Borrelia turicatae

Last updated

Borrelia turicatae
Scientific classification OOjs UI icon edit-ltr.svg
Domain: Bacteria
Phylum: Spirochaetota
Class: Spirochaetia
Order: Spirochaetales
Family: Borreliaceae
Genus: Borrelia
Species:
B. turicatae
Binomial name
Borrelia turicatae
(Brumpt 1933) Steinhaus 1946

Borrelia turicatae is a bacterial species of the spirochaete class of the genus Borrelia . [1] It is one of the relapsing fever spirochaetes, which are globally distributed yet understudied agents of tick-borne relapsing fever. [2] The tick vector Ornithodoros turicata transmits B. turicatae, which causes relapsing fever, an arthropod-borne infection of humans and other mammals caused by different Borrelia species. [1] [3] [4] B. turicatae is long and spiral-shaped, as is typical for all spirochaetes. [5] It is a Gram-negative bacterium and visible with light microscopy. [5] Few epidemiological studies have been performed and few molecular data exist for B. turicatae and its arthropod vector O. turicata. [2]

Contents

Distribution

Borellia turicatae is predominant in the Southwestern United States. [2] Endemic foci for B. turicatae occur in Texas and Florida, where clinical isolates have been obtained from sick dogs, suggesting a role for wild canids in the maintenance of the spirochaetes in nature. [2] O. turicata has also been reported to be distributed in Mexico and Central and South America, yet given the absence of Latin American isolates for B. turicatae, the identification of endemic foci is unclear. [2]

Host species

Currently, the only known isolates of B. turicatae originate from argasid soft ticks and sick dogs, although the mammalian hosts for most species of relapsing fever spirochaetes include rodents and insectivores. [2] [6] The epidemiological evidence for B. turicatae causing human infections is strong. [6]

History

Borellia turicatae was first described by Émile Brumpt in 1933 and later described by Edward Arthur Steinhaus in his book Insect Microbiology, published in 1946. [7] Its vector O. turicata was first described by Eugenio Dugès in 1876. [1]

Relapsing fever

Symptoms

Along with fever, patients may experience an incredible range of nonspecific symptoms. [5] The clinical features of relapsing fever may include recurring febrile episodes, chills, nausea, headache, muscle and joint aches, vomiting, lethargy, thrombocytopenia, spirochetemia, anemia, facial paralysis, neutrophilia, lymphopenia, anorexia, dry cough, light sensitivity, rash, neck pain, eye pain, confusion, dizziness, eosinopenia, myocarditis, dermatitis, brain infection, lymphoid hyperplasia, and pregnancy complications. [2] [5] [6] [8] The neurological complications of Borrelia infections are referred to as neuroborreliosis, and the most common manifestations of neuroborreliosis in relapsing fever include meningitis, facial nerve palsy, radiculitis, and encephalopathy. [9] The severity of the disease depends on the infecting serotype. [3] The incubation period typically lasts 7 days, while the symptomatic periods tend to last 3 days, and the afebrile periods tend to last 7 days. [5] Each febrile episode ends with a sequence of symptoms collectively known as a "crisis". [5] During the "chill phase" of the crisis, which lasts 10 to 30 minutes, patients develop very high fever (up to 106.7 °F or 41.5 °C) and may become delirious, agitated, tachycardic, and tachypneic. [5] This phase is followed by the "flush phase", characterized by drenching sweats and a rapid decrease in body temperature and transient hypotension. [5] Generally, patients who are not treated will experience one to four episodes of fever before illness resolves. [5] TBRF contracted during pregnancy can cause spontaneous abortion, premature birth, and neonatal death. [5] The maternal-fetal transmission of Borrelia is believed to occur either transplacentally or while traversing the birth canal. [5] In general, pregnant women have higher spirochaete loads and more severe symptoms than nonpregnant women. [5]

