Asymptotic weight and maturing rate in mice selected for body conformation

Di Masso, Ricardo J.; Silva, Patricia S.; Font, María Teresa

doi:10.1590/S1415-47572000000200016

Abstracts

Growth patterns of four lines of mice selected for body conformation were analyzed with the logistic function, in order to provide baseline information about the relationship between asymptotic weight and maturing rate of body weight. Two lines were divergently selected favoring the phenotypic correlation between body weight and tail length (agonistic selection: CBi+, high body weight and long tail; CBi-, low body weight and short tail), whereas the other two lines were generated by a disruptive selection performed against the correlation between the aforementioned traits (antagonistic selection: CBi/C, high body weight and short tail; CBi/L, low body weight and long tail). The logistic parameters A (asymptotic weight) and k (maturing rate) behaved in CBi/C and CBi- mice and in CBi+ females as expected in terms of the negative genetic relationship between mature size and earliness of maturing. An altered growth pattern was found in CBi/L mice and in CBi+ males, because in the former genotype, selected for low body weight, the time taken to mature increased, whereas in the latter, selected for high body weight, there was a non-significant increase in the same trait. In accordance with the selective criterion, different sources of genetic variation for body weight could be exploited: one inversely associated with earliness of maturing (agonistic selection), and the other independent of maturing rate (antagonistic selection), showing that genetic variation of A is partly independent of k.

Padrões de crescimento de 4 linhagens de camundongos selecionados para a conformação do corpo foram analisadas com a função logística, de modo a se obterem informações basais a respeito da relação entre o peso assintótico e a taxa de maturação do peso corporal. Duas linhagens foram selecionadas divergentemente, favorecendo a correlação fenotípica entre o peso corporal e o comprimento da cauda (seleção agonística: CBi+, peso corporal elevado e cauda longa; CBi-, peso corporal reduzido e cauda curta), enquanto que as outras duas linhagens foram geradas por uma seleção disruptiva feita contra a correlação entre os caracteres acima citados (seleção antagonística: CBi/C, peso corporal elevado e cauda curta; CBi/L, peso corporal reduzido e cauda longa). Os parâmetros logísticos A (peso assintótico) e k (taxa de maturação) comportaram-se em camundongos CBi/C e CBi- e em fêmeas CBi+ conforme esperado, em termos da relação genética negativa entre o tamanho maduro e a precocidade de maturação. Um padrão alterado de crescimento foi encontrado em camundongos CBi/L e em machos CBi+, porque no primeiro genótipo, selecionado para reduzido peso corporal, o tempo decorrido para a maturação aumentou, enquanto que no último, selecionado para elevado peso corporal, houve um aumento não significante no mesmo caráter. De acordo com o critério de seleção, fontes diferentes de variação genética para o peso corporal puderam ser exploradas: uma inversamente associada com precocidade de maturação (seleção agonística) e a outra independente da taxa de maturação (seleção antagonística), mostrando que a variação genética de A é parcialmente independente de k.

ASYMPTOTIC WEIGHT AND MATURING RATE IN MICE SELECTED FOR BODY CONFORMATION

Ricardo J. Di Masso, Patricia S. Silva and María Teresa Font

Departamento de Ciencias Fisiológicas, Instituto de Genética Experimental, Facultad de Ciencias Médicas, Consejo de Investigaciones, Universidad Nacional de Rosario, Santa Fe 3100, 2000 Rosario, Argentina. Send correspondence to M.T.F. E-mail: rjdimasso@ciudad.com.ar

