Chlamydia abortus

C. abortus is responsible for enzootic abortion of ewes, also known as ovine enzootic abortions, an economically important disease of sheep occurring globally in ruminant‐rearing regions, with the exception of Australia and New Zealand (Rodolakis and Laroucau 2015; Jelocnik 2019). Ewes and goats experience late term abortions, stillbirths, or delivery of weak, non‐thriving offspring. C. abortus is thought to be transmitted via the oronasal route by contamination of the environment from abortigenic material and fetuses, vaginal discharges from aborting ewes and fecal shedding, although sexual transmission is also plausible (Wattegedera et al. 2020). When a non‐pregnant ewe or a ewe lamb is exposed to the pathogen, the C. abortus infection can remain latent and asymptomatic. However, when the ewe becomes pregnant, the organism invades the placenta and begins to proliferate, eventually causing abortion in the last two to three weeks of gestation (Gutierrez et al. 2011; Wattegedera et al. 2020). This increased incidence of abortion cases can persist until a large proportion of ewes in the flock have aborted. After aborting, the ewes and goats develop protective immunity to C. abortus but may continue to shed the organism. The disease takes on a cyclic nature that may result in “storms of abortion” when new introductions or primiparous ewes enter the flock (Gutierrez et al. 2011; Rodolakis and Laroucau 2015).

Chlamydial placentitis develops late in gestation, evidenced by placental lesions from days 90–100 of gestation onwards, and from then on gradually progresses to a diffuse inflammatory response, with thrombotic vasculitis and tissue necrosis. Grossly, the C. abortus infected placenta reveals edema, thickening, hemorrhage, necrosis, and purulent exudate. Histopathological examination often shows a purulent to necrotizing placentitis with vasculitis, mixed inflammatory infiltration with predominantly polymorphonuclear neutrophils and intratrophoblastic basophilic chlamydial inclusions can be observed (Livingstone et al. 2017). Fetal infection is secondary to placentitis and can result in focal necrosis in liver, lung, spleen, and less frequently in lymph nodes and brain (Borel et al. 2018).

C. abortus infections also occur in cattle, pigs, yaks, deer, horses, a variety of birds and farmed fur animals, associated with epididymitis, pneumonia, arthritis, and conjunctivitis in ruminants and asymptomatic fecal shedding (Rodolakis and Laroucau 2015; Borel et al. 2018). C. abortus presents a documented zoonotic risk to humans, particularly to pregnant women, and those actively working with small ruminants, including veterinarians and production workers (Pichon et al. 2020). The route of transmission to humans for C. abortus is uncertain, but both direct and indirect contact with infected placenta and infective secretions are likely routes. In humans, clinical manifestation of C. abortus infection can range from mild flu‐like symptoms or pneumonia to severe illness and abortion (Pichon et al. 2020).

Chlamydia pecorum

C. pecorum is a well‐recognized pathogen of domesticated livestock and wildlife, infecting a broad range of hosts, including sheep, cattle, goats, pigs, free‐range ruminants such as ibex and deer, birds, koalas, and other marsupials. In livestock, C. pecorum infections have been associated with sporadic cases of encephalomyelitis, abortions, polyarthritis, conjunctivitis, enteritis, mastitis, pneumonia, reproductive disorders, and asymptomatic fecal shedding. The infection is thought to be endemic in livestock with most infections being clinically inapparent. However, subclinical C. pecorum infections may impact herd performance, leading to chronic pathological changes associated with reduced growth rates in calves (Reinhold et al. 2011).

