Symposium Paper: Post-Calving Nutrition and Management Programs for Two-Year-Old Beef Cows11Presented at the Extension Symposium at the Midwest American Society of Animal Science sectional meetings in Des Moines, IA, on March 16, 2004. The symposium was sponsored by NCR-87, Committee on Cow-Calf Nutrition and Management

Effects of corn supplementation and age on performance and reproduction of beef females grazing lush spring pasture

This study evaluated how corn supplementation and age of female affected body weight (BW), body condition score (BCS), artificial insemination (AI) pregnancy rate, and blood metabolites (nonesterified fatty acid [NEFA], β-hydroxybutyrate [BHBA], and blood urea nitrogen [BUN]) when grazing lush spring pasture. Angus and Angus × Simmental beef females (n = 361) were blocked by location, stratified by BW and BCS, and then were assigned to groups (n = 8 groups/treatment combination; 9–14 females/group). The study utilized a stratified, randomized complete block design with a 2 × 2 factorial arrangement of treatments. The four treatment combinations were: yearling heifers receiving no supplement (CON-H); yearling heifers receiving supplement of dry-rolled corn (SUPP-H; 1.81 kg as-fed/heifer/d) for 42 d; 2-yr-old lactating cow-calf pairs receiving no supplement (CON-C); and 2-yr-old lactating cow-calf pairs receiving supplement of dry-rolled corn (SUPP-C; 1.81 kg as-fed/cow/d) for 42 d. Supplementation began at AI (end of April) when cows began grazing tall fescue (Festuca arundinacea schreb)-red clover (Trifolium pratense) pastures. Pasture forage was collected weekly for analysis. Throughout the study, forage crude protein decreased (P < 0.01) over time, but acid detergent fiber (ADF), neutral detergent fiber, dry matter, forage height, and forage mass all increased (P < 0.01) over time. Females receiving SUPP tended (P = 0.10) to have greater BW and greater BW change over the supplementation period. Supplementation × age effects for BCS were detected (P = 0.04); SUPP-H had greater BCS than all other treatment combinations at d 42. Cow BHBA was greater (P < 0.01) compared with heifers. Female NEFA increased (P < 0.01) from d 12 to 42. Control females had greater (P = 0.02) serum NEFA concentrations compared with SUPP females. Control females had greater (P = 0.03) BUN concentrations compared with SUPP females. Cow BUN was greater (P < 0.01) than heifer BUN. Supplementation effects were not detected (P ≥ 0.25) for AI or overall pregnancy rate. In conclusion, there were no supplementation × age interactions excluding d 42 BCS. Supplementation regardless of female age tended to improve d 42 BW and BW change. Cow BHBA and BUN was greater compared with the heifers, whereas the supplemented females had decreased NEFA and BUN. Cows tended to have greater AI pregnancy rates than heifers, but supplementation did not affect AI or overall pregnancy rates.

Effects of timing of weaning on energy utilization in primiparous beef cows and post-weaning performance of their progeny1

Early weaning is used to minimize cow nutrient requirements in situations where feed inputs are scarce or expensive. For many years, maintenance energy requirements have been assumed to be 20% greater in lactating compared with non-lactating beef cows. While not well established, maintenance energy requirements are thought to be greatest in primiparous cows and to decline with age. Consequently, early weaning primiparous cow-calf pairs should improve overall efficiency, particularly in situations where mid-to-late lactation forage or feed nutritive value is low. The objective of this study was to determine the biological efficiency of early weaning and maintenance energy requirements of lactating versus non-lactating primiparous cows. Experiments were conducted in two consecutive years using 90 primiparous cows and their calves (48 in yr 1, 42 in yr 2). Pairs were randomly assigned to one of the six pens (8 pairs/pen yr 1, 7 pairs/pen yr 2) and pens were randomly assigned to 1 of 2 treatments; (1) early weaning (130 d ± 15.4; EW, n = 6) and (2) traditional weaning (226 d ± 13.1; TW, n = 6). Late lactation cow and calf performance and feed consumption were measured for 92 d (yr 1) and 100 d (yr 2). Cows were limit-fed to meet maintenance requirements, while calves were offered ad libitum access to the same diet in a creep-feeding area. Calves were not allowed access to the cows' feed. Cow feed intake, body condition score, body weight (BW), milk yield and composition, and calf body weight gain and creep feed intake were recorded. After accounting for lactation and retained energy, there was a trend for greater maintenance energy requirements of lactating primiparous cows (P = 0.07). From the early weaning date to traditional weaning date, calf average daily gain (ADG) was greater (P < 0.01) for TW calves. Feed and energy efficiency of the pair was improved for the TW system (P < 0.01). Greater ADG were reported for EW calves during the stocker period (P = 0.03), but there were no differences during the finishing period (P > 0.40). At harvest, BW was greater (P = 0.02) and gain to feed ratio tended (P = 0.06) to be improved for TW calves. The increased TW calf performance offset the additional maintenance costs of their lactating dams, resulting in the TW system converting total feed energy to kilograms of calf BW gain more efficiently.