ABSTRACT

Growth patterns of four lines of mice selected for body conformation were analyzed with the logistic function, in order to provide baseline information about the relationship between asymptotic weight and maturing rate of body weight. Two lines were divergently selected favoring the phenotypic correlation between body weight and tail length (agonistic selection: CBi+, high body weight and long tail; CBi-, low body weight and short tail), whereas the other two lines were generated by a disruptive selection performed against the correlation between the aforementioned traits (antagonistic selection: CBi/C, high body weight and short tail; CBi/L, low body weight and long tail). The logistic parameters A (asymptotic weight) and k (maturing rate) behaved in CBi/C and CBi- mice and in CBi+ females as expected in terms of the negative genetic relationship between mature size and earliness of maturing. An altered growth pattern was found in CBi/L mice and in CBi+ males, because in the former genotype, selected for low body weight, the time taken to mature increased, whereas in the latter, selected for high body weight, there was a non-significant increase in the same trait. In accordance with the selective criterion, different sources of genetic variation for body weight could be exploited: one inversely associated with earliness of maturing (agonistic selection), and the other independent of maturing rate (antagonistic selection), showing that genetic variation of A is partly independent of k.

INTRODUCTION

Growth can be studied from at least three interrelated perspectives: dimensional, compositional and functional (Reeds and Fiorotto, 1990). From the dimensional viewpoint, the term growth refers to an increase in some measure of size (height, length, weight) with age. These different types of size-age relationships are typically described by fitting experimental data to the appropriate mathematical model, frequently using nonlinear regression techniques. This approach condenses the numerical information included in the longitudinal data set into a few biologically interpretable parameters.

Among the different mathematical models available for fitting growth curves, perhaps the most extensively used in mice are the special cases of Richards function (Richards, 1959): logistic (Monteiro and Falconer, 1966), Gompertz (Laird and Howard, 1967) and von Bertalanffy (Gall and Kyle, 1968). Two of the three parameters yielded by these models, asymptotic size and maturing rate, have particular importance because of their usefulness in describing the shape of a growth curve (Fitzhugh, 1976).

In some situations of primary production, certain growth patterns may be more desirable than others (Tallis, 1968), and any particular advantageous pattern can generally be expressed in terms of the two aforementioned parameters. In meat animals for example, a profitable model should combine a rapid, early body weight gain and a small mature body size, as seen in beef cattle (Dickerson, 1976) and poultry (Grossman and Bohren, 1985).

The relevance of animal breeding research with laboratory mice to farm animals is nowadays widely accepted (Roberts, 1965; Malik, 1984). Although these mouse models cannot be expected to be exact models of similar phenomena in livestock, they can be valuable for studying the biochemical and physiological determinants of growth, leading to a better understanding of growth biology.

Artificial selection for growth rate or body weight in laboratory rodents has usually been effective in bringing about noticeable changes in mature weight. However, since the larger the mature size of a mammal, the longer it tends to take to mature (Taylor, 1965), comparisons of growth traits between animals of the same chronological age but of different mature sizes could result in misleading conclusions because of differences in physiological age.

We examined the growth pattern of four lines of mice artificially selected for different body conformations, and with different adult sizes. The relationship between asymptotic weight and maturing rate for body weight was studied in order to provide baseline information about their interaction and because of the relevance of these parameters for growth studies.

MATERIAL AND METHODS

Body conformation index

The mice used in this experiment (CBi+, CBi-, CBi/C and CBi/L) were selected for body conformation at 49 days of age (Di Masso et al., 1991a) by means of an index which combines body weight and tail length, two positively correlated traits (r_P = 0.56, r_G = 0.60) in the base population stock (CBi). This index was constructed as follows:

I = [(X_i - x) / S_X] ± [(Y_i - y) / S_Y]

where X_i and Y_i are the individual scores for body weight and tail length, respectively, x and y are the base population means, and S_X and S_Y are the phenotypic standard deviations of each character. Both terms of the index were either added or subtracted to differentiate between the two procedures applied. Two lines were divergently selected favoring the aforementioned phenotypic correlation (agonistic selection: CBi+, high body weight and long tail; CBi-, low body weight and short tail), whereas the other two were obtained by a disruptive selection performed against the correlation between body weight and tail length (antagonistic selection: CBi/C, high body weight and short tail; CBi/L, low body weight and long tail). Mice from CBi stock were used as controls. Since tail length was used as an estimator of skeletal length (Baker and Cockrem, 1970; Hetzel and Nicholas, 1986), the four selected lines presented different biomass per unit of skeleton weight ratios (Di Masso et al., 1991b, 1998), showing different body conformations. The agonistic selection generated two lines with different shapes, since CBi+ had increased body weight and tail length, whereas both traits decreased in CBi-. Genotypes from the antagonistic selection experiment showed different forms with increasing body weight and decreasing tail length in CBi/C, and decreasing body weight and increasing tail length in CBi/L. These genotypes also differ in the pattern of fat deposition (Trumper et al., 1989, Di Masso et al., 1992), in the humoral immune response to sheep red blood cells (Scharovsky et al., 1991) and in bone biomechanics (Di Masso et al., 1997).

Animals

Mice belonging to litters randomly standardized at one day of age, to yield eight pups with a 1:1 sex ratio, were weaned at three weeks of age, individually marked using ear notching and assigned, eight individuals of the same sex, to standard polypropylene cages (32 x 24 x 10 cm) with wood shavings for bedding. Animals (16 per genotype-sex subgroup) were housed contemporaneously in the same breeding room, kept at 23 ± 1ºC with alternate 12-h light/dark periods. Pelleted food (Aliper Lab. Chow) and water were provided ad libitum. Individual body weights were recorded to the nearest tenth of a gram, weekly from weaning to 17 weeks of age.

Curve fitting

A nonlinear estimation procedure (GraphPad Prism Software, Version 2.0) based on Marquardt's algorithm (Marquardt, 1963) was used to fit the experimental individual weight-age data with a reparameterized form of the logistic function (Dieulefait, 1932) W_(t) = A/{1 + exp[(k - t)/b]}, to estimate A and k, the asymptotic value of size as t®¥, interpreted as average size (weight) at maturity, and the maturing rate of the curve (i.e., the relative rate at which A is attained), respectively. In this particular reparameterized version, k is the age at the inflexion point and, since the logistic curve is symmetrical, it represents the time taken to reach 50% of the mature body weight (A).

Statistical analysis

Goodness of fit was evaluated by the coefficient of multiple determination (R²), and also judged by the significance of the tests performed to verify the random distribution of the residuals. For statistical analysis, asymptotic weight (A) and maturing rate for body weight (k) were treated as metric traits. Since in mice sexes almost always show quite different growth patterns (Timon and Eisen, 1969; Eisen, 1976; Koops et al., 1987; Kastelic et al., 1996), males and females were treated separately after demonstrating a nonsignificant genotype x sex interaction effect. Differences in asymptotic weight and maturing rate among genotypes within the selection procedure were assessed by one way analysis of variance (Sokal and Rohlf, 1969).

RESULTS

In both sexes, mice with positive selection for body weight (CBi/C and CBi+) were heavier than controls, whereas lines selected for low body weight (CBi/L and CBi-) were lighter than CBi (Table I). Although not shown, there was good agreement between actual weights and the theoretical points of the fitted curves (R²values ranged from 0.963 to 0.982 for the different data set). There were obvious differences in growth patterns between agonistic and antagonistic selection groups, the former showing a more symmetrical response with respect to the control line (Figure 1).

Thumbnail

When selection was made favoring the phenotypic correlation between body weight and tail length (agonistic selection), maturing rate for body weight was negatively associated with mature body weight (since k represents the abscissa of the inflexion point, a positive relation between A and k indicates a negative relationship between mature size and time taken to mature). Therefore, CBi+ mice were heavier and later maturing than CBi-, and control animals (CBi) had intermediate values (Figure 2). In contrast, this behavior was not evidenced when selection was performed against the phenotypic correlation between body weight and tail length (antagonistic selection). CBi/C mice were heavier and later maturing than controls; CBi/L males and females, although significantly lighter at maturity than the other two genotypes, had maturing rate values similar to CBi/C (Figure 3).

