Hostname: page-component-848d4c4894-pftt2 Total loading time: 0 Render date: 2024-05-16T16:13:51.429Z Has data issue: false hasContentIssue false
  • English
  • Français

Essential oil supplementation in milk replacers: short- and long-term impacts on feed efficiency, the faecal microbiota and the plasma metabolome in dairy calves

Published online by Cambridge University Press:  02 April 2024

Sonia Andrés Open the ORCID record for Sonia Andrés [Opens in a new window] ,
Chiara Gini ,
Fabrizio Ceciliani ,
Daniel Gutiérrez-Expósito ,
Noive Arteche-Villasol ,
Alba Martín ,
Paola Cremonesi ,
Fiorenza Faré ,
Morteza Hosseini Ghaffari  and
F. Javier Giráldez
...Show all authors
Sonia Andrés*
Affiliation:
Instituto de Ganadería de Montaña (CSIC-Universidad de León), León, Spain
Chiara Gini
Affiliation:
Department of Veterinary Medicine and Animal Sciences, Università degli Studi di Milano, Lodi, Italy
Fabrizio Ceciliani
Affiliation:
Department of Veterinary Medicine and Animal Sciences, Università degli Studi di Milano, Lodi, Italy
Daniel Gutiérrez-Expósito
Affiliation:
Instituto de Ganadería de Montaña (CSIC-Universidad de León), León, Spain Departamento de Sanidad Animal, Facultad de Veterinaria, Universidad de León, León, Spain
Noive Arteche-Villasol
Affiliation:
Instituto de Ganadería de Montaña (CSIC-Universidad de León), León, Spain Departamento de Sanidad Animal, Facultad de Veterinaria, Universidad de León, León, Spain
Alba Martín
Affiliation:
Instituto de Ganadería de Montaña (CSIC-Universidad de León), León, Spain
Paola Cremonesi
Affiliation:
Department of Bioinformatics, Biostatistics, Genomics, Institute of Agricultural Biology and Biotechnology, IBBA-CNR, Milano, Italy
Fiorenza Faré
Affiliation:
Department of Pharmacological and Biomolecular Sciences, Università degli Studi di Milano, Milano, Italy
Morteza Hosseini Ghaffari
Affiliation:
Institute for Animal Science Physiology Unit, Rheinische Friedrich-Wilhelms-Universität Bonn, Bonn, Germany
F. Javier Giráldez
Affiliation:
Instituto de Ganadería de Montaña (CSIC-Universidad de León), León, Spain
Latifa Abdennebi-Najar
Affiliation:
Quality and Health Department, IDELE Institute, Paris, France Centre de Recherche Saint-Antoine (CRSA), Sorbonne University, Paris, France
*
Corresponding author: S. Andrés; Email: sonia.andres@eae.csic.es
Rights & Permissions [Opens in a new window]

Abstract

Early supplementation with oregano essential oil (EO) in milk replacer (MR) may improve growth, immune responses, the microbiota and the metabolome in dairy calves during pre-weaning and in adulthood. Sixteen female dairy calves (3 days of age) were divided in two groups (n = 8/group): the control group (no EO) and the EO group (0.23 ml of EO in MR during 45 days). After weaning, calves were kept in a feedlot and fed ad libitum. The animals were weighed, and blood and faecal samples were collected on days 3 (T0), 45 (T1) and 370 (T2) to measure the biochemical profile and characterise peripheral blood mononuclear cells (PBMCs; CD4+, CD8+, CD14+, CD21+ and WC1+), the metabolome and microbiota composition. The EO group only had greater average daily weight gain during the suckling (EO supplementation) period (P = 0.030). The EO group showed higher average CD14+ population (monocytes) values, a lower abundance of Ruminococcaceae UCG-014, Faecalibacterium, Blautia and Alloprevotella and increased abundances of Allistipes and Akkermansia. The modification of some metabolites in plasma, such as butyric acid, 3-indole-propionic acid and succinic acid, particularly at T1, are consistent with intestinal microbiota changes. The data suggest that early EO supplementation increases feed efficiency only during the suckling period with notable changes in the microbiota and plasma metabolome; however, not all of these changes can be considered desirable from a gut health point of view. Additional research studies is required to demonstrate that EOs are a viable natural alternative to antibiotics for improving calf growth performance and health.

Keywords

Essential oilsfeed efficiencymetabolic programmingdairymetabolomemicrobiota
Type
Original Article
Information
Journal of Developmental Origins of Health and Disease , Volume 15 , 2024 , e5
Check for updates
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press in association with The International Society for Developmental Origins of Health and Disease (DOHaD)

Introduction

Developmental programming refers to the influence of pre- and postnatal factors that affect growth and development and result in long-term consequences for the health and productivity of the animals. Early life is a susceptible window in which different factors may affect the developmental plasticity of the organism, with consequences throughout the lifespan Reference Gluckman, Hanson, Spencer and Bateson1,Reference Van Eetvelde and Opsomer2 In the past decades, nutritional events have been considered the most relevant factors driving metabolic programming and phenotypic expression in dairy cattle; thus, it has been demonstrated that milk yield potential can be negatively affected by malnutrition during the preweaning period. Reference Erickson and Kalscheur3 It has recently been hypothesised that one of the factors involved in this long-term effect is microbial gut colonisation during early life, which shapes the immune response throughout life by providing stimulatory signals that activate innate and adaptative immune responses. Reference Haase, Haghikia, Wilck, Müller and Linker4 Once established, the microbiota composition often results in permanent effects on the host’ phenotype. Therefore, the microbiota can be envisaged as a key participant in the Developmental Origins of Health and Disease. Reference Stiemsma and Michels5 Accordingly, manipulating the gut microbiome of livestock animals during early life may be an effective way to achieve long-term health benefits, thus improving feed efficiency traits. Reference Arshad, Hassan, Rehman, Huws, Cheng and Din6,Reference Fan, Kim and Liu7

Dietary administration of essential oil (EO) has shown an impact on rumen fermentation processes, including less methane production, Reference Bach, Elcoso, Escartín, Spengler and Jouve8 decreased degradation of feed protein, or increased feed efficiency via selection for or against specific groups of microorganisms in the rumen. Reference Nehme, Andrés and Pereira9,Reference Bodas, Prieto, García-González, Andrés, Giráldez and López10 The potential of EOs to modulate the gut microbiome during early life (when included in milk replacer for dairy calves) is a less-explored strategy to ‘program’ long-term effects. Pieces of evidence have revealed a promising impact on the growth, feed efficiency, nutrient digestibility and immunity of neonatal calves when supplementing a blend of EO 70 days from birth, Reference Liu, Chen and Bai11 together with increased concentrations of propionate and a higher abundance of Prevotella ruminicola. Reference Poudel, Froehlich, Casper and St-Pierre12 Targeting calves’ in early life by supplementing them with the appropriate amount of EO to increase feed efficiency and/or improve the animal’s health status would reduce antibiotic use and allow them to boost their immunity, thus preventing diseases in the adult stage. Reference Evangelista, Corrêa, Pinto and Luciano13,Reference Matté, Luciano and Evangelista14 Moreover, this strategy may provide farmers with opportunities to enhance future cattle dairy performance by paying attention to appropriate early intervention, guaranteeing efficient neonate nutrition and profitable cattle production.