Diagnosis

The definitive diagnosis of TBRF is based on the observation of Borrelia spirochaetes in smears of peripheral blood, bone marrow, or cerebrospinal fluid in a symptomatic person. [5] [6] B. turicatae is best seen by dark-field microscopy, but the organisms can also be detected using acridine orange or Wright's stain. [5] The organisms are best detected in blood obtained while a person is febrile. [5] With subsequent febrile episodes, the number of circulating spirochaetes decreases, making detecting spirochetes on a peripheral blood smear more difficult. [5] Even during the initial episode, spirochaetes can only be seen 70% of the time. [5]

Especially in resource-poor areas, people continue to be afflicted by undiagnosed febrile illnesses, which pose a significant health burden. [2] [6] However, the ecology, pathogenesis, and distribution of B. turicatae remains understudied, and regions of endemicity not previously known to exist continue to be identified. [2] [6] Because relapsing fever has such nonspecific clinical manifestations, the disease is likely underreported, thus improved diagnostic tools for relapsing fever spirochaetes are needed to better identify the endemic foci and to ensure proper treatment. [2]

A limitation in defining the distribution of B. turicatae has been the absence of diagnostic antigens specific for the species. [2] A spirochaete antigen designated the Borrelia immunogenic protein A (BipA) has been identified in B. turicatae. [2] As antibody responses generated against recombinant BipA appear to be unique to infections caused by B. turicatae, these immune responses generated against BipA suggest that it may be a species-specific antigen that could be used to identify additional vertebrate hosts, define endemic foci for B. turicatae, and increase the awareness of the disease to improve healthcare. [2]

Prevention

To prevent infection of B. turicatae, an individual should avoid tick exposure. To prevent tick bites, use insect repellent containing DEET on skin or clothing or permethrin on clothing or equipment. [5] Wear clothing that fully covers arms and legs when outdoors. Avoid sleeping in caves in the Southwestern US, where the tick vector O. turicata can be found. Use tweezers to remove a tick by its mouthparts from skin, not by its body. Identification of the tick species may assist in diagnosis, so removed ticks should be kept.

Treatment

Treatment for relapsing fever can include various antibiotics. TBRF spirochaetes are susceptible to penicillin and other β-Lactam antibiotics, as well as tetracyclines, macrolides, and possibly fluoroquinolones. [5] Although the CDC has not yet developed specific treatment guidelines for TBRF, experts generally recommend tetracycline 500 mg every 6 hours for 10 days as the preferred oral regimen for adults. [5] If tetracyclines are contraindicated, erythromycin, 500 mg (or 12.5 mg/kg) every 6 hours for 10 days is an effective alternative. [5] For patients with central nervous system involvement, parenteral therapy with ceftriaxone 2 g/day for 10–14 days is preferred. [5] All patients treated with antibiotics should be observed during the first 4 hours of treatment for a Jarisch-Herxheimer reaction, which is a worsening of symptoms characterized by rigors, hypotension, and high fever. [5] The reaction occurs in over 50% of cases and may be difficult to distinguish from a febrile crisis. [5] Given appropriate treatment, most patients recover within a few days. [5]

