Oklahoma State University
Stillwater 74078
Birth,
weaning, feedlot and carcass traits were evaluated on 1,181 calves sired by
Charolais and Limousin bulls out of eight crossbred dam groups (Hereford X
Angus, Angus X Hereford, Simmental X Angus, Simmental X Hereford, Brown Swiss X
Angus, Brown Swiss X Hereford, Jersey x Angus, Jersey X Hereford). Calves were
born in the spring over a 4-yr period during which dams ranged from 3 to 8 yr
of age. Charolais-cross calves were 2.7 kg heavier (P
(Key Words: Cattle, Charolais, Limousin, Crossbreeding, Terminal Sires.)
Mating
crossbred dams to sires of a third breed allows maximum utilization of
heterotic effects and complementary breed differences. Computer simulations
comparing beef cattle crossbreeding systems have indicated that breeding programs
that include matings to terminal sires with a high breeding value for growth
rate can maximize production efficiency (Cartwright et al., 1975; Fitzhugh et
al., 1975; Morris and Wilton, 1976; Wilton and Morris, 1976; Notter et al.,
1979; Clarke et al., 1984). The Limousin and Charolais breeds were among those
used and suggested as terminal sire breeds (Turton, 1964; Smith, 1976; Vissac,
1976; Frahm and Belcher, 1978). Charolais-sired crossbred progeny have been
characterized as heavier at birth, their dams experience more dystocia and calf
mortality is greater than for Limousin-sired calves out of similar dams (Pattie
and Menissier, 1976; Smith et al., 1976b; Vissac, 1976; Anderson et al., 1977b;
Freeden et al., 1982a). Charolais-sired crossbred calves have also been
reported to be heavier at weaning and they gain more rapidly postweaning and
are heavier at slaughter than those sired by Limousin bulls (Bonelli and Poly,
1964; Bergstrom, 1966; Reichen, 1966; Frebling et al., 1967; Adams et al.,
1973; Smith et al., 1976a; Vissac, 1976; Anderson et al., 1977a; Freeden et
al., 1982b). Reported differences between Charolais and Limousin crosses for
carcass characteristics (Frebling et al., 1967; Bergstrom, 1966; Reichen, 1966;
Koch et al., 1976; Anderson et al., 1977a) and feed efficiency (Smith et al.,
1976a) have been small. Dependent on economic conditions, the superior growth
rate, feed efficiency and carcass merit of cattle sired by very large terminal
breeds can offset greater costs per calf weaned associated with increased
calving difficulty (Smith, 1976). The objective of this study was to compare
the birth to slaughter performance and carcass characteristics of crossbred
progeny produced by mating Limousin and Charolais sires to various crossbred
dam groups.
Data
used in this study were collected from 1978 through 1982 as part of an
extensive experiment in progress at the Oklahoma Agricultural Experiment
Station to evaluate lifetime productivity of various two-breed cross cows when
mated to sires of a third breed. The crossbred dams involved in this study were
produced in 1973, 1974 and 1975 by making appropriate matings of Angus,
Hereford, Simmental, Brown Swiss and Jersey bulls to Angus and Hereford cows.
The cow herd has been described in detail by Belcher and Frahm (1979).
Experimental Design. Purebred Charolais and Limousin bulls were mated to eight two-breed cross cow groups (Hereford x Angus, Angus x Hereford, Simmental x Angus, Simmental x Hereford, Brown Swiss x Angus, Brown Swiss x Hereford, Jersey x Angus, Jersey x Hereford) to produce a total of 589 steer and 592 heifer calves in the spring of 1978, 1979, 1980 and 1981. Cows were 3 to 5 yr old in 1978, 4 to 6 yr old in 1979, 5 to 7 yr old in 1980 and 6 to 8 yr old in 1981 at the time of calving. A different set of eight Limousin sires was used each year for a total of 32 Limousin sires. Eight Charolais sires were used each year; however, some were used for two or three breeding seasons. Consequently, there were only 19 different Charolais sires (table 1). Limousin sires were selected by the North American Limousin Foundation and used through artificial insemination, with semen furnished by owners of the bulls, to produce 541 Limousin-cross calves. The Limousin bulls used were representative of the more popular bulls in the breed and each year a reference sire was included. Seventeen of the Charolais sires were purchased from Oklahoma breeders and selected on the basis of growth performance. The remaining two Charolais sires were from out-of-state and were also quite popular. Semen from these two bulls was used to produce 61 of the 640 Charolais-cross calves. Cows were randomly allotted to sires within crossbred type and age. The number of calves sired by a particular sire in a given year ranged from 8 to 24.