Divergent genotypes for fatness or residual feed intake in Angus cattle. 2. Body composition but not reproduction was affected in first-parity cows on both low and high levels of nutrition

This paper reports a subset of results from the Beef Cooperative Research Centre-funded Maternal Productivity Project. This research aimed to describe the response of Angus cows of different and divergent genotypes to variable nutritional environments over five breeding seasons. Cows selected for a divergence in either fat depth (HFat vs LFat) or residual feed intake (RFI: HRFI vs LRFI) based on mid-parent estimated breeding values (EBV) for those traits were allocated in replicate groups to either high or low nutritional treatments at two different sites, namely the Vasse Research Centre in Western Australia and the Struan Research Centre in South Australia. The traits reported in this paper include output traits (birth and weaning weight of calves, liveweight change of cows), change traits (change in Rib Fat, P8 fat, eye muscle area and liveweight between specified time points) and reproductive traits [pregnancy rates, percentage calves born alive and days to calving at the days to calving at the second calving opportunity (DC2)]. Having had their first calf, the vulnerability of these young cows to nutritional restriction and how it may adversely affect rebreeding was examined. HFat and HRFI cows were fatter, heavier and had greater eye muscle area than LFat and LRFI, respectively, at all times during the breeding cycle on both levels of nutrition. There was no difference in either days-to-calving or pregnancy rates after the second mating between genotypes. Equally, nutritional treatment had no effect on these traits in this cohort of cows. There was evidence for an implied genetic correlation between Rib Fat EBV, DC2 and pregnancy rates of –0.38 that suggests that selection for leanness may result in reduced fertility of the herd but the effect was not significant herein. As long as producers record the phenotype for both traits and select cows with favourable DC2 as well as low fatness, these problems can be avoided, owing to only 22% of variation in pregnancy rates being explained by DC2 and Rib Fat EBV. Producers can largely be confident that selection for leanness, or increased feed efficiency, has little impact on productivity as long as cows are in adequate body condition to remain healthy and productive.

Supplementation of corn dried distillers grains plus solubles to gestating beef cows fed low-quality forage: I. Altered intake behavior, body condition, and reproduction

To investigate the effects of corn dried distillers grains plus solubles (DDGS) supplementation to cows fed corn stover and silage during late gestation, 27 multiparous beef cows (674 ± 17 kg; BCS, 5.6 ± 0.1) were divided randomly into 2 pens equipped with electronic feeders. For 10 wk, both groups were fed the basal diet for ad libitum intake while 1 group was supplemented (SUP; = 12) with DDGS at 0.3% of BW (DM basis). Following parturition, all cows received the same diet for an additional 8 wk. During gestation, SUP cows gained BW ( < 0.01), and there was no change in BCS ( 0.79). Nonsupplemented (CON) cows tended to lose BW ( 0.06) and lost BCS ( < 0.01) during gestation. Supplemented cows consumed more forage ( 0.01) and total feed than CON cows. An interaction of treatment and day was observed for time spent consuming forage ( < 0.01); SUP cows consumed forage faster than CON cows ( ≤ 0.01) early in gestation. Control cows ate more meals than SUP cows ( = 0.06) from d 201 to 218 of gestation. Supplemented cows tended ( = 0.09) to consume larger meals than CON cows and spent more ( < 0.01) time eating than CON cows around d 240 of gestation. Calves born to SUP cows tended ( = 0.06) to be heavier than calves born to CON cows. During lactation, both groups gained ( < 0.01) BW. Body condition score was less ( < 0.05) in CON cows than it was in SUP cows at the end of the study. Dry matter intake during lactation increased ( < 0.01) over time but was not influenced ( = 0.44) by treatment. Supplemented cows spent more time ( < 0.01) eating than CON cows after wk 4 of lactation, and they ate faster than CON cows until wk 3 of lactation whereas CON cows ate faster than SUP cows after wk 6 of lactation ( 0.01). The number of meals increased with advancing lactation ( < 0.01) and CON cows averaged more meals daily than SUP cows ( = 0.01). Conversely, meal size decreased as lactation advanced ( < 0.01), and SUP cows consumed larger meals than CON cows ( = 0.05). Supplementation with DDGS during gestation influenced intake behavior during gestation and lactation as well as the maintenance of maternal BW and BCS and calf birth BW.

