ANTIBIOTIC RESISTANCE OF ESCHERICHIA COLI ISOLATED FORM POULTRY WORKERS, PATIENTS AND CHICKEN IN THE EASTERN PROVINCE OF SAUDI ARABIA ppt

volume 4 no 4 pp 278–283 april 1999Antibiotic resistance of Escherichia coli isolated from poultry workers, patients and chicken in the eastern province of Saudi Arabia Mastour S.. Al-Mu

volume 4 no 4 pp 278–283 april 1999

Antibiotic resistance of Escherichia coli isolated from poultry

workers, patients and chicken in the eastern province of Saudi Arabia

Mastour S Al-Ghamdi 1 , Fikry El-Morsy 2 , Zaki H Al-Mustafa 1 , Mustafa Al-Ramadhan 3 and Mohammad Hanif 4

1 Department of Pharmacology, College of Medicine, King Faisal University

2 Department of Microbiology, College of Medicine, King Faisal University

3 College of Veterinary Medicine, King Faisal University

4 Department of Family and Community Medicine, College of Medicine, King Faisal University, Saudi Arabia

Summary The prevalence of antibiotic-resistant Escherichia coli isolates from faecal samples from 117 poultry industry

workers, 100 patients and119 healthy chicken were compared Resistance of E coli chicken isolates to

ampi-cillin, chloramphenicol, gentamicin, spectinomycin, tetracycline and trimethoprim 1 sulphamethoxazole (TMP 1 SMX) (range 57% – 99.1%) were significantly higher than those isolated from patients (range 21.9% – 71.4%) and workers (range 35% – 71.8%) However, for drugs not used in poultry, such as amoxi-cillin 1 cluvalanate (AMX 1 CLV), ceftazidime and nitrofurantoin, resistance rates of chicken isolates (range 0% – 2.6%) were significantly lower than those of patient isolates (range 8.7% – 30%) Resistance to

spectinomycin reached 96% in E coli chicken isolates and 71% in organisms isolated from humans Use of

this drug in Saudi Arabia is mostly limited to veterinary purposes Multidrug resistance is alarmingly high in

all groups but was highest in chicken isolates (77.4%) Serotyping of E coli isolates showed that 27% of the

organisms isolated from patients were overlapping with 10.9% of the chicken isolates, indicating the possi-bility of chicken being a source of the resistance pool for humans We therefore call for the banning of antibiotics in the poultry industry as growth promoters and recommend that their use be restricted to treat-ing infections

keywords Escherichia coli, microbial, antibiotics, antibiotic resistance, poultry, Saudi Arabia.

correspondence Dr Mastour Al-Ghamdi, Department of Pharmacology, College of Medicine, King Faisal

University, PO Box 2114, Dammam 31451, Saudi Arabia

Introduction

Antibiotics are widely used in poultry production as growth

promoters or to control infectious disease This practice is

reported to have caused high resistance to antimicrobial

agents in normal chicken flora (Swan Report 1969; Smith

1974; Aronson 1975; Linton 1977; Allan et al 1993) and

path-ogenic organisms (Amara et al 1995) These resistant

micro-organisms may act as a possible source for the transfer of

antimicrobial resistance to human pathogens (Bebora et al.

1994) Plasmid and transpon-mediated resistance is widely

transmitted between different bacterial species and genera

including human pathogens (Wise et al 1985; Davies 1994).

Multidrug-resistant strains of E coli are prevalent in both

human and animal isolates in different parts of the world

(Mahipal et al 1992; Bebora et al 1994; Amara et al 1995).

E coli is a common normal flora organism in the gastro-intestinal tract of animals and man (Jawetz et al 1984) but may become pathogenic to both (Jacobs et al 1970; Marier

et al 1973; Burkhanova 1980; Levine 1987) Serious outbreaks

of gastrointestinal illness caused by foodborne pathogenic

E coli, especially 0157:H7, have occurred during the past two decades (Armstrong et al 1996) Thus, resistant strains of

E coli arising from the exposure of animals to antimicrobials

may possibly become infectious organisms in humans Antimicrobial agents are widely used in the poultry indus-try of Saudi Arabia In fact, our own survey showed that 28 antimicrobial agents were available for poultry use in the Eastern Province of Saudi Arabia These include b– lactams, tetracyclines, aminoglycosides, macrolides, fluoroquinolones,

linconasomides and sulphonamides They are mainly added,

often concomitantly, to drinking water for infection

prophy-laxis Twenty of these antimicrobial agents are also

com-monly used in the treatment of human infections However,

no study was so far conducted in Saudi Arabia to evaluate

resistance to antibiotics in poultry and its possible impact on

human health

Our aims were to investigate and compare the patterns of

resistance of E coli isolated from poultry industry workers,

patients and chicken, and to identify the common serotypes

of E coli isolated from humans and poultry.