DISCUSSION

Changes in the shape of a growth curve are basically determined by the degree of genetic independence between its parameters (Fitzhugh, 1976). Several researchers have provided direct or indirect experimental evidence of the partially independent genetic control of mature weight and time taken to mature in different species. In mice, for example, Roberts (1965) observed that two lines positively selected for six-week body weight achieved the same asymptotic weight but at different ages, while Timon and Eisen (1969), as a general conclusion from a study of the heritabilities and genetic correlations among parameters of the Richards and logistic growth functions, argued that direct selection for a change in the shape of the growth curve would be at least moderately successful. In poultry, Ricard (1975) showed the feasibility of modifying the trajectory of the growth curve of chickens by selecting for antagonistic combinations of body weights at different ages. Brown et al. (1972) found different proportions of maturing rate to be independent of asymptotic weight in beef cattle.

The behavior of the logistic parameters observed in both sexes in CBi/C and CBi- mice, and in CBi+ females confirms the general positive relationship between asymptotic weight and time taken to mature described for comparisons within (Taylor, 1968) and between (Taylor, 1965) species. This behavior could be ascribed to the expected response to selection for body weight, as animals genetically heavier at maturity tend to take longer to mature and vice versa (Taylor and Fitzhugh, 1971). In contrast, this expected correlated response was not observed in CBi/L mice or CBi+ males. These animals showed an altered growth pattern resulting from a decrease in maturing rate in a genotype that had a lowered mature size (CBi/L) and a nonsignificant decrease of the same trait in a genotype (CBi+) that had increased asymptotic weight.

The results herein described show some similarities with those observed in mice selected for different combinations of body weights at two ages (lines H₁₀, L₅ R₁₀ and R₅ H₁₀; McCarthy and Doolittle, 1977), whose growth patterns were described by McCarthy and Bakker (1979). CBi+ males selected for high body weight at seven weeks had increased asymptotic weight without significantly altering the maturing rate as occurred in line H₁₀, selected for high body weight at 10 weeks. Line L₅ R₁₀, selected for low body weight at five weeks, without altering body weight at 10 weeks, showed the same response as CBi/L: a lower asymptotic weight and also, a lower maturing rate than controls; in contrast, line R₅ H₁₀, selected for high body weight at 10 weeks without altering body weight at five weeks, had increased its asymptotic weight and decreased maturing rate much like CBi/C mice did. From this evidence, an analogy between both selection experiments could be made. CBi/L mice selected for low body weight and long tail at 49 days of age showed diminished body weight at five weeks but maintained the length of the tail characteristic of a 10-week-old mouse. Conversely, CBi/C mice selected for high body weight and short tail at 49 days of age had increased body weight at 10 weeks but maintained a tail length appropriate for a five-week-old-mouse.

Fitzhugh (1976) proposed that artificial selection for the ratio between a late maturing trait like body weight and an early maturing trait, represented in this case by tail length, should decrease age of maturing and decrease mature size for both characters. In our experiment, animals were not selected by a ratio but by a linear index. This is similar to McCarthy's lines, but combines two traits with different earliness of maturing, and although the animals were not selected for the combination of traits at different ages, the use of two characters differing in maturing rate would parallel this situation. This criterion would permit exploitation of different sources of genetic variation for body weight, one inversely associated with earliness of maturing (agonistic selection), and the other independent of maturing rate (antagonistic selection). Recently, Archer et al. (1998) found a lack of significant responses in maturation rate, in spite of differences in mature size when correlated responses of rate of maturation in Angus cattle divergently selected for yearling growth rate were analyzed. They argued that their results contradicted the observation that higher mature weights were related to lower maturation rates within a breed, and concluded that such experimental evidence does not support the dogma that selection for high growth rate leads to later maturing individuals. Evidently both aforementioned sources of genetic variation for growth would also be evident in beef cattle.