The present study hypothesises that EO administration during the first 45 days of life could promote short and long-term effects on feed efficiency traits, immune status, the microbiota and the plasma metabolome when included in milk replacer (MR) for newborn dairy calves.

Material and methods

Care and use of animals

All handling practices followed the recommendations of Directive 2010/63/EU of the European Parliament, the Council on Protecting Animals used for scientific purposes, and the IGM-CSIC Animal Experimentation Committee (protocol 736/2018). The study reported in the manuscript follows the recommendations in the ARRIVE guidelines. Reference Percie du Sert, Hurst and Ahluwalia15

Animals, diets and feed efficiency measurement

CSIC conducted feeding trials using 16 female dairy calves born in the same commercial farm and selected to minimise the range of live body weight (LBW) and day of birth. These animals were separated from the cows in the first 24 hours of life and fed 3 L of colostrum daily until day 3 of life. Starting at 3 days, once housed in individual straw-bedded hutches, they were allocated to one of two groups (n = 8 per group; control and EO) balanced according to the body weight at birth. Calves were fed MR (145 g of Novilac Turbostart, Schils/L) twice a day using a bucket with a nipple (allowing the reflex closure of the oesophageal groove) until day 45. During this phase, these animals were fed daily a fixed amount of reconstituted MR (divided into two feedings, at 09:00 a.m. and 6:00 p.m.) that was gradually increased from 3 to 7 L at the same rate for all the individuals.

Moreover, the animals in the EO group were supplied daily with 0.23 ml of oregano EO, accounting for 200 mg of carvacrol (Zane Hellas 100%) diluted in the first 100 mL of MR for 45 days. No concentrates were offered, and no leftovers of MR remained during this phase, so dry matter intake was similar for all calves. All the animals were weighed at birth and on days 4, 10, 25 and 45 of life (e.g., at the end of the EO administration period) to estimate the average daily gain (ADG) and then calculate the feed-to-gain conversion rate during the suckling period.

Animals were managed in a feedlot once they reached 45 days of age using an automatic feeding machine until weaning (70 days of life) programmed to control the total amount of MR (without EO) consumed by each animal [recognised by radio frequency identification (RFID) ear tags]. Thus, the automatic feeding systems stopped delivering MR when each animal had reached a total accumulated dry matter intake of 54 kg MR. During this phase, animals were allowed access to a starter feed compound (ad libitum).

After weaning (70 days of life), all the calves were managed in the feedlot and fed with a total mixed ration (TMR-1; Barley straw, 120 g/kg; dehydrated alfalfa, 140 g/kg; concentrate, 740 g/kg) formulated (with no EO) to cover their nutritional requirements during the first post-weaning period (up to 6 months of life) and a second TMR (TMR-2, with no EO) with a higher amount of fibre during the replacement phase (6-12 months of life). Voluntary feed intake was recorded individually daily using control feed intake devices (Agrolaval S.L., Gijón, Asturias, Spain) and RFID ear tags for 70 days, starting when animals were, on average, 322 days old. Daily sampling of TMR-2 after mixing (before feeding) and sufficient mixing and subsampling to minimise sampling error was conducted. Weekly analysis of daily composited feed samples of TMR-2 supplied to dairy cows was performed for DM (ISO 6496:1999), ash (ISO 5984:2002), CP (ISO 5983:2009), amylase-treated neutral detergent fibre [(aNDF), NDF assayed with a heat-stable amylase and expressed inclusive of residual ash; Ankom Technology Corp., Macedon, NY, USA] and ADF (ADF expressed inclusive of residual ash; Ankom Technology Corp., Macedon, NY, USA). The ingredients and chemical composition of TMR-2 administered during the feed intake control period are summarised in Table 1.

Table 1. Ingredients and chemical composition (g/kg DM unless otherwise stated) of the total mixed ration (TMR-2) consumed by the heifers during the replacement phase

a Amylase-treated neutral detergent fibre.

Animals were weighed monthly during the replacement phase to measure feed efficiency traits regarding the feed-to-gain ratio and residual feed intake (RFI). Average daily weight gain (ADG, g/d) was estimated as the regression coefficient (slope) of LBW against time using the REG procedure of the SAS package (SAS Institute Inc., Cary, NC). The feed-to-gain ratio was obtained by dividing daily feed intake by the ADG (g/d). RFI was calculated using a multiple linear regression model. The DMI, ADG and mid-test metabolic body weight data (MBW, as LBW0.75) of all the calves were introduced. The statistical model used was Yi = β 0 + β 1 MBWi + β 2 ADGi + ei , where Yi represents the predicted feed intake of the i th animal; β 0 is the equation intercept; β 1, the regression coefficient on MBW; β 2, the regression coefficient on ADG and ei , the residual of the ith animal. Thus, this prediction may be considered the ‘average’ or expected value for animals of similar weights and rates of gain. The actual daily feed intake minus the predicted feed intake of each individual corresponds to the RFI, so the RFI value is inversely related to the feed efficiency.

Blood and faecal sampling

Three blood sampling times, 3 (T0), 45 (T1) days and 13 months old (T2), were planned. Blood samples were collected into glass tubes by venipuncture (tail or jugular). Tubes with no anti-coagulant were allowed to clot at room temperature and then centrifuged at 3.520 × g for 16 min at 4 °C. After that, the obtained serum samples were stored at –80 °C until use in biochemical profiling. A second blood sample was collected into tubes containing lithium-heparin, placed in iced water and centrifuged at 3.520 × g for 16 min at 4 °C. Then, plasma samples were stored at –80 °C until use in metabolomics. As explained below, a third blood sample collected into a lithium-heparin tube was used for flow cytometry analyses to measure several peripheral blood mononuclear cells (PBMCs) markers such as CD4+, CD8+, CD21+, WC1+ and CD14+.

Two sampling times for faeces [45 days (T1) and 13 months old (T2)] were planned. Faecal samples (rectal grab samples) were collected before the morning meal and stored at −80 °C until freeze-drying and use in either total apparent digestibility (T2) determination according to Keulen and Young (1997) Reference Van Keulen and Young16 or total DNA (T1 and T2) extraction as explained below.

Biochemical profile and antioxidant status

Serum samples were stored at –80 °C until used for the analysis of the biochemical profile (albumin, aspartate aminotransferase [AST/GOT], gamma-glutamyl transpeptidase [GGT], beta-hydroxybutyrate [BHB], total bilirubin, Ca, Zn, Mg, ceruloplasmin, creatine kinase, creatinine, high-density lipoprotein [HDL], low-density lipoprotein [LDL], cholesterol, glucose, insulin, non-esterified fatty acids [NEFA], triglycerides, urea, protein and globulin). The biochemical profile was measured using clinical chemistry and the turbidimetry analyser Biosystems BA400 (Biosystems S.A., Barcelona, Spain). According to the manufacturer’s instructions, superoxide dismutase activity (SOD) was assayed using a Sigma Aldrich kit (Ref. 19160).