Management and Data Collection. With the exception of 35 calves produced in 1978 that were reared in drylot to weaning, calves were reared by their dams on native and bermudagrass pasture at the Lake Carl Blackwell Research Range west of Stillwater. Calves were born primarily during February and March. All calves were weighed within 24 h of birth and assigned a calving difficulty score on a scale from 1 (no difficulty) to 5 (Caesarean birth). Calving difficulty scores of 3, 4 and 5 were considered a difficult calving that required assistance from the herdsman. Calves were dehorned and castrated before 1 mo of age. At an average age of 205 d, calves were weaned, weighed and assigned a condition and a conformation score by a panel of at least three persons. Conformation score was primarily a visual appraisal of the degree of muscling.
After weaning, all calves were trucked to the Southwestern Livestock and Forage Research Station, El Reno, Oklahoma, and placed in the feedlot the following day. Steers and heifers were placed in separate feeding barns, each consisting of 14 11.0 X 14.3 m concrete-floor pens with 6.4 m of each pen covered with an open-sided pole barn that faced south. All calves of a specific three-breed cross of the same sex were fed together in a pen assigned at random. Cattle were fed ad libitum the finishing diet presented in table 2. Feed was weighed as it was dispensed in the feeders and, after all animals had been removed from the feeding study, residual feed was reweighed. All calves received implants (Synovex-H for heifers and Synovex-S for steers) when they entered the feedlot. A random half of the calves in each pen was reimplanted after approximately 120 d in 1979 and 1980. All calves were reimplanted in 1981. Cattle were weighed approximately every 30 d until the first animals were removed for slaughter. Adjusted yearling weights were calculated using weights obtained with cattle averaged 1 yr of age. At this time the cattle were also scored for body conformation. Cattle were weighed at 2-wk intervals during the slaughter phase. Each animal was sent to slaughter when an estimated carcass grade of low Choice was attained. A shrunk weight was obtained before shipment.
Cattle were transported to a commercial slaughter plant and slaughtered on the day of arrival, or the following day. Carcass data were obtained after a minimum of a 48-h chill. Carcasses were evaluated for quality grade, conformation, maturity, marbling, color and percentage kidney, heart and pelvic fat (KHP fat) by Oklahoma State University meat science faculty. Longissimus muscle area and external fat thickness were measured at the 12th rib. Dressing percentage was calculated by adjusting cold carcass weight to warm carcass weight and dividing by live shrunk weight at slaughter. Cutability was estimated by the USDA cutability equation (USDA, 1981).
Statistical Analysis. All traits except feed efficiency were analyzed by least-squares, mixed model procedures (Harvey, 1977, 1982). The model for all traits analyzed by mixed model procedures included the fixed effects of sire breed, crossbred dam group, dam age, calf sex and all two-factor interactions. Based on preliminary analyses, three-factor interactions were assumed nonsignificant. Birth date was included as a covariate in the analysis of all traits, and marbling score was included as an additional covariate in the analyses of all carcass traits except marbling score. Random effects included in the model were years nested within sire breed and sires nested within year and sire breed. It would have been more descriptive of the design to consider sire breed and years as cross-classified effects with sires nested in their interaction. However, programming limitations prevented nesting within an interaction. Nonetheless, the model is appropriate because years within sire breed adjusts for year main effects and sire breed x year interaction effects (Smith et al., 1976b). Preliminary analyses with a model in which years were treated as a fixed effect and sire effects omitted indicated that two-way interactions between year and other fixed effects were not important. Significant sources of variation were determined from the analysis of each trait using full mixed models. The mean square for sires within year and sire breed was used to test sire breed and years nested within sire breed. The residual mean square was used to test all other effects. Least-squares means were calculated from reduced models in which nonsignificant sources of variation were eliminated.
Feed efficiency was measured on a pen basis and was analyzed by a fixed effects model that included the effects of sire breed, crossbred dam group, calf sex and all two-way interactions. The three-way interaction was assumed to be nonsignificant. The residual mean square was used to test the statistical significance of all effects. Least-squares means were calculated from a reduced model in which nonsignificant effects were omitted.
