Nutritional and productive performance of purebred Nellore heifers and crossed with Brangus and Braford ﬁnished in a feedlot system

BENTO, FELIPE C.; MORAES, KAMILA A.K. DE; ARAUJO, CLÁUDIO VIEIRA DE; MACHADO, VINÍCIUS AUGUSTO; CECCONELLO, NATAN L.; CUNHA, LORRAYNE O. DA; SOUSA, JARLIANE DO NASCIMENTO; NAVES, KARINE R. DOS SANTOS; ORTELAM, JULIANA C.; MORENO, LEANDRO F.; MORAES, EDUARDO HENRIQUE B.K. DE

doi:10.1590/0001-3765202420230826

Abstract

This study evaluated the nutritional and productive performance of Nellore purebred heifers and crossbred Brangus x Nellore (BGNE) and Braford x Nellore (BFNE) in a feedlot system. Thirty heifers (10 of each genetic group) with an average age of 18 months and an initial body weight of 261 kg were used. The experiment was structured and conducted according to a completely randomized design, with three treatments. Heifers received two diets (60 days each) during the experimental period. The experiment lasted 120 days with four experimental periods. Nellore heifers had a lower intake than crossbred heifers (P <0.05). There were no differences between BGNE and BFNE heifers, which had higher final body weight, average daily gain, feed efficiency, hot carcass weight and carcass length than NE heifers. Crossed heifers presented better fat cover than NE heifers. However, NE heifers had higher carcass dressing Despite presenting lower carcass yields than Nellore heifers, crossed heifers are more efficient and have higher performance and better fat cover on the carcass than purebred Nellore heifers. Crossbreeding synthetic breeds, such as Brangus and Braford breeds, with the Nellore breed is an effective way to increase the productivity and efficiency of feedlot heifers in tropical regions.

Key words
Bos taurus indicus; Bos taurus taurus; carcass; feed efficiency; intake

INTRODUCTION

Bos indicus presents high representativeness in the global cattle herd, since more than half of the cattle in the world are raised in tropical environments (Cundiff et al. 2012CUNDIFF LV, THALLMAN RM & KUEHN LA. 2012. Impact of Bos indicus Genetics on the Global Beef Industry. In: Beef Improvement Federation. Proc. 44th Annual Research Symposium and Annual Meeting. Houston, TX. p. 31.) and the Nellore (NE - Bos indicus) represents 80% of the Brazilian herd (Oliveira & Millen 2014OLIVEIRA CA & MILLEN DD. 2014. Survey of the nutritional recommendations and management practices adopted by feedlot cattle nutritionists in Brazil. Anim Feed Sci Technol 197: 64-75.). The use of crossbred animals has been an alternative to increase animal performance and reduce the feedlot period, and the NE breed also plays a key role in providing heterosis (Amaral et al. 2018AMARAL PM, MARIZ LDS, ZANETTI D, PRADOS LF, MARCONDES MI, santos AS, DETMANN E, FACIOLA AP & VALADARES FILHO SC. 2018. Effect of dietary protein content on performance, feed efficiency and carcass traits of feedlot Nellore and Angus × Nellore cross cattle at different growth stages. J Agric Sci 156: 110-117.).

Crossbred animals exposed to high-quality diets could be an alternative to reduce the feedlot period. Since the genetic composition has an influence on performance, when planned correctly, it can positively influence 20 to 25% of the final productivity of cattle (Pastor et al. 2017PASTOR FM, FALÇONI FMS & LIMA MDV. 2017. Crossings between Nellore and Bos taurus: a potential improvement of carcass dressing. Pubvet 11: 723-726.). Crossbreeding can be a gainful strategy to improve beef production and profitability (Rezagholivand et al. 2021REZAGHOLIVAND AA, NIKKHAH A, KHABBAZAN MH, MOKHTARZADEH S, DEHGHAN M, MOKHTABAD Y, SADIGHI F, SAFARI F & RAJAEE A. 2021. Feedlot performance, carcass characteristics and economic profits in four Holstein-beef crosses compared with pure-bred Holstein cattle. Livestock Science 244: 104358.) both by providing the complementarity between breeds and by the manifestation of heterosis (Guimarães et al. 2022), which leads to improvements in performance, carcass characteristics and productivity (Amaral et al. 2018AMARAL PM, MARIZ LDS, ZANETTI D, PRADOS LF, MARCONDES MI, santos AS, DETMANN E, FACIOLA AP & VALADARES FILHO SC. 2018. Effect of dietary protein content on performance, feed efficiency and carcass traits of feedlot Nellore and Angus × Nellore cross cattle at different growth stages. J Agric Sci 156: 110-117.). However, Bos indicus cattle differ from Bos taurus in feed intake, growth rate and body composition (Lunstra & Cundiff 2003LUNSTRA DD & CUNDIFF LV. 2003. Growth and pubertal development in Brahman-, Boran-, Tuli-, Belgian Blue-, Hereford- and Angus-sired bulls. J Anim Sci 81: 1414-1426., Schutt et al. 2009SCHUTT KM, ARTHUR PF & BURROW HM. 2009. Brahman and Brahman crossbred cattle grown on pasture and in feedlots in subtropical and temperate Australia. 3. Feed efficiency and feeding behavior offeedlot finished animals. Anim Prod Sci 49: 452-460.). These possible differences imply differences in the use of nutrients, which are supported by different requirement systems, such as BR-CORTE (Valadares Filho et al. 2016) and NASEM (2016)NASEM - NATIONAL ACADEMIES OF SCIENCES, ENGINEERING, AND MEDICINE. 2016. Nutrient Requirements of Beef Cattle. 8th ed. National Academies Press..

