Type 3 Secretion System

A major molecular virulence factor of Y. enterocolitica (all biotypes except BT1A), Y. pseudotuberculosis and Y. pestis is a type III secretion system (T3SS) encoded in the pYV plasmid (known also as pCD1 in Y. pestis). This system is composed of an injectisome, a nanomachine that spans the bacterial cell wall and allows the injection of bacterial effectors (known as Yersinia outer proteins or Yops) directly into the cytoplasm of host cells. Expression of the system is activated at 37°C and depends on RNA‐based thermoregulation of the virulence regulator LcrF, since its mRNA displays a hairpin structure that is occluded at environmental temperatures and is only accessible to ribosomes at mammal host temperatures (Böhme et al. 2012). Upon bacterial contact with host cells, a decrease in calcium triggers translocation of Yops into host cells (Figure 9.3).

Yops have been shown to interfere with several host signaling cascades, inhibiting in particular phagocytosis and activation of immune responses, and promoting cell death. Phagocytosis inhibition is promoted by inactivation or downregulation of host cell Rho GTPases, which are master regulators of actin cytoskeleton polymerization. For example, YopT is a cysteine protease that inactivates RhoGTPases such as RhoA, Cdc42 and Rac by removing post‐translational modifications that are required for the membrane attachment and function of these host‐cell enzymes (Shao et al. 2003). YopE mimics GTPase activating proteins (GAPs), increasing the hydrolytic activity of RhoGTPases which leads to their inactivation upon hydrolysis of GTP to GDP (Von Pawel‐Rammingen et al. 2000). YopO (also known as YpkA) displays a guanine nucleotide dissociation inhibitor domain which allows to sequester inactive GDP‐bound RhoGTPases (Prehna et al. 2006). Interestingly, YopO can also use actin as a bait and through a serine/threonine kinase domain it can phosphorylate/inactivate multiple actin binding proteins (Lee et al. 2015). Inactivation of immune responses is achieved by molecules such as YopH, a phosphatase that dephosphorylates critical proteins required for T‐cell receptor signaling (Gerke et al. 2005), or YopJ (named YopP in Y. enterocolitica), an acetyltransferase that blocks mitogen‐activated protein kinase and nuclear factor‐κB (NF‐κB) signaling by inhibit their phosphorylation (Orth et al. 2000). Host cell death is promoted by YopM, which displays E3 ubiquitin ligase activity targeting NLRP3. YopK, a protein with no sequence homology to any protein outside pathogenic Yersinia species, functions not by interacting with host proteins but by preventing recognition of the T3SS by the host cell by associating/masking the YopB/YopD proteins, which constitute tip of the T3SS needle (Brodsky et al. 2010).

It is important to note that LcrV, which is also localized at the tip of the injectisome and is essential for the assembly of a functional translocation pore formed by YopB and YopD, is highly immunogenic and has been extensively used as a target for vaccination against pathogenic Yersinia, and particularly Y. pestis.

Iron‐Sequestering Systems

The most highly pathogenic Yersinia are characterized by the presence of a mobile element, the HPI, which encodes the yersiniabactin‐based iron acquisition system (Carniel 2001). Genes responsible for the biosynthesis, transport and regulation of yersiniabactin (Ybt) are repressed by the iron‐loaded ferric uptake regulator (Fur) and are activated by the AraC‐type YbtA transcriptional activator. Inactivation of the Ybt biosynthetic and/or transport genes results in significant virulence attenuation of highly pathogenic Yersinia (Rakin et al. 2012). Interestingly, some pathogenic Y. pseudotuberculosis strains have been shown to be devoid of the HPI, suggesting the presence of other iron‐sequestering systems. Indeed, the pseudochelin (also known as Yersinia non‐ribosomal peptide, Ynp) and the yersiniachelin (Ych, encoded by the ysu gene cluster) have been subsequently identified in Y. pestis and Y. pseudotuberculosis, but not in Y. enterocolitica. Functional studies are currently lacking to fully understand the contribution of these alternative iron‐sequestering system to the pathogenicity of Y. pestis and Y. pseudotuberculosis.

Source of Infection: Evolution, Ecology and Epidemiology

Y. pestis evolved less than 20 000 years ago from its ancestor Y. pseudotuberculosis. Both gene gain and gene inactivation events played an important role in the evolution from the mildly pathogenic, foodborne ancestor Y. pseudotuberculosis toward the highly pathogenic, vector‐borne, Y. pestis. Besides the virulence plasmid pYV/pCD1, present also in Y. pseudotuberculosis and Y. enterocolitica, Y. pestis harbors two additional plasmids, pFra and pPla (also known as pMT1 and pPCP1, respectively), which play important roles in adaptation to the flea vectors and in pathogenesis in mammalian hosts.

A key step in the adaptation of Y. pestis to its flea vector was the silencing of urease activity through mutation of the ureD gene, which reduces significantly the bacterial oral toxicity (Chouikha and Hinnebusch 2014). Another important adaptive step was the formation of a bacterial biofilm that blocks the flea’s proventriculus (the valve connecting the esophagus to the midgut), inhibiting the arrival of the blood meal to the midgut. Starving infected fleas bite their mammalian hosts with high frequency in their attempt to feed, and Y. pestis released from the biofilm and regurgitated at the feeding site can transmit plague. The biofilm is enveloped in a beta‐1,6‐N‐acetyl‐D‐glucosamine polymer and its production by the HmsHFRS complex is favored through inactivation in Y. pestis of the rcsA gene, whose product RcsA forms a dimer with RcsB that transcriptionally represses the hmsHFRS operon (Sun et al. 2014). Cyclic di‐GMP activates biofilm formation in Y. pestis, and inactivation of the genes rtn and y3389, which encode two phosphodiesterases that degrade cyclic di‐GMP, also contributes to increased biofilm formation in the flea (Sun et al. 2014). Two additional genes which participate to Y. pestis resistance to toxic compounds encountered in the flea gut, and which also contribute directly or indirectly to biofilm formation, are the ancestral gene rpiA, which encodes for a ribose‐5 phosphate isomerase, and the recently acquired gene ymt (present in the pFra plasmid), which encodes a phospholipase (Dewitte et al. 2020).

