1Arq. Inst. Biol., v.85, 1-5, e0112016, 2018

ABSTRACT: Antimicrobial sensitivity and pathogenicity 
level of 90 strains of Escherichia coli isolated from livers and 
intestines from commercial layer hens presenting diarrhea 
were analyzed. To  evaluate the antimicrobial susceptibility, 
all samples were subjected to antimicrobial susceptibility 
testing using 11  commercial drugs. The results have showed 
none of the strains was susceptible to all antibiotics tested. 
All samples showed resistance to two or more drugs. According 
to the mortality rate of the birds, the in-vivo pathogenicity test 
classifies the strains into four classes: high, intermediate, low 
and nonpathogenic. The test has showed 23 (25.5%) of the 
samples were highly pathogenic, 21 (23.3%) of intermediate 
pathogenicity, 23 (25.5%) low pathogenic, and 23 (25.5%) non-
pathogenic. When the results of the classes of pathogenicity from 
isolates have been associated with antimicrobial susceptibility, 
nonpathogenic strains were less sensitive to the antibiotic 
ampicillin and increased sensitive to streptomycin antimicrobial 
compared to the others classes of pathogenic. Nonpathogenic 
strains showed resistance to many antimicrobials, an alert for 
poultry, since these bacteria might acquire the virulence genes 
and infect birds, others animals and even human beings.

KEYWORDS: antimicrobial susceptibility; Escherichia coli; 
pathogenic.

RESUMO: Foram verificados a sensibilidade antimicrobiana e o 
índice de patogenicidade de 90 amostras de Escherichia coli isoladas 
do fígado e do intestino de pintainhas de postura comercial com 
diarreia. Para avaliar a sensibilidade antimicrobiana, todas as amos-
tras foram submetidas ao teste de susceptibilidade antimicrobiana 
por meio de 11 drogas comerciais. Os resultados demonstraram que 
nenhuma das estirpes foi sensível a todos os antimicrobianos testa-
dos. Todas as amostras apontaram resistência a duas ou mais drogas. 
De acordo com o índice de mortalidade das aves, o teste de patoge-
nicidade in vivo classificou as estirpes em quatro classes: alta, inter-
mediária, baixa e não patogênica. O teste revelou que 23 (25,5%) 
das amostras foram de alta patogenicidade, 21 (23,3%) de patoge-
nicidade intermediária, 23 (25,5%) de baixa patogenicidade e 23 
(25,5%) não patogênicas. Quando os resultados das classes de pato-
genicidade dos isolados foram associados à sensibilidade antimicro-
biana, estirpes não patogênicas apresentaram menor sensibilidade ao 
antimicrobiano ampicilina e maior sensibilidade ao antimicrobiano 
estreptomicina, quando comparadas com as estirpes das demais clas-
ses de patogenicidade. Estirpes não patogênicas exibiram resistência 
a vários antimicrobianos, representando um alerta para a avicultura, 
uma vez que essas bactérias podem adquirir genes de virulência e, 
assim, infectar aves, outros animais e até mesmo o seres humanos.

PALAVRAS-CHAVE: Sensibilidade antimicrobiana; Escherichia 
coli; patogenicidade.

In-vivo evaluation of pathogenicity and antimicrobial 
profile susceptibility from Escherichia coli samples 
isolated from commercial layer hens

Avaliação da patogenicidade in vivo e do perfil de resistência antimicrobiana 
de amostras de Escherichia coli isoladas de galinhas de postura comercial

Elisabete Aparecida Lopes Guastalli1*, Marcos Roberto Buim1, Bruno Henrique Lopes Guastalli2, 
Fernando Antonio de Ávila2

1Instituto Biológico, CAPTAA, Unidade de Pesquisa e Desenvolvimento de Bastos – Bastos (SP), Brazil 
2Universidade Estadual Paulista “Júlio de Mesquita Filho”, Faculdade de Ciências Agrárias e Veterinárias de Jaboticabal – 
Jaboticabal (SP), Brazil
*Corresponding author: guastalli@biologico.sp.gov.br
Received on: 02/08/2016. Accepted on: 03/12/2018

DOI: 10.1590/1808-1657000112016ANIMAL PATHOLOGY / SCIENTIFIC ARTICLE

mailto:guastalli@biologico.sp.gov.br


22 Arq. Inst. Biol., v.85, 1-5, e0112016, 2018

E.A.L. Guastalli et al.

