Carolina Bespalhok Jacometo

Overfeeding Dairy Cattle During Late-Pregnancy Alters Hepatic PPARα-Regulated Pathways Including Hepatokines: Impact on Metabolism and Peripheral Insulin Sensitivity

Hepatic metabolic gene networks were studied in dairy cattle fed control (CON, 1.34 Mcal/kg) or higher energy (overfed (OVE), 1.62 Mcal/kg) diets during the last 45 days of pregnancy. A total of 57 target genes encompassing PPARα-targets/co-regulators, hepatokines, growth hormone (GH)/insulin-like growth factor 1 (IGF-1) axis, lipogenesis, and lipoprotein metabolism were evaluated on −14, 7, 14, and 30 days around parturition. OVE versus CON cows were in more negative energy balance (NEB) postpartum and had greater serum non-esterified fatty acids (NEFA), β-hydroxybutyrate (BHBA), and liver triacylglycerol (TAG) concentrations. Milk synthesis rate did not differ. Liver from OVE cows responded to postpartal NEB by up-regulating expression of PPARα-targets in the fatty acid oxidation and ketogenesis pathways, along with gluconeogenic genes. Hepatokines (fibroblast growth factor 21 (FGF21), angiopoietin-like 4 (ANGPTL4)) and apolipoprotein A-V (APOA5) were up-regulated postpartum to a greater extent in OVE than CON. OVE led to greater blood insulin prepartum, lower NEFA:insulin, and greater lipogenic gene expression suggesting insulin sensitivity was not impaired. A lack of change in APOB, MTTP, and PNPLA3 coupled with upregulation of PLIN2 postpartum in cows fed OVE contributed to TAG accumulation. Postpartal responses in NEFA and FGF21 with OVE support a role of this hepatokine in diminishing adipose insulin sensitivity.

Maternal consumption of organic trace minerals alters calf systemic and neutrophil mRNA and microRNA indicators of inflammation and oxidative stress

Organic trace mineral (ORG) supplementation to dairy cows in substitution of sulfate (INO) sources has been associated with improvement in immune function during stressful states such as the peripartal period. However, the effect of supplemental ORG during pregnancy on the neonatal calf is unknown. Therefore, our aim was to investigate the effects of ORG supplementation during late pregnancy on the immune system and growth of the neonatal calf. Of specific interest was the evaluation of inflammation-related microRNA (miRNA) and target gene expression in blood neutrophils as indicators of possible nutritional programming. Forty multiparous cows were supplemented for 30d prepartum with 40 mg/kg of Zn, 20 mg/kg of Mn, 5 mg/kg of Cu, and 1mg/kg of Co from either organic (ORG) or sulfate (INO) sources (total diet contained supplemental 75 mg/kg of Zn, 65 mg/kg of Mn, 11 mg/kg of Cu, and 1 mg/kg of Co, and additional Zn, Mn, and Co provided by sulfates), and a subset of calves (n=8/treatment) was used for blood immunometabolic marker and polymorphonuclear leukocyte (PMNL) gene and miRNA expression analyses. Samples were collected at birth (before colostrum feeding), 1d (24 h after colostrum intake), and 7 and 21d of age. Data were analyzed as a factorial design with the PROC MIXED procedure of SAS. No differences were detected in BW, but maternal ORG tended to increase calf withers height. Calves from INO-fed cows had greater concentrations of blood glucose, GOT, paraoxonase, myeloperoxidase, and reactive oxygen metabolites. Antioxidant capacity also was greater in INO calves. The PMNL expression of toll-like receptor pathway genes indicated a pro-inflammatory state in INO calves, with greater expression of the inflammatory mediators MYD88, IRAK1, TRAF6, NFKB, and NFKBIA. The lower expression of miR-155 and miR-125b in ORG calves indicated the potential for maternal organic trace minerals in regulating the PMNL inflammatory response at least via alterations in mRNA and miRNA expression. Overall, these results indicate that maternal nutrition with organic trace minerals could alter the neonatal innate immune response at least in part via changes in gene and miRNA expression. Further studies involving inflammatory challenges during the neonatal period should be performed to determine the functional benefit of maternal organic trace minerals on the neonatal immune response.

