EFFECT OF PROPOLIS ON THE IMMUNE RESPONSE AND MEAT QUALITY IN EXPERIMENTALLY ESCHERICHIA COLI INFECTED BROILERS

Authors

1 Poultry Diseases Department. Mansoura Lab. Animal Health Research Institute. ARC. Egypt.

2 Food Hygiene.Tanta Lab. Animal Health Research Institute. ARC. Egypt

3 Pathology Department. Mansoura Lab. Animal Health Research Institute. ARC. Egypt.

Abstract

ABSTRACT
 
The present study was conducted to evaluate the effects of propolis on performance, immune response and meat quality of broiler chickens infected with E. coli. A total of 120 day old chicks were divided randomly into 4 equal experimental groups. The 1st group (G1) was fed a basal diet and infected with E. coli (1x108 CFU) at 5 days of age. The 2nd group (G2) was fed a basal diet supplemented with propolis (400mg/kg diet) and infected with E. coli (1x108 CFU) at 5 days of age. The 3rd group (G3) was fed a basal diet supplemented with propolis (400mg/kg diet). The 4th group (G4) was fed a basal diet and served as a control. Propolis supplemented groups showed a significantly increased body weight, decreased mortality, decreased reisolation frequency of E. coli from internal organs and early recovery of infection. Propolis improved significantly the phagocytic activity in both supplemented groups. Total leukocytic count was significantly increased in propolis supplemented group with significant increase in lymphocytes and concurrent decrease in heterophils. Propolis improved the Newcastle disease vaccine antibody production in both supplemented groups. Propolis treated groups have significantly higher breast muscles protein concentration and lower fat content. Also, it showed a significant reduction on the bacterial load in the examined samples in comparison to the samples of the non supplemented groups.
 

Keywords


Assiut University web-site: www.aun.edu.eg

 

EFFECT OF PROPOLIS ON THE IMMUNE RESPONSE AND MEAT QUALITY IN EXPERIMENTALLY ESCHERICHIA COLI

INFECTED BROILERS

 

MONA, S.I.1; NAGLAA, A.A.2 AND HALA, M. ISMAIL3

1Poultry Diseases Department. Mansoura Lab. Animal Health Research Institute. ARC. Egypt.

2 Food Hygiene.Tanta Lab. Animal Health Research Institute. ARC. Egypt.

3 Pathology Department. Mansoura Lab. Animal Health Research Institute. ARC. Egypt.

 

Received: 1 April 2021;     Accepted:28April 2021

 

 

ABSTRACT

 

The present study was conducted to evaluate the effects of propolis on performance, immune response and meat quality of broiler chickens infected with E. coli. A total of 120 day old chicks were divided randomly into 4 equal experimental groups. The 1st group (G1) was fed a basal diet and infected with E. coli (1x108 CFU) at 5 days of age. The 2nd group (G2) was fed a basal diet supplemented with propolis (400mg/kg diet) and infected with E. coli (1x108 CFU) at 5 days of age. The 3rd group (G3) was fed a basal diet supplemented with propolis (400mg/kg diet). The 4th group (G4) was fed a basal diet and served as a control. Propolis supplemented groups showed a significantly increased body weight, decreased mortality, decreased reisolation frequency of E. coli from internal organs and early recovery of infection. Propolis improved significantly the phagocytic activity in both supplemented groups. Total leukocytic count was significantly increased in propolis supplemented group with significant increase in lymphocytes and concurrent decrease in heterophils. Propolis improved the Newcastle disease vaccine antibody production in both supplemented groups. Propolis treated groups have significantly higher breast muscles protein concentration and lower fat content. Also, it showed a significant reduction on the bacterial load in the examined samples in comparison to the samples of the non supplemented groups.

 

Keywords:Propolis – E. coli - immune response - meat quality

 

           


INTRODUCTION

 

Collibacillosis is a common wide spread disease of poultry. It causes a great economic losses to poultry industry through increasing mortalities, decreasing productivity and down grading meat quality and increased

 

 


Corresponding author:MONA, S.I.

E-mail address:dr_mona.saidibrahim@yahoo.com

Present address: Poultry Diseases Department. Mansoura Lab. Animal Health Research Institute. ARC. Egypt.

condamination of carcasses, about 36-43%, during processing due to lesions of E. coli assepticemia, fibrinous pericarditis, fibrinous perihepatitis, peritonitis and air saculitis(Hasan et al., 2011; Abd El-Tawab et al., 2015). E. coli infection negatively affect humoral and cellular immune response, it can alone induce marked lymphocytic depletion from thymus and bursa, so the clinical E. coli infection is indicative of immune suppression(Nakamura et al., 1990;Kumari et al., 2020).

The antibiotics were used in poultry production as growth promotor and for treatment. The un controlled usage of antibiotics resulted in the appearance of multidrug resistant E. coli serotypes that were resistant to tetracycline, ciprofloxacine, co-trimoxazol and gentamycin (Hussain et al., 2017) making collibacillosis difficult to treat, in addition of increasing the risk of transmission of the resistance gene to other pathogens and pass to human via food causing a serious public health threat. The existence of shared antimicrobial resistance between E. coli isolates from broiler carcasses and human was demonstrated by Ramadan et al. (2020) so there is an increasing interest to replace antibiotics with natural products. In modern poultry production, work is now being done on poultry feed to further improve the quality and nutritional value of meat (Zdunczyk and Jankowski, 2013). The use of natural additives in poultry feed is particularly important, among which the use of propolis (Gregacevicet al., 2014).

 

Propolis is a natural resinous hive product that is collected by honey bees fromplants, flowers and leaf buds and then modified by their enzymes(Babaei et al., 2016). Propolis contains several chemical bioactive compounds as polyphenols (flavonoid aglycones, phenolic aldehydes, phenolic acids, alcohols and their esters and ketones), steroids terpenoids, amino acids (Eyng et al., 2015), vitamins (A, C, D, E and B1, B2, B6, niacin and folate) and some micro and macro minerals like calcium, iron, copper, zinc, magnesium, manganese, nickel and cobalt (Zabaiouet al.,2017). It also contains some enzymes asglucose-6-phosphatase, dehydrogenase, adenosine triphosphate and acid phosphatase(Yilmaz et al., 2003); (Kurek-Górecka et al., 2014).

 

The diversity of chemical composition of propolis are responsible for the antibacterial, antiviral, antifungal and immunomodulatory activity(klaric et al., 2018). It also gives propolis an additional advantage as antibacterial agent, the compination of different active ingredients with different concentrations prevents the bacterial resistance from occurring(Talas and Gulhan 2009); (Pamplona et al., 2011); (Eyng et al., 2013).

 

Several researchers have investigated the growth promoting effect of propolis by increasing feed intake, body weight gain and FCR (Shalmany and schivazad,2006); (Hassan and Abdulla, 2011);(Klaric et al., 2018). Others have reported the potentiating effect of propolis on humoral and cellular immunity in broiler chicken (Attia et al., 2017); (Mohamedet al., 2019).

 

Propolis increased the aroma, taste, juiciness, softness properties of breast muscles of broiler, improved meat digestibility, tenderness and skin pigmentation (Haščíket al., 2011). Broiler chicks fed diet supplemented with propolis had significantly higher breast muscles protein, moisture concentration and bone strength (Rabie et al., 2018).

 

Propolis supplementation protects the hepatic tissue from hepatotoxic factors and increased the intestinal villi length (Tekeli et al., 2010); (Babinska et al., 2013).

 

In this study we assessed the efficacy of propolis as natural alternative to antibiotics to control collibacillosis. Propolis effect on growth performance, immune response, reisolation of E. coli, meat quality and pathological changes was investigated.  

