Enterotoxigenic E. coli

ETEC is the most common cause of E. coli diarrhea in farm animals. This pathotype is characterized by the production of enterotoxins and of adhesins that adhere to the intestinal epithelium and promote colonization (Dubreuil et al. 2016). Enterotoxins produced by ETEC may be heat stable (STa, STb, or enteroaggregative E. coli heat‐stable enterotoxin 1, EAST1), or heat labile (LT). In pigs, the most frequently encountered fimbrial adhesins of ETEC are F4(K88), F5(K99), F6(987P), F41, and F18. Isolates producing the F4 or F18 adhesin and certain isolates producing F6 are hemolytic. In calves and lambs, the most important fimbrial adhesins of ETEC are F5 and F41. Colonies of ETEC that possess these adhesins are usually mucoid and nonhemolytic. F17 fimbriae are associated with bovine or ovine strains that cause diarrhea or septicemia. The virulence genes and O serogroups of ETEC most commonly associated with diarrhea in pigs, cattle, and sheep are shown in Tables 7.4 and 7.5.

ETECs cause severe watery diarrhea, which may lead to dehydration, listlessness, metabolic acidosis, and death. In some cases, especially in pigs, the infection may progress so rapidly that death occurs before the development of diarrhea and is referred to as enteric colibacillosis complicated by shock. Diarrhea is mostly observed in the first few days after birth and affects one or more animals in a group. A less watery diarrhea may be observed in pigs during the first one to two weeks of age, or as early as two days post‐weaning, with low mortality and often with decreased weight gain. In affected piglets of this age group, co‐infection with other pathogens such as transmissible gastroenteritis virus, rotavirus, or coccidia, is often observed. F4‐producing isolates occasionally proliferate rapidly in the small intestine of young pigs and induce symptoms of shock and rapid death. Enteric colibacillosis complicated by shock occurs in unweaned and recently weaned pigs, and manifests as rapid death with cutaneous cyanosis of the extremities, or less acutely with hyperthermia, diarrhea, and anorexia.

Post‐weaning diarrhea is seen as yellowish or gray fluid and most commonly starts three to five days after weaning, lasting up to a week and causing emaciation (Fairbrother and Nadeau 2019). Over several days, most of the pigs in a group may be affected and mortality of up to 25% may be observed. In farms where husbandry measures at weaning include addition of higher levels of protein of animal source, plasma, acidifying agents, or zinc oxide to the feed, peaks of diarrhea and enteric colibacillosis complicated by shock may be delayed, occurring up to eight weeks after weaning.

Postmortem findings of post‐weaning diarrhea may be dehydration, dilation of the stomach, gastric infarcts in the mucosa of the stomach, intestinal dilation (by fluid) and congestion, and hyperemia of the small intestine. Intestinal contents vary from yellow to green, watery to mucoid with blood sometimes, and a characteristic odor. On histopathology, layers of E. coli are observed adhering to the mucosa of the jejunum and ileum in newborn and post‐weaning pigs with ETEC infection. Bacteria are usually located at a distance of approximately half to one bacterial width away from the microvilli. Typically, there is no microscopic lesion. ETEC colonize the crypts of Lieberkühn and cover the apex of the villi. In cases of enteric colibacillosis complicated by shock, typical microscopic lesions of hemorrhagic gastroenteritis, congestion, and microvascular fibrinous thrombi and villus necrosis may be observed in the mucosa of the stomach, small intestine, and colon.

The O serogroups and virulence gene profiles (virotypes) of ETEC most commonly associated with diarrhea in post‐weaning pigs are shown in Tables 7.4 and 7.6. These ETECs are typically hemolytic and are predominantly O149, O8, O141, or O138.

In calves and lambs, diarrhea is mostly observed in the first few days after birth. Animals produce large amounts of foul‐smelling pasty to watery feces varying from pale yellow to white and occasionally containing flecks of blood. In acute cases, extensive loss of fluid leads to a marked decrease in body weight within six to eight hours of the onset of diarrhea. The intestinal mucosa usually appears normal on histopathology.

In dogs, ETEC have been associated with cases of diarrhea, especially in young animals, and rarely from healthy control groups of dogs.

Shigatoxigenic E. coli

Stx is the critical virulence factor in diseases caused by STEC. Edema disease in pigs is the only animal disease for which the role of Stx is clearly established. This subgroup of STEC is referred to as EDEC. However, there is evidence to implicate STEC in diarrhea and dysentery in calves and lambs. Affected calves show attaching and effacing lesions in the terminal ileum, colon and rectum, with edema and neutrophil infiltration of the lamina propria and an exudate of neutrophils, mucus, and exfoliated epithelial cells in the lumen. The lesions are more severe in colostrum‐deprived than in colostrum‐fed calves and may be induced with Stx1‐ or Stx2‐positive STEC.

