Seeing and not seeing

Current Opinion in Neurobiology

Volumn 12, Issue 6, 2002, Pages 728-734

  Kimchi, Tali ^a   Terkel, Joseph ^a  

^a TEL AVIV UNIVERSITY   (Israel)

Author keywords

[No Author keywords available]

Indexed keywords

ANIMAL BEHAVIOR; ANIMAL COMMUNICATION; CIRCADIAN RHYTHM; DARKNESS; DEPTH PERCEPTION; ENVIRONMENT; LIGHT; MAGNETIC FIELD; MAMMAL; MOLE RAT; NONHUMAN; PRIORITY JOURNAL; REVIEW; SMELLING; SPATIAL ORIENTATION; TACTILE STIMULATION; TIME PERCEPTION; VISION;

ANIMALS; CIRCADIAN RHYTHM; CUES; DARKNESS; DISTANCE PERCEPTION; LIGHT; MAGNETICS; MAMMALS; ORIENTATION; SMELL; SPACE PERCEPTION; TOUCH; VISION; VISUAL PERCEPTION;

EID: 0036902934     PISSN: 09594388     EISSN: None     Source Type: Journal    
DOI: 10.1016/S0959-4388(02)00381-1     Document Type: Review

References (70)

1. Nevo E. Nevo E. Mosaic Evolution of Subterranean Mammals-Regression, Progression, and Global Convergence. 1999;Oxford University Press, New York.
2. Arieli R. Adaptation of the mammalian gas transport system to subterranean life. Nevo E., Reig O.A. Evolution of Subterranean Mammals at the Organismal and Molecular Levels-Progress in Clinical and Biological Research. 1990;251-268 Alan R Liss Inc, New York.
3. Vleck D. The energy cost of burrowing by the pocket gopher Thomomys bottae. Physiol Zool. 52:1979;391-396.
4. Rado R., Shanas U., Zuri I., Terkel J. Seasonal activity in the blind mole rat. Can J Zool. 71:1993;1733-1737.
5. Roper T.J., Bennett N.C., Conradt L., Molteno A.J. Environmental conditions in burrows of two species of African mole-rat, Georhychus capensis and Cryptomys damarensis. J Zool. 254:2001;101-107.
6. Heth G. Burrow pattern of the mole rat Spalax ehrenbergi in two soil types (terra-rossa and rendzina) in Mount Carmel, Israel. J Zool Lond. 217:1989;39-56.
7. Jarvis J.U.M., Bennet M.J., Spinks A.C. Food availability and foraging by wild colonies of Damaraland mole-rats (Cryptomys damarensis): implications for sociality. Oecologia. 113:1998;290-298.
8. Spinks A.C., Bennett N.C., Jarvis J.U.M. A comparison of the ecology of two populations of the common mole-rat, Cryptomys hottentotus hottentotus: the effect of aridity on food, foraging and body mass. Oecologia. 25:2000;341-349.
9. Kuyper M.A. The ecology of the golden mole Amblysomms hottentotus. Mammal Rev. 15:1985;3-11.
10. Hickman G.C. Locomotory activity of captive Cryptomys hottentotus (Mammalia: Bathyergidae), a fossorial rodent. J Zool. 192:1980;225-235.
11. th International Congress on Photobiology, Jerusalem, Israel. 1991;581-589 Plenum Press, New York.
12. Riccio A.P., Goldman B.D. Circadian rhythms of locomotor activity in naked mole-rats (Heterocephalus glaber). Physiol Behav. 71:2000;1-13.
13. Lovegrove B.G., Papenfus M.E. Circadian activity rhythms in the solitary cape mole rat (Georychus capensis: Bathyergidae) with some evidence of splitting. Physiol Behav. 58:1995;679-685.
14. Janssen J.W.H., Bovee-Guertz P.H.M., Peeters Z.P.A., Bowmaker J.K., Cooper H.M., David-Gray Z.K., Nevo E., DeGrip W.J. A fully functional rod pigment in a blind mole mammal. J Biol Chem. 275:2000;38674-38679.
15. Rado R., Shanas U., Terkel J. Entrainment of locomotor in the blind mole rat by brief light pulses. Mammalia. 55:1991;479.
16. Bronchti G., Rado R., Terkel J., Wollberg Z. Retinal projections in the blind mole rat: a WGA-HRP tracing study of a natural degeneration. Dev Brain Res. 58:1991;159-170.
17. Vuillez P., Herbin M., Cooper H.M., Nevo E., Pevet P. Photic induction of Fos immunoreactivity in the suprachiasmatic nuclei of the blind mole rat (Spalax ehrenbergi). Brain Res. 654:1994;81-84.
18. Oelschlager H.H.A., Nakamura M., Herzog M. Visual system labelled by c-fos immunohistochemistry after light exposure in the 'blind' subterranean Zambian mole-rat (Cryptomys anselli). Brain Behav Evol. 55:2000;209-220.