 

MATERIALS AND METHODS

 

1. Chicks and ration:

A total of 120 day-old chicks of mixed sex obtained from a breeder flock liberated from bacterial infection were used to study the effect of propolis on the immune response and meat quality in E. coli infected chicks.Birds were vaccinated against Newcastle disease (ND) using Hitchner B1at 7 days of age and Lasota vaccine at 18 and 28 days of age, and against Gumboro at 12 days of age.The chicks feda starter ration from 1 to 21days of age (contained protein 21%, fat 3.5%and energy 3054 Kcal/kg) and grower ration from 21 to 35 days of age (contained protein 17.2%, fat 2.5%, energy 3020 Kcal/kg). Both starter and grower ration were produced without any antibiotics and coccidiostats.

 

2. Bacterial strain:

E. coli (NCTC12241/ ATCC 25922) was obtained from Animal Health Research Institute, Dokki, Giza, Egypt.

 

3. Propolis:

Crud Egyptian propolis, from Dakahlia Governorate, was cut into small pieces and extracted using 70% ethanol (1:9) in dark warm place for 14 days. The alchoholic extract was evaborated under vaccum at 50oC until drying. The obtained dried extract was added to the ration at the concentration of 400mg/kg of ration. (krell, 1996).

 

4. Experimental design:

A total of 120 unsexed one day old Cobb chicks were randomly divided into 4equal experimental groups (30 chicks each). The 1st group (G1) was fed a basal diet and infected intratracheally with E. coli 1x108CFU at 5 days of age. The 2nd group (G2) was fed abasal diet supplemented with propolis (400 mg/kg diet) and infected intratracheally with E. coli 1x108CFU at 5 days of age. The 3rd group (G3) was feda basal diet supplemented with propolis (400 mg/kg diet). The 4th group (G4) was fed basal diet without any additives and served as a control. The birds were challenged intratracheally with 0.2 ml of a stock solution of E. coli containing 1x109 CFU/ml, providing a dose of 1x108 CFU.

 

5.Measured parameters

5. 1. Mortality,clinical signs, and postmortem examination:

The experimental birds were noticed periodically for clinical signs. Dead birds were subjected to post mortem examination, three birds from each group were slaughtered and sacrificed weekly for recording the suspected lesion.

 

5.2. Performance:

Oncoming, the chicks were weighed,performance parameters that includes the body weight (BW), weight gain (WG) feed intake (FI) and Feed conversion ratio (FCR) were recorded.

 

5.3. Bacterial reisolation:

Reisolation of E. coli from lung, liver and heart of weekly slaughtered birds on Eosin methylene blue agar media.

 

5.4. Evaluation of immune response:

Blood samples weekly collected from slaughtered birds were used for detecting the phagocytic activity, differential leukocytic count and Haemagglutination inhibition test for detection of antibodies against Newcastle disease vaccine.

 

5.4.1. Phagocytic activity

Blood samples were collected in vials containing heparin. Measurment of phagocytic activity of peripheral blood monocytes using Candida albicans was adapted as described by Anthony et al. (1985), Boyum (1986), Goddeeris et al. (1986), Chu and Dietert (1989)and Wilkinson (1976).

 

Phagocytic activity % = macrophages containing yeast/ totalnumber of macrophages X 100

Phagocytic index =number of yeast phagocytized / number of phagocytic cells containing yeast

 

5.4.2. Differential leukocytic count:

Blood samples were collected in vials containing EDTA. Blood film was prepared according to Lucky(1977) for differential leukocytic count, the percentage of each type of cells were calculated according to Schalm(1986).

 

5.4.3.Haemagglutination inhibition test for detection of Newcastledisease vaccine antibodies:

Serum was separated from blood samples by centrifugation at 3000 rpm. Micro-techniqe of haemagglutination inhibition test was done according to Takatsy(1955). Antibody titer was calculated according to Brugh(1978).

 

5.5. Evaluation of meat quality:

At the end of the experiment(35 days), 24 birds (6 birds per group) were chosen at random. Birds were slaughtered, at the slaughterhouse. After evisceration, the carcasses were kept at approximately 18 °C for 1 h post mortem.Breast meat samples (pectoralis major) were dissected from each left half-carcass (right half-carcasses were assigned to other analysis) and stored at 4 °C until 24 h post mortem. The samples (boneless breast without skin) were individually packaged in labelled bags and stored at -18 °C for prior to analysis.

 

5.5.1.Chemical composition:

Samples of chicken breast muscle without skin (n = 24) were analyzed for

 

a)Crude protein content was estimated by means of the Kjeldahl method using BÜCHI B324 apparatus (Switzerland)(AOAC,1990).

 

b)Ash using the ash content procedure described by the AOAC (1990).

 

c)The fat was determined by extraction with petroleum ether using a Tecator Extraction System 1045 Soxtec (Foss Tecator AB, Hoganas, Sweden)(AOAC, 1990).

 

d)Determination of moisture (Corzo et al.,2009).

 

e) Determination pH according to Biswas et al.(2007).

 

5.5.2 Microbiological evaluation:

a)Total Plate Count(USDA, 2011).By usingNutrient agarmedia.

 

b)Total Enterobacteriaceae count(ISO, 2001).By using Violet Red Bile Glucose Agar(VRBG) media.

 

c)Total Coliform count(FDA,2012).By using Violet Red Bile gar (VRB).

 

d)Total Staphylococci count(USDA, 2011).By using Baird Parker agar media.

 

e)Total Psycrotrophic count (USDA, 2011).By using standard plate count agar media.

2.5.5.3: sensory evaluation:

Sensory profiles were determined by panelists were instructed on the assessment criteria. Panelists were asked to evaluate the samples of breast muscle for aroma (1 = very poor, 5 = very good), juiciness (1 = extremely dry, 5 = extremely juicy), tenderness (1 = extremely tough, 5 = extremely tender), and overall acceptability (1 = not acceptable, 5 = extremely acceptable) on a 5-point hedonic scale. The samples were presented to the panelists monadically on plain white porcelain plates. Panelists were provided with water for neutralization of receptors before and between the samples. The panel evaluated each sample in triplicate over an 8-week period (n = 6) (Pelin-Can and Arslan, 2011).

 

5.6. Pathological studies:

 

5.6.1. Histopathological examination:

Tissue specimens from bursa, thymus, spleen, lung, liver, intestine and heart of all experimental groups were collected at 21 of age andfixed in 10% neutral buffered formalin. The tissues were prepared for routine histopathological examination (Bancroft et al., 2013) and examined using the light microscope (Olympus CX31, Japan) and photographed using a digital camera (Olympus, Camedia C-5060, Japan).

 

5.6.2.Immunohistochemistry investigations:

For detection the possitive immune cells in spleen, bursa and thymus: Paraffin sections from the spleen, bursa of fabricius and thymus were used for immunohistochemical detection of CD79 (B-lymphocytes) in spleen and bursa of fabricius and CD3 (T- lymphocytes) in thymus at day 21of age. The tissue sections (3µm thick), were deparaffinized and hydrated then washed by distal water. Antigen retrieval was applied in a water bath using citrate buffer (pH6) for 20 minutes. The endogenous peroxidase activities were removed with 3% hydrogen peroxide (H2O2), then sections were incubated in diluted polyclonal primary antibody for one hour at room temperature in a humidified chamber for CD79 (obtained from Novus Biologicus company) and CD3 polyclonal rabbit anti-human CD3 (Dako) at 1 in 300 dilutions. The primary antibodies were detected in all experimental groups. The staining was performed using Power-StainTM 1.0 Poly HRP DAB according to the manufacturer's instructions. The sections were rinsed three times for 5 min each with Phosphate buffered saline, and were incubated in Poly HRP Conjugate for 15 minutes at room temperature. A mixture of DAB chromogen visualized the sections, then counterstained with hematoxylin and dehydrated and mounted (Anis et al., 2013).

 

5.6.3. Scoring of the positive immune cells in bursa, spleen and thymus:

The relative frequency of B-lymphocytes and T lymphocytes per focus was calculated according to the point count method, by using digital an Axiostar plus microscope interfaced with an Axiostar plus digital camera and Axiovision 4.1 software (Carl Zeiss) at a magnification of 100 (Weibel, 1969).

