MOLECULAR CHARACTERIZATION OF STREPTOCOCCUS AND ENTEROCOCCUS SPECIES ISOLATED FROM BROILER CHICKENS

Document Type : Research article

Authors

1 Bacteriology, Mycology and Immunology Department, Faculty of Veterinary Medicine, Beni-Suef University, Beni-Suef 62511, Egypt.

2 Poultry Diseases Department, Faculty of Veterinary Medicine, Beni-Suef University, Beni-Suef 62511, Egypt.

Abstract

Streptococcus and Enterococcus infections in chickens may result in significant negative effect on economy. In the current study, the prevalence of Streptococcus and Enterococcus species was planned in different broiler chickens farms in Beni-Suef Governorate. A total of 272 samples were collected from lesions (septicemic organs, enlarged organs, necrotic focci) of the affected organs including heart, lung, liver and kidney of diseased broiler chickens and freshly dead ones. Out of 272 samples a total of 49 isolates were recovered with incidence of 18% including 26Streptococcus spp. (53.1%) and 21 Enterococcus spp. (42.8%) meanwhile 2 isolates (4.1%) were unidentified. Streptococcus isolates were identified as S.gallinaceous (24.5%), S. dysgalactiae (16.3%) and S. durans (12.2%). Meanwhile all Enterococcus isolates were identified as E. faecalis. The in-vitro antibiotic sensitivity testing showed that all isolates were highly sensitive to amoxicillin (77.6%), sulfamethoxazole-trimethoprim (73.5%) and amoxicillin-clavulanic acid (65.3%). Meanwhile, all isolates were resistant to cephalexin, cefotaxime sodium, cefipime, cefotriaxone, tetracycline, kanamycin and apramycin while 87.8 and 63.2% of isolates showed resistance aganist gentamicin and enrofloxacin, respectively. Moreover, multidrug resistant were detected in all isolates. Polymerase chain reaction (PCR) was applied to identify 4 resistance-associated genes including (tetO, aac(6')aph(2''), blaZ and Pbp < /em>1A) as well as 6 virulence-associated genes including (cylE, brp < /em>A, hyl, cylA, asa1 and gelE). The results indicated that tetO, aac(6')aph(2''), blaZ, Pbp < /em>1A, cylE, brp < /em>A, cylA and asa1 genes were recovered from all the tested isolates (100%). Meanwhile, none of streptococcus isolates had hly gene also, gelE gene not detected in enterococcus isolates.

Keywords

Main Subjects


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

 

MOLECULAR CHARACTERIZATION OF STREPTOCOCCUS AND ENTEROCOCCUS SPECIES ISOLATED FROM BROILER CHICKENS

 

AHMED H. ABED 1; ASMAA S. A. SEDIK 1 AND SALAMA A. S. SHANY 2

1 Bacteriology, Mycology and Immunology Department, Faculty of Veterinary Medicine, Beni-Suef University, Beni-Suef 62511, Egypt.

2 Poultry Diseases Department, Faculty of Veterinary Medicine, Beni-Suef University, Beni-Suef 62511, Egypt.

 

Received: 19 September 2021;     Accepted: 3 October 2021

 

 

ABSTRACT

 

Streptococcus and Enterococcus infections in chickens may result in significant negative effect on economy. In the current study, the prevalence of Streptococcus and Enterococcus species was planned in different broiler chickens farms in Beni-Suef Governorate. A total of 272 samples were collected from lesions (septicemic organs, enlarged organs, necrotic focci) of the affected organs including heart, lung, liver and kidney of diseased broiler chickens and freshly dead ones. Out of 272 samples a total of 49 isolates were recovered with incidence of 18% including 26Streptococcus spp. (53.1%) and 21 Enterococcus spp. (42.8%) meanwhile 2 isolates (4.1%) were unidentified. Streptococcus isolates were identified as S.gallinaceous (24.5%), S. dysgalactiae (16.3%) and S. durans (12.2%). Meanwhile all Enterococcus isolates were identified as E. faecalis. The in-vitro antibiotic sensitivity testing showed that all isolates were highly sensitive to amoxicillin (77.6%), sulfamethoxazole-trimethoprim (73.5%) and amoxicillin-clavulanic acid (65.3%). Meanwhile, all isolates were resistant to cephalexin, cefotaxime sodium, cefipime, cefotriaxone, tetracycline, kanamycin and apramycin while 87.8 and 63.2% of isolates showed resistance aganist gentamicin and enrofloxacin, respectively. Moreover, multidrug resistant were detected in all isolates. Polymerase chain reaction (PCR) was applied to identify 4 resistance-associated genes including (tetO, aac(6')aph(2''), blaZ and Pbp1A) as well as 6 virulence-associated genes including (cylE, brpA, hyl, cylA, asa1 and gelE). The results indicated that tetO, aac(6')aph(2''), blaZ, Pbp1A, cylE, brpA, cylA and asa1 genes were recovered from all the tested isolates (100%). Meanwhile, none of streptococcus isolates had hly gene also, gelE gene not detected in enterococcus isolates.