Materials and methods

The susceptibility patterns of 119, 117 and 100 E coli

organ-isms isolated from live healthy chicken in local slaughter

shops, poultry industry workers and patients in King Fahd

Hospital of the University, Al-Khobar, Saudi Arabia,

respect-ively, were determined Specimens were directly inoculated on

MacConkey agar, eosin methylene blue and xylose lysine

des-oxycholate agar media and growth was identified by standard

laboratory methods including Gram stain and API system

(BioMerieux SA, Marcy Etoile, France) The Bauer-Kirby disc

diffusion method (Bauer et al 1966) was used to test

suscepti-bility of the isolated organisms to ampicillin (10 mg),

amoxi-cillin 1 clavulanic acid (AMX 1 CLV) (Augmentin, 30 mg),

ceftazidime (75 mg), chloramphenicol (30 mg), tetracycline

(30 mg), gentamicin (10 mg), spectinomycin (10 mg),

tri-methoprim 1 sulphamethoxazole (TMP 1 SMX) (Septrin,

25 mg) and nitrofurantoin (100 mg) All antibiotic discs were

obtained from Oxoid (Unipath Ltd, Basingstoke, UK)

Interpretation followed criteria recommended in the National

Committee for Clinical Laboratory Standards (NCCLS 1993)

In addition, E coli organisms isolated from chicken and

patients were serotyped using E coli antisera (Denken Seiken,

Tokyo, Japan)

All data were recorded and analysed using SPSS/PC soft-ware Results were statistically analysed using the Spearman

correlation coefficient test and Student’s t-test, with a signifi-cance level of P , 0.05.

Results

The susceptibility of E coli isolates from chicken and

patients to the tested antibiotics is summarised in Table 1

The highest resistance rate observed in the chicken E coli

isolates was to tetracycline (99.1%) followed by those to spectinomycin (95.7%), TMP 1 SMX (92.2%), gentamicin (89.7%), ampicillin (88.7%) and chloramphenicol (57.0%) AMX 1 CLV, ceftazidime and nitrofurantoin remained highly effective with resistance rates # 2.6% The highest

rate of resistance in E coli isolated from patients was to

spectinomycin (71.4%), followed by ampicillin (70.7%), tetra-cycline (64.7%), TMP 1 SMX (46.3%) and AMX 1 CLV (30.0%)

Moderate or low resistance rates were noted with cef-tazidime, nitrofurantoin and gentamicin Both groups showed similar patterns of resistance to the tested antibiotics, with a

Spearman correlation coefficient of 0.7448 (P 5 0.021) However, resistance rates to individual drugs in E coli

iso-lated from patients remained significantly lower than those of

E coli chicken isolates with the exception of resistance to

cef-tazidime, AMX and nitrofurantoin (Table 1)

The Spearman test also revealed a highly significant

corre-lation (coefficient 5 0.9289, P 5 0.000) between the resist-ance pattern of E coli isolated from poultry industry workers and E coli isolated from chicken (Table 2) However, despite

the similarity of resistance patterns to the tested antibiotics in

E coli-chicken E coli-patient

isolates isolates t-test

Drugs tested resistance tested resistance P-value Significance

Ampicillin 115 88.7 99 70.7 0.0002 S AMX1CLV 116 02.60 99 30.0 0.0002 S Ceftazidime 114 00.0 92 08.70 – NA Chloramphenicol 113 57.0 92 28.3 0.0001 S Tetracycline 116 99.1 99 64.7 0.0000 S Gentamicin 116 89.7 96 21.9 0.0001 S Spectinomycin 116 95.7 91 71.4 0.0000 S TMP1SMX 116 92.2 95 46.3 0.0000 S Nitrofurantoin 116 02.6 74 10.8 0.0456 S

S, Significant; NA, Not applicable Spearman Correlation coefficient 5 0.7448, P 5 0.021

Table 1 Comparison of pattern of

resistance of E coli isolates from

chicken and patients

both groups, resistance rates remained significantly lower in

E coli isolated from the workers than those from chicken.

Multidrug resistance rates of E coli organisms isolated

from chicken were significantly greater than those of patient

isolates (Table 3) This became more evident when comparing

the rates of resistance to four drugs or more in both groups

(78.3% and 77.4% against 8.8% and 7.7%, respectively) In

addition, 20.5% of E coli organisms isolated from workers

were multiply resistant to the same drugs, which was also

sig-nificantly (P 5 0.0124) more than in patients’ isolates.