 

6. Statistical analysis:

The data was set as mean ± standard error and was analyzed using analysis of variance (ANOVA). The significance of difference between means at P<0.05 was calculated using Duncan test. (Steel and Torrie, 1980).

RESULTS

 

The experimental study was done to evaluate propolis as a feed additive to decrease the adverse effect of collibacillosis in broilers instead of using antibiotics.

 

Clinical signs, mortality and postmortem lesions:

The clinical signs ofE. coli infected group (G1) appeared 24h after infection. Birds showed depression, inappetence, ruffled feathers, droppy wings, huddling together and greenish diarrhea. The signs continued for 2 weeks post infection. These signs were less sever in E. coli-propolissupplemented group (G2) and lasted for only one week post infection.Morbidity was decreased from 53.3% in (G1) to 16.6% in (G2). Group 3 and group 4 showed no signs of illness. Mortality was decreased from 26.6% in (G1) to 6.6%in (G2).(Table 1).

 

Postmortem examination of dead birds revealed severcongestion of lung, liver, spleen, pericarditis, perihepatitis, unabsorbed yolk sac and enteritis.

 

E. coliinfected birds (G1) showed sever congestion of all internal organs (lung, liver spleen, heart, and kidney) at 1st week of age. At 2nd week there was fibrinous pericarditis, fibrinous perihepatitis, airsaculitis and enteritis. At 3rd week of age the there was a thick fibrin sheet on the liver surface causing adhesion with other internal organs.At 4th and 5th week there was only fibrinous pericarditis and perihepatitis.

 

In E. coli-propolis supplemented birds (G2) there was congestion of lung, liver and spleen at the 1st week of age. At 2nd week of age there was mild pericarditis, perihepatitis and airsaculitis. At 3rd week and onward all dissected birds appeared normal.

 

Performance:

Propolis supplemented group (G3) showed a significant increase in mean body weight all over the experimental period when compared to other groups.From the 3rd week of age until the end of the experiment G2 showed a significant increase in body weight when compared to G1 and control group (G4). Propolis increased the feed intake in both treated groups (G2 and G3) when compared to corresponding control groups (G1and G4).There is no difference in the FCR in propolis supplemented group (G3) when compared to control group (G4), but there is a decrease in FCR in E. coli-propolis supplemented group (G2) in comparison to E. coliinfected (G1).(Table 2).

 

Reisolation:

Propolis decreased the reisolation frequency of E. coli from lung, liver and heart in E. coli-propolis supplemented group(10/45)when compared to E. coli infected group (23/45). The highest frequency of reisolation was from lung followed by liver and heart. E. coli-Propolis supplemented group showed early clearance of infection as early as 3rd week of age whileE. coliwas still reisolated from lung until the end of experiment in E. coli infected group (G2). (Table 3).

 

Evaluation of immune response:

Phagocytic activity:

E. coli infected groupshowed a significant decrease in phagocytic activity when compared to control group. Propolis increased significantly the phagocytic activity in both supplemented groups (G2 and G3) when compared to corresponding groups (G1 and G4). The phagocytic activity of the E. coli-propolis supplemented group was improved to reach the levels of control at the 4th and 5th week of age. (Table 4)

 

Differential leukocytic count:

Total leukocytic count was significantly increased in E. coli infected group (G1) with significant lymphocytopenia and heterophilia all over the experimental period when compared to control group (G4). Propolis supplemented group (G3) showed a significant increase in total leukocytic count all over the experimental period, significant increase in lymphocytes at the 1st, 2nd and 3rd week of age and a significant decrease in heterophils at the 1st, 2nd,3rd and 4th week of age when compared to control group (G4).

 

E. coli-propolis supplemented group (G2) revealed a significant decrease in total leukocytic count when compared to E. coli infected group(G1) while was significantly higher when compared to control (G4) all over the experimental period. There was a non-significant difference in lymphocytes and heterophils between E. coli-propolis supplemented group (G2) and E. coliinfected group (G1) at the 1st week of age, while there was a significant increase in lymphocytes and significant decrease in heterophil in E. coli-propolis supplemented group (G2) when compared to E. coli infected group (G1) from the 2nd week of age and onward. Lymphocytes and heterophils showed a significant difference in E. coli-propolis supplemented group (G2) during the 1st and 2nd week of age while there was anon significant difference during the 3rd, 4th and 5th week of age when compared to control group. There was a non significant difference in eosinophil, monocytes and basophils between the experimental groups. Table (5).

 

Haemagglutination inhibition test for detection of Newcastle antibodies:

Mean antibody titer against Newcastle disease vaccine was higher in propolis supplemented group (G3) when compared to control group (G4) all over the experimental period but a significant increase was seen only at 2nd and 3rd weeks of age. The E. coli-propolis supplemented group (G2) showed a higher antibody titer all over the experiment but a significant increase was seen during the 3rdweek of age when compared to E. coli infected group (G1). (Fig 1).


 

Table 1:Effect of propolis on morbidity and mortality rate.

 

 

G1(E. coli)

G2(E.coli+Propolis)

G3(Propolis)

G4(control)

Morbidity

No

18/30

5/30

0/30

0/30

%

53.3%

16.6%

0%

0%

Mortality

No

8/30

2/30

0/30

0/30

%

26.6%

6.6%

0%

0%

 


 

Table 2:Effect of propolis on performance.

 

 

Age

Group

G1(E. coli)

G2(E.coli+Propolis)

G3(Propolis)

G4(control)

1 w

BW

227.2±5.96c

241.5±5.78c

284±2.99a

259±5.84b

2 w

BW

546±19.53c

583.5±11.92bc

671.3±2.76a

610±13.30b

3 w

BW

1032.5±34.13d

1198.5±10.74b

1332.5±8.91a

1127±10.79c

4 w

BW

1523.8±49.34d

1785±48.14b

1960±12.46a

1670±16.90c

5 w

BW

2158.3±64.95d

2536.5±76.77b

2858.3±17.02a

2390±12.25c

Total

WG

2095.7

2473.5

2795.3

2328

 

FI

3162.8

3684

4071

3388.3

 

FCR

1.51

1.48

1.46

1.46

 

Data was set as mean ± Standard error. Means within the same row with different superscripts are significantly different (P< 0.05).

BW: Body weight.                                        WG: weight gain.

FI: feed intake.                                               FCR: Feed conversion ratio.

 

Table 3: Effect of propolis on reisolation frequency of E. coli from lung, liver and heart.

 

Age

organ

G1(E. coli)

G2(E.coli+Propolis)

G3(Propolis)

G4(control)

1st w

Lung

3/3

2/3

0/3

0/3

Liver

2/3

2/3

0/3

0/3

Heart

3/3

3/3

0/3

0/3

Total

8/9

7/9

0/9

0/9

2nd w

Lung

2/3

1/3

0/3

0/3

Liver

2/3

1/3

0/3

0/3

Heart

1/3

0/3

0/3

0/3

Total

5/9

2/9

0/9

0/9

3rd w

Lung

2/3

0/3

0/3

0/3

Liver

2/3

0/3

0/3

0/3

Heart

1/3

0/3

0/3

0/3

Total

5/9

0/9

0/9

0/9

4th w

Lung

2/3

0/3

0/3

0/3

Liver

1/3

0/3

0/3

0/3

Heart

0/3

0/3

0/3

0/3

Total

3/9

0/9

0/9

0/9

5th

Lung

1/3

0/3

0/3

0/3

Liver

0/3

0/3

0/3

0/3

Heart

0/3

0/3

0/3

0/3

Total

1/9

0/9

0/9

0/9

Total

23/45

10/45

0/45

0/45

 


 

Table 4: Effect of propolis on phagocytic activity% and phagocytic index.

