Evolución de interacciones parásito - hospedero: coevolución, selección sexual y otras teorías propuestas
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Evolución de interacciones parásito - hospedero: coevolución, selección sexual y otras teorías propuestas
.

Sumario:

Esta revisión resume los modelos teóricos de interacciones parásito-hospedero que se encuentran disponibles en la literatura científica. Se revisaron publicaciones internacionales en revistas especializadas sobre parasitología y ecología. Estudios teóricos y prácticos de las interacciones parásitohospedero, en algunos casos, sugieren variaciones evolutivas y ecológicas. La evolución de las interacciones parásitohospedero no se limita a consideraciones coevolutivas, sino que tiene efectos directos sobre caracteres de historia de vida del hospedero, evolución del sexo, comportamiento reproductivo, selección sexual e, incluso, sobre transferencia génica. El estudio de las interacciones parásito-hospedero, como fuerzas modeladoras de la evoluci... Ver más

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Revista U.D.C.A Actualidad & Divulgación Científica

0123-4226

2619-2551

Rico Hernández, Guillermo

UNIVERSIDAD DE CIENCIAS APLICADAS Y AMBIENTALES

10.31910/rudca.v14.n2.2011.782

14

2011-12-31

119

130

Colombia

Parasitismo

Modelos teóricos

Selección sexual

Teoría evolutiva

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spelling Evolución de interacciones parásito - hospedero: coevolución, selección sexual y otras teorías propuestas
The evolution of host-parasite interactions: coevolution, sexual selection and other suggested theories
Esta revisión resume los modelos teóricos de interacciones parásito-hospedero que se encuentran disponibles en la literatura científica. Se revisaron publicaciones internacionales en revistas especializadas sobre parasitología y ecología. Estudios teóricos y prácticos de las interacciones parásitohospedero, en algunos casos, sugieren variaciones evolutivas y ecológicas. La evolución de las interacciones parásitohospedero no se limita a consideraciones coevolutivas, sino que tiene efectos directos sobre caracteres de historia de vida del hospedero, evolución del sexo, comportamiento reproductivo, selección sexual e, incluso, sobre transferencia génica. El estudio de las interacciones parásito-hospedero, como fuerzas modeladoras de la evolución y ecología de los organismos, tiene gran importancia, pues aunque, actualmente, carece de evidencia firme en la práctica en algunas de sus áreas y permanece como difícil de demostrar, es clara de manera teórica.
This review summarizes the theoretical models of the parasitehost interactions, available in literature. Articles publishes in international journal specialized in parasitology and ecology were revised. Some theoretical and experimental studies on host-parasite interactions suggest evolutive and ecologic variations. The evolution of host-parasite interactions is not constrained to coevolutive considerations, it has direct effects on host life-history traits, sex evolution, reproductive behavior, sexual selection and even on gene exchange. Even though there is scarcity of evidence in the practice, the study of host-parasite interactions as modelling forces of the evolution and ecology of organisms is a milestone, it is clear in theory.
Rico Hernández, Guillermo
Parasitismo
Modelos teóricos
Selección sexual
Teoría evolutiva
Parasitism
Theoretical models
Sexual selection
Evolutive theory
14
2
Núm. 2 , Año 2011 :Revista U.D.C.A Actualidad & Divulgación Científica. Julio-Diciembre
Artículo de revista
Journal article
2011-12-31T00:00:00Z
2011-12-31T00:00:00Z
2011-12-31
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Universidad de Ciencias Aplicadas y Ambientales U.D.C.A
Revista U.D.C.A Actualidad & Divulgación Científica
0123-4226
2619-2551
https://revistas.udca.edu.co/index.php/ruadc/article/view/782
10.31910/rudca.v14.n2.2011.782