Serotyping of 119 and 100 E coli organisms isolated from

chicken and patients, respectively, is presented in Table 4

Only 30.3% of chicken E coli isolates and 38% of patient

isolates were serotypeable Twenty-one serotypes were found

among E coli isolated from chicken, most commonly 0114

(6 isolates), 06 (4 isolates) and 01 (3 isolates) There were 15

serotypes in human E coli isolates with 06 (14 isolates), 027

(6 isolates) and 018 (3 isolates) being the most common ones Seven serotypes (01, 06, 08, 015, 027, 0119 and 0167) were found in both groups These represent 10.9% of the poultry

E coli isolates and 27% of the E coli isolated from patients

(Table 4)

Discussion

We investigated the resistance of E coli isolated from poultry

industry workers and patients to 9 antimicrobial agents commonly used in the poultry industry and/or for patients in

E coli-chicken E coli-patient

isolates isolates t-test

————————— ————————— —————————–

Drugs tested resistance tested resistance P-value Significance

Ampicillin 115 88.7 117 53.8 0.0000 S

AMX1CLV 116 02.60 117 05.1 0.4472 NS

Ceftazidime 114 00.0 117 00.0 – NA

Chloramphenicol 113 57.0 117 35.0 0.0006 S

Tetracycline 116 99.1 117 58.1 0.0000 S

Gentamicin 116 89.7 117 37.6 0.0000 S

Spectinomycin 116 95.7 117 71.8 0.0000 S

TMP1SMX 116 92.2 117 53.0 0.0000 S

Nitrofurantoin 116 02.6 117 06.0 0.2892 NS

S, Significant; NA, Not applicable; NS, Not significant Spearman Correlation coefficient

50.9289, P 5 0.000

E coli-chicken E coli-patient t-test

———————– ———————– ———————–—–

No % No % Drugs tested resistance tested resistance P-value Significance

Ampicillin, chloramphenicol 113 49.6 92 20.6 0.0000 S

Ampicillin, gentamicin 115 82.6 96 16.7 0.0000 S

Ampicillin, spectinomycin 115 88.7 91 48.4 0.0000 S

Ampicillin, tetracycline 115 89.6 99 55.6 0.0000 S

Ampicillin, TMP1SMX 115 85.2 94 43.6 0.0000 S

Ampicillin, gentamicin, 115 78.3 91 08.8 0.0000 S

tetracycline & TMP1SMX

Ampicillin, gentamicin, 115 77.4 91 07.7 0.0000 S

spectinomycin, tetracycline &

TMP1SMX

S, Significant

Table 2 Comparison of pattern of

resistance of E coli isolates from

chicken and laborers

Table 3 Comparison of multi-resistance

of E chicken isolates and E

coli-patients isolates

Van-den-Bogaard and Stobberingh (1996) recently called for banning the use of antibiotics as growth promoters in ani-mals in the Netherlands

Spectinomycin is an aminocyclitol compound related struc-turally to aminoglycosides and used by veterinarians as a broad spectrum antibiotic against gram negative bacteria

including E coli, Klebsiella, Salmonella, Proteus and Enterobacter organisms (Allen et al 1993) E coli organisms

isolated from chicken were almost totally resistant to tetra-cycline and spectinomycin This might be explained by the fact that both are heavily used in the poultry industry in Saudi Arabia and could be the result of misuse or antagonism effect between the two drugs, especially when used

concur-rently (Allen et al 1993) High resistance rates were also noted with TMP 1 SMX and chloramphenicol in E coli

iso-lated from poultry despite the fact that the latter is not licensed for veterinary use in Saudi Arabia This again could

be associated with the misuse of spectinomycin as reported

by Ginns et al (1996).

Although the high resistance rate of E coli chicken isolates

to spectinomycin may be attributed to the misuse of this drug

in the poultry industry, the reasons for high resistance in

human E coli isolates are not fully understood, as its clinical use is limited to second-line therapy for Neisseria gonorrhea (Kapusnik-Uner et al 1996) However, such resistance could

be either natural or due to poultry as a possible source of the spectinomycin resistance pool for humans

Exposure to antibiotics at work may also contribute to increased resistance rates The Spearman correlation co-efficient test revealed a significant correlation between the

pattern of resistance to antibiotics in E coli organisms from

chicken and from patients (Table 1) as well as from workers (Table 2) These findings not only demonstrate the similarity

of the organisms’ attitude toward the investigated antibiotics, but also confirm the effect of work exposure to antibiotics This is corroborated by multiple resistance to four or five antimicrobial agents commonly used in the poultry industry

