The evolution of covert, silent infection as a parasite strategy

Many parasites and pathogens cause silent/covert infections in addition to the more obvious infectious disease-causing pathology. Here, we consider how assumptions concerning superinfection, protection and seasonal host birth and transmission rates affect the evolution of such covert infections as a...

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Veröffentlicht in:	Proceedings of the Royal Society. B, Biological sciences Biological sciences, 2009-06, Vol.276 (1665), p.2217-2226
Hauptverfasser:	Sorrell, Ian, White, Andrew, Pedersen, Amy B., Hails, Rosemary S., Boots, Mike
Format:	Artikel
Sprache:	eng
Schlagworte:	Animals Biological Evolution Birth rates Covert Disease Disease transmission Evolution Host-Parasite Interactions Infections Latent Models, Biological Parasite hosts Parasites Parasites - physiology Population Dynamics Seasons Superinfection Tuberculosis Vertical disease transmission Vertical Transmission
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creator	Sorrell, Ian White, Andrew Pedersen, Amy B. Hails, Rosemary S. Boots, Mike
description	Many parasites and pathogens cause silent/covert infections in addition to the more obvious infectious disease-causing pathology. Here, we consider how assumptions concerning superinfection, protection and seasonal host birth and transmission rates affect the evolution of such covert infections as a parasite strategy. Regardless of whether there is vertical infection or effects on sterility, overt infection is always disadvantageous in relatively constant host populations unless it provides protection from superinfection. If covert infections are protective, all individuals will enter the covert stage if there is enough vertical transmission, and revert to overt infections after a 'latent' period (susceptible, exposed, infected epidemiology). Seasonal variation in transmission rates selects for non-protective covert infections in relatively long-lived hosts with low birth rates typical of many mammals. Variable host population density caused by seasonal birth rates may also select for covert transmission, but in this case it is most likely in short-lived fecund hosts. The covert infections of some insects may therefore be explained by their outbreak population dynamics. However, our models consistently predict proportions of covert infection, which are lower than some of those observed in nature. Higher proportions of covert infection may occur if there is a direct link between covert infection and overt transmission success, the covert infection is protective or the covert state is the result of suppression by the host. Relatively low proportions of covert transmission may, however, be explained as a parasite strategy when transmission opportunities vary.
doi_str_mv	10.1098/rspb.2008.1915
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B, Biological sciences</title><addtitle>PROC R SOC B</addtitle><description>Many parasites and pathogens cause silent/covert infections in addition to the more obvious infectious disease-causing pathology. Here, we consider how assumptions concerning superinfection, protection and seasonal host birth and transmission rates affect the evolution of such covert infections as a parasite strategy. Regardless of whether there is vertical infection or effects on sterility, overt infection is always disadvantageous in relatively constant host populations unless it provides protection from superinfection. If covert infections are protective, all individuals will enter the covert stage if there is enough vertical transmission, and revert to overt infections after a 'latent' period (susceptible, exposed, infected epidemiology). Seasonal variation in transmission rates selects for non-protective covert infections in relatively long-lived hosts with low birth rates typical of many mammals. Variable host population density caused by seasonal birth rates may also select for covert transmission, but in this case it is most likely in short-lived fecund hosts. The covert infections of some insects may therefore be explained by their outbreak population dynamics. However, our models consistently predict proportions of covert infection, which are lower than some of those observed in nature. Higher proportions of covert infection may occur if there is a direct link between covert infection and overt transmission success, the covert infection is protective or the covert state is the result of suppression by the host. 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subjects	Animals Biological Evolution Birth rates Covert Disease Disease transmission Evolution Host-Parasite Interactions Infections Latent Models, Biological Parasite hosts Parasites Parasites - physiology Population Dynamics Seasons Superinfection Tuberculosis Vertical disease transmission Vertical Transmission
title	The evolution of covert, silent infection as a parasite strategy
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