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Effects of supplementation of calcium salts of polyunsaturated fatty acids on serum concentrations of progesterone and insulin of pregnant dairy cows

Abstract

Forty-five non-lactating, pregnant Holstein animals (18 heifers and 27 multiparous cows; BW = 561±114 kg; BCS = 2.9±0.3; days pregnant = 110±56 d) were stratified by initial BW and BCS, and randomly assigned to receive daily (as-fed basis) 0.50 kg of ground corn plus 0.22 kg of kaolin (CON), calcium salts of saturated fatty acids (SFA) or polyunsaturated fatty acids (PF) for 14 d. Blood samples were collected on days 0, 7 and 14, immediately prior to (0 h) and 3, 6, 9 and 12 h after feeding, to determine the serum concentrations of P4 and insulin. No treatment effects were detected for serum concentrations of P4 (5.52, 6.13 and 5.63±0.41 ng/mL for CON, SFA and PF, respectively). No treatment effects were detected for serum concentrations of insulin (11.5, 10.5 and 10.1±1.43 µIU/mL for CON, SFA and PF, respectively). Heifers had greater serum concentrations of P4 than multiparous cows (6.35 vs. 5.16±0.42 ng/mL), but lower serum concentrations of insulin (7.0 vs. 14.4±1.49 µIU/mL). Feeding 0.22 kg of calcium salts of polyunsaturated fatty acids is not sufficient to increase the serum concentrations of P4 and insulin of non-lactating, pregnant dairy cows.

hepatic metabolism; linoleic; linolenic; PUFA


BREEDING, GENETICS AND REPRODUCTION

Effects of supplementation of calcium salts of polyunsaturated fatty acids on serum concentrations of progesterone and insulin of pregnant dairy cows

Philipe MorielI; Bruno Ieda CappellozzaI; Luiz Felipe FerrarettoI; Augusto Cossolino AboinI; Fernanda Victor Rodrigues VieiraI; Ricardo de Oliveira RodriguesI; Reinaldo Fernandes CookeII; José Luiz Moraes VasconcelosI

IDepartamento de Produção Animal, Faculdade de Medicina Veterinária e Zootecnia, Universidade Estadual Paulista, Botucatu, SP, Brasil

IIEastern Oregon Agricultural Research Center, Oregon State University, Burns, OR, USA

ABSTRACT

Forty-five non-lactating, pregnant Holstein animals (18 heifers and 27 multiparous cows; BW = 561±114 kg; BCS = 2.9±0.3; days pregnant = 110±56 d) were stratified by initial BW and BCS, and randomly assigned to receive daily (as-fed basis) 0.50 kg of ground corn plus 0.22 kg of kaolin (CON), calcium salts of saturated fatty acids (SFA) or polyunsaturated fatty acids (PF) for 14 d. Blood samples were collected on days 0, 7 and 14, immediately prior to (0 h) and 3, 6, 9 and 12 h after feeding, to determine the serum concentrations of P4 and insulin. No treatment effects were detected for serum concentrations of P4 (5.52, 6.13 and 5.63±0.41 ng/mL for CON, SFA and PF, respectively). No treatment effects were detected for serum concentrations of insulin (11.5, 10.5 and 10.1±1.43 µIU/mL for CON, SFA and PF, respectively). Heifers had greater serum concentrations of P4 than multiparous cows (6.35 vs. 5.16±0.42 ng/mL), but lower serum concentrations of insulin (7.0 vs. 14.4±1.49 µIU/mL). Feeding 0.22 kg of calcium salts of polyunsaturated fatty acids is not sufficient to increase the serum concentrations of P4 and insulin of non-lactating, pregnant dairy cows.