Bongers et al (1995) noted a significantly higher level of

resistance to oxytetracycline and ampicillin in poultry indus-try workers than in pig husbandry workers or those not working with animals This was attributed to the differences

in exposure to antibiotics at work

The E coli isolated from chicken belonged to 21 serotypes,

with 69.6% being nontypeable The most frequent serotypes

in this study were 0114, 06 and 01 Similarly, Ngeleka et al (1996) reported that only 38.4% of 39 E coli isolated from

broiler chickens with cellulitis were typeable, but the most frequent serotypes in their study were 025 and 078 In

con-trast to our findings, Allan et al (1993) found that 61% of 44 avian E coli isolates were typeable, with 01, 02 and 078 being

the most frequent serotypes

E coli isolated from patients belonged to 15 serotypes,

the Eastern Province of Saudi Arabia E coli isolated from

chicken clearly demonstrated high resistance rates to all

tested antibiotics commonly used in the poultry industry

but not to those which are mainly used for patients

(AMX 1 CLV, ceftazidime and nitrofurantoin) (Table 1) By

contrast, higher resistance rates to these drugs were noted in

organisms isolated from human patients This suggests that

the extent of resistance to an antibiotic is associated with the

extent of its use The high antibiotic resistance rate of

organ-isms isolated from animals is not a phenomenon unique to

Saudi Arabia A recent report by Blanco et al (1997) in Spain

showed that up to 67% of avian E coli strains were resistant

to TMP 1 SMX and that resistance to the new

fluoro-quinolones was also increasing Similarly, Son and Gulam

(1995) in Malaysia isolated plasmids of E coli with high

resistance rates to 9 antibiotics in clinical use for humans

Table 4 Serotypes of organisms isolated from chicken and patients

Serotyping E coli-chicken E coli-patient

isolates isolates Polyvalent Serotype

non-serotypeable 83 62

Total serotyped 36 (30.3%) 38 (38%)

Overlapped serotype 13 (10.9%) 27 (27%)

with 62% being nontypeable (Table 4) However, serotypes of

27% of E coli organisms isolated from human patients were

also found in chicken isolates, with 06 and 027 being the most

common serotypes in both groups (Table 4) These results

suggest that chicken may act as a possible source of human

pathogenic organisms Cherry et al (1961) reported that

some serotypes, such as 055, 0126, 086, 026 and 0119, which

were isolated from chicken, were capable of producing

infec-tion in children More recently, E coli 0157:H7 has been

rec-ognized as a dangerous foodborne pathogen (Griffin 1995;

Armstrong et al 1996).

In conclusion, our data demonstrate alarmingly high

individual and multiple resistance to antibiotics in E coli,

reflecting the misuse of these agents in the poultry industry

Since chicken may act as a possible source of pathogenic

organisms in humans, we concur with the calls to ban the use

of antibiotics as growth promoters and recommend the

re-striction of their use to treat infections in the poultry industry

Acknowledgements

This work was funded by the King Abdulaziz City of Science

and Technology (Grant no AT-15–79) to whom we express

our gratitude Our sincere thanks also go to Dr

Abdul-Rahman Qurashi and the technical staff at the Microbiology

Laboratories at King Fahd Hospital of the University and the

College of Medicine for their assistance We also thank Prof

A Ghandour, Department of Microbiology, King Faisal

University, for reviewing the manuscript

References

Allan BJ, Van-den-Hurk W & Potter AA (1993) Characterization of

Escherichia coli isolated from cases of avian colibacillosis.

Canadian Journal of Veterinary Research57, 146–151

Allen DG, Pringle X, Smith D, Conlon PD & Burgmann PM (1993)

Handbook of Veterinary Drugs Lippincott, Philadelphia, pp.

257–258

Amara A, Ziani Z & Bouzoubaa K (1995) Antibioresistance of

Escherichia coli strains isolated in Morocco from chickens with

colibacillosis Veterinary Microbiology 43, 325–330.

Armstrong GL, Hollingsworth J & Morris JG Jr (1996) Emerging

foodborne pathogens: Escherichia coli 0157: H7 as a model of

entry of a new pathogen into the food supply of the developed

world Epidemiological Review 18, 29–51.

Aronson AL (1975) Potential impact of the use of antimicrobial drugs

in farm animals on public health Presented at the meeting on

pharmacology in the animal health sector Sept 23–24, 1975

Colorado State University, Fort Collins

Bauer AW, Kirby WMM, Sherris JC & Turk M (1966) Antibiotic

sus-ceptibility testing by a standardized single disk method American

Journal of Clinical Pathology 45, 493–496.