Effects of gestation and lactation on forage intake, digestion, and passage rates of primiparous beef heifers and multiparous beef cows

Angus-cross cows (n = 13; 8 pregnant, BW 610 ± 24 kg, and 5 nonpregnant, BW 571 ± 23 kg) and heifers (n = 13; 8 pregnant, BW 511 ± 40 kg, and 5 nonpregnant, BW 451 ± 60 kg) were individually fed chopped warm-season grass hay (5.5% CP, 67% NDF) for ad libitum intake and soybean meal (46% CP) at 450 g/d. Intake was measured daily, and DM digestibility, digesta passage rate, and plasma glucose and β-hydroxybutyrate (BHBA) concentrations were measured every 14 d from 49 d prepartum to 49 d postpartum. Prepartum DMI (% of BW) increased over time for pregnant heifers through 2 wk prepartum before declining but did not change over time for pregnant cows. Dry matter digestibility decreased with advancing gestation (P < 0.001); pregnant animals had greater digestibility than nonpregnant cows and heifers (P = 0.02). Digestibility was not influenced by age (P = 0.99). Pregnant cows and heifers had faster digesta passage rates than their nonpregnant counterparts (P = 0.02). Pregnant animals had lower plasma glucose (P < 0.001). Plasma BHBA concentrations were greater in pregnant animals than in nonpregnant animals (P < 0.001) but were not influenced by age (P = 0.27) or time prepartum (P = 0.98). Postpartum DMI (% of BW) was greater for lactating heifers than other groups (age × lactation status; P = 0.05) and increased over time (P < 0.001). Diet digestibility increased with time postpartum (P < 0.001), and heifers had greater digestibility than cows from 3 to 7 wk postpartum but not at 1 wk postpartum (age × time; P = 0.02). Postpartum passage rate was not influenced by age or lactation status (P > 0.23). Lactating animals had lower plasma glucose and greater plasma BHBA concentrations postpartum than nonlactating animals (P < 0.001). Calves from mature cows grew faster than calves from heifers (age × time; P < 0.001). These data show that although primiparous beef heifers have similar DM digestibility, passage rates, and plasma glucose and BHBA concentrations, intake patterns differ between heifers and cows. Although DMI (% of BW) and digestibility did not differ between pregnant beef heifers and pregnant mature cows, the DMI (% of BW) was greater for lactating primiparous cows (heifers) than for lactating multiparous cows. Even with their postpartum increase in DMI, primiparous beef heifers were not able to consume adequate amounts of the warm-season forage to support their requirements for maintenance, growth, and lactation.

Whole soybean supplementation and cow age class: effects on intake, digestion, performance, and reproduction of beef cows

Two experiments were conducted to determine the effects of whole soybean supplementation on intake, digestion, and performance of beef cows of varying age. Treatments were arranged in a 2 x 3 factorial with 2 supplements and 3 age classes of cows (2-yr-old, 3-yr-old, and mature cows). Supplements (DM basis) included 1) 1.36 kg/d of whole raw soybeans, and 2) 1.56 kg/d of a soybean meal/hulls supplement. Supplements were formulated to provide similar amounts of protein and energy, but a greater fat content with the whole soybeans. Supplements were individually fed on Monday, Tuesday, Thursday, and Saturday mornings. During the treatment period, cows had free choice access to bermudagrass hay [Cynodon dactylon (L.) Pers.; 8.4% CP; 72% NDF; DM basis]. In Exp. 1, 166 spring-calving Angus and Angus x Hereford crossbred beef cows were individually fed supplements for an average of 80 d during mid to late gestation. During the first 50 d of supplementation, cows fed soybean meal/hulls gained more BW (10 kg; P < 0.001) and body condition (0.18 BCS units; P = 0.004) than cows fed whole soybeans. However, BW change (P = 0.87) and BCS change (P = 0.25) during the 296-d experiment were not different between supplements. Although calves from cows fed soybean meal/hulls were 2 kg heavier at birth, there was no difference in calf BW at weaning between supplements. Additionally, first service conception rate (68%; P = 0.24) and pregnancy rate (73%; P = 0.21) were not different between supplements. In Exp. 2, 24 cows from Exp. 1 were used to determine the effect of supplement composition on forage intake and digestion; cows remained on the same supplements, hay, and feeding schedule as Exp. 1. Crude fat digestibility was the only intake or digestibility measurement influenced by supplement composition; fat digestibility was higher for cows fed whole soybeans compared with cows fed the soybean meal/hulls supplement (58.1 vs. 48.8%). Hay intake and DMI averaged 1.63 and 1.92% of BW daily, respectively. Dry matter, NDF, and CP digestibility averaged 54.1, 55.1, and 63.2%, respectively. Compared with supplementation with soybean meal/ hulls, whole soybean supplementation during mid to late gestation resulted in reduced BW weight gain during supplementation, inconsistent effects on reproduction, no effect on calf weaning weight, and no effect on forage intake or digestion.