 1 g probiotic and 4 g prebiotic (synbiotic) per day. Calves received whole milk twice daily at 0700 and 1600 h: calf starter and water were offered ad libitum throughout the trial of 60 days. Calf starter contained no growth promoters. The composition and the analyzed nutrient content of offered feeds are provided in Table 1. Starter intake was recorded daily throughout the trial. Body weight was measured at birth and thereafter at weekly interval up to 8 week of age.

The composition and the analyzed nutrient content in the diet fed to the calves

Sampling, measurement, and analyses

Fecal samples were collected weekly from rectum with sterile rubber gloves and place in sterile plastic tubes with led. The samples were stored in a freezer at −20°C until analysis for counts of E. coli. In vitro survival and enumeration of E. coli was determined according to the method of Gue et al. (2006).

Blood samples were collected from jugular veins on d 3, 30 and 60, approximately 3 h after the morning feeding and transported to the laboratory. Serum was separated from blood by centrifugation at 2,000×g for 10 min. Serum was frozen at −25°C till analyzed for WBC count, neutrophil, lymphocyte and monocyte concentration. Plasma samples were extracted and stored frozen for ELISA analysis of immunoglobulin G1. The ELISA analysis was described previously by Rivera et al. (2002).

Cell-mediated immune response was measured in vivo by phytohemagglutinin (PHA) skin test. On d 60, calves were injected by 150 μg of PHA in 0.1 ml of PBS. The injection site was immediately posterior to the scapula. The skinfold thickness was measured before injection and 2, 4, 6, 8, 12, 24 and 48 h after injection using micrometric clippers.

Statistical analysis

All statistical analyses were conducted by ANOVA using the general linear models procedures of SAS (SAS Institute, 2000). Data were analyzed as a randomized complete design with calf as the experimental unit and repeated measurements. Effect of time and interaction between treatment and time were included in the model as fixed effects when blood parameters were analyzed. Results were presented as least square means with SEM. There were no significant difference between average weight of calves by Duncan test (p>0.10) at the beginning of the study, therefore no longer correction of birth weight of calves have done. Treatment effects were considered significant at p≤0.05.


Calf starter intakes were recorded beginning at 2 week of age because calves did not consume starter during the first week of life. Comparison of weekly dry matter intake (DMI) illustrated that there was no significant difference among treatments till the end of trial (Table 1). In most experiments which studied effects of probiotics in calves, researchers focused on a single or two strain probiotics. Quigly et al. (1992) found no significant effect of yeast probiotic on intake of starter in dairy calves. Donovan et al. (2002) reported that intake of dry starter was similar between calves fed prebiotic or control. However, Rust et al. (2000) reported increased DMI in beef steers which received lactic acid based probiotic. Michael and Abney (2001) reported no significant difference in DMI between calves received probiotic and prebiotic and control group.

Data on weekly average daily gain (ADG) indicate that calves fed synbiotic and calves fed prebiotic had consistently higher ADG than probiotic and control treatments (Table 2). At week 7 and 8, ADG was significantly greater (p<0.05) for synbiotic, probiotic and prebiotic treatments than control treatment. Overall, it was observed that calves fed synbiotic (557 g/d) had greater ADG than other treatments (p<0.05) and there was no significant difference between probiotic (514 g/d) and prebiotic (530 g/d) and between probiotic and control (489 g/d) treatments. In large intestine probiotic will start to colonize and beneficial bacteria such as lactobacillus acidophilus and enterococcus faecium will multiply, exclude the harmful bacteria and establish themselves in the digestive system. Prebiotic in the colon and large intestine are readily fermented by these beneficial bacteria. This may result in changes in the population of beneficial microorganisms, while repressing the number of harmful bacteria. In addition, the production of VFA by bacteria fermenting prebiotics in animals may improve energy efficiency and alter intestinal morphology. These possible changes in the microbiology and chemistry of the large intestine may be responsible for improved ADG at ending weeks. It is also believed that probiotics and prebiotics can improve digestibilities of dry matter, energy, crude protein and amino acids (Li et al., 2008; Kong et al., 2008; Kong et al., 2011) and increase bioavailability of minerals in the gut. Moreover, probiotics produce water soluble vitamin B group which may improve nutrient metabolism in gut ADG in this trial were similar to those reported by Quigly et al. (1997). Lesmeister et al. (2004) reported improvement in ADG when 2% supplemental probiotic was added to a calf diet. Abe et al. (1995) administered Bifidiobacterium Pseudolongum or Lactobacillus Acidophilus in MR to neonatal from d 7 to d 35 of age. They reported that both probiotic improved body weight gain. In this experiment calves received a combination of probitic and prebiotic together had greater ADG than calves received probiotic or prebiotic alone, this may be due to more synergetic effects of synbiotic on stimulating beneficial microflora compared to supplementing probiotic and prebiotic alone.