 

Keywords:Streptococci, Enterococci, Broiler chickens, Resistance genes, Virulence genes.

 

 


INTRODUCTION

 

The poultry industry is considered one of main sources of animal protein (meat and

 


Corresponding author: Asmaa S.A. Sedik

E-mail address: asmaa.saad91@yahoo.com

Present address: Bacteriology, Mycology and Immunology Department, Faculty of Veterinary Medicine, Beni-Suef University, Beni-Suef 62511, Egypt.

egg) to man also it is a good source of  manure for crops. (Mohammed and Sunday, 2015). Streptococci and Enterococci are intestinal inhabitants of birds and mammals and they may accidentally enter circulation and causing disease in poultry (Smyth and McNamee, 2001). Streptococci are Gram-positive cocci, arranged in short chains catalase-negative organisms. Recently more than 40 species are documented, most of these species are contributed with causing disease in human and animals (Collins et al., 2001). Enterococci are Gram-positive cocci facultative anaerobes  and non sporulated also, they are able to hydrolyze esculin in the presence of bile salts, and are catalase negative (Dubin and Pamer, 2017). Since 2000, several new species have been identified and currently more than 50 species of streptococci and at least 21 species of enterococci are recognized and the most common species isolated from poultry are Streptococcus gallinaceus, Streptococcus zooepidemicus, Enterococcus durans, Enterococcus faecalis and Enterococcus hirae (Smyth and McNamee, 2001).

 

In chicken husbandry, antimicrobial agents used for treatment and growth promotion in broilers more than layers, so resistant enterococci usually  recovered from broilers (Klare et al., 1995; Butaye et al., 1999). Enterococcus isolates from poultry subsequently acquired resistance against macrolides, chloramphenicol, β-lactams, and tetracycline has been described (Maasjost et al., 2015). High resistance to aminoglycosides recorded in Enterococci found related to different genes such as (aac(6′) aph(2′′), ant(6))  (Hegstad et al., 2010).Moreover, tetM and tetO were the most common tetracycline resistance genes detected in different Streptococcus species(Oppegaard et al., 2020). Some recent studies established that, the genes encoding certain Enterococcus virulence factors such as asa1, gelE and cylA in addition to different antibiotic resistance genes are associated with causing nosocomial infection (Ngbede et al., 2017). The present study was designed for detection of genotypic characterization of Streptococcus and Enterococcus species isolated from broiler chickens achieved by determination of some virulence and antimicrobial resistance associated genes in the MDR isolates using PCR technique.

 

MATERIALS AND METHODS

 

1. Ethical approval

The present study was approved by the Institutional Animal Care and Use committee Beni-Suef University (BSU-IACUC, 021-191), Egypt.

 

2. Chicken Samples

A total of 272 pooling samples were aseptically collected from 272 diseased broiler chickens aged from 2-5 weeks from different farms in Beni-Suef Governorate during duration from December 2018 untill December 2019. The pooling samples were collected aseptically from lesions (septicemic organs, enlarged organs, necrotic focci) in the internal organs; liver, lung, heart, and kidney of diseased slaughtered chickens and freshly dead ones.

 

3. Bacteriological isolation

Isolation of both Streptococci and Enterococci was done according to Collee et al. (1996) and Quinn et al. (2002).

 

4. Identification of Streptococci and Enterococci isolates

4.1. Morphological identification

Pure culture from each isolate was identified morphologically according to its staining reaction, shape, size, and arrangement. these colonies that revealed to be Gram positive cocci  medium  size  and non- sporulated were further examiened biochemically.

 

4.2. Biochemical identification

1. catalase test: used to differentiate between catalase positive and catalase ngative cocci. Colonies which revealed to be catalase negative were further examiened.  

 

2. Other non-biochemical tests: were performed on catalase negative colonies including,

  • · growth on MacConkey agar
  • cultivation on bile aesculin agar  
  • · detection of hemolytic activity of isolates using sheep blood agar (7%) this was done according to Collee et al. (1996).

 

4.3. Biochemical identification of isolates using Vitek2 compact system: (Using ID-GP kits) according to (BioMérieux, 2013)

The Vitek2 compact system using ID-GP (Gram positive cocci) identification kits was applied on pure cultures for complete identification according to BioMérieux (2013).