19. Giger R.D. Movements and homing in Townsend's mole near Tillamook, Oregon. J Mamm. 54:1973;648-659.
20. Eloff G. Orientation in the mole-rat Cryptomys. Br J Psychol. 42:1951;134-145.
21. Brett R.A. Ecology of naked mole-rat colonies. Sherman P.W., Jarvis J.U.M., Alexander R.D. The Biology of the Naked Mole Rat. 1991;97-136 Princeton University Press, Princeton.
22. Reichman O.J., Smith S.C. Burrows and burrowing behavior by mammals. Genoways H.H. Current Mammology. 2:1990;197-243 Plenum Press, New York.
23. Jarvis J.U.M., Sale J.B. Burrowing and burrow patterns of East African mole-rats Tachyoryctes, Heliophobius and Heterocephalus. J Zool Lond. 163:1971;451-479.
24. Kimchi T, Terkel J: Assessment of physical properties and spatial arrangement of underground obstacles and selection of optimal detour by the blind mole rat. Anim Behav 2003, revised, submitted version.
25. Kimchi T., Terkel J. Spatial learning and memory in the blind mole rat (Spalax ehrenbergi) in comparison with the laboratory rat and Levant vole. Anim Behav. 61:2001;171-180. The authors used a specially designed multiple labyrinth that resembled the natural tunnel system of SMs such as the blind mole rat, in order to show that despite the mole rat's functional blindness, it is significantly better than the Levant vole and laboratory rat (sighted surface-dwelling species) at learning and memorizing a complex tunnel system.
26. Heth G., Todrank J., Begall S., Koch R., Zilbiger Y., Nevo E., Braude S.H., Burda H. Odors underground: subterranean rodents may not forage 'blindly. Behav Ecol Sociobiol. 52:2002;53-58.
27. Heffner R.S., Heffner H.E. Hearing and sound localization in blind mole rats (Spalax ehrenbergi). Hear Res. 62:1992;206-216.
28. Heffner R.S., Heffner H.E. Degenerate hearing and sound localization in naked mole rats (Heterocephalus glaber), with an overview of central auditory structures. J Comp Nerol. 331:1993;418-433.
29. Heth G., Frankenberg E., Nevo E. Adaptive optimal sound for vocal communication in tunnels of a subterranean mammal (Spalax ehrenbergi). Experienta. 42:1986;1287-1289.
30. Marhold S., Wiltschko W. Magnetic polarity compass or direction finding in a subterranean mammal. Naturwissenschaften. 84:1997;421-423.
31. Kimchi T., Terkel J. Magnetic compass orientation in the blind mole rat Spalax ehrenbergi. J Exp Biol. 204:2001;751-758. Experiments using a pair of 'Helmholtz coils' (to create a defined magnetic field and alter the earth's natural magnetic field) revealed that mole rats sensed and used the earth's magnetic field, independently of light, to determine the location of sleeping nest and food chambers in an eight arm maze, and to find their way to a goal in a labyrinth. As far as we know, this is the only study to have shown that mammals can use the earth's magnetic field for short-distance orientation.
32. Kirschvink J.L., Walker M.M., Diebel C.E. Manetite-based magnetoreception. Curr Opin Neurobiol. 11:2001;462-467.
33. Deutschlander M.E., Phillips J.B., Borland C. The case for light-dependent magnetic orientation in animals. J Exp Biol. 202:1999;891-908.
34. Nemec P., Altmann J., Marhold S., Burda H., Oelschlager H.H.A. Neuroanatomy of magnetoreception: the superior colliculus involved in magnetic orientation in mammals. Science. 294:2001;366-368. The authors combined a behavioral test for magnetic compass orientation in the Zambian mole rat with marking c-Fos expression to indicate neuronal activity. The study showed the superior colliculus region of the mole rat to contain neurons that respond to magnetic stimuli.