Weekly dry matter intake (g/d) of calves fed with or without additives

Result of fecal E. coli count illustrated that calves received pro-prebiotic and synbiotic had significantly lower E. coli in feces on d 56 compared with the control treatment (Table 4). There are two proposed mechanisms by which probiotics may reduce harmful bacteria such as E. coli in intestinal tract and following in feces. Firstly, probiotics microorganisms produce some inhibitory substances such as organic acids, hydrogen peroxide and bacteriocins which these antimicrobial-like compounds might be active against some pathogens. Second mechanism is that of competitive inhabitation for harmful bacteria adhesion on intestinal epithelial surfaces. Elam et al. (2003) reported that lactobacillus acidophilus decreased fecal E. coli shedding in beef steers. Liu et al. (2008) in an experiment studied effects of prebiotic on fecal shedding of E. coli and lactobacillus in weaning pigs. They concluded that diet containing prebiotic decreased E. coli count and increase lactobacillus in the feces on d 21 compared with the control diet. Mannanoligosaccharides (MOS) prebiotic is thought to bind the lectins contained in the cell wall of certain pathogenic bacteria. This binding of the MOS to the pathogenic cell wall inactive the binding sites of the bacteria, thus they are flushed out of the GIT without causing pathogenic effects. However, Micheal and Abney (2001) observed no significant difference in fecal E. coli populations of calves received probiotic, prebiotic and control calves.

Number of Escherichia coli (log cfu/g of wet digesta) in calves fed with or without additives

Shim (2005) reported that population of E. coli in the colon of suckling pigs which received probiotic, prebiotic and synbiotic was significantly lower compared to the control.

Data on serum and plasma biochemistry indicated that there was no significant difference in white blood cell count, neutrophil, lymphocyte and monocyte concentration and plasma IgG1 concentration at any collection period (Table 5). No treatment×time interaction was noted for white blood cell count, neutrophil, lymphocyte and monocyte concentration. This could be due to good hygienic provided to the calves that these blood parameters which related to immune system was unaffected by treatments. Shim (2005) reported that haematological traits (WBC count, neutrophil, monocyte, lymphocyte and hemoglobin) were unaffected by prebiotic, multi-strain probiotic and synbiotic in weaned pigs. However, Heinrich et al. (2002) found that immune parameters such as lymphocytes, leukocyte and neutrophils tended to increase in supplementation of synbiotic (combining lactobacillus and fructooligosaccharides) compared to the single administration of lactobacillus and the control in weaned pigs. Plasma IgG1 concentartion changed over the time and there was no treatment×time interaction. Although plasma IgG1 concentration tended to be higher in synbiotic and prebiotic treatments but the differences was not significant. Plasma IgG1 concentration was greater in all calves on d 3 than d 30 and 60. Plasma IgG is highest after birth because of passive transfer of colostrum antibodies, then it reduced until animal is able to produce its own antibodies (Riddell et al., 2010). It was hypothesized that addition of pro- prebiotic and synbiotic to milk would stimulate an increase in IgG levels as an anti-spore immune response (Hong et al., 2005). However, Morill et al. (1995) showed that probiotic supplementation in calves had no effect on immunoglobulins. Riddell et al. (2010) also showed that probiotic had no significant effect on plasma IgG1 concentration of preruminant calves. Kelly, (2004) reported that mares receiving prebiotic supplementation had higher colostrums IgA and IgM than control group, but were no significant difference between treatments for mare IgG IgM and IgA plasma levels at any collection period. Franklin et al. (2005) reported numerically greater IgG and IgM concentration 24 h post calving in calves from cows supplemented with prebiotic, but the difference were not significant. Kaila et al. (1992) reported that the immune system of weaned pig was stimulated by probiotics supplementation. Deng et al. (2007) reported that dietary supplementation with polysaccharides from Semen cassiae increased: i) serum concentrations of interleukin (IL)-1, IL-2 and IL-6, as well as IgG IgM and IgA; ii) expression of the IL-1 and IL-2 genes in blood mononuclear cells and lymphatic nodes. They suggested that these polysaccharides enhanced both cell-mediated immune response and the humoral immunity in the early-weaned piglets. Yin et al (2008) showed that galacto-mananan-ologosaccharid and chitosan oligosaccharide enhanced IL-1 gene expression in jejunal mucosa as well as serum levels of IL-1, IL-2, IL-6, IgG IgM and IgA in piglets.

Blood parameters in calves fed with or without additives

There was no significant difference between treatments in increase of skinfold thickness to intradermal injection of phytohemagglutinin (Table 6).

Effect of probiotic, prebiotic and synbiotic on skinfold response to intradermal injection of PHA

The skin test provides a measure of the proliferative response potential of circulating T lymphocytes to an injected mitogen such as phytohemagglutinin (Smits et al., 1999). Apgar et al. (1993) reported that probiotic had no effect in cell-mediated immune response of pigs. The skin test conducted in the current study to determine whether pro- prebiotic and synbiotic could improve immune response even if no significant blood parameters response was observed. Panda et al. (2007) reported probiotic had an immunoregulatory effect on cell mediated immunity and humoral immune response in poultry. Emmanuel et al. (2007) reported that probiotic induced an inflammatory response in feedlot steers fed high-grain diets. Kong et al. (2009), observed an increase in cellular immunity in weanling rats supplemented with Chinese Yam polysaccharide In a same experiment done by the author of the current study, humoral immune response to ovalbumin injection was tended to increased in calves received synbiotic on d 56 compared to the control and calves received multi-strain probiotic and mannano-ligosaccharide prebiotic (Mohamadi and Dabiri, 2011).