Flow cytometry analyses on the mononuclear cell population

PBMCs were isolated from 30 mL of heparinised blood by density-gradient centrifugation with Lymphoprep (STEMCELL Technologies Cologne, Germany) as previously described elsewhere. Reference Arteche-Villasol, Benavides and Espinosa17 The resultant PBMCs were washed three times with PBS, pelleted and resuspended in supplemented RPMI1640 medium + GlutaMAX with phenol red (Gibco, Paisley, UK). PBMCs were counted in a Neubauer chamber and adjusted to a final concentration of 106 cells mL−1. Cell viability (> 90%) was assessed by Trypan blue dye exclusion.

Single-colour flow cytometry analyses were performed as previously described. Reference Arteche-Villasol, Gutiérrez-Expósito and Vallejo18 Briefly, a total of 2 × 105 cells per well were seeded in different wells in a 96-well plate (Thermo Fisher Scientific, Roskilde, Denmark) and individually incubated with non-conjugated anti-bovine CD4 (MCA834GA, Bio-Rad®), CD8 (MCA837GA, Bio-Rad®) and CD21 (MCA1424GA, Bio-Rad®) as primary antibodies at a 1:400 dilution for 1 h at 4 °C. Cells were washed twice with PBS and incubated with fluorescein isothiocyanate (FITC)-conjugated anti-mouse IgG (F0313, Dako®) as a secondary antibody at a dilution of 1:50 for 1 h at 4 °C in the dark. At the same time, cells from two wells were also individually incubated with FITC-conjugated anti-bovine CD14 (MCA2678F, Bio-Rad®) and WC1 (MCA383F, Bio-Rad®) antibodies at a 1:400 dilution for 1 h in the darkness at 4 °C. Finally, the wells were washed twice with PBS, and the cells were fixed with 1% CellFIX (Becton Dickinson and Company, Erembodegem, Belgium) and kept in the dark until flow cytometric analysis.

Sample acquisition and data analysis were performed as previously described by Arteche-Villasol et al. (2020). Reference Arteche-Villasol, Benavides and Espinosa17 At least 10,000 events were acquired using a MACSQuant flow cytometer (Miltenyi Biotec®) and gated to discard the presence of air and doublets. Then, the data were analysed using MACSQuantify10 Software (Miltenyi Biotec®), and the results were expressed as a percentage of positive cells for each lymphocyte surface marker.

Microbiota characterisation of faecal samples

DNA was extracted from each faecal sample using a QIAamp Fast DNA Stool Mini Kit (Qiagen, Germany), according to the manufacturer’s protocol. DNA quality and quantity were assessed using a NanoDrop ND-1000 spectrophotometer (NanoDrop Technologies, Wilmington, DE, USA). The isolated DNA was then stored at −20 °C until use. Then, bacterial DNA was amplified using primers to target the V3–V4 hypervariable regions of the 16S rRNA gene, as previously described. Reference Caporaso, Lauber and Walters19 DNA Sequencing, bioinformatic processing and statistical analysis were performed as described in Ranilla et al. (2023). Reference Ranilla, Andrés and Gini20

Metabolomics analysis

A volume of 400 µL of ice-cold methanol (LC-MS grade) was added to 100 µL of plasma sample containing 5 µL of internal standard (15N L-Leucine, 98%, Sigma –Aldrich, 1 mg/mL), vigorously vortexed and then stored for 30 min at − 20°C. Samples were centrifuged at 14,800 r.p.m. for 10 min at + 4°C. The supernatant was transferred to a new tube and dried under a stream of nitrogen. The residue was reconstituted in 100 µL of mobile phase (1% of 0.1% formic acid in acetonitrile – FM B) and analysed by LC-QTOF-MS. A blank sample (100 µL of water LC-MS grade) and a quality control sample (QC, a pool of all samples analysed) were also prepared.

Five microlitres of each sample were injected in duplicate. The autosampler and column temperatures were set at 10°C and 40°C, respectively. The analytes were eluted using a CORTECS UPLC T3 C18 (2.1 × 150 mm, 1.6 µm) (Waters™) connected to an ExionLC™ AD system (Sciex™) using 0.1% formic acid in water as mobile phase A and 0.1% formic acid in acetonitrile as mobile phase B. The gradient was from 99% A to 5% A in 8 min, with a total run of 20 min at a flow rate of 0.4 mL/min. The separated metabolites were then ionised using a Turbo V™ Ion Source with an ESI Probe source (Sciex™) and analysed in a ZenoTOF 7600 System equipped with a Zeno trap (Sciex™). Mass spectra were collected, in both positive- and negative ion modes, in Full-Mass Scan from 50 to 1500Da (250 ms accumulation time) and in IDA® mode (Information Dependent Acquisition) from 40 to 1500Da (50 ms accumulation time). For both methods, ion source gas 1 (GS1) and 2 (GS2) were set to 40 and 55 psi, respectively; the curtain gas to 25 psi, CAD gas to 7 and the source temperature to 550°C. The Spray Voltage was fixed at 4.5 kV (−4.5 kV in negative mode), the declustering potential (DP) was 80 eV and the collision energy was 30 eV with a collision energy spread of 15 eV.

The data were analysed using SCIEX OS 2.2 software (SCIEX™), in two processing functions: (1) FormulaFinder, to identify possible compound formulas based on TOF-MS spectra (compound molecular weight); (2) LibraryView™ (ver 1.0) to search MS/MS spectra with the built-in accurate mass spectral library (Metabolite High-Resolution MS/MS Spectral Library). Data were expressed as the ratio of the analytes versus the internal standard. The average corresponding area’ was normalised to the estimated protein concentration in each extracted sample. Identifications (ID) were obtained based on the value m/z (parent ion) achieved and determined in high resolution.

Statistical analyses

Feed efficiency traits and digestibility were analysed by one-way ANOVA, whereas the biochemical profile, SOD and PBMCs were assessed by repeated measurements using the MIXED procedure of SAS. In the repeated measurement analysis, data from the first sampling day (day 3, before including EO in the MR of the EO group) was used as a covariate, and adjusted mean values were estimated when the effect was significant.

Regarding the faecal microbiota, differences between groups (EO vs. control) along time points in terms of OTU abundances and diversity indices were evaluated with the three following linear models: linear model A: Yik = μ + timepointk + eik, or linear model B: Yij = μ + treatmentj + eij, or linear model C: Yikj = μ + timepointk + treatmentj + eikj, where Ykj is the abundance (counts) or index value for each taxonomy (OTU) and diversity metric per sample i in timepoint k and treatment j; timepointk is the effect of the categorical variable time point (2 classes); treatmentj is the effect of the categorical variable treatment (2 classes); ekj are the residuals of the model. Faecal microbial diversity was assessed within- (alpha-diversity) and across- (beta-diversity) samples. All indices (alpha- and beta-diversity, previously listed in Ranilla et al. 2023) Reference Ranilla, Andrés and Gini20 were estimated from the complete OTU table and filtered for OTUs with more than 10 total counts distributed in at least two samples. Details about the indices used can be found in Appendix S2 of Biscarini et al. (2018). Reference Biscarini, Palazzo and Castellani21 Beta-diversity significances were tested using PERMANOVA.

