''Schistosoma'' is a

genus Genus ( plural genera ) is a taxonomic rank used in the biological classification of living and fossil organisms as well as viruses. In the hierarchy of biological classification, genus comes above species and below family. In binomial nom ...

trematode Trematoda is a class of flatworms known as flukes. They are obligate internal parasites with a complex life cycle requiring at least two hosts. The intermediate host, in which asexual reproduction occurs, is usually a snail. The definitive h ...

s, commonly known as blood flukes. They are

parasitic Parasitism is a close relationship between species, where one organism, the parasite, lives on or inside another organism, the host, causing it some harm, and is adapted structurally to this way of life. The entomologist E. O. Wilson ha ...

flatworm The flatworms, flat worms, Platyhelminthes, or platyhelminths (from the Greek πλατύ, ''platy'', meaning "flat" and ἕλμινς (root: ἑλμινθ-), ''helminth-'', meaning "worm") are a phylum of relatively simple bilaterian, unsegmen ...

s responsible for a highly significant group of

infection An infection is the invasion of tissues by pathogens, their multiplication, and the reaction of host tissues to the infectious agent and the toxins they produce. An infectious disease, also known as a transmissible disease or communicable di ...

s in

human Humans (''Homo sapiens'') are the most abundant and widespread species of primate, characterized by bipedalism and exceptional cognitive skills due to a large and complex brain. This has enabled the development of advanced tools, cultu ...

s termed ''

schistosomiasis Schistosomiasis, also known as snail fever, bilharzia, and Katayama fever, is a disease caused by parasitic flatworms called schistosomes. The urinary tract or the intestines may be infected. Symptoms include abdominal pain, diarrhea, blo ...

'', which is considered by the

World Health Organization The World Health Organization (WHO) is a specialized agency of the United Nations responsible for international public health. The WHO Constitution states its main objective as "the attainment by all peoples of the highest possible level o ...

as the second-most socioeconomically devastating parasitic

disease A disease is a particular abnormal condition that negatively affects the structure or function of all or part of an organism, and that is not immediately due to any external injury. Diseases are often known to be medical conditions that a ...

(after

malaria Malaria is a mosquito-borne infectious disease that affects humans and other animals. Malaria causes symptoms that typically include fever, tiredness, vomiting, and headaches. In severe cases, it can cause jaundice, seizures, coma, or death. ...

), with hundreds of millions infected worldwide. Adult flatworms parasitize blood capillaries of either the

mesenteries In zoology, a mesentery is a membrane inside the body cavity of an animal. The term identifies different structures in different phyla: in vertebrates it is a double fold of the peritoneum enclosing the intestines; in other organisms it forms com ...

plexus In neuroanatomy, a plexus (from the Latin term for "braid") is a branching network of vessels or nerves. The vessels may be blood vessels (veins, capillaries) or lymphatic vessels. The nerves are typically axons outside the central nervous system ...

of the bladder, depending on the infecting species. They are unique among trematodes and any other flatworms in that they are

dioecious Dioecy (; ; adj. dioecious , ) is a characteristic of a species, meaning that it has distinct individual organisms (unisexual) that produce male or female gametes, either directly (in animals) or indirectly (in seed plants). Dioecious reproducti ...

with distinct

sexual dimorphism Sexual dimorphism is the condition where the sexes of the same animal and/or plant species exhibit different morphological characteristics, particularly characteristics not directly involved in reproduction. The condition occurs in most an ...

between male and female. Thousands of eggs are released and reach either the bladder or the intestine (according to the infecting species), and these are then excreted in urine or feces to fresh water. Larvae must then pass through an intermediate snail Host (biology), host, before the next larval stage of the parasite emerges that can infect a new mammalian host by directly penetrating the skin.

