Influences of thermal acclimation and acute temperature change on the motility of epithelial wound-healing cells (keratocytes) of tropical,temperate and Antarctic fish
10.1242/jeb.00706
Crossref journal-article
The Company of Biologists
Journal of Experimental Biology (237)
Abstract

SUMMARYThe ability to heal superficial wounds is an important element in an organism's repertoire of adaptive responses to environmental stress. In fish,motile cells termed keratocytes are thought to play important roles in the wound-healing process. Keratocyte motility, like other physiological rate processes, is likely to be dependent on temperature and to show adaptive variation among differently thermally adapted species. We have quantified the effects of acute temperature change and thermal acclimation on actin-based keratocyte movement in primary cultures of keratocytes from four species of teleost fish adapted to widely different thermal conditions: two eurythermal species, the longjaw mudsucker Gillichthys mirabilis (environmental temperature range of approximately 10-37°C) and a desert pupfish, Cyprinodon salinus (10-40°C), and two species from stable thermal environments, an Antarctic notothenioid, Trematomus bernacchii(-1.86°C), and a tropical clownfish, Amphiprion percula(26-30°C). For all species, keratocyte speed increased with increasing temperature. G. mirabilis and C. salinus keratocytes reached maximal speeds at 25°C and 35°C, respectively, temperatures within the species' normal thermal ranges. Keratocytes of the stenothermal species continued to increase in speed as temperature increased above the species'normal temperature ranges. The thermal limits of keratocyte motility appear to exceed those of whole-organism thermal tolerance, notably in the case of T. bernacchii. Keratocytes of T. bernacchii survived supercooling to -6°C and retained motility at temperatures as high as 20°C. Mean keratocyte speed was conserved at physiological temperatures for the three temperate and tropical species, which suggests that a certain rate of motility is advantageous for wound healing. However, there was no temperature compensation in speed of movement for keratocytes of the Antarctic fish, which have extremely slow rates of movement at physiological temperatures. Keratocytes from all species moved in a persistent,unidirectional manner at low temperatures but at higher temperatures began to take more circular or less-persistent paths. Thermal acclimation affected the persistence and turning magnitude of keratocytes, with warmer acclimations generally yielding more persistent cells that followed straighter paths. However, acclimation did not alter the effect of experimental temperature on cellular speed. These findings suggest that more than one temperature-sensitive mechanism may govern cell motility: the rate-limiting process(es) responsible for speed is distinct from the mechanism(s) underlying directionality and persistence. Keratocytes represent a useful study system for evaluating the effects of temperature at the cellular level and for studying adaptive variation in actin-based cellular movement and capacity for wound healing.

Bibliography

Ream, R. A., Theriot, J. A., & Somero, G. N. (2003). Influences of thermal acclimation and acute temperature change on the motility of epithelial wound-healing cells (keratocytes) of tropical,temperate and Antarctic fish. Journal of Experimental Biology, 206(24), 4539–4551.