 

Age

G1(E. coli)

G2(E. coli+Propolis)

G3(Propolis)

G4(control)

PA

PI

PA

PI

PA

PI

PA

PI

1 w

43.3±0.66d

1.13±0.67

63.33±2.16c

3.27±0.15

81.67±0.15a

4.53±0.15

72±0.15b

3.9±0.58

2 w

46±2d

1.3±0.10

65.33±0.67c

3.1±0.10

83±1.53a

4.6±0.12

72.33±1.45b

3.88±0.17

3 w

48±1.15d

1.4±0.58

64±1.15c

3.33±0.03

83±1.00a

4.6±0.1

73.33±2.40b

4.02±0.10

4 w

45±0.58c

1.25±0.29

68.67±0.67b

3.73±0.33

82.33±2.19a

4.55±0.16

74±2.30b

4.02±0.10

5 w

50±1.15c

1.48±0.44

71.33±1.76b

3.97±0.15

83.67±0.88a

4.63±0.88

73.67±0.88b

3.95±0.29

Data was set as mean ± Standard error. Means within the same row with different superscripts are significantly different (P< 0.05).

 

Table 5: Effect of propolis on total and differential leukocytic count.

 

Age

 

G1(E. coli)

G2(E. coli+Propolis)

G3(Propolis)

G4(control)

1 w

TLC

19.5±0.15a

19.3±0.11a

18.2±0.89b

16.7±0.12c

L

40.7±1.20c

42.7±0.88c

52±1.15a

46.5±1.38b

H

48.3±0.33a

45.7±0.67ab

38±1.73c

43±0.58b

M

5.3±0.33a

5.3±0.67a

5.7±0.33a

5.3±0.33a

E

4.3±0.89a

4.7±0.33a

4±1.15a

3.7±0.33a

B

1.3±0.33a

1.7±0.67a

1±0.58a

1.3±0.33a

2 w

TLC

27.2±0.13a

23.4±0.15b

22.7±0.12c

20.4±0.15d

L

36±1.00d

44±1.00c

53.7±1.20a

49.3±0.88b

H

53.3±0.33a

47±1.00b

38.7±0.88c

40.7±1.20c

M

5.3±0.33a

6±0.58a

5.7±0.67a

5±0.00a

E

4.3±0.33a

3±0.58ab

1.7±0.33b

4±1.15ab

B

1±0.58a

1±0.58a

0.3±0.33a

1±0.00a

3 w

TLC

30.1±0.15a

28.5±0.20b

27.7±0.17c

25.2±0.67d

L

28.7±0.88c

48.7±0.88b

53.7±0.88a

50.7±0.88b

H

59±0.58a

42.3±1.45b

36±1.00c

39.7±0.88b

M

4.3±0.33a

5±0.58aa

5.3±0.33a

5.3±0.33a

E

6±0.00a

4±0.58a

4±1.15a

3.7±0.88a

B

2±0.58a

0.7±0.33a

0.7±0.33a

0.7±0.33a

4 w

TLC

34.5±0.21a

30.1±0.03b

29.3±0.12c

27.4±0.17d

L

31.7±1.45b

51.7±0.88a

54.3±0.88a

52±1.00a

H

56±1.15a

38.7±0.33b

34.3±1.20c

38.7±0.88b

M

4.7±0.88a

5±0.58a

6±0.00a

5±1.15a

E

6±0.58a

4±0.58a

3.7±1.20a

4.7±0.88a

B

1.7±0.88a

0.7±0.67a

1±0.58a

1±0.58a

5 w

TLC

40.1±0.17a

32.2±0.15b

32.1±0.14b

29.3±0.58c

L

35±2.08b

52±1.00a

54.7±2.40a

54.7±2.19a

H

53.7±1.76a

37.7±0.88b

36.7±1.20b

36±1.00b

M

4.7±0.33a

5±0.58a

5.7±0.33a

4.7±0.88a

E

5.7±0.88a

4.7±0.88a

3±1.15a

4±1.00a

B

1±0.58a

0.7±0.33a

0.7±0.33a

0.7±0.33a

Data was set as mean ± Standard error. Means within the same row with different superscripts are significantly different (P< 0.05).

 

 

Fig (1): Effect of propolis on antibody titer (log) against Newcastle disease vaccine.

 


Meat quality

Chemical composition

The results displayed in Table (6)indicatedthat thegroups of broiler chicks fed diet supplemented with propolis (G2 and G3) resulted in significantly higher protein (20.31±0.1, 22.16±0.23), respectively. There was a non significant difference in moisture content amonggroups, the highest content was detected in propolis supplemented group (74.6±1.9) and the lowest in E. coli infected group(74.3±0.4). Meanwhile, there was a non significant differencesof pH valuein between groups. In addition, no significant differences were observed in ash content among dietary groups, with the highest value in E.coli infected group (1.18±0.20g.100 g-1) and the lowest one in propolis supplemented group (1.05±0.28 g.100 g-1).Also the significant changes (p ≤0.05) were observedin fat content between groups, the highest fat content was detected in E. coliinfected group (G1) by (1.8±0.75) and lowest was detected in propolis supplemented group (G3) by(0.84±0.12) when compared to the control one.

Microbial evaluation:

As shown inTable (7)using of propolis in boiler chicken feed significantly (P<0.05) reduced coliform, Staphylococci and Psycrotrophic bacteria in chicken’s breast muscle in propolis supplemented groups (G2 and G3) when compared to E. coliinfected and control group(G1 and G4) respectively. Propolis supplemented group showed the lowest Agar Plate count among groups (5.97±0.18) log cfu/g.Enterobacteriaceae count was significantly decreased in propolis supplemented group (3.42±0.14) log cfu/g when compared to other groups.

 

Sensory evaluation:            

Table (8) represented the scores given by panelists for the sensory characteristics (color, flavor, juiciness, tenderness, and overall acceptability) of breast chicken meat. There was significant effects (P≤0.05) of propolis supplementation on the sensory attributes. The  highest scores  foroverall acceptability was given for propolis supplemented group (4.26  ±0.29) which considered as the most  acceptable  for  panelists  and  E. coliinfected group (G1) has received the  lowest score (3.26 ±0.18) when compared to control group. As for the color, all  the groups differ from  each other, with the highest mean score found in propolis supplemented group  (4.5±0.36) and the lowest score was found in E. coli infected group (3.62  ±0.27).Alsofor flavor there was significant difference (P≤0.05)between (G2 and G3)and (G1 and G4). For tenderness, lowest score was detected in the Eoliinfected group (3.2±0.21). Statistically significant differences (P≤0.05) were detected between mean scores for (G2 and G3) and those for G1 and G4 group. In terms of juiciness, the highest score observed in G3 (4.38 ±0.31). This means that after application of the propolis in the diet of chickens were found improved organoleptic properties of thebreast muscle. However, panelists were unable to differentiate tenderness of chicken breast meat from groups G2 and G3, as well as juiciness of meat from groups G2 and G3. 

 

 

Table 6: Effect of propolis on chemical composition of broiler breast samples (%).

 

 

G1(E. coli)

G2(E. coli+Propolis)

G3(Propolis)

G4(control)

Protein

19.35±0.35c

20.31±0.1b

22.16±0.23a

20.24±0.25b

Fat

1.8±0.75a

1.36±0.43b

0.84±0.12c

0.92±0.05c

Ash

1.18±0.20a

1.15±0.1a

1.05±0.28a

1.08±0.46a

PH

5.9±0.057a

6.01±0.12a

5.94±0.17a

5.92±0.05a

Moisture

72.03±0.89a

74.3±0.43a

74.6±1.9a

74.01±0.2a

Data was set as mean ± Standard error. Means within the same row with different superscripts are significantly different (P< 0.05).

 

Table 7:Effectof propolis on the microbial count (log cfu/g) of broiler breast samples.

 

 

G1(E. coli)

G2(E. coli+Propolis)

G3(Propolis)

G4(control)

Total APC counts

7.26±0.39a

6.26±0.26ab

5.97±0.18b

6.59±0.95ab

Total Coliform

4.08±0.07a

3.4±0.99b

3.12±0.91b

3.84±0.87a

Total Enterobacteriaceae

3.99±0.05a

3.88±0.09a

3.42±0.14b

4.04±0.15a

Total Staphylococci count

4.55±0.19a

3.46±0.16b

3.33±0.18b

4.52±0.28a

Total Pscychrotrophic

5.12±0.05a

4.34±0.19b

4.57±0.02b

5.23±0.04a

Data was set as mean ± Standard error. Means within the same row with different superscripts are significantly different (P< 0.05).