Addition of pro- prebiotic and symbiotic to the whole milk of dairy female calves increased ADG and reduced fecal shedding of E. coli at the ending weeks but dry matter intake and blood parameters related to immune system and cell-mediated immune response were not affected. However, when a combination of probiotic and prebiotic added to the milk a better improvement in average daily gain and more decrease in fecal E. coli was observed. The effects of pro-prebiotic and synbiotic on the immune system of dairy calves seems merits further research.

Weekly average daily gain (g/d) of calves fed with or without additives


The authors gratefully acknowledge Behdaneh Pars Company for preparing calves and other facilities.


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Table 1

The composition and the analyzed nutrient content in the diet fed to the calves

Composition %
 Corn 35
 Barley 20
 Soybean meal 25
 Cotton seed meal 5
 Fish meal 1
 Bran 9.5
 Salt 0.5
 Mineral and vitamin premix 2
 Calcium carbonate 1
 Sodium bicarbonate 1
Analyzed content
 Dry matter (%) 87.5
 Crude fiber (g/kg) 46.5
 Crude protein (g/kg) 192
 Calcium (g/kg) 11.1
 phosphorus (g/kg) 12.1

Provided (pp/kg), iron 25.0; manganese, 100.0; cobalt 2.5; iodine, 0.0; selenium, 0.2; vitamin A, 20,000 IU/kg; vitamin D, 4,000 IU/kg; vitamin E, 120 UI/kg.

Table 2

Weekly dry matter intake (g/d) of calves fed with or without additives

Week Treatment
Pooled SE
Control Probiotic Prebiotic Synbiotic
2 51 74 40 75 24
3 188 168 174 202 46
4 530 573 519 604 51
5 677 635 615 696 24
6 746 684 711 774 31
7 1,142 1,068 1,017 1,125 48
8 1,408 1,385 1,375 1,432 35

Table 3

Weekly average daily gain (g/d) of calves fed with or without additives

Week Treatment
Pooled SE
Control Probiotic Prebiotic Synbiotic
1 22 63 55 67 13
2 59 101 115 128 29
3 200 284 252 295 22
4 507 596 612 635 35
5 643 677 689 711 44
6 995 1,018 1,037 1,125 43
7 1,024b 1,185a 1,190a 1,212a 25
8 974b 1,149a 1,188a 1,269a 38

Value with different Superscripts within a row differ significantly (p<0.05).

Table 4

Number of Escherichia coli (log cfu/g of wet digesta) in calves fed with or without additives

Day Treatment
Pooled SE
Control Probiotic Prebiotic Synbiotic
7 7.58 7.44 7.87 7.61 0.44
14 7.49 7.55 7.69 7.58 0.21
21 7.53 7.59 7.71 7.54 0.12
28 7.66 7.31 7.55 7.39 0.24
35 7.44 7.55 7.38 7.41 0.11
42 7.53 7.61 7.31 7.29 0.15
49 7.65 7.52 7.38 7.26 0.33
56 7.58a 7.44b 7.11b 7.04b 0.38

Value with different Superscripts within a row differ significantly (p<0.05).

Table 5

Blood parameters in calves fed with or without additives

Collection day Blood parameters Treatment
Pooled SE
Control Probiotic Prebiotic Symbiotic
3 White blood cell (number/μl) 10,200 10,280 10,310 1,0340 188
Neutrophil % 37 32 36 36 6
Lymphocyte % 62 4 63 64 3
Monocyte % 0 0 0 0 1
Immunoglobulin G (mg/dl) 1,220 1,148 1,285 1,347 259
30 White blood cell (number/μl) 6,100 6,750 6,500 6,720 98
Neutrophil % 31 26 24 27 3
Lymphocyte % 74 73 74 72 4
Monocyte % 1 0 1 0 2
Immunoglobulin G (mg/dl) 912 825 995 1,065 118
60 White blood cell (number/μl) 8,840 8,920 9,010 8,760 122
Neutrophil % 23 24 28 26 4
Lymphocyte % 76 75 71 71 6
Monocyte % 0 0 0 0 1
Immunoglobulin G (mg/dl) 1,012 942 1,103 1,133 0.25

Table 6

Effect of probiotic, prebiotic and synbiotic on skinfold response to intradermal injection of PHA

Hours after PHA injection Treatment
Pooled SE
Control Probiotic Prebiotic Synbiotic
  2 4.38a 4.31 4.29 4.35 0.55
  4 4.05 3.98 3.94 3.99 0.53
  8 3.27 3.22 3.32 3.36 0.45
12 3.77 3.65 3.58 3.80 0.43
24 2.97 2.84 2.89 2.93 0.40
48 2.55 2.34 2.29 2.73 0.42

Skinfold increase (mm).