The use of crosses between Bos taurus and Bos indicus has boosted cattle production in tropical areas, primarily through the utilization of Aberdeen Angus (Santiago et al. 2021SANTIAGO B, BALDASSINI W, TOMAZ L, ROCHA L, SANTOS W, CURI R, CHARDULO LA & NETO OM. 2021. Comparison of dental carcass maturity in non-castrated male F1 Angus-Nellore cattle finished in feedlot. Food Sci Anim Resour 41: 554-562.). Research has shown significant differences in the nutritional efficiency and carcass characteristics between different genetic groups of beef cattle (Goulart et al. 2020GOULART RS, CAETANO M, POTT EB, DA CRUZ GM, TULLIO RR, DE ALENCAR MM, BERTHO RDM & LANNA DPD. 2020. Comparison of Nellore and Bos taurus × Nellore beef crosses at the same age on performance, carcass characteristics, and fecal starch content. Applied Animal Science 36(3): 430-436.). However, there is little information on Brangus and Braford animals crossed with NE.

Therefore, this study aimed to evaluate the nutritional and productive performance of purebred NE, Brangu x NE (BGNE) and Braford xNE (BFNE) heifers in a feedlot system.

MATERIALS AND METHODS

The research was carried out in accordance with the Ethical Principles in Animal Experimentation, adopted by the National Council for the Control of Animal Experimentation (CONCEA) of Brazil.

Design, experimental procedures and sampling

The experiment was carried out in the experimental feedlot, located in Campos de Júlio city with latitude: 13° 53 ‘58 “S and longitude: 59° 08’ 51” W, in the state of Mato Grosso, from August to November 2016.

Thirty heifers (body weight - BW = 261 kg ± 17.5; 18 months) from three genetic groups - Nellore (NE), Brangus x Nellore (BGNE) and Braford x Nellore (BFNE) - were used. The experiment was structured and conducted according to a completely randomized design, with three treatments (genetic groups) with 10 repetitions each.

The heifers were submitted to a 14-day adaptation period to the feedlot and fed a total mixed diet at 1.8% of BW composed of corn silage and concentrated feed. Then, the heifers were weighed at the beginning of the experiment after being subjected to fasting from solids (12 hours) and randomly allocated to individual pens (15.75 m²) provided with a feeder and a drinking fountain. The experiment lasted 120 days with four experimental periods.

Heifers received two diets during the experimental period (Table II). In the initial diet (roughage:concentrate ratio, R:C - 40:60), corn silage was used as roughage, and in the second diet (R:C - 30:70), the roughage was Panicum Hybrid cv. Massai hay. The animals were fed each diet for 60 days, and in both groups, the commercial concentrate (17.85% CP) from Nutrideal® was used (Table I).

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Table I
Chemical composition (g/kg of dry matter) of diet ingredient.

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Table II
Chemical composition (g/kg DM) of the diets according to the roughage.

A total mixed ration was provided twice a day (7h00 am and 4h00 pm). The amount of feed was adjusted daily, allowing 5.0% leftovers to guarantee ad libitum intake. Leftover was collected and weighed daily, obtaining a sample composed of animal/week. Diet samples were collected every day, and at the end of a week, a sample composed of animals was taken.

Fecal collection was performed for three days (Day 1 - 9h00; Day 2 -13h00 and Day 3 - 16h00) in the last week of each experimental period, obtaining a composed sample per animal per period.

Sample processing and chemical analysis

The samples were dried in a forced air ventilation oven (55 °C) for 72 h and ground (Wiley mill - Tecnal, SP, Brazil) at 2,0 mm to determine the indigestible neutral detergent fiber (iNDF) concentration and 1,0 mm for other analyses. To quantify iNDF, the fecal samples, feeds and leftovers were placed in filter bags (model F57, Ankon®) and incubated in a rumen-cannulated animal for 288 h (Valente et al. 2011VALENTE TNP, DETMANN E, QUEIROZ ACD, VALADARES FILHO SC, GOMES DI & FIGUEIRAS JF. 2011. Evaluation of ruminal degradation profiles of forages using bags made from different textiles. Brazilian Journal of Animal Sciences 40: 2565-2573.).

The samples were put in the bags following the ratio of 20 mg DM/cm² of surface (Nocek 1988NOCEK JE. 1988. In situ and other methods to estimate ruminal protein and energy digestibility: a review. Journal of Dairy Science 71: 2051-2069.) and were incubated in the rumen of two crossbred Holstein × Zebu steers. After 288 h, the bags were cleaned with tap water and oven-dried (60°C/72 hours and 105°C/1 hour) for posterior analysis. Fecal production (FP) was estimated using indigestible neutral detergent fiber (iNDF) as an internal marker for calculating apparent digestibility.

The samples collected were analyzed for dry matter (DM) and organic matter (OM, method No. 934.01), mineral matter (MM, method No. 924.05) and crude protein (CP, method No. 920.87) according to AOAC (2000)AOAC - ASSOCIATION OF OFFICIAL ANALYTICAL CHEMISTS. 2000. Official Methods of Analysis, 17th ed. AOAC, Gaithersburg, MD, USA. and ether extract (EE) determined by method No. 920.85 (AOAC 1990AOAC - ASSOCIATION OF OFFICIAL ANALYTICAL CHEMISTS. 1990. Official Methods of Analysis, 15th edn. AOAC, Arlington, VA.).

The neutral detergent fiber (NDF) content was estimated according to Mertens (2002)MERTENS DR. 2002. Gravimetric determination of amylase treated neutral detergent fiber in feeds with refluxing in beakers or crucibles: Collaborative study. Journal of AOAC Int 85: 1212-1240. without the addition of sodium sulphite using thermostable alpha-amylase in the detergent. The NDF was corrected to ash (Mertens 2002MERTENS DR. 2002. Gravimetric determination of amylase treated neutral detergent fiber in feeds with refluxing in beakers or crucibles: Collaborative study. Journal of AOAC Int 85: 1212-1240.) and protein (Licitra et al. 1996LICITRA G, HERNANDES TM & VAN SOEST PJ. 1996. Standardization of procedures for nitrogen fractionation of ruminants feeds. Anim Feed Sci Technol 57: 347-358.). Nonfiber carbohydrates (NFC) were calculated according to Detmann & Valadares Filho (2010). The contents of total digestible nutrients (TDN) were calculated according to the NRC (2001)NRC - NATIONAL RESEARCH COUNCIL. 2001. Nutrient Requirements of Dairy Cattle 7th rev. Ed. National Academies Press..