https://doi.org/10.31910/rudca.v14.n2.2011.782
spa
https://creativecommons.org/licenses/by-nc-sa/4.0/
119
130
ADAMO, S.A. 1999. Evidence for adaptative changes in egg laying in cricket exposed to bacteria and parasites. Animal Behaviour. 57:117-124.
AGRAWAL, F.A.; LIVELY, C.M. 2001. Parasites and the evolution of self- fertilization. Evolution. 55(5):869-879.
ALLISON, A.C. 1982. Coevolution between host and infectious diseases agents and its effects on virulence. En : Anderson, R.M.; May, R.M. eds. Population biology of infectious diseases. Oxford University Press, (Oxford, USA). p.245-268.
ANDERSON, R.M. 1991. Populations and infectious diseases: ecology or epidemiology? J. Animal Ecol. 60:1-50.
BAER, B.; SCHMID-HEMPEL, P. 1999. Experimental variation in polyandry affects a parasite loads and fitness in a bumblebee. Nature. 397:151-154.
BAER, B.; SCHMID-HEMPEL, P. 2001. Unexpected consequences of polyandry for parasitism and fitness in the bumblebee (Bombus terrestris). Evolution. 55(8):1639-1643.
BARLOW, N.D. 1996. The ecology of wildlife disease control: simple models revisited. J. Appl. Ecol. 33:303- 314.
BEGON, M.; HARPER, J.L.; TOWNSEND, C.R. 1986. Ecology: Individuals, populations and communities. Blackwell Science Publications. (New York, USA). 486p.
BENÍTEZ, H.; BRIONES, R.; JEREZ, V. 2008. Asimetría fluctuante en dos poblaciones de Ceroglossus chilensis (Eschscholtz, 1829) (Coleoptera: Carabeidae) en el agroecosistema Pinus radiata D. Don región del Bio- Bio, Chile. Gayana. 72(2):131-139.
BOOTS, M.; SASAKI, A. 2001. Parasite-driven extinction in spatially explicit host-parasite systems. Am. Naturalist. 34(12):706-713.
BUSH, A.O.; FERNÁNDEZ, J.C.; ESCH, G.W.; SEED, J.R. 2001. Parasitism. The diversity and ecology of animal parasites. Cambridge University Press. (Cambridge, UK). 566p.
CARIUS, H.J.; LITTLE, T.J.; EBERT, D. 2001. Genetic variation in host-parasite association: potencial for coevolution and frequency-dependent selection. Evolution. 55(6):1136-1145.
CUNNINGHAM, A.; DASZAK, P.; RODRÍGUEZ, J. 2003. Pathogen pollution: defining a parasitological threat to biodiversity conservation. J. Parasitol. 89 (Suppl.):S78-S83.
DAMIAN, R.T. 1979. Molecular mimicry in biology adaptation. En: Nickol, B.B. ed. Host-Parasite Interfaces. Academic Press. (USA). p.103-126.
DASZAK, P.; CUNNINGHAM, A.; HYATT, A. 2003. Infectious disease and amphibian population declines. Diversity and Distributions. 9:141-150.
DYBDAHL, M.F.; LIVELY, C.M. 1998. Host-parasite coevolution: Evidence for rare advantage and time lagged selection in a natural polulation. Evolution. 52:1057-1066.
DOBSON, A.P.; HUDSON, P.J. 1992. Regulation and stability of a free-living host-parasite system: Trichostrongylus tenuis in red grouse. II. Population models. J. Anim. Ecol. 61:487-498.
EWALD, P.W. 1995. The evolution of virulence: a unifying link between parasitology and ecology. J. Parasitol. 81:659-669.
F UTUYMA, D.J. 1986. Evolutionary Biology. Sinauer Associates. (USA).
GANDON, S.; AGNEW, P.; MICHALAKIS, Y. 2002. Coevolution between parasite virulence and host lifehistory traits. Am. Natural. 160(3):374-387.
GANDON, S.; VAN ZANDT, P.A. 1998. Local adaptation and host-parasite interactions. Trends in Ecology and Evolution. 13(6):214-216.
GRETHER, G.F. 1997. Survival cost of an intrasexual selected ornament in a damselfly. Proc. Royal Soc. London 264:207-210.
GULLAND, F.M.D. 1998. Impact of infectious diseases of wild animal population - a review. En: Grenfell, B.T.; Dobson, A.P. eds. Ecology of infectious diseases in natural populations. Cambridge University Press. (Cambridge, U.K). p.20-51.
HAFNER, M.S.; NADLER, S.A. 1990. Cospeciation in host-parasite assemblages: comparative analysis of rates of evolution and timing of cospeciation events. Syst. Zool. 39:192-204.
HAMILTON, W.D.; ZUK, M. 1982. Heritable true fitness and bright birds: a role for parasites? Science. 218:384- 387.
