Abstracts
Avian pathogenic Escherichia coli (APEC) strains cause a great diversity of diseases in birds and are responsible for great economic losses in the avian industry. To date, several studies have been carried out to better understand the APEC pathogenesis for a possible development of tools which could prevent the economics losses caused by these strains. This review discusses the virulence factors described do date to be expressed by these strains and the advances made to understand and identify virulence determinants present in APEC.
APEC; avian Escherichia coli; virulence factors
Linhagens de Escherichia coli patogênicas para aves (APEC) causam uma grande diversidade de doenças em aves e são responsáveis por grandes prejuízos na indústria aviária. Nos últimos anos, vários estudos foram realizados para melhor entender a patogênese de linhagens APEC e para desenvolver ferramentas que podem prevenir as perdas econômicas causadas por estas linhagens. Esta revisão discute os fatores de virulência descritos nestas linhagens e os avanços realizados para entender e identificar os determinantes de virulência presentes em APEC.
APEC; Escherichia coli aviária; fatores de virulência
REVIEW ARTICLE
Virulence factors of avian pathogenic Escherichia coli (APEC)
Fatores de virulência de Escherichia coli aviária patogênica (APEC)
Gerson Nakazato; Tatiana Amabile de Campos; Eliana Guedes Stehling; Marcelo Brocchi; Wanderley Dias da Silveira** Corresponding author: wds@unicamp.br
Departamento de Microbiologia e Imunologia, Instituto de Biologia, Universidade Estadual de Campinas (Unicamp), Cidade Universitária Zeferino Vaz s/n, Cx. Postal 6109, Barão Geraldo, Campinas, SP 13081-862, Brazil
ABSTRACT
Avian pathogenic Escherichia coli (APEC) strains cause a great diversity of diseases in birds and are responsible for great economic losses in the avian industry. To date, several studies have been carried out to better understand the APEC pathogenesis for a possible development of tools which could prevent the economics losses caused by these strains. This review discusses the virulence factors described do date to be expressed by these strains and the advances made to understand and identify virulence determinants present in APEC.
Index terms: APEC, avian Escherichia coli, virulence factors.
RESUMO
Linhagens de Escherichia coli patogênicas para aves (APEC) causam uma grande diversidade de doenças em aves e são responsáveis por grandes prejuízos na indústria aviária. Nos últimos anos, vários estudos foram realizados para melhor entender a patogênese de linhagens APEC e para desenvolver ferramentas que podem prevenir as perdas econômicas causadas por estas linhagens. Esta revisão discute os fatores de virulência descritos nestas linhagens e os avanços realizados para entender e identificar os determinantes de virulência presentes em APEC.
Termos de indexação: APEC, Escherichia coli aviária, fatores de virulência.
INTRODUCTION
Escherichia coli is a rod-shaped, Gram-negative, facul-tative anaerobic bacterium that belongs to the Enterobacteriaceae family. E. coli typically colonizes the intestinal tract of humans (Drasar & Hill, 1974), mammals and birds (Sokja, 1965). E. coli strains are usually found confined to the intestinal lumen, however in imunosuppressed hosts or when the gastrointestinal barriers are violated, these bacteria may cause infectious diseases (Nataro & Kaper, 1998). Besides that, there are E. coli strains originated from adapted pathogenic clones that cause diseases among healthy animals (Nataro & Kaper 1998).
Pathogenic E. coli are associated with intestinal (Nataro & Kaper 1998) and extraintestinal human infections, like cystitis and pyelonephritis (Pechere 1985), septicemia (Orskov & Orskov 1985) and meningitis in neonatal infants (Overall Jr 1970). Among other animals, pathogenic E. coli strains are also able to cause extraintestinal infections such as urinary infection (Wooley & Blue 1976, Peeters 1994) and pyometra (Bjurstrom 1993) in dogs, and respiratory diseases in birds (Kaper et al. 2004). Currently, E. coli is considered to be the most significant example of gram-negative bacterium related with diverse diseases because of the different pathogenicity mechanisms and diseases that it is able to cause.
Diseases caused by avian pathogenic Escherichia coli (APEC)
Avian pathogenic E. coli strains are known as APEC (Dho-Moulin & Fairbrother 1999) and are associated with diverse diseases, mainly extraintestinal, being responsible for great losses in the avian industry (Gross 1994). These diseases include: inflamation of the oviduct that results in decreased egg production and sporadic mortality in laying chickens and breeders, salpingitis that occurs when E. coli ascends the oviduct from the cloaca and extension into the body cavity through the compromised oviduct wall that leads to concurrent peritonitis (in: Barnes et al. 2003).