35. Kimchi T, Terkel J: Mole rats (Spalax ehrenbergi) use path integration mechanism for spatial orientation. Isr J Zool 2002, in press.
36. Etienne A.S., Maurer R., Berlie J., Reverdin B., Rowe T., Georgakopulos J., Seguinot V. Navigation through vector addition. Nature. 396:1998;161-164.
37. Stackman R.W., Herbert A.M. Rats with lesions of the vestibular system require a visual landmark for spatial navigation. Behav Brain Res. 128:2002;27-40.
38. Save E., Guazzelli A., Poucet B. Dissociation of the effects of bilateral lesions of the dorsal hippocampus and parietal cortex on path integration in the rat. Behav Neurosci. 115:2001;1212-1223.
39. Maaswinkel H., Jarrard L.E., Whishaw I.Q. Hippocampectomized rats are impaired in homing by path integration. Hippocampus. 9:1999;553-561.
40. Whishaw I.Q., Dustin J.H., Wallace D.G. Dead reckoning (path integration) requires the hippocampal formation: evidence from spontaneous exploration and spatial learning tasks in light (allothetic) and dark (idiothetic) tests. Behav Brain Res. 127:2001;49-69.
41. Lindendenlaub T., Burda H., Nevo E. Convergent evolution of the vestibular organ in the subterranean mole-rats, Cryptomys and Spalax as compared with the above ground rat, Rattus. J Morph. 224:1995;203-311.
42. Frahim H.D., Rehkampler G., Nevo E. Brain structure volumes in the mole rat, Spalax ehrenbergi (Spalacidae, Rodentia) in comparison to the rat and suberrestrial insectivores. J Brain Res. 38:1997;209-222.
43. Mason M.J., Narins P.M. Seismic sensitivity in the desert golden mole (Eremitalpa granti): a review. J Comp Psychol. 116:2002;158-163. This report is a continuation of field observations that golden moles orient directly toward grass mounds assumed to contain prey. Geophones recorded that these mounds generate high intensity seismic vibrations [44]. Furthermore, anatomical observation showed the moles to possess enlarged ossicles, possibly adapted to detecting seismic signals [45]. The authors rely here on the results of studies by Narins et al. [44] and Mason [45] to suggest that the golden mole detects prey using seismic signals.
44. Narins P.M., Lewis E.R., Jarvis J.U.M., O'riain J. The use of seismic signals by fossorial southern African mammals: a neroethological gold mine. Brain Res Bull. 44:1997;641-646.
45. Mason M.J. Middle ear structures in fossorial mammals: a comparison with non-fossorial species. J Zool Lond. 255:2001;467-486.
46. Klaur G., Burda H., Nevo E. Adaptive differentiations of the skin of the head in a subterranean rodent, Spalax ehrenbergi. J Morph. 233:1997;53-66.
47. Gorman M.L., Stone R.D. Neal E. The Natural History of Moles. 1990;Christopher Helm, London.
48. Bennet N.C., Faulks C.G. African Mole-Rats, Ecology and Eusociality. 2000;Cambridge University Press, Cambridge, UK.
49. Kimchi T., Terkel J. Importance of touch for the blind mole rat (Spalax ehrenbergi) in learning a complex maze. Isr J Zool. 46:2000;165.
50. Catania K.C. A comparison of the Eimer's organs of three north American moles: the hairy tailed mole (Parascalops breweri), the star-nosed mole (Condylura cristata), and the Eastern mole (Scalopus aquaticus). J Comp Neurol. 354:1995;150-160.
51. Catania K.C. Structure and innveration of the sensory organs on the snout of the star-nosed mole. J Comp Neurol. 351:1995;536-548.
52. Catania K.C., Kaas J.H. Organization of the somatosensory cortex of the star-nosed mole. J Comp Neurol. 351:1995;549-567.
53. Catania K.C. Cortical organization in insectivore: the parallel evolution of the sensory periphery and the brain. Brain Behav Evol. 55:2000;311-321. Using the technique [52] of staining for the metabolic enzyme, cytochrome oxidase, organization of the somatosensory cortex was compared in the African hedgehog, the masked shrew, the Eastern mole and the star-nosed mole. Results show that in these four insectivore species, possessing different configurations of peripheral sensory receptors, the cortex evolved in parallel with the respective changes to the different sensory peripheries.