INTRODUCTION

Escherichia coli is a facultatively anaerobic gram-negative 
bacillus and belongs to the family Enterobacteriaceae, which 
is part of the enteric microbiota of mammals and most birds 
(FERREIRA; KNÖBL, 2009). It is an important pathogen 
for human and veterinary medicine due to the innumerable 
health problems caused by intestinal pathotypes — entero-
pathogenic E. coli (EPEC), enterotoxigenic E. coli (ETEC), 
enteroinvasive E. coli (EIEC), enterohemorrhagic. E. coli 
(EHEC), enteroaggregative E. coli (EaggEC) and extra-intes-
tinal pathogenic E. coli (ExPEC) (CUNHA et al., 2013). 
The pathotype that affects the birds is called Avian pathogenic 
E. coli (APEC) and belongs to the category of ExPEC (FER-
REIRA; KNÖBL, 2009).

In birds, E. coli is responsible for different infectious 
conditions, acting as primary and secondary agent. The bac-
teria can affect virtually all of the bird’s organs, causing intes-
tinal and extra-intestinal infections, known as colibacillosis 
(BARNES et al., 2003). 

In the digestive tract of birds, E. coli can be found in con-
centrations above 106 colony forming units per gram of feces. 
This number may be even higher in young birds, since they 
do not have established microbiota (LEITHNER; HELLER, 
1992). Out of this total, 15 to 20% is potentially pathogenic 
to birds, because they possess antigenic determinants capable 
of causing disease (FERREIRA; KNÖBL, 2009). 

Stress factors such as deprivation of food and water or 
exposure to heat may lead to the propagation of E. coli from 
the gut of the birds into the bloodstream, resulting in signifi-
cant mortality (LEITHNER; HELLER, 1992).

In the available literature, the intestinal infection of the 
E. coli is abundantly mentioned as an unusual disease. How-
ever, there are reports that affirm the bacterium is responsi-
ble for histopathological lesions in the intestines of pigeons 
and chicks (WADA et al., 1995; SUEYOSHI et al., 1997).

In recent years, the genetic similarity between APEC and 
strains has associated with human infections and has become 
the target of research and health concern in the poultry pro-
duction chain (MALUTA et al. 2016; MARYVONN et al. 
2006; RON, 2006). According to CUNHA et al. (2013), the 
hypothesis that production animals could serve as reservoirs of 
potentially pathogenic strain to humans may be strong enough 
to make avian colibacillosis a new sanitary barrier and impose 
restrictions on animal-exporting countries.

In poultry, antimicrobials are used to prevent infections 
to minimize the damage caused by bacterial infections and the 
incidence of mortality, thus reducing economic losses. How-
ever, misuse, its use in animal feed for therapeutic, prophylactic 
and growth promoting purposes are primarily responsible for 

the presence of resistance to antibiotics by pathogenic bacteria 
for animals and for humans (SILVA, 2008). 

In turn, these resistant bacteria can be transferred from 
animals to humans, especially in individuals who work directly 
with animals or in the processing industries of products of 
animal origin (BARTON, 2000). 

This work aimed to associate pathogenicity in vivo with 
the antimicrobial resistance profile of strains of E. coli isolated 
from laying hens with diarrhea.

MATERIALS AND METHODS

This work is in accordance with the Ethical Principles in Ani-
mal Experimentation, adopted by the Colégio Brasileiro de 
Experimentação Animal (COBEA), and was also approved by 
the Comissão de Ética Bioética Bem-estar Animal (CEBEA) 
from the Comitê de Ética em Experimentação Animal da 
Universidade Estadual Paulista “Júlio de Mesquita Filho” 
(UNESP), protocol no. 026702-08.

Twenty flocks of seven-day-old white and brown com-
mercial layer hens were used in this study. The birds were pur-
chased from commercial farms from Bastos city and region, 
state of São Paulo.

Fifteen birds of each flock presenting smaller size and with 
diarrhea were selected for the investigation. The birds were 
taken to the Bastos Research and Development Unit, where 
they were necropsied, and a pool of fragments of liver and 
intestine (in separate flasks) of each flock for the isolation of 
E. coli was collected aseptically.