 

5. Antibiograms sensetivity testing

The isolated Enterococci and Streptococci were investigated for their susceptibility aganist 12 different antimicrobial agents of veterinary and human significance. Antimicrobial discs included amoxicillin (10μg), apramycin (15μg), cefotaxime sodium (30μg), ceftriaxone (30μg), cephalexine (30μg), cefepime (30μg), enrofloxacin (5μg), sulphamethoxazol-trimethoprim (25μg), amoxicillin-clavulanic (30μg), tetracycline (30μg), gentamicin (10μg) and kanamycin (30μg). All antimicrobial discs used in this study were obtained from (Oxoid, Basing Stoke, UK). Antimicrobial susceptibility profiling and reults interpretation were performed according to (CLSI, 2019). Resistance to more than three antimicrobials of different classes was recorded as multidrug resistance (MDR) according to Chandran et al. (2008).

 

6. Polymerase chain reaction (PCR) for Streptococcus and Enterococcus isolates

PCR used for detection 3 resistance-associated genes (tetO,aac(6')aph(2'') and pbp1A) and 3 virulence-associated genes (cylE, hyl and brpA) in 3 streptococci isolates. Moreover, it was applied on 3 enterococcus isolates for detection of 3 resistance genes (tetO,aac(6')aph(2'') and blaZ) and 4 virulence genes (hyl, cylA, Asa1 and gelE). Extraction of Genomic DNA was done by using QIAamp DNA extraction Mini prep Kit. Extracted DNA was stored at -80˚C for later using in PCR amplification. Table (1) reveals the used Primers sequences and amplified products for the targeted genes for Streptococcus and Enterococcus isolates. Cycling conditions (temperature & time) of the primers during PCR were displayed in table (2).


 

Table 1: Primers of virulence and resistance genes used in PCR.

Reference

Length of amplified product

Primer sequence

(5'-3')

Gene

Bacteria

Vankerckhoven

et al., 2004

276 bp

ACAGAAGAGCTGCAGGAAATG

hyl

Enterococcus spp.

GACTGACGTCCAAGTTTCCAA

688 bp

ACTCGGGGATTGATAGGC

cylA

GCTGCTAAAGCTGCGCTT

213 bp

TATGACAATGCTTTTTGGGAT

gelE

AGATGCACCCGAAATAATATA

375 bp

GCACGCTATTACGAACTATGA

asa1

TAAGAAAGAACATCACCACGA

Duran et al., 2012

 

173 bp

ACTTCAACACCTGCTGCTTTC

blaZ

TGACCACTTTTATCAGCAACC

491 bp

GAAGTACGCAGAAGAGA

aac(6')aph(2'')

Enterococcus and Streptococcus spp.

ACATGGCAAGCTCTAGGA

Malhotra-Kumar

et al. 2005

515 bp

AACTTAGGCATTCTGGCTCAC

tetO

TCCCACTGTTCCATATCGTCA

Alves-Barroco

et al., 2019

534 bp

TGA AGC TAA GTT GAA TGC TGC

brpA

Streptococcus spp.

GAA CCA CCA TCA GAC AAG GT

Mosleh et al., 2014

430 bp

AAACAAGGTCGGACTCAACC

pbp1A

AGGTGC­TACAAATTGAGAGG

Krishnaveni

et al., 2014

950 bp

CATACC TTAACAAAGATATATAACAA

hyl

AGATTTTTTAGAGAATGAGAAGTTTTTT

Bergseng et al., 2007

248 bp

TGACATTTACAAGTGACGAAG

cylE

TTGCCAGGAGGAGAATAGGA

 

 

Table 2: Cycling conditions of the different primers during PCR.

 

Bacteria

Gene

Primary denaturation

Secondary denaturation

Annealing

Extension

No. of cycles

Final extension

Enterococcus spp.

Hyl

94˚C/ 5 min.

94˚C/ 30 sec.

55˚C/30 sec

72˚C/30sec.

35

72˚C/7 min.

cylA

94˚C/5 min.

94˚C/30 sec.

50˚C/40 sec

72˚C/45sec.

35

72˚C/10 min.

gelE

94˚C/5 min.

94˚C/30 sec.

50˚C/30 sec

72˚C/30sec.

35

72˚C/7 min.

Asa1

94˚C/5 min.

94˚C/30 sec.

53˚C/40 sec

72˚C/40sec.

35

72˚C/10 min.

blaZ

94˚C/5 min.

94˚C/30 sec.

54˚C/30 sec

72˚C/30sec.

35

72˚C/7 min.

Enterococcus and streptococcus spp.

aac(6')aph(2'')

94˚C/5 min.

94˚C/30 sec.

54˚C/40 sec

72˚C/40sec.

35

72˚C/10 min.

tetO

94˚C/5 min.

94˚C/30 sec.

56˚C/40 sec

72˚C/45sec.

35

72˚C/10 min.

Streptococcus spp.

brpA

94˚C/5 min.

94˚C/30 sec.

42˚C/40 sec

72˚C/45sec.

35

72˚C/10 min.

Pbp1A

94˚C/5 min.

94˚C/30 sec.

57˚C/40 sec

72˚C/45sec.