MetaboAnalyst 5.0 Reference Pang, Chong and Zhou22 was used to perform multivariate data analyses, including principal component analysis (PCA), Partial Least Squares Discriminant Analysis (PLS-DA), heat maps, hierarchical clustering and pathway analysis Reference Pang, Chong and Zhou22 Volcano plots were drawn at T0 (3 days), T1 (45 days) and T2 (13 months) to identify significant metabolites between treatments. Plots used a threshold of 1.5 for fold change (FC) on the × axis and a threshold of 0.05 for the false-discovery rate (adjusted P-value) on the y axis.

Results

Feed efficiency, biochemical profile and antioxidant status

According to the results obtained (Table 2), the ADG of the EO group was higher (100 vs. 172 g/d; P = 0.003) during the first 45 days of life. Thus, these animals were heavier (44.0 vs. 47.4 kg; P = 0.030) and more efficient when they received supplementation with EO in the MR. However, no long-term effects of EO supplementation during the milk-fed period on RFI (−0.118 vs. 0.119, P = 0.308) nor digestibility (51.9 vs. 51.7%; P = 0.965) were observed at the adult stage when animals were fed the TMR-2 diet. In addition, the biochemical profile (Table 3) and SOD inhibition rate measurement (181.8 vs. 79.5% for the control and EO groups, respectively; P = 0.795) were similar between the two groups at all sampling times (P > 0.05).

Table 2. Effects of essential oil supplementation during the first 45 days of life on the pre-weaning and replacement performance of dairy calves

a Standard error of the difference.

b LBW = live body weight.

c Average daily gain.

d Residual feed intake (RFI) calculated using ADG estimated by regression.

Table 3. Biochemical profile the day 45 (end of EO administration) and day 370 (replacement phase) of dairy calves being supplied essential oil (EO group) or not (CTRL group) during the suckling period

a AST, aspartate aminotransferase.

b Beta-hidroxybutirate.

c GGT, gamma-glutamyl transpeptidase.

d NEFA, non-esterified fatty acid.

Flow cytometry analyses of the mononuclear cell population

As far as the mononuclear cell population is concerned, none of the markers studied (CD4+, CD8+, CD21+, WC1+ and CD14+) presented significant differences between treatments (Table 4; P > 0.05). It is remarkable, however, that a statistical interaction existed between diet and day for CD21+; accordingly, the reduction of this parameter over time was lower for the EO group (Figure 1). Interestingly, higher significant values (P = 0.006) for monocytes (CD14+) were obtained in the EO group, indicating a direct effect of EO treatment on this population.

Figure 1. Peripheral blood mononuclear cell (PBMC) measured by flow cytometry the day 45 (end of EO administration) and day 370 (replacement phase) of dairy calves being supplied essential oil (EO group) or not (CTRL group) during the suckling period.

Table 4. Peripheral blood mononuclear cell (PBMC, % positive cells) measured by flow cytometry the day 45 (end of EO administration) and day 370 (replacement phase) of dairy calves being supplied essential oil (EO group) or not (CTRL group) during the suckling period

a Standard error of the difference to compare experimental groups.

b Standard error of the difference to compare sampling days.

Microbiome analysis

Sequencing results

Sequencing the V3-V4 regions of the bacterial 16S rRNA gene of the 32 feces samples produced 2,184,670 assembled reads (joined R1-R2 paired-end reads). After quality filtering, 354,387 sequences were removed, leaving 1,830,283 sequences for subsequent analyses (84% average retention rate, maximum 94.5%, minimum 79.2%). On average, there were 55,694 (± 22,788) sequences per sample in the control group and 58,698 ± 25,898 in the EO group. The initial number of OTUs identified was 6,466; after filtering out OTUs with less than 10 counts in at least 2 samples, 2,531 distinct OTUs were left.

Alpha- and beta-diversity indexes

The estimated alpha-diversity indices are reported in Supplementary Table S1. Considering the effect of the treatment alone, several indices (Fisher, Chao1, Shannon, ACE, Observed OTUs and Simpson) were statistically significant at T1, while none were significant at T2 (P ≤ 0.05). Still, three indices (Simpson, InvSimspon and Shannon) were positive in the 0.05–0.10 area of significance at T2 (Figure 2A). On the other hand, considering the time effect alone, three indices (Observed_OTUs, Chao1 and ACE) were significant in the control group. By contrast, the EO group had no index with a significant P-value (Figure 2B). Still, the time effect did not show the same behaviour (only three indices −Observed_OTUs, Chao1 and ACE − in the 0.05 − 0.10 range) (Figure 2C). The relationships between samples were assessed using the weighted Unifrac distances between samples.

Figure 2. The fecal microbiota of calves after EO feeding. Panel A, B, and C are scatterplots reporting the significance of the alpha diversity indices in treatments and time points. P-values were obtained from a linear regression model with the Control group as the benchmark. The dashed lines identify the suggestive-significance area. Panel D and E present the Principal Component Analysis (PCA) plot of unweighted Unifrac distances of fecal microbiota in this study. Panel D represents the clustering per treatment, while Panel E represents the clustering per time point. Panels F and G show significantly abundant taxa in fecal microbiota at the genera level. Panel F is the heatmap of the significance of taxa relative abundance. Panel G Bar plot presents the behavior of the significantly different abundant genera along time points: the scale in the x-axis is the ratio of Treated against Controls.

The distribution of samples (PCA) showed no clustering for samples grouped by treatment (P = 0.905). Clear clusters were only detected when considering samples grouped by time point (P = 0.001).

Description of the core microbiome in faeces

The core faecal microbiota at the family and phylum level comprised 87 and 21 OTUs shared within 100% of the samples (Supplementary Table S2). Eight main phyla were detected in the faecal microbiota, with a relative abundance larger than 1%, in particular, Firmicutes (49.21%), Bacteroidetes (32.19%), Proteobacteria (4.15%), Verrucomicrobia (3.1%), Cyanobacteria (2.9%), Euryarchaeota (2.26%), Spirochaetes (1.54%) and Actinobacteria (1.29%). The core faecal microbiota at the genus level was composed of 228 OTUs shared within 100% of the samples, plus uncultured or unknown genera (Supplementary Table S3, Figure 3). Fourteen main genera were detected in the faecal microbiota, with a relative abundance larger than 2%, in particular, Bacteroides (13.4%), Ruminococcaceae UCG-005 (12%), Alloprevotella (9.63%), Ruminococcaceae UCG-010 (6.7%), Faecalibacterium (5.9%), Ruminococcaceae UCG-014 (4.8%), Prevotella 9 (4.49%), Akkermansia (4.45%), Blautia (3.75%), Alistipes (3.24%), Rikenellaceae RC9 gut group (3.16%), Prevotella 2 (2.69%), Escherichia-Shigella (2.49%) and Methanobrevibacter (2.38%).