Hemolytic uremic syndrome (HUS) occurs occasionally in young dogs of several breeds, in which there is a prodrome of bloody diarrhea followed by thrombocytopenia, microangiopathic hemolytic anemia, and anuric acute renal failure. The kidneys of affected dogs show renal proximal tubular necrosis and hemorrhage, and glomerular lesions consisting of hypertrophy, necrosis and loss of capillary endothelial cells, adherence of aggregated platelets to the basement membrane, fibrin thrombi, and fibrinoid necrosis of blood vessels.

Edema disease may be sporadic or may affect many litters or an entire herd and may be first recognized as sudden death without signs of illness. Some affected pigs become inappetent, develop swelling of the eyelids and forehead, emit a peculiar squeal, and show incoordination and respiratory distress. There is no diarrhea or fever.

Pigs that die of edema disease typically show gross lesions of edema and hemorrhage in some or all of the following sites: the subcutaneous tissues of the eyelids and forehead, the greater curvature of the stomach; the mesenteric lymph nodes, the colonic mesentery, and the brain, especially the cerebellum. Light and electron microscopy identify degenerative changes in vascular endothelial cells, thrombosis in blood vessels, perivascular edema and necrosis of vascular smooth muscle. EDEC recovered from affected pigs most commonly belong to O group 139, and less frequently to O group 138, or 141 (Table 7.4).

EDEC may or may not be enterotoxigenic. Those hybrid strains which are enterotoxigenic are known as ETEC/STEC and are most commonly associated with diarrhea.

Enteropathogenic E. coli

EPECs are a cause of diarrhea in several animal species, most importantly, in rabbits, pigs, and dogs. These strains induce AE lesions on the intestinal mucosa and are grouped in a category of E. coli called attaching and effacing E. coli (AEEC), which also includes EHEC strains. Healthy cattle, sheep and pigs, as well as dogs and cats, appear to be important reservoirs of AEEC, most of which are classified as EPEC producing the outer membrane protein adhesin intimin (Eae), encoded by the eae gene.

EPEC may be associated with post‐weaning diarrhea in pigs (Fairbrother and Nadeau 2019). Histopathological lesions range from mild and scattered through the large and small intestine, to severe and involving mostly the cecum and colon. They include light to moderate inflammation of the lamina propria, enterocyte desquamation and some mild ulceration, and light to moderate villus atrophy in the small intestine. Extensive multifocal bacterial colonization of the surface epithelium by a thin layer of coccobacilli, often oriented in a palisade pattern, is observed. Typical intimate attachment of bacteria to intestinal epithelial cells and effacement of microvilli are observed on electron microscopy.

EPEC are the pathogenic E. coli most commonly associated with diarrhea in dogs (Beutin 1999). There is at least one report of identical EPEC strains having been isolated from a diarrheic puppy and a young child in the same household. EPEC have also been isolated from cats. Cases in dogs have a history of gastrointestinal disease associated with histological and bacteriological evidence of AEEC. Typical attaching and effacing lesions are observed in the jejunum and ileum, to a lesser extent in the large intestine, and have been reported in the stomach of affected dogs. Many of these dogs originate from kennels and pet shops and are aged between 1.5 and 3 months. Co‐infection with other enteric pathogens, such as canine distemper virus, canine parvovirus, or coccidia, is often observed.

EPECs are the only important class of pathogenic E. coli in rabbits, being one of the principal infectious agents in diarrheic rabbits and causing 25–40% losses. Certain serotypes of EPEC, such as O109:H2 and O8:H?, are mainly pathogenic for suckling rabbits whereas other serotypes, such as O26:H11, O20:H7, O109:H7, O153:H7, O128:H2, and O132:H2, are associated predominantly with disease in weaned rabbits. EPEC of serotypes O2:H6, O15:H‐, O103:H2 are associated with disease in both suckling and weaned rabbits (Milon et al. 1999). In general, O109:H2 strains tend to cause severe and lethal diarrhea in suckling but not weaned rabbits, whereas O15:H‐, O103:H2, and some O26:H11 strains tend to induce severe diarrhea with a high mortality rate in weaned rabbits. EPEC strains of other serotypes tend to cause a mild diarrhea with possible weight loss.

In suckling rabbits, typical attaching and effacing lesions are observed over the entire length of the small and large intestines. In weanling rabbits, typical lesions are found mostly in the cecum, and to a lesser extent in the colon and ileum.

