Abstract
Emus are farmed for fat production. Oil rendered from their back and abdominal fat pads has good anti-oxidant and anti-inflammatory properties and has ingredients that promote cell growth. Our objective is to examine the mRNA expression of 7 emu adipokine genes (eFABP4, eSCD1, eAdipoQ, eAdipoR1, eAdipoR2, eLEP and eLepR) to identify gene markers that may help improve emu fat production. Back and abdominal fat tissues from 11 adult emus were biopsied at four time points (April, June, August and November). Total RNA was isolated and cDNA was synthesized. Gene specific primers were designed for partial cloning fragments to amplify the open reading frame of the 7 genes. eLEP was not expressed in emu fat tissue. Nucleotides and amino acids sequences of the 6 expressed gene were compared with homologs from other species and phylogenetic relationships established. Seasonal mRNA expression of each gene was assessed by quantitative RT-PCR and differential expression analysed by the 2−ΔΔCT method. The 6 expressed genes showed seasonal variation in expression and showed association of expression level with back fat adiposity. More whole-genome scanning studies are needed to develop novel molecular markers that can be applied to improve fat production in emus.
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Introduction
Emu (Dromaius novaehollandiae) is indigenous to Australia and is the second largest living ratite bird. Australian aborigines first used emu oil for wound healing and pain‐alleviation. Currently emu is farmed globally. In Canada, emu is primarily farmed to produce oil. Emu oil is rendered from both the subcutaneous and retroperitoneal fat tissues1 and has anti‐inflammatory and antioxidant formulation with reparative properties2,3,4,5. Topical application of emu oil has been shown to reduce inflammation associated with reduced levels of interleukin 1-alpha (IL-1α), tumor necrosis factor-alpha (TNFα) and other proinflammatory cytokines in a croton-oil-induced inflammation mouse model6,7. More recently, well‐controlled pre‐clinical studies have demonstrated the efficacy of orally‐administered emu oil in attenuating inflammatory intestinal disorders8,9,10,11,12,13. Emu oil has not been approved as a drug for human use but is widely used in veterinary medicine and cosmetic and skincare products.
Emus have seasonal pattern of foraging and fat deposition. Adult emus start to gain fat in spring and summer in preparation for breeding in winter. Like other ratites, emus have paternal incubation and brooding. During the incubation period, males have little feed intake and are sustained by the energy in their stored fat, which amounts to about 10 kg.
Adipose tissue has been recognized not only as a fat storage site but also as an important endocrine organ, affecting systemic energy homeostasis, inflammatory processes and development of insulin resistance14. In adipose tissue lipid metabolism, four essential major enzymes and hormones are involved; (1) fatty acid binding protein (FABP4), a soluble protein in the cytoplasm; (2) stearoyl-CoA desaturase (SCD1), a key enzyme that regulates the synthesis of unsaturated fatty acids15; (3) adiponectin (AdipoQ), an adipokine hormone that is mainly secreted from mammalian adipose tissue, is involved with lipogenesis and insulin resistance16. In birds, adiponectin receptors are expressed in a diversity of tissues and its function may be altered from that of mammals17,18,19; (4) leptin, an adipocyte-derived hormone that regulates feeding behavior in mammals where energy expenditure via its interaction with the leptin receptor (LepR) belongs to the class I cytokine receptor superfamily20.
The FABPs are abundant intracellular proteins that play important roles in the transportation and metabolism of long-chain fatty acids14,21,22. FABP family proteins could be used as tissue specific injury markers because they have high tissue specificity, abundance in the tissue, and low molecular weight (approx. 15 kDa)21,23. The development and growth of adipose tissue are due to increases of both adipocyte cell size and cell number. The FABP4 has been extensively used as a marker for differentiated adipocytes14,24.
AdipoQ is an adipokine hormone that influences several metabolic functions including glucose utilization, lipogenesis, energy homeostasis and immunity by signaling through two distinct receptors, AdipoR1 and AdipoR2. AdipoR1 is abundantly expressed in skeletal muscle, whereas AdipoR2 is predominantly expressed in the liver. AdipoR1 and AdipoR2 genes are ubiquitously expressed in chicken tissues and their expression is altered by feed deprivation in the anterior pituitary gland and adipose tissue25.
Leptin (LEP) is an adipokine hormone that is the central mediator in a negative feedback loop that regulates energy homeostasis through the hypothalamus. In mammals, LEP administration leads to reduced food intake, increased energy expenditure and weight loss26. Unlike in mammals, LEP shows no expression in adipose tissue of the few avian species examined so far27,28, while its receptor (LepR) is still weakly expressed with no correlation to adiposity in chickens29. Previous studies revealed that avian LepR shares signal transduction pathway via administration of mammalian LEP30.
In this study, we first cloned these adipokine genes, FABP4, SCD1, AdipoQ, AdipoR1, AdipoR2, and LepR, from emu adipose tissue and investigated the seasonal gene expression profile associated fat deposition with the intention to identify genetic markers for improving fat production in the emu.
We tested the following null hypotheses:
H0 1
The selected emu adipokine genes do not share DNA and amino acid sequence similarity with homologous genes in other avian species.
H0 2
In emus, the selected adipokine genes have no seasonal variation in expression between April and November.