Colisepticemia is the most important disease caused by APEC strains. This infectious disease is considered to be initiated in the avian upper respiratory tract after a primary infection caused by different virus such as the Newcasttle virus, Infectious Bronchitis virus or Mycoplasma (Gross 1991). These primary infections would increase the avian susceptibility to APEC strains due to the decilliation of the upper respiratory cells and exposition to ammonia and contaminated dust existing in the growth animal environment would also favor the infectious process (Oyentude et al. 1978, Nagaraja et al. 1984). The respiratory infection caused by APEC strains, further to the virus infection, is considered to be the initial step for colisepticemia development in birds (Gross 1991). This infection is also referred to as aero sac disease and usually occurs among birds with 2 to 12 weeks of age, with the majority of the cases occurring among birds with 4 to 9 weeks of age with mortality reaching rates as high as 20% (Dho-Moulin & Fairbrother 1999).
Death is the usual outcome of colisepticemia, but some birds may completely recover or recover with residual sequelae, as meningitis, panophthalmitis (swollen eye), osteoarthritis, synovitis and coligranuloma (Hjarres's Diseases) that is characterized by multiple granulomas in liver, cecum, duodenum and mesentery (in: Barnes et al. 2003).
In broilers and hatchers chickens, APEC strains also cause a syndrome named "swollen head syndrome". Lesions observed in this syndrome include gelatinous edema on the skin head and peri orbital tissues, and, in some cases, fibrous exudates in the subcutaneous head tissues and in the lachrymal glands (Pattison et al. 1989, Nunoya et al. 1991). Swollen head syndrome was first described in the South America (Morley & Thomson 1984) and is considered to be an important avian disease in various countries including Brazil (Arns & Hafez 1992). This syndrome has caused considerable losses in the avian industry because it is responsible for mortality of 3 to 4% of the birds and for reduction of 2 to 3 % at the egg production (Morley & Thomson 1984). Swollen head syndrome usually begins after an acute rhinitis caused by pneumovirus being followed by the invasion of the subcutaneous skin tissues by E.coli what causes the characteristic edema (Picault et al. 1987, Hafez & Loehren 1990).
In broilers, APEC strains are also associated with cellulitis that is characterized by a necrotic dermatitis of the abdomen and thighs (Dho-Moulin & Fairbrother 1999). Epidemiological data about this syndrome are not known but the lesions associated with cellulitis causes losses in the avian industry due to carcasses condemnation (Elfadil et al. 1996).
Some studies have showed positive relation among APEC and human extraintestinal pathogenic E. coli (ExPEC), mainly uropathogenic E. coli (UPEC) and newborn meningitis-causing E. coli (NMEC), sugesting that some APEC strains could be considered potential zoonotic agents (Ewers et al. 2007, Moulin-Schouleur et al. 2007, Johnson et al. 2008).
Virulence factors of APEC strains
Several investigations have added knowledge about the pathogenic mechanisms expressed by APEC strains (Dho-Moulin & Fairbrother 1999). The virulence factors that have been described to be expressed by these strains include adhesins, toxins, iron uptake systems, and resistance to the host serum.
Adhesins. The bacterial adhesion to epithelium tissues is considered to be an important step for the establishment of the E. coli infection since it permits the bacterial linkage and maintenance in close contact to the host epithelial tissues (Moon 1990). Evidences that the adherence capacity of E. coli could be a virulence factor were initially proposed by Arp et al. (1980) which observed that a fimbriated and virulent strain was more persistent in the turkey trachea than an avirulent and afimbriated strain.
Among APEC strains, Type 1 fimbriae are related to the adhesion to the avian upper respiratory tract (Wooley et al. 1998). The adhesive properties of Type 1 fimbriae are inhibited by specific antiserum and by D-mannose, a carbohydrate that is its cellular receptor on the eurocariotic cell membrande. These characteristics are used for its characterization (Gyimah & Panigraphy 1988). Pourbaskhsh et al. (1997) suggested that while Type 1 fimbriae is associated with the upper respiratory tract initial colonization P fimbrial adhesin may be involved in the bacterial establishment in deeper avian organs. Wooley et al. (1998) also suggested that while Type 1 is necessary to initial colonization of the respiratory epithelium, additional factors like motility and colicin V production would be responsible by the persistence of the colonization and by the observed trachea lesions development. Marc et al. (1998) demonstrated, with the utilization of a fim- APEC mutant, that Type 1 fimbriae is not strictly required as a colonization factor during the avian colibacilosis development.