Hepatic global DNA and peroxisome proliferator-activated receptor alpha promoter methylation are altered in peripartal dairy cows fed rumen-protected methionine

The availability of Met in metabolizable protein (MP) of a wide range of diets for dairy cows is low. During late pregnancy and early lactation, in particular, suboptimal Met in MP limits its use for mammary and liver metabolism and also for the synthesis of S-adenosylmethionine, which is essential for many biological processes, including DNA methylation. The latter is an epigenetic modification involved in the regulation of gene expression, hence, tissue function. Thirty-nine Holstein cows were fed throughout the peripartal period (-21 d to 30 d in milk) a basal control (CON) diet (n=14) with no Met supplementation, CON plus MetaSmart (MS; Adisseo NA, Alpharetta, GA; n=12), or CON plus Smartamine M (SM; Adisseo NA; n=13). The total mixed ration dry matter for the close-up and lactation diets was measured weekly, then the Met supplements were adjusted daily and top-dressed over the total mixed ration at a rate of 0.19 (MS) or 0.07% (SM) on a dry matter basis. Liver tissue was collected on -10, 7, and 21 d for global DNA and peroxisome proliferator-activated receptor alpha (PPARα) promoter region-specific methylation. Several PPARα target and putative target genes associated with carnitine synthesis and uptake, fatty acid metabolism, hepatokines, and carbohydrate metabolism were also studied. Data were analyzed using PROC MIXED of SAS (SAS Institute Inc., Cary, NC) with the preplanned contrast CON versus SM + MS. Global hepatic DNA methylation on d 21 postpartum was lower in Met-supplemented cows than CON. However, of 2 primers used encompassing 4 to 12 CpG sites in the promoter region of bovine PPARA, greater methylation occurred in the region encompassing -1,538 to -1,418 from the transcription start site in cows supplemented with Met. Overall expression of PPARA was greater in Met-supplemented cows than CON. Concomitantly, PPARA-target genes, such as ANGPTL4, FGF21, and PCK1, were also upregulated overall by Met supplementation. The upregulation of PPARα target genes indicates that supplemental Met, likely through the synthesis of S-adenosylmethionine, activated PPARA-regulated signaling pathways. Upregulation of hepatic PPARA has been associated with improved lipid metabolism and immune function, both of which were reported in companion publications from this study. In turn, those positive effects resulted in improved postpartal health and performance. Further research is needed to study more closely the mechanistic connections between global DNA and promoter region-specific PPARA methylation with PPARA expression and functional outcomes in liver.

Maternal rumen-protected methionine supplementation and its effect on blood and liver biomarkers of energy metabolism, inflammation, and oxidative stress in neonatal Holstein calves

In nonruminants, nutrition during pregnancy can program offspring development, metabolism, and health in later life. Rumen-protected Met (RPM) supplementation during the prepartum period improves liver function and immune response in dairy cows. Our aim was to investigate the effects of RPM during late pregnancy on blood biomarkers (23 targets) and the liver transcriptome (24 genes) in neonatal calves from cows fed RPM at 0.08% of diet dry matter/d (MET) for the last 21 d before calving or controls (CON). Blood (n=12 calves per diet) was collected at birth before receiving colostrum (baseline), 24 h after receiving colostrum, 14, 28, and 50 d (post-weaning) of age. Liver was sampled (n=8 calves per diet) via biopsy on d 4, 14, 28, and 50 of age. Growth and health were not affected by maternal diet. The MET calves had greater overall plasma insulin concentration and lower glucose and ratios of glucose-to-insulin and fatty acids-to-insulin, indicating greater systemic insulin sensitivity. Lower concentration of reactive oxygen metabolites at 14 d of age along with a tendency for lower overall concentration of ceruloplasmin in MET calves indicated a lesser degree of stress. Greater expression on d 4 of fructose-bisphosphatase 1 (FBP1), phosphoenolpyruvate carboxykinase 1 (PCK1), and the facilitated bidirectional glucose transporter SLC2A2 in MET calves indicated alterations in gluconeogenesis and glucose uptake and release. The data agree with the greater expression of the glucocorticoid receptor (GR). Greater expression on d 4 of the insulin receptor (INSR) and insulin-responsive serine/threonine-protein kinase (AKT2) in MET calves indicated alterations in insulin signaling. In that context, the similar expression of sterol regulatory element-binding transcription factor 1 (SREBF1) in CON and MET during the preweaning period followed by the marked upregulation regardless of diet after weaning (d 50) support the idea of changes in hepatic insulin sensitivity during early postnatal life. Expression of carnitine palmitoyltransferase 1A (CPT1A) was overall greater and acyl-CoA oxidase 1 (ACOX1) was lower in MET calves, indicating alterations in fatty acid oxidation. Except forkhead box O1 (FOXO1), all genes changed in expression over time. Transcriptome results indicated that calves from MET-supplemented cows underwent a faster maturation of gluconeogenesis and fatty acid oxidation in the liver, which would be advantageous for adapting to the metabolic demands of extrauterine life.