Evolution

The origins of this

remain unclear. For many years it was believed that this genus had an African origin, but DNA sequencing suggests that the species (''S. edwardiense'' and ''S. hippopotami'') that infect the hippo (''Hippopotamus, Hippopotamus amphibius'') could be basal. Since hippos were present in both Africa and Asia during the Cenozoic era, the genus might have originated as parasitism, parasites of hippos. The original hosts for the South East Asian species were probably rodents. Based on the phylogenetics of the host snails it seems likely that the genus evolved in Gondwana between and . The sister group to ''Schistosoma'' is a genus of elephant-infecting schistosomes — ''Bivitellobilharzia''. The cattle, sheep, goat and cashmere goat parasite ''Orientobilharzia turkestanicum'' appears to be related to the African schistosomes. This latter species has since been transferred to the genus ''Schistosoma''. Within the ''haematobium'' group ''S. bovis'' and ''S. curassoni'' appear to be closely related as do ''S. leiperi'' and ''S. mattheei''. ''S. mansoni'' appears to have evolved in East Africa 0.43–0.30 million years ago. ''S. mansoni'' and ''S. rodhaini'' appear to have shared a common ancestor between 107.5 and 147.6 thousand years ago. This period overlaps with the earliest archaeological evidence for fishing in Africa. It appears that ''S. mansoni'' originated in East Africa and experienced a decline in effective population size 20-90 thousand years ago before dispersing across the continent during the Holocene. This species was later transmitted to the Americas by the slave trade. ''S. incognitum'' and ''S. nasale'' are more closely related to the African species rather than the ''japonicum'' group. ''S. sinensium'' appears to have radiated during the Pliocene. ''S. mekongi'' appears to have invaded South East Asia in the mid-Pleistocene. Estimated speciation dates for the ''japonicum'' group: ~3.8 million years ago for ''S. japonicum''/South East Asian schistosoma and ~2.5 million years ago for ''S. malayensis''/''S. mekongi''. ''Schistosoma turkestanicum'' is found infecting red deer in Hungary. These strains appear to have diverged from those found in China and Iran. The date of divergence appears to be 270,000 years before present.

Taxonomy

The genus ''Schistosoma'' as currently defined is paraphyletic, so revisions are likely. Over twenty species are recognised within this genus. The genus has been divided into four groups: ''indicum'', ''japonicum'', ''haematobium'' and ''mansoni''. The affinities of the remaining species are still being clarified. Thirteen species are found in Africa. Twelve of these are divided into two groups—those with a lateral spine on the egg (''mansoni'' group) and those with a terminal spine (''haematobium'' group).

Mansoni group

The four ''mansoni'' group species are: ''Schistosoma edwardiense, S. edwardiense'', ''Schistosoma hippotami, S. hippotami'', ''Schistosoma mansoni, S. mansoni'' and ''Schistosoma rodhaini, S. rodhaini''.

Haematobium group

The nine ''haematobium'' group species are: ''Schistosoma bovis, S. bovis'', ''Schistosoma curassoni, S. curassoni'', ''Schistosoma guineensis, S. guineensis'', ''Schistosoma haematobium, S. haematobium'', ''Schistosoma intercalatum, S. intercalatum'', ''Schistosoma kisumuensis, S. kisumuensis'', ''Schistosoma leiperi, S. leiperi'', ''Schistosoma margrebowiei, S. margrebowiei'' and ''Schistosoma mattheei, S. mattheei''. ''S. leiperi'' and ''S. matthei'' appear to be related. ''S. margrebowiei'' is basal in this group. ''S. guineensis'' is the sister species to the ''S. bovis'' and ''S. curassoni'' grouping. ''S. intercalatum'' may actually be a species complex of at least two species.

Indicum group

The ''indicum'' group has three species: ''Schistosoma indicum, S. indicum'', ''Schistosoma nasale, S. nasale'' and ''Schistosoma spindale, S. spindale''. This group appears to have evolved during the Pleistocene. All use pulmonate snails as hosts. ''S. spindale'' is widely distributed in Asia, but is also found in Africa. They occur in Asia and India. ''S. indicum'' is found in India and Thailand. The indicum group appears to be the sister clade to the African species.

Japonicum group

The ''japonicum'' group has five species: ''Schistosoma japonicum, S. japonicum'', ''Schistosoma malayensis, S. malayensis'' and ''Schistosoma mekongi, S. mekongi'', ''Schistosoma ovuncatum, S. ovuncatum'' and ''Schistosoma sinensium, S. sinensium'' and these species are found in China and Southeast Asia. ''Schistosoma ovuncatum, S. ovuncatum'' forms a clade with ''Schistosoma sinensium, S. sinensium'' and is found in northern Thailand. The definitive host is unknown and the intermediate host is the snail ''Tricula bollingi''. This species is known to use snails of the Family (biology), family Pomatiopsidae as hosts. ''Schistosoma incognitum, S. incognitum'' appears to be basal in this genus. It may be more closely related to the African-Indian species than to the Southeast Asian group. This species uses pulmonate snails as hosts. Examination of the mitochondria suggests that ''Schistosoma incognitum'' may be a species complex.Webster BL, Littlewood DT (2012) Mitochondrial gene order change in ''Schistosoma'' (Platyhelminthes: Digenea: Schistosomatidae). Int J Parasitol 42(3):313-321

New species

As of 2012, four additional species have been transferred to this genus., previously classified as species in the genus ''Orientobilharzia''. Orientobilharzia differs from Schistosoma morphologically only on the basis of the number of testes. A review of the morphological and molecular data has shown that the differences between these genera are too small to justify their separation. The four species are *''Schistosoma bomfordi'' *''Schistosoma datta'' *''Schistosoma harinasutai'' *''Schistosoma turkestanicum''