Authors 3
  1. Rachael A. Ream (first)
  2. Julie A. Theriot (additional)
  3. George N. Somero (additional)
References 33 Referenced 51
  1. Baudoy, A. M., Danton, M. and Merle, G. (1980). Virémie printanière de la carpe: étude expérimentale de l'infection évoluant èdifférentes températures. Ann. Virol.131E,479-488.
  2. Bly, J. E. and Clem, L. W. (1991). Temperature-mediated processes in teleost immunity: in vitroimmunosuppression induced by in vivo low temperature in channel catfish. Vet. Immunol. Immunopathol.28,365-377. (10.1016/0165-2427(91)90127-X)
  3. Bly, J. E. and Clem, L. W. (1992). Temperature and teleost immune functions. Fish Shellfish Immunol.2, 159-171. (10.1016/S1050-4648(05)80056-7)
  4. Collazos, M. E., Ortega, E. and Barriga, C.(1994). Effect of temperature on the immune system of a cyprinid fish (Tinca tinca, L.). Blood phagocyte function at low temperature. Fish Shellfish Immunol.4, 231-238.
  5. Cossins, A. R., Behan-Martin, M., Jones, G. and Bowler, K.(1987). Lipid-protein interactions in the adaptive regulation of membrane function. Biochem. Soc. Trans.15, 77-81. (10.1042/bst0150077)
  6. Detrich, H. W., III, Parker, S. K., Williams, R. C., Jr,Nogales, E. and Downing, K. H. (2000). Cold adaptation of microtubule assembly and dynamics. Structural interpretation of primary sequence changes present in the alpha- and beta-tubulins of Antarctic fishes. J. Biol. Chem.275,37038-37047. (10.1074/jbc.M005699200)
  7. DeVries, A. L. and Cheng, C.-H. C. (1992). The role of antifreeze glycopeptides and peptides in the survival of cold-water fishes. In Water and Life (ed. G. N. Somero, C. B. Osmond and C. L. Bolis), pp. 301-315. Berlin:Springer-Verlag. (10.1007/978-3-642-76682-4_18)
  8. Dexiang, C. and Ainsworth, A. J. (1991). Effect of temperature on the immune system of channel catfish (Ictalurus punctatus). II. Adaptation of anterior kidney phagocytes to 10°C. Comp. Biochem. Physiol. A100,913-918.
  9. Ellsaesser, C. F. and Clem, L. W. (1986). Haematological and immunological changes in channel catfish stressed by handling and transport. J. Fish Biol.28,511-521. (10.1111/j.1095-8649.1986.tb05187.x)
  10. Eschmeyer, W. N., Herald, E. S. and Hamann, H.(1983). A Field Guide to Pacific Coast Fishes of North America. Boston: Houghton Mifflin.
  11. Euteneuer, U. and Schliwa, M. (1984). Persistent directional motility of cells and cytoplasmic fragments in the absence of microtubules. Nature310, 58-61. (10.1038/310058a0)
  12. Fischer, W. and Hureau, J. C. (1985). FAO Species Identification Sheets for Fishery Purposes: Southern Ocean (Fishing Areas 48, 58 and 88) (CCAMLR Convention Area). Rome: Food and Agriculture Organization of the United Nations.
  13. Goodrich, H. B. (1924). Cell behavior in tissue cultures. Biol. Bull.46,252-262. (10.2307/1536726)
  14. Hartmann-Petersen, R., Walmod, P. S., Berezin, A. V. and Bock,E. (2000). Individual cell motility studied by time-lapse video recording: influence of experimental conditions. Cytometry40,260-270. (10.1002/1097-0320(20000801)40:4<260::AID-CYTO2>3.0.CO;2-J)
  15. Hochachka, P. and Somero, G. N. (2002). Biochemical Adaptation: Mechanism and Process in Physiological Evolution. New York: Oxford University Press. (10.1093/oso/9780195117028.001.0001)
  16. Hofmann, G. E., Buckley, B. A., Airaksinen, S., Keen, J. E. and Somero, G. N. (2000). Heat-shock protein expression is absent in the Antarctic fish Trematomus bernacchii (Family Nototheniidae). J. Exp. Biol.203,2331-2339. (10.1242/jeb.203.15.2331)
  17. Kawall, H. G., Torres, J. J., Sidell, B. D. and Somero, G. N. (2002). Metabolic cold adaptation in Antarctic fishes:evidence from enzymatic activities of brain. Mar. Biol.140,279-286.
  18. Le Morvan, C., Clerton, P., Deschaux, P. and Troutaud, D.(1997). Effects of environmental temperature on macrophage activities in carp. Fish Shellfish Immunol.7, 209-212. (10.1006/fsim.1996.0075)
  19. Le Morvan, C., Deschaux, P. and Troutaud, D.(1996). Effects and mechanisms of environmental temperature on carp (Cyprinus carpio) anti-DNP antibody response and nonspecific cytotoxic cell activity: a kinetic study. Dev. Comp. Immunol.20,331-340. (10.1016/S0145-305X(96)00027-4)
  20. Le Morvan, C., Troutaud, D. and Deschaux, P.(1995). Effects of temperature on carp leukocyte mitogen-induced proliferation and nonspecific cytotoxic activity. Dev. Comp. Immunol.19,87-95.
  21. Le Morvan, C., Troutaud, D. and Deschaux, P.(1998). Differential effects of temperature on specific and nonspecific immune defenses in fish. J. Exp. Biol.201,165-168. (10.1242/jeb.201.2.165)
  22. Page, L. M. and Burr, B. M. (1991). A Field Guide to Freshwater Fishes of North America North of Mexico. Boston: Houghton Mifflin.
  23. Radice, G. P. (1980a). The spreading of epithelial cells during wound closure in Xenopus larvae. Dev. Biol.76,26-46. (10.1016/0012-1606(80)90360-7)
  24. Radice, G. P. (1980b). Locomotion and cell-substratum contacts of Xenopus epidermal cells in vitro and in situ.J. Cell Sci.44,201-223. (10.1242/jcs.44.1.201)
  25. Ream, R. A. (2002). The temperature biology of vertebrate actins and the actin-based motility of fish keratoytes. PhD thesis, Stanford University, Palo Alto, CA,USA.
  26. Ream, R. A., Johns, G. C. and Somero, G. N.(2003). Base compositions of genes encoding alpha-actin and lactate dehydrogenase-A from differently adapted vertebrates show no temperature-adaptive variation in G + C content. Mol. Biol. Evol.20,105-110. (10.1093/molbev/msg008)
  27. Rijkers, G. T., Frederix-Wolters, E. M. H. and Van Muiswinkel,W. B. (1980). The immune system of cyprinid fish. Kinetics and temperature dependence of antibody-producing cells in carp (Cyprinus carpio). Immunology41, 91-97.
  28. Small, J. V., Herzog, M. and Anderson, K.(1995). Actin filament organization in the fish keratocyte lamellipodium. J. Cell Biol.129,1275-1286. (10.1083/jcb.129.5.1275)
  29. Somero, G. N. (1996). Biochemical mechanisms of cold adaptation and stenothermality in Antarctic fish. In Biology of Antarctic Fish (ed. G. di Prisco, B. Maresca and B. Tota), pp.232-247. Berlin: Springer-Verlag.
  30. Somero, G. N. and DeVries, A. L. (1967). Temperature tolerance of some Antarctic fishes. Science156,257-258. (10.1126/science.156.3772.257)
  31. Somero, G. N., Giese, A. C. and Wohlschlag, D. E.(1968). Cold adaptation of the Antarctic fish Trematomus bernacchii.Comp. Biochem. Physiol.26,223-233. (10.1016/0010-406X(68)90327-7)
  32. Theriot, J. A. and Mitchison, T. J. (1991). Actin microfilament dynamics in locomoting cells. Nature352,126-131. (10.1038/352126a0)
  33. Verlhac, V., Sage, M. and Deschaux, P. (1990). Cytotoxicity of carp (Cyprinus carpio) leucocytes induced against TNP-modified autologous spleen cells and influence of acclimatization temperature. Dev. Comp. Immunol.14,475-480. (10.1016/0145-305X(90)90040-L)
Dates
Type When
Created 21 years, 9 months ago (Nov. 10, 2003, 6:28 p.m.)
Deposited 1 year, 7 months ago (Jan. 11, 2024, 4:45 a.m.)
Indexed 1 month, 2 weeks ago (July 16, 2025, 8:07 a.m.)
Issued 21 years, 8 months ago (Dec. 15, 2003)
Published 21 years, 8 months ago (Dec. 15, 2003)
Published Print 21 years, 8 months ago (Dec. 15, 2003)
Funders 0

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@article{Ream_2003, title={Influences of thermal acclimation and acute temperature change on the motility of epithelial wound-healing cells (keratocytes) of tropical,temperate and Antarctic fish}, volume={206}, ISSN={0022-0949}, url={http://dx.doi.org/10.1242/jeb.00706}, DOI={10.1242/jeb.00706}, number={24}, journal={Journal of Experimental Biology}, publisher={The Company of Biologists}, author={Ream, Rachael A. and Theriot, Julie A. and Somero, George N.}, year={2003}, month=dec, pages={4539–4551} }