HOUCK, M.A. 1994. Mites as potencial horizontal transfer vector of eukatyotic mobile genes: Proctolaelaps regalis as a model. J. Parasitol. 80:457-469.
HOWELL, M.J. 1985. Gene exchange between hosts and parasites. Internal J. Parasitol. 15: 597-600.
IWAMURA, Y.; IRIE, Y.; KOMINAMI, R.; NARA, T.; YASURAOKA, K. 1991. Existence of host-related DNA sequences in the schistosome genome. Parasitol. 102:397-403.
JOHNSON, S.G. 2000. Population structure, parasitism, and survivorship of sexual and autodiploid parthenogenetic Campeloma limun. Evolution. 54(1):167-175.
KELLY, A.; HATCHER, M.J.; EVANS, L.; DUNN, A.M. 2001. Mate choice and mate guarding under the influence of a vertically transmited, parasitic sex ratio distorter. Anim. Behaviour. 61:763-770.
KIDWELL, M.G. 1993. Lateral transfer in natural populations of eukariotes. Ann. Rev. Genetics. 27:235- 256.
KOSKELA, T. 2002. Variation in life-history traits among Urtica dioica populations with different history in parasitism by the holoparasitic plant Cuscuta europeae. Evol. Ecol. 16:433-454.
LIVELY, C.M. 1992. Parthenogenesis in a freshwater snail: reproductive assurance versus parasitic release. Evolution. 46:907-913.
LIVELY, C.; APANIUS, V. 1998. Genetic diversity in hostparasite interactions. En: Grenfell, B.; Dobson, A. eds. Ecology of infectious diseases in natural populations. Cambridge University Press. (Cambridge, RU). p.421-449.
LIVELY, C.M.; CRADOCCI, C.; VRIJENHOEK, R.C. 1990. Red Queen Hypothesis supported by parasitism in clonal and sexual fish. Nature 344:864-866.
LYLES, A.M.; DOBSON, A.P. 1993. Infectious disease and intensive management: population dynamics, threatened hosts, and their parasites. J. Zoo and Wildlife Med. 24(3):315-326.
LYTHGOE, K.A. 2000. The coevolution of parasites with host-acquired immunity and the evolution of sex. Evolution. 54(4):1142-1156.
MARTENS, K.; SCH?N, I. 2000. Parasites, predators and the Red Queen. Trends in Ecology & Evolution. 15: 392-393.
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title Evolución de interacciones parásito - hospedero: coevolución, selección sexual y otras teorías propuestas
spellingShingle Evolución de interacciones parásito - hospedero: coevolución, selección sexual y otras teorías propuestas
Rico Hernández, Guillermo
Parasitismo
Modelos teóricos
Selección sexual
Teoría evolutiva
Parasitism
Theoretical models
Sexual selection
Evolutive theory
title_short Evolución de interacciones parásito - hospedero: coevolución, selección sexual y otras teorías propuestas
title_full Evolución de interacciones parásito - hospedero: coevolución, selección sexual y otras teorías propuestas
title_fullStr Evolución de interacciones parásito - hospedero: coevolución, selección sexual y otras teorías propuestas
title_full_unstemmed Evolución de interacciones parásito - hospedero: coevolución, selección sexual y otras teorías propuestas
title_sort evolución de interacciones parásito - hospedero: coevolución, selección sexual y otras teorías propuestas
title_eng The evolution of host-parasite interactions: coevolution, sexual selection and other suggested theories
description Esta revisión resume los modelos teóricos de interacciones parásito-hospedero que se encuentran disponibles en la literatura científica. Se revisaron publicaciones internacionales en revistas especializadas sobre parasitología y ecología. Estudios teóricos y prácticos de las interacciones parásitohospedero, en algunos casos, sugieren variaciones evolutivas y ecológicas. La evolución de las interacciones parásitohospedero no se limita a consideraciones coevolutivas, sino que tiene efectos directos sobre caracteres de historia de vida del hospedero, evolución del sexo, comportamiento reproductivo, selección sexual e, incluso, sobre transferencia génica. El estudio de las interacciones parásito-hospedero, como fuerzas modeladoras de la evolución y ecología de los organismos, tiene gran importancia, pues aunque, actualmente, carece de evidencia firme en la práctica en algunas de sus áreas y permanece como difícil de demostrar, es clara de manera teórica.
