Cuesta arriba: integración de rutas en tres dimensiones por la hormiga arriera, Atta colombica

La integración de rutas es una estrategia de navegación ampliamente usada por muchos animales que les permite retornar a un punto de partida, mediante el procesamiento de información angular y de distancia. A pesar de que la integración de rutas está bien establecida en el plano bidimensional (2D) a...

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Fecha de publicación:
2021
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Universidad del Rosario
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Repositorio EdocUR - U. Rosario
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spa
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oai:repository.urosario.edu.co:10336/30933
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https://doi.org/10.48713/10336_30933
https://repository.urosario.edu.co/handle/10336/30933
Palabra clave:
Hormigas cortadoras de hojas Atta colombica
Percepción en tres dimensiones de las hormigas
Mecanismo de navegación visoespacial en hormigas cortadoras de hojas
Sentido de la orientación basado en integración de rutas (IR) en insectos
Uso de información alotética o idiotética en hormigas
Invertebrados
Leaf cutter ants Atta colombica
Three-dimensional perception of ants
Visuospatial navigation mechanism in leaf cutter ants
Path integration (IR) based orientation sense in insects
Use of allothetic or idiotic information in ants
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Atribución-SinDerivadas 2.5 Colombia
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network_acronym_str EDOCUR2
network_name_str Repositorio EdocUR - U. Rosario
repository_id_str
dc.title.spa.fl_str_mv Cuesta arriba: integración de rutas en tres dimensiones por la hormiga arriera, Atta colombica
dc.title.TranslatedTitle.eng.fl_str_mv Uphill: integration of routes in three dimensions by the arriera ant, Atta colombica
title Cuesta arriba: integración de rutas en tres dimensiones por la hormiga arriera, Atta colombica
spellingShingle Cuesta arriba: integración de rutas en tres dimensiones por la hormiga arriera, Atta colombica
Hormigas cortadoras de hojas Atta colombica
Percepción en tres dimensiones de las hormigas
Mecanismo de navegación visoespacial en hormigas cortadoras de hojas
Sentido de la orientación basado en integración de rutas (IR) en insectos
Uso de información alotética o idiotética en hormigas
Invertebrados
Leaf cutter ants Atta colombica
Three-dimensional perception of ants
Visuospatial navigation mechanism in leaf cutter ants
Path integration (IR) based orientation sense in insects
Use of allothetic or idiotic information in ants
title_short Cuesta arriba: integración de rutas en tres dimensiones por la hormiga arriera, Atta colombica
title_full Cuesta arriba: integración de rutas en tres dimensiones por la hormiga arriera, Atta colombica
title_fullStr Cuesta arriba: integración de rutas en tres dimensiones por la hormiga arriera, Atta colombica
title_full_unstemmed Cuesta arriba: integración de rutas en tres dimensiones por la hormiga arriera, Atta colombica
title_sort Cuesta arriba: integración de rutas en tres dimensiones por la hormiga arriera, Atta colombica
dc.contributor.advisor.none.fl_str_mv Riveros Rivera, Andre Josafat
Srygley, Robert B
dc.subject.spa.fl_str_mv Hormigas cortadoras de hojas Atta colombica
Percepción en tres dimensiones de las hormigas
Mecanismo de navegación visoespacial en hormigas cortadoras de hojas
Sentido de la orientación basado en integración de rutas (IR) en insectos
Uso de información alotética o idiotética en hormigas
topic Hormigas cortadoras de hojas Atta colombica
Percepción en tres dimensiones de las hormigas
Mecanismo de navegación visoespacial en hormigas cortadoras de hojas
Sentido de la orientación basado en integración de rutas (IR) en insectos
Uso de información alotética o idiotética en hormigas
Invertebrados
Leaf cutter ants Atta colombica
Three-dimensional perception of ants
Visuospatial navigation mechanism in leaf cutter ants
Path integration (IR) based orientation sense in insects
Use of allothetic or idiotic information in ants
dc.subject.ddc.spa.fl_str_mv Invertebrados
dc.subject.keyword.spa.fl_str_mv Leaf cutter ants Atta colombica
Three-dimensional perception of ants
Visuospatial navigation mechanism in leaf cutter ants
Path integration (IR) based orientation sense in insects
Use of allothetic or idiotic information in ants
description La integración de rutas es una estrategia de navegación ampliamente usada por muchos animales que les permite retornar a un punto de partida, mediante el procesamiento de información angular y de distancia. A pesar de que la integración de rutas está bien establecida en el plano bidimensional (2D) aún no se entiende muy bien si se extiende a la tercera dimensión (3D). Aquí investigamos si A. colombica tiene la capacidad de calcular vectores en 3D mediante el uso de diferentes experimentos en los que se modifica la inclinación y la distancia de diferentes recorridos. Los resultados indican que A. colombica es capaz de percibir los cambios en la dirección e inclinación de sus rutas e incorpora dicha información angular al integrador de rutas con las distancias al suelo correspondientes; mostrando una mejor habilidad para hacerlo en las configuraciones 3D. Estos resultados sugieren una posible representación tridimensional de su mundo, sumada a lo que podría ser una representación neural del espacio mucho más tolerante al ruido del procesamiento de la entrada y salida de información.
