The bacterium Francisella tularensis is the etiological agent of tularemia, a natural focal, especially dangerous infection, which, “thanks to” its low infectious dose and ability to be transmitted to humans via all possible routes, is a potential bioterrorism agent. This pathogen has been known to mankind for over a hundred years, but it is still impossible to prevent massive human disease outbreaks and sporadic incidence cases, whereas tularemia diagnosis may be verified within several days-to-weeks. The basis for tularemia causative agent virulence is based on its ability to disrupt phagocyte function. In animals and humans, the various Francisella tularensis systems work together to bypass host immune system, attach to and enter eukaryotic cells, block phagosome-lysosome fusion, multiply in various host cells without being detected, inhibit their destruction and cause host cell death to release bacteria and infect neighboring tissue cells, thus developing an infectious disease in different organs. This is achieved through a unique complement-dependent penetration process into host cell, called loop phagocytosis, and an unusual inert endotoxin as well as variation in diverse forms of “free” lipid A modifications and lipid A in the LPS composition, its dynamic acyl chain length regulation, and specifically combined regulatory factors to induce the “pathogenicity island” protein synthesis. Accumulated point mutations, intragenomic rearrangements, deletions, insertions, duplications, transpositions, gene degradation, variation in the number of copies in repeated DNA sequences, as well as homologous and non-homologous recombinations underlie a markedly expanded potential for existence of the tularemia causative agent: they contribute to the holarctic subspecies strain survival in varying conditions, including osmotic shock, to form multiple resistance to various toxic substances and alter F. tularensis subspecies virulence. Analyzing a whole body of publications on the abovementioned aspects for tularemia causative agent life activity attempts to combine the differences, structural features and “tricks” of the F. tularensis species cells allowing them to be a powerful pathogen, with a high potential to adapt upon low pathogen variability and a limited genome length compared with other specially dangerous bacteria.
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