Microsatellite analysis of pacu broodstocks used in the stocking program of Paranapanema River, Brazil

Monitoring the genetic diversity has fundamental importance for fish stocking programs. This experiment aims to evaluate the genetic diversity in two hatchery stations (A and B) with pacu Piaractus mesopotamicus (Holmberg, 1887) in Andira, state of Parana, Brazil used in stocking programs of Paranapanema River. Six microsatellite loci were amplified using DNA extracted from 60 fin-clipping samples. The broodstock B had the average number of alleles and the mean heterozygosity (alleles: 3.7 and HO: 0.628) higher than the broodstock A (alleles: 3.5 and HO: 0.600). Alleles with low frequency levels were observed in the both broodstocks. The positive coefficients of endogamy in the locus Pme2 (broodstock A: FIS = 0.30 and broodstock B: FIS = 0.20), Pme5 (broodstock B: FIS = 0.15), Pme14 (broodstock A: FIS = 0.07) and Pme28 (broodstock A: FIS = 0.24 and broodstock B: FIS = 0.20) indicated deficiency of heterozygotes. Presence of null allele in the locus Pme2 was detected. The negative estimates in loci Pme4 (broodstock A: FIS = - 0.43 and broodstock B: FIS = - 0.37), Pme5 (broodstock A: FIS= - 0.11), Pme14 (broodstock B: FIS= - 0.15) and Pme32 (broodstock A: FIS = - 0.93 and broodstock B: FIS = - 0.60) were indicating the excess of heterozygotes. Evidence of linkage disequilibrium and lower allelic richness was found only in the broodstock A. Neis gene diversity was high in both broodstocks. The genetic distance (0.085) and identity (0.918) showed similarity between broodstocks, which reflects a possible common origin. 6.05% of the total genetic variance was due to differences among broodstocks. Recent bottleneck effect in two broodstocks was observed. The results indicated a higher genetic diversity in the two broodstocks and they presented low genetic difference. This was caused by the reproductive management in both hatchery stations, reduction of population size and genetic exchange between the hatchery stations.

Supplementation with rumen-protected methionine or choline during the transition period influences whole-blood immune response in periparturient dairy cows

Methionine, together with Lys, is the most limiting AA for milk production in dairy cows. Besides its crucial role in milk production, Met and its derivate metabolites (e.g., glutathione, taurine, polyamines) are well-known immunonutrients in nonruminants, helping support and boost immune function and activity. In the present study, the effects of Met or choline, as its precursor, were investigated using an ex vivo whole blood challenge. The study involved 33 multiparous Holstein cows (from a larger cohort with a factorial arrangement of treatments) assigned from d -21 to +30 relative to parturition to a basal control (CON) diet, CON plus rumen-protected Met (MET, Smartamine M, Adisseo NA, Alpharetta, GA) at a rate of 0.08% of dry matter, or CON plus rumen-protected choline (CHOL, ReaShure, Balchem Inc., New Hampton, NY) at 60 g/d. Blood was sampled on d -15, -7, 2, 7, and 20 for ex vivo lipopolysaccharide (LPS) challenge, and on d 1, 4, 14, and 28 relative to parturition for phagocytosis and oxidative burst assays. The MET cows had greater energy-corrected milk production and milk protein content. Overall, IL-6 response to LPS increased around parturition, whereas IL-1β remained constant, casting doubt on the existence of systemic immunosuppression in the peripartal period. Supplementation with MET dampened the postpartal blood response to LPS (lower IL-1β), while improving postpartum neutrophil and monocyte phagocytosis capacity and oxidative burst activity. In contrast, CHOL supplementation increased monocyte phagocytosis capacity. Overall, the data revealed a peripartal immune hyper-response, which appeared to have been mitigated by MET supplementation. Both MET and CHOL effectively improved immune function; however, MET affected the immune and antioxidant status before parturition, which might have been beneficial to prepare the cow to respond to metabolic challenges after parturition. These results provide insights on potential differences in the immunomodulatory action of methionine and choline in dairy cows. As such, the effects observed could have implications for ration formulation and dietary strategies.