publishDate 2021
dc.date.accessioned.none.fl_str_mv 2021-02-17T22:37:15Z
dc.date.available.none.fl_str_mv 2021-02-17T22:37:15Z
dc.date.created.none.fl_str_mv 2021-01-27
dc.type.eng.fl_str_mv bachelorThesis
dc.type.coar.fl_str_mv http://purl.org/coar/resource_type/c_7a1f
dc.type.document.spa.fl_str_mv Artículo
dc.type.spa.spa.fl_str_mv Trabajo de grado
dc.identifier.doi.none.fl_str_mv https://doi.org/10.48713/10336_30933
dc.identifier.uri.none.fl_str_mv https://repository.urosario.edu.co/handle/10336/30933
url https://doi.org/10.48713/10336_30933
https://repository.urosario.edu.co/handle/10336/30933
dc.language.iso.spa.fl_str_mv spa
language spa
dc.rights.spa.fl_str_mv Atribución-SinDerivadas 2.5 Colombia
dc.rights.coar.fl_str_mv http://purl.org/coar/access_right/c_abf2
dc.rights.acceso.spa.fl_str_mv Abierto (Texto Completo)
dc.rights.uri.none.fl_str_mv http://creativecommons.org/licenses/by-nd/2.5/co/
rights_invalid_str_mv Atribución-SinDerivadas 2.5 Colombia
Abierto (Texto Completo)
http://creativecommons.org/licenses/by-nd/2.5/co/
http://purl.org/coar/access_right/c_abf2
dc.format.mimetype.none.fl_str_mv application/pdf
dc.publisher.spa.fl_str_mv Universidad del Rosario
dc.publisher.department.spa.fl_str_mv Facultad de Ciencias Naturales y Matemáticas
dc.publisher.program.spa.fl_str_mv Biología
institution Universidad del Rosario
dc.source.bibliographicCitation.spa.fl_str_mv Banks AN, Srygley RB. 2003. Orientation by magnetic field in leaf-cutter ants, Atta colombica (Hymenoptera: Formicidae). Ethology 109: 835–846.
Cheung A. 2014. Animal path integration: A model of positional uncertainty along tortuous paths. Journal of Theoretical Biology 341: 17–33.
Cheung A, Zhang S, Stricker C, Srinivasan M V. 2007. Animal navigation: the difficulty of moving in a straight line. Biological cybernetics 97: 47–61.
Cheung A, Zhang S, Stricker C, Srinivasan M V. 2008. Animal navigation: general properties of directed walks. Biological Cybernetics 99: 197–217.
Collett TS, Collett M. 2002. Memory use in insect visual navigation. Nature Reviews Neuroscience 3: 542–552.
Dyer FC. 1998. Cognitive ecology of navigation. In: Cognitive ecology: The evolutionary ecology of information processing and decision making. Chicago, IL, US: University of Chicago Press, 201–260.