Effects of treatments on microbiota at the genus level

Thirty-eight genera differed significantly when the treatment groups were compared over time: 34 genera were differentially expressed at T1, of which 18 decreased in the EO group compared with the control, the most significant being that 16 increased. The remaining four genera were differentially expressed at T2, of which 2 (Prevotella 2 and Howardella) decreased in the EO group compared with the control, and in the same group, two (Caldicoprobacter and Ruminiclostridium 1) increased (Supplementary Table S4, Figure 3) as compared to the control, although the increase was limited.

Plasma metabolome analysis

Untargeted metabolomic analyses identified 109 metabolites (Supplementary Table S5). The supervised PCA (Figure 3A) showed separation of the three age-related group samples. The heat map in Figure 3B, generated by hierarchical clustering, also presented evidence that three age-related groups can be distinguished by their metabolomes. Figure 3C shows the Volcano plot score of the changes, proving the significant metabolites that change along the time course.

Figure 3. The plasma metabolome changes in calves not fed with EO. Panel A: Pairwise PCA with density plots outlines the different times of sampling (T0, T1, and T2). Panel B: Presentation of the 50 most significant metabolites determined by one-way ANOVA analysis. Panel C: Clustering results are shown as a heatmap (distance measured using Euclidean and clustering algorithm using ward).

When the plasma metabolomes from control calves and those fed with EO were compared, no statistical changes were evidenced between the groups regarding the plasma metabolome at T0 (Figure 4, Panels A and B). However, at T1, we observed significant statistical changes (P > 0.05) for indole, propionic acid, succinic acid and butyric acid (Figure 4, Panel C and D), whereas T2 differed significantly for 10 metabolites (Figure 4, Panel E and F).

Figure 4. The changes in the plasma metabolomes of calves fed with EO-enriched diets. The plasma metabolome changes between in calves fed (EO) and not fed (CON) with EO at T0 (Panels A and B), T1 (Panels C and D), and T2 (Panel E and F). Panels A, C, and E show the Volcano plot of changes at T0, T1, and T2, respectively. Important features selected by the volcano plot with fold change threshold (x) 2 and t-tests threshold (y) 0.1. The red circles represent features above the threshold. Note that both the fold changes and the p-values are log-transformed. The further its position away from the (0,0), the more significant the feature is. Panel B, D, and F present the 3D scores plot between the selected PCs at T0 (B), T1 (D), and T2 (F), respectively. The explained variances are shown in brackets.

The major metabolic pathways that changed with age in control calves were aminoacyl-tRNA biosynthesis and valine, leucine and isoleucine biosynthesis, followed by the biosynthesis of several amino acid pathways (Figure 5, Panel A). The significant pathways modified by EO feeding at T2 were arginine biosynthesis and alanine, aspartate and glutamate metabolism (Figure 5, Panel B).

Figure 5. The metabolic pathway changes. Summary of Pathway Analysis: the circle's size indicates the pathway's impact, while the color represents the significance (the more intense the red color, the lower the significance). Panel A: The significant pathway modified in the plasma metabolome in control calves not fed with EO. All the changed metabolites are included. Panel B: The significant pathway modified in the plasma metabolome changes in calves at T2.

Discussion

Calves are born as functional monogastric animals that rely on nutrients from milk or MR in early life. Reference Baldwin, McLeod, Klotz and Heitmann23 This initial period of life is essential and could affect the welfare, growth and development of newborn calves as well as drive their future performance. The present study investigated the effects of neonatal feeding with EO on feed efficiency and related performance parameters, immune status, the gut microbiome and the plasma metabolome in both the short and the long term.

According to the results, calves receiving EO in the MR improved their feed efficiency during this phase. Thus, these EO calves gained more weight during the suckling phase consuming the same amount of dry matter as the control group. Our results agree with previous studies, Reference Froehlich, Abdelsalam, Chase, Koppien-Fox and Casper24 showing that EO (carvacrol, caryophyllene, -cymene, cineole, terpinene and thymol) enhance the growth rate and stimulate appetite in newborn dairy calves. Moreover, Liu et al. Reference Liu, Chen and Bai11 demonstrated that calves fed commercial EO from three days of age through the end of the 70-day experimental period showed greater apparent total-tract nutrient digestibility of DM, ADF, NDF, starch and minerals (Na, Mg, P, S, K, Ca, Cl, Mn, Fe and Cu) as compared with calves fed the control diet. Moreover, they also indicated that EO given during the early life may consistently challenge gut health and prevent diarrhoea. Other authors have suggested that the positive effects of EO might be related to the inhibition of pernicious bacteria exerted by carvacrol and thymol lipophilic components at the gut level. Reference Zhou, Pan and Xin25 Nevertheless, in the present study, this positive effect on feed efficiency was not observed later on during the replacement phase.

Early supplementation with EO did not modify most PBMC populations, including CD4+ (T helper lymphocytes), CD8+ (T cytotoxic lymphocytes), CD21+ (B cells) and WC1+ (γδ T lymphocytes) at 3 and 45 days and 13 months. However, an interaction between diet and day for CD21+ was observed (P = 0.048; Table 4), which may indicate a persistent decrease of CD21+ in the EO group compared to the control group that did not receive EO. By contrast, CD14+ monocytes presented statistically significant increased average values in the EO group, and this effect persisted throughout the replacement phase. It must be considered that CD14+ monocytes are a different lineage from intestinal macrophages, cells which are key regulators of inflammatory responses to the gut microbiome and play a central role in maintaining gastrointestinal homoeostasis, epithelial integrity and protecting against specific mucosal pathogens; Reference Cassol, Rossouw and Malfeld26 however, if a similar effect of EO on the intestine were assumed, the changes observed in CD14+ and the smaller decrease in CD21+ over time observed in the EO group might have influenced or be related to changes in the gut microbiome.

To clarify this hypothesis, the effects of EO on the uncultured faecal microbiota were studied. Diversity significance indices described the impact of time and treatment, underlying that, for differences between groups, treatment was crucial, while for diversity within groups (beta-diversity) the time effect was critical. Moreover, feeding EO during early life increased the abundance of two genera, namely Akkermansia and Allistipes, at T1. Bacteria belonging to the genus Akkermansia are included in the intestinal mucus and regulate the integrity of the intestinal barrier by producing both anti-inflammatory cytokines (e.g., IL-10) Reference Ottman, Reunanen and Meijerink27 and SCFA to further support gut health. Reference Portincasa, Bonfrate and Vacca28 In addition, when abundant, Akkermansia fulfils protective roles against several diseases in humans Reference Scollan, Price, Morgan, Huws and Shingfield29 as well as in calves Reference Fernández-Ciganda, Fraga and Zunino30 and is regarded as a third-generation probiotic. Reference Scollan, Price, Morgan, Huws and Shingfield29 Regarding Allistipes, previous studies have demonstrated in humans that this genus includes bacteria positively related to healthy anaerobes in the host. Reference Franzosa, Sirota-Madi and Avila-Pacheco31