Productive performance and carcass traits

Heifers were weighed (after being subjected to fasting from solids -12 hours) to obtain final BW and average daily gain (ADG). The feed efficiency (FE) was estimated by the ratio between ADG (kg) and DM intake. The animals were slaughtered in a commercial slaughterhouse (Diamantino, Mato Grosso State) following the procedures of Brazilian standards (Ludtke et al. 2012LUDTKE CB, CIOCCA JRP, DANDIN, T, BARBALHO PC, VILELA JA & FERRARINI C. 2012. Humane slaughter of cattle. First edition, WSPA Brazil - World Society for Animal Protection, Rio de Janeiro.). Fat cover was subjectively evaluated according to the scale used by the packing plant where the animals were slaughtered by the same evaluators. The carcasses were classified on a scale of 1 to 5: 1 = absent fat, 2 = sparse fat (1 to 3 mm), 3 = medium fat (above 3 to 6 mm), 4 = uniform fat (over 6 to 10 mm), and 5 = excessive fat (over 10 mm).

The carcass dressing (CD - %) was calculated through the ratio between hot carcass weight (HCW) and the final body weight (FBW). The HCW was obtained by the sum of the half-carcasses after slaughter and evisceration. After 48 hours of cooling in a cold chamber, measurements of carcass length (CL) and carcass thoracic depth (CTD) were performed. The CL was measured using a measuring tape from the cranial border of the middle portion of the first rib to the cranial border of the pubic bone (Boggs & Merkel 1984BOGGS DL & MERKEL RA. 1984. Live animal evaluation and selection manual. 2nd ed. Dubuque: Kendall/Hunt Publishing Company, 215 p.), and the CTD was measured from the ventral base of the 5th rib (sternum bone) to the ventral base of the vertebral foramen of the 5th thoracic vertebra.

Statistical analysis

Comparisons between treatment averages were performed using the following orthogonal contrasts: Nellore versus crossbred heifers (BGNE and BFNE) and BGNE versus BFNE. The initial BW was used as a covariate to adjust the other variables analyzed. The data were analyzed using the PROC MIXED procedure of the SAS statistical package, version 9.0, using the following statistical model:

Y_{i j} = µ + t i + β (ӿ_{i j} - x_{i j}) + e_{i j}

where Yij = experimental response measured in the experimental unit already submitted to treatment i; µ = general constant; ti = effect related to treatment i; β = linear regression coefficient between the covariate (Xij) and response variable (Y); and eij = random error associated with each observation. The Kruskal‒Wallis nonparametric test was performed to evaluate the means for finishing the fat in the carcass. For all procedures, a significance level of 5% was adopted.

RESULTS

Intake and digestibility

Nellore heifers had a lower intake of dietary constituents than crossbred heifers (P <0.05). BGNE heifers presented higher NDFcp intake (P<0.05) than BFNE heifers (Table III).

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Table III
Intake and total apparent digestibility and dietary concentration of total digestible nutrients (TDN) according to genetic group.

Except for the higher NDFap digestibility (P <0.05) observed in BGNE than BFNE heifers, there was no difference (P> 0.05) among the genetic groups for the apparent digestibility of nutrients and for the dietary concentration of TDN (Table III).

Productive performance and carcass traits

There were no differences between BGNE and BFNE heifers (P>0.05), which had higher FBW, ADG, FE, HCW and CL than NE heifers. However, NE heifers had higher CD (P>0.05) (Table IV). There was no difference in CTD between NE and crossbred heifers (P>0.05). Crossed heifers presented better fat cover (P<0.05) than NE heifers (Table V).

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Table IV
Productive performance and quantitative characteristics of the carcass according to the genetic group.

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Table V
Fat cover of carcasses according to the genetic group.

DISCUSSION

Crossbred heifers (BGNE and BFNE) presented higher intake, performance and feed efficiency than purebred NE heifers. Regarding carcass traits, except for CD (higher for NE heifers), crossbred heifers presented higher HCW and better fate cover.

Adjustments to predict the DM intake for different breeds of beef cattle were proposed by the AFRC (1993)AFRC. 1993. Energy and Protein Requirements of Ruminants. Wallingford, UK: CAB International. system with higher DM intake for Bos taurus cattle. In addition, the BR-CORTE nutritional requirement system (Valadares Filho et al. 2016) also predicts a higher DM intake for crossbred animals than for Nellore cattle. This difference would be associated with the higher genetic potential for the growth of Bos taurus cattle (NASEM 2016NASEM - NATIONAL ACADEMIES OF SCIENCES, ENGINEERING, AND MEDICINE. 2016. Nutrient Requirements of Beef Cattle. 8th ed. National Academies Press.).

In fact, it was observed that crossbred heifers had a higher DM and TDN intake, with consequently higher ADG and FE than NE heifers. Crossbred heifers consumed (DM) 20.7% more than NE heifers and were 18.2% more efficient (EF) with performance (ADG) 46.7% higher. These positive results for crossbred heifers can be attributed to heterosis and breed complementarity, resulting in genetic gains. According to Marcondes et al. (2011)MARCONDES MI, VALADARES FILHO SDC, OLIVEIRA IMD, PAULINO PVR, VALADARES RFD & DETMANN E. 2011. Feed efficiency of pure and crossbred cattles fed high or low concentrate level. Brazilian Journal of Animal Science 40: 1313-1324., it is possible that the higher EF of crossbred animals is associated not only because they have Bos taurus blood composition but also since they have higher ADG, energy expenditure with maintenance is diluted and thus makes them more efficient.