Genetics

The outcome, including disease severity and tissue tropism, of RF can vary significantly depending on the infecting serotype due to a difference in variable major proteins (VMPs), which include variable small proteins (Vsps) and variable large proteins. [3] [4] B. turicatae has two antigenically distinct isogenic serotypes, Bt1 and Bt2, which differ only in their expressed Vsps, thus in their degree of virulence and tropism, or the location of the infection. [3] [4] [10] Infection with serotype 1 can cause severe vestibular dysfunction and increased morbidity and mortality. [3] Coinfection with serotype 2 reduces the severity of vestibular dysfunction and prevents early mortality. [3] Infection with serotype 2 causes severe arthritis, but coinfection with serotype 1 has little effect on this. [3] This shows that the combination of serotype present during mixed infection significantly influences the manifestations of infection with B. turicatae. [3] Bt2 (20-kDa Vsp2) causes higher spirochetemia and neonatal mortality, as well as severe arthritis, while Bt1 (23-kDa Vsp1) is more neurotropic. [3] Bt1 localizes to the brain in five- to 10-fold higher numbers than Bt2, while Bt2 features five- to 10-fold higher pathogen load in the blood, joints, heart, and skin than Bt1. [10] Additionally, Bt2 causes more severe systemic disease than Bt1, including conjunctivitis, ruffled skin, tibiotarsal arthritis, reduced spontaneous activity, and neonatal mortality. [10] As significant differences exist in the ability of the individual serotypes to enter the brain, and the only difference between the serotypes is their VMPs, expressing certain VMPs (such as Vsp1) may facilitate brain invasion. [9] Additionally, RF borreliae tend to persist in the brain after they disappear from the blood, a phenomenon referred to as residual brain infection. [9]

The ability to mount a specific antibody response is the main determinant of susceptibility to RF. [9] The target of antibody-mediated clearance is the major outer membrane lipoproteins, which are highly variable in sequence and define the serotype. [3] [10] In the RF spirochaete B. turicatae (Bt), these proteins occur in two sizes, variable small proteins (Vsp) around 22 kDa and variable large proteins (Vlp) around 37 kDa. [10] Relapsing fever spirochaetes have a unique process of DNA rearrangement that allows them to periodically change the expression of the VMPs in their outer membrane, which results in the generation of multiple serotypes. [3] [5] This process, called antigenic variation, allows the spirochaete to evade the host's immune response and cause relapsing episodes of fever and other symptoms. [5] [10] Antibodies in the blood that bind to and clear spirochaetes expressing the old VMP do not recognize spirochaetes expressing the new VMP. [5] This results in the characteristic pattern of febrile relapses and remissions. [10]

The vector

The vector, Ornithodoros turicata , is an extremely fast feeder among ticks, requiring a 5- to 60-minute blood meal, and is not likely to be collected from the host, making it difficult to track transmission. [11] O. turicata can be found in caves and ground squirrel or prairie dog burrows in the Plains regions of the Southwest. [5] [6] [11] The ticks emerge at night and feed on the rodent or other mammal as it sleeps. [5] The bites are painless, and most people are unaware they have been bitten. [5] The ticks become infected by feeding on infected wild rodents. Once infected, the ticks remain infected for the rest of their lives, which can be up to 10 years. [5] Individual ticks take many blood meals during each stage of their lifecycle. [5] Although soft ticks prefer to feed on rodents, they may seek out humans if rodents are scarce.

Related Research Articles

<span class="mw-page-title-main">Dengue fever</span> Tropical disease caused by the dengue virus, transmitted by mosquito

Dengue fever is a mosquito-borne tropical disease caused by the dengue virus. Symptoms typically begin three to fourteen days after infection. These may include a high fever, headache, vomiting, muscle and joint pains, and a characteristic skin itching and skin rash. Recovery generally takes two to seven days. In a small proportion of cases, the disease develops into a more severe dengue hemorrhagic fever, resulting in bleeding, low levels of blood platelets and blood plasma leakage, or into dengue shock syndrome, where dangerously low blood pressure occurs.

<span class="mw-page-title-main">Lyme disease</span> Infectious disease caused by Borrelia bacteria, spread by ticks

Lyme disease, also known as Lyme borreliosis, is a vector-borne disease caused by Borrelia bacteria, which are spread by ticks in the genus Ixodes. The most common sign of infection is an expanding red rash, known as erythema migrans (EM), which appears at the site of the tick bite about a week afterwards. The rash is typically neither itchy nor painful. Approximately 70–80% of infected people develop a rash. Early diagnosis can be difficult. Other early symptoms may include fever, headaches and tiredness. If untreated, symptoms may include loss of the ability to move one or both sides of the face, joint pains, severe headaches with neck stiffness or heart palpitations. Months to years later, repeated episodes of joint pain and swelling may occur. Occasionally, shooting pains or tingling in the arms and legs may develop. Despite appropriate treatment, about 10 to 20% of those affected develop joint pains, memory problems, and tiredness for at least six months.