Ovine C. pecorum polyarthritis (often accompanied by keratoconjunctivitis) is an economically important disease affecting one or more joints, and resulting in swollen joints, palpable synovial joint effusions, lameness, stiffness, anorexia, and weight loss in young sheep (Walker et al. 2018; Ostfeld et al. 2020). Ovine arthritis is characterized by an inflammatory and proliferative response in synovial membranes possibly progressing to chronic changes with articular erosions and fibrotic thickening (Ostfeld et al. 2020). In ruminants, C. pecorum keratoconjunctivitis, characterized by conjunctival reddening, discharge, and blepharospasm, can lead to prominent conjunctival follicular formation, corneal neovascularization and scarring, leading to blindness (Walker et al. 2018; Jelocnik et al. 2019b). Infected cattle can exhibit a range of clinical disease such as sporadic bovine encephalomyelitis (SBE), pneumonia, enteritis, reproductive pathologies (abortions, vaginitis, endometritis) and mastitis (Reinhold et al. 2011). In young cattle, C. pecorum infection can cause fatal SBE, characterized with encephalomyelitis, systemic infection, and fibrinous polyserositis, including pericarditis, pleuritis, peritonitis, and arthritis (Jelocnik et al. 2014). C. pecorum can also cause sporadic abortions in small ruminants and cattle (Struthers et al. 2021; Westermann et al. 2021). Pathological observations may show marked diffuse necrosuppurative placentitis with vasculitis, thrombosis and inflammatory cell infiltration (Westermann et al. 2021), similar to that observed in ovine C. abortus abortion. Furthermore, fetal brain, liver and lung lesions with enteritis and cryptitis can be present (Westermann et al. 2021). In cattle, aborted fetuses, multifocal random suppurative or mononuclear meningoencephalitis with vasculitis can be observed (Struthers et al. 2021).

Chlamydia suis

C. suis is an economically important pig pathogen associated with a range of diseases, such as conjunctivitis, enteritis, pneumonia, pericarditis, polyarthritis, and polyserositis in piglets, and reproductive problems, including vaginal discharge, return to estrus, abortion, increased perinatal and neonatal mortality, epididymitis, and urethritis in adult pigs (Schautteet and Vanrompay 2011). The pathogenicity of C. suis remains unclear, as it is also commonly found in the gastrointestinal tract of pigs as an endemic and generally asymptomatic infection (Hoffmann et al. 2015), although some studies have demonstrated an impact of infections on health and production. C. suis is the only chlamydial species known to have naturally acquired a tetracycline class C (tetC) gene that encodes tetracycline resistance, causing concerns that this resistance will become widespread under selective pressure of tetracycline treatment of fattening pig herds (Wanninger et al. 2016; Unterweger et al. 2020). The zoonotic transmission of C. suis from pigs to humans has been documented, although only with extensive contact (De Puysseleyr et al. 2017).

Chlamydia psittaci

C. psittaci is primarily considered an avian pathogen; however, this species also causes infections in cattle, horses, sheep, and pigs, with growing evidence of transmission from birds to livestock (Cheong et al. 2019). Although C. psittaci infections in livestock are mostly subclinical, they are associated with reduced performance (such as retarded growth of calves, reduced fertility, and decreased milk yield) and respiratory disease (acute bronchopneumonia) in cattle (Ostermann et al. 2013). In both sheep and cattle, C. psittaci infection is also associated with infectious keratoconjunctivitis (Osman et al. 2013).

Globally, sporadic reports of equine C. psittaci infections that may result in reproductive loss and/or abortions are well described. However, this pathogen may also cause equine abortion epizootics (Jelocnik 2019). The mechanism of equine chlamydial abortion remains unknown; however, histopathology studies reveal mild, diffuse, interstitial placentitis, deep chorionitis and allantoitis, amnionitis, and funisitis. In the fetus, acute non‐suppurative interstitial pneumonia with vasculitis and multifocal hepatitis was observed (Jenkins et al. 2018). This pathogen was also described in cases of acute respiratory distress in live neonatal foals. Molecular epidemiology indicated that these equine abortions could result from C. psittaci spillover from birds. Additionally, equine chlamydiosis was associated with apparent zoonotic transmission of C. psittaci from equine placental membranes to humans, a previously unrecognized route of transmission (Jelocnik 2019).