Key Words: hepatic metabolism, linoleic, linolenic, PUFA

Introduction

Polyunsaturated fatty acids (PUFA), such as linoleic (LA) and linolenic (LNA) acids have been associated with enhanced reproduction of dairy and beef cows (Staples et al., 1998; Lopes et al., 2009, 2011). The mechanisms by which calcium salts of PUFA may decrease pregnancy loss include: 1) increased circulating progesterone (P4) concentrations (Stronge et al., 2005; Demetrio et al., 2007); 2) reduced PGFsynthesis and luteolysis (Williams and Stanko, 2000); and 3) enhanced maternal recognition of pregnancy (Wathes et al., 2007). Linoleic acid is a precursor for the synthesis of arachidonic acid, which may increase mitochondrial uptake of cholesterol (Stocco and Clark, 1996), and thus, increase P4 synthesis (Grummer and Carroll, 1991). Also, PUFA supplementation may decrease the hepatic metabolism of P4 (Hawkins et al., 1995). However, limited information exists regarding the effects of relatively small amounts of PUFA supplementation on circulating concentrations of P4 in dairy cows (Reis et al., 2012). Polyunsaturated fatty acids may be partitioned into different locations (e.g. body tissue, milk, and embryo), depending on the priority of the metabolism (Hess et al., 2008). Thus, it is not known if relatively small amounts of PUFA may increase the circulating concentrations of P4 by increasing the synthesis of P4 and/or decreasing the hepatic metabolism of P4.

Circulating concentrations of insulin usually reflect energy intake of cattle (Staples et al., 1998). Cows with greater serum concentrations of insulin had greater serum concentrations of P4 compared with cows having lower serum concentrations of insulin (Moriel et al., 2008; Lopes et al., 2009). Williams and Stanko (2000) reported that cows supplemented with PUFA had greater circulating insulin concentrations when compared with nonsupplemented cohorts. The mechanisms by which insulin concentrations may affect P4 concentrations include enhanced synthesis of P4 through steroidogenesis (Butler et al., 2004), and reduced hepatic expression of P4 catabolic enzymes P450 2C and 3A (Lemley et al., 2008; Vieira et al., 2013).

Based on this information, it was hypothesized that supplementation of calcium salts of PUFA would increase serum concentrations of P4 and insulin due to an increased P4 synthesis and/or decreased hepatic metabolism of P4. Thus, the objectives were to evaluate the effects of supplementing relatively small amounts of calcium salts of PUFA on serum concentrations of P4 and insulin of dairy cows.

Material and Methods

The study was conducted at a commercial dairy farm (Fazenda Globo), located in Borebi, São Paulo, Brazil. The animals utilized in these experiments were cared for in accordance with acceptable practices as outlined in the Guide for the Care and Use of Agricultural Animals in Agricultural Research and Teaching (FASS, 1999).

This experiment was designed to evaluate the effects of calcium salts of PUFA on serum concentrations of P4 and insulin in non-lactating, pregnant cows.Thisanimal category was selected to avoid the partitioning of supplemented FA into milk, which could decrease the PUFA availability for body metabolism. Furthermore, the laboratory utilized ovariectomized cows inserted with an intravaginal device containing P4 as the model for evaluating P4 metabolism (Moriel et al., 2008; Lopes et al., 2009). However, because the experiment was conducted at a commercial dairy farm, ovariectomized cows were not an option. Thus, pregnant cows at later stages of pregnancy were selected in order to have a constant supply of P4 (e.g. corpus luteum-and placenta-derived P4), and hence, have a clearer picture of potentialeffectsof PUFAsupplementationon P4metabolism. Forty-five Holstein animals (18 heifers and 27 multiparous cows; BW = 561±114 kg; BCS = 2.9±0.3; days pregnant = 110±56 d) were stratified by initial BW and BCS (Wildman et al., 1982). Cows were randomly assigned to receive individual daily (as-fed basis) supplementation of 0.50 kg of finely ground corn plus 0.22 kg of kaolin (a rumen-inert indigestible substance; CON), calcium salts of saturated fatty acids (SFA; Megalac®; Arm & Hammer Animal Nutrition, Division of Church & Dwight Co.; Inc.), or calcium salts of polyunsaturated fatty acids (PF; Megalac-E®; Quimica Geral do Nordeste, Rio de Janeiro, Brazil) (Table 1) for 14 d. The SFA treatment was included as an iso-lipidic, iso-caloric, and iso-nitrogenous control treatment relative to PF. Also, a supplementation period of 14 d was utilized based on previous findings (Lopes et al., 2009, 2011) observing positive effects of PUFA supplementation on reproductive performance of beef cows. Treatments were top-dressed daily (07.00 hours) and individually. Cows were offered free choice access to a corn silage-based diet (Table 2), in a dry lot facility with free access to Tifton (Cynodon spp) pastures for 14 d. Cows had free access to water throughout the experiment.