P fimbrial adhesins were first described among E. coli strains associated with human urinary tract infections (UTI) (Kallenius et al. 1980) being also found among APEC strains (Achtman et al. 1983, Dozois et al. 1992). P fimbriae is encoded by the pap operon that is located in the bacterial chromosome (Latham & Stamm 1994). papA gene encodes for the major structural protein (PapA), papI and papB are regulatory genes responsible for the phase variation process (Mol & Oudega 1996). papE gene encodes for the fimbrial structural extremity, papG gene encodes for the adhesin, and papD, papH, papJ, papF and papK genes are responsible for the expression of proteins related to the hole integrity of the complex fimbrial assemblage (Mol & Oudega 1996). The adhesive property of P fimbriae is conferred by the terminal adhesin PapG that presents three molecular variants (I, II and III) (Hos-chützky et al. 1989) that recognize different isoreceptors containing a-D-galactosyl-(1-4)-b-galactopyranosil carbo-hydrate.
The role of P fimbriae in the APEC pathogenicity has not been completed elucidated yet. Pourbakhsh et al. (1997) using in vivo studies, verified that P fimbriae presented phase variation and suggested that these adhesins would not be important for the initial colonization of the upper respiratory tract, but it would be in the latter infection stages. Recently, Kariyawasam et al. (2006) demonstrated that the pap operon is present in a pathogenicity island of APEC strain APEC-O1. The authors suggested that the pap occurrence in horizontaly acquired genomic regions might be involved in the transformation of avirulent strains into virulent ones.
Curli fimbriae are thin and curly appendices found on the cell surface of Salmonella enterica and E. coli (Olsén et al. 1989), and are responsible for the bacterial linkage to proteins of the extracellular matrix (Collinson et al. 1993) and for bacterial survival in the external environment (Olsén et al. 1993). Curli fimbriaes are optimally expressed at 26ºC during the growth in the stationary phase and in low osmolarity medium (Olsén et al. 1993). The genes responsible for curli fimbriae expression are encoded by two operons: csgBAC and csgDEFG. csgA gene encodes for the monomers structural subunits, named curlina while csgB gene encodes for a protein needed for curlina complex stability. The operon csgDEGF has it expression controlled by environmental factors like temperature, osmolarity, pH, and other stress factors (La Ragione & Woodward 2002). The curli fimbriae expression is also dependent of RpoS factor, an ó factor that controls the expression of several genes during the stationary phase of bacterial growth (Olsén et al. 1993). Curli related sequences have been widely found among APEC strains. Maurer et al. (1998) detected csgA gene in all APEC strains analyzed. The same curli-related sequence was found among 90% of the strains isolated by Knöbl (2001) from ostriches with respiratory disease and among 70% of strains analyzed by Campos et al. (2005). In this latter study, the authors detected csgA sequence in all APEC isolated from chickens with septicemia and in none of the E. coli strains isolated from the intestinal microbiota of chickens. However a study made by McPeake et al. (2005) demonstrated that the csgA gene was presented among all strains analyzed, isolated from chickens with septicemia and from healthy chickens.
Other adhesins identified among APEC strains comprised the AC/1 fimbriae and type 1-like fimbriae (La Ragione & Woodward 2002). The presence of fimbriae F17, Afa, Sfa, and Eae DNA-related sequences among APEC strains may indicate that these adhesins can be found on the cell surface of APEC (Stordeur et al. 2002, Campos et al. 2005, McPeake et al. 2005) and could also be implicated in the pathogenesis presented by these strains.
Temperature-sensitive hemagglutinin. The tempe-rature-sensitive hemagglutinin (TSH) is a protein expressed by APEC strains that present chicken erythrocytes hemagglutination activity at 26ºC and have this activity repressed at 42ºC (Provence & Curtiss III 1994). TSH is a serine-protease autotransporter protein that is synthesized as a 140 KDa precursor, and is cleaved in two subunits in the bacterial periplasm: one subunit, with 33 KDa, that remains inserted in the outer membrane and functions like a passenger domain; and other subunit with 106 KDa that is secreted to extracellular environment. The 106 KDa subunit remains temporally in the outer membrane and mediates the bacterial adhesion during the initial stages of the infection (Stathopoulos et al. 1999). After its secretion, the 106 KDa sub-unit probably presents a characteristic proteolytic activity, that renders the TSH protein a bifunctional protein, with adhesive and proteolytic activities (Kostakioti & Stathopoulos 2004).