35

72˚C/10 min.

Hyl

94˚C/5 min.

94˚C/30 sec.

52˚C/40 sec

72˚C/50sec.

35

72˚C/10 min.

cylE

94˚C/5 min.

94˚C/30 sec.

55˚C/30 sec

72˚C/30sec.

35

72˚C/7 min.

 


RESULTS

 

1. Prevalence of bacterial isolation from different samples

Out of 272 samples from broiler chickens, a total of 49 bacterial isolates suspected (morphologically and by biochemical tests) to be streptococci or enterococci were recovered; with a total prevalence of 18%.

 

According to Vitek2 compact system, the bacterial isolates were arranged as 26 Streptococcus spp. (53.1%) and 21 Enterococcus spp. (42.8%) while there were 2 unidentified isolates (4.1%). Streptococcus isolates (n= 26) were identified as 12 S. gallinaceous (24.5%), 8 S. dysgalactiae (16.3%) and 6 S. durans (12.2%). On the other hand, all Enterococcus isolates (n=21) were identified as E. faecalis (Table 3).

 

 

Table 3: Prevalence of Streptococcus and Enterococcus isolated from the diseased broiler chickens.

 

Genus                                   Species

Isolation

No.

%

Streptococcus

S. gallinaceous

S. dysgalactiae

S. durans

12

8

6

24.5

16.3

12.3

Total

26

53.1

Enterococcus

E. faecalis

21

42.8

Unidentified

2

4.1

Total isolates

49

100

%: was calculated according to the corresponding number (No.) of isolates

 


2. Antibiogram sensetivity testing

The in-vitro antimicrobial susceptibility testing revealed that the tested isolates (n=49) showed high sensitivity to amoxicillin (77.6%), sulfamethoxazole-trimethoprim (73.5%) and amoxicillin-clavulanic acid (65.3 %). On the other hand, they were completely resistant to cephalexin, cefotaxime, cefipime, cefotriaxone, tetracycline, kanamycin and apramycin (100% for each) and were highly resistant to gentamicin (87.8%) and enrofloxacin (63.2%) (Table 4). More over, all investigated isolates showed presence of multidrug resistance.



 

Table 4: Results of in-vitro antimicrobial susceptibility testing of recovered isolates.

Antimicrobial type

Symbol

Disc content (µg)

Tested isolates (n= 49)

R

I

S

No

%

No

%

No

%

Amoxicillin-clavulanic acid

AMC

30

17

34.7

0

0

32

65.3

Cephalexin

CL

30

49

100

0

0

0

0

Cefotaxime

CTX

30

49

100

0

0

0

0

Cefipime

FEP

30

49

100

0

0

0

0

Cefotraxione

CRO

30

49

100

0

0

0

0

Enrofloxacin

ENR

5

31

63.2

9

18.4

9

18.4

Tetracyclin

TE

30

49

100

0

0

0

0

Gentamicin

CN

10

43

87.8

1

2

5

10.2

Sulfamethoxazole- trimethoprim

SXT

25

11

22.4

2

4.1

36

73.5

Kanamycin

K

30

49

100

0

0

0

0

Apramycin

APR

15

49

100

0

0

0

0

Amoxicillin

AML

10

11

22.4

0

0

38

77.6

% was calculated according to the number of the tested isolates (n=49).

                                                                    


3. Polymerase chain reaction (PCR) analyses of streptococcus and enterococcus isolates

Concerning Streptococcus isolates (n=3), all the tested resistance associated genes (tetO,aac(6')aph(2'') and pbp1A) were detected in all the tested isolates (n=3; 100%). On the other hand, among the tested virulence genes; cylE and brpA genes were detected in all the tested isolates (n=3; 100%) while hyl gene was not found in any isolates (Table 5 and Figs. 1, 2& 3).

 

 

Table 5: Distribution and prevalence of resistance and virulence -associated genes in the examined Streptococcus isolates.

            Gene

Sample

Resistance genes

Virulence genes

tetO

aac(6')aph

(2'')

pbp1A

cylE

hyl

brpA

1

+

+

+

+

-

+

2

+

+

+

+

-

+

3

+

+

+

+

-

+

Total (%)

3 (100%)

3 (100%)

3 (100%)

3 (100%)

0 (0%)

3 (100%)

%: was calculated according to the number (No.) of the tested isolates (n=3).

 

 

Moreover, it was applied on 3 enterococcus isolates for detection of 3 resistance genes (tetO,aac(6')aph(2'') and blaZ) and 4 virulence genes (hyl, cylA, Asa1 and gelE).

 

Regarding Enterococcus isolates (n=3), all the tested resistance genes (tetO,aac(6')aph(2'') andblaZ) were detected in all the tested isolates (n=3; 100%). On the other hand, among the tested virulence genes; hyl, cylA and Asa1 genes were detected in all the tested isolates (n=3; 100%) while gelE gene was not found in any isolates (Tables 6 and Figs. 1, 2, 4, 5& 6).