Birth
and Weaning Traits.
Breed of sire least-squares means for birth and weaning traits are presented in
table 3. Charolais-sired calves were 2.7 kg heavier at birth than
Limousin-sired calves and their dams experienced more dystocia. Charolais-sired
calves had a 9.9% higher incidence of calvings requiring assistance and a
higher mean calving difficulty score (1.42 vs 1.13) than did Limousin-sired
calves. Charolais-cross calves had 4.6% more preweaning death loss than did
Limousin-cross calves. The higher mortality of Charolais-cross calves is likely
associated with their increased calving difficulty. Because cows were closely
observed during the calving period, the difference in preweaning death loss of
calves sired by these two breeds may be even larger in herds that are not
managed so intensively.
Due to their 2.7 kg heavier birth weight and 31 g/d more rapid preweaning rate of gain, Charolais-sired calves were 9.0 kg heavier (P<.0l) at weaning. Charolais-sired calves received higher condition scores (5.2 vs 5.0, P><.0l) at weaning than did Limousin-sired calves. Weaning conformation scores were the same and quite acceptable for calves from both sire breeds.>
Feedlot Traits. Breed of sire least-squares means for feedlot traits are presented in table 4. Initial feedlot weight of Charolais-cross calves was 9 kg heavier than that of Limousin-cross calves. The superior preweaning rate of gain exhibited by Charolais-cross calves persisted after weaning and resulted in a 19.2-kg advantage in yearling weight over Limousin-cross calves. Charolais crosses also had a slight advantage in muscle development as indicated by a higher conformation score. There was a sire breed X sex of calf interaction (P<.0l) for yearling weight. The difference in yearling weight between steer and heifer calves was 46.8 kg for Limousin sires compared with 41.3 kg for Charolais sires (table 5).>
For the total feedlot period, Charolais-sired calves outgained Limousin-sired calves by 60 g/d and were in the feedlot on the average 6.8 fewer days. However, there was a sire breed X crossbred dam group interaction (P<.10) for days in the feedlot. The sire breed X crossbred cow group means (table 6) indicate that this interaction resulted from a combination of reversal in ranking between sire breeds when mated to Simmental X Hereford and Brown Swiss X Hereford cows (Charolais-cross calves averaged 3 d longer in the feedlot) and an increased magnitude of difference between Limousin- and Charolais-cross calves from Jersey cross cows (Limousin-cross calves averaged 18 d longer in the feedlot).>
On the average, feed efficiency was similar for calves sired by both sire breeds (7.88 vs 7.83 kg feed/kg gain for Charolais and Limousin, respectively); however, there was a sire breed X year interaction (P<.0l). Feed efficiency was similar for the two sire breeds in 1979 and 1980. However, Limousin-sired calves were more efficient in 1978 (7.76 ± .10 vs 7.35 ± .10 kg/kg for Charolais and Limousin), whereas Charolais-sired calves were more efficient in 1981 (7.84 ± .10 vs 8.09 ± .10 kg/kg for Charolais and Limousin). The reversal in sire breed rank between 1978 and 1981 may have occurred because a different sample of sires from the two breeds was used each year.>
Although Charolais-cross calves were in the feedlot fewer days, their advantage in growth rate was sufficient to result in 17.3 kg heavier slaughter weight on a grade-constant basis.
Carcass Traits. Least-squares means by sire breed for carcass traits are presented in table 7. With the exception of marbling score, least-squares means for carcass traits were adjusted to the average marbling score of 4.91 by linear regression. This is slightly below the equivalent of a marbling score of small, the minimal requirement for the USDA low Choice carcass quality grade. The adjustment to the average marbling score was minor because the actual average marbling scores were very similar for the two sire breeds (4.93 vs 4.89 for Charolais and Limousin).