According to Habib et al. (2008)HABIB M, POLLOTT GE & LEAVER JD. 2008. Effect of cattle genotype and variable feed supply on forage intake and digestibility. Asian-Australas. J Anim Sci 21: 1435-1440., the difference in DM intake between subspecies seems to be dependent on the diet, with intake becoming less similar in diets with a high proportion of concentrate. Chemostatic effects are related to the adjustment of DM intake to keep energy intake constant (Krehbiel et al. 2006KREHBIEL CR, CRANSTON JJ & MCCURDY MP. 2006. An upper limit for caloric density of finishing diets. J Anim Sci 84: 34-39.). In diets with high energy and lower fiber content, ruminants will regulate DM intake by meeting their energy requirement (Mertens 1994MERTENS DR. 1994. Regulation of forage intake. In: Fahey Jr GC (Ed) Forage quality, evaluation and utilization. Wisconsin: American Society of Agronomy, 450-493.), with a consequent balance occurring with the other nutrients.

The net energy requirement for maintenance (NEm) is one of the most important factors for DM intake; thus, the lower TDN intake observed in NE heifers can also be associated with lower nutritional requirements than crossbred heifers. According to the NASEM (2016)NASEM - NATIONAL ACADEMIES OF SCIENCES, ENGINEERING, AND MEDICINE. 2016. Nutrient Requirements of Beef Cattle. 8th ed. National Academies Press., NEm would be 10% lower in Bos indicus (except Nellore) than in Bos taurus and considers that crossbred cattle (Bos taurus × Bos indicus) have intermediate NEm between purebred breeds. This lower NEm for Bos indicus cattle is partly due to the lower weight of internal organs, mainly the gastrointestinal tract (GIT - high metabolic rates) (Menezes et al. 2005MENEZES LFG, RESTLE J, BRONDANI IL, ALVES FILHO DC, KUSS F, SILVEIRA MF & AMARAL GA. 2005. Carcass Characteristics of Feedlot Finished Steers from Advanced Generations of Rotational Crossbreeding between Charolais and Nellore Breeds. Rev Bras Zootec 34: 934-945.), which also contributes to the lower DM intake than that of crossbred animals (Ferrell & Jenkins 1998FERRELL CL & JENKINS TG. 1998. Body composition and energy use by steers of diverse genotypes fed a high-concentrate diet during the finishing period: II. Angus, Boran, Brahman, Hereford, and Tuli sires. Journal of Animal Science 6: 647-657.).

It is known that the amount of DM consumed is related to meeting the animal’s energy needs. According to Nascimento et al. (2021)NASCIMENTO ET AL. 2021. A comparison of Nellore and Nellore-cross entire male cattle finished in a feedlot in a tropical area of Brazil with respect to carcass characteristics and meat quality after aging either with or without 60 days of prior frozen storage. Anim Prod Sci 62: 173-181., as the diet energy concentration increases, the animals consume more energy per unit of metabolic weight, which also justifies the lower DM intake by Nellore heifers, since they had lower final BW.

This lower GIT weight also partly explains the higher CD of NE heifers. Zebu animals have the genetic characteristic of having a higher CD when compared to Bos taurus animals (Rubiano et al. 2009RUBIANO GAG, ARRIGONI MB, MARTINS CL, RODRIGUES E, GONÇALVES HC & ANGERAMI CN. 2009. Performance, carcass traits and meat quality of Young Canchim, Nellore and crossbread bulls. Rev Bras Zootec 38: 2490-2498.). Furthermore, they present thinner bones, thin leather and less head weight (Façanha et al. 2014FAÇANHA DAE, LEITE JHGM, QUEIROGA RCRE, COSTA RG, GARRUTI DS & SILVA TLS. 2014. Carcass and meet characteristics of very young Angus x Nellore steers in the Agreste Potiguar region. Revista Ciência Agronômica 45: 612-619.). Putrino et al. (2006)PUTRINO SM, LEME PR & SILVA SL. 2006. Net protein and energy requirements for weight gain of Brangus and Nellore bulls fed diets containing different proportions of concentrate. Rev Bras Zootec 35: 292-300., evaluating the CD of NE and Brangus, also found a higher CD for NE cattle.

In addition to the nonadditive (heterosis) and additive (breed complementary) effects, the higher ADG and HCW of crossbred heifers can be attributed to the higher CP and TDN intake that allowed the expression of genetic potential. According to Amaral et al. (2018)AMARAL PM, MARIZ LDS, ZANETTI D, PRADOS LF, MARCONDES MI, santos AS, DETMANN E, FACIOLA AP & VALADARES FILHO SC. 2018. Effect of dietary protein content on performance, feed efficiency and carcass traits of feedlot Nellore and Angus × Nellore cross cattle at different growth stages. J Agric Sci 156: 110-117., the higher ADG of crossbred animals is also related to a greater carcass gain with higher amounts of protein and fat retained in the animals’ bodies. In fact, it was found that in addition to the higher ADG, crossbred heifers had a higher fat cover than NE heifers.

Genetics is a factor that influences the characteristics of growth and deposition of fat due to the different characteristics of each genetic group that are caused by the maturity of the breed (Lopes et al. 2012LOPES LS, LADEIRA MM, MACHADO NETO OR, PAULINO PVR, CHIZZOTTI ML, RAMOS EM & OLIVEIRA DM. 2012. Characteristics of carcass and commercial meat cuts from Red Norte and Nellore young bulls finished in feedlot. Rev Bras Zootec 41: 970-977.). In this way, crossbred heifers reach maturity earlier and present higher deposition of fat on carcasses. Barwick et al. (2009)BARWICK SA, WOLCOTT ML, JOHNSTON DJ, BURROW HM & SULLIVAN MT. 2009. Genetics of steer daily and residual feed intake in two tropical beef genotypes, and relationships among intake, body composition, growth and other post-weaning measures. Ani Prod Sci 49: 351-366. related the deposition of fat according to the origin of the breeds, considering the evolutionary differences and adaptations to the environments in which they were inserted.