description_eng This review summarizes the theoretical models of the parasitehost interactions, available in literature. Articles publishes in international journal specialized in parasitology and ecology were revised. Some theoretical and experimental studies on host-parasite interactions suggest evolutive and ecologic variations. The evolution of host-parasite interactions is not constrained to coevolutive considerations, it has direct effects on host life-history traits, sex evolution, reproductive behavior, sexual selection and even on gene exchange. Even though there is scarcity of evidence in the practice, the study of host-parasite interactions as modelling forces of the evolution and ecology of organisms is a milestone, it is clear in theory.
author Rico Hernández, Guillermo
author_facet Rico Hernández, Guillermo
topicspa_str_mv Parasitismo
Modelos teóricos
Selección sexual
Teoría evolutiva
topic Parasitismo
Modelos teóricos
Selección sexual
Teoría evolutiva
Parasitism
Theoretical models
Sexual selection
Evolutive theory
topic_facet Parasitismo
Modelos teóricos
Selección sexual
Teoría evolutiva
Parasitism
Theoretical models
Sexual selection
Evolutive theory
citationvolume 14
citationissue 2
citationedition Núm. 2 , Año 2011 :Revista U.D.C.A Actualidad & Divulgación Científica. Julio-Diciembre
publisher Universidad de Ciencias Aplicadas y Ambientales U.D.C.A
ispartofjournal Revista U.D.C.A Actualidad & Divulgación Científica
source https://revistas.udca.edu.co/index.php/ruadc/article/view/782
language spa
format Article
rights https://creativecommons.org/licenses/by-nc-sa/4.0/
info:eu-repo/semantics/openAccess
http://purl.org/coar/access_right/c_abf2
references ADAMO, S.A. 1999. Evidence for adaptative changes in egg laying in cricket exposed to bacteria and parasites. Animal Behaviour. 57:117-124.
AGRAWAL, F.A.; LIVELY, C.M. 2001. Parasites and the evolution of self- fertilization. Evolution. 55(5):869-879.
ALLISON, A.C. 1982. Coevolution between host and infectious diseases agents and its effects on virulence. En : Anderson, R.M.; May, R.M. eds. Population biology of infectious diseases. Oxford University Press, (Oxford, USA). p.245-268.
ANDERSON, R.M. 1991. Populations and infectious diseases: ecology or epidemiology? J. Animal Ecol. 60:1-50.
BAER, B.; SCHMID-HEMPEL, P. 1999. Experimental variation in polyandry affects a parasite loads and fitness in a bumblebee. Nature. 397:151-154.
BAER, B.; SCHMID-HEMPEL, P. 2001. Unexpected consequences of polyandry for parasitism and fitness in the bumblebee (Bombus terrestris). Evolution. 55(8):1639-1643.
BARLOW, N.D. 1996. The ecology of wildlife disease control: simple models revisited. J. Appl. Ecol. 33:303- 314.
BEGON, M.; HARPER, J.L.; TOWNSEND, C.R. 1986. Ecology: Individuals, populations and communities. Blackwell Science Publications. (New York, USA). 486p.
BENÍTEZ, H.; BRIONES, R.; JEREZ, V. 2008. Asimetría fluctuante en dos poblaciones de Ceroglossus chilensis (Eschscholtz, 1829) (Coleoptera: Carabeidae) en el agroecosistema Pinus radiata D. Don región del Bio- Bio, Chile. Gayana. 72(2):131-139.
BOOTS, M.; SASAKI, A. 2001. Parasite-driven extinction in spatially explicit host-parasite systems. Am. Naturalist. 34(12):706-713.
BUSH, A.O.; FERNÁNDEZ, J.C.; ESCH, G.W.; SEED, J.R. 2001. Parasitism. The diversity and ecology of animal parasites. Cambridge University Press. (Cambridge, UK). 566p.
CARIUS, H.J.; LITTLE, T.J.; EBERT, D. 2001. Genetic variation in host-parasite association: potencial for coevolution and frequency-dependent selection. Evolution. 55(6):1136-1145.
CUNNINGHAM, A.; DASZAK, P.; RODRÍGUEZ, J. 2003. Pathogen pollution: defining a parasitological threat to biodiversity conservation. J. Parasitol. 89 (Suppl.):S78-S83.
DAMIAN, R.T. 1979. Molecular mimicry in biology adaptation. En: Nickol, B.B. ed. Host-Parasite Interfaces. Academic Press. (USA). p.103-126.