Bebora LC, Oundo JO & Yamamoto H (1994) Resistance of E coli

strains, recovered from chickens, to antibiotics with particular

ref-erence to trimethoprim-sulfamethoxazole (Septrin) East African

Medical Journal 71, 624–627.

Blanco JE, Blanco M, Mora A & Blanco J (1997) Prevalence of bac-terial resistance to quinolones and other antimicrobials among

avian Escherichia coli strains isolated from septicemic and healthy

chickens in Spain Journal of Clinical Microbiology 35, 2184–2185.

Bongers JH, Franssen F, Elbers AR & Tielen MJ (1995)

Antimicrobial resistance of Escherichia coli isolates from the

faecal flora of veterinarians with different professional specialties

Veterinarians’ Quarterly 17, 146–149.

Burkhanova KHK (1980) Properties of E coli strains isolated fron

diseased fowls Veterinarria Moscow USSR 10, 66.

Cherry WB, Thomason BM, Pomales Lebron A & Ewing WB (1951)

Rapid presumptive identification of entero pathogenic Escherichia coli in faecal smears by means of fluorescent antibody 3 Field

eval-uation Bulletin of the of the World Health Organization 25,

159–171

Davies J (1994) Inactivation of antibiotics and the dissemination of

resistance genes Science 264, 375–382.

Ginns CA, Browning GF, Benham ML, Anderson GA & Whithear

KG (1996) Antimicrobial resistance and epidemiology of

Escherichia coli in broiler breeder chickens Avian Pathology 3,

591–605

Griffin PM (1995) Escherichia coli 0157: H7 and other enterohemor-rhagic Escherichia coli In: Infections of the Gastrointestinal Tract (ed M.J Blaser et al.) Raven Press, New York, pp 739–761.

Jacobs SI, Halizel A & Wolman B (1970) Outbreak of infantile

gastroenteritis caused by E coli 0114 Archives of Disease in Childhood 45, 243.

Jawetz E, Melnick J & Adelberg EA (1984) Review of Medical Microbiology, 16th edn Long Medical Publication, Los Altos.

Kapusnik-Uner JE, Sande MA & Chambers HF (1996) Tetracyclines, chloramphenicol, erythromycin and miscellaneous antibacterial

agents In: The Pharmacological Basis of Therapeutics 9th edn (ed J.G Hardman et al.) McGraw Hill, New York, p 1143 Levine M (1987) Escherichia coli that cause diarrhea:

enterotoxi-genic, enteropathoenterotoxi-genic, enteroinvasive, enterohemorrhagic and

enteroadherent Journal of Infectious Diseases 155, 377–390.

Linton AH (1977) Antibiotics, animals and man An appraisal of a

continuous subject In: Antibiotics and Antibiosis in Agriculture

(ed M Woobine), Butterworths, London, pp 315–343

Mahipal S, Chaudhry MA, Yadava JNS & Sanyal SC (1992) The spectrum of antibiotic resistance in human and veterinary isolates

of Escherichia coli collected from 1984 to 1986 in Northern India.

Journal of Antimicrobial Chemotherapy 29, 159–168.

Marier R, Wells JG, Swanson RC, Collahan W & Mehlaman IJ

(1973) An outbreak of enteropathogenic E coli foodborne disease

traced to imported French cheese Lancet ii, 1376.

National Committee for Clinical Laboratory Standards (NCCLS)

(1993) Performance Standards for Antimicrobial Disk Susceptibility Tests Approved Standard M2 -A5 5th edn NCCLS,

Villanova, Pa

Ngeleka M, Kwaga JK, White DG, Whittam TS, Riddell C &

Goodhope R (1996) Escherichia coli cellulitis in broiler chickens:

clonal relationships among strains and analysis of

virulence-asso-ciated factors of isolates from diseased birds Infection and

Immunity 64, 3118–3126.

4190), HMSO, London.

Van-den-Bogaard AE & Stobberingh EE (1996) Time to ban all

antibiotics as animal growth promoting agents? Lancet 348, 619.

Wise RJ, Towner KJ, Webster CA, Slack RC & Jones TO (1985)

Trimethoprim resistance plasmids in Escherichia coli isolated from diarrhoeae in cattle, pigs and sheep Journal of Applied

Bacteriology 58, 555–561.

Smith HW (1974) Veterinary and food aspects of drug resistance

Journal of Science in Food and Agriculture 25, 227–237.

Son RI & Gulam RRA (1995) Plasmids and antimicrobial

susceptibil-ity of Escherichia coli with special reference to poultry isolates in

Sarawak Journal of Veterinar Malaysia 7, 21–25.

Swan Report (1969) Report of the Joint Committee on the use of

antibiotics in animal husbandry and veterinary medicine (Cmnd