 

Table 8:Effect of propolis on sensory evaluation of chicken breast meat.

 

Groups

G1(E. coli)

G2(E. coli+Propolis)

G3(Propolis)

G4(control)

Color

3.62±0.27b

4.2±0.21a

4.5±0.36a

3.78±0.22b

Flavor

3.42±0.37b

4.1±0.42a

4.44±0.28a

3.6±0.26b

Juiciness

3.22±0.19c

3.64±0.4b

4.38±0.31a

3.24±0.23c

Tenderness

3.2±0.21c

3.76±0.32b

4.26±0.29a

3.44±0.27ab

Overall acceptability

3.26±0.18c

3.8±0.25b

4.26±0.29a

3.69±0.45c

Data was set as mean ± Standard error. Means within the same row with different superscripts are significantly different (P< 0.05).

 


Histopathological changes:

Heart:

In control group, heart displayed normal myocardium with normal cardiac muscle fiber striations (Fig.2A). Heart in E. coli infected group showed severe degeneration of myocardial muscle (myopathy), loss of striations of muscle fibres, revealed eosinophilic necrotic area with leucocytic infiltration, predominantly heterophils in myocardium and hemorrhage (Fig.2B). In propolis supplemented group, heart showed normal myocardium and normal cardiac muscle fibers (Fig.2C). E.coli-propolis supplemented group, showed normal cardiac muscle striations, moderate edema and accumulation of heterophils were also observed (Fig.2D).

 

 

 

 

Figure (2): Histopathological changes in heart in different groups

 

A: Control group showing normal myocardium with normal cardiac muscle fiber striations (arrow).HE, 100x.

B: E.coli infected group showing severe degeneration of myocardium, loss of striations of muscle fibres (thin arrow), diffuse heterophilic aggregation in myocardium and hemorrhage (thick arrow).HE, 100x.

C: Propolis supplemented group showing normal myocardium, normal cardiac muscle fibers(arrow).HE, 100x.  

D:  E.coli-propolis supplemented group showing normal cardiac muscle fibers (star), moderate edema and heterophilic aggregation (arrow).HE, 100x.


 

 

Lungs:

Lung in control group showed normal hexagonal shape parabronchi lined with squamous epithelium, its wall has numerous openings leading to respiratory atria and air capillaries. Each parapronchi separated from adjacent lobules by fibrous septa and capillaries (Fig.3A). In E.coli infected group, there was marked degeneration of parenchyma characterized by strongly stained eosinophilic zone surrounding the parabronchi, besides haemorrhage and edema in the interalveolar septa. Also, most of parabronchi was ringed due to swelling of lining epithelium and filled with eosinophilic exudates with granulocytes aggregations in bronchial epithelium marked obliteration of pulmonary capillary (Fig.3B). Propolis supplemented group showed normal parabronchi without any exudates, and intact lining epithelium. The interalveolar septa were prominent with normal capillaries (Fig.3C). E.coli-propolis supplemented group showed swelling of atrial lining cells, besides mild infiltration of heterophils in parabronchial lumen and respiratory atria. The septa among parabronchi were distended with engorged capillaries (Fig.3D).

 

 

 

 

Figure (3): Histopathological changes in lung in different groups.

 

A: control group showing normal hexagonal shape parabronchi lined with squamous epithelium (thick arrow), leading to normal respiratory atria (thin arrow), and separated by fibrous septa with blood capillaries (star).HE, 400x.

B: E.coli infected group showing degenerated parabronchi surrounded by eosinophilic zone(thick arrow) and filled with intense exudate and granulocytes aggregation(star),hemorrhage and diffuse edema in the inter alveolar septa(thin arrow),HE, 400x.

C: propolis supplemented group showing normal parabronchi and atria with intact lining epithelium (arrows), prominent interalveolar septa and normal capillaries (thick arrow). HE, 400x.

D: E. coli-propolis supplemented group showing swelling of atrial lining cells (thin arrow), mild infiltration of heterophils in parabronchial lumen and respiratory atria (star), distended septa with engorged capillaries (thick arrow).HE, 400x.

 



 

Liver:

In the control group, the liver tissue displayed normal parenchyma with hepatocytes arranged in radiating cords toward the central vein (Fig.4A). In E.coli infected group, Liver showed, Congestion of blood vessels and hemorrhages, hepatic vacuolar degeneration besides focal coagulative necrosis and heterophilic

 

aggregation(Fig.4B).propolis supplemented group, hepatocytes and sinusoids appeared normally with dialated central vein (Fig.4C).  Liver of E.coli-propolis supplemented group showed focal congestion, perivascular inflammatory cells infiltration, beside mild vaculation (Fig.4D).

 

 

 

 

Figure (4): Histopathological changes in liver in different groups

 

A: Control group showing normal parenchyma with hepatocytes arranged in radiating cords. HE, 100x.

B: E.coli infected group showing hepatic vacuolar degeneration (thick arrow), focal coagulative necrosis (thin arrow) and heterophilic aggregation (star).HE, 100x.

C: Propolis supplemented group showing normal hepatic tissue, with dialated hepatic central vein (star).HE, 100x.

D: E.coli-propolis supplemented group showing mild congestion, perivascular inflammatory cells infiltration (thick arrow) mild vacular degeneration (thin arrow).HE, 100x.

 


Intestine:

In the control group, Intestine showed normal intestinal villi with intact lining epithelium (Fig.5A). E.coli infected group showed severe villus destruction and lymphocytic aggregation in intestinal lumen (Fig. 5B). Propolis supplemented group, showed increase in the absorptive area of intestine by increase the villus width and length with intact lining epithelium and goblet cell hyperplasia (Fig.5C). The intestine of E.coli-propolis supplemented group showed mild epithelium desquamation and hyperplasia of intestinal glands (Fig.5D).

 

 

 

 

 

Figure (4): Histopathological changes of intestine in different groups

 

A: control group showing normal intestinal villi with intact lining epithelium (arrow). HE, 100x.

B:E.coli infected group showing severe villus destruction and necrosis with lymphocytic aggregation in intestinal lumen (arrow).HE, 400x.

C: propolis supplemented group showing increase the villus width and length with intact lining epithelium (thick arrow) and goblet cell hyperplasia (thin arrow).HE, 400x.

D:E.coli-propolis supplemented group showing hyperplasia of intestinal glands with (thick arrow) mild epithelial desquamation and lymphocytic aggregation (thin arrow). HE, 400x.

 


Bursa of Fabricius:

In the control group, bursa composed of tightly packed lymphoid follicles which consist of cortex and medulla. Follicles separated by connective tissue and covered with pseudostratified columnar epithelium (Fig.6A). E.coli infected group showed lymphocytolysis characterized by severe depletion and lysis of lymphoid cells, associated with appearance of multiple epithelial cysts and edema of subfollicular epithelium and in interfollicular connective tissue (Fig.6B). Propolis supplemented group showed intact surface epithelium, normal lymphoid tissue of cortex and medulla, normal interfollicular and subepithelial connective tissue (Fig.6C). E.coli-propolis supplemented group showed mild focal lymphoid deplesion, mild subepithelial and inter follicular congestion and edema with small cyst formation (Fig.6D).

 

 

 

 

 

                                                                                                       

 

 

Figure (6): Histopathological changes of Bursa of Fabricius in different groups

 

A: control group showing tightly packed lymphoid follicles consist of cortex and medulla (thin arrow), Separated by connective tissue (thick arrow) and covered with pseudostratified columnar epithelium (HE, 100x).

B: E.coli infected group showing severe lymphoid depletion and lymphocytolysis (thick arrow), multiple epithelial cysts (thin arrow), and oedema and congestion of follicular surface epithelium and in interfollicular connective tissue (star). HE, 100x.