Although the genetic correlation between mature weight and maturing rate was not estimated in the present study, its value would be low enough not to restrain a response that permits a modification of the growth trajectory. This response could, for example, be one of the desirable patterns associated with a more profitable productive strategy. In this sense, it appears that genetic variation in A is partially independent of k.

In general terms, growth defined by mathematical models has definite advantages over point evaluations confined to constant ages, constant time periods or constant weight periods, since this approach provides parameters that can describe lifetime growth biologically. Optimum mature size and strategies for improving the bioenergetic efficiency of body-weight growth in beef animals depend on an understanding of how to manipulate genetic and environmental factors to control average lifetime rates of growth and maturing independently of mature weight. The selected lines of mice used in this experiment could be a useful model for the study of the relationship between mature weight, maturing rate and different associated growth traits like feeding efficiency and body composition, since comparisons between genotypes with different mature weights and with similar (CBi/C, CBi/L) or different (CBi+, CBi-) maturing rates could be performed.

ACKNOWLEDGMENTS

The authors thank Mrs. Fabiana Severino for expert care and breeding of the mice.

RESUMO

Padrões de crescimento de 4 linhagens de camundongos selecionados para a conformação do corpo foram analisadas com a função logística, de modo a se obterem informações basais a respeito da relação entre o peso assintótico e a taxa de maturação do peso corporal. Duas linhagens foram selecionadas divergentemente, favorecendo a correlação fenotípica entre o peso corporal e o comprimento da cauda (seleção agonística: CBi+, peso corporal elevado e cauda longa; CBi-, peso corporal reduzido e cauda curta), enquanto que as outras duas linhagens foram geradas por uma seleção disruptiva feita contra a correlação entre os caracteres acima citados (seleção antagonística: CBi/C, peso corporal elevado e cauda curta; CBi/L, peso corporal reduzido e cauda longa). Os parâmetros logísticos A (peso assintótico) e k (taxa de maturação) comportaram-se em camundongos CBi/C e CBi- e em fêmeas CBi+ conforme esperado, em termos da relação genética negativa entre o tamanho maduro e a precocidade de maturação. Um padrão alterado de crescimento foi encontrado em camundongos CBi/L e em machos CBi+, porque no primeiro genótipo, selecionado para reduzido peso corporal, o tempo decorrido para a maturação aumentou, enquanto que no último, selecionado para elevado peso corporal, houve um aumento não significante no mesmo caráter. De acordo com o critério de seleção, fontes diferentes de variação genética para o peso corporal puderam ser exploradas: uma inversamente associada com precocidade de maturação (seleção agonística) e a outra independente da taxa de maturação (seleção antagonística), mostrando que a variação genética de A é parcialmente independente de k.

(Received October 14, 1999)