Chlamydia psittaci

C. psittaci is disseminated globally with a broad avian host range, infecting over 500 avian species with highest prevalence in pigeons and psittacine birds (Knittler et al. 2014; Radomski et al. 2016). In avian hosts, C. psittaci infections may vary from subclinical with persistent organism shedding to severe acute disease. Disease presentations in affected birds include wasting, lethargy, air sacculitis, hepatitis, pericarditis, conjunctivitis, and respiratory symptoms including nasal mucopurulent discharge, and pneumonia (Radomski et al. 2016). Between birds, C. psittaci transmission typically occurs by inhalation of the respiratory exudate, but the bacteria can also be excreted in fecal and nasal discharges and feather dust (Knittler et al. 2014).

The zoonotic potential of veterinary chlamydial species is best demonstrated by human C. psittaci infections. Humans can become infected through inhalation of aerosolized bacteria, and through the handling of contaminated feathers, feces, or carcasses (Hulin et al. 2015). In humans, C. psittaci predominantly causes respiratory infections with highly variable clinical symptoms, ranging from asymptomatic to mild or severe pneumonia, and even including often‐fatal systemic disease with involvement of different organs (Radomski et al. 2016). As such, zoonotically acquired C. psittaci infections are an occupational hazard for animal workers, veterinarians, and healthcare workers (Hogerwerf et al. 2020).

Chlamydia gallinacea and Chlamydia avium

The globally distributed avian species C. gallinacea is endemic in chickens but can also infect other poultry and wild birds (Cheong et al. 2019). C. gallinacea‐infected chickens may remain asymptomatic but show significant body weight reduction impacting production (Guo et al. 2016). C. avium has been detected in pigeons and captive psittacids and is likely to cause respiratory disease in parrots and fatal disease in pigeons (Kik et al. 2020; Popelin‐Wedlarski et al. 2020). The pathogenic and zoonotic potential has yet to be elucidated for C. gallinacea and C. avium, as well as other recently described avian species (C. buteonis, Ca. Chasiempis ibidis).

Chlamydial Infections in the Koala (Phascolarctos cinereus)

Chlamydial infections in the iconic Australian marsupial the koala are one of the most researched chlamydial infections of wildlife. Both C. pecorum and genetically distinct animal C. pneumoniae strains can infect the koala; however, C. pecorum is the most prevalent pathogen. C. pecorum infections and associated disease pose a very serious threat to the long‐term survival and conservation of this unique Australian native animal (Quigley and Timms 2020).

Almost all Australian mainland koala populations are infected with C. pecorum, with prevalence of infection of 21–88%. The pathogen can be readily detected shedding at the ocular, nasal, urogenital, and rectal sites. Sexual contact, direct contact with infectious discharges from the eyes and/or urogenital tract of infected koalas, and dam to joey transmission are considered routes of transmission for this infection (Jelocnik et al. 2019a; Quigley and Timms 2020). In koalas, C. pecorum infection can manifest as asymptomatic through to severe ocular, urogenital and respiratory disease.

In the eyes, C. pecorum infects the conjunctiva and can lead to keratoconjunctivitis, corneal scarring, and eventual blindness. Acute conjunctivitis is often characterized by serous discharge, blepharospasm, and hyperemia of the conjunctiva and sclera, while in a chronic active conjunctivitis, purulent discharge, conjunctival hyperplasia, chronic active neutrophilic and lymphocytic keratitis with corneal neovascularization and fibrosis can be observed. If left untreated, a chronic inactive keratoconjunctivitis characterized by extensive conjunctival hyperplasia, minimal erythema and mature scarring develops, eventually causing blindness (Gonzalez‐Astudillo et al. 2019).

The urogenital C. pecorum infections (including the urethra, ureters, bladder, and kidneys, upper reproductive tract in females, and prostate, epididymis, and testes in males), can develop into urethritis, cystitis, and/or pyelonephritis. Acute cystitis is characterized by thickening of the bladder wall, with or without pyuria, in both males and females, and fibrosis and ovarian bursal cysts in females. Both can cause severe pain, polyuria and/or urinary incontinence, leading to characteristic “wet‐bottom” (urine staining of the rump fur). Renal complications include hydronephrosis, pyelonephritis, and renal crystal precipitation (e.g. struvite and calcium oxalate). If infection establishes in the reproductive tract, inflammation in both females (e.g. salpingitis, endometritis, vaginitis) and males (e.g. epididymitis, orchitis, urethritis) can lead to infertility (Gonzalez‐Astudillo et al. 2019).