Hybrids

The hybrid ''S. haematobium-S.guineenis'' was observed in Cameroon in 1996. ''S. haematobium'' could establish itself only after deforestation of the tropical rainforest in Loum, Cameroon, Loum next to the endemic ''S. guineensis''; hybridization led to competitive exclusion of ''S. guineensis''. In 2003, a ''S. mansoni-S. rodhaini'' hybrid was found in snails in western Kenya, As of 2009, it had not been found in humans. In 2009, ''S. haematobium–S. bovis'' hybrids were described in northern Senegalese children. The Senegal River Basin had changed very much since the 1980s after the Diama Dam in Senegal and the Manantali Dam in Mali had been built. The Diama dam prevented ocean water to enter and allowed new forms of agriculture. Human migration, increasing number of livestock and sites where human and cattle both contaminate the water facilitated mixing between the different schistosomes in N'Der, for example. The same hybrid was identified during the 2015 investigation of a schistosomiasis outbreak on Corsica, traced to the Cavu river. In 2019, a ''S. haematobium–S. mansoni'' hybrid was described in a 14-year-old patient with hematuria from Côte d'Ivoire.

Cladogram

A cladogram based on 18S ribosomal RNA, 28S ribosomal RNA, and partial cytochrome c oxidase subunit I (COI) genes shows phylogenic relations of species in the genus ''Schistosoma'':

Comparison of eggs

File:Schistosoma haematobium egg 4842 lores.jpg, ''Schistosoma japonicum'' File:Schistosoma japonicum egg 4843 lores.jpg, ''Schistosoma haematobium'' File:Schistosoma mansoni egg 4841 lores.jpg, ''Schistosoma mansoni'' File:S mekongi eggR.jpg, ''Schistosoma mekongi'' File:S interculatum eggS.jpg, ''Schistosoma intercalatum''

Geographical distribution

Geographical areas associated with schistosomiasis by the World Health Organization as of January 2017 include in alphabetical order: Africa, Brazil, Cambodia, the Caribbean, China, Corsica, Indonesia, Laos, the Middle East, the Philippines, Suriname, and Venezuela. There had been no cases in Europe since 1965, until an outbreak occurred on Corsica.

Schistosomiasis

The parasitic flatworms of ''Schistosoma'' cause a group of chronic infections called

known also as bilharziasis. An anti-schistosome drug is a schistosomicide.

Species infecting humans

Parasitism of humans by ''Schistosoma'' appears to have evolved at least three occasions in both Asia and Africa. *''Schistosoma guineensis, S. guineensis'', a recently described species, is found in West Africa. Known snail intermediate hosts include ''Bulinus forskalii.'' *''Schistosoma haematobium, S. haematobium'', commonly referred to as the ''bladder fluke'', originally found in Africa, the Near East, and the Mediterranean Sea, Mediterranean basin, was introduced into India during World War II. Freshwater snails of the genus ''Bulinus'' are an important intermediate host for this parasite. Among final hosts humans are most important. Other final hosts are rarely baboons and monkeys. *''Schistosoma intercalatum, S. intercalatum.'' The usual final hosts are humans. Other animals can be infected experimentally. *''Schistosoma japonicum, S. japonicum'', whose common name is simply ''blood fluke'', is widespread in East Asia and the southwestern Pacific Ocean, Pacific region. Freshwater snails of the genus ''Oncomelania'' are an important intermediate host for ''S. japonicum.'' Final hosts are humans and other mammals including cats, dogs, goats, horses, pigs, rats and water buffalo. *''Schistosoma malayensis, S. malayensis'' This species appears to be a rare infection in humans and is considered to be a zoonosis . The natural vertebrate host is Müller's giant Sunda rat (''Sundamys muelleri''). The snail hosts are Robertsiella species (''R. gismanni'', ''R. kaporensis'' and ''R. silvicola'' (see Attwood et al. 2005 Journal of Molluscan Studies Volume 71, Issue 4 pp. 379–391). *''Schistosoma mansoni, S. mansoni'', found in Africa, Brazil, Venezuela, Suriname, the lesser Antilles, Puerto Rico, and the Dominican Republic. It is also known as ''Manson's blood fluke'' or ''swamp fever''. Freshwater snails of the genus ''Biomphalaria'' are an important intermediate host for this trematode. Among final hosts humans are most important. Other final hosts are baboons, rodents and raccoons. *''Schistosoma mekongi, S. mekongi'' is related to ''S. japonicum'' and affects both the superior and inferior mesenteric veins. ''S. mekongi'' differs in that it has smaller eggs, a different intermediate host (''Neotricula aperta'') and longer prepatent period in the mammalian host. Final hosts are humans and dogs. The snail ''Tricula aperta'' can also be experimentally infected with this species.