In suckling rabbits, diarrhea due to EPEC occurs at 3–12 days of age, with mortality of up to 100% within a litter. In weanling rabbits, diarrhea is observed at 5–14 days after weaning, with mortality of 5–50% and decreased weight.

Extraintestinal Pathogenic E. coli

ExPEC includes E. coli implicated in a wide range of infections including septicemia (septicemic E. coli, SEPEC), and infections of the urinary and genital tracts (uropathogenic E. coli, UPEC), the respiratory tract (avian pathogenic E. coli; APEC), and the mammary gland. The importance of ExPEC is increasing rapidly as they are constantly present in the intestinal microbiota of the various animal species and are increasingly becoming more resistant to antimicrobials (Vila et al. 2016; Biran and Ron 2018). Some ExPEC recovered from disease in humans and animals share several virulence factors and animals may be reservoirs of some of these pathogens that cause disease in humans. ExPEC are found in the normal intestinal microbiota. In contrast to ETEC, EPEC, and STEC, they are not characterized by the presence of a particular virulence factor or group of factors but usually possess a large number of virulence factors, which may vary greatly among strains. These are now commonly grouped into functional categories (see Section Virulence factors). There are several gene clusters for similar activities within each functional category and an ExPEC strain may carry one or more of them (Tables 7.4,7.5, and 7.7; Biran and Ron 2018). ExPEC strains usually carry at least one gene cluster for adherence, iron‐binding, and serum survival. ExPEC mostly occur in phylogroups B2, F, or G, although certain strains of other phylogroups have acquired sufficient virulence factors, probably by horizontal gene transfer, to become ExPEC (Vila et al. 2016). Conversely, some B2 strains that are ExPEC‐like also show characteristics defining diarrheagenic pathotypes such as adherent and invasive E. coli (Dogan et al. 2020). Many of the specialized traits distinguishing ExPEC from other E. coli are now considered as “fitness” rather than “virulence” factors, as they mediate host colonization and persistence without resulting in disease (Vila et al. 2016).

In pigs, E. coli septicemia occurs in neonates and less frequently in suckling animals. It is characterized by an acute generalized infection, sometimes with diarrhea at the terminal stage, with signs of shock, often followed by death in three to eight hours, with fatality of up to 100%. The infection may become localized causing polyarthritis, pneumonia, metritis, abortion, or meningitis.

In acute primary septicemia, there may be no gross lesions but congestion of the intestine, the mesenteric lymph nodes and the extraintestinal organs may be observed. In subacute cases, subserosal or submucosal hemorrhages and fibrinous polyserositis with gross lesions of pneumonia are usually observed, and may be accompanied by fibrinopurulent arthritis and meningitis.

In pigs manifesting symptoms of shock and rapid death, typical histopathological lesions of septicemia such as hemorrhagic gastroenteritis, congestion, renal hemorrhage, and thrombi in the mucosa of the stomach and small intestine are observed. These lesions probably result from the rapid release of bacterial LPS from the intestine into the circulation.

In ruminants, E. coli septicemia occurs in calves in the first few days of life and in lambs at two to three weeks of age. Bacteria enter the host across the intestinal epithelium, or through the umbilicus. The clinical signs and localizations are as described for pigs. Bacteria are excreted in nasal secretions, urine, and feces in affected animals. On postmortem examination of calves with peracute disease, there are usually petechial hemorrhages on the epicardium and serosal surfaces and there may be pulmonary edema and hemorrhage and enlargement of the spleen. Fibrinous polyarthritis and meningitis may be observed in chronic cases.

In poultry, clinical signs vary with age. Young birds, often following yolk sac infection and/or omphalitis, may die rapidly of septicemia at a high prevalence with enlargement of the liver and spleen and increased fluid in body cavities. This first week mortality results from colonization of day‐old chickens by APEC originating from the parents (Christensen et al. 2021). This vertical transmission may occur following surface contamination of eggs from the environment of the parents and may lead to infection of the embryo if the bacteria penetrate the eggshell. The bacteria then spread horizontally during hatch and subsequent handling and transport of chicks. The risk of this transmission has been associated with broiler parents older than 43 weeks of age and following the use of floor eggs.

Respiratory tract infection with APEC results in depression and fever in birds of four to nine weeks of age and may result in extensive economic losses, with up to 20% mortality. Air sacs of infected birds are thickened and often have a caseous exudate on the respiratory surface. On histopathology, edema is the earliest change and initial infections are characterized by airsacculitis with a serous to fibrinous exudate, an initial infiltration with heterophils and a subsequent predominance of macrophages, which is frequently followed by a general infection commonly resulting in perihepatitis and/or pericarditis. In laying birds, APEC may infect the oviduct via the left abdominal air sacs leading to salpingitis and loss of egg laying ability. APEC may invade the peritoneal cavity via the oviduct, leading to peritonitis and death in caged layer hens. APEC may also cause a syndrome called swollen head syndrome characterized by gelatinous edema of the facial skin and periorbital tissues, and caseous exudate in the conjunctival sac, facial subcutaneous tissues and lacrimal gland.