Charolais-sired cattle had a .7% lower dressing percentage than did Limousin-sired cattle, but because they were heavier at slaughter, they yielded carcasses that were 7 kg heavier. Charolais crosses produced 22 g more carcass weight per day of age than did Limousin crosses, reflecting the superior growth rate of Charolais-cross calves. Charolais crosses had slightly less internal fat (2.99 vs 3.11% KHP fat) and external fat at the 12th rib (1.57 vs 1.67 cm) than did Limousin crosses at a constant amount of marbling. Carcass grade was not significantly different between Charolais and Limousin-sired calves at a constant amount of marbling, as would be expected, because carcass quality grade is determined primarily by marbling. In fact, the average actual carcass grades were very similar because the cattle were slaughtered at an anticipated carcass grade of low Choice. Longissimus muscle area and curability were not significantly different between sire breeds; however, there was a sire breed X sex of calf interaction (P<.0l). The difference in longissimus muscle area between steers and heifers was zero for Charolais sires and 3.1 cm 2 for Limousin sires (table 5). Heifers had a higher curability than steers for both sire breeds; however, the advantage was larger for Charolais-sired calves (.7 vs .3%; table 5).>
Although
mated to a diverse group of crossbred cows, both sire breeds produced calves
that were uniform in appearance with quite acceptable conformation, performance
and carcass desirability. The economic advantage associated with less calving
difficulty and greater calf survival of Limousin crosses would be at least
partially offset by the greater growth rate of Charolais crosses. The relative
economic advantage of lighter birth weights associated with the use of Limousin
sires would be greatest when mated to immature or smaller cows for which the
risk of calving difficulty is expected to be higher. These data suggest both
breeds have merit as sire breeds in terminal crossbreeding systems. The
selection of available bulls within the Limousin and Charolais breeds and their
relative cost may be as important as the choice of sire breed.
Adams,
N. J., W. N. Garrett and J. T. Elings. 1973. Performance and carcass characteristics
of crosses from imported breeds. J. Anim. Sci. 37:1.
Anderson, B. B., T. Liboriussen K. Kousgaard and L. Buchter. 1977a. Crossbreeding experiment with beef and dual- purpose sire breeds on Danish dairy cows. III. Daily gain, feed conversion and carcass quality of intensively fed young bulls. Livestock Prod. Sci. 4:19.
Anderson, B. B., T. Liboriussen, I. Thyson, K. Kousgaard and L. Buchte. 1977b. Crossbreeding experiment with beef and dual-purpose sire breeds on Danish dairy cows. Livestock Prod. Sci. 3:227.
Belcher, C. G. and R. R. Frahm. 1979. Productivity of two-year-old crossbred cows producing three-breed cross calves. J. Anim. Sci. 49:1195.
Bergstrom. 1966. Fattening experiments with crossbred calves from FH cows and Charolais, Limousin and MRY bulls. Rapp. Inst. Veeteeltk. Onderz. No. B83:23.
Bonelli, P. and J. Poly. 1964. Incrocio industriale nella produzione di vitellone. Progresso. Agr. (Bologna) 10:189.
Cartwright, T. C., H. A. Fitzhugh and C. R. Long. 1975. Systems analysis of sources of genetic and environmental variation in efficiency of beef production: Mating plans. J. Anim. Sci. 40:433.
Clarke, S. E., C. T. Gaskins, J. K. Hillers and W. D. Hohenboken. 1984. Mathematical modeling of alternative culling and crossbreeding strategies in beef production. J. Anim. Sci. 58:6.
Fitzhugh, H. A., C. R. Long and T. C. Cartwright. 1975. Systems analysis of sources of genetic and environmental variation in efficiency of beef production: Heterosis and complementarity. J. Anim. Sci. 40:421.
Frahm, R. R. and D. R. Belcher. 1978. An evaluation of Limousin Cattle. Oklahoma State Univ. Bull. B-736.
Frebling, J., B. Poujardieu, B. Vissac, C. Beranger, J. H. Teissier and M. Rondeau. 1967. Stations de selection bovine. Complete rendu technique No. 2. Etude du croisement sur la race d'Aubrac. Bull. Tech. Inf. No. 225:895.
Freeden, H. T., G. W. Weiss, J. E. Lawson, J. A. Newman and G. W. Rahnfeld. 1982a. Environmental and genetic effects on preweaning performance of calves from first cross cows, I. Calving ease and preweaning mortality. Can. J. Anim. Sci. 62:35.
Freeden,H. T., G. M. Weiss, G. W. Rahnefeld, J. E. Lawson and J. A. Newman. 1982b. Environmental and genetic effects on preweaning performance of calves from first cross cows. II. Growth traits. Can. J. Anim. Sci. 62:51.
Harvey, W. R. 1977. User's guide for LSML76, mixed model least-squares and maximum likelihood computer program (Mimeo). Ohio State Univ., Wooster.