Archer, J.A., Herd, R.M., Arthur, P.F. and Parnell, P.F. (1998). Correlated responses in rate of maturation and mature size of cows and steers to divergent selection for yearling growth rate in Angus cattle. Livest. Prod. Sci. 54: 183-192.
Baker, R.L. and Cockrem, F.R.M. (1970). Selection for body weight in the mouse at three temperatures and the correlated response in tail length. Genetics 65: 505-523.
Brown, J.E., Brown, C.J. and Butts, W.T. (1972). A discussion of the aspects of weight, mature weight and rate of maturing in Hereford and Angus cattle. J. Anim. Sci. 34: 525-534.
Dickerson, G.E. (1976). The choice of selection objectives in meat producing animals. In: Meat Animals. Growth and Productivity (Lister, D., Rhodes, D.N., Fowler, V.R. and Fuller, M.F., eds.). Plenum Press, New York, pp. 449-462.
Dieulefait, C.E. (1932). La teoría de la población en relación con sus grupos sociales componentes. Congresso Internazionale per gli Studi sulla Popolazione. Istituto Poligrafico dell Stato, Roma, pp. 3-23.
Di Masso, R.J., Abdala, S., Sánchez, S.M. and Font, M.T. (1991a). Disruptive selection for body conformation in mice. Mendeliana 9: 79-92.
Di Masso, R.J., Celoria, G.C. and Font, M.T. (1991b). Morphometric traits and femoral histomorphometry in mice selected for body conformation. Bone and Miner. 15: 209-218.
Di Masso, R.J., Silva, P.S. and Font, M.T. (1992). The effect of sex on the pattern of fat deposition in mice selected for body conformation: Agonistic selection. Rev. Bras. Genet. 15: 65-72.
Di Masso, R.J., Font, M.T., Capozza, R., Detarsio, G., Sosa, F. and Ferretti, J.L. (1997). Long-bone biomechanics in mice selected for body conformation. Bone 20: 539-545.
Di Masso, R.J., Celoria, G.C. and Font, M.T. (1998). Morphometric skeletal traits, femoral measurements, and bone mineral deposition in mice with agonistic selection for body conformation. Bone 22: 539-543.
Eisen, E.J. (1976). Results of growth curve analyses in mice and rats. J. Anim. Sci. 42: 1008-1023.
Fitzhugh, H.A. (1976). Analysis of growth curves and strategies for altering their shape. J. Anim. Sci. 42: 1036-1051.
Gall, G.A.E. and Kyle, W.H. (1968). Growth of the laboratory mouse. Theor. Appl. Genet. 38: 304-308.
Grossman, M. and Bohren, B.B. (1985). Logistic growth curve of chickens: heritability of parameters. J. Hered. 76: 459-462.
Hetzel, D.J.S. and Nicholas, F.W. (1986). Growth, efficiency and body composition of mice selected for post-weaning weight gain on ad libitum or restricted feeding. Genet. Res. 48: 101-109.
Kastelic, M., Salehar, A., Drobnic, M. and Kovac, M. (1996). Mature size and maturing rate in RoC57BL/6 and RoNMRI lines of mice. J. Anim. Breed. Genet. 113: 545-551.
Koops, W.J., Grossman, M. and Michalska, E. (1987). Multiphasic growth curve analysis in mice. Growth 51: 372-382.
Laird, A.K. and Howard, A. (1967). Growth curves in inbred mice. Nature 213: 786-788.
Malik, R.C. (1984). Genetic and physiological aspects of growth, body composition and feed efficiency in mice. A review. J. Anim. Sci. 58: 577-590.
Marquardt, D.W. (1963). An algorithm for least-squares estimation of non linear parameters. J. Soc. Industr. Appl. Math. 11: 431-441.
McCarthy, J.C. and Bakker, H. (1979). The effects of selection for different combinations of weights at two ages on the growth curve of mice. Theor. Appl. Genet. 55: 57-64.
McCarthy, J.C. and Doolittle, D.P. (1977). Effects of selection for independent changes in two highly correlated body weight traits in mice. Genet. Res. 29: 133-145.
Monteiro, L.S. and Falconer, D.S. (1966). Compensatory growth and sexual maturity in mice. Anim. Prod. 8: 179-182.
Reeds, P.J. and Fiorotto, M.L. (1990). Growth in perspective. Proc. Nutr. Soc. 49: 411-420.
Ricard, F.H. (1975). A trial of selecting chickens on their growth curve pattern: Experimental design and first general results. Ann. Genet. Sel. Anim. 7: 427-443.
Richards, F.J. (1959). A flexible growth function for empirical use. J. Exp. Bot. 10: 290-300.
Roberts, R.C. (1965). Some contributions of the laboratory mouse to animal breeding research. Anim. Breed. Abstracts 33: 3-30.
Scharovsky, O.G., Celoria, G.C., Racca, A.L. and Font, M.T. (1991). Association between immune response and body conformation in the mouse (Mus musculus). Rev. Bras. Genet. 14: 373-380.
Sokal, R.R. and Rohlf, F.J. (1969). Biometry. W.H. Freeman, San Francisco.
Tallis, G.M. (1968). Selection for an optimum growth curve. Biometrics 24: 169-177.
Taylor, St.C.S. (1965). A relation between mature weight and time taken to mature in animals. Anim. Prod. 7: 203-220.
Taylor, St.C.S. (1968). Time taken to mature in relation to mature weight for sexes, strains and species of domesticated mammals and birds. Anim. Prod. 10: 157-169.
Taylor, St.C.S. and Fitzhugh, H.A. (1971). Genetic relationships between mature weight and time taken to mature within a breed. J. Anim. Sci. 33: 726-731.
Timon, V.M. and Eisen, E.J. (1969). Comparison of growth curves of mice selected and unselected for postweaning gain. Theor. Appl. Genet. 39: 345-351.
Trumper, L., Di Masso, R.J., Abdala, S. and Font, M.T. (1989). The effect of sex on the pattern of fat deposition in mice selected for body conformation. Rev. Bras. Genet. 12: 535-542.