APEC are also associated with asymptomatic cellulitis of the lower abdomen and thighs. The skin is discolored and yellowish fibrinocaseous plaques are found in the subcutaneous tissues underlying the skin lesions.

E. coli is the pathogen that is most frequently implicated in urinary tract infections (UTI) in dogs, cats, and humans. Infection, which is more common in dogs than in cats, is most frequently manifested as cystitis but urethritis, pyelonephritis and prostatitis are also seen.

E. coli mastitis can develop in any host species but is most common in dairy cattle, particularly in high‐producing animals, in the first two weeks after calving, and in animals with low somatic cell counts. Infection of the mammary gland by E. coli results in mild to severe inflammation and a clinical course of mastitis, which may be peracute, acute, or chronic.

Granulomatous colitis is a rare type of inflammatory bowel disease occurring in Boxer dogs and French bulldogs (Dogan et al. 2020). Clinical signs include colitis, hematochezia, and weight loss, progressing to cachexia. Invasive E. coli may be observed in colonic macrophages. Isolated E. coli resemble ExPEC, possessing several of the ExPEC‐associated virulence genes.

Adhesins

Toxins

Enterotoxins

E. coli enterotoxins cause disturbances in intestinal fluid metabolism but do not produce pathological lesions or morphological changes in the intestinal mucosa. Two major classes of enterotoxin are produced by ETEC (Dubreuil et al. 2016): low molecular weight, poorly antigenic heat‐stable toxins, which are resistant to 100°C for 15 minutes, and high molecular weight, highly antigenic heat‐labile toxin (LT), which is inactivated at 60°C for 15 minutes. Both types of enterotoxin are plasmid encoded. This family of enterotoxins consists of STa (or STI), STb (or STII) and EAST1, differentiated on the basis of size, molecular structure, and biological activity. The LT family of enterotoxins consists of LTI and LTII, which differ in their antigenicity but have similar biological activity associated with similar A subunits. The secretion and delivery of LT and STa appear to be associated with bacterial contact with the intestinal epithelium (Zhu et al. 2018).

STa

STa is an 18‐ or 19‐amino acid peptide of about 2000 Da, which is produced as a 72‐amino acid pre‐pro‐peptide, transported across the inner membrane, folded in the periplasm in which three intramolecular disulfide bonds are formed by DsbA protein, then secreted through TolC. STa has been designated STaP (produced by bovine, porcine, and human ETEC) or STaH (produced by human ETEC), based on minor differences in composition. All forms of STa have a conserved C‐terminal 13 amino acids which include three disulfide bonds.

STa binds to a guanyl cyclase C (GCC) glycoprotein receptor on the brush border of villous and crypt intestinal epithelial cells and activates guanyl cyclase, which stimulates production of cyclic guanosine monophosphate (cGMP; Figure 7.1a; Liu et al. 2020b). Elevated concentration of cGMP results in (i) phosphorylation of cGMP‐dependent protein kinase II (cGMPKII), which phosphorylates and thereby stimulates the cystic fibrosis transmembrane conductance regulator (CFTR) chloride channel; and (ii) inhibition of phosphodiesterase 3 (PDE₃) leading to accumulation of cAMP which activates protein kinase A (PKA). PKA then turns on CFTR and also inhibits sodium/hydrogen exchanger 3 (NHE₃) leading to release of Cl⁻ and HCO₃⁻ through CFTR into the intestinal lumen and to inhibition of Na⁺ reabsorption from the intestinal lumen (Figure 7.1a). Binding of STa to GCC on villous enterochromaffin cells also appears to stimulate neural pathways. Here, the increased levels of cGMP trigger the release of paracrine mediators such as serotonin and neurotensin into the subepithelial space, leading to release of secretagogues, such as vasoactive intestinal peptide, which attach to receptors on the enterocytes and stimulate fluid secretion. Based on the concentration and affinity of STa receptors, the posterior jejunum appears to be the major site of hypersecretion in response to STa. STa also appears to induce intestinal secretion in mice by binding to receptors other than GCC (Sellers et al. 2008).

The effects of STa are reversible. STa is active in infant mice and young pigs but is less active in older pigs, consistent with decreasing affinity and density of STa receptors with increasing age. Not surprisingly, ETEC strains that produce STa as the only enterotoxin are associated with disease in neonatal pigs, calves, and lambs.

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