Harvey, W. R. 1982. Mixed model capabilities of LSML76. J. Anim. Sci. 54:1279.
Koch, R. M., M. E. Dikeman, D. M. Allen, M. May, J. D. Crouse and D. R. Campion. 1976. Characterization of biological types of cattle. III. Carcass composition, quality and palatability. J. Anim. Sci. 43:48.
Morris, C. A. and J. W. Wilton. 1976. Integrated beef production models for crossbreeding studies: Comparison of different management programs. Can. J. Anim. Sci. 56:475.
Notter, D. R., J. O. Sander, G. E. Dickerson, G. M. Smith and T. C. Cartwright. 1979. Simulated efficiency of beef production for a cow-calf-feedlot management system. III. Crossbreeding systems. J. Anim. Sci. 49:92.
Pattie, W. A. and F. Menissier. 1976. Calving difficulties among pure-bred Charolais, Limousin, Maine-Anjou and Hereford cattle in France. Australian Anim. Prod. 21:357.
Reichen, F. 1966. Production de viande de boeuf par croisement industriel. Agr. Romande Ser. A. 5:73.
Smith, G. M. 1976. Sire breed effects on economic efficiency of a terminal-cross beef production system. J. Anim. Sci. 43:1163.
Smith, G. M., D. B. Laster, L. V. Cundiff and K. E. Gregory. 1976a. Characterization of biological types of cattle. II. Postweaning growth and feed efficiency of steers. J. Anim. Sci. 43:37.
Smith, G, M., D. B. Laster and K. E. Gregory 1976b. Characterization of biological types of cattle. I. Dystocia and preweaning growth. J. Anim. Sci. 43:27.
Turton, J. D. 1964. The Charolais and its use in crossbreeding. Anim. Breed. Abstr. 32:119.
USDA. 1981. Guidelines for uniform beef improvement programs. Ext. Service Prog. Aid 1020.
Vissac, B. 1976. Using large muscular breeds to improve world beef production. World Anim. Rev. 19:1.
Wilton, J. W, and C. A. Morris. 1976. Effects of reproductive performance and mating system on farm gross margins in beef production. Can. J. Anim. Sci. 56:171.
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TABLE
1. NUMBER OF SIRES BY YEAR |
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Number of sires |
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|
Sire
breed |
1978 |
1979 |
1980 |
1981 |
Total |
|
|
|||||
|
Charolais |
8 |
8 (3) |
8 (4) |
8 (6) |
19 |
|
Limousin |
8 |
8 (0) |
8 (0) |
8 (0) |
32 |
|
|
|||||
a |
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TABLE
2. FINISHING DIET
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|
|
Ingredient |
Percentage |
|
|
|
|
Corn
(IFN 4-02-931) |
78 |
|
Alfalfa
(IFN 1-00-063) |
8 |
|
Cottonseed
hulls (IFN 1-01-599) |
4 |
|
Molasses
(IFN 4-00-668) |
5 |
|
Supplemental
pellets |
5 |
|
Total |
100 |
|
|
|
a |
|
|
TABLE
3. LEAST-SQUARES MEANS AND STANDARD ERRORS FOR BIRTH AND WEANING TRAITS |
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|
Sire breed |
Difference |
||
|
Trait |
Charolais (C) |
Limousin (L) |
(C-L) |
|
|
|||
|
Birth
wt, kg |
38.5 ± .4 |
35.8 ± .4 |
2.7** |
|
Difficult
calvings, % |
13.8 ± 1.5 |
3.9 ± 1.5 |
9.9** |
|
Dystocia
score |
1.42 ± .05 |
1.13 ± .05 |
.29** |
|
Preweaning
mortality, % |
9.3 ± 1.3 |
4.7 ± 1.4 |
4.6* |
|
Preweaning
avg daily gain, g/d |
940 ± 13 |
909 ± 11 |
31** |
|
Weaning
wt, kg |
231.2 ± 1.3 |
222.2 ± |
9.0** |
|
Weaning
conformation |
13.6 ± .04 |
13.6 ± .04 |
0 |
|
Weaning
condition |
5.2 ± .02 |