Tick-borne diseases, which afflict humans and other animals, are caused by infectious agents transmitted by tick bites. They are caused by infection with a variety of pathogens, including rickettsia and other types of bacteria, viruses, and protozoa. The economic impact of tick-borne diseases is considered to be substantial in humans, and tick-borne diseases are estimated to affect ~80 % of cattle worldwide.

<i>Borrelia burgdorferi</i> Species of bacteria

Borrelia burgdorferi is a bacterial species of the spirochete class in the genus Borrelia, and is one of the causative agents of Lyme disease in humans. Along with a few similar genospecies, some of which also cause Lyme disease, it makes up the species complex of Borrelia burgdorferi sensu lato. The complex currently comprises 20 accepted and 3 proposed genospecies. B. burgdorferi sensu stricto exists in North America and Eurasia and until 2016 was the only known cause of Lyme disease in North America. Borrelia species are Gram-negative.

Relapsing fever is a vector-borne disease caused by infection with certain bacteria in the genus Borrelia, which is transmitted through the bites of lice or soft-bodied ticks.

<i>Borrelia</i> Genus of bacteria

Borrelia is a genus of bacteria of the spirochete phylum. Several species cause Lyme disease, also called Lyme borreliosis, a zoonotic, vector-borne disease transmitted by ticks. Other species of Borrelia cause relapsing fever, and are transmitted by ticks or lice, depending on the species of bacteria. A few Borrelia species as Candidatus Borrelia mahuryensis harbor intermediate genetic features between Lyme disease and relapsing fever Borrelia. The genus is named after French biologist Amédée Borrel (1867–1936), who first documented the distinction between a species of Borrelia, B. anserina, and the other known type of spirochete at the time, Treponema pallidum. This bacterium must be viewed using dark-field microscopy, which make the cells appear white against a dark background. Borrelia species are grown in Barbour-Stoenner-Kelly medium. Of 52 known species of Borrelia, 20 are members of the Lyme disease group, 29 belong to the relapsing fever group, and two are members of a genetically distinct third group typically found in reptiles. A proposal has been made to split the Lyme disease group based on genetic diversity and move them to their own genus, Borelliella, but this change is not widely accepted. This bacterium uses hard and soft ticks and lice as vectors. Testing for the presence of the bacteria in a human includes two-tiered serological testing, including immunoassays and immunoblotting.

<i>Anaplasma phagocytophilum</i> Species of bacterium

Anaplasma phagocytophilum is a Gram-negative bacterium that is unusual in its tropism to neutrophils. It causes anaplasmosis in sheep and cattle, also known as tick-borne fever and pasture fever, and also causes the zoonotic disease human granulocytic anaplasmosis.

<span class="mw-page-title-main">Anaplasmosis</span> Medical condition

Anaplasmosis is a tick-borne disease affecting ruminants, dogs, and horses, and is caused by Anaplasma bacteria. Anaplasmosis is an infectious but not contagious disease. Anaplasmosis can be transmitted through mechanical and biological vector processes. Anaplasmosis can also be referred to as "yellow bag" or "yellow fever" because the infected animal can develop a jaundiced look. Other signs of infection include weight loss, diarrhea, paleness of the skin, aggressive behavior, and high fever.

<span class="mw-page-title-main">Lyme disease microbiology</span>

Lyme disease, or borreliosis, is caused by spirochetal bacteria from the genus Borrelia, which has 52 known species. Three main species are the main causative agents of the disease in humans, while a number of others have been implicated as possibly pathogenic. Borrelia species in the species complex known to cause Lyme disease are collectively called Borrelia burgdorferisensu lato (s.l.) not to be confused with the single species in that complex Borrelia burgdorferi sensu stricto which is responsible for nearly all cases of Lyme disease in North America.