54. Mann M.D., Rehkamper G., Reinke H., Frahm H.D., Necker R., Nevo E. Size of somatosensory cortex and of somatosensory thalamic nuclei of the naturally blind mole rat, Spalax ehrenbergi. J Brain Res. 38:1997;47-59.
55. Necker R., Rehkampler G., Nevo E. Electrophysiological mapping of body representation in the cortex of the blind mole rat. Neuroreport. 3:1992;505-508.
56. Bennet N.C., Jarvis J.U.M. The social structure and reproductive biology of colonies of the mole-rat, Cryptomys damarensis (Rodentia, Bathyergidae). J Mammal. 69:1988;293-302.
57. Gorman M.L., Stone R.D. Mutual avoidance by European moles Talpa europea. Macdonald D.W., Muller-Schwarze D., Natyncuk S.E. Chemical Signals in Vertebrates. 5:1990;367-377 Oxford University Press, Oxford, UK.
58. Loy A., Dupre E., Capanna E. Territorial behavior in Talpa romana, a fossorial insectivore from Southcentral Italy. J Mamm. 75:1994;529-535.
59. Zuri I., Terkel J. Locomotor patterns, territory, and tunnel utilization in the mole rat Spalax ehrenbergi. J Zool Lond. 240:1996;123-140.
60. Stone R.D., Gorman M.L. Social organization of the European mole (Talpa europea) and the Pyrenean desman (Galemys pyrenaicus). Mamm Rev. 15:1985;35-42.
61. Mason J.M., Narins P.M. Seismic signals use by fossorial mammals. Am Zool. 41:2001;1171-1184. The authors review the use of seismic signals among different subterranean mammals from theoretical, behavioral and anatomical prospects, suggesting the importance of this sensory channel for mammals living underground.
62. Rado R., Levi N., Hauser H., Witcher J., Adler N.I., Wollberg Z., Terkel J. Seismic signaling as a means of communication in subterranean mammal. Anim Behav. 35:1987;1249-1251.
63. Narins P.M., Reichman O.J., Jarvis J.U.M., Lewis E.R. Seismic signal transmission between burrows of the Cape mole-rat, Georychus capensis. J Comp Physiol. 170:1992;13-21.
64. Heth G., Frankenburg E., Nevo E. Vibrational communication in subterranean mole rats (Spalax ehrenbergi). Behav Ecol Sociobiol. 21:1987;31-33.
65. Liu H.P., Anderson D.L., Kanamori H. Velocity dispersion due to inelasticity: implication for seismology and mantle composition. Geophys J R Astronomi Soc. 47:1979;41-58.
66. Rado R., Himelfarb M., Arensburg B., Terkel J., Wollberg Z. Are seismic communication signals transmitted in the blind mole-rat by bone conduction? Hear Res. 41:1989;23-30.
67. Rado R., Terkel J., Wollberg Z. Seismic communication signals in the blind mole-rat (Spalax ehrenbergi): electrophysiological and behavioral evidence for their processing by the auditory system. J Comp Physiol. 183:1998;503-511.
68. Nevo E., Heth G., Pratt H. Seismic communication in a blind subterranean mammal: a major somatosensory mechanism in adaptive evolution underground. Proc Natl Acad Sci USA. 88:1991;1256-1260.
69. Walker M.M., Diebel C.E., Haugh C.V., Pankhurst P.M., Montgomery J.C., Green C.R. Structure and function of the vertebrate magnetic sense. Nature. 371:1997;371-376.
70. Diebel C.E., Proksch R., Green C.R., Neilson P., Walker M.M. Magnetite defines a vertebrate magnetoreceptors. Nature. 406:2000;299-302. Following behavioral, electrophysiological and preliminary anatomical studies of magnetite-based magnetic sense in rainbow trout [69], a confocal magnetic force microscope identified the properties of the crystals suspected to be the magnetoreceptors. A three-dimensional reconstruction of the candidate receptors demonstrated arrangement of the crystals in the cell.