Of the four bacteria genera whose abundance was decreased in EO calves at T1 (e.g., Ruminococcaceae UCG-014, Faecalibacterium, Blautia and Alloprevotella), bacteria belonging to genera such as Faecalibacterium and Blautia dominate the faeces of pre-weaned calves. Reference Amin, Schwarzkopf and Tröscher-Mußotter32 A higher abundance of Faecalibacterium has been associated with a lower sensitivity to neonatal diarrhoea. Reference Zeineldin, Aldridge and Lowe33,Reference Hennessy, Indugu and Vecchiarelli34 We may then speculate that decreasing the abundance of Faecalibacterium genus when feeding EO might expose the calves to an increased risk of developing gut alterations related to body weight and ADG. Reference Kumar, Khan and Beijer35 However, we observed an increase of ADG at T1, probably because the magnitude of the decreased abundance of Blautia in EO animals was insufficient (by itself) to induce changes in the calves’ ADG. The other two genera that were decreased at T1 in the group of calves being fed EO are Ruminococcaceae UCG-014 and Alloprevotella. Alloprevotella produces succinic acid as the end-product of plant fibre. Reference Downes, Dewhirst, Tanner and Wade36 Interestingly, as discussed below, the decrease in the abundance of the genus Alloprevotella corresponds to the decrease of succinic acid in the plasma metabolome. In calves, both Ruminococcaceae UCG-014 and Alloprevotella are critical biomarkers of gut health, and their abundance correlates with a healthy phenotype. Reference Te, Chen, Hsieh, Li, Ho and Chen37,Reference Chen, Liu and Huang38 Again, reducing the abundance of both genera might increase the risk of developing intestinal diseases in calves fed EO. Finally, the effect of EO at T2 was limited to a decrease in the genus Prevotella-2. The bacteria belonging to this genus, like other Prevotellaceae, are reduced during calf diarrhoea, Reference Chen, Liu and Huang38 so again, this change promoted by EO might indicate gut dysbiosis.

The last part of the study also revealed changes induced by treatment on the untargeted metabolome of calf’ plasma. No changes were found at T0, confirming that the two groups were homogeneous concerning the plasma metabolome at 3 days of life. At T1 (45 days old), only three metabolites changed: 3-indole propionic acid, butyric acid and succinic acid. The descent of butyric acid (a metabolite produced by intestinal bacteria) agrees with the decrease in Blautia, Ruminococcaceae and Faecalibacterium, three bacterial genera associated with butyric acid production. Moreover, 3-indole-propionic acid is a bacterial metabolite derived from tryptophan metabolism and produced by the genus Faecalibacterium. As for Blautia, there was a correlation between the decrease of Faecalibacterium at T1 and the decrease of 3-indole propionic acid, Reference Menni, Hernandez, Vital, Mohney, Spector and Valdes39 an inhibitor of gut dysbiosis and endotoxin leakage and a potent scavenger of hydroxyl radicals. Reference Zhao, Xin and Xue40 Butyric acid also shows a protective effect against the inflammatory response, Reference Frutos, Andrés and Trevisi41 so the decrease of both metabolites at T1 seems to corroborate the increased risk of gut disease when feeding EOs during early life.

At T2, 340 days after birth, the plasma abundance of 14 metabolites changed. Pathway analysis of the changes occurring at T2 suggests that most changes were related to a reduction of energy and protein metabolism and a potential decrease of the antioxidant capacity. In particular, metabolites associated with the citric acid cycle, such as fumaric acid and malic acid, and carnitines, such as L-acetyl carnitine and L-carnitine, were decreased in the EO group. Biogenic amines, such as taurine (a sulphur-containing non-essential amino acid whose low level may reduce antioxidant activity) and citrulline, were also decreased. Additionally, two metabolites related to decreased protein catabolism (e.g., creatinine and 1-methylhistidine) were also decreased, which may indicate reduced proteolytic processes. Reference Pires, Delavaud, Faulconnier, Pomiès and Chilliard42 In any case, the magnitude of all these changes was not enough to promote variations in ADG during the replacement phase. In conclusion, according to the results of the present study, daily administration of 0.23 ml of oregano EO (accounting for 200 mg of carvacrol) to newborn dairy calves promotes a positive transitory effect on body growth and feed efficiency during the suckling period but no long-term effects during the replacement phase. This early supply of EO also induces early changes in the gut microbial population consistent with changes in the plasma metabolome, but not all of them are considered desirable from a gut health point of view. Future work should be focused on determining the optimum dosage and duration of EO administration to determine if EOs may provide a viable natural alternative to antibiotics to minimise health challenges while improving calf growth performance and economic returns to the dairy calf raiser. Therefore, additional research studies is warranted to evaluate different mechanisms of action of EO on the interaction between the microbiota, immunity and health.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S2040174424000084.

Data availability statement

The 16S rRNA gene sequences obtained from this study were deposited in the EMBL-EBI European Nucleotide Archive (ENA) repository with the accession number PRJEB57631. The rest of the data are available upon request. The 16S rRNA gene sequences obtained from this study and the OTU table derived as described in the test were deposited and available in the Università degli Studi di Milano Dataverse repository. A private URL for reviewers is hereby provided, while datasets will be disclosed upon article acceptance (https://dataverse.unimi.it/privateurl.xhtml?token=8b1dab61-e1e3-49a2-a4a2-aa1e969c6eb7).

Acknowledgements

The metabolomics analysis was carried out at the UNI-TECH “OMICS” platforms of the Università degli Studi di Milano. We acknowledge Mrs. Manuela Fontana and Prof. Donatella Caruso’s important support from the UNI-TECH “OMICS” platforms of the Università degli Studi di Milano.

Author contribution

SA, LA-N and FC contributed to the conception and design of the study. SA, FG, AM and IM conducted the in vivo study. DGE, NA and AM carried out the flow cytometry analyses. PC sequenced the DNA microbiome samples, and CG conducted the bioinformatics analyses. FG performed the statistical analysis of the in vivo study. FF carried out the metabolome analysis. MG and FC carried out the metabolomic statistical analysis. SA and LA-N wrote the first draft of the manuscript. All authors contributed to writing, revising and reading the manuscript before submission.

Financial support

This work was funded by CSIC (Proyectos Intramurales Especiales, 201940E115) and MUR (Direzione Generale dell’internazionalizzazione e della comunicazione Programma cooperazione internazionale PRIMA - Decreto Ministeriale 26 luglio 2016 n. 593) in the context of the MILKQUA-H2020-PRIMA 2018—Section 2. Alba Martín gratefully acknowledges receipt of a pre-doctoral grant (PRE2019-089288) from Ministerio de Ciencia e Innovación (MCIN/AEI/10.13039/501100011033, “El FSE invierte en tu futuro”).

Competing interests

None.

Ethical standard

The authors assert that all procedures contributing to this work comply with the ethical standards of the relevant national guides on the care and use of laboratory animals (Directive 2010/63/EU) and has been approved by the institutional committee (IGM-CSIC Animal Experimentation Committee).