H0 3
In emus, the selected adipokine genes are not associated with back and abdominal fat adiposity.
H0 4
In emus, LEP gene expression can be detected in the back and abdominal fat pads.
H0 5
In emus, the selected adipokine genes are not associated with fatty acids profile in November.
H0 6
In emus, there is no difference between males and females in their fat pad fatty acids profile in November.
Methods
The study was conducted in accordance with the relevant guidelines and regulations. Methods are reported in accordance with ARRIVE guidelines (https://arriveguidelines.org).
Animal tissue
We tracked 11 adult emus (7 males, 4 females) over one breeding season (TryHarder farm, Saskatchewan, Canada). Birds were weighed and back fat and abdominal fat tissues were biopsied with a tissue punch with plunger (diameter core size: 6.0 mm, TED PELLA Ltd.) at four time points (April, June, August and November 2011). These time points were chosen as April was the time when birds started to put on fat, June was the time when birds were gaining fat, August was the time when maximum fat was put on and between August and November there were minimum fat gain, November was the start of the breeding season and birds started to use back fat as an energy source. In addition, for June, August and November, 6 birds from the same flock were also sampled. Different 6 birds were sampled for each of these 3 time points (See Supplemental Table S1). A total of 62 samples were collected. The samples were kept in RNALater (Ambion, Carlsbad, CA) at -20 °C until use. In November 2011, the birds were slaughtered and the back and abdominal fat and body weight were recorded. Emu fat was rendered into oil (see “Fatty acids analysis” section below). All studies were approved by the Animal Care and Use Committee at University of British Columbia (Certificate # A10-0106).
Total RNA extraction and cloning
Adipose tissue (0.2 g) in RNALater® was used to isolate total RNA with TRI Reagent (Sigma, St. Louis, MO) and RNeasy kit (Qiagen, Toronto, Ontario) using TRI Reagent31. Total RNA was quantified on a NanoDrop 2000 (Thermo Scientific, Wilmington, DE). The first strand cDNA was synthesized using SuperScript First-Strand Synthesis System (Invitrogen, Carlsbad, CA) and followed the manufacture protocol. Based on EST database of other avian species (mainly Gallus gallus, Meleagris gallopavo, Anser anser, Taeniopygia guttata), the gene specific primers were designed and used for partial cloning fragments to amplify the open reading frame of FABP4, SCD1, AdipoQ, AdipoR1, AdipoR2, LepR and β-actin (Table 1). Because of the uncertainty of LEP expression in avian adipose tissue, we have designed specific primers based on the conserved LEP gene region of six different species (Gallus gallus, Meleagris gallopavo, Anas platyrhynchos, Silurus asotus, Mus musculus) for amplifying LEP mRNA in emu adipose tissue (Table 2). Never the less, we were not able to amplify LEP mRNA in emu adipose tissue. The PCR was performed using pfuUltra high fidelity DNA polymerase (Stratagene, Mississauga, ON) and the PCR profile was 2 min at 94 °C, 30 s at 94 oC, 30 s at annealing temperature 53–60 °C (25 cycles) and 90 s at 72 °C, followed by a final extension at 72 °C for 10 min. The amplicon of each gene was subcloned into Zero Blunt PCRII vector (Invitrogen, Carlsbad, CA) and sequenced at NAPS Unit, University of British Columbia. Sequence data were analyzed using Lasergene SeqManII software (DNASTAR Inc., Madison, WI, https://www.dnastar.com/software/). The final sequence was confirmed by at least three clones in any segment, with at least two sequenced from either direction.
Amino acids similarity
Putative amino acid sequences of emu FABP4 (eFABP4), emu SCD1 (eSCD1), emu AdipoQ (eAdipoQ), emu AdipoR1 (eAdipoR1), emu AdipoR2 (eAdipoR2) and emu LepR (eLepR) were aligned with homologs from other species and the sequence similarity of amino acid was compared using ClustalW 2.0 (http://www.ebi.ac.uk/Tools/msa/clustalw2/). Conserved domain within a protein sequence was used NCBI (http://www.ncbi.nlm.nih.gov/Structure/cdd/wrpsb.cgi). PRINTS (http://www.bioinf.man.ac.uk/dbbrowser/PRINTS/index.php).
Phylogenetic analysis
Amino acid sequences of the eFABP4, eSCD1, eAdipoQ, AdipoR1, AdipoR2 and eLepR of the emu were aligned with those of 12 other species (including 7 other avian species) and compared using the phylogenetic and molecular evolutionary analysis software, MEGA X 10.2 (http://www.megasoftware.net/mega.php)32. Bootstrapped neighbor-joining method was used for phylogenetic reconstruction. Five hundred bootstrap replicates were employed. These 12 species were Anas platyrhynchos (wild mallard duck, ABC96712.2), Anser anser (greylag goose, AAL79836.1), Anser cygnoides (swan goose, XP_013028005.1), Taeniopygia guttata (zebra finch, XP_002199746.1), Gallus gallus (chicken, AAL30743.1), Meleagris gallopavo (turkey, XP_003205187.1), Phasianus colchicus (pheasant, XP_031446733.1), Homo sapiens (human, NP_001433.1), Mus musculus (mouse, EDL05171.1), Salmo salar (salmon, AGH92578.1), Anolis carolinensis (Carolina anole lizard, XP_003219598.1), and Xenopus tropicalis (Western clawed frog, NP_001015823.1).