<i>Coltivirus</i> Genus of viruses

Coltivirus is a genus of viruses that infects vertebrates and invertebrates. It includes the causative agent of Colorado tick fever. Colorado tick fever virus can cause a fever, chills, headache, photophobia, myalgia, arthralgia, and lethargy. Children, in particular, may develop a hemorrhagic disease. Leukopenia with both lymphocytes and neutrophils is very common for Colorado tick fever virus. In either case, the infection can lead to encephalitis or meningitis.

<i>Ixodes scapularis</i> Species of tick

Ixodes scapularis is commonly known as the deer tick or black-legged tick, and in some parts of the US as the bear tick. It was also named Ixodes dammini until it was shown to be the same species in 1993. It is a hard-bodied tick found in the eastern and northern Midwest of the United States as well as in southeastern Canada. It is a vector for several diseases of animals, including humans and is known as the deer tick owing to its habit of parasitizing the white-tailed deer. It is also known to parasitize mice, lizards, migratory birds, etc. especially while the tick is in the larval or nymphal stage.

<span class="mw-page-title-main">Pappataci fever</span> Medical condition

Pappataci fever is a vector-borne febrile arboviral infection caused by three serotypes of Phlebovirus. It occurs in subtropical regions of the Eastern Hemisphere. The name, pappataci fever, comes from the Italian word for sandfly; it is the union of the words pappa and taci (silent), distinguishing these insects from blood-feeding mosquitoes, which produce a typical noise while flying.

<i>Borrelia hermsii</i> Species of bacterium

Borrelia hermsii is a spirochete bacterium that has been implicated as a cause of tick-borne relapsing fever. It is spread by the soft-bodied tick Ornithodoros hermsi.

<i>Borrelia recurrentis</i> Species of bacterium

Borrelia recurrentis is a species of Borrelia, a spirochaete bacterium associated with relapsing fever. B. recurrentis is usually transmitted from person to person by the human body louse. Since the 1800s, the body louse has been known as its only known vector.

<i>Theileria parva</i> Species of single-celled organism

Theileria parva is a species of parasites, named in honour of Arnold Theiler, that causes East Coast fever (theileriosis) in cattle, a costly disease in Africa. The main vector for T. parva is the tick Rhipicephalus appendiculatus. Theiler found that East Coast fever was not the same as redwater, but caused by a different protozoan.

<i>Ornithodoros hermsi</i> Species of tick

Ornithodoros hermsi is a species of soft tick. It can be infected with Borrelia hermsii.

<i>Ornithodoros moubata</i> Species of tick

Ornithodoros moubata, commonly known as the African hut tampan or the eyeless tampan, is a species of tick in the family Argasidae. It is an ectoparasite and vector of relapsing fever in humans, and African swine fever in pigs.

Borrelia miyamotoi is a bacterium of the spirochete phylum in the genus Borrelia. A zoonotic organism, B. miyamotoi can infect humans through the bite of several species of hard-shell Ixodes ticks, the same kind of ticks that spread B. burgdorferi, the causative bacterium of Lyme disease. Ixodes ticks are also the primary vector in the spread of babesiosis and anaplasmosis.

Kemerovo tickborne viral fever is an aparalytic febrile illness accompanied by meningism following tick-bite. The causative agent is a zoonotic Orbivirus first described in 1963 in western Siberia by Mikhail Chumakov and coworkers. The virus has some 23 serotypes, and can occur in coinfections with other Orbiviruses and tick-transmitted encephalitis viruses, complicating the course of illness. Rodents and birds are the primary vertebrate hosts of the virus; Ixodes persulcatus ticks are a vector of the virus. Kemerovo and related viruses may be translocated distances in the environment by migratory birds.