TSH is encoded by the tsh gene (Provence & Curtiss III 1994). This gene is located in high molecular weigh plasmids (Dozois et al. 2000, Stehling et al. 2003, Johnson et al. 2006), mainly in ColV plasmids and is frequently found among APEC strains. Maurer et al. (1998) detected the tsh gene among 46% of the studied APEC strains and in none of the commensal isolates. Campos et al. (2005) demonstrated that the tsh gene was found among 25 and 50% APEC strains isolated from chickens with septicemia and swollen head syndrome, respectively, and in only 6% of the commensal strains. Because the association of the tsh gene with APEC pathogenicity, Ewers et al (2004) proposed its utilization as a molecular marker to detect APEC strains.
Iron acquisition systems. APEC strains survive and growth in environments with low iron availability, mainly inside the host, because the expression of iron acquisition systems (Dho & Lafont 1984). The bacterial iron acquisition mechanisms include the production of siderophores that act as ion chelants in the host (Williams & Griffiths 1992). Two types of siderophores are known: fenolates and hidroxamate. Aerobactin is a hidroxamate siderophore that is encoded by a plasmid operon (Gibson & Magrath 1969, Williams 1979). This siderophore is also found among fungi, enteroinvasive E. coli and APEC strains (Dho & Lafont 1984, Waters & Crosa 1991).
Dho & Lafont (1984) observed a positive correlation between the low iron concentration, APEC growth ability and the lethality capacity to one-day old chickens observed in these strains. Also, Linggood et al. (1987), Dozois et al. (1992), Emery et al. (1992) and Silveira et al. (2002a) demonstrated that pathogenic APEC strains expressed iron uptake systems while non pathogenic strains did not express. The yersiniabactin system (fyuA and irp-2 genes) (Pelludat et al. 1998, Schubert et al. 1998, Karch et al. 1999) were found in higher frequencies among APEC strains (Gophna et al. 2001, JanBen et al. 2001). Genes related with another iron acquisition systems, like iucA and fepC genes, were also found among APEC strains (Okeke et al. 2004). A recent work realized by our research group (Campos et al. 2005) showed a high frequency of iron uptake related genes among pathogenic avian E. coli strains.
Recently, a sitABCDE Salmonella enterica homologue system were identified in an APEC strain (Sabri et al. 2006, Sabri et al. 2008). In this strain, the sitABCDE is an iron and manganese transporter system that, in combination with other iron uptake systems, can contributes to iron acquisition and to the oxidative stress bacterial survival (Sabri et al. 2006). Among APEC strains, iron acquisition systems can be encoded by plasmid genes (Johnson et al. 2006, Sabri et al. 2006) or by chromosomal patho-genicity islands (Kariyawasam et al. 2006).
Colicins. These are proteins expressed by E. coli that inhibit the bacterial growth from the same or related species. Colicins are compounded by two subunits: one that provokes bacterial cell lesions and other that protects the bacterium against their own colicins (Hardy et al. 1975). Colicins can be encoded by genes located in plasmids. Because of this, they are frequently called Col plasmids. Works establishing colicin expression by APEC strains indicated that colicins Ia, Ib, E1, E2, E3, I, K, B and V are the most prevalent ones among these bacterial strains (Fantinatti et al. 1994, Silveira et al. 2002a).
The majority of APEC strains have colicin V plasmids (Wray & Woodward 1997). Theses plasmids also contain other pathogenicity related genes (Valvano et al. 1992, Johnson et al. 2003). Mutations at ColV plasmids demons-trated decreasing of the virulence, suggesting that some genes linked to ColV plasmids are involved in the establishment of avian infection (Skyberg et al. 2008).
Capsule. Some E. coli strains have an N-acetyl muramic acid capsule on their cell surface that interacts with the classical complement pathway conferring immune resistance to the bacteria and that induces the immune resistance (Jann & Jann 1977).