Quantitative real time PCR
Back adipose tissues of the 11 adult birds in April and 17 adult birds each from June, August, and November were used (Table S1). Total RNA from each adipose sample was extracted using TRI Reagent (Invitrogen, Carlsbad, CA). The first-strand cDNA was synthesized by reverse transcribing total RNA using Oligo(dT)12–18 primer, and 2,000U Superscript III reverse transcriptase (Invitrogen, Carlsbad, CA). Primers obtained from GenBank, RACE and partial sequencing (Tables 1 and 2) were used to amplify the specific candidate genes.
For RT-PCR, gene-specific primers (Table 3) were used in PCR reactions to amplify corresponding cDNA sequences under the following PCR conditions: 94 °C for 3 min, followed by 35 cycles of (94 °C for 30 s, 53 °C for 30 s, and 72 °C for 1 min) followed by 72 °C for 10 min, using Taq polymerase in a 50-μL total reaction. Housekeeping gene eβ-actin was used as control (Table 1). For quantitative RT-PCR of eFABP4, eSCD1, eAdipoQ, eAdipoR1, eAdipoR2, and eLepR expression, 700 ng of cDNA was incubated with 10 μL iQ SYBR Green Supermix (Bio-Rad, Hercules, CA) and 10 pmol of each forward and reverse primer in a total volume of 20 μL. An initial denaturation step at 95 °C for 2:30 min followed by 40 cycles at 95 °C for 15 s, 53 °C for 15 s, and 72 °C for 30 s. Each qRT-PCR run had technical duplicate samples to generate average quantification cycle data per run (iQ5 Real-Time PCR Detection Systems, Bio-Rad, Canada). At the end of amplification, a melting curve analysis was done by heating the PCR products to 55–95 °C and the fluorescence was detected to confirm a single amplification product. Three biological replicates were averaged for quantitative analysis.
Differential expression
The relative changes in eFABP4, eSCD1, eAdipoQ, eAdipoR1, eAdipoR2, and eLepR expression over time were measured by the relative quantification of their qRT-PCR signal in the 4 time points (April, June, August, and November) and analysed by the 2−ΔΔCT method33.
Fatty acids analysis
Fat samples collected in November were thawed, weighed and ground (cold pressed). The samples were then placed in a double boiler pan and heated at 70 °C for 30 min to yield the rendered oil. The resulting oil samples were then filtered, weighed and stored under nitrogen in white plastic bottles at 4 °C.
Total lipids in the oil samples were extracted with chloroform:methanol (2:1 v/v) containing 0.01% butylated hydroxytoluene (BHT) as the antioxidant. Fatty acid methyl esters (FAME) were prepared by transesterification with Boron trifluoride (BF3) in methanol following the method described by Kitts et al.34, based on the procedure described by Ackman et al.35. After the extraction with hexane, FAMEs were analyzed by gas liquid chromatograph (GC-17A, Shimadzu Scientific Instruments Inc., Columbia, Maryland), equipped with flame ionization detector and an auto injector (AOC1400, Shimadzu Scientific Instruments Inc., Columbia, Maryland). Samples were injected onto a capillary column (30 m × 0.25 mm; 0.25 μm film thickness; liquid phase: J and W DB 23), with helium as the carrier gas. Temperature programming was used according to the method described by Budge et al.36 with minor modification. The column temperature was initially set at 153 °C for 2 min, then increased to 174 °C at 2.3 °C/min, and then to a final temperature of 220 °C at 2 °C/min with a final hold time of 2 min. Detector and injector temperatures were both set at 250 °C. Chromatographic peaks were integrated and identified using the Shimadzu software package (version 7.2.1 SP1, https://www.shimadzu.com/an/products/software-informatics/software-option/index.html), which were compared to known standards supplied by Nu-Chek Prep (Elysian, MN). Individual fatty acids are reported as weight percent of total fatty acids using mass response factors relative to C18:0.
Statistical analysis
Repeated Measures Mixed Model Least Squares ANOVA tests and multiple regression analyses were performed using JMP 8.0 (SAS Institute, Cary, North Carolina, USA). Tukey’s HSD was used for mean separation and the level of significance was defined at P < 0.05.
Statistical models:
-
1.
Seasonal variation in gene expression
$$ Y_{ijk} = \mu + Sex_{i} + e_{ij} + Season_{k} + \, \left( {Season \times Sex} \right)_{ik} + e_{ijk} $$where Yijkl = the mRNA expression level of an adipokine gene, μ = the grand mean, Sexi = the effect of sex, i = male or female, eij = the effect of replication and the sub-plot error term for testing the sex effect, j = 1, 2, 3…17, Seasonk = the effect of season, k = April, June, August, or November time point, (Season x Sex)ik = the interaction between sex and season, eijk = model error term.
Both Season and Sex and their interaction were treated as fixed terms. Replication is considered as a random effect nested in Sex.
-
2.