Esch H, Burns J. 1996. Distance estimation by foraging honeybees. The Journal of Experimental Biology 199: 155 LP – 162.
Evangelista C, Kraft P, Dacke M, Labhart T, Srinivasan M V. 2014. Honeybee navigation: critically examining the role of the polarization compass. Philosophical Transactions of the Royal Society B: Biological Sciences 369: 20130037.
Grah G, Wehner R, Ronacher B. 2005. Path integration in a three-dimensional maze: ground distance estimation keeps desert ants <em>Cataglyphis fortis</em> on course. Journal of Experimental Biology 208: 4005 LP – 4011.
Grah G, Wehner R, Ronacher B. 2007. Desert ants do not acquire and use a three-dimensional global vector. Frontiers in Zoology 4: 12.
Heinze S, Narendra A, Cheung A. 2018. Principles of Insect Path Integration. Current Biology 28: R1043–R1058.
Hironaka M, Filippi L, Nomakuchi S, Horiguchi H, Hariyama T. 2007. Hierarchical use of chemical marking and path integration in the homing trip of a subsocial shield bug. Animal Behaviour 73: 739–745.
Hoffmann G. 1983. The search behavior of the desert isopod Hemilepistus reaumuri as compared with a systematic search. Behavioral Ecology and Sociobiology 13: 93–106.
Kempf WW. 1972. Catálogo abreviado das formigas da região Neotropical. Studia Entomologica 15.
Lebhardt F, Koch J, Ronacher B. 2012. The polarization compass dominates over idiothetic cues in path integration of desert ants. The Journal of Experimental Biology 215: 526 LP – 535.
Lipp A, Wolf H, Lehmann F-O. 2005. Walking on inclines: energetics of locomotion in the ant Camponotus. The Journal of experimental biology 208: 707–719.
Markl H. 1962. Borstenfelder an den Gelenken als Schweresinnesorgane bei Ameisen und anderen Hymenopteren. Zeitschrift für vergleichende Physiologie 45: 475–569.
Markl H. 1964. Geomenotaktische Fehlorientierung bei Formica polyctena Förster. Zeitschrift für vergleichende Physiologie 48: 552–586.
Müller M, Wehner R. 1988. Path integration in desert ants, <em>Cataglyphis fortis</em> Proceedings of the National Academy of Sciences 85: 5287 LP – 5290.
Narendra A, Cheng K, Sulikowski D, Wehner R. 2008. Search strategies of ants in landmarkrich habitats. Journal of Comparative Physiology A 194: 929–938.
Patel RN, Cronin TW. 2020. Path integration error and adaptable search behaviors in a mantis shrimp. bioRxiv: 2020.03.04.977439.
Riveros AJ, Esquivel DMS, Wajnberg E, Srygley RB. 2014. Do leaf-cutter ants Atta colombica obtain their magnetic sensors from soil? Behavioral Ecology and Sociobiology 68: 55– 62.
Riveros AJ, Srygley RB. 2008. Do leafcutter ants, Atta colombica, orient their path-integrated home vector with a magnetic compass? Animal Behaviour 75: 1273–1281.
Ronacher B. 2020. Path integration in a three-dimensional world: the case of desert ants. Journal of Comparative Physiology A 206: 379–387.
Ronacher B, Westwig E, Wehner R. 2006. Integrating two-dimensional paths: do desert ants process distance information in the absence of celestial compass cues? Journal of Experimental Biology 209: 3301 LP – 3308.
Sommer S, Wehner R. 2004. The ant’s estimation of distance travelled: experiments with desert ants, Cataglyphis fortis. Journal of Comparative Physiology A 190: 1–6.
Srinivasan M V, Zhang S, Altwein M, Tautz J. 2000. Honeybee Navigation: Nature and Calibration of the "Odometer" Science 287: 851 LP – 853.
Vilela EF, Jaffé K, Howse PE. 1987. Orientation in leaf-cutting ants (Formicidae: Attini). Animal Behaviour 35: 1443–1453.