K1 capsular antigen is frequently associated to APEC strains belonging to serogroups O1, O2 and to non typable strains (Gross 1991). Pourbakhsh et al. (1997) demonstrated the three APEC strains expressing capsule K1 were more resistance to the serum bactericidal effects than APEC strains that expressed other K antigens.
Serum resistance. The bacterial resistance to the complement, mediated by bacterial surface structures like LPS, capsule, Col V colicin, and outer membrane proteins, have been associated with APEC strains (Gross 1991, Fantinatti et al. 1994, Ngeleka et al. 1996, Lynne et a. 2007).
Pfaff-McDonough et al. (2000) suggested that the Iss factor (increased serum survival) is associated with APEC pathogenicity since the iss gene have been found more frequently among pathogenic than non pathogenic strains, despite of serotype, avian species and lesion origin. The occurrence of iss gene in conjugative Col V plasmid (Johnson et al. 2002, Mellata et al. 2003) can suggest the relationship of Iss factor to the APEC pathogenicity. Besides the role of Iss, Mellata et al. (2003) suggested that the O78 polysaccharide and the K1 capsule are virulence factors that increase the bacterial serum survival.
Toxins. Some APEC strains are able to produce toxins like labile temperature (LT) and stable temperature (ST) enterotoxins (Smith & Gyles 1969), and verotoxins known as Shiga-toxins (Stx) (O'Brien et al. 1977; O'Brien et al. 1982, Emery et al. 1992, Parreira & Yano 1998, Fantinatti et al. 1994, Blanco et al. 1997).
APEC strains cytotoxic activity to Vero cells was observed by Fantinatti et al. (1994) and by Parreira & Yano (1998). Parreira & Gyles (2002) identified a Stx- gene among E. coli strains isolated from chickens suffering from cellulitis, septicemia, and swollen head syndrome and from sick turkeys. These same authors (Parreira & Gyles 2003) described a vacuolating toxin to be expressed by an APEC strain. This toxin is encoded by the vat gene that belongs to a pathogenicity island and was latter found to be expressed by another APEC strains (Ewers et al. 2004, Ewers et al. 2005).
Other virulence factors. Other virulence factors found among APEC strains include pathogenicity islands (Parreira & Gyles 2003, Kariyawasam et al. 2006, Kariyawasam et al. 2008) and the locus of enterocyte effacement (LEE) (Foster et al. 1998, Pennycott et al. 1998, La Ragione et al. 2002). Rodriguez-Siek et al. (2005) showed that E. coli strains isolates obtained from human UTI and avian colibacilosis could have substantial overlap in terms of serogroups, phylogenetic groups and virulence genotypes, including plasmid-DNA-related sequences, adhesion, iron uptake, protectins and toxins-related sequences.
The Congo red linkage capacity in agar medium has been observed among APEC strains. Some authors have purposed the utilization of this characteristic as virulence marker to APEC strains (Berkhoff & Vinal 1986, Corbett et al. 1987).
New approaches for virulence determinants detection
Modern molecular biology techniques such as the in vivo expression (Mahan et al., 1993), selective capture of transcript sequences - SCOTS (Graham & Clarck- Curtiss 1999), fluorescence differential induction (Valdivia & Falkow 1996) and signature tagged transposon mutagenesis - STM (Shea et al. 1996) have added knowledge to the bacterial pathogenicity because permit verify the gene expression during the infectious process. By the sequencing of cDNAs obtained from pathogen-specific transcripts sequences selection (SCOTS), Dozois et al. (2003) verified that transcripts related to adhesins, LPS synthesis, iron uptake systems, plasmid and phage sequences were expressed by X7122 APEC strain during the infection process. Using the STM technology, Li et al. (2005) observed that LPS, iron uptake systems, and capsule are important virulence determinants associated with septicemia by APEC strains. Besides, these authors observed that genes encoding metabolic enzymes are required during the pathogenesis of avian colisepticemia process.
