Yersinia pestis | |
---|---|
A scanning electron micrograph depicting a mass of Yersinia pestis bacteria in the foregut of an infected flea | |
Scientific classification | |
Domain: | Bacteria |
Phylum: | Proteobacteria |
Class: | Gammaproteobacteria |
Order: | Enterobacterales |
Family: | Yersiniaceae |
Genus: | Yersinia |
Species: |
Y. pestis
|
Binomial name | |
Yersinia pestis
(Lehmann & Neumann, 1896)
van Loghem, 1944 | |
Synonyms | |
Bacillus
|
Yersinia pestis (formerly Pasteurella pestis) is a gram-negative, non-motile, rod-shaped, coccobacillus bacterium, with no spores. It is a facultative anaerobic organism that can infect humans via the Oriental rat flea (Xenopsylla cheopis). It causes the disease plague, which takes three main forms: pneumonic, septicemic, and bubonic.
All three forms have been responsible for high-mortality epidemics throughout human history, including the Plague of Justinian in the sixth century; the Black Death, which accounted for the death of at least one-third of the European population between 1347 and 1353; and the Third Pandemic, sometimes referred to as the Modern Plague, which began in the late 19th century in China and spread by rats on steamships, claiming close to 10 million lives.
Those plagues may have originated in Central Asia or China and were transmitted west via trade routes. However, research in 2018 found evidence of the pathogen in an ancient Swedish tomb, which may have been the cause of what has been described as the Neolithic decline around 3000 BC, in which European populations declined significantly. This would suggest that Y. pestis may have originated in Europe in the Cucuteni–Trypillia culture instead of Asia.
Y. pestis was discovered in 1894 by Alexandre Yersin, a Swiss/French physician and bacteriologist from the Pasteur Institute, during an epidemic of the plague in Hong Kong. Yersin was a member of the Pasteur school of thought. Kitasato Shibasaburō, a German-trained Japanese bacteriologist who practised Koch's methodology, was also engaged at the time in finding the causative agent of the plague. However, Yersin actually linked plague with Y. pestis. Formerly named Pasteurella pestis, the organism was renamed Yersinia pestis in 1944.
Every year, thousands of cases of the plague are still reported to the World Health Organization, although with proper treatment, the prognosis for victims is now much better. A five- to six-fold increase in cases occurred in Asia during the time of the Vietnam War, possibly due to the disruption of ecosystems and closer proximity between people and animals. The plague is now commonly found in sub-Saharan Africa and Madagascar, areas that now account for over 95% of reported cases. The plague also has a detrimental effect on nonhuman mammals. In the United States, mammals such as the black-tailed prairie dog and the endangered black-footed ferret are under threat.
General characteristics
Y. pestis is a nonmotile, stick-shaped, facultative anaerobic bacterium with bipolar staining (giving it a safety pin appearance) that produces an antiphagocytic slime layer. Similar to other Yersinia species, it tests negative for urease, lactose fermentation, and indole. Its closest relative is the gastrointestinal pathogen Yersinia pseudotuberculosis, and more distantly Yersinia enterocolitica.
Genome
A complete genomic sequence is available for two of the three subspecies of Y. pestis: strain KIM (of biovar Y. p. medievalis), and strain CO92 (of biovar Y. p. orientalis, obtained from a clinical isolate in the United States). As of 2006, the genomic sequence of a strain of biovar Antiqua has been recently completed. Similar to the other pathogenic strains, signs exist of loss of function mutations. The chromosome of strain KIM is 4,600,755 base pairs long; the chromosome of strain CO92 is 4,653,728 base pairs long. Like Y. pseudotuberculosis and Y. enterocolitica, Y. pestis is host to the plasmid
pCD1. It also hosts two other plasmids, pPCP1 (also called pPla or
pPst) and pMT1 (also called pFra) that are not carried by the other Yersinia species. pFra codes for a phospholipase D that is important for the ability of Y. pestis to be transmitted by fleas. pPla codes for a protease, Pla, that activates plasmin in human hosts and is a very important virulence factor for pneumonic plague. Together, these plasmids, and a pathogenicity island called HPI, encode several proteins that cause the pathogenesis, for which Y. pestis
is famous. Among other things, these virulence factors are required for
bacterial adhesion and injection of proteins into the host cell,
invasion of bacteria in the host cell (via a type-III secretion system), and acquisition and binding of iron harvested from red blood cells (by siderophores). Y. pestis is thought to be descended from Y. pseudotuberculosis, differing only in the presence of specific virulence plasmids.