Wehner R. 1997. The ant’s celestial compass system: spectral and polarization channels BT - Orientation and Communication in Arthropods. In: Lehrer M, ed. Basel: Birkhäuser Basel, 145– 185.
Wehner R, Meier C, Zollikofer C. 2004. The ontogeny of foragwehaviour in desert ants, Cataglyphis bicolor. Ecological Entomology 29: 240–250.
Wehner R, Srinivasan M V. 1981. Searching behaviour of desert ants, genusCataglyphis (Formicidae, Hymenoptera). Journal of comparative physiology 142: 315–338.
Wehner R, Srinivasan M. 2003. Path integration in insects. In: The Neurobiology of Spatial Behaviour. 9–30.
Weihmann T, Blickhan R. 2009. Comparing inclined locomotion in a ground-living and a climbing ant species: sagittal plane kinematics. Journal of Comparative Physiology A 195: 1011.
Wetterer J, Gruner D, Lopez J. 1998. Foraging and Nesting Ecology of Acromyrmex octospinosus (Hymenoptera: Formicidae) in a Costa Rican Tropical Dry Forest. Florida Entomologist 81: 61–67.
Wirth R, Herz H, Ryel R, Beyschlag W, Hölldobler B. 2003. Herbivory of Leaf-Cutting Ants: A Case Study on Atta Colombica in the Tropical Rainforest of Panama.
Wittlinger M, Wehner R, Wolf H. 2006. The Ant Odometer: Stepping on Stilts and Stumps. Science (New York, N.Y.) 312: 1965–1967.
Wittlinger M, Wehner R, Wolf H. 2007a. The desert ant odometer: A stride integrator that accounts for stride length and walking speed. The Journal of experimental biology 210: 198–207.
Wittlinger M, Wolf H, Wehner R. 2007b. Hair plate mechanoreceptors associated with body segments are not necessary for three-dimensional path integration in desert ants, <em>Cataglyphis fortis</em> Journal of Experimental Biology 210: 375 LP – 382.
Wohlgemuth S, Ronacher B, Wehner R. 2001. Ant odometry in the third dimension. Nature 411: 795–798.
Wohlgemuth S, Ronacher B, Wehner R. 2002. Distance estimation in the third dimension in desert ants. Journal of comparative physiology. A, Neuroethology, sensory, neural, and behavioral physiology 188: 273–281.
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spelling Riveros Rivera, Andre Josafat79974449600Srygley, Robert B557a22d4-1d23-4bb0-8ccc-a104880502bd600Cardona Hurtado, DavidBiólogoFull time87c58b40-83d2-446b-ba85-a22fa1695f406002021-02-17T22:37:15Z2021-02-17T22:37:15Z2021-01-27La integración de rutas es una estrategia de navegación ampliamente usada por muchos animales que les permite retornar a un punto de partida, mediante el procesamiento de información angular y de distancia. A pesar de que la integración de rutas está bien establecida en el plano bidimensional (2D) aún no se entiende muy bien si se extiende a la tercera dimensión (3D). Aquí investigamos si A. colombica tiene la capacidad de calcular vectores en 3D mediante el uso de diferentes experimentos en los que se modifica la inclinación y la distancia de diferentes recorridos. Los resultados indican que A. colombica es capaz de percibir los cambios en la dirección e inclinación de sus rutas e incorpora dicha información angular al integrador de rutas con las distancias al suelo correspondientes; mostrando una mejor habilidad para hacerlo en las configuraciones 3D. Estos resultados sugieren una posible representación tridimensional de su mundo, sumada a lo que podría ser una representación neural del espacio mucho más tolerante al ruido del procesamiento de la entrada y salida de información.Path integration is a navigation strategy widely used by many animals enabling them to return to their starting point, through the processing of angular and distance information. Although path integration is well established in the two-dimensional (2D) plane, it is still not well understood whether it extends to the third dimension (3D). This project investigated whether