Association between fat gain and level of gene expression
$$ \begin{aligned} \hat{Y}_{(Apr - June)} & = \beta_{0} + \beta_{1} \left( {eFABP4_{(Apr)} } \right) + \beta_{2} \left( {eSCD1_{(Apr)} } \right) + \beta_{3} \left( {eAdipoQ_{(Apr)} } \right) + \beta_{4} \left( {eAdipoR1_{(Apr)} } \right) \\ & \quad + \beta_{5} \left( {eAdipoR2_{(Apr)} } \right) + \beta_{6} \left( {eLepR_{(Apr)} } \right) \\ \hat{Y}_{(June - Aug)} & = \beta_{0} + \beta_{1} \left( {eFABP4_{(June)} } \right) + \beta_{2} \left( {eSCD1_{(June)} } \right) + \beta_{3} \left( {eAdipoQ_{(June)} } \right) + \beta_{4} \left( {eAdipoR1_{(June)} } \right) \\ & \quad + \beta_{5} \left( {eAdipoR2_{(June)} } \right) + \beta_{6} \left( {eLepR_{(June)} } \right) \\ \hat{Y}_{(Aug - Nov)} & = \beta_{0} + \beta_{1} \left( {eFABP4_{(Aug)} } \right) + \beta_{2} \left( {eSCD1_{(Aug)} } \right) + \beta_{3} \left( {eAdipoQ_{(Aug)} } \right) + \beta_{4} \left( {eAdipoR1_{(Aug)} } \right) \\ & \quad + \beta_{5} \left( {eAdipoR2_{(Aug)} } \right) + \beta_{6} \left( {eLepR_{(Aug)} } \right) \\ \end{aligned} $$where \(\hat{Y}\) is the is the predicted value of the dependent variable (i.e., amount (kg) of fat gain during the period specified (April–June, June to August, or August to November)); β0 is the value of Y when all of the independent variables equal to zero (i.e. the Y- intercept); β1–β6 are the coefficients of the independent variables listed in the equation (eFABP4, eSCD1, eAdipoQ, eAdipoR1, eAdipoR2, eLepR which are the mRNA expression level of the adipokine genes at a month specified (April, June, or August).
-
3.
Association between fatty acid profile and gene expression
$$ \begin{aligned} \hat{Y} & = \beta_{0} + \beta_{1} \left( {Sex_{(female)} } \right) + \beta_{2} \left( {eFABP4_{(Nov)} } \right) + \beta_{3} \left( {eSCD1_{{\left( {Nov} \right)}} } \right) + \beta_{4} \left( {eAdipoQ_{(Nov)} } \right) + \beta_{5} \left( {eAdipoR1_{(Nov)} } \right) \\ & \quad + \beta_{6} \left( {eAdipoR2_{(Nov)} } \right) + \beta_{7} \left( {eLepR_{(Nov)} } \right) \\ \end{aligned} $$where \(\hat{Y}\) is the predicted value of proportion of a Fatty Acid in the oil extracted from emu fat tissue collected in November; β0 is the value of Y when all of the independent variables are equal to zero (i.e. the Y- intercept); β1–β7 are the coefficients of the independent variables listed in the equation; Sex(female) is a one for female birds and zero for male birds; eFABP4, eSCD1, eAdipoQ, eAdipoR1, eAdipoR2, and eLepR are the mRNA expression level of the adipokine genes in November.
Ethics approval
All experiments were performed in accordance with protocols reviewed and approved by the UBC Animal Care Committee (Certificate # A10-0106).
Results
Isolation, amplification and cloning
The full-length cDNA of eFABP4, eSCD1, eAdipoQ, eAdpoiR1, eAdipoR2, eLepR, and eβ-actin were isolated and cloned from emu adipose tissue with gene specific primers conserved by other avian species EST database (Table 3). Nomenclature of each gene was based on identities of the primary gene structure to other homologs (Table 1), and was assigned the following GenBank accession numbers: eFABP4 (JN663389), eSCD1 (JN663390), eAdipoQ (JQ289558.1), eAdipoR1 (JQ289559.1), eAdipoR2 (JQ289560.1), eLepR (JQ289561), and housekeeping gene eβ-actin (JN663391).
Nucleic acid sequence of eFABP4 (92–94% similarity) and eAdipoR2 (92–94% similarity), showed the highest similarity with orthologues of other avian species (wild mallard, Greylag goose, Swan goose, zebra finch, chicken, turkey, and pheasant) (Table 4). eAdipoR1 also showed high similarity (92–94%) with other avian species with the exception of Zebra finch (only 90% similar). eSCD1 and eAdipoQ were the next high with 88–91% and 80–85%, respectively. We were not able to amplify any eLEP mRNA in emu adipose tissue. eLepR showed the most divergent among the 6 genes examined with similarity ranging from 76 (zebra finch) to 88% (Greylag and Swan geese).
Amino acid sequence similarity
The primary protein structure assigned the nomenclature and Genbank accession numbers are: eFABP4 (AET74082), eSCD1 (AET74083), eAdipoQ (AFF19461), eAdopoR1 (AFF19462), eAdipoR2 (AFF19463), eLepR (AFF19464) and eβ-actin (AET74084). The eFABP4 encodes a protein of 132 amino acids and shares high similarities with other avian species (average 96.1%) (Table 5). The eSCD1 encodes a protein of 360 amino acids and also shares high similarities with other avian species (average 94%). eAdipoQ encodes a protein of 245 amino acids and shows average 88.5% similarities with other avian species. eAdipoR1 and eAdipoR2 are the most conservative proteins we have examined in this study. eAdipoR1 encodes a protein of 352 amino acids, shares 100% similarity with Swan goose and an average 89.8% similarities with all other species examined. eAdipoR2 encodes a protein of 385 amino acids and shows an average of 92.3% similarities with all other species. The eLepR encodes 1,151 amino acids and shares 90% similarities with the waterfowl group, 86% similarities with chicken, turkey and pheasant, and 79% with zebra finch. (Table 5).