For the isolation and identification of E. coli, followed 
by the technique described by FERREIRA; KNÖBL (2009). 
All the isolated samples were conserved in Luria Bertani agar 
(LB) and submitted to the in-vivo pathogenicity test and to 
the antimicrobial susceptibility test. The pathogenicity test in 
one-day-old chicks was carried out following the methodology 
described by KNÖBL (2005) and MONROY et al. (2005). 
For each sample, ten-day-old male chicks from a commercial 
source were used, which were inoculated with 0,1 mL of bac-
terial culture, containing approximately 107 colony forming 
units/mL (UFC/mL) in the left thoracic air sac. The chicks were 
observed for ten days, and the strains were classified accord-
ing to the following mortality index: highly pathogenic (mor-
tality ≥ 80%), intermediate pathogenicity (mortality > 50% 
but < 80%), low pathogenicity (mortality ≤ 50%) and non-
pathogenic (no mortality).

For the antimicrobial susceptibility test, the technique 
of diffusion of the antibiotic impregnated in filter paper 
disks was used, following the methodology described by 



3Arq. Inst. Biol., v.85, 1-5, e0112016, 2018

In-vivo evaluation of pathogenicity and antimicrobial profile susceptibility from Escherichia coli samples isolated from commercial layer hens

National Committee for Clinical Laboratory Standards 
(NCCLS, 2008). 

All isolates from E. coli were transferred to tubes containing 
2 mL of saline solution 0,85%, in sufficient quantity to estab-
lish a turbidity compatible with the grade 0.5 of the McFarland 
scale. With a cotton swab, the culture was seeded on plates 
containing Mueller-Hinton agar (CM 0337). After drying, the 
plates were placed on the surface of the medium discs of the 
following antimicrobials: ampicillin (10 mcg), enrofloxacin 
(5 mcg), erythromycin (15 mcg), spectinomycin (100 mcg), 
streptomycin (10 mcg), fosfomicina (200 mcg), kanamycin 
(30 mcg), lincomycin (2 mcg), norfloxacin (10 mcg), sulfa + 
trimethoprim (25 mcg) and tetracycline (30 mcg). The plates 
were incubated at 37ºC for 24h. The reading was performed, 
classifying the strains under analysis according to the follow-
ing items: sensitive, intermediate or resistant to the antimi-
crobial tested.

RESULTS AND DISCUSSION

The in-vivo pathogenicity test revealed 23 (25.5%), 21 (23.3%), 
23 (25.5%) and 23 (25.5%) of the 90 E. coli strains stud-
ied were of high, intermediate, low and none pathogenicity, 
respectively.

The results of the susceptibility test are shown in Fig-
ure 1. The test was performed using 11 commercial drugs. 
The results showed that none of the isolated strains was sensi-
tive to all tested antimicrobials, and all of them were resistant 
to two or more drugs.

Spectinomycin and fosfomycin were the most efficient 
antimicrobials; the samples of E. coli presented 92.2% 
and 91.1%, respectively, of sensitivity to these antibiotics. 

Kanamycin, sulfa + trimethoprim and norfloxacin showed 
moderate antibacterial activity (from 62.2 to 45.6% of sen-
sitive strains). For the antimicrobials enrofloxacin, tetracy-
cline, ampicillin and streptomycin, the sensitivity was lower 
(38.9 to 11.1%). 

Table 1 demonstrates the in-vivo pathogenicity results 
associated with antimicrobial susceptibility. The results 
showed that the strains classified in the pathogenicity test as 
non-pathogenic had lower sensitivity for three antimicrobials: 
ampicillin (13.04%), enrofloxacin (34.78%) and fosfomycin 
(86.96%), when compared to those with high pathogenicity 
(30.43, 39.13 and 95.65%, respectively). In relation to the 
higher sensitivity presented by non-pathogenic strains, when 
compared to those with high pathogenicity, it was presented 
against antimicrobials: streptomycin, kanamycin, norfloxa-
cin, sulfa + trimethoprim and tetracycline, when compared to 
the high and to the intermediate pathogenicity classes (0%).

None of the four classes of pathogenicity for the strains 
of E. coli has antimicrobial sensitivity for the drugs erythro-
mycin and lincomycin.