Borrelia mayonii is a Gram-negative, host-associated spirochete that is capable of causing Lyme disease. This organism can infect various vertebrate and invertebrate hosts such as humans and ticks, primarily Ixodes scapularis. Migratory songbirds play a role in the dispersal of the tick vector, Ixodes scapularis, across long distances, indirectly dispersing Borrelia mayonii as well.

References

  1. 1 2 3 EUZÉBY (J.P.): List of Bacterial Names with Standing in Nomenclature: a folder available on the Internet. Int. J. Syst. Bacteriol., 1997, 47, 590-592. (List of Prokaryotic names with Standing in Nomenclature. http://www.bacterio.net).
  2. 1 2 3 4 5 6 7 8 9 10 11 12 13 Lopez JE, Wilder HK, Boyle W, Drumheller LB, Thornton JA, et al. (2013) Sequence Analysis and Serological Responses against Borrelia turicatae BipA, a Putative Species-Specific Antigen. PLoS Negl Trop Dis 7(9): e2454. doi:10.1371/journal.pntd.0002454
  3. 1 2 3 4 5 6 7 8 9 10 11 Cadavid D, Garcia E, Gelderblom H. Coinfection with Borrelia turicatae serotype 2 prevents the severe vestibular dysfunction and earlier mortality caused by serotype 1. Journal of Infectious Diseases [serial online]. June 2007;195(11):1686-1693. Available from: CINAHL Plus with Full Text, Ipswich, MA.
  4. 1 2 3 Pennington P, Cadavid D, Bunikis J, Norris S, Barbour A. Extensive interplasmidic duplications change the virulence phenotype of the relapsing fever agent Borrelia turicatae. Molecular Microbiology [serial online]. December 1999;34(5):1120-1132. Available from: Academic Search Complete, Ipswich, MA.
  5. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 Centers for Disease Control and Prevention, National Center for Emerging and Zoonotic Infectious Diseases (NCEZID), Division of Vector-Borne Diseases (DVBD). Tick-borne Relapsing Fever (TBRF). January 23, 2012. Available electronically from https://www.cdc.gov/relapsing-fever/
  6. 1 2 3 4 5 6 7 Schwan TG, et al. 2005. Phylogenetic analysis of the spirochetes Borrelia parkeri and Borrelia turicatae and the potential for tick-borne relapsing fever in Florida. J. Clin. Microbiol. 43:3851–3859. Abstract/FREE Full Text
  7. Insect Microbiology by Edward A. Steinhaus. Review by: James E. Ackert. Transactions of the American Microscopical Society , Vol. 67, No. 1 (Jan., 1948), pp. 83-85. Published by: Wiley on behalf of American Microscopical Society Article. JSTOR   3223087
  8. Whitney MS, Schwan TG, Sultemeier KB, McDonald PS, Brillhart MN (2007) Spirochetemia caused by Borrelia turicatae infection in 3 dogs in Texas. Vet Clin Pathol 36: 212–216. [PubMed]
  9. 1 2 3 4 Cadavid D, Sondey M, Garcia E, Lawson C. Residual Brain Infection in Relapsing-Fever Borreliosis. Journal of Infectious Diseases [serial online]. May 15, 2006;193(10):1451-1458. Available from: Academic Search Complete, Ipswich, MA.
  10. 1 2 3 4 5 6 7 Mehra R, Londoño D, Sondey M, Lawson C, Cadavid D. Structure-Function Investigation of Vsp Serotypes of the Spirochete Borrelia hermsii. PLoS One [serial online]. October 2009;4(10):1-9. Available from: Academic Search Complete, Ipswich, MA.
  11. 1 2 Sanders, David M. (2011). Ticks and Tick-Borne Pathogens Associated with Feral Swine in Edwards Plateau and Gulf Prairies and Marshes Ecoregions of Texas. Doctoral dissertation, Texas A&M University. Available electronically from http : / /hdl .handle .net /1969 .1 /ETD -TAMU -2011 -05 -9135.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.