The CL (Pacheco et al. 2014PACHECO, OS, RESTLE J, VAZ FN, BRONDANI IL, ALVES FILHO DC, SILVEIRA MF, SEGABINAZZI LR, FREITAS LS, SEVERO MM & NIGELISKII AF. 2014. Additive and non-additive genetic effects, genetic group and breeding system on carcass metric characteristics of steers originated from Charolais x Nellore rotational crossbreeding. Semina: Ciências Agrárias 35: 3319-3330.) and CTD (Mourão et al. 2010MOURÃO RC, RODRIGUES VC, MUSTACHES VS, COSTA DPB, PINHEIRO RSB, FIGUEIREDO M & VIEIRA AO. 2010. Morphometric measurements of steers Nellore and Nellore X Limousin. Agropecuária Científica no Semi-árido 06: 27-32.) show a positive correlation with carcass weight and are metric characteristics more influenced by genetic additive racial and heterotic effects. Thus, crossbred animals tend to grow earlier than NE animals and have greater longitudinal growth (Machado et al. 2014MACHADO DS, BRONDANI IL, ALVES FILHO DC, CATTELAM J, QUADROS ARB, SILVA VS, CARDOSO GSC & BORCHATE D. 2014. Heterotic effect on performance and body measures of feedlot steers. Revista Ciência Agroveterinárias. 13: 284-292.).

BGNE and BFNE heifers have the same proportion of Bos Taurus blood composition (British taurine breed - Hereford and Angus). Thus, considering that the same diet was offered, the same DM and GE intake observed may be associated with the same maintenance and production needs of heifers. Regarding carcass traits, the similarity between BGNE and BFNE heifers is also due to the same slaughter weight and HCW.

Bartoň et al. (2006)BARTOŇ L, ŘEHÁK D, TESLÍK V, BUREŠ D & ZAHRÁDKOVÁ R. 2006. Effect of breed on growth performance and carcass composition of Aberdeen Angus, Charolais, Hereford and Simmental bulls. Czech J Anim Sci 51: 47-53. evaluated the performance and composition of the Hereford and Angus carcasses, which are part of the compostition of the Braford and Brangus breeds, respectively, and found no differences regarding ADG, slaughter weight and fat cover. Göncü et al. (2020)GÖNCÜ S, ANITAŞ O & GÖRGÜLÜ M. 2020. The comparisons of fattening performance of Angus, Brangus and Hereford Bullocks at different initial body weight. MOJ Ecology and Environmental Sciences (MOJES) 5: 188-191. also did not observe differences in the fattening performance of Angus and Hereford steers.

CONCLUSION

Despite presenting lower carcass yield than Nellore heifers, crossed heifers are more efficient and present higher performance and better carcass fat cover than purebred Nellore heifers. Crossbreeding synthetic breeds, such as Brangus and Braford breeds, with the Nellore breed is an effective way to increase the productivity and efficiency of feedlot heifers in tropical regions.

ACKNOWLEDGMENTS

This study was financed in part by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - Brazil (CAPES) - Finance Code 001. The authors gratefully acknowledge Mr. Celso Jaloto Ávila Júnior for intermediating and enabling the research to be carried out at the Fazenda Genética La Aurora and Mr. Diego Parodi, owner of the Fazenda Genética La Aurora, for the heifers, the feed and the feedlot facilities.