Although the use of probiotics and prebiotics contrib-
utes to intestinal colonization by bacteria beneficial to intes-
tinal health, those drugs are not always effective in eliminat-
ing pathogenic samples from the intestine (CUNHA et al., 
2013). These pathogenic strains present in the intestinal tract, 
when eliminated in feces, promote intense environmental con-
tamination and lead to the occurrence of extra-intestinal and 
systemic infections, resulting in increased mortality of young 
birds (PHILIPS et al., 2004).

Non-pathogenic strains of E. coli from intestines of ani-
mals are important reservoirs of resistant genes to antimicro-
bial drugs (MARSHALL et al. 1990). According to DAVIES, 
(1994) and BUERIS (2005), the transmission of virulence 
genes and plasmid resistance between different genera and 
bacterial species occur widely.

In this study, non-pathogenic strains isolated from both 
the liver and the intestine presented resistance to several anti-
microbials, representing an alert for poultry farming, since the 
transmission of virulence genes may occur and infect birds, 
other animals and even humans. So, the results are important 
not only for poultry, but also for human medicine, reinforc-
ing the importance of performing the antibiogram before the 
prescription of the treatment.

CONCLUSION

• None of the strains, no matter the classification degree 
of pathogenicity, presented sensitivity to all tested 
antimicrobials;

Figure 1. Result of the antimicrobial susceptibility test of 
90 strains of Escherichia coli against 11 commercial drugs.

Sensitive %100
90
80
70
60
50
40
30
20
10

0

Ampici
llin

Enro
floxa

cin

Eryt
hro

myc
in

Specti
nomyc

in

Fo
sfo

myc
in

Kan
am

yc
in

Linco
myc

in

Norfloxa
cin

Sulfa
 +

 tr
im

ethoprim

Te
tra

cy
cli

ne

Specti
nomyc

in

%



44 Arq. Inst. Biol., v.85, 1-5, e0112016, 2018

E.A.L. Guastalli et al.

Table 1. Percentage of Escherichia coli strains sensitive to antimicrobials tested, according to pathogenicity classification.

Antimicrobials
% of sensitive strains in each class of pathogenicity

High
(n = 23)

Intermediate 
(n = 21)

Low
(n = 23)

Non-pathogenic
(n = 23)

Ampicillin 30.43 9.52 4.35 13.04
Enrofloxacin 39.13 28.57 47.83 34.78
Erythromycin 0 0 0 0
Streptomycin 0 0 21.74 21.74
Spectinomycin 86.96 100 82.61 100
Fosfomycin 95.65 85.71 95.65 86.96
Kanamycin 60.87 47.62 65.22 69.56
Lincomycin 0 0 0 0
Norfloxacin 39.13 28.57 65.22 47.87
Sulfa + Trimethoprim 52.17 38.09 60.87 60.87
Tetracycline 17.39 9.52 30.43 21.74

Antimicrobials
% of sensitive strains in each class of pathogenicity

High
(n = 23)

Intermediate 
(n = 21)

Low
(n = 23)

Non-pathogenic
(n = 23)

Ampicillin 30.43 9.52 4.35 13.04
Enrofloxacin 39.13 28.57 47.83 34.78
Erythromycin 0 0 0 0
Streptomycin 0 0 21.74 21.74
Spectinomycin 86.96 100 82.61 100
Fosfomycin 95.65 85.71 95.65 86.96
Kanamycin 60.87 47.62 65.22 69.56
Lincomycin 0 0 0 0
Norfloxacin 39.13 28.57 65.22 47.87
Sulfa + Trimethoprim 52.17 38.09 60.87 60.87
Tetracycline 17.39 9.52 30.43 21.74

• Strains classified as non-pathogenic in the in-vivo test had 
a less sensitive profile to the antimicrobial ampicillin;

• E. coli samples studied showed higher sensitivity to the 
antimicrobial spectinomycin;

• It was not possible to claim that more pathogenic samples 
have higher resistance to the antimicrobials evaluated.

ACKNOWLEDGMENT

The authors gratefully acknowledge the Fundação de Amparo à Pes-
quisa do Estado de São Paulo (FAPESP – grant no. 2009/02066-3) 
and the Conselho Nacional de Desenvolvimento Científico e Tec-
nológico (CNPq – grant no. 578023/2008-3), for financial support.

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