 

 

Table 6: Distribution and prevalence of resistance and virulence -associated genes in the examined Enterococcus isolates.

         Gene                  

 

Sample

Resistance genes

Virulence genes

tetO

aac(6')aph(2'')

blaZ

hyl

cylA

Asa1

gelE

1

+

+

+

+

+

+

-

2

+

+

+

+

+

+

-

3

+

+

+

+

+

+

-

Total (%)

3 (100%)

3 (100%)

3 (100%)

3 (100%)

3 (100%)

3 (100%)

0 (0%)

%: was calculated according to the number (No.) of the tested isolates (n=3).

   

Fig. (1): PCR amplification of the 515 bp fragment of tetO resistance gene from 3 Streptococci (S1-S3) and 3 Enterococci (E1-E3) showing positive amplicons migrates with the molecular DNA size ladder (L)., P (control positive), and N (control negative).

Fig. (2): PCR amplification of the 491 bp fragment of aac(6') aph(2'') resistance gene from 3 Streptococci (S1-S3) and 3 Enterococci (E1-E3) showing positive amplicons migrates with the molecular DNA size ladder (L)., P (control positive), and N (control negative).

 

 

Fig. (3): PCR amplification of the 534 bp fragment of brpA resistance gene and 248, 950 and 430 bp fragments of cylE, hyl and pbp1A virulence genes, respectively, from 3 Streptococci (S1-S3) showing positive amplicons migrates with the molecular DNA size ladder (L)., P (control positive), and N (control negative).

 

   

Fig. (4): PCR amplification of the 173 bp fragment of blaZ resistance gene from 3 Enterococci (E1-E3) showing positive amplicons migrates with the molecular DNA size ladder (L)., P (control positive), and N (control negative).

Fig. (5): PCR amplification of the 213 and 688 bp fragments of  gelE and cylA virulence genes, respectively, from 3 Enterococci (E1-E3) showing positive amplicons migrates with the molecular DNA size ladder (L)., P (control positive), and N (control negative).


 

Fig. (6): PCR amplification of the 276 and 375 bp fragments of hyl and asa1 virulence genes, respectively, from 3 Enterococci (E1-E3) showing positive amplicons migrates with the molecular DNA size ladder (L)., P (control positive), and N (control negative).

 


DISCUSSION

 

Agreat attention has been paid to poultry-based industries due to its importance as a source of animal protein in Egypt. Poultry are regarded the most appropriate source of animal protein supply of high nutritive value for humans all over the world. This is due to the efficiency cost of production.

 

Infectious diseases such as (Streptococci and Enterococci) are important in the broiler industry due to high mortality, retardation of growth, as well as the preventive and therapeutic use of antimicrobials. Moreover, economic losses may result from the loss of uniformity of the flock and condemnations in the slaughterhouse (McKissick, 2006). Streptococcus and Enterococcus  are considered to cause  disease in human and animals (Collins et al., 2001). Also, the enterococci are important agents in human nosocomial infections (Cardona et al., 1993). Streptococcus and Enterococcus have been considered as normally inhabitant, Gram-positive fastidus microorganisms of chickens. Additionally, they may cause disease conditions as endocarditis and urinary tract, intra- abdominal infections in broilers. (Tankson et al., 2001). In the present study, the incidence of Streptococci and Enterococci were identified in broilers in Beni Suef Governorate. The data illustrated in the table (3) revealed that the total prevalence of Streptococcus and Enterococcus speciesin the diseased broiler chickens was 18% where 49isolates were recovered from 272 diseased broiler chickens. According to Vitek2 compact system, the bacterial isolates were arranged as 26 Streptococcus spp. (53.1%) and 21 Enterococcus spp. (42.8%) and isolates while there were 2 unidentified isolates (4.1%). Streptococcus isolates (n= 26) were identified as 12 S. gallinaceous (24.5%), 8 S. dysgalactiae (16.3%) and 6 S. durans (12.3%). On the other hand, all Enterococcus isolates (n=21) were identified as E. faecalis. These results were higher than those recovered by Cauwerts et al. (2007) who found E. faecalis with  a prevalence  rate of 13.6% in broilers, Diarra et al. (2010); who remarked that prevalence rate of E.faecalis  was 10.1%.While the lowest result recorded by (Chadfield et al., 2004) who collected 227 samples from broiler chickens  and recovered 15 E. faecalis isolates (6.6%). Also, Aslantaş (2019) isolated E.durans with prevalence of 2.4% and Cauwerts et al. (2007) who recorded E. durans with prevelace of 9.5%. Results in present study was noted to be less than those recorded by (Chadfield et al., 2004) who documented S. gallinaceous with prevelace of 37.4%  and Abd El-Hafeez et al. (2018) who recorded S. dysgalactae with prevalace rate 34.7%. Higher rates of isolation were achived by Petersen et al. (2008); 77.5%, and 46.5%. Meanwhile, much higher prevalence was recorded by Aslantaş (2019); 87.8%.