References

Gluckman, PD, Hanson, MA, Spencer, HG, Bateson, P. Environmental influences during development and their later consequences for health and disease: implications for the interpretation of empirical studies. Proc Royal Soc B Biol Sci. 2005; 272(1564), 671677.CrossRefGoogle ScholarPubMed
Van Eetvelde, M, Opsomer, G. Prenatal programming of later performance in dairy cattle. Vlaams Diergeneeskd Tijdschr. 2020; 89(1), 5362.Google Scholar
Erickson, PS, Kalscheur, KF. Nutrition and feeding of dairy cattle. Animal Agriculture. 2020, 157180. doi: 10.1016/B978-0-12-817052-6.00009-4.CrossRefGoogle Scholar
Haase, S, Haghikia, A, Wilck, N, Müller, DN, Linker, RA. Impacts of microbiome metabolites on immune regulation and autoimmunity. Immunology. 2018; 154(2), 230238.CrossRefGoogle ScholarPubMed
Stiemsma, LT, Michels, KB. The role of the microbiome in the developmental origins of health and disease. Pediatrics. 2018; 141(4), 122.CrossRefGoogle ScholarPubMed
Arshad, MA, Hassan, F-U, Rehman, MS, Huws, SA, Cheng, Y, Din, AU. Gut microbiome colonization and development in neonatal ruminants: strategies, prospects, and opportunities. Anim Nutr. 2021; 7(3), 883895.CrossRefGoogle ScholarPubMed
Fan, P, Kim, M, Liu, G, et al. The gut microbiota of newborn calves and influence of potential probiotics on reducing diarrheic disease by inhibition of pathogen colonization. Front Microbiol. 2021; 12, 111.CrossRefGoogle ScholarPubMed
Bach, A, Elcoso, G, Escartín, M, Spengler, K, Jouve, A. Modulation of milking performance, methane emissions, and rumen microbiome on dairy cows by dietary supplementation of a blend of essential oils. Animal. 2023; 17(6), 18.CrossRefGoogle ScholarPubMed
Nehme, R, Andrés, S, Pereira, RB, et al. Essential oils in livestock: from health to food quality. Antioxidants. 2021; 10(2), 330.CrossRefGoogle ScholarPubMed
Bodas, R, Prieto, N, García-González, R, Andrés, S, Giráldez, FJ, López, S. Manipulation of rumen fermentation and methane production with plant secondary metabolites. Anim Feed Sci Technol. 2012; 176(1-4), 7893.CrossRefGoogle Scholar
Liu, T, Chen, H, Bai, Y, et al. Calf starter containing a blend of essential oils and prebiotics affects the growth performance of Holstein calves. J Dairy Sci. 2020; 103(3), 23152323.CrossRefGoogle ScholarPubMed
Poudel, P, Froehlich, K, Casper, DP, St-Pierre, B. Feeding essential oils to neonatal Holstein dairy calves results in increased ruminal prevotellaceae abundance and propionate concentrations. Microorganisms. 2019; 7(5), 120. doi: 10.3390/microorganisms7050120.CrossRefGoogle ScholarPubMed
Evangelista, AG, Corrêa, JAF, Pinto, ACSM, Luciano, FB. The impact of essential oils on antibiotic use in animal production regarding antimicrobial resistance – a review. Crit Rev Food Sci Nutr. 2022; 62(19), 52675283.CrossRefGoogle ScholarPubMed
Matté, EHC, Luciano, FB, Evangelista, AG. Essential oils and essential oil compounds in animal production as antimicrobials and anthelmintics: an updated review. Anim Health Res Rev. 2023; 24(1), 111.CrossRefGoogle ScholarPubMed
Percie du Sert, N, Hurst, V, Ahluwalia, A,, et al. The ARRIVE guidelines 2.0: updated guidelines for reporting animal research. PLoS Biol. 2020; 18, 16.Google ScholarPubMed
Van Keulen, J, Young, BA. Evaluation of acid-insoluble ash as a natural marker in ruminant digestibility studies. J Anim Sci. 1977; 44, 282287.CrossRefGoogle Scholar
Arteche-Villasol, N, Benavides, J, Espinosa, J, et al. Optimized in vitro isolation of different subpopulation of immune cells from peripheral blood and comparative techniques for generation of monocyte-derived macrophages in small ruminants. Vet Immunol Immunopathol. 2020; 230, 111.CrossRefGoogle ScholarPubMed
Arteche-Villasol, N, Gutiérrez-Expósito, D, Vallejo, R, et al. Early response of monocyte-derived macrophages from vaccinated and non-vaccinated goats against in vitro infection with mycobacterium avium subsp. paratuberculosis. Vet Res. 2021; 52(1), 212.CrossRefGoogle ScholarPubMed
Caporaso, JG, Lauber, CL, Walters, WA, et al. Global patterns of 16S rRNA diversity at a depth of millions of sequences per sample. Proc Natl Acad Sci USA. 2011; 108, 45164522.CrossRefGoogle Scholar
Ranilla, MJ, Andrés, S, Gini, C, et al. Effects of thymbra capitata essential oil on in vitro fermentation end-products and ruminal bacterial communities. Sci Rep. 2023; 13(1), 112.CrossRefGoogle ScholarPubMed
Biscarini, F, Palazzo, F, Castellani, F, et al. Rumen microbiome in dairy calves fed copper and grape-pomace dietary supplementations: composition and predicted functional profile. PLoS One. 2018; 13(11), 120.CrossRefGoogle ScholarPubMed
Pang, Z, Chong, J, Zhou, G, et al. MetaboAnalyst 5.0: narrowing the gap between raw spectra and functional insights. Nucleic Acids Res. 2021; 49(W1), 388396.CrossRefGoogle Scholar
Baldwin, RL, McLeod, KR, Klotz, JL, Heitmann, RN. Rumen development, intestinal growth and hepatic metabolism in the pre- and postweaning ruminant. J Dairy Sci. 2004; 87, 5565.CrossRefGoogle Scholar
Froehlich, KA, Abdelsalam, KW, Chase, C, Koppien-Fox, J, Casper, DP. Evaluation of essential oils and prebiotics for newborn dairy calves. J Anim Sci. 2017; 95(8), 37723782.Google ScholarPubMed
Zhou, D, Pan, Q, Xin, FZ, et al. Sodium butyrate attenuates high-fat diet-induced steatohepatitis in mice by improving gut microbiota and gastrointestinal barrier. World J Gastroenterol. 2017; 23(1), 6075.CrossRefGoogle ScholarPubMed
Cassol, E, Rossouw, T, Malfeld, S, et al. CD14+ macrophages that accumulate in the colon of African AIDS patients express pro-inflammatory cytokines and are responsive to lipopolysaccharide. BMC Infect Dis. 2015; 15, 113.CrossRefGoogle ScholarPubMed
Ottman, N, Reunanen, J, Meijerink, M, et al. Pili-like proteins of Akkermansia muciniphila modulate host immune responses and gut barrier function. PLoS One. 2017; 12(3), 118.CrossRefGoogle ScholarPubMed
Portincasa, P, Bonfrate, L, Vacca, M, et al. Gut microbiota and short chain fatty acids: implications in glucose homeostasis. Int J Mol Sci. 2022; 23(3), 123.CrossRefGoogle ScholarPubMed
Scollan, ND, Price, EM, Morgan, SA, Huws, SA, Shingfield, KJ. Can we improve the nutritional quality of meat? Proc Nutr Soc. 2017; 76(4), 603618.CrossRefGoogle ScholarPubMed
Fernández-Ciganda, S, Fraga, M, Zunino, P. Probiotic lactobacilli administration induces changes in the fecal microbiota of preweaned dairy calves. Probiotics Antimicrob Proteins. 2022; 14(5), 804815.CrossRefGoogle ScholarPubMed
Franzosa, EA, Sirota-Madi, A, Avila-Pacheco, J, et al. Gut microbiome structure and metabolic activity in inflammatory bowel disease. Nat Microbiol. 2018; 4(2), 293305.CrossRefGoogle ScholarPubMed
Amin, N, Schwarzkopf, S, Tröscher-Mußotter, J, et al. Host metabolome and faecal microbiome shows potential interactions impacted by age and weaning times in calves. Anim Microbiome. 2023; 5(1), 119.CrossRefGoogle ScholarPubMed
Zeineldin, M, Aldridge, B, Lowe, J. Dysbiosis of the fecal microbiota in feedlot cattle with hemorrhagic diarrhea. Microb Pathog. 2018; 115, 123130.CrossRefGoogle ScholarPubMed
Hennessy, M, Indugu, N, Vecchiarelli, B, et al. Short communication: comparison of the fecal bacterial communities in diarrheic and nondiarrheic dairy calves from multiple farms in southeastern Pennsylvania. J Dairy Sci. 2021; 104(6), 72257232.CrossRefGoogle ScholarPubMed
Kumar, S, Khan, MA, Beijer, E, et al. Effect of milk replacer allowance on calf faecal bacterial community profiles and fermentation. Anim Microbiome. 2021; 3(1), 112.CrossRefGoogle ScholarPubMed
Downes, J, Dewhirst, FE, Tanner, ACR, Wade, WG. Description of Alloprevotella rava gen. nov., sp. nov., isolated from the human oral cavity, and reclassification of prevotella tannerae, Moore, et al, 1994 as Alloprevotella tannerae gen. nov., comb. nov. Int J Syst Evol Microbiol. 2013; 63, 12141218.CrossRefGoogle Scholar
Te, CS, Chen, CT, Hsieh, JC, Li, KY, Ho, ST, Chen, MJ. Development of next-generation probiotics by investigating the interrelationships between gastrointestinal microbiota and diarrhea in preruminant Holstein calves. Animals. 2022; 12, 117.Google Scholar
Chen, H, Liu, Y, Huang, K, et al. Fecal microbiota dynamics and its relationship to diarrhea and health in dairy calves. J Anim Sci Biotechnol. 2022; 13(1), 120.CrossRefGoogle ScholarPubMed
Menni, C, Hernandez, MM, Vital, M, Mohney, RP, Spector, TD, Valdes, AM. Circulating levels of the anti-oxidant indoleproprionic acid are associated with higher gut microbiome diversity. Gut Microbes. 2019; 10(6), 688695.CrossRefGoogle ScholarPubMed
Zhao, ZH, Xin, FZ, Xue, Y, et al. Indole-3-propionic acid inhibits gut dysbiosis and endotoxin leakage to attenuate steatohepatitis in rats. Exp Mol Med. 2019; 51(9), 114.Google ScholarPubMed
Frutos, J, Andrés, S, Trevisi, E, et al. Moderated milk replacer restriction of ewe lambs alters gut immunity parameters during the pre-weaning period and impairs liver function and animal performance during the replacement phase. Anim Feed Sci Technol. 2018; 243, 8089.CrossRefGoogle Scholar
Pires, JAA, Delavaud, C, Faulconnier, Y, Pomiès, D, Chilliard, Y. Effects of body condition score at calving on indicators of fat and protein mobilization of periparturient holstein-friesian cows. J Dairy Sci. 2013; 96(10), 64236439.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Ingredients and chemical composition (g/kg DM unless otherwise stated) of the total mixed ration (TMR-2) consumed by the heifers during the replacement phase