A comprehensive and comparative proteomics analysis of Y. pestis strain KIM was performed in 2006. The analysis focused on the transition to a growth condition mimicking growth in host cells.
Small noncoding RNA
Numerous bacterial small noncoding RNAs
have been identified to play regulatory functions. Some can regulate
the virulence genes. Some 63 novel putative sRNAs were identified
through deep sequencing of the Y. pestis sRNA-ome. Among them was Yersinia-specific (also present in Y. pseudotuberculosis and Y. enterocolitica) Ysr141 (Yersinia small RNA 141). Ysr141 sRNA was shown to regulate the synthesis of the type III secretion system (T3SS) effector protein YopJ. The Yop-Ysc T3SS is a critical component of virulence for Yersinia species. Many novel sRNAs were identified from Y. pestis grown in vitro and in the infected lungs of mice suggesting they play role in bacterial physiology or pathogenesis. Among them sR035 predicted to pair with SD region and transcription initiation site of a thermo-sensitive regulator ymoA, and sR084 predicted to pair with fur, ferric uptake regulator.
Pathogenesis and immunity
In the urban and sylvatic (forest) cycles of Y. pestis, most of the spreading occurs between rodents and fleas. In the sylvatic cycle, the rodent is wild, but in the urban cycle, the rodent is primarily the brown rat (Rattus norvegicus). In addition, Y. pestis
can spread from the urban environment and back. Transmission to humans
is usually through the bite of infected fleas. If the disease has
progressed to the pneumonic form, humans can spread the bacterium to
others by coughing, vomiting, and possibly sneezing.
In reservoir hosts
Several species of rodents serve as the main reservoir for Y. pestis in the environment. In the steppes, the natural reservoir is believed to be principally the marmot. In the western United States, several species of rodents are thought to maintain Y. pestis.
However, the expected disease dynamics have not been found in any
rodent. Several species of rodents are known to have a variable
resistance, which could lead to an asymptomatic carrier status. Evidence indicates fleas from other mammals have a role in human plague outbreaks.
The lack of knowledge of the dynamics of plague in mammal species
is also true among susceptible rodents such as the black-tailed prairie
dog (Cynomys ludovicianus), in which plague can cause colony collapse, resulting in a massive effect on prairie food webs.
However, the transmission dynamics within prairie dogs do not follow
the dynamics of blocked fleas; carcasses, unblocked fleas, or another
vector could possibly be important, instead.
In other regions of the world, the reservoir of the infection is
not clearly identified, which complicates prevention and early-warning
programs. One such example was seen in a 2003 outbreak in Algeria.
Domestic house cats are susceptible to plague. Their symptoms are
similar to those experienced by humans. Cats infected with plague can
infect people through bites, scratches, coughs, or sneezes.
Vector
The transmission of Y. pestis by fleas is well characterized. Initial acquisition of Y. pestis by the vector
occurs during feeding on an infected animal. Several proteins then
contribute to the maintenance of the bacteria in the flea digestive
tract, among them the hemin storage system and Yersinia murine
toxin (Ymt).
Although Ymt is highly toxic to rodents and was once thought to be
produced to ensure reinfection of new hosts, it is important for the
survival of Y. pestis in fleas.
The hemin storage system plays an important role in the transmission of Y. pestis back to a mammalian host. While in the insect vector, proteins encoded by hemin storage system genetic loci induce biofilm formation in the proventriculus, a valve connecting the midgut to the esophagus.
Aggregation in the biofilm inhibits feeding, as a mass of clotted blood
and bacteria forms (referred to as "Bacot's block" after entomologist A.W. Bacot, the first to describe this phenomenon). Transmission of Y. pestis
occurs during the futile attempts of the flea to feed. Ingested blood
is pumped into the esophagus, where it dislodges bacteria lodged in the
proventriculus, which is regurgitated back into the host circulatory
system.
In humans and other susceptible hosts
Pathogenesis due to Y. pestis infection of mammalian hosts is due to several factors, including an ability of these bacteria to suppress and avoid normal immune system responses such as phagocytosis and antibody production. Flea bites allow for the bacteria to pass the skin barrier. Y. pestis expresses a plasmin
activator that is an important virulence factor for pneumonic plague
and that might degrade on blood clots to facilitate systematic invasion. Many of the bacteria's virulence factors are antiphagocytic in nature. Two important antiphagocytic antigens, named F1 (fraction 1) and V or LcrV, are both important for virulence. These antigens are produced by the bacterium at normal human body temperature. Furthermore, Y. pestis survives and produces F1 and V antigens while it is residing within white blood cells such as monocytes, but not in neutrophils. Natural or induced immunity is achieved by the production of specific opsonic antibodies against F1 and V antigens; antibodies against F1 and V induce phagocytosis by neutrophils.