 

In poultry rearing Antimicrobials are used for treatment infecous microbial diseases also they play an important role in growth promotion. Its exessive use in animal production leads to spread of antibiotic resistance (Gosh and LaPara 2007). In-vitro antimicrobial suscebtibility testing of different veterinary pathogens helps the veterinarian in the choice of the most suitable drug for treatment (Radwan et al., 2016). In the present study, the isolated Enterococci and Streptococci were investigated for their susceptibility aganist 12 different antimicrobial agents of veterinary and human significance. The in-vitro antibiogram sensetivity testing results for both Streptococcus and Enterococcus isolates were showed in table (4). Isolates were highly sensitive to amoxicillin (77.6%) followed by sulfamethoxazole- trimethoprim (73.5%) and amoxicillin- clavulanic acid (65.3 %). Meanwhile, they were completely resistant to cephalexin, cefotaxime sodium, cefipime, cefotriaxone, tetracyclin, kanamycin and apramycin (100%) and were highly resistant to gentamicin (87.8%) and enrofloxacin (63.2%). Also, growing of resistance was observed by the intermediate behavior of the tested isolates against the tested antimicrobial agents. The percentages of the intermediate zones were 2, 4.1 and 18.4 % against gentamicin, trimethoprim- sulfamethoxazole and enrofloxacin, respectively. Additionally, multidrug resistance was detected in all tested isolates. Higher prevelance rates of resistance were reported against tetracycline and kanamycin by Diarra et al. (2010) 91.3, 59.4% ; (Tremblay et al., 2011) 95.6, 25.2% and Nowakiewicz et al. (2017) 60.5, 42.1%, respectively. Also, Hershberger et al. (2005) recorded resistance against gentamicin in 32% of isolates. On the other hand, Rehman et al. (2018); Aslantaş (2019); Obeng et al. (2013) and Liu et al. (2013) reported closely matching resistance rates with those detected in present study. B eacuse of misuse antmicrobials which might leads to high resistance rates, it was difficult to found an effective drug aganist the Streptococci and Enterococci infections. (Sharada et al., 2001). More over, all investigated isolates showed presence of multidrug resistance. Our results were nearly similar to previous reports all over the world. Aslam et al. (2012) founded that multidrug resistance were detected in 91% of isolates. Meanwhile, lower percentages of MDR were recorded by Nowakiewicz et al. (2017); 56.8% and (Ngbede et al., 2017); 53.1%.

 

In the present study, PCR was used for detection of 3 resistance-associated genesincluding resistance to tetracycline (tetO), resistance to aminoglycosides (aac(6')aph(2'') and resistance to β-lactams (pbp1A) in 3 Streptococcus isolates. Moreover, it was applied on 3 Enterococcus isolates for detection of 3 resistance genes including (tetO, aac(6')aph(2'') and blaZ). The data illsturated in (tables 5-6 and Figs. (1:4) revealed that 100% of the tested isolates harbored teto, (aac(6')aph(2'') genes on the other hand 100% of streptococci isolates harbored (Pbp1A) gene also, (blaZ) gene were detected in all investigated  Enterococci isolates. 

 

Many genes were detected for tetracycline resistance including tetK, tetL, tetM and tetO genes Ngbede et al. (2017). Tet(O) gene which resposible for tetracycline resistance was detected in enterococci isolated from broilers  byAarestrup et al. (2000) and, when studing  tetracycline resistance determinants in raw food, Wilcks et al. (2005) founded that  this gene only occur in enterococci isolated from poultry meat. Also, this gene has been described in human E. faecalis, but is rare Aarestrup et al. (2000). The efflux proteins have been the best studied of the Tet determinants including tetA, tetB, tetC, tetD, tetE, tetG, tetH, tetK, tetL and tetA(P) genes which have been identified. All of the following Tet determinants (tetA, tetB, tetC, tetD, tetE) protected the bacterial ribosomes because they ecoded for energy-dependent membrane associated proteins which release tetracycline out of the cell reducing the intercellular tetracycline concentration (El-Seedy et al. 2019). Regarding the obtained results of tetO which was detected in all tested isolates (100%), they were higher than those recorded by Cauwerts et al. (2007) who found tetO and tetM in 30% of tested isolates. Meanwhile, much lower prevalence was recorded by Diarra et al. (2010) who founded that 7.2% of tested isolates harbored tetO also, tetL and tetM were detected in 57.15% of isolates. Moreover, (Tremblay et al., 2011; Ngbede et al., 2017; Nowakiewicz et al., 2017) detected this gene in Enterococci isolates from broilers. On the other hand, the obtained results of aminoglycosides resistance encoding gene (aac(6')aph(2'')) which is detected in all tested isolate (100%), were higher than those obtained by Diarra et al. (2010) who found (aac(6')aph(2'')) gene in 30.4% of tested isolates. Also, Rehman et al. (2018) recorded (aac(6')aph(2'')) gene in 8.3% of Enterococci isolates from broilers.