C: propolis supplemented group showing intact surface epithelium (star), normal cortical and medullary lymphoid tissue (thin arrow) and normal subepithelial and interfollicular connective tissue (thick arrow).HE, 100x.

D: E.coli-propolis supplemented group showing mild focal lymphoid deplesion (arrow), mild subepithelial congestion and oedema, small cyst formation (star). HE, 100x.

 


Immunohistochemistry of CD79 in bursa and spleen and CD3A in thymus:

The immune reactive CD79A positive cells in the spleen and bursa showed a significant increase in propolis supplemented groups (G2 and G3) when compared to the corresponding groups (G1 and G4). Detection of CD3A positive cytoplasmic reaction in the thymus showed a significant increase in propolis supplemented groups (G2 and G3) in comparison to the corresponding groups (G1 and G4).E.coli infected group showed asignificant decrease of immune cells when compared to other groups (G2, G3, and G4).Fig.7


 


 

 

 

 

Fig. 7: Immunohistochemistry of CD79 in bursa and spleen and CD3A in thymus:

 

Table 9: Number of possitive cells, CD79A in bursa and spleen, and CD3A in thymus.

 

 

G1(E.coli)

G2(E.coli+Propolis)

G3(Propolis)

G4(control)

CD79A in bursa

37.6±3.25d

65.8 ±2.41b

88.4±8.71a

62.5±2.75c

CD79A in spleen

29.4 ±8.21d

58.21 ±7.3b

79.3± 2.01a

56.15± 3.36c

CD3A in thymus

32.4 ± 8.63d

47.3 ± 4.1b

69.5 ± 5.23a

45.32 ± 3.73c

 

Data was set as mean ± Standard error. Means within the same row with different superscripts are significantly different (P< 0.05).

 


DISCUSSION

 

Propolis is a highly nutritive material containing vitamins, minerals and other chemicals. The present study was done to evaluate propolis as a feed additive to decrease the adverse effect of collibacillosis instead of using antibiotics. In this study E. coli caused 26.6% mortality, sever clinical signs that extends for 2 weeks after infection and sever postmortem lesions. Similar results were obtained by Kumari et al.(2020) andHams and Waleed(2018) whom recorded a mortality rate of 25.7% and 25%, respectively when infect 7 days old broilers with E. coli. Several studies had recorded the ability of propolis to increase the survival rate of broilers. Klaric et al. (2018(found that the addition of propolis (0.5 g/ kg diet) resulted in significant decrease in the mortality rate (0%) when compared non supplemented group (10%).Also,Shalmany and Shivazad (2006) andOmar et al. (2002)recorded much lower mortality in broilers supplemented with propolis.

 

The positive effect of propolis in decreasing the mortality (6.6%), severity of clinical signs and postmortem lesion and shortening of the duration of collibacillosis in E. coli-propolis supplemented group may be due to its powerful bactericidal properties. The Egyptian, Spanish and Greece propolis have the highest antimicrobial activity against E. coli when compared to Chinese, Bulgarian, Australian, Italian and Canadian propolis (Hegaziet al., 2014). Dakahliapropolis showed the highest antibacterial activity against E. coli when compared to Ismailia and Sharkia propolis (Abd El Hady and Hegazi 2002).The positive effect of propolis may also be attributed to its ability to stimulate the immune system,improve macrophage activity and the functions of the lymphatic tissues (Cetinet al., 2010, Freitas et al., 2011, Shihab and Ali, 2012). Several previous studies on animals have showed that propolis or its flavonoids activate macrophages, increasing phagocytic capability and the release of microbicidal agents, such as nitric oxide and tumour necrosis factor-α (Orsi et al., 2000; Sforcin, 2007).propolis also enhance the resistance of chickens which lead to reduce mortality (Omar et al., 2002; Shalmany and Shivazad, 2006).

 

E. coli caused a significant decrease in body weight when compared to controlall over the experimental period, similar result was obtained by Kumari et al.(2020)when infect 7 days old chicks. The E. coli-propolis supplemented group showed a non significant increase in body weight during the 1st and 2nd week of age and after that showed a significant increase in body weight when compared to E. coli infected group which attributed to the antibacterial effect of propolis and early recovery of infection.Propolis had a significant effect on body weight and feed intake in propolis supplemented group. Klaric et al.(2018) reported a significant increase in average body weights of chickens supplemented with 0.5g and 1g propolis/kg feed mixture all over the experimental period while Hassanet al.(2018) indicated that addition of 1gm, 2gm and 3gm of propolis/ kg of broiler diet had non significant effect on body weight until the 2nd week of age, which increased significantly from the 3rd week to the 6th week of age. A dose response effect of propolis on body weight was reported where the body weight was significantly improved by increasing the dose of propolis in feed at 50, 100, 150, 200 and 250 mg/ kg diet (Shalmany and Schivazad, 2006).

 

Propolis improved the feed intake in propolis supplemented group in comparison to control group, but did not affect the FCR. An improvement in feed intake and FCR in chickens received 250 mg and 400 mg of propolis was reported by Shalmany and Schivazad(2006) and Hassan and Abdulla(2011).On the other hand,Mahmoud et al.(2013) found that inclusion of different doses in broiler diet did not affect feed intake and FCR and significantly reduced body weight in comparison to control diet and had adverse effect on performance. Propolis improved both feed intake and FCR in E. coli-propolis supplemented group when compared with E. coliinfected non supplemented group. Addition of propolis 1gm/kg of diet caused an improvement in feed intake and FCR in chickens exposed to lead toxicity and in laying hens reared under chronic heat stress (Tatli and Seven., 2008; Seven et al., 2011; Sevens et al., 2012). The improvement in feed intake and FCR was associated with enhanced flavor due to flavonoid content of propolis and improved digestion and nutrient absorption and metabolism leading to changes in blood concentrations of cholesterol, total protein, and amino acid (Tekeli et al., 2011; Abd El-Rahman and Mosaad, 2013; Attia et al., 2014).

 

Propolis decreased the reisolation frequency of E. coli from internal organs and caused early clearance of infection,where E. colicannot be reisolated after 2nd week of age in E. coli-propolis supplemented group while still reisolated at the 5th week of age in E. coliinfected group. Kumari et al.(2020) isolated E. coli from liver until 28 dayspost infection. The lower frequency of reisolation and early clearance of infection in infected supplemented group reflects the antibacterial activity of propolis. Several researchers reported the invitro antibacterial activity of propolis on E. coli(Abd El Hady and Hegazi 2002; Hegaziet al., 2014). Propolis showed bacteriostatic activity against wide range of bacterial genera and possess a bactericidal activity in high concentrations (Mirzoeva et al., 1997 and Drago et al., 2000). Antibacterial properties of flavonoids occurs by interfering bacterial cell wall permeability and interaction with bacterial DNA (Bryan, 1982; Wilson and Gisvold, 1982).The antimicrobial activity of propolis is related to the synergistic effect of its compounds (Santos et al., 2002).

 

Phagocytosis is essential for macrophage to remove invades and present antigens to T cells so it affects the cellular and humoral immunity (Yang et al., 2014). The effect of E. coliinfection on phagocytic activity was reported by Hams and waleed (2018), E. coli caused a significant decrease in the phagocytic activity at the 2nd and 3rd week of age after infection of 7 days old chicks. Propolis improved significantly the phagocytic activity in both supplemented groups. Several authors have documented the role of propolis in improving the phagocytic activity (Eyng et al., 2013; Attia et al., 2017). Phagocytic activity was significantly enhanced by propolis flavonoids and tended to be a dose dependent (Yang et al., 2014).

 

E. coli infection caused leukocytosis with lymphocytopenia and heterophilia. Similarly, Umar et al.(2020) found a significant increase in the mean values of leukocytes and significantly increased heterophils with concurrent decrease in lymphocyte count in E. coli naturally infected birds when compared to age matched non infected birds. Tandal et al.(2019) revealed leukocytosis at 1st, 2nd and 3rd week post E. coli infection, heterophilia and significant decrease in lymphocytes at 1st and 2nd weeks post infection. Leukocytosis and heterophilia in E. coli infected birds could be due to subsequent inflammatory response to E. coli induced tissue damage (Patil, 2018).E. coli can induce marked lymphocyte depletion from bursa and thymus (Nakamura et al., 1990).