Phylogeny tree
Phylogeny trees of the eFABP1, eSCD1, eAdipoQ, eAdipoR1, eAdipoR2 and eLepR in this study in association with other selected species were constructed to illustrate their genetic relatedness (Fig. 1). Generally speaking, clustering of amino acid sequences resulted in trees showing that emu was closer to zebra finch and migrating waterfowl (swan goose, graylag goose, and mallard) than domestic and gallinaceous birds (turkey, chicken and pheasant). The eFABP4 and eSCD1 are less divergent than eAdipoQ. eAdipoR1 and eAdipoR2 are both less divergent than eAdipoQ, while eAdipoR1 is the least divergent of the emu proteins examined. On the other hand, eLepR is the most divergent from the non-avian proteins.
Seasonal variation in emu back and abdominal fat weight gain
We recorded the body weights of the birds in April, June, August and November. After the birds were slaughtered in November, the back and abdominal fat pads were dissected out and weighed. We also weighed the bird carcasses without the fat pads. The carcass weight (34.8 ± 1.2 kg) was not significantly (P < 0.91) different from the April body weight (34.6 ± 1.2 kg). We therefore concluded that the difference in body weight between two time points would be a good estimate of fat gained between the two time points. In this study (Fig. 2), emus gained fat from April to August. From August to November (beginning of breeding season), there was very little fat gain. The mean fat gain from April to November was 11.3 ± 3.28 kg. There was no significant difference between males and females in fat gain.
Seasonal variation in eFABP4 expression
The level of eFABP expression was highest in November, intermediate in April, and low in June and August (Table 6 and Fig. 3A). Sex effect and the Season X Sex interaction were not significant.
Regression of fat gained (kg) on eFABP4 expression levels
The amount of fat gained between April and June regressed significantly and positively on eFABP4 expression level in April (Table 8 and Supplemental Fig. 1A). The amount of fat gained between June and August regressed significantly and positively on eFABP4 expression level in June. However, the amount of fat gained between August and November regressed significantly but negatively on eFABP4 expression level in August.
Seasonal variation in eSCD1 expression
There was a significant difference between males and females in their seasonal variation (Season X Sex interaction) in eSCD1 expression level (Table 7 and Fig. 3A). Male eSCD1 expression level was slightly higher (not statistically significant) in April and remained low from June to November. Female eSCD1 level was significantly higher in August but not significantly different than male levels in April, June and November.
Regression of fat gained (kg) on eSCD1 expression levels
Fat gain was not associated with eSCD1 expression level except from June to August. The amount of fat gained during that period significantly regressed on June eSCD1 expression level (Table 8 and Supplemental Fig. 1B).
Seasonal variation in eAdipoQ expression
eAdipoQ expression level was not significantly (P = 0.23) affected by season and there was no significant (P = 0.10) difference between males and females (Table 6 and Fig. 3A).
Regression of fat gained (kg) on eAdipoQ expression level
Fat gain from April to June was not associated with eAdipoQ expression level. Fat gain from June to August significantly regressed on June eAdipoQ level (Table 8 and Supplemental Fig. 1C). Fat gain from August to November significantly but negatively on August eAdipoQ level.
Seasonal variation in eAdipoR1 expression
eAdipoR1 expression was significantly higher in April than the rest of the year (Table 6 and Fig. 3B). Sex effect and the Season X Sex interaction were not significant.
Regression of fat gained (kg) on eAdipoR1 expression level
The amount of fat gained from April to June significantly but negatively regressed on April eAdipoR1 level (Table 7 and Supplemental Fig. 1D). From June to August, fat gain regressed significantly on June eAdipoR1 level.
Seasonal variation in eAdipoR2 expression
eAdipoR2 expression level was highest in April, intermediate in June and August, and lowest in November (Table 6 and Fig. 3B). Sex effect and the Season X Sex interaction were not significant.
Regression of fat gained (kg) on eAdipoR2 expression level
Fat gain from April to August was not affected by eAdipoR2 level. Fat gain from August to November regressed significantly on August eAdipoR2 level (Table 7 and Supplemental Fig. 1E).
Seasonal variation in eLepR expression
eLepR expression level was highest in April, intermediate in June and August, and lowest in November (Table 6 and Fig. 3B). Sex effect and the Season X Sex interaction were not significant.
Regression of fat gained (kg) on eLepR expression level
Amount of fat gained from June to August regressed significantly and negatively on June eLepR level (Table 7 and Supplemental Fig. 1F).