Publication Dates

Publication in this collection
22 Sept 2000
Date of issue
June 2000

History

Received
14 Oct 1999

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] Archer, J.A., Herd, R.M., Arthur, P.F. and Parnell, P.F. (1998). Correlated responses in rate of maturation and mature size of cows and steers to divergent selection for yearling growth rate in Angus cattle. Livest. Prod. Sci. 54: 183-192.

[2] Baker, R.L. and Cockrem, F.R.M. (1970). Selection for body weight in the mouse at three temperatures and the correlated response in tail length. Genetics 65: 505-523.

[3] Brown, J.E., Brown, C.J. and Butts, W.T. (1972). A discussion of the aspects of weight, mature weight and rate of maturing in Hereford and Angus cattle. J. Anim. Sci. 34: 525-534.

[4] Dickerson, G.E. (1976). The choice of selection objectives in meat producing animals. In: Meat Animals. Growth and Productivity (Lister, D., Rhodes, D.N., Fowler, V.R. and Fuller, M.F., eds.). Plenum Press, New York, pp. 449-462.

[5] Dieulefait, C.E. (1932). La teoría de la población en relación con sus grupos sociales componentes. Congresso Internazionale per gli Studi sulla Popolazione. Istituto Poligrafico dell Stato, Roma, pp. 3-23.

[6] Di Masso, R.J., Abdala, S., Sánchez, S.M. and Font, M.T. (1991a). Disruptive selection for body conformation in mice. Mendeliana 9: 79-92.

[7] Di Masso, R.J., Celoria, G.C. and Font, M.T. (1991b). Morphometric traits and femoral histomorphometry in mice selected for body conformation. Bone and Miner. 15: 209-218.

[8] Di Masso, R.J., Silva, P.S. and Font, M.T. (1992). The effect of sex on the pattern of fat deposition in mice selected for body conformation: Agonistic selection. Rev. Bras. Genet. 15: 65-72.

[9] Di Masso, R.J., Font, M.T., Capozza, R., Detarsio, G., Sosa, F. and Ferretti, J.L. (1997). Long-bone biomechanics in mice selected for body conformation. Bone 20: 539-545.

[10] Di Masso, R.J., Celoria, G.C. and Font, M.T. (1998). Morphometric skeletal traits, femoral measurements, and bone mineral deposition in mice with agonistic selection for body conformation. Bone 22: 539-543.

[11] Eisen, E.J. (1976). Results of growth curve analyses in mice and rats. J. Anim. Sci. 42: 1008-1023.

[12] Fitzhugh, H.A. (1976). Analysis of growth curves and strategies for altering their shape. J. Anim. Sci. 42: 1036-1051.