Figure 1

Table 2. Effects of essential oil supplementation during the first 45 days of life on the pre-weaning and replacement performance of dairy calves

Figure 2

Table 3. Biochemical profile the day 45 (end of EO administration) and day 370 (replacement phase) of dairy calves being supplied essential oil (EO group) or not (CTRL group) during the suckling period

Figure 3

Figure 1. Peripheral blood mononuclear cell (PBMC) measured by flow cytometry the day 45 (end of EO administration) and day 370 (replacement phase) of dairy calves being supplied essential oil (EO group) or not (CTRL group) during the suckling period.

Figure 4

Table 4. Peripheral blood mononuclear cell (PBMC, % positive cells) measured by flow cytometry the day 45 (end of EO administration) and day 370 (replacement phase) of dairy calves being supplied essential oil (EO group) or not (CTRL group) during the suckling period

Figure 5

Figure 2. The fecal microbiota of calves after EO feeding. Panel A, B, and C are scatterplots reporting the significance of the alpha diversity indices in treatments and time points. P-values were obtained from a linear regression model with the Control group as the benchmark. The dashed lines identify the suggestive-significance area. Panel D and E present the Principal Component Analysis (PCA) plot of unweighted Unifrac distances of fecal microbiota in this study. Panel D represents the clustering per treatment, while Panel E represents the clustering per time point. Panels F and G show significantly abundant taxa in fecal microbiota at the genera level. Panel F is the heatmap of the significance of taxa relative abundance. Panel G Bar plot presents the behavior of the significantly different abundant genera along time points: the scale in the x-axis is the ratio of Treated against Controls.

Figure 6

Figure 3. The plasma metabolome changes in calves not fed with EO. Panel A: Pairwise PCA with density plots outlines the different times of sampling (T0, T1, and T2). Panel B: Presentation of the 50 most significant metabolites determined by one-way ANOVA analysis. Panel C: Clustering results are shown as a heatmap (distance measured using Euclidean and clustering algorithm using ward).

Figure 7

Figure 4. The changes in the plasma metabolomes of calves fed with EO-enriched diets. The plasma metabolome changes between in calves fed (EO) and not fed (CON) with EO at T0 (Panels A and B), T1 (Panels C and D), and T2 (Panel E and F). Panels A, C, and E show the Volcano plot of changes at T0, T1, and T2, respectively. Important features selected by the volcano plot with fold change threshold (x) 2 and t-tests threshold (y) 0.1. The red circles represent features above the threshold. Note that both the fold changes and the p-values are log-transformed. The further its position away from the (0,0), the more significant the feature is. Panel B, D, and F present the 3D scores plot between the selected PCs at T0 (B), T1 (D), and T2 (F), respectively. The explained variances are shown in brackets.

Figure 8

Figure 5. The metabolic pathway changes. Summary of Pathway Analysis: the circle's size indicates the pathway's impact, while the color represents the significance (the more intense the red color, the lower the significance). Panel A: The significant pathway modified in the plasma metabolome in control calves not fed with EO. All the changed metabolites are included. Panel B: The significant pathway modified in the plasma metabolome changes in calves at T2.

Supplementary material: File

Andrés et al. supplementary material 1

Andrés et al. supplementary material
Download Andrés et al. supplementary material 1(File)
File 99.3 KB
Supplementary material: File

Andrés et al. supplementary material 2

Andrés et al. supplementary material
Download Andrés et al. supplementary material 2(File)
File 52.4 KB