 

Propolis caused leukocytosis with significant increase in lymphocytes and significant decrease of heterophils. Attia et al.(2017) found that propolis significantly increased the leukocytes, lymphocytes, heterophil while decreasing H/L ratio when administered in poultry feed continuously or intermittently. Propolis supplementation significantly increased lymphocytes and significantly decreased heterophils and H/L ratio in broiler chickens and laying hens (Ziaran et al., 2005; Galal et al., 2008). Propolis has anabolic effect, stimulate immune response, activate mitosis, promotes lymphocyte proliferation and enlarge immune organs (Fan et al., 2013; Giuragea et al., 1981). On the other hand, Eyng et al.(2013) and Hassanet al.(2018)observed no differences in the number of lymphocytes, Heterophils, basophils and monocytes or H/L ratio at 21 and 42days after propolis supplementation at different doses in chicken feed.

 

In the current study,E. coli infection caused a significant decrease in the Newcastle antibody titer during the 3rd, 4th and 5th week of age. A higherNewcastle antibody titerwas observed in vaccinated non infected birds when compared to vaccinated and E. coli infected one (Hegazy et al., 2010;Hassanin et al., 2014; Awad et al., 2019). These results confirmed the immune suppressive effect of E. coli. Propolis supplementation increased the Newcastle antibody titer all over the experimental period while a significant increase was seen at the 2nd and 3rd week only in propolis supplemented group and at the 3rdweek of age in E. coli-propolis supplemented group. (Eyng et al., 2013; Eyng et al., 2015) found that supplementation of propolis did not influence the antibody titer against Newcastle disease vaccine while Mohamedet al.(2019) reported a significant increase in serum antibody titer in propolis supplemented group at 21, 28, 35, and 42 days of age. Supplementation of propolis continuously or intermittently in poultry feed significantly increase the antibody titter against Newcastle disease vaccine (Attia et al., 2017). Wang et al. (2004) and Taheri et al. (2005) reported the significant effect of propolis on serum antibody titer against NDV, AIV and IBDV and suggested that propolis may have a positive effect on humoral immunity.

 

As has been shown by this study, propolis supplementation was the most favorable among the groups either infected or not with highest protein content and the lowest fat content in the breast muscle when compared to control group. This agreed withHaščík et al. (2016)who reported high protein content (22.33±0.58 %) in breast muscle of broiler fed propolis 400 mg/kg of diet. El-Saadany (2017) mentioned that the beneficial effects of propolis on protein fractions may be due to its stimulating effect on the liver exhibiting an anabolic action favoring protein synthesis and its preserving effect to the body protein from degeneration. Also,it indicates a better retention of minerals (Ca, P), nitrogen and improved protein efficiency ratio (Khaksefidi, 2005).

 

Normal pH values were detected in all groups ranged from 5.76–6.50 and there were no significant difference between groups.Normal  pH indicate the good quality of the chicken meat  since the pH values were not below 5.4 and not above 7.0 when autolysis of meat appeared ,these results are all in agreement with those obtained by Gunya et al. (2019).pH has an effect on other attributes of meat such as color (Drażbo et al., 2019), texture (Toomer et al., 2019), shelf life, and loss during thermal processing (Janković et al., 2020).

 

As seen there was an increase on the moisture content of breastmuscles in G2and G3 groups when compared to G1 and G4 groups. The moisture content isconsidered an important factor for product sensorycharacteristics and this agreed withRabieet al. (2018) who reported high moisture content in breast muscle for broiler fed propolis 400 mg/kg diet by (78.3±0.9) andHaščík et al. (2016).The data on chemical composition of chicken breast meat were similar to those reported in previous studies, where various supplements were use.However, the data have shown positive effect of propolis on the chemical composition in breast muscle of the investigated parameters (in both propolis-supplemented groups) than those in the Ecoliinfected and control groups.

 

Bacterial contamination of broiler meat is mainlyconfined to the skin and/ or visceral cavity which occurs during washing, plucking and evisceration.Different bacterial genera were recovered from broiler meat(Odetunde et al., 2011).The colonization pattern of the gastrointestinal tract of broiler chickens by microorganisms might be affected by type of diet (Halliwell and Gutteridge, 2007).The anti-bacterial activity of propolis may be considered on two levels. First, it is connected with the direct action on the microorganism, and the other with stimulation of the immune system resulting in activation of natural defenses of the bird(Santos and González, 2017). This is in agreement with Bankovaet al. (1995) who examinedthe activity of different fractions of Brazilian propolis towards Staphylococcus aureus, and observedthat the antibacterial activity is mainly due to polarphenolic compounds.Melliouet al.(2007) reported that the volatiles of greek propolisinhibited four different species of Gram-negativebacteria (E. coli, E. cloacae, K. pneumoniae, P. aeruginosa). The ethanolic extract of Bulgarian propolisinhibited 90.9% of Gram-negative bacteria tested (Boyanova et al., 2006).Capasso, (2002) reportedthat propolis samples showed in vitro antimicrobial activity mainly against Gram-positive (Staphylococcus spp. and Streptococcus spp.)and Gram-negativebacteria (Escherichia coli, Klebsiella pneumoniae, Proteus vulgaris and Pseudomonas aeruginosa) (Bankova et al. 2007).

 

Propolis has different antibacterial mechanisms, including inhibition of cell division, collapsing microbial cytoplasm cell membranes and cell walls, inhibition of bacterial motility, enzyme inactivation, bacteriolysis, and protein synthesis inhibition (Fernandes Júnioret al., 2005). propolis exerts a bactericidal effects against Gram-positive microorganisms and a bacteriostatic effect against Gram-negative microorganisms and this difference could be attributed to variable cell wall and membrane structure of the corresponding organisms(Issamet al.,2018).It has been reoprted that the propolis had anti-microbial properties against a wide range of Gram-positive bacterial pathogens and a usual effect against Gram-negative organisms as well as its signifcant antiviral action is due to its high contents of bio-flavonoids (Kamboh et al., 2017). Propolis fights diseases caused by Salmonella, Staphylococcus aureus, or Escherichia coli (Hascik et al., 2012).Propolisalso had effect on normal gastrointestinal microflora which enhancing the beneficialbacteria and decreasing the pathogenic ones(Kačániová et al., 2012). Propolis, as a material composed to a large extent of plants secretions, is a rich source of cinnamic acid and esters. Many studies documented the antimicrobial activity of cinnamic acid against Vibrio spp., EcoliL.monocytogene,Mycobacterium tuberculosis, Bacillus spp., Staphylcoccus spp. Streptococcus pyogenes, Micrococcus flavusP. aeruginosaS.enterica  serotype Typhimurium, Enterobactercloacae and Yersinia ruckeri (Yilmaz et al., 2018).The way propolis exerts its antimicrobial action is complex and occur, among other things, through inhibition of the bacterial growth by inhibiting of its enzymatic activity diminishing their effects on biological systems (Zeighampour et al., 2014).

 

Sensory quality is crucial for consumer acceptance. Dietary supplementation is the key factor which can most easily be manipulated and has one of the most profound effects on sensory quality of meat (Joo et al., 2013).Sensory analysiseither by people measure appearance, aroma, color, tast, texture, and sound or instrumentsmeasure physical or chemical characteristics of a product that can relate to the sensoryexperience (Lyon et al., 2010).