Fatty acid profile
From oil extracted from back and abdominal fat in November, the predominant fatty acids were Oleic Acid and Palmitic Acid (Table 9). Female oil was significantly (P < 0.0117) higher in %Palmitic Acid than male oil. Male oil was significantly (P < 0.036) higher in %Oleic Acid than female oil. (Table 10 and Supplemental Fig. 2A). Percent Palmitic Acid regress negatively (P = 0.043, R2 = 0.48) on eAdipoR1 November expression (Table 10 and Supplemental Fig. 2B). Percent Linoleic acid regressed significantly (P = 0.0008) but negatively (R2 = 0.54) on November AdipoR2 level (Table 10 and Supplemental Fig. 2C). Percent α-linolenic acid level also regressed significantly (P = 0.0011) but negatively (R2 = 0.52) on November AdipoR2 level (Table 10 and Supplemental Fig. 2D).
Discussion
In order to better understand the genetics of adiposity in emu, a bird that has huge seasonal variation in fat deposition and metabolism, we have selected 7 adipokine genes for examination that have been established to be involved with fat deposition and metabolism. We were able to reject all the null hypotheses that we set out to test. Of the 6 genes (eFABP4, eSCD1, eAdipoQ, eAdipoR1, eAdipoR2, and eLepR) expressed, they shared high nucleotides sequences and amino acids sequences similarity with other avian species (H0 1 rejected). Except for eAdipoQ, there were seasonal variation in the mRNA expression between April and November (H0 2 rejected), and the expression level of all 6 genes were associated with back fat weight gain during some time in the season (H0 3 rejected). eAdipoR1 expression level was associated with the % of Palmitic acid in emu oil while eAdipoR2 level was associated with % Lenoleic acid and % α-Linolenic Acid in emu oil (H0 5 rejected). There were significant differences between males and females in % Palmitic acid and % Oleic Acid in emu oil (H0 6 rejected).
We were not able to detect any eLEP mRNA expression in the emu adipose tissue. Based on the lack of LEP expression in the adipose tissue of zebra finch37, jungle fowl38, several lines of commercial chickens39, rock dove40, and quail29, Friedman and Seroussi28 suggested that LEP is not expressed in avian adipose tissue. More avian species have to be examined to confirm this observation. Our result from emu, a ratite that is phylogenetically distant from the birds examined so far, provided support to their observations (H04 rejected). In birds, LEP is expressed in brain tissue, adrenal glands and gonads, but is not expressed in the liver and is generally not detectable in the blood. LepR receptors are predominantly expressed in the pituitary. Seroussi et al.29 reported that in chicken, ducks, and quail adipose tissue, LEP and LepR were scarcely transcribed, and the expression level was not correlated to adiposity. They proposed that LEP in birds may act as an autocrine or paracrine instead of being a circulating hormone as in mammals. These observations, mostly from chicken studies, allowed Friedman and Seroussi28 to speculate that avian adipose tissue does not control appetite, insulin resistance, or inflammation.
We have detected low expression levels of eLepR in emu fat tissue. Expression level was highest in April and stepwise decreased to the lowest level in November, which was opposite to the fat weight gain trend. The amount of back and retroperitoneal fat gain between June and August regressed significantly but negatively on eLepR June expression level. Since there was no eLEP expression in emu fat tissue, it seems likely that LEP in emu is still a circulating hormone that affects fat deposition and metabolism. Our phylogenetic analysis found that emu LepR is closer to those of migrating waterfowl than other bird species examined. In mammals, LEP specially repressed the expression of SCD1 and reduced the accumulation of hepatic triglycerides, cholesterol esters and VLDL synthesis26,41,42. It is suspected that the role of LEP in governing adipose tissue regulation of appetite and energy expenditure has been altered in birds28. Never the less, the relationship between LEP and the loss of appetite over the winter breeding period in emus remains to be studied.
eSCD1 is expressed in emu adipose tissue. There was little seasonal variation in expression except that fat samples collected from females in August had a significant 35-fold increase in expression. Fat weight gained between June and August regressed significantly on June eSCD1 expression level. Individuals that had high fat weight gain would have high eSCD1 expression but low eLepR expression and vice versa for individuals that had little fat weight gain. This would indicate that emu leptin can suppress the expression of eSCD1 as seen in mammals. SCD1 is also transcriptionally regulated by a number of factors in mammals, including sterol regulatory element-binding protein-1 (SREBP-1) and polyunsaturated fatty acids43,44.
SCD1 is predominately located in the endoplasmic reticulum and catalyzes the rate-limiting step in the cellular synthesis of mono-unsaturated fatty acids from saturated fatty acids15,45. SCD-1 converts the saturated fatty acids, palmitic acid (16:0) and stearic acid (18:0), to generate the mono-unsaturated fatty acids, palmitoleic (16:1 n7) and oleic acid (18:1 n9), which are accumulated as triglycerides in adipose tissues45,46,47,48. Oleic acid is the predominant fatty acid in emu adipose tissue. A proper ratio of saturated fatty acids to mono-unsaturated fatty acids contributes to membrane fluidity. In mice, SCD-1, known as a lipid synthesis enzyme, also plays a role in upregulating lipid mobilization through its desaturation product, oleic acid49. Specific unsaturated fatty acids are preferentially used during metabolism over saturated fatty acids50,51,52.