Species infecting other animals

''Schistosoma indicum'', ''Schistosoma nasale'', ''Schistosoma spindale'', ''Schistosoma leiperi'' are all parasites of ruminants. ''Schistosoma edwardiense'' and ''Schistosoma hippopotami'' are parasites of the hippo. ''Schistosoma ovuncatum'' and ''Schistosoma sinensium'' are parasites of rodents.

Morphology

Adult schistosomes share all the fundamental features of the digenea. They have a basic Symmetry in biology#Bilateral symmetry, bilateral symmetry, oral and ventral suckers, a body covering of a syncytium, syncytial integumentary system, tegument, a blind-ending Digestion, digestive system consisting of mouth, esophagus and bifurcated cecum, caeca; the area between the tegument and alimentary canal filled with a loose network of mesoderm Cell (biology), cells, and an excretory or osmoregulatory system based on flame cells. Adult worms tend to be long and use globins from their hosts' hemoglobin for their own circulatory system.

Reproduction

Unlike other trematodes and basically all other flatworms, the schistosomes are

, ''i.e.'', the sexes are separate. The two sexes display a strong degree of

, and the male is considerably larger than the female. The male surrounds the female and encloses her within his ''gynacophoric canal'' for the entire adult lives of the worms. As the male feeds on the host's blood, he passes some of it to the female. The male also passes on chemicals which complete the female's development, whereupon they will reproduce sexually. Although rare, sometimes mated schistosomes will "divorce", wherein the female will leave the male for another male. The exact reason is not understood, although it is thought that females will leave their partners to mate with more genetically distant males. Such a biological mechanism would serve to decrease inbreeding, and may be a factor behind the unusually high genetic diversity of schistosomes.

Genome

The genomes of ''Schistosoma haematobium'', ''S. japonicum'' and ''Schistosoma mansoni, S. mansoni ''have been reported.

History

The eggs of these parasitism, parasites were first seen by Theodor Bilharz, Theodor Maximilian Bilharz, a Germany, German Pathology, pathologist working in Egypt in 1851 who found the eggs of ''Schistosoma haematobium'' during the course of a Autopsy, post mortem. He wrote two letters to his former teacher Karl Theodor Ernst von Siebold, von Siebold in May and August 1851 describing his findings. Von Siebold published a paper in 1852 summarizing Bilharz's findings and naming the worms ''Distoma haematobium''. Bilharz wrote a paper in 1856 describing the worms more fully. Their unusual morphology (biology), morphology meant that they could not be comfortably included in ''Distoma''. So in 1856 Meckel von Helmsback (:de:Heinrich Meckel von Hemsbach, de) created the

''Bilharzia'' for them. In 1858 David Friedrich Weinland proposed the name ''Schistosoma'' (Greek: "split body") because the worms were not hermaphroditic but had separate sexes. Despite ''Bilharzia'' having precedence, the

name ''Schistosoma'' was officially adopted by the International Commission on Zoological Nomenclature. The term ''Bilharzia'' to describe infection with these parasites is still in use in medical circles. Bilharz also described ''Schistosoma mansoni'', but this species was redescribed by Louis Westenra Sambon in 1907 at the London School of Hygiene & Tropical Medicine, London School of Tropical Medicine who named it after his teacher Patrick Manson. In 1898, all then known species were placed in a subfamily by Stiles and Hassel. This was elevated to family status by Arthur Looss, Looss in 1899. Poche in 1907 corrected a grammar, grammatical error in the family name. The Biological life cycle, life cycle of ''Schistosoma mansoni'' was determined by the Brazilian parasitologist Pirajá da Silva (1873-1961) in 1908. In 2009, the genomes of ''Schistosoma mansoni'' and ''Schistosoma japonicum'' were decoded opening the way for new targeted treatments. In particular, the study discovered that the genome of ''S. mansoni'' contained 11,809 genes, including many that produce enzymes for breaking down proteins, enabling the parasite to bore through tissue. Also, ''S. mansoni'' does not have an enzyme to make certain fats, so it must rely on its host to produce these.

Treatment

Praziquantel

References

External links

British Department for International Development Control of SchistosomiasisThe World Health Organisation page on SchistosomiasisUniversity of Cambridge Schistosome LaboratorySchistosoma parasites overview, biology, life cycle image at MetaPathogen
{{Authority control Digenea genera Parasitic helminths of humans Diplostomida