 

In the present study organoleptic evaluation of the breast muscle were improved by addition of propolis to chicken feed.Color is one of the most important quality attributes, and is related to the functional properties of the meat, directly impacting consumer product selection and cooked product appearance. (Jianget al.,2017). Where propolis supplemented groups represent a significant effect on the breast muscle color when compared to E. coli infected and control groups, as demonstrated in other similar studies (Saláková et al., 2009; Sulcerová et al., 2011). The color of the meat is a feature that signifcantly determines its quality, as it is the first visual criterion for consumers to assess the appearance and attractiveness of meat. There by, the chicken breast muscle should be pink in color, and any deviation from this nuance is considered unacceptable to consumers(Garcia et al., 2010).Meat tenderness is defined by the ease of mastication, which involves initial penetration by the teeth, the breakdown of meat into fragments and the amount of residue remaining after chewing (Kong et al., 2008). The obtained results agreed with Haščík et al.(2015) who suggested that the dietary supplementation of propoliscould improve meat tenderness of broilers.Anyway, propolis has been shown as the most favourable  diet  supplement  in  order  to  get  good  meat tenderness  as  well  as  getting  the  lowest  roasting  losses.

 

The positive effect of propolis in improving sensory quality of chicken breast muscle in supplemented groups were corresponded with the findingofHaščíket al.(2011)who noted positive results of sensory evaluation of the breast of the Ross 308 chickens with the application of propolis extract in amount of 200, 300 and 400mg.kg-1 in the feed mixtures.

 

In the current study, cardiac lesionswere severe and diffuse in E. coli infected group. Similar results recorded by (Ghosh et al., 2006). While in E. coli-propolis supplemented group, lesions were mild and focal, that may be attributed to propolis conistituents (CAPE, chrysin, acacetin) which has a cardioprotective role against the toxic doxorubicin by inhibiting the oxygen free radicals (Marcucci et al.,2000; Shalamanyand Shivazad, 2006). Furthermore, propolis supplementation significantly reduces the concentration of triglycerides, cholesterol, nitric oxide, malonaldahyde, low density lipoproteins, and improves the levels of high density lipoprotein and superoxide dismutase activity which indicate that propolis could normalize the circulatory function (Huang et al., 2005; Nam et al.,2009).

 

Lung in E. coli infected group, showed degenerative changes in parenchyma, edema, haemorrhage and diffuse infiltration of inflammatory cells in the bronchus wall and parabronchial lumen, these results were supported by (Tonu et al.,2011). On the other side, lung was mostly normal in E. coli-propolis supplemented group, this may be due to caffeic acid phenethyl ester that showed a marked reduction in the infiltration of inflammatory cells within the peribronchiolar and perivascular regions(Hegaziand Abd El Hady, 2002).

 

Liver in E. coli infected group showed inflammatory and necrotic lesions, congested central vein and sinusoids with cellular infiltration around the portal area. These lesions may be due to E. coliendotoxin and vascular injury (Newairy and Abdou,2013). The hepatic coagulative necrosis attributed to tissue hypoxia occasioned by vascular compromise (Abalaka et al., 2017). Liver in E. coli- propolis supplemented group showed mild hepatocytic vacuolar degeneration and mild focal congestion as propolis consist of (phenolics, diterpenes and bio-flavinoids) which consider as a strong hepatoprotective conistituents against CCl4(carbon tetrachloride) which induces severe hepatocellular damage (Abd El Ghany and madian,2011), and the long term intake of propolis could prevent the liver degeneration (El-Khatib et al., 2002).

The small intestine is an important and vital organ responsible for the diet digestion and absorption of nutrients, any histological changes affect its function will affect the function of other organs and systems (Mahmoud et al., 2014). In the current study, the recorded lesions ofintestine in E. coli infected group were in the form of degeneration, necrosis and desquamation of mucosal epithelia associated withsevere inflammation, these results agree with Islam et al.(2003). Propolis supplemented groups showed marked increasing of intestinal villi length and width with intact epithelium and hyperplasia of intestinal glands comparing to control and E coli infected groups, which leading to increase the intestinal surface area and improve the nutrients absorption and improve the weight gain as explained byAhn et al. (2007).

 

Histopathological examination of E. coli-propolis supplemented group in all examined organs were mostly normal,these results explained by De Moura et al.(2011) andWoo et al.(2005) who reported that some propolis constituents (Quercetin, caffeic acid phenethyl ester(CAPE) and chrysin) have a mediating role against the chronic inflammation, by inhibiting gene expression of TNFα and reduces the synthesis of prostaglandis and leukotrienes. Moreover, propolis has the ability to inhibit the activation of NLRP3 inflamatory factors through decreasing the reactive oxygen species production and impair the expression of interleukin-1beta (Pushpavalli et al.,2010;Izuta et al.,2009).

 

In the current study, E. coli infected group showed a significant decrease in the immune reactive positive cells in spleen and bursa(CD79A), and in thymus(CD79A), these results supported by Abd El-Tawab et al.(2015) who recorded a significant decrease in phagocytic activity, phagocytic index and weight of bursa of Fabricius, thymus and spleen in E. coli infected broilers. Propolis supplemented groupsshowed  enhancement of lymphocytic proliferation in lymphoid organ compared to control group, that agree with Hegazi and Abd El Hady (2002) who reported that propolis supplementation reflect in the lymphoid organs development and weight, impacting on immune function and disease resistance ability.

 

CONCLUSION

 

Escherichia coli infection is a major worldwide proplem due to increasing antibiotic resistance and increasing the hazard of spreading antibiotic resistance genes. Propolis efficiently decreased the adverse effect of E. coliinfection, it decreased morbidity and mortality, increased significantly body weight and resulted in early recovery of E. coliinfection. Also, it enhanced the phagocytic activity and ND antibody production. Moreover, the diversity of chemical bioactive compounds of propolis are responsible for the growth promotor, immune-modulatory, antibacterial, antiviral, antifungal activity. Furthermore it gives propolis an additional advantage as antibacterial agent, the combination of different active ingredients with different concentrations prevents the bacterial resistance from occurring. It also improves the poultry meat quality. So the use of propolis as a natural supplement in poultry feed would be promising in poultry industry.

 

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تأثير البروبوليس على الاستجابة المناعية و جودة اللحم فى بدارى التسمين المعداه اصطناعيا بالميکروب القولونى

 

منى سعيد ابراهيم سليم ، نجلاء عباس الطيب عبدالحميد، هالة محمد اسماعيل حبيب

E-mail:dr_mona.saidibrahim@yahoo.com     Assiut University web-site: www.aun.edu.eg

 

تم اجراء هذه الدراسة لتقييم تأثير البروبوليس على معدل النمو والاستجابة المناعي وجودة اللحم فى بدارى التسمين المعداه اصطناعيا بالميکروب القولونى. تم تقسيم عدد 120 کتکوت عمر يوم عشوائيا إلى 4 مجموعات. المجموعة الأولى تحصل على عليقة أساسية بدون اضافات ومعداه بالميکروب القولونى عند عمر 5 أيام. المجموعة الثانية تحصل على عليقة اساسية مضاف إليها البروبوليس بمعدل 400مجم/کجم من العليقة و معداه بالميکروب القولونى عند عمر 5 أيام. المجموعة الثالثة تحصل على عليقة أساسية مضاف اليها البروبوليس بمعدل 400مجم/کجم من العليقة وغير معداه. المجموعة الرابعة تحصل على عليقة أساسية فقط وتعمل کمجموعة ضابطة. اظهرت المجموعات الى تتلقى البروبوليس زيادة معنوية فى الأوزان ، نقص فى معدل الوفيات، نقص معنوى فى معدل إعادة عزل الميکروب القولونى من الأعضاء الداخلية و الشفاء المبکر من الإصابة. أدى البروبوليس إلى تحسن معنوى فى معدل التهام الخلايا فى کلا من المجموعتين الثانية والثالثة وکذلک زيادة معنوية فى کرات الدم البيضاء مع زيادة الليمفوسايت ونقص فى الهتيروفيل. أدى البروبوليس إلى تحسن فى رد الفعل المناعى لتحصين النيوکاسيل فى کلا من المجموعتين الثانية والثالثة. أظهرت المجموعات المعاملة بالبروبوليس زيادة فى نسبة البروتين ونقص نسبة الدهون فى صدور الدجاج وکذلک نقص معنوى فى الحمل البکتيرى عند مقارنتها بالمجموعة الأولى و الرابعة.

 
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