Blood samples were collected on days 0, 7 and 14, immediately prior to (0 h), and 3, 6, 9 and 12 h after the morning supplement feeding, for determination of serum concentrations of P4 and insulin. Blood was collected from the coccygeal vein or artery into commercial blood collection tubes (Vacutainer, 10 mL; Becton Dickinson, Franklin Lakes, NJ), placed on ice immediately and centrifuged at 1500 × g for 30 min for serum collection. Harvested serum was stored frozen at -20 ºC until laboratory analysis.

Serum concentrations of P4 and insulin were determined using a Coat-A-Count Kit (DPC Diagnostic Products Inc.; Los Angeles, CA) solid phase 125I RIA, previously validated for cattle (Moriel et al., 2008). The intra-and inter-assay CV were 1.8 and 0.1% for P4, and 10.3 and 7.4% for insulin, respectively.

Blood measurements were analyzed as repeated measures using the MIXED procedure of SAS (Statistical Analysis System, version 9.2). The model statement contained the effects of treatment, time, day, parity and the resultant interactions. Cow (treatment × parity) was included as a random variable and error term for the tests of fixed effects. Cow (treatment × parity × day) was included as the subject in the repeated statement. The criterion for choosing the covariance structure was the one with the lowest Akaike information criterion. The autoregressive covariance structure was used for both serum variables. Satterthwaite approximation was used to determine the denominator degrees of freedom for all the tests of fixed effects. Means were separated using PDIFF in all experiments. Significance was set at P<0.05, and tendencies were determined if P>0.05 and <0.10.

For comparison of P4 concentrations in cows with insulin above or below the median before feeding, data were analyzed with the UNIVARIATE procedure of SAS for median determination and the MIXED procedure of SAS to determine insulin effects on P4 concentrations. The model statement for this analysis contained the effects of insulin (above or below median), time, and the resultant interaction. For the analysis of insulin concentrations within each group, the model statement included only the effects of time. Period was the random variable and error term for the tests of fixed effect for both analyses within each group. Cow (period) was used as the subject in the repeated statement. Following the same criterion for choosing the covariance structure as mentioned above, the compound symmetry covariance structure was used in all analyses. Satterthwaite approximation was used to determine the denominator degrees of freedom for all the tests of fixed effects. Significance was set at P<0.05, tendencies were determined if P>0.05 and P<0.10. Results are reported according to main effects if no interactions were significant, or according to the highest-order interaction detected.

Results

Dietary treatments did not affect (P>0.52) the overall serum concentrations of P4 and insulin (Table 3). Time effects were detected (P<0.01; Figure 1) for serum concentrations of P4 and insulin. Serum P4 concentrations decreased from 0 (6.09 ng/mL; SEM = 0.25) to 3 h (5.73 ng/mL; SEM = 0.25), but remained unaltered from 3 to 12 h (5.60 ng/mL; SEM = 0.25) after feeding the supplements. Serum concentrations of insulin peaked at 3 h (12.51 µIU/mL; SEM = 0.93), but decreased 12 h after supplements were offered (7.69 µIU/mL; SEM = 0.98).


Aparity effect was detected (P = 0.04; Table 4) for serum P4 concentrations. Heifers had greater serum concentrations of P4 compared with multiparous cows (6.35 vs. 5.16 ng/mL, respectively; SEM = 0.42). Similarly, a parity effect (P<0.001; Ta ble 4) was detected on serum concentrations of insulin because multiparous cows had greater (P<0.01) insulin concentrations (14.4 µIU/mL; SEM = 1.08) than heifers (7.0 µIU/mL; SEM = 1.49).