Y. pestis is endemically present in diverse sylvatic and periurban mammal populations in the Americas, in Africa and in Asia. Rodents (279 species) are the main reservoirs, but carnivores (31 species), and lagomorphs (14 species) have been also reported as reservoirs (Mahmoudi et al. 2020). In North America (mainly the United States), for example, reservoir species include prairie dogs (genus Cynomys), California voles (Microtus californicus) and deer mice (genus Peromycus; Mahmoudi et al. 2020). In South America (mainly Brazil and Peru), mammals found to harbor Y. pestis include hairy‐tailed bolo mice (Necromys lasiurus), common yellow‐toothed cavy (genus Galea), and also the lagomorph tapeti (Sylvilagus brasiliensis) (Bonvicino). In Africa (mainly Democratic Republic of Congo and Madagascar), black rats (Rattus rattus), brown rats (Rattus norvegicus), Southern African vlei rats (Otomys irroratus), and the house shrew (Suncus murinus) have been reported as reservoirs. In Asia (China, Mongolia, former Soviet Union, Iran), reservoirs include many different species, including meriones and gerbils (genus Meriones), great gerbils (Rhombomys opimus), marmots (genus Marmotta), and ground squirrels (genus Spermophilus) (Mahmoudi et al. 2020). It is proposed that in animal reservoirs, Y. pestis can silently persist during long periods in enzootic cycles within plague‐resistant wild rodents, and that transmission to susceptible hosts (such as periurban rodents) leads to epizootic cycles, in which high host mortality is observed. The organism can also survive in soil, such as in the burrows of rodents, allowing contamination of animals that circulate in these environments.

Plague can be transmitted through the bite of fleas infected with Y. pestis (Figure 9.3). Fleas can be infected upon feeding on septicemic mammalian hosts. Fleas species are often specific to individual mammalian hosts species and, since the mammalian reservoirs of Y. pestis are diverse as described above, many flea species can be potentially involved in plague transmission. Y. pestis infection of its flea vector has been particularly well studied in the species Oropsylla montana (associated with ground squirrels in North America), the Oriental rat flea Xenopsylla cheopsis, and the cat flea Ctenocephalides felis. Y. pseudotuberculosis, the ancestor of Y. pestis, is orally toxic to fleas due to the expression of urease, which leads to insect diarrhea, immobility and up to 40% mortality of infected insects (Erickson et al. 2007).

In the case of pulmonary plague, Y. pestis can be transmitted via aerosols produced upon coughing. Airborne plague transmission from animals to humans has been reported (Doll et al. 1994).

Types of Disease and Pathogenesis

There are three presentations of plague in animals and in humans: bubonic, the most common form, associated with lymph‐node swelling with abscessation, called buboes, and fatal febrile illness; pneumonic plague, associated with fatal pneumonic disease; and septicemic plague, characterized by septic shock and death.

Plague primarily affects wild and domestic rodents, although felines are also very susceptible. Disease in rodents can vary from subacute and mild to acute, severe, and fatal. In acute disease, rodents die within a few days with hemorrhagic buboes and splenomegaly, whereas in subacute disease, rodents develop necrotic and suppurative lymph nodes and similar lesions in the liver, lung, spleen, and other organs; some animals may recover. Secondary pneumonic plague characterized by severe hemorrhagic pneumonia develops in a small proportion of subacutely infected animals. Cats (and other felines) develop typical bubonic plague, with abscesses and lymphadenopathy, often of the cervical and submandibular lymph nodes, spread of infection to and development of lesions in the liver and spleen, and secondary suppurative pneumonia. Cats may also develop septicemic illness without buboes. Disease occurs uncommonly in dogs and has been rarely reported in species such as mule deer and antelope, but does not occur in cattle, horses, sheep, and pigs.

Infection in humans usually follows a flea bite, with sudden onset of severe systemic illness and development of a bubo in the local draining lymph node, and subsequent spread to other lymph nodes in the body; patients go on to develop septicemia and multiple organ failure (including lung collapse during pneumonic plague). The name “black death” comes from the gangrene associated with the coagulopathy characteristic of septic or endotoxic shock.

Pneumonic Plague

Y. pestis can efficiently proliferate in the lungs of mammalian hosts, leading to the form of the disease known as pneumonic plague, which is almost always fatal. Bacteria can reach the lungs via the bloodstream upon dissemination from primary infected lymph nodes, giving rise to secondary pneumonic plague. Primary pneumonic plague can occur upon inhalation of aerosols produced by a person (or animal) infected with pneumonic plague. In humans, acute pneumonia, intra‐alveolar hemorrhage and edema follow Y. pestis replication in the alveoli, leading to collapse of pulmonary functions and death (Smith 1959

Only gold members can continue reading. Log In or Register to continue

Share this:

• Click to share on Twitter (Opens in new window)
• Click to share on Facebook (Opens in new window)

Related

Related posts:

1. Themes in Bacterial Pathogenesis
2. Campylobacter
3. Escherichia coli
4. Other Pasteurellaceae: Avibacterium, Bibersteinia, Gallibacterium, Glaesserella, and Histophilus

Stay updated, free articles. Join our Telegram channel

Join