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GÖNCÜ S, ANITAŞ O & GÖRGÜLÜ M. 2020. The comparisons of fattening performance of Angus, Brangus and Hereford Bullocks at different initial body weight. MOJ Ecology and Environmental Sciences (MOJES) 5: 188-191.
GOULART RS, CAETANO M, POTT EB, DA CRUZ GM, TULLIO RR, DE ALENCAR MM, BERTHO RDM & LANNA DPD. 2020. Comparison of Nellore and Bos taurus × Nellore beef crosses at the same age on performance, carcass characteristics, and fecal starch content. Applied Animal Science 36(3): 430-436.
GUIMARAES TP, BILEGO UO, REZENDE, PLDP, AUGUSTO WF, MARCHESIN WA, SILVA AHGD, MOREIRA KKG & RESTLE J. 2022. Effect of mineral-energy supplementation on the performance of young bulls from different genetic groups on pasture. Semina Ciências Agrárias, 73-90.
HABIB M, POLLOTT GE & LEAVER JD. 2008. Effect of cattle genotype and variable feed supply on forage intake and digestibility. Asian-Australas. J Anim Sci 21: 1435-1440.
KREHBIEL CR, CRANSTON JJ & MCCURDY MP. 2006. An upper limit for caloric density of finishing diets. J Anim Sci 84: 34-39.
LICITRA G, HERNANDES TM & VAN SOEST PJ. 1996. Standardization of procedures for nitrogen fractionation of ruminants feeds. Anim Feed Sci Technol 57: 347-358.
LOPES LS, LADEIRA MM, MACHADO NETO OR, PAULINO PVR, CHIZZOTTI ML, RAMOS EM & OLIVEIRA DM. 2012. Characteristics of carcass and commercial meat cuts from Red Norte and Nellore young bulls finished in feedlot. Rev Bras Zootec 41: 970-977.
LUDTKE CB, CIOCCA JRP, DANDIN, T, BARBALHO PC, VILELA JA & FERRARINI C. 2012. Humane slaughter of cattle. First edition, WSPA Brazil - World Society for Animal Protection, Rio de Janeiro.
LUNSTRA DD & CUNDIFF LV. 2003. Growth and pubertal development in Brahman-, Boran-, Tuli-, Belgian Blue-, Hereford- and Angus-sired bulls. J Anim Sci 81: 1414-1426.
MACHADO DS, BRONDANI IL, ALVES FILHO DC, CATTELAM J, QUADROS ARB, SILVA VS, CARDOSO GSC & BORCHATE D. 2014. Heterotic effect on performance and body measures of feedlot steers. Revista Ciência Agroveterinárias. 13: 284-292.
MARCONDES MI, VALADARES FILHO SDC, OLIVEIRA IMD, PAULINO PVR, VALADARES RFD & DETMANN E. 2011. Feed efficiency of pure and crossbred cattles fed high or low concentrate level. Brazilian Journal of Animal Science 40: 1313-1324.
MENEZES LFG, RESTLE J, BRONDANI IL, ALVES FILHO DC, KUSS F, SILVEIRA MF & AMARAL GA. 2005. Carcass Characteristics of Feedlot Finished Steers from Advanced Generations of Rotational Crossbreeding between Charolais and Nellore Breeds. Rev Bras Zootec 34: 934-945.
MERTENS DR. 1994. Regulation of forage intake. In: Fahey Jr GC (Ed) Forage quality, evaluation and utilization. Wisconsin: American Society of Agronomy, 450-493.
MERTENS DR. 2002. Gravimetric determination of amylase treated neutral detergent fiber in feeds with refluxing in beakers or crucibles: Collaborative study. Journal of AOAC Int 85: 1212-1240.
MOURÃO RC, RODRIGUES VC, MUSTACHES VS, COSTA DPB, PINHEIRO RSB, FIGUEIREDO M & VIEIRA AO. 2010. Morphometric measurements of steers Nellore and Nellore X Limousin. Agropecuária Científica no Semi-árido 06: 27-32.
NASCIMENTO ET AL. 2021. A comparison of Nellore and Nellore-cross entire male cattle finished in a feedlot in a tropical area of Brazil with respect to carcass characteristics and meat quality after aging either with or without 60 days of prior frozen storage. Anim Prod Sci 62: 173-181.
NASEM - NATIONAL ACADEMIES OF SCIENCES, ENGINEERING, AND MEDICINE. 2016. Nutrient Requirements of Beef Cattle. 8th ed. National Academies Press.
NRC - NATIONAL RESEARCH COUNCIL. 2001. Nutrient Requirements of Dairy Cattle 7th rev. Ed. National Academies Press.
NOCEK JE. 1988. In situ and other methods to estimate ruminal protein and energy digestibility: a review. Journal of Dairy Science 71: 2051-2069.
OLIVEIRA CA & MILLEN DD. 2014. Survey of the nutritional recommendations and management practices adopted by feedlot cattle nutritionists in Brazil. Anim Feed Sci Technol 197: 64-75.
PACHECO, OS, RESTLE J, VAZ FN, BRONDANI IL, ALVES FILHO DC, SILVEIRA MF, SEGABINAZZI LR, FREITAS LS, SEVERO MM & NIGELISKII AF. 2014. Additive and non-additive genetic effects, genetic group and breeding system on carcass metric characteristics of steers originated from Charolais x Nellore rotational crossbreeding. Semina: Ciências Agrárias 35: 3319-3330.
PASTOR FM, FALÇONI FMS & LIMA MDV. 2017. Crossings between Nellore and Bos taurus: a potential improvement of carcass dressing. Pubvet 11: 723-726.
PUTRINO SM, LEME PR & SILVA SL. 2006. Net protein and energy requirements for weight gain of Brangus and Nellore bulls fed diets containing different proportions of concentrate. Rev Bras Zootec 35: 292-300.
REZAGHOLIVAND AA, NIKKHAH A, KHABBAZAN MH, MOKHTARZADEH S, DEHGHAN M, MOKHTABAD Y, SADIGHI F, SAFARI F & RAJAEE A. 2021. Feedlot performance, carcass characteristics and economic profits in four Holstein-beef crosses compared with pure-bred Holstein cattle. Livestock Science 244: 104358.
RUBIANO GAG, ARRIGONI MB, MARTINS CL, RODRIGUES E, GONÇALVES HC & ANGERAMI CN. 2009. Performance, carcass traits and meat quality of Young Canchim, Nellore and crossbread bulls. Rev Bras Zootec 38: 2490-2498.
SANTIAGO B, BALDASSINI W, TOMAZ L, ROCHA L, SANTOS W, CURI R, CHARDULO LA & NETO OM. 2021. Comparison of dental carcass maturity in non-castrated male F1 Angus-Nellore cattle finished in feedlot. Food Sci Anim Resour 41: 554-562.
SCHUTT KM, ARTHUR PF & BURROW HM. 2009. Brahman and Brahman crossbred cattle grown on pasture and in feedlots in subtropical and temperate Australia. 3. Feed efficiency and feeding behavior offeedlot finished animals. Anim Prod Sci 49: 452-460.
VALADARES FILHO SC, SILVA LFC, GIONBELLI MP, ROTTA PP, MARCONDES MI, CHIZZOTTI ML & PRADOS LF. 2016. Nutrient requirements of zebu and crossbred cattle - BR CORTE. 3rd ed. Viçosa: Minas Gerais, 314.
VALENTE TNP, DETMANN E, QUEIROZ ACD, VALADARES FILHO SC, GOMES DI & FIGUEIRAS JF. 2011. Evaluation of ruminal degradation profiles of forages using bags made from different textiles. Brazilian Journal of Animal Sciences 40: 2565-2573.

Publication Dates

Publication in this collection
10 May 2024
Date of issue
2024

History

Received
25 July 2023
Accepted
4 Feb 2024

This is an open-access article distributed under the terms of the Creative Commons Attribution License

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[13] GOULART RS, CAETANO M, POTT EB, DA CRUZ GM, TULLIO RR, DE ALENCAR MM, BERTHO RDM & LANNA DPD. 2020. Comparison of Nellore and Bos taurus × Nellore beef crosses at the same age on performance, carcass characteristics, and fecal starch content. Applied Animal Science 36(3): 430-436.

