Principles of Virology, Volume 2. S. Jane Flint

Principles of Virology, Volume 2 - S. Jane Flint


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acids, or other inhibitors secreted by commensal microorganisms. Some virus particles are removed from the body when dead cells slough of; many others are washed away by soap and water. However, when the integrity of the dead cell layer is compromised by cuts, abrasions, or punctures (e.g., insect bites and needle sticks), virus particles can access the rich array of live cells beneath the keratinized layer, including epithelial cells, endothelial cells, neuronal processes, and capillaries.

      The body’s response to a breach in the critical barrier formed by the skin is to make rapidly a hard, water-resistant shell over the wound, called a scab. Scabs are more than just the dermis below the site of injury drying and hardening; neutrophils and macrophages are recruited in large numbers to a wound, primarily to engulf bacteria and other pathogens that may benefit from this breach in the skin to infect the host. In addition, macrophages further aid the healing process by producing growth factors that promote cell proliferation. As the air dries the wound area, these formerly useful immune cells become part of the scab as well.

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      Surfaces exposed to the environment but not covered by skin are lined by living cells and are at risk for infection despite the continuous actions of self-cleansing mechanisms. The most common route of viral entry is through the respiratory tract. In a human lung, there are about 300 million terminal sacs, called alveoli, which function in gaseous exchange between inspired air and the blood. Each sac is in close contact with capillary and lymphatic vessels. The combined surface area of the human lungs is ∼180 m2, approximately the size of a tennis court! At rest, humans inspire ∼6 liters of air per minute. Together, the impressive surface area and large volumes of “miasma” that one inhales each minute imply that foreign particles, such as bacteria, allergens, and viruses, are likely introduced into the lungs with every breath.

      EXPERIMENTS

       Dermal damage increases immunity and host survival

      When it was still in use, the smallpox vaccine was delivered by a bifurcated (two-pronged) needle in a process referred to as scarification. Vaccination resulted in local damage to the skin and a subsequent (though quickly re solved) lesion in most individuals that often left a lifelong scar. Until recently, it was not appreciated that the scarification process itself was an important component of the vaccine’s efficacy. Experiments using the smallpox-related virus vaccinia virus showed that intra dermal inoculation of the virus into rabbits resulted in lethal disease by 8 days after infection, whereas delivery by scarification led to a protective host response and animal survival. Scarified rabbits also responded immunologically earlier than those inoculated by the intradermal route. Moreover, scarification in the absence of virus, followed immediately by a same-site intradermal challenge with virus, resulted in significant protection to the infected rabbits. This dramatic difference can be attributed to the rapid induction of a nonspecific host response caused by the scarification wound itself. Scarification damages skin cells and the underlying epidermis, inducing the release of cytokines and chemokines that help direct the host’s immune response to the site of infection and restrict the dissemination of the virus throughout the host.

       Rice AD, Adams MM, Lindsey SF, Swetnam DM, Manning BR, Smith AJ, Burrage AM, Wallace G, MacNeill AL, Moyer RW. 2014. Protective properties of vaccinia virus-based vaccines: skin scarification promotes a nonspecific immune response that protects against orthopoxvirus disease. J Virol 88:7753–7763.

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