5.0 ± .02 |
.2** |
|
|
|||
|
a
Calving difficulty: 1 = no difficulty, 2 = little difficulty, 3 = moderate
difficulty, 4 = major difficulty and 5 = caesarian. |
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TABLE
4. LEAST-SQUARES MEANS AND STANDARD ERRORS FOR FEEDLOT TRAITS |
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|
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|
Sire breed |
Difference |
||
|
Trait |
Charolais (C) |
Limousin (L) |
(C-L) |
|
|
|||
|
Initial
feedlot wt, kg |
231.2 ± 1.2 |
222.2 ± 1.2 |
9.0** |
|
Yearling
wt, kg |
428.0 ± 2.6 |
208.8 ± 2.6 |
19.2 ** |
|
Yearling
confonnation |
13.5 ± .03 |
13.2 ± .03 |
.3** |
|
Days
on feed |
260.0 ± .98 |
266.8 ± 1 |
-6.8* |
|
Feedlot
avg daily gain, g/d |
1119 ± 11 |
1059 ± 11 |
60** |
|
Feed
efficiency, kg feed/kg gain |
7.88 ± .05 |
7.83 ± .05 |
.05 |
|
Slaughter
wt, kg |
520.0 ± 2.3 |
502.7 ± 2.4 |
17.3** |
|
|
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|
a
Conformation scores: 13 = average Choice and 14 = high choice. |
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TABLE 5. LEAST-SQUARES
MEANS AND STANDARD ERRORS BY SUBCLASS MEANS |
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Trait |
||||
|
Sire
breed |
Sex
of calf |
Yearling |
M. longissimus |
Cutability, % |
|
|
||||
|
Charolais |
Steer |
449.5 ± 9.4 |
84.5 ± 1.29 |
50.0 ± .3 |
|
Heifer |
408.2 ± 9.4 |
84.5 ± 1.29 |
50.7 ±.3 |
|
|
Limousin |
Steer |
432.3 ± 9.5 |
86.3 ± 1.29 |
50.0 ± .3 |
|
Heifer |
385.5 ± 9.4 |
83.2 ± 1.29 |
50.3 ± .3 |
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TABLE 6. LEAST-SQUARES
MEANS AND STANDARD ERRORS BY SIRE BREED AND CROSSBRED COW GROUP FOR DAYS ON
FEED |
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Crossbred |
Sire breed |
|
|
cow
group |
Charolais |
Limousin |
|
|
||
|
Hereford
X Angus |
268 ± 12.2 |
274 ± 12.4 |
|
Angus
X Hereford |
252 ± 12.5 |
262 ± 12.8 |
|
Simmental
X Angus |
270 ± 11.3 |
273 ± 11.1 |
|
Simmental
X Hereford |
279 ± 12.6 |
275 ± 13.2 |
|
Brown
Swiss X Angus |
263 ± 11.9 |
268 ± 12.4 |
|
Brown
Swiss X Hereford |
265 ± 12.3 |
263 ± 12.9 |
|
Jersey
X Angus |
242 ± 11.2 |
259 ± 10.7 |
|
Jersey
X Hereford |
242 ± 11.2 |
261 ± 10.4 |
|
|
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TABLE
7. LEAST-SQUARES MEANS AND STANDARD ERRORS FOR CARCASS TRAITS |
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|
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|
Sire breed |
Difference |
||
|
Trait |
Charolais (C) |
Limousin (L) |
(C-L) |
|
|
|||
|
Carcass
wt, kg |
332.1 ± 1.7 |
325.1 ± 1.8 |
7.0* |
|
Carcass
wt/day of age, g |
714 ± 5 |
692 ± 5 |
22** |
|
Dressing
percentage |
63.9 ± .13 |
64.6 ± .14 |
-.7** |
|
Single
fat thickness, cm |
1.11 ± .03 |
1.24 ± .03 |
-.13** |
|
Avg
fat thickness, cm |
1.57 ± .03 |
1.67 ± .04 |
-.10* |
|
Kidney,
heart and pelvic |
2.99 ± .04 |
3.11 ± .04 |
.12* |
|
M.
longissimus area, cm² |
84.7 ± .75 |
84.8 ± .79 |
-.04 |
|
Cutability,
% |
50.37 ± .10 |
50.15 ± .10 |
.22 |
|
Marbling
score |
4.93 ± .06 |
4.89 ± .06 |
.04 |
|
Carcass
grade |
9.78 ± .002 |
9.76 ± .002 |
.02 |
|
|
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|
a
Marbling score: 4 = slight and 5 = small. |
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