For comparison of serum P4 concentrations according to serum insulin concentrations, the results within each group were combined and separated by cows having serum concentrations of insulin above or below the median (10.41 µIU/mL) immediately before the morning feeding. Cows having insulin concentrations above the median had similar (P = 0.15) mean concentrations of P4 compared with cows having insulin concentrations below the median (5.64 vs. 5.87 ng/mL, respectively; SEM = 0.25; Figure 2). There was a tendency for treatment × time effect (P = 0.06) on serum concentrations of P4. Cows having insulin concentrations above the median had lower (P<0.01) concentrations of P4 12 h after the supplements were offered compared with cows having insulin concentrations below the median (5.14 vs. 5.84 ng/mL, respectively; SEM = 0.25).


Discussion

Polyunsaturated fatty acids play an important role on stimulation and inhibition of prostaglandin production (Staples et al., 1998), affecting ovary function and follicular development (Thatcher et al., 2004), improving the oocyte quality (Fouladi-Nashta et al., 2007), and increasing the first-service conception rate (Thatcher et al., 2006; Lopes et al., 2009). Although there is evidence that feeding fatty acids improved the energy status of lactating dairy cows (Staples et al., 1998), an enhanced reproductive performance may occur apart from an improved energy status of the animals (Sklan et al., 1991). In agreement, Reis et al. (2012) reported that feeding calcium salts of polyunsaturated fatty acids (PUFA) at 1.1% of diet DM to lactating dairy cows did not affect DM or energy intake, but decreased pregnancy losses compared with control cows that did not receive PUFA supplementation.

Adding calcium soaps of FA to the diet increased serum concentrations of P4 in bovine females (Hightshoe et al., 1991; Hawkins et al., 1995). Greater concentrations of P4 before and after breeding are associated with enhanced fertility (Folman et al., 1973) and embryonic survival (Mann et al., 2006). However, the present study showed no effects of feeding 0.22 kg of rumen-inert source of SFA or PUFA on serum concentrations of P4 compared with feeding a non-fat control supplement. There are several potential explanations for the outcomes of this study, including: 1) insufficient amount of PUFA to decrease the hepatic clearance of P4; 2) length of supplementation period; and 3) frequency of blood sampling.

Approximately 3 to 4 h following feeding, there is an increase in the rate of blood flow to the liver. This event leads to an increase in the metabolism of P4 by hepatic cells (Sangsritavong et al., 2002), which results in decreased concentrations of P4 after feeding (Sangsritavong et al., 2002; Vasconcelos et al., 2003). This response was observed in the present study, since all treatments had a decrease in P4 concentrations at approximately 3 to 4 h following feeding (Figure 1). Hepatic clearance of P4 may be diminished by adding PUFAto the diet. Sangsritavong et al. (2002) reported increased hepatic P4-half life, and decreased clearance of P4 in non-lactating dairy cows infused with an emulsion of soybean oil. Piccinato et al. (2010) reported decreased hepatic clearance of P4 in vitro when concentrations of LNA were 100 to 300 µM. However, plasma concentrations of P4 did not increase after in vivo infusions of 490 mL of linseed oil (56% LNA and 16.4% LA) in lactating dairy cows. Those authors concluded that the plasma concentrations of LNA (less than 8 µM) after the linseed oil infusions were not sufficient to inhibit the key enzymes responsible for P4 metabolism (P450 2C and P450 3A) and thus, did not decrease hepatic clearance of P4. Hawkins et al. (1995) reported increased serum concentrations of P4 in pregnant heifers when calcium salts of FA were fed at 0.57 kg/heifer daily. Fouladi-Nashta et al. (2007) only observed a tendency for greater P4 concentrations when lactating dairy cows were fed 0.80 kg/d of calcium salts of FA compared with 0.20 kg/d. The results of the present study are in agreement with Lopes et al. (2009) and Reis et al. (2012), who did not observe increase in serum P4 concentrations by adding calcium salts of PUFA at approximately 0.20 kg/cow daily. Taking these results together, it is possible that adding 0.22 kg of PF did not result in sufficient amounts of PUFA to decrease the hepatic clearance of P4.