Some genomic comparison studies have demonstrated that APEC strains share virulence sequences with ExPEC isolated from humans. A subtractive hybridization analysis with two APEC strains and one E. coli K12 strain (Stocki et al. 2002) detected APEC specific DNA sequences presenting high homology with DNA sequences of E. coli O157:H7 and human ExPEC strains. Johnson et al. (2003) recovered strains from chicken retails products that presented virulence profiles, phylogenetic group background, and O antigens resembling those of humans ExPEC isolates and, recently, Johnson et al. (2007) obtained the DNA sequence of the genome of a APEC O1. It contained a 5,082,025-bp chromosome and four plasmids totaling 565,600 bp in size giving it a total genome size of 5,647,625 bp. Overall, APEC O1 shared the greatest nucleotide and protein similarities with strain UTI 89 (O18:K1:H7), isolated from a patient with uncomplicated cystitis followed by strain 536 (O6:K15:H31), isolated from a patient with a complicated UTI and strain CFT073 (O6:K2:H1), isolated from a patient with pyelonephritis.
A subtractive hybridization study performed with a human UTI E. coli and an avian colisepticemia strain demonstrated that both group of strains have virulence determinants in common such as the Type Three Secretion System (TTSS) and iron uptake systems but shared few virulence related sequences (Mokady et al. 2005). In this study it was observed that non-common virulence-related DNA sequences found in ExPEC and APEC strains were phenotypically associated with the same pathogenic process. The authors suggested that both groups of strains were using different factors with similar roles in the various stages of the infection: adhesion mediated by pilus, internalization by curli fibers, invasion, and persistence in the host by the iron uptake systems and by the evasion from the host immune system. Altogether, these studies suggest that since APEC and human ExPEC and diarrhegenic E. coli may encounter similar challenges when establishing infection, they could share similar virulence genes and capacities to cause disease, indicating that APEC could serve as a reservoir and source of virulence genes for human pathogenic E. coli such as ExPEC and diarrheogenic E. coli.
Clonal relationship and pathogenic clone detection
Molecular typing based in repetitive extragenic palimdromic amplification (REP) and Enterobacterial repetitive intergenic (ERIC) sequences analysis have been used to the clonal characterization of Enterobacteriaceae. The dispersive distribution of these repetitive DNA sequences in microbial organisms can be detected by using conserved primer in polymerase chain reaction (PCR) (Hulton et al. 1991, Versalovic et al. 1991). Moura et al. (2001) using REP-PCR and ERIC-PCR techniques suggested that there was not an association between the phenotype and genotype of APEC strains isolated from chickens in Londrina (Paraná, Brazil), based on the great phenotypic and genotypic variability presented by the studied strains. Brocchi et al. (2006) also found a high genomic diversity among APEC strains using REP-PCR, but these authors concluded that this technique is not efficient to differentiate among APEC pathogenic clones. A clonal diversity study with commensal avian E. coil strains and APEC strains performed by Silveira et al. (2002b), using ERIC-PCR, demonstrated a relationship between the pathogenicity and the clonal origin of APEC strains. These observations were also made by Brito et al. (2003) in APEC strains isolated from chickens with cellulitis.
White et al. (1993), using multilocus enzyme electrophoresis (MLEE), observed that APEC strains causing septicemia in turkeys belonged to a mixture of specialized pathogenic clones and non-pathogenic opportunist clones. Using the same technique, Ngeleka et al. (1996) demonstrated that APEC isolated from chickens with cellulitis belonged to the same clonal complex and had similar phenotypic and genotypic characteristics of APEC causing septicemia. In addition, Silveira et al. (2003) using the same technique also demonstrated that pathogenic clones are more similar one to another when compared with commensal strains suggesting a correlation between the genetic background and the pathogenic characteristics of the avian pathogenic E. coli strains.
Ewers et al. (2004), using pulsed field gel electro-phoresis (PFGE), have verified the presence of a limited number of epidemic clones among APEC strains from different regions of Germany. However, the authors did not observe an association between virulence-related sequences and clonal clusters. Ewers et al. (2005) suggested that a horizontal gene transference of virulence genes could be responsible by the non association of virulence genes presence and pathogenic clonal clusters of APEC from Germany.
Altogether, these studies have demonstrated that APEC strains present a complex structure which could be responsible for the absence of a clear definition of pathotypes in these strains.
CONCLUSION
Although several advances have been made about the virulence factors of APEC strains, the exact role in the pathogenesis of these strains still remains unclear. It is apparent that APEC causes multi-factorial diseases, which involves host-pathogens interactions. Thus, molecular and biological characterization linked to appropriated animal models is needed to better understand the APEC patho-genesis.
Accepted for publication on March 12, 2009.
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Publication Dates
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Publication in this collection
21 Sept 2009 -
Date of issue
July 2009
History
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Accepted
12 Mar 2009 -
Received
11 Nov 2008