In addition, the type-III secretion system (T3SS) allows Y. pestis to inject proteins into macrophages and other immune cells. These T3SS-injected proteins, called Yersinia outer proteins (Yops), include Yop B/D, which form pores in the host cell membrane and have been linked to cytolysis. The YopO, YopH, YopM, YopT, YopJ, and YopE are injected into the cytoplasm of host cells by T3SS into the pore created in part by YopB and YopD. The injected Yops limit phagocytosis and cell signaling pathways important in the innate immune system, as discussed below. In addition, some Y. pestis strains are capable of interfering with immune signaling (e.g., by preventing the release of some cytokines).
Y. pestis proliferates inside lymph nodes, where it is able to avoid destruction by cells of the immune system such as macrophages. The ability of Y. pestis to inhibit phagocytosis allows it to grow in lymph nodes and cause lymphadenopathy. YopH is a protein tyrosine phosphatase that contributes to the ability of Y. pestis to evade immune system cells. In macrophages, YopH has been shown to dephosphorylate p130Cas, Fyb (Fyn binding protein) SKAP-HOM and Pyk, a tyrosine kinase homologous to FAK. YopH also binds the p85 subunit of phosphoinositide 3-kinase, the Gab1, the Gab2 adapter proteins, and the Vav guanine nucleotide exchange factor.
YopE functions as a GTPase-activating protein for members of the Rho family of GTPases such as RAC1. YopT is a cysteine protease that inhibits RhoA by removing the isoprenyl group, which is important for localizing the protein to the cell membrane. YopE and YopT has been proposed to function to limit YopB/D-induced cytolysis.
This might limit the function of YopB/D to create the pores used for
Yop insertion into host cells and prevent YopB/D-induced rupture of host
cells and release of cell contents that would attract and stimulate
immune system responses.
YopJ is an acetyltransferase that binds to a conserved α-helix of MAPK kinases. YopJ acetylates MAPK kinases at serines and threonines that are normally phosphorylated during activation of the MAP kinase cascade. YopJ is activated in eukaryotic cells by interaction with target cell phytic acid (IP6). This disruption of host cell protein kinase activity causes apoptosis
of macrophages, and this is proposed to be important for the
establishment of infection and for evasion of the host immune response.
YopO is a protein kinase also known as Yersinia protein kinase A (YpkA). YopO is a potent inducer of human macrophage apoptosis.
Depending on which form of the plague with which the individual
becomes infected, the plague develops a different illness; however, the
plague overall affects the host cell’s ability to communicate with the
immune system, hindering the body to bring phagocytic cells to the area
of infection.
Y. pestis is a versatile killer. In addition to rodents and humans, it is known to have killed dogs, cats, camels, chickens, and pigs.
Immunity
A formalin-inactivated vaccine was in the past available in the United States for adults at high risk of contracting the plague until removal from the market by the Food and Drug Administration. It was of limited effectiveness and could cause severe inflammation. Experiments with genetic engineering
of a vaccine based on F1 and V antigens are underway and show promise.
However, bacteria lacking antigen F1 are still virulent, and the V
antigens are sufficiently variable such that vaccines composed of these
antigens may not be fully protective. The United States Army Medical Research Institute of Infectious Diseases has found that an experimental F1/V antigen-based vaccine protects crab-eating macaques, but fails to protect African green monkey species. A systematic review by the Cochrane Collaboration found no studies of sufficient quality to make any statement on the efficacy of the vaccine.
Isolation and identification
In 1894, two bacteriologists, Alexandre Yersin of Switzerland and Kitasato Shibasaburō of Japan, independently isolated in Hong Kong the bacterium responsible for the Third Pandemic.
Though both investigators reported their findings, a series of
confusing and contradictory statements by Kitasato eventually led to the
acceptance of Yersin as the primary discoverer of the organism. Yersin
named it Pasteurella pestis in honor of the Pasteur Institute, where he worked. In 1967, it was moved to a new genus and renamed Yersinia pestis
in his honor. Yersin also noted that rats were affected by plague not
only during plague epidemics, but also often preceding such epidemics in
humans and that plague was regarded by many locals as a disease of
rats; villagers in China and India asserted that when large numbers of
rats were found dead, plague outbreaks soon followed.