[13] Gall, G.A.E. and Kyle, W.H. (1968). Growth of the laboratory mouse. Theor. Appl. Genet. 38: 304-308.

[14] Grossman, M. and Bohren, B.B. (1985). Logistic growth curve of chickens: heritability of parameters. J. Hered. 76: 459-462.

[15] Hetzel, D.J.S. and Nicholas, F.W. (1986). Growth, efficiency and body composition of mice selected for post-weaning weight gain on ad libitum or restricted feeding. Genet. Res. 48: 101-109.

[16] Kastelic, M., Salehar, A., Drobnic, M. and Kovac, M. (1996). Mature size and maturing rate in RoC57BL/6 and RoNMRI lines of mice. J. Anim. Breed. Genet. 113: 545-551.

[17] Koops, W.J., Grossman, M. and Michalska, E. (1987). Multiphasic growth curve analysis in mice. Growth 51: 372-382.

[18] Laird, A.K. and Howard, A. (1967). Growth curves in inbred mice. Nature 213: 786-788.

[19] Malik, R.C. (1984). Genetic and physiological aspects of growth, body composition and feed efficiency in mice. A review. J. Anim. Sci. 58: 577-590.

[20] Marquardt, D.W. (1963). An algorithm for least-squares estimation of non linear parameters. J. Soc. Industr. Appl. Math. 11: 431-441.

[21] McCarthy, J.C. and Bakker, H. (1979). The effects of selection for different combinations of weights at two ages on the growth curve of mice. Theor. Appl. Genet. 55: 57-64.

[22] McCarthy, J.C. and Doolittle, D.P. (1977). Effects of selection for independent changes in two highly correlated body weight traits in mice. Genet. Res. 29: 133-145.

[23] Monteiro, L.S. and Falconer, D.S. (1966). Compensatory growth and sexual maturity in mice. Anim. Prod. 8: 179-182.

[24] Reeds, P.J. and Fiorotto, M.L. (1990). Growth in perspective. Proc. Nutr. Soc. 49: 411-420.

[25] Ricard, F.H. (1975). A trial of selecting chickens on their growth curve pattern: Experimental design and first general results. Ann. Genet. Sel. Anim. 7: 427-443.

[26] Richards, F.J. (1959). A flexible growth function for empirical use. J. Exp. Bot. 10: 290-300.

[27] Roberts, R.C. (1965). Some contributions of the laboratory mouse to animal breeding research. Anim. Breed. Abstracts 33: 3-30.

[28] Scharovsky, O.G., Celoria, G.C., Racca, A.L. and Font, M.T. (1991). Association between immune response and body conformation in the mouse (Mus musculus). Rev. Bras. Genet. 14: 373-380.

[29] Sokal, R.R. and Rohlf, F.J. (1969). Biometry. W.H. Freeman, San Francisco.

[30] Tallis, G.M. (1968). Selection for an optimum growth curve. Biometrics 24: 169-177.

[31] Taylor, St.C.S. (1965). A relation between mature weight and time taken to mature in animals. Anim. Prod. 7: 203-220.

[32] Taylor, St.C.S. (1968). Time taken to mature in relation to mature weight for sexes, strains and species of domesticated mammals and birds. Anim. Prod. 10: 157-169.

[33] Taylor, St.C.S. and Fitzhugh, H.A. (1971). Genetic relationships between mature weight and time taken to mature within a breed. J. Anim. Sci. 33: 726-731.

[34] Timon, V.M. and Eisen, E.J. (1969). Comparison of growth curves of mice selected and unselected for postweaning gain. Theor. Appl. Genet. 39: 345-351.

[35] Trumper, L., Di Masso, R.J., Abdala, S. and Font, M.T. (1989). The effect of sex on the pattern of fat deposition in mice selected for body conformation. Rev. Bras. Genet. 12: 535-542.

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Asymptotic weight and maturing rate in mice selected for body conformation

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