5–12 μm. In common with other diplomonads, there are no mitochondria, but they possess a row of hydrogenosomes alongside the axostyle. This arrangement distinguishes T. vaginalis from other trichomonad species. Hydrogenosomes probably derive from mitochondria but unlike the more degenerate mitosomes, they make ATP, as well as the hydrogen that gives them their name. Interestingly, although T. vaginalis only infects us, molecular evidence indicates that it originated in pigeons and subsequently switched hosts (Peters et al. 2020).
Figure 3.7 Trichomonas vaginalis. This protozoan parasite expresses only one body shape, but its size varies considerably: the length can be 7–32 μm, whilst the width is 5–12 μm. Five flagellae emerge at the anterior end: four of these flagella are free whilst the fifth curves back to form a short undulating membrane that extends just over half the length of the cell.
Although T. vaginalis infects millions of women every year, most of them remain asymptomatic. The protozoa feed on bacteria and sloughed off epithelial cells present in the reproductive tract. However, in some women the parasites induce a severe inflammatory response that manifests as a copious frothy white or greenish vaginal discharge. Infection during pregnancy is often associated with poor outcomes such as premature delivery and below‐average birth weight for the baby, although whether the parasite induces these effects is uncertain.
3.3.2.3 Trichomonas tenax
This is a common human parasite and occurs throughout the world. It is rather like T. vaginalis in appearance although it is slightly smaller (5–16 μm long, 2–15 μm wide), has a somewhat shorter undulating membrane, and the hydrogenosomes are arranged differently. Molecular studies indicate a close similarity between the two species and T. tenax may be a variant of T. vaginalis (Kucknoor et al. 2009). Trichomonas tenax is usually restricted to the oral cavity where it feeds on bacteria and tissue debris.
Trichomonas tenax does not form cysts and cannot survive passage through the digestive tract. Consequently, transmission probably involves contamination via kissing and the sharing of food and eating/drinking utensils. It is less host fastidious than T. vaginalis, and in addition to humans, it infects various domestic animals, including cats and dogs (Kellerová and Tachezy 2017). There is therefore the potential for zoonotic transmission between those besotted owners who inexplicably kiss their pets and those who do not follow basic hygiene during food preparation and consumption.
Although T. tenax is associated with periodontal diseases (Marty et al. 2017), it is also common in people with good dental hygiene. This is probably because strains of T. tenax differ in their pathogenicity (Benabdelkader et al. 2019). There are occasional reports of bronchopulmonary infections, but these are usually associated with pre‐existing pulmonary conditions, such as cancer.
3.3.2.4 Trichomonas gallinae
Trichomonas gallinae has a worldwide distribution and is a common parasite of poultry, pigeons, and many other birds. In doves and pigeons, it causes a condition called ‘canker’ whilst in birds of prey the condition is known as ‘frounce’. It lives predominantly in the upper digestive tract and particularly the crop. In contrast, the related species Tetratrichomonas gallinarum tends to live in the lower digestive tract, caeca, and sometimes the liver.
The trophozoites of T. gallinae are usually ovoid in shape, 7–11 μm in length, and have four free flagella with a fifth recurving to form an undulating membrane (Figure 3.8). There is no cyst stage. Strains differ in their pathogenicity and pigeons, doves, and other members of the colubriformes are more badly affected than most other birds. In addition, raptors such as peregrine falcons (Falco peregrinus) and sparrowhawks (Accipiter nisus) that consume pigeons often suffer badly from T. tenax infections, and this can have consequences for their conservation (Dudek et al. 2018).
Avian trichomoniasis (trichomonosis) is an emerging disease in finches and other passerine birds in the UK, Europe, and Canada (Chi et al. 2013; Forzán et al. 2010). The first report of the problem was from the United Kingdom in 2005. Since then, it has become an ongoing epidemic as migrating birds spread the parasite across the country and throughout Europe. In the United Kingdom, this has resulted in a catastrophic decline in the number of greenfinches (Chloris chloris). In Europe, the epidemic is associated with a single clonal strain of T. tenax that is distinct from the strain causing extensive bird mortalities in America (Alrefaei et al. 2019).
Figure 3.8 Trichomonad parasites of animals. (a): Tritrichomonas foetus; (b): Trichomonas gallinae.
Source: Reproduced from Chandler and Read, (1961), © Wiley‐Blackwell.
The pathogenic strains of T. tenax induce lesions in the wall of the intestine and the parasites, then spread around the bird’s body and cause liver pathology similar to that of Histomonas meleagridis. Young birds are the worst affected, and whilst adults are often infected, they do not show evidence of disease – although they act as carriers of infection. In badly affected birds, necrotic lesions to the intestine and mouth can extend to the bones.
Pigeons often clash bills during social interactions and until they are 10 days old; young squabs feed by pushing their beaks into their parent’s mouth to feed on ‘milk’ held within the parent’s crop. This provides many opportunities for parasite transmission to occur. Trichomonas tenax probably spread from pigeons to finches through infected pigeons contaminating garden birdbaths. In addition, in the United Kingdom, there has been a marked rise in the population of wood pigeons, and this has probably increased the levels of contamination. The parasites can survive for up to 1 hour in water, so a single infected bird can potentially infect many others after using a popular birdbath. They can also survive on moist but not dry bird seed, so it is possible that in some circumstances bird feeders may act as an additional source of infection (McBurney et al. 2017).
3.3.2.5 Tritrichomonas foetus
This is a sexually transmitted parasite of cattle, and although it is also found as a sexually transmitted infection in other animals (e.g., horses), it is not usually pathogenic in them. The trophozoite of T. foetus is a pear‐shaped organism 10–25 μm long and 3–15 μm wide with four anterior flagella, three of which are free and one flagellum curves backwards to form an undulating membrane that extends the length of the body and then projects freely from the posterior apex (Figure 3.8). There is no cyst stage although they form pseudocysts in response to iron depletion. It is uncertain whether the pseudocyst stage plays an important role in parasite transmission.
In bulls, the parasites are usually found in the preputial cavity and cause little harm although there is sometimes inflammation that causes painful urination and unwillingness to copulate. In cows, the parasite causes more serious pathology. The infection begins with vaginitis and then spreads to the uterus where they can cause early abortion and permanent sterility. The parasite remains in the lumen and does not penetrate the underlying tissues.
There are increasing reports of T. foetus causing large bowel diarrhoea in domestic cats in the UK, USA, and parts of Europe. The parasites isolated from cats are morphologically identical to those from cattle, and there are only very minor differences in their DNA sequences (Yao and Köster 2015). Therefore, the current consensus is that they represent two isolates of a single species. However, in cats, transmission of the parasite occurs through faecal–oral