In 1898, French scientist Paul-Louis Simond (who had also come to China to battle the Third Pandemic) established the rat–flea vector
that drives the disease. He had noted that persons who became ill did
not have to be in close contact with each other to acquire the disease.
In Yunnan, China, inhabitants would flee from their homes as soon as they saw dead rats, and on the island of Formosa (Taiwan),
residents considered the handling of dead rats heightened the risks of
developing plague. These observations led him to suspect that the flea
might be an intermediary factor in the transmission of plague, since
people acquired plague only if they were in contact with rats that had
died less than 24 hours before. In a now classic experiment, Simond
demonstrated how a healthy rat died of plague after infected fleas had
jumped to it from a rat that had recently died of the plague. The outbreak spread to Chinatown, San Francisco, from 1900 to 1904 and then to Oakland and the East Bay from 1907 to 1909.
It has been present in the rodents of western North America ever since,
as fear of the consequences of the outbreak on trade caused authorities
to hide the dead of the Chinatown residents long enough for the disease
to be passed to widespread species of native rodents in outlying areas.
Ancient DNA evidence
In 2018, the emergence and spread of the pathogen during the Neolithic decline (as far back as 6,000 years ago) was published.
A site in Sweden was the source of the DNA evidence and trade networks
were proposed as the likely avenue of spread rather than migrations of
populations.
DNA evidence published in 2015 indicates Y. pestis infected humans 5,000 years ago in Bronze Age
Eurasia, but genetic changes that made it highly virulent did not occur until about 4,000 years ago.
The highly virulent version capable of transmission by fleas through
rodents, humans, and other mammals was found in two individuals
associated with the Srubnaya culture from the Samara region in Russia from around 3,800 years ago and an Iron Age individual from Kapan, Armenia from around 2,900 years ago. This indicates that at least two lineages of Y. pestis were circulating during the Bronze Age in Eurasia. The Y. pestis
bacterium has a relatively large number of nonfunctioning genes and
three "ungainly" plasmids, suggesting an origin less than 20,000 years
ago.
Three main strains are recognised: Y. p. antiqua, which caused a plague pandemic in the sixth century; Y. p. medievalis, which caused the Black Death and subsequent epidemics during the second pandemic wave; and Y. p. orientalis, which is responsible for current plague outbreaks.
Plague causes a blockage in the proventriculus of the flea by forming a biofilm.
The biofilm formation is induced by the ingestion of blood. The
presence of a biofilm seems likely to be required for stable infection
of the flea. It has been suggested that a bacteriophage – Ypφ – may have been responsible for increasing the virulence of this organism.
Recent events
In
2008, the plague was commonly found in sub-Saharan Africa and
Madagascar, areas that accounted for over 95% of the reported cases.
In September 2009, the death of Malcolm Casadaban, a molecular genetics professor at the University of Chicago, was linked to his work on a weakened laboratory strain of Y. pestis. Hemochromatosis was hypothesised to be a predisposing factor in Casadaban's death from this attenuated strain used for research.
In 2010, researchers in Germany definitely established, using PCR evidence from samples obtained from Black Death victims, that Y. pestis was the cause of the medieval Black Death.
In 2011, the first genome of Y. pestis isolated from Black Death victims was published, and concluded that this medieval strain was ancestral to most modern forms of Y. pestis.
In 2015, Cell published results from a study of ancient graves. Plasmids of Y. pestis were detected in archaeological samples of the teeth of seven Bronze Age individuals, in the Afanasievo culture in Siberia, the Corded Ware culture in Estonia, the Sintashta culture in Russia, the Unetice culture in Poland, and the Andronovo culture in Siberia.
On September 8, 2016, the Y. pestis bacterium was identified from DNA in teeth found at a Crossrail building site in London. The human remains were found to be victims of the Great Plague of London, which lasted from 1665 to 1666.
On January 15, 2018, researchers at the University of Oslo and the University of Ferrara suggested that humans and their parasites were the biggest carriers of the plague.
Two cases of pneumonic plague were diagnosed at a hospital in
Beijing's Chaoyang district on 13 November 2019, prompting fears of an
outbreak. Doctors diagnosed a middle-aged man with fever, who had
complained of difficulty breathing for some ten days, accompanied by his
wife with similar symptoms. Police quarantined the emergency room at the hospital and controls were placed on Chinese news aggregators.
On the 18th, a third case was reported in a 55-year-old male from
Xilingol League, one of the twelve Mongolic autonomous regions in
Northern China. The patient received treatment and 28 symptomless
contacts were placed in quarantine.