Duration of the supplementation period is another potential reason for the discrepancy between the results of the present study and others (Hightshoe et al., 1991; Hawkins et al., 1995). In the present study, a supplementation period of 14 d was used based on previous studies from our laboratory (Lopes et al., 2009, 2011). Hawkins et al. (1995) fed calcium salts of FA to pregnant heifers starting 100 d before parturition through day 12 of the third estrus cycle. Hightshoe et al. (1991) fed calcium salts of FA to multiparous beef cows from parturition throughout the second postpartum ovulation. Therefore, it is possible that longer periods of fat supplementation are required to potentially increase circulating concentrations of P4.

In contrast to the results of the present study, Lopes et al. (2009) reported greater concentrations of P4 when ovariectomized cows were fed 0.10 kg/d of rumen-inert PUFA (39.8% LA) compared with feeding a non-fat control supplement, but no effect on P4 concentrations when same rumen-inert PUFA were provided at 0.20 kg/d. The reason for 0.10 kg/d of rumen-inert PUFA resulting in greater concentrations of P4 in the study of Lopes et al. (2009) remains unclear. The less frequent blood sampling in the present study could be one of the reasons for the lack of differences detected in the circulating serum concentrations of P4. Hawkins et al. (1995) collected blood samples at -60, -30 and 0 min before ovariectomy and 15, 30, 45, 60, 90 and 120 min after ovariectomy. Thereafter, blood samples were collected hourly for 5 h, and every other hour for an additional 6 h. Lopes et al. (2009) collected blood samples immediately before feeding (0 h), and 2, 4, 6, 8, 10 and 12 h after feeding. A more frequent blood sampling could have increased the chances of detecting treatment effects on circulating concentrations of P4.

Although Piccinato et al. (2010) demonstrated that different concentrations of palmitic (16:0), palmitoleic (16:1), oleic (18:1) and LNA (18:3) inhibited the in vitro metabolism of P4, the concentrations of each FA required to inhibit the hepatic clearance of P4 represents supraphysiological concentrations if utilized in in vivo studies. Therefore, the relative contribution of FA (other than LNA and LA) can be considered inexistent due to the small amount of calcium salts of FA provided in this study (0.22 kg/cow daily).

The effects of fat supplementation on insulin concentrations are varied, showing increase (Blum et al., 1985; Reis et al., 2012), no effect (Fouladi-Nashta et al., 2007; Reis et al., 2012), and decrease in concentrations of insulin after fat supplementation (Relling and Reynolds, 2007). Insulin concentrations reflect energy intake, and therefore, differences in insulin concentrations can be due to differences in energy status (Lucy et al., 1991). In the present study, no effects of rumen-inert PUFA supplementation were detected on serum concentrations of insulin, which suggests that differences in DMI did not occur. Likewise, Lopes et al. (2009) did not observe differences in serum concentrations of insulin in beef cows supplemented with up to 0.20 kg/d rumen-inert PUFA. Reis et al. (2012) reported that adding calcium salts of PUFA (1.1% of diet DM) increased serum P4 concentrations, and tended to increase serum insulin concentrations in primiparous, but not multiparous cows, which suggests that the outcome of fat supplementation is dependent on the category of animal being used. Thus, it is possible that the lack of differences detected in serum insulin concentrations may be a result of the animal category used in the present study. Further evaluations are required to confirm this hypothesis.