Diversidade genética de dourado utilizado em programas de repovoamento no rio Paranapanema

The objective of this work was to estimate by RAPD markers the genetic diversity of a Salminus brasiliensis lot used in stock enhancement programs in the Paranapanema River, Parana, Brazil. Ten broodstocks (five males and five females) and their progeny (40 larvae and 40 fingerlings) were analyzed. Eight analyzed primers produced 96 fragments, of which 81.2% were polymorphic. There was significant difference in the frequency of 32 out of the 96 fragments, with the presence of an exclusive fragment in the fingerlings. The Shannon index, the percentage of polymorphic fragments, and the genetic distance and identity showed less genetic divergence between broodstocks and larvae, besides a decrease of genetic variability in the fingerlings. Genetic divergence was lower in the fingerlings in comparison to the larvae and broodstocks. The molecular variance results showed that most of the genetic variation is within (90.05%) and not between groups (9.95%). The broodstock lot has high genetic variability, and genetic differences were observed between the larval and fingerling stages.

Maternal supply of methionine during late pregnancy is associated with changes in immune function and abundance of microRNA and mRNA in Holstein calf polymorphonuclear leukocytes

Pregnancy and early life are critical periods during which environmental factors such as nutrition can affect development. Rumen-protected methionine (Met; RPM) supplementation during the prepartum period improves not only performance but immune responses in dairy cows. We investigated the effects of enhanced maternal supply of Met via feeding RPM on whole-blood in vitro lipopolysaccharide (LPS; 0, 0.01, or 5 μg/mL of blood) challenge and targeted microRNA and mRNA abundance in calf blood polymorphonuclear leukocytes (PMNL). Calves (n = 12/maternal diet) born to cows fed RPM at 0.08% of diet dry matter (DM)/d (MET) for the last 21 ± 2 d before calving or fed a control diet with no added Met (CON) were used. The PMNL were isolated at birth (before colostrum feeding) and d 1 (24 h after colostrum intake), 14, 28, and 50 of age. Maternal blood was collected at -10 ± 1.3 d relative to calving. Cows in the MET group had greater DM intake and lower prepartal haptoglobin concentration. In CON cows, haptoglobin was positively correlated with proinflammatory and host-defense mRNA abundance in CON calves. Except for NOS2 and NFE2L2, abundance of CASP8, MPO, ZBP1, and TNF was lower at birth in MET calves. Interleukin 1β concentration in response to LPS challenge in CON and MET calves was greatest at birth, underscoring the role of this cytokine for lymphocyte activation. Compared with 1 d of age, the interleukin-1β response to incremental doses of LPS was greater at 14 through 28 d, suggesting that the neonatal calf can mount a robust response to inflammatory stimuli. Greater abundance in CON calves of NOS2, CADM1, and TLR2 coupled with lower SELL from 1 through 50 d of age suggested a chronic activation of the PMNL. There was a marked upregulation over time of MIR125b, MIR146a, MIR155, and MIR9 in both CON and MET calves, suggesting that these microRNA could affect gene transcription associated with differentiation and inflammatory function in PMNL. Regardless of maternal diet, the gradual downregulation of MIR223 (the most abundant microRNA in PMNL) is in line with the progressive increase over time in the proinflammatory signature of the PMNL. Data revealed the potential for maternal supply of Met during late pregnancy through either greater DM intake or Met to elicit some changes in PMNL function during early postnatal life, partly through changes in mRNA expression encompassing cell adhesion and chemotaxis, oxidative stress, Toll-like receptor signaling, and Met metabolism.

Diets Rich in Polyunsaturated Fatty Acids With Different Omega-6/Omega-3 Ratio Decrease Liver Content of Saturated Fatty Acids Across Generations of Wistar Rats

Our study evaluated how the consumption of diets with low (LOW group - 0.4/1) or high (CON group - 13.6/1) omega-6/omega-3 ratio across generations (F1 and F2) can modulate liver fatty acid (FA) profile and blood biomarkers. Liver content of α-linolenic acid was higher in animals always fed with LOW diet than animals that changed from CON to LOW diet, which by your time was higher than animals always fed with CON diet. Liver saturated FA concentration decreased in both groups from F1 to F2. In conclusion, both diets were efficient in decreasing the saturated FA liver content across generations, the LOW ratio diet was more effective in reducing blood triglycerides and non-esterified fatty acids, and there was a multigenerational effect of the LOW ratio diet, improving the FA profile even when the offspring start receiving the CON diet.