 

 In the present  study, PCR was applied on 3 MDR  Streptococci and 4 Enterococcci   isolates  to detect the following virulence associated genes including β-haemolysin cytolysin gene (cylE), hyalurinidase encoded by (hly)andbiofilm production (brpA) for Streptococci isolates. Also, the following genes asa1 (aggregation substance), which associated with adherence and conjugation; cylA encodes (cytolysin-haemolysin) which lyses red blood cells, hly (hyalurindase) while gelatinase, encoded by (gelE) which can hydrolyze gelatin,  were investigated in Enterococci isolates  using PCR. The results illustrated in tables (5-6) and Figs. (3, 5& 6) revealed that all the tested isolates (100%) harbored both cylE and brpA genes meanwhile no isolates (0%) harbored hly gene in case of Streptococci isolates. On the other hand, all Enterococci tested isolates (100%) harbored asa1, cylA and hly genes meanwhile no isolates (0%) harbored gelE gene. Regarding the obtained results of cylA and cylE which were detected in all tested isolates (100%), this result was higher than those recorded by Diarra et al. (2010) who found cylA and cylB genes in 28.5 % of tested isolates. Also, Ngbede et al. (2017) recorded cylA gene in 28.3% of tested isolates. Meanwhile, Song et al. (2019) found cylA in 16% isolates. The lower prevelances were recorded by (Champagne et al., 2011) who detected cylA and cylB in 6% of isolates and Aslantaş (2019) who found cylA in 0.7 %. On the contrary, Nowakiewicz et al. (2017) reported that none of tested isolates (0%) exhibeted genes responsible for haemolysin – cytolysin production. Regarding the obtained results of gelE which were not detected in any tested isolate,this result is lower than those detected by Ngbede et al. (2017) who found gelE gene in 11.3 % and Aslantaş (2019) recorded this gene in 40.3% of tested isolates. While (Diarra et al., 2010; Champagne et al. 2011; Nowakiewicz et al., 2017) recorded gelE in 100% of investegated isolates. Regarding the obtained results of asa1 gene which was found in all investigated isolates (100%). This result is higher than those recorded by Aslantaş (2019) who found asa1 gene in 6.1% of isolates. While   Song et al. (2019) found asa1 gene in 44% of tested  isolates.

 

CONCLUSION

 

Streptococcus and Enterococcus spp. are important infectious agents which can cause disease in broilers, and affect on morbidity and mortality rates. The exessive use of antibiotics resulting in multidrug resistance pathogens and this is considered a great problem. The in-vitro antimicrobial sensetivity testing revealed that all tested isolates were highly sensitive to amoxicillin, sulfamethoxazole- trimethoprim and amoxicillin- clavulanic acid meanwhile they  were completely resistant to cephalexin, cefotaxime, cefipime, cefotriaxone, tetracycline, kanamycin and apramycin. All the testedisolates were MDR. PCR results revealed  that tetO, aac(6')aph(2''), blaZ, pbp1A, cylE, brpA, cylA asa1 genes were detected in all the investigated  isolates meanwhile, hyl gene was not detected in any Streptococcusisolates and gelE gene was not detected in Enterococcus isolates.

 

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Aslam, M.; Diarra, M.S.; Checkley, S.; Bohaychuk, V. and Masson, L. (2012): Characterization of antimicrobial resistance and virulence genes in Enterococcus spp. isolated from retail meats in Alberta, Canada. International Journal of Food Microbiology, 156(3), 222-230.‏

Aslantaş, Ö. (2019): Molecular and phenotypic characterization of enterococci isolated from broiler flocks in Turkey. Tropical Animal Health and Production, 51(5), 1073–1082.

Bergseng, H.; Bevanger, L.; Rygg, M. and Bergh, K. (2007): Real-time PCR targeting the sip gene for detection of group B Streptococcus colonization in pregnant women at delivery. Journal of medical microbiology, 56(2), 223-228.‏

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Cardona, C.J.; Bickford, A.A.; Charlton, B.R. and Cooper, G.L. (1993): Enterococcus durans infection in young chickens associated with bacteremia and encephalomalacia. Avian diseases, 234-239.‏

Cauwerts, K.; Decostere, A.; De Graef, E.M.; Haesebrouck, F. and Pasmans, F. (2007): High prevalence of tetracycline resistance in Enterococcus isolates from broilers carrying the erm(B) gene. Avian Pathology, 36(5), 395–399.