Fat storage and usage in birds are mainly for survival, migration and reproductive performance53,54,55,56. Catbirds increased adipose storage during spring and autumn migration, showing increased rates of basal lipolysis during migration and tropical overwintering57. In our study, emus started gaining fat in April and the rate of gain was maximized between June and August. Fat weight gain between June and August significantly regressed on June eSCD1 expression. From August to November fat gain was minimal. It was during this period when female emus were getting ready to lay eggs. There was a 35-fold increase in eSCD1 expression in females in August. They may be optimizing the fatty acid composition of the adipose tissue to get ready for the mobilization of lipids into the ovary for formation of the egg yolk. Unfortunately, we only had the fatty acid profile of emu oil collected in November and by that time eSCD1 expression was extremely low and we found no association of eSCD1 expression and fatty acid profile of emu oil.
FABPs are a family of proteins known as intracellular lipid chaperones that regulate lipid trafficking and responses in cells58. FABP genes have been shown to be associated with lipid metabolism (lipogenesis and lipolysis), homeostasis in adipocytes, marbling and back fat deposition59,60,61. FABP4 is highly expressed in adipocytes and its expression can be highly induced during adipocyte differentiation which is transcriptionally controlled by peroxisome proliferator-activated receptor (PPAR) γ agonists, fatty acids, dexamethasone and insulin57,62. It has also been postulated that FABP4 can activate hormone sensitive lipase (HSL) in adipocytes to regulate lipolysis63,64. In chickens, earlier studies that examined the relationship of FABP4 with growth and fat accumulation reported results ranging from no association with fat accumulation in hybrid chickens65, significant positive correlation with abdominal fat in Luyuan chickens66, to correlation with growth depression in Arbor Acre genotype but strong positive association with growth performance of Cobb genotype61. In our study, eFABP4 expression in emu adipose tissue was high both in April and November and relatively low in June and August. Fat gain from April to August regressed positively on April and June eFABP-4 expression, respectively. However, fat gain from August to November regressed negatively on August eFABP4 expression. From August to November, fat gain was minimal and a couple of birds even had negative fat gain. By this time of the year, emus started to draw on the energy from the accumulated fat and the role of FABP4 switched from lipogenesis to lipolysis57. eFABP4 expression was highest in November and this may be an indication that the birds were more and more dependent on fat for energy because they have very little feed intake during breeding. In geese, FABP4 was found to be involved in lipid transportation and metabolic process, follicle development and final egg production. FABP4 was upregulated in the laying group compared with the pre-laying group67.
AdipoQ has been originally identified as a protein secreted and expressed exclusively in adipose tissue68,69,70. AdipoQ showed many functions like expanding fatty acids oxidation, controlling glucose level and managing receptor activity. In humans, Adiponectin is known to stimulate the expression of FABP16. In chickens, adiponectin plays important roles in energy homeostasis, body weight, lipid metabolism, and insulin sensitivity71,72,73. In broiler chickens, Tahmoorespur et al.74 showed that AdipoQ expression in adipose tissue was inversely related to chicken abdominal fat deposition levels. Adiponectin has an effect on the impairment of adipocyte differentiation, which contributes to the negative regulation of fat deposition in chicken71. In adipose tissue of adult chickens, AdipoQ expression is higher in females than males, but AdipoR1 expression was higher in males than females17. In female birds, Adiponectin is secreted into the blood from adipocytes with a higher serum level75. In emus, eAdipoQ expression did not show any seasonal (April to November) nor sexual variation. Emu fat gain from June to August regressed positively on June eAdipoQ expression but fat gain from August to November regressed negatively on August eAdipoQ expression. Similarly, fat gain from June to August also regressed positively on June eAdipoR1 expression while fat gain from August to November regressed negatively on August eAdipoR2 expression. White-throated sparrows increase fat deposits during pre-migratory periods and rely on these fat stores to fuel migration. In the adipose tissue, there was a significant change in the biological control of adipokine expression from pre-migratory conditions to migratory conditions. It was proposed that Adiponectin may play a role in the switch from fat deposition to lipid metabolism as the main source of energy to fuel migratory flight in birds76. In emus, eAdipoR1/R2 expression was highest in April, before the birds started gaining fat. eAdipoR1/R2 expression declined until the lowest level in November. Interestingly, in the oil extracted from emu fat in November, the % of Palmitic Acid (C16:0) regressed negatively on November eAdipoR1 expression. Both Lenoleic Acid (C18:2n6) and α-linolenic acid (C18:3n3) regressed negatively on November eAdipoR2 expression. These observations support the role of Adiponectin in lipid metabolism for converting the stored fat to energy during the period of low feed intake50,51. In emus, back fat showed a higher level of protein, cholesterol, C16:1 and the elements K, P, Si, Na, Ca, Mg, Fe, Zn, Se and Cu than abdominal fat. Abdominal fat was characterized by higher content of fat and ash, as well as Mn and Ba. Regardless of back or abdominal fat, there was generally high content of MUFA and PUFA. Males have higher content of Si, Ca, Cu, Sr in the adipose tissue than female77. In chickens, the most promising candidate genes affecting polyunsaturated fatty acids percentage were FADS2, DCN, FRZB, OGN, PRKAG3, LHFP, CHCHD10, CYTL1, FBLN5, and ADGRD178.