A. colombica can compute vectors in 3D by using different experiments in which the inclination and distance of different routes were modified. The results indicate that A. colombica is able of perceiving changes in the direction and inclination of its routes and incorporates the angular information to the path integrator with the corresponding distances to the ground; exhibiting better ability to do so in 3D settings. These results suggest a possible three-dimensional representation of their world, in addition to what could be a neural representation of space that is much more tolerant to the noise of information input and output processing.application/pdfhttps://doi.org/10.48713/10336_30933 https://repository.urosario.edu.co/handle/10336/30933spaUniversidad del RosarioFacultad de Ciencias Naturales y MatemáticasBiologíaAtribución-SinDerivadas 2.5 ColombiaAbierto (Texto Completo)EL AUTOR, manifiesta que la obra objeto de la presente autorización es original y la realizó sin violar o usurpar derechos de autor de terceros, por lo tanto la obra es de exclusiva autoría y tiene la titularidad sobre la misma.http://creativecommons.org/licenses/by-nd/2.5/co/http://purl.org/coar/access_right/c_abf2Banks AN, Srygley RB. 2003. Orientation by magnetic field in leaf-cutter ants, Atta colombica (Hymenoptera: Formicidae). Ethology 109: 835–846.Cheung A. 2014. Animal path integration: A model of positional uncertainty along tortuous paths. Journal of Theoretical Biology 341: 17–33.Cheung A, Zhang S, Stricker C, Srinivasan M V. 2007. Animal navigation: the difficulty of moving in a straight line. Biological cybernetics 97: 47–61.Cheung A, Zhang S, Stricker C, Srinivasan M V. 2008. Animal navigation: general properties of directed walks. Biological Cybernetics 99: 197–217.Collett TS, Collett M. 2002. Memory use in insect visual navigation. Nature Reviews Neuroscience 3: 542–552.Dyer FC. 1998. Cognitive ecology of navigation. In: Cognitive ecology: The evolutionary ecology of information processing and decision making. Chicago, IL, US: University of Chicago Press, 201–260.Esch H, Burns J. 1996. Distance estimation by foraging honeybees. The Journal of Experimental Biology 199: 155 LP – 162.Evangelista C, Kraft P, Dacke M, Labhart T, Srinivasan M V. 2014. Honeybee navigation: critically examining the role of the polarization compass. Philosophical Transactions of the Royal Society B: Biological Sciences 369: 20130037.Grah G, Wehner R, Ronacher B. 2005. Path integration in a three-dimensional maze: ground distance estimation keeps desert ants <em>Cataglyphis fortis</em> on course. Journal of Experimental Biology 208: 4005 LP – 4011.Grah G, Wehner R, Ronacher B. 2007. Desert ants do not acquire and use a three-dimensional global vector. Frontiers in Zoology 4: 12.Heinze S, Narendra A, Cheung A. 2018. Principles of Insect Path Integration. Current Biology 28: R1043–R1058.Hironaka M, Filippi L, Nomakuchi S, Horiguchi H, Hariyama T. 2007. Hierarchical use of chemical marking and path integration in the homing trip of a subsocial shield bug. Animal Behaviour 73: 739–745.Hoffmann G. 1983. The search behavior of the desert isopod Hemilepistus reaumuri as compared with a systematic search. Behavioral Ecology and Sociobiology 13: 93–106.Kempf WW. 1972. Catálogo abreviado das formigas da região Neotropical. Studia Entomologica 15.Lebhardt F, Koch J, Ronacher B. 2012. The polarization compass dominates over idiothetic cues in path integration of desert ants. The Journal of Experimental Biology 215: 526 LP – 535.Lipp A, Wolf H, Lehmann F-O. 2005. Walking on inclines: energetics of locomotion in the ant Camponotus. The Journal of experimental biology 208: 707–719.Markl H. 1962. Borstenfelder an den Gelenken als