Chadfield, M.S.; Christensen, J.P.; Christensen, H. and Bisgaard, M. (2004): “Characterization of Streptococci and Enterococci Associated with Septicaemia in Broiler Parents with a High Prevalence of Endocarditis.” Avian Pathology 33(6): 610–17.

Champagne, J.; Diarra, M.S.; Rempel, H.; Topp, E.; Greer, C.W.; Harel, J. and Masson, L. (2011): Development of a DNA microarray for enterococcal species, virulence, and antibiotic resistance gene determinations among isolates from poultry. Applied and Environmental Microbiology, 77(8), 2625-2633.‏

Chandran, A.; Hatha, A.A.M.; Varghese, S. and Sheeja, K.M. (2008): Prevalence of multiple drug resistant escherichia coli serotypes in a tropical estuary, India. Microbes and Environments, 23(2), 153–158.

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Diarra, M.S.; Rempel, H.; Champagne, J.; Masson, L.; Pritchard, J. and Topp, E. (2010): Distribution of antimicrobial resistance and virulence genes in Enterococcus spp. and characterization of isolates from broiler chickens. Applied and Environmental Microbiology, 76(24), 8033-8043.‏

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التوصيف الجزيئيللمکورات السبحية والمعويةالمعزولة من دجاج التسمين

 

أحمد حسين عابد، أسماء سعد عبد الصادق صديق ، سلامه أبوحمرة سيد شانى

 

E-mail:  asmaa.saad91@yahoo.com      Assiut University web-site: www.aun.edu.eg

 

قد تؤدي عدوى المکورات السبحيه والمکورات المعوية في الدجاج إلى خسائر اقتصادية کبيرة. في الدراسة الحالية تمت دراسة انتشار المکورات السبحية والمکورات المعوية في مزارع دجاج التسمين المختلفة بمحافظة بني سويف. تم جمع 272 عينة من الأعضاء الداخلية المصابة متضمنة القلب والرئة والکبد والکلى لدجاج التسمين المذبوحة والميتة حديثاً. تم الاهتمام بعزل الاعضاء التى تحمل الآفات التشريحية الاتية: البؤر النخرية في الکبد وتضخم الکلى والتهاب الکلية والأعضاء الداخلية التى تعانى من تسمم الدم. من خلال الفحص البکتريولوجي للعينات تم عزل 49 عزلة إيجابية باجمالى معدل انتشار 18٪ . تم التعرف على العزلات باستخدام الاختبارات البيوکيميائية (catalase test  ( ووايضا تم زرع العزلات على أوساط مختلفة (MacConkey agar , bile aesculin agar,    sheep blood agar ) للتعرف على خصائصها . کما أنه تم تصنيف العزلات باستخدام Vitek2 compact system الى26 Streptococcus spp.          ( (53.1٪ و 21 Enterococcus spp. ( (42.8٪ بينما 2 عزلة (4.1٪) لم يتم التعرف عليها. تم التعرف على عزلات المکورات السبحية على أنها سلالة S. gallinaceous  (24.5٪) ، (16.3٪S.dysgalactiae و ) S. durans (12.2. من ناحية أخرى ، تم تحديد جميع عزلات Enterococcus على أنها E. faecalis. أظهر اختبار الحساسية للمضادات الحيوية في المختبر أن جميع العزلات کانت شديدة الحساسية للأموکسيسيلين (77.6٪) ، سلفاميثوکسازول-تريميثوبريم (73.5٪) وأموکسيسيلين-کلافولانيک أسيد (65.3٪). في الوقت نفسه کانت جميع العزلات مقاومة لمضادات سيفاليکسين ، سيفوتاکسيم صوديوم ، سيفيبيم ، سيفوترياکسون ، تتراسيکلين ، کاناميسين وأبراميسين بينما کانت 87.8 و 63.2٪ من العزلات مقاومة للجنتاميسين والإنروفلوکساسين على التوالي. علاوة على ذلک ، لوحظ وجود مقاومة متعددة للأدوية في 100٪ من العزلات. تم استخدام تفاعل البلمرة المتسلسل  للکشف عن 4 جينات مرتبطة بالمقاومة بما في ذلک (tetO ، aac (6 ') aph (2' ') ، blaZ و Pbp1A) بالإضافة إلى 6 جينات مرتبطة بالضراوة بما في ذلک (CylE ، brpA ، hyl ، cylE ، asa1 وgelE). أظهرت النتائج أن جميع العزلات المختبرة (100٪) تحتوي على جينات tetO وaac (6 ') aph (2') و blaZ و Pbp1A و cylE و brpA و cylA و asa1. في الوقت نفسه ، لم يتم الکشف عن جين hyl في أيا من عزلات المکورات السبحيه کما لم يتم الکشف عن جين gelE في عزلات المکورات المعوية.

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