[14] GUIMARAES TP, BILEGO UO, REZENDE, PLDP, AUGUSTO WF, MARCHESIN WA, SILVA AHGD, MOREIRA KKG & RESTLE J. 2022. Effect of mineral-energy supplementation on the performance of young bulls from different genetic groups on pasture. Semina Ciências Agrárias, 73-90.

[15] HABIB M, POLLOTT GE & LEAVER JD. 2008. Effect of cattle genotype and variable feed supply on forage intake and digestibility. Asian-Australas. J Anim Sci 21: 1435-1440.

[16] KREHBIEL CR, CRANSTON JJ & MCCURDY MP. 2006. An upper limit for caloric density of finishing diets. J Anim Sci 84: 34-39.

[17] LICITRA G, HERNANDES TM & VAN SOEST PJ. 1996. Standardization of procedures for nitrogen fractionation of ruminants feeds. Anim Feed Sci Technol 57: 347-358.

[18] LOPES LS, LADEIRA MM, MACHADO NETO OR, PAULINO PVR, CHIZZOTTI ML, RAMOS EM & OLIVEIRA DM. 2012. Characteristics of carcass and commercial meat cuts from Red Norte and Nellore young bulls finished in feedlot. Rev Bras Zootec 41: 970-977.

[19] LUDTKE CB, CIOCCA JRP, DANDIN, T, BARBALHO PC, VILELA JA & FERRARINI C. 2012. Humane slaughter of cattle. First edition, WSPA Brazil - World Society for Animal Protection, Rio de Janeiro.

[20] LUNSTRA DD & CUNDIFF LV. 2003. Growth and pubertal development in Brahman-, Boran-, Tuli-, Belgian Blue-, Hereford- and Angus-sired bulls. J Anim Sci 81: 1414-1426.

[21] MACHADO DS, BRONDANI IL, ALVES FILHO DC, CATTELAM J, QUADROS ARB, SILVA VS, CARDOSO GSC & BORCHATE D. 2014. Heterotic effect on performance and body measures of feedlot steers. Revista Ciência Agroveterinárias. 13: 284-292.

[22] MARCONDES MI, VALADARES FILHO SDC, OLIVEIRA IMD, PAULINO PVR, VALADARES RFD & DETMANN E. 2011. Feed efficiency of pure and crossbred cattles fed high or low concentrate level. Brazilian Journal of Animal Science 40: 1313-1324.

[23] MENEZES LFG, RESTLE J, BRONDANI IL, ALVES FILHO DC, KUSS F, SILVEIRA MF & AMARAL GA. 2005. Carcass Characteristics of Feedlot Finished Steers from Advanced Generations of Rotational Crossbreeding between Charolais and Nellore Breeds. Rev Bras Zootec 34: 934-945.

[24] MERTENS DR. 1994. Regulation of forage intake. In: Fahey Jr GC (Ed) Forage quality, evaluation and utilization. Wisconsin: American Society of Agronomy, 450-493.

[25] MERTENS DR. 2002. Gravimetric determination of amylase treated neutral detergent fiber in feeds with refluxing in beakers or crucibles: Collaborative study. Journal of AOAC Int 85: 1212-1240.

[26] MOURÃO RC, RODRIGUES VC, MUSTACHES VS, COSTA DPB, PINHEIRO RSB, FIGUEIREDO M & VIEIRA AO. 2010. Morphometric measurements of steers Nellore and Nellore X Limousin. Agropecuária Científica no Semi-árido 06: 27-32.

[27] NASCIMENTO ET AL. 2021. A comparison of Nellore and Nellore-cross entire male cattle finished in a feedlot in a tropical area of Brazil with respect to carcass characteristics and meat quality after aging either with or without 60 days of prior frozen storage. Anim Prod Sci 62: 173-181.

[28] NASEM - NATIONAL ACADEMIES OF SCIENCES, ENGINEERING, AND MEDICINE. 2016. Nutrient Requirements of Beef Cattle. 8th ed. National Academies Press.

[29] NRC - NATIONAL RESEARCH COUNCIL. 2001. Nutrient Requirements of Dairy Cattle 7th rev. Ed. National Academies Press.

[30] NOCEK JE. 1988. In situ and other methods to estimate ruminal protein and energy digestibility: a review. Journal of Dairy Science 71: 2051-2069.

[31] OLIVEIRA CA & MILLEN DD. 2014. Survey of the nutritional recommendations and management practices adopted by feedlot cattle nutritionists in Brazil. Anim Feed Sci Technol 197: 64-75.

[32] PACHECO, OS, RESTLE J, VAZ FN, BRONDANI IL, ALVES FILHO DC, SILVEIRA MF, SEGABINAZZI LR, FREITAS LS, SEVERO MM & NIGELISKII AF. 2014. Additive and non-additive genetic effects, genetic group and breeding system on carcass metric characteristics of steers originated from Charolais x Nellore rotational crossbreeding. Semina: Ciências Agrárias 35: 3319-3330.

[33] PASTOR FM, FALÇONI FMS & LIMA MDV. 2017. Crossings between Nellore and Bos taurus: a potential improvement of carcass dressing. Pubvet 11: 723-726.

[34] PUTRINO SM, LEME PR & SILVA SL. 2006. Net protein and energy requirements for weight gain of Brangus and Nellore bulls fed diets containing different proportions of concentrate. Rev Bras Zootec 35: 292-300.

[35] REZAGHOLIVAND AA, NIKKHAH A, KHABBAZAN MH, MOKHTARZADEH S, DEHGHAN M, MOKHTABAD Y, SADIGHI F, SAFARI F & RAJAEE A. 2021. Feedlot performance, carcass characteristics and economic profits in four Holstein-beef crosses compared with pure-bred Holstein cattle. Livestock Science 244: 104358.

[36] RUBIANO GAG, ARRIGONI MB, MARTINS CL, RODRIGUES E, GONÇALVES HC & ANGERAMI CN. 2009. Performance, carcass traits and meat quality of Young Canchim, Nellore and crossbread bulls. Rev Bras Zootec 38: 2490-2498.

[37] SANTIAGO B, BALDASSINI W, TOMAZ L, ROCHA L, SANTOS W, CURI R, CHARDULO LA & NETO OM. 2021. Comparison of dental carcass maturity in non-castrated male F1 Angus-Nellore cattle finished in feedlot. Food Sci Anim Resour 41: 554-562.

[38] SCHUTT KM, ARTHUR PF & BURROW HM. 2009. Brahman and Brahman crossbred cattle grown on pasture and in feedlots in subtropical and temperate Australia. 3. Feed efficiency and feeding behavior offeedlot finished animals. Anim Prod Sci 49: 452-460.

[39] VALADARES FILHO SC, SILVA LFC, GIONBELLI MP, ROTTA PP, MARCONDES MI, CHIZZOTTI ML & PRADOS LF. 2016. Nutrient requirements of zebu and crossbred cattle - BR CORTE. 3rd ed. Viçosa: Minas Gerais, 314.

[40] VALENTE TNP, DETMANN E, QUEIROZ ACD, VALADARES FILHO SC, GOMES DI & FIGUEIRAS JF. 2011. Evaluation of ruminal degradation profiles of forages using bags made from different textiles. Brazilian Journal of Animal Sciences 40: 2565-2573.

Item	Concentrate^a	Corn silage	Massai hay
Dry matter	870.4	347.5	861.6
Organic matter	923.9	972.8	959.4
Crude protein	178.5	85.3	29.5
Ether extract	44.5	22.7	12.4
Nonfibrous carbohydrates	612.2	277.1	131.6
Neutral detergent fibre (NDF)	114.2	621.0	836.0
NDF corrected for ash and protein	91.7	586.0	785.9
Indigestible NDF	15.4	186.5	318.2

Item	Diets^a
Item	Corn silage	Massai hay
Dry matter	661.2	867.8
Organic matter	943.4	934.5
Crude protein	141.2	134.0
Ether extract	35.8	34.9
Nonfibrous carbohydrates	478.2	468.0
Neutral detergent fibre (NDF)	316.9	370.7
NDF corrected for ash and protein	289.4	300
Indigestible NDF	83.8	106.2
Total digestible nutrients	776.1	718.0

Item^b	Genetic group^a			e.p.m^c	Contrasts
	NE	BGNE	BFNE		NE x Crossbred		BGNE x BFNE
	NE	BGNE	BFNE		Estimate	P value	Estimate	P value
Intake
DM	7.59	9.45	8.87	0.08	-3.19	0.001	0.46	0.342
OM	6.67	8.16	7.82	0.09	-3.29	<0.001	0.83	0.053
CP	0.96	1.28	1.14	0.07	-0.52	<0.001	0.12	0.063
EE	0.26	0.33	0.31	0.06	-0.12	0.001	0.02	0.270
NDFcp	2.08	2.66	2.29	0.04	-0.80	0.009	0.35	0.014
TDN	5.78	7.19	6.50	0.10	-2.15	0.006	0.67	0.051
	g/kg of body weight
DM	23.00	26.98	26.47	1.09	-7.19	0.001	1.07	0.408
NDFap	6.76	8.07	7.31	0.76	-1.77	0.006	0.93	0.018
Digestibility (g/g)
DM	0.75	0.75	0.73	0.15	2.92	0.199	1.99	0.141
OM	0.78	0.77	0.75	0.14	3.55	0.087	1.44	0.219
CP	0.76	0.76	0.76	0.16	-0.71	0.756	0.37	0.785
EE	0.86	0.84	0.84	0.15	2.64	0.267	0.42	0.764
NDFap	0.69	0.69	0.66	0.12	1.48	0.198	2.56	0.001
Dietary concentration (g/g)
TDN	0.76	0.75	0.75	0.11	3.92	0.328	-1.00	0.668

Item	Genetic group^a			e.p.m^b	Contrasts
	Genetic group^a				NE x Crossbred		BGNE x BFNE
	NE	BGNE	BFNE		Estimate	P value	Estimate	P value
Average daily gain (kg/day)	0.76	1.14	1.09	0.04	-0.65	<0.001	0.11	0.205
Final body weight (kg)	344.10	385.40	382.01	5.36	-68.6	<0.001	11.53	0.203
Feed efficiency (kg)	0.11	0.13	0.13	0.01	-0.03	0.001	0.01	0.527
Carcass
Hot weight (kg)	181	198.45	195.5	2.43	-25.99	0.001	7.88	0.077
Yield (%)	52.65	51.52	51.19	0.27	2.74	0.017	0.54	0.403
Length (cm)	122.40	127.10	126.56	0.77	-9.49	0.002	-0.25	0.883
Thoracic depth (cm)	42.50	41.30	42.56	0.36	1.04	0.502	-1.38	0.154

Item	Fat cover
Item	Minimum	Average	Maximum
Nellore	2.0^b	2.8^b	4.1
Brangus x Nellore	3.0^a	3.4^a	4.0
Braford x Nellore	3.2^a	3.3^a	4.1

Brasil

Brasil

Nutritional and productive performance of purebred Nellore heifers and crossed with Brangus and Braford ﬁnished in a feedlot system

Abstract

INTRODUCTION

MATERIALS AND METHODS

Design, experimental procedures and sampling

Sample processing and chemical analysis

Productive performance and carcass traits

Statistical analysis

RESULTS

Intake and digestibility

Productive performance and carcass traits

DISCUSSION

CONCLUSION

ACKNOWLEDGMENTS

REFERENCES

Publication Dates

History