Schweresinnesorgane bei Ameisen und anderen Hymenopteren. Zeitschrift für vergleichende Physiologie 45: 475–569.Markl H. 1964. Geomenotaktische Fehlorientierung bei Formica polyctena Förster. Zeitschrift für vergleichende Physiologie 48: 552–586.Müller M, Wehner R. 1988. Path integration in desert ants, <em>Cataglyphis fortis</em> Proceedings of the National Academy of Sciences 85: 5287 LP – 5290.Narendra A, Cheng K, Sulikowski D, Wehner R. 2008. Search strategies of ants in landmarkrich habitats. Journal of Comparative Physiology A 194: 929–938.Patel RN, Cronin TW. 2020. Path integration error and adaptable search behaviors in a mantis shrimp. bioRxiv: 2020.03.04.977439.Riveros AJ, Esquivel DMS, Wajnberg E, Srygley RB. 2014. Do leaf-cutter ants Atta colombica obtain their magnetic sensors from soil? Behavioral Ecology and Sociobiology 68: 55– 62.Riveros AJ, Srygley RB. 2008. Do leafcutter ants, Atta colombica, orient their path-integrated home vector with a magnetic compass? Animal Behaviour 75: 1273–1281.Ronacher B. 2020. Path integration in a three-dimensional world: the case of desert ants. Journal of Comparative Physiology A 206: 379–387.Ronacher B, Westwig E, Wehner R. 2006. Integrating two-dimensional paths: do desert ants process distance information in the absence of celestial compass cues? Journal of Experimental Biology 209: 3301 LP – 3308.Sommer S, Wehner R. 2004. The ant’s estimation of distance travelled: experiments with desert ants, Cataglyphis fortis. Journal of Comparative Physiology A 190: 1–6.Srinivasan M V, Zhang S, Altwein M, Tautz J. 2000. Honeybee Navigation: Nature and Calibration of the "Odometer" Science 287: 851 LP – 853.Vilela EF, Jaffé K, Howse PE. 1987. Orientation in leaf-cutting ants (Formicidae: Attini). Animal Behaviour 35: 1443–1453.Wehner R. 1997. The ant’s celestial compass system: spectral and polarization channels BT - Orientation and Communication in Arthropods. In: Lehrer M, ed. Basel: Birkhäuser Basel, 145– 185.Wehner R, Meier C, Zollikofer C. 2004. The ontogeny of foragwehaviour in desert ants, Cataglyphis bicolor. Ecological Entomology 29: 240–250.Wehner R, Srinivasan M V. 1981. Searching behaviour of desert ants, genusCataglyphis (Formicidae, Hymenoptera). Journal of comparative physiology 142: 315–338.Wehner R, Srinivasan M. 2003. Path integration in insects. In: The Neurobiology of Spatial Behaviour. 9–30.Weihmann T, Blickhan R. 2009. Comparing inclined locomotion in a ground-living and a climbing ant species: sagittal plane kinematics. Journal of Comparative Physiology A 195: 1011.Wetterer J, Gruner D, Lopez J. 1998. Foraging and Nesting Ecology of Acromyrmex octospinosus (Hymenoptera: Formicidae) in a Costa Rican Tropical Dry Forest. Florida Entomologist 81: 61–67.Wirth R, Herz H, Ryel R, Beyschlag W, Hölldobler B. 2003. Herbivory of Leaf-Cutting Ants: A Case Study on Atta Colombica in the Tropical Rainforest of Panama.Wittlinger M, Wehner R, Wolf H. 2006. The Ant Odometer: Stepping on Stilts and Stumps. Science (New York, N.Y.) 312: 1965–1967.Wittlinger M, Wehner R, Wolf H. 2007a. The desert ant odometer: A stride integrator that accounts for stride length and walking speed. The Journal of experimental biology 210: 198–207.Wittlinger M, Wolf H, Wehner R. 2007b. Hair plate mechanoreceptors associated with body segments are not necessary for three-dimensional path integration in desert ants, <em>Cataglyphis fortis</em> Journal of Experimental Biology 210: 375 LP – 382.Wohlgemuth S, Ronacher B, Wehner R. 2001. Ant odometry in the third dimension. Nature 411: 795–798.Wohlgemuth S, Ronacher B, Wehner R. 2002. Distance estimation in the third dimension in desert ants. Journal of comparative physiology. 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