DASZAK, P.; CUNNINGHAM, A.; HYATT, A. 2003. Infectious disease and amphibian population declines. Diversity and Distributions. 9:141-150.
DYBDAHL, M.F.; LIVELY, C.M. 1998. Host-parasite coevolution: Evidence for rare advantage and time lagged selection in a natural polulation. Evolution. 52:1057-1066.
DOBSON, A.P.; HUDSON, P.J. 1992. Regulation and stability of a free-living host-parasite system: Trichostrongylus tenuis in red grouse. II. Population models. J. Anim. Ecol. 61:487-498.
EWALD, P.W. 1995. The evolution of virulence: a unifying link between parasitology and ecology. J. Parasitol. 81:659-669.
F UTUYMA, D.J. 1986. Evolutionary Biology. Sinauer Associates. (USA).
GANDON, S.; AGNEW, P.; MICHALAKIS, Y. 2002. Coevolution between parasite virulence and host lifehistory traits. Am. Natural. 160(3):374-387.
GANDON, S.; VAN ZANDT, P.A. 1998. Local adaptation and host-parasite interactions. Trends in Ecology and Evolution. 13(6):214-216.
GRETHER, G.F. 1997. Survival cost of an intrasexual selected ornament in a damselfly. Proc. Royal Soc. London 264:207-210.
GULLAND, F.M.D. 1998. Impact of infectious diseases of wild animal population - a review. En: Grenfell, B.T.; Dobson, A.P. eds. Ecology of infectious diseases in natural populations. Cambridge University Press. (Cambridge, U.K). p.20-51.
HAFNER, M.S.; NADLER, S.A. 1990. Cospeciation in host-parasite assemblages: comparative analysis of rates of evolution and timing of cospeciation events. Syst. Zool. 39:192-204.
HAMILTON, W.D.; ZUK, M. 1982. Heritable true fitness and bright birds: a role for parasites? Science. 218:384- 387.
HOUCK, M.A. 1994. Mites as potencial horizontal transfer vector of eukatyotic mobile genes: Proctolaelaps regalis as a model. J. Parasitol. 80:457-469.
HOWELL, M.J. 1985. Gene exchange between hosts and parasites. Internal J. Parasitol. 15: 597-600.
IWAMURA, Y.; IRIE, Y.; KOMINAMI, R.; NARA, T.; YASURAOKA, K. 1991. Existence of host-related DNA sequences in the schistosome genome. Parasitol. 102:397-403.
JOHNSON, S.G. 2000. Population structure, parasitism, and survivorship of sexual and autodiploid parthenogenetic Campeloma limun. Evolution. 54(1):167-175.
KELLY, A.; HATCHER, M.J.; EVANS, L.; DUNN, A.M. 2001. Mate choice and mate guarding under the influence of a vertically transmited, parasitic sex ratio distorter. Anim. Behaviour. 61:763-770.
KIDWELL, M.G. 1993. Lateral transfer in natural populations of eukariotes. Ann. Rev. Genetics. 27:235- 256.
KOSKELA, T. 2002. Variation in life-history traits among Urtica dioica populations with different history in parasitism by the holoparasitic plant Cuscuta europeae. Evol. Ecol. 16:433-454.
LIVELY, C.M. 1992. Parthenogenesis in a freshwater snail: reproductive assurance versus parasitic release. Evolution. 46:907-913.
LIVELY, C.; APANIUS, V. 1998. Genetic diversity in hostparasite interactions. En: Grenfell, B.; Dobson, A. eds. Ecology of infectious diseases in natural populations. Cambridge University Press. (Cambridge, RU). p.421-449.
LIVELY, C.M.; CRADOCCI, C.; VRIJENHOEK, R.C. 1990. Red Queen Hypothesis supported by parasitism in clonal and sexual fish. Nature 344:864-866.
LYLES, A.M.; DOBSON, A.P. 1993. Infectious disease and intensive management: population dynamics, threatened hosts, and their parasites. J. Zoo and Wildlife Med. 24(3):315-326.
LYTHGOE, K.A. 2000. The coevolution of parasites with host-acquired immunity and the evolution of sex. Evolution. 54(4):1142-1156.
MARTENS, K.; SCH?N, I. 2000. Parasites, predators and the Red Queen. Trends in Ecology & Evolution. 15: 392-393.
MICHAELI, D.; SENYK, G.; MAOZ, A.; FUCHS, S. 1972. Ascaris cuticle collagen and mammalian collagens: cell mediated and humoral immunity relationships. J. Immunol. 109:103-109.
MOCK, B.A.; GILL, D.E. 1984. The infrapopulation dynamics of trypanosomes in red- spotted newts. Parasitol. 88:267-282.
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