Other less common chlamydial disease can present as a syndrome of rhinitis/pneumonia with coughing, and copious oronasal mucopurulent exudate caused by both C. pneumoniae and C. pecorum. Chlamydial infections in koalas are often accompanied by other comorbidities such as neoplasia, wasting, other infectious diseases, and trauma (Jelocnik et al. 2019a). Chlamydial infections have been described in other Australian native marsupials (e.g., gliders, possums, quolls and bandicoots), but the impact in these hosts remains unknown (Jelocnik 2019).

Virulence Factors and Pathogenomics

Advances in the field of Chlamydia genomics, including both culture‐independent sequencing methods and analytical approaches, have led to deeper understanding of their biology, epidemiology, and pathogenesis. Chlamydia rely on a suite of T3SS effector proteins, which are exported across the bacterial and inclusion membranes into the host cell where they modulate host cell functions. Some of these are believed to be essential to the replication of the organism while others are predicted to confer pathogenic advantage.

Similar to many other intracellular bacteria, members of the genus Chlamydia have conserved reduced genomes of up to 1.5 Mb, with 850–1050 coding sequences (Sigalova et al. 2019). Systematic analyses of whole genome sequences from across the Chlamydia genus has demonstrated that about 75% of genes are universally conserved throughout the genus, likely representing core functions for all, and 382 unique coding sequences were present only in particular genomes, likely important for host‐ or tissue‐specific functions (Sigalova et al. 2019). Almost all Chlamydia, except C. abortus and rare plasmid‐free C. trachomatis isolates, contain a small, highly conserved, non‐conjugative or integrative virulence plasmid containing eight coding sequences and no antibiotic resistance genes (Sigar et al. 2014; Zhong 2017). C. pecorum comparative genomics revealed that the plasmid was common in strains infecting livestock and koalas, but not all C. pecorum strains carry the plasmid (Jelocnik et al. 2015). In C. muridarum, the plasmid was important for chlamydial colonization in the gastrointestinal and urogenital tracts (Ma et al. 2020). Finally, in contrast to many other bacteria, the Chlamydia spp. display no evidence of antibiotic resistance, with the only exception being the tetracycline resistance gene tetA(C), which is found on the genomic Tet‐island in C. suis and encodes a tetracycline efflux system (Marti et al. 2017; Seth‐Smith et al. 2017).

Pathogenomics research has revealed that there are certain loci that are subject to expansion in particular species or strains, suggesting that these are factors for host specificity. A subset of known virulence factors is described here in more detail, including the major outer‐membrane protein (MOMP), the polymorphic membrane proteins (Pmps), T3SS effectors including inclusion membrane proteins (Incs), the chlamydial plasmid, and some metabolic factors.

The chlamydial MOMP (encoded by ompA) is a membrane‐associated protein, with immunodominant hypervariable domains exposed on the outside of chlamydial elementary body. These outer surface regions have multiple T‐ and B‐cell epitopes that induce T‐cell immunity and neutralizing antibodies (Hepler et al. 2018).

The Pmp family of proteins are membrane‐bound, surface‐exposed autotransporters known or expected to have a variety of functions related to host–pathogen interactions, including host cell adhesion and virulence. All Chlamydia species have genes encoding Pmps, which may constitute up to 13% of their genome coding capacity; however, the number of copies varies widely across the species (Vasilevsky et al. 2016). One subset of pmp genes is likely to undergo phase variation, that is the random, high‐frequency, reversible switching of gene expression from on to off. This trait is conferred by homopolymeric polyG tracts in C. pneumoniae and C. abortus that can cause replication‐coupled frameshifting (Sigalova et al. 2019).

Chlamydiae

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