There are two major methods of quantitative trait loci (QTL) determination, the candidate gene approach and the whole-genome scanning. The candidate gene approach is used to detect QTL (Quantitative Trait Loci) responsible for genetic variation in the traits of interest. In chickens, FABP4 gene polymorphism has been associated with abdominal fat weight and percentage of abdominal fat, and FABP4 gene could be a candidate locus or linked to a major gene(s) that affects abdominal fat content79. In pigs, SCD-1 expression plays a critical role in adipocyte differentiation and has been identified as the promising candidate gene for less back fat deposition80,81. Fat deposition in emu is seasonal77. Under natural conditions, increased fat deposition in birds is for energy storage to cope with migration or periods when food is scarce, and is not associated with obesity. In addition to being an energy storage organ, the adipose is also an endocrine organ influencing reproduction, feeding behaviour, insulin sensitivity and disease resistance75. Whether genetic selection for increased fat deposition would lead to complications with obesity must be considered. In broiler chickens and turkeys, the selection for fast growth rate inevitably led to increase abdominal fat deposition and drastic reduction in breeder fertility82,83. Additionally, one has to consider whether selection for increased fat deposition would alter the fatty acids composition and other bioactive ingredients in the adipose tissue and thus affecting the efficacy of the emu oil5.
Conclusion
There has not been any reported genetic selection studies for increasing subcutaneous fat deposition in farm animals and no genetic improvement of emu productive traits has been carried out due to their short history of domestication compared to other livestock species84. Our study has laid down the groundwork for identifying promising candidate genes for such purpose. A follow-up whole-genome scanning study85 explored the gene networks in emu adipose tissue affecting fat deposition and utilization and identified marker genes that deserve further analyses to develop novel molecular markers that can be applied to improve fat production in emus86,87.
Data availability
The full-length cDNA of eFABP4, eSCD1, eAdipoQ, eAdpoiR1, eAdipoR2, eLepR, and eβ-actin were assigned the following GenBank accession numbers: eFABP4 (JN663389), eSCD1 (JN663390), eAdipoQ (JQ289558.1), eAdipoR1 (JQ289559.1), eAdipoR2 (JQ289560.1), eLepR (JQ289561), and housekeeping gene eβ-actin (JN663391). The primary protein structure assigned the nomenclature and Genbank accession numbers are: eFABP-4 (AET74082), eSCD-1 (AET74083), eAdipoQ (AFF19461), eAdopoR1 (AFF19462), eAdipoR2 (AFF19463), eLepR (AFF19464) and eβ-actin (AET74084). The datasets generated during and/or analysed during the current study are available from the corresponding author on reasonable request.
References
Whitehouse, M. W., Turner, A. G., Davis, C. K. & Roberts, M. S. Emu oil(s): A source of non-toxic transdermal anti-inflammatory agents in aboriginal medicine. Inflammopharmacology 6, 1–8. https://doi.org/10.1007/s10787-998-0001-9 (1998).
Politis, M. J. & Dmytrowich, A. Promotion of second intention wound healing by emu oil lotion: Comparative results with furasin, polysporin, and cortisone. Plast. Reconstr. Surg. 102, 2404–2407. https://doi.org/10.1097/00006534-199812000-00020 (1998).
Qiu, X. W. et al. Anti-inflammatory activity and healing-promoting effects of topical application of emu oil on wound in scalded rats. Di Yi Jun Yi Da Xue Xue Bao. 25, 407–410 (2005).
Bennett, D. C., Code, W. E., Godin, D. V. & Cheng, K. M. Comparison of the antioxidant properties of emu oil with other avian oils. Aust. J. Exp. Agric. 48, 1345–1350. https://doi.org/10.1071/EA08134 (2008).
Kennewell, T. L., Mashtoub, S., Howarth, G. S., Cowin, A. J. & Kopecki, Z. Antimicrobial and healing-promoting properties of animal and plant oils for the treatment of infected wounds. Wound Pract. Res. 27, 175–183. https://doi.org/10.33235/wpr.27.4.175-183 (2019).
López, A. et al. Effect of emu oil on auricular inflammation induced with croton oil in mice. Am. J. Vet. Res. 12, 1558–1561 (1999).
Yoganathan, S. et al. Antagonism of croton oil inflammation by topical emu oil in CD-1 mice. Lipids 38, 603–607. https://doi.org/10.1007/s11745-003-1104-y (2003).
Lindsay, R., Geier, M., Yazbeck, R., Butler, R. & Howarth, G. Orally administered emu oil decreases acute inflammation and alters selected small intestinal parameters in a rat model of mucositis. Br. J. Nutr. 104, 513–519. https://doi.org/10.1017/S000711451000084X (2010).
Abimosleh, S. M., Tran, C. D. & Howarth, G. S. Emu oil: A novel therapeutic for disorders of the gastrointestinal tract?. J. Gastroenterol. Hepatol. 27, 857–861. https://doi.org/10.1111/j.1440-1746.2012.07098.x (2012).
Mashtoub, S. Potential therapeutic applications for emu oil. Lipid Technol. 29, 28–31. https://doi.org/10.1002/lite.201700009 (2017).
Safaeian, R. et al. Emu oil reduces disease severity in a mouse model of chronic ulcerative colitis. Scand. J. Gastroenterol. 54, 273–280. https://doi.org/10.1080/00365521.2019.1581253 (2019).
Barker, S. J., Howarth, G. S., Chartier, L. C., Scherer, B. L. & Mashtoub, S. Mucosal stimulation following oral administration of emu oil represents