Circulating concentrations of P4 are highly affected by feed intake (Vasconcelos et al., 2003; Cooke et al., 2007; Moriel et al., 2008). The concentration of insulin peaked 3 h after feeding, whereas those of P4 decreased after feeding (Figure 1). The time effects detected for P4 concentrations were similar to previous reports (Vasconcelos et al., 2003; Cooke et al., 2007; Moriel et al., 2008). In the present study, pregnant heifers had greater serum concentrations of P4 compared with pregnant mature cows. In agreement with these results, heifers had greater serum concentrations of P4 from days 5 to 12 of the estrus cycle compared with lactating cows, despite their lower luteal volume on day 14 of the estrus cycle (Wiltbank et al., 2001). Sangsritavong et al. (2002) reported similar absolute increase in liver blood flow (LBF) of lactating and non-lactating dairy cows. However, as a percentage of basal LBF, non-lactating cows had greater increase in LBF compared with lactating cows, probably due to the lower basal LBF. Although the DMI of non-lactating pregnant heifers and cows estimated by the NRC (2001) are similar (as a percentage of BW; 2.0% of BW), the absolute amount of feed intake is lower for heifers than non-lactating cows. Thus, it is possible that LBF in nonlactating multiparous cows was greater (as a percentage of basal LBF), which consequently may have increased hepatic clearance of P4 and reduced P4 concentrations compared with heifers. However, further evaluation is required to confirm this hypothesis. In addition, although DMI was not measured in this study, greater DMI of non-lactating cows would also suggest greater energy intake and likely greater insulin concentration.

Previous results from our laboratory have shown that peripheral concentrations of insulin potentially modulates the hepatic metabolism of P4 (Moriel et al., 2008; Lopes et al., 2009; Vieira et al., 2010, 2013). Elevated insulin concentrations reduced hepatic expression of P4 catabolic enzymes P450 2C and P450 3A (Lemley et al., 2008; Vieira et al., 2013), which may further increase circulating concentrations of P4 (Moriel et al., 2008; Lopes et al., 2009; Vieira et al., 2010). Accordingly, Vieira et al. (2013) reported that dairy cows in adequate nutritional status receiving jugular glucose infusion (3 h at a rate of 0.5 g/kg of BW) had greater circulating insulin concentrations and reduced hepatic mRNA expression of P4 catabolic enzymes CYP2C19 and CYP3A4 compared with cohorts receiving saline infusion. Butler et al. (2003) observed that hepatic clearance of P4 is reduced linearly after increasing amounts of insulin infusion. Therefore, it is possible that there is a minimum amount of insulin required to reduce the hepatic clearance of P4. In agreement with this hypothesis, Reis et al. (2012) reported that adding calcium salts of PUFA (1.1% of diet DM) increased serum P4 concentrations, and tended to increase serum insulin concentrations in primiparous, but not multiparous cows. In the present study, there was a tendency (Figure 2) for lower serum concentrations of P4 in cows having serum insulin concentrations greater than the median. Moriel et al. (2008) also reported that cows with insulin concentrations above the median experienced a more severe decrease in P4 concentrations 5 h after feeding. Those authors attributed this response to increased rumen fermentation, propionate production, and subsequent glucose synthesis, which likely caused the initial elevated concentrations of insulin concentrations but also enhanced hepatic blood flow after feeding. Thus, the increased metabolism of P4 likely overrides a potential inhibitory effect of insulin on P4 catabolism (Moriel et al., 2008).

Conclusions

Supplementation of relatively small amounts of calcium salts of PUFA (0.22 kg) is not sufficient to enhance the serum P4 or insulin concentrations of non-lactating, pregnant dairy cows. However, increasing the serum insulin concentrations seems to augment serum concentrations of P4. Therefore, better understanding of how nutritional management can affect insulin synthesis and the rate of hepatic P4 metabolism may improve reproductive efficiency in dairy herds, but further evaluations are required.

Received May 9, 2012 and accepted September 20, 2013.

Corresponding author: gutoaboin@hotmail.com

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Publication Dates

  • Publication in this collection
    13 Jan 2014
  • Date of issue
    Jan 2014

History

  • Received
    09 May 2012
  • Accepted
    20 Sept 2013
Sociedade Brasileira de Zootecnia Universidade Federal de Viçosa / Departamento de Zootecnia, 36570-900 Viçosa MG Brazil, Tel.: +55 31 3612-4602, +55 31 3612-4612 - Viçosa - MG - Brazil
E-mail: rbz@sbz.org.br