AbstractThe objectives of this stud

Abstract



The objectives of this study were to determine if percentage Bos taurus (0 or 50%) of the cow had an effect on ME requirements and milk production, and to compare cow/calf efficiency among 3 mating systems. Metabolizable energy requirements were estimated during a feeding trial that encompassed a gestation and lactation feeding trial for each of 2 groups of cows. Cows were 0 or 50% Bos taurus (100 or 50% Nellore) breed type: Nellore cows (NL; n = 10) mated to Nellore bulls, NL cows (n = 9) mated to Angus bulls, Angus × Nellore (ANL; n = 10) and Simmental × Nellore (SNL; n = 10) cows mated to Canchim (5/8 Charolais 3/8 Zebu) bulls. Cows were individually fed a total mixed diet that contained 11.3% CP and 2.23 Mcal of ME/kg of DM. At 14-d intervals, cows and calves were weighed and the amount of DM was adjusted to keep shrunk BW and BCS of cows constant. Beginning at 38 d of age, corn silage was available to calves ad libitum. Milk production at 42, 98, 126, and 180 d postpartum was measured using the weigh-suckle-weigh technique. At 190 d of age, calves were slaughtered and body composition estimated using 9-10-11th–rib section to obtain energy deposition. Regression of BW change on daily ME intake (MEI) was used to estimate MEI at zero BW change. Increase in percentage Bos taurus had a significant effect on daily ME requirements (Mcal/d) during pregnancy (P < 0.01) and lactation (P < 0.01). Percentage Bos taurus had a positive linear effect on maintenance requirements of pregnant (P = 0.07) and lactating (P < 0.01) cows; during pregnancy, the ME requirements were 91 and 86% of those in lactation (131 ± 3.5 vs. 145 ± 3.4 Mcal·kg−0.75·d−1) for the 0 and 50% B. taurus groups, respectively. The 50% B. taurus cows, ANL and SNL, suckling crossbred calves had greater total MEI (4,319 ± 61 Mcal; P < 0.01) than 0% B. taurus cows suckling NL (3,484 ± 86 Mcal) or ANL calves (3,600 ± 91 Mcal). The 0% B. taurus cows suckling ANL calves were more efficient (45.3 ± 1.6 g/Mcal; P = 0.03) than straightbred NL (35.1 ± 1.5 g/Mcal) and ANL or SNL pairs (41.0 ± 1.0 g/Mcal). Under the conditions of this study, crossbreeding improved cow/ calf efficiency and showed an advantage for cows that have lower energy requirements.

--------------------------------------------------------------------------------





INTRODUCTION

The output of the cow/calf enterprise is a function of weaning weight and the number of calves weaned (Dickerson, 1970). Weaning weight is an important trait and can be increased by crossbreeding programs (Short et al., 1996) utilizing different Bos taurus × Bos indicus crosses. Ferrell and Jenkins (1984), Solis et al. (1988), and Montaño-Bermudez et al. (1990) showed that breeds with greater milk production potential, associated with greater weaning weights, also had greater maintenance needs than breeds with lower milk production potential.

Maintenance requirements of cows represent approximately 50% of the total energy requirements for beef production (Ferrell and Jenkins, 1984). At restricted feed availability, breeds with greater maintenance requirements could have reduced performance relative to breeds with less maintenance requirements, resulting in reduced feed efficiency (Frisch and Vercoe, 1978). Green et al. (1991) reported that the most efficient system was represented by cows with less BW and decreased maintenance energy requirements. Beef production in Brazil (165 million cattle), as well as in other tropical and subtropical countries, is conducted mainly in extensive systems where feed availability is limited. In Brazil almost 80% of beef cattle are represented by Zebu breeds (mostly Nellore) and its crosses. Studies reporting nutrient requirements and efficiency of cows from tropically adapted breeds are scarce. Research in this area is important to provide data that more closely matches cow genetics with their environment and production system.

The objectives were to estimate energy requirements and milk production of straightbred Nellore and Continental/British × Nellore crosses; and compare cow/ calf efficiency among 3 mating systems (straightbred Nellore cow/calf pair, Nellore cows suckling Angus × Nellore calves, and crossbred cows suckling crossbred calves).




MATERIALS AND METHODS

All procedures with animals were conducted according to the University of São Paulo ethical standards established by the College of Agriculture Research Commission.



Animals and Management

The study was conducted at Embrapa (São Carlos, SP, Brazil) from October 2005 to October 2006. The cows produced for this study were from the same Nellore breeding herd, where Nellore dams were mated by natural service to Nellore bulls or artificially inseminated to Aberdeen Angus or Simmental bulls. The sires were represented by 6 Angus, 8 Simmental, and 7 Nellore.

Twenty mature cows for each group of percentage Bos taurus, Nellore (NL; 0% Bos taurus) cows and Angus or Simmental × Nellore (ANL or SNL; 50% Bos taurus) cows, were sampled for use in the study. The 50% B. taurus cows were mated by AI to Canchim (5/8 Charolais 3/8 Zebu) bulls (n = 3), whereas the 0% B. taurus females were mated by AI to NL (n = 4) or Aberdeen Angus (n = 2) bulls during the fall breeding season, from April to June 2005. As a result we had 2 groups of cows (0 or 50% Bos taurus) and 3 mating systems: straightbred NL cows with NL calves, NL cows suckling ANL calves, and ANL or SNL cows suckling crossbred calves (CC). The first system represents a low-input pair adapted to a challenging environment. The second system uses crossbreeding with a low-input cow and a high-growth-potential calf. The last system uses crossbreeding with high genetic potentials for growth in both the cows and calves.

Cows were kept on pasture and received a mineralized salt fed at a rate of 65 g·cow−1·d−1. At the beginning of the experiment, the cows were 60 ± 1.3 mo of age and with their third calf.



Gestation.

The trial was conducted from October 19, 2005, to March 2, 2006. Calves were weaned approximately 248 d before initiation of the gestation study. At 189 ± 11 d after mating, cows were distributed in individual pens with ad libitum access to water and received a total mixed diet (Table 1) containing 11.3% CP and 2.23 Mcal/kg of DM. The ME content of the diet was calculated from the TDN concentration, which was estimated according to the equation of Weiss et al. (1992), using 0.85 as the rate of degradation of the potentially digestible NDF. Cows were fed daily at 0800 h. The DM of feed was determined weekly. Orts were collected daily, weighed, and sampled, and at the end of the trial, a composite sample per cow was prepared and analyzed for DM, NDF, ADF, lignin, ash, ether extract, CP, NDIN, and ADIN. Cows were weighed at 14-d intervals after a 16-h shrink. Cow BCS (1 to 9 scale; Fox et al., 1992) was evaluated by 2 trained evaluators at first and last BW. Cow shrunk BW (SBW) was defined as full BW minus estimated weight of the gravid uterus calculated by the equation of Ferrell et al. (1976) as reported by Freetly et al. (2005).

At the start of the trial, maintenance ME requirements (MEm) were estimated according to NRC (1996). Based on the variation of SBW during the trial, the amount of feed provided to each cow was adjusted to maintain SBW. The energy requirements for pregnancy (conceptus: MEy) were estimated according to NRC (1996). Metabolizable energy intake (MEI) was calculated as the sum of MEm and MEy.

At 263 ± 12 d after mating, cows were transferred to pasture for calving. During this period, cows received mineralized salt, and the ME consumption was not recorded. After calving, the energy required for gestation, weights of the gravid uterus, and variation of cow SBW were corrected for the actual birth weight. Difference between initial and final SBW was observed during the gestation trial. The daily MEI at zero BW change for each cow was estimated by regression of BW change on daily MEI.

There were 5 male and 5 female calves in the CC group: ½ Canchim, ¼ Simmental, ¼ NL (CSN) and ½ Canchim, ¼ Angus, ¼ NL (CAN); 8 males and 2 females in the NL group, and 4 males and 5 females in the ½ Angus ½ NL (ANL) group. One ANL was born dead. Male calves were not castrated or implanted.




Lactation.

At 17 ± 8.9 d postpartum, 39 cow/calf pairs were redistributed in the individual pens. Cows were not exposed to bulls during the fall breeding season in 2006 and consequently, reproductive data were not evaluated. Cows were fed the same total mixed diet offered during pregnancy (Table 1). At 38 d of age, corn silage was fed to calves ad libitum. Cow and calf feeders were separated physically so that cows had no access to the feeders used by calves and vice versa, and individual cow and calf intakes were recorded. Animals were fed twice daily at 0700 and 1500 h. Dry matter intake was determined weekly. Orts were collected daily, weighed, and sampled, and at the end of the trial, a composite sample per cow was prepared and analyzed for DM, NDF, ADF, lignin, ash, ether extract, CP, NDIN, and ADIN. Cows and calves were weighed in the morning before feeding every 14 d. Cow BCS was evaluated by 2 trained evaluators.

At the beginning of the trial (first 14 d), daily MEI was estimated based on NE requirements for maintenance, according to the NRC (1996) and ME requirements for lactation (MEl) as described by Freetly et al. (2005).

The DMI of each individual cow was adjusted at 14-d intervals to minimize change in BW and keep BCS constant. The DMI was adjusted to zero SBW change during lactation as described for the gestation phase.

Milk yields at 42, 98, 126, and 180 d postpartum were determined using the weigh-suckle-weigh technique (Cundiff et al., 1974). Before each measurement cow/calf pairs were separated for 16 h. Calves were weighed, allowed to suckle under constant observation, and then reweighed. This was repeated after the pairs were se