Synopsis
The morphology of minnows Phoxinus phoxinus from two rivers at the south-east of England was analysed on mensural characters and qualitative traits (occurrence of appendages, pattern of pigmentation and scalation). Eight developmental intervals were identified from the qualitative traits, and bivariate and multivariate analysis revealed that allometric growth occurs occasionally during ontogeny, mainly in earlier developmental periods. Body shape is under the influence of rapid increase during development, mainly due to the quick growth in early developmental intervals. The exclusion of ‘general size’, remarkable in early developmental intervals, revealed several ‘shape’ characters that mainly determine minnow morphology by changing the mode of variability during development (e.g. caudal characters, maximum body height, belly length and ventral head length). The tail certainly undergoes the most consistent and most durable change, its characters being the most variable and the most discriminative for developmental periods from larvae to adults. The most prominent alteration in the overall shape development occurs at the transition from larva to juvenile, both regarding the number of characters involved into the change and their variability. This transition takes place at about 28 mm SL, which corresponds to a significant change in microhabitat use in both the rivers Lee and Frome, characterized by shifts by 0+ juveniles to significantly deeper waters than those occupied by larvae, with increased amounts of either submerged filamentous algae (Lee) or vegetation (Frome).
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References cited
Balon, E.K. 1990. Epigenesis of an epigeneticist: the development of some alternative concepts on the early ontogeny and evolution of fishes. Guelph Ichthyol. Rev. 1: 1–48.
Baton, E.K. 1999. Alternative ways to become a juvenile or a definitive phenotype (and on some persisting linguistic offenses). Env. Biol. Fish. 56: 17–38.
Cock, A.G. 1966. Genetical aspects of metrical growth and form in animals. Quat. Rev. Biol. 41: 131–190.
Copp, G.H. 1992. Comparative microhabitat use of cyprinid larvae and juveniles in a lotic floodplain channel. Env. Biol. Fish. 33: 181–193.
Copp, G.H. and T.A. Bennetts. 1996. Short-term effects of removing riparian and instream cover on barbel (Barbus barbus) and other fish populations in a stretch of English chalk stream. Folia Zool. 45: 283–288.
Copp, G.H. and P. Garner. 1995. Evaluating the microhabitat use of freshwater fish larvae and juveniles with point abundance sampling by electrofishing. Folia Zool. 44: 145–158.
Copp, G.H. and V. Kovâc. 1996. When do fish with indirect development become juveniles? Can. J. Fish. Aquat. Sci. 53: 746–752.
Economou, A.N., C. Daoulas and T. Psarras. 1991. Growth and morphological development of chub, Leuciscus cephalus (L.), during the first year of life. J. Fish Biol. 39: 393–408.
Garner, P. 1997a. Determination of length bias and calculation of minimum sample sizes required for length and density estimation when using point sampling by electrofishing. J. Fish Biol. 50: 95–106.
Garner, P. 1997b. Effects of variable discharge on the velocity use and shoaling behaviour of Phoxinus phoxinus. J. Fish Biol. 50: 1214–1220.
Garner, P. and S. Clough. 1996. Habitat use by adult dace (Leuciscus leuciscus ( L.)) in a side channel of the River Frome, England. Fish. Manag. Ecol. 3: 349–352.
Gozlan, R.E., G.H. Copp and J.-N. Tourenq. 1999. Comparison of growth plasticity in the laboratory and field, and implications for the onset of juvenile development in sofie, Chondrostoma toxostoma. Env. Biol. Fish. 56: 153–165.
Howes, G.J. 1985. A revised synonymy of the minnow genus Phoxinus Rafinesque, 1820 (Teleostei: Cyprinidae) with comments on its relationships and distribution. Bull. Br. Mus. Nat. Hist. ( Zool. ) 48: 57–74.
Ibbotson, A., P. Armitage, W. Beaumont, M. Ladle and S. Welton. 1994. Spatial and temporal distribution of fish in a small lowland stream. Fish. Manag. Ecol. 1: 145–156.
Joliceur, P. 1963. The multivariate generalisation of the allometry equation. Biometrics 19: 497–499.
Koblitskaya, A.F. 1981. Key for identifying young freshwater fishes. Light and Food Industrial Publ. House, Moscow (in Russian).
Kovd, V. and G.H. Copp. 1996. Ontogenetic patterns of relative growth in young roach Rutilus rutilus: within-river basin comparisons. Ecography 19: 153–161.
Kovâc, V., G.H. Copp and M.P. Francis. 1999. Morphometry of the stone loach, Barbatula barbatula: do mensural characters reflect the species’ life history thresholds? Env. Biol. Fish. 56: 105–115.
Kuo, J. 1994. Sigmaplot scientific graphing software. Transforms and curve fitting. Jandel Scientific, San Rafael.
Krupka, I. 1988. Early development of barbel [Barbus barbus (Linnaeus, 1758)]. Prâce ústavu Rybârstva a Hydrobiológie 6: 115–138.
Mastrorillo, S., F. Dauba and A. Beland. 1996. Microhabitat use by minnow, gudgeon and stone loach, in three rivers in Southwestern France. Ann. Limnol. 32: 185–195.
Mills, C.A. 1987. The life history of the minnow Phoxinus phox- inus (L.) in a productive stream. Freshwat. Biol. 17: 53–67.
Penâz, M. 1975. Diel lokomotorische Aktivitat larvaler and juveniler Elritzen (Phoxinus phoxinus). Zoologické Listy 24: 263–276.
Prokes, M. and M. Penâz. 1978. The course of spawning, early development and longitudinal growth of the nase carp, Chondrostoma nasus, in the Rokytnâ and Jihlava Rivers. Folia Zool. 27: 269–278.
Prokes, M. and M. Pebâz. 1979. Reproduction and early development of the gudgeon, Gobio gobio. II. Larval and juvenile period. Folia Zool. 28: 55–64.
Rohlf, F.J. 1988. NTSYS-pc: numerical taxonomy and multivariate analysis system. Version 1. 50. Exeter Publishing Ltd. and Applied Biostatistics Inc., New York.
Sagnes, P., P. Gaudin and B. Statzner. 1997. Shifts in morphometrics and their relation to hydrodynamic potential and habitat use during grayling ontogenesis. J. Fish Biol. 50: 846–858.
Sempeski, P. and P. Gaudin. 1995. Habitat selection by grayling (Thymallus thymallus). II. Preliminary results on larval and juvenile daytime habitats. J. Fish Biol. 47: 345–349.
Sneath, P.H. and R.R. Sokal. 1973. Numerical taxonomy. W.H. Freeman and Co., San Francisco. 573 pp.
Sokal, R.R. and F.J. Rohlf. 1981. Biometry. W.H. Freeman and Co., San Francisco. 776 pp.
Zar, J.H. 1984. Biostatistical analysis. Prentice Hall Inc., Englewood Clifts. 375 pp.
Watkins, M.S., S. Doherty and G.H. Copp 1997. Microhabitat use by 0+ and older fishes in a small English chalk stream. J. Fish Biol. 50: 1010–1024.
Webb, P.W. and P. Weihs. 1986. Functional locomotor morphology of early life history of fish. Trans. Amer. Fish. Soc. 115: 115–127.
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Simonović, P.D., Garner, P., Eastwood, E.A., Kováč, V., Copp, G.H. (1998). Correspondence between ontogenetic shifts in morphology and habitat use in minnow Phoxinus phoxinus . In: Copp, G.H., Kováč, V., Hensel, K. (eds) When do fishes become juveniles?. Developments in environmental biology of fishes, vol 19. Springer, Dordrecht. https://doi.org/10.1007/978-94-017-3678-7_9
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DOI: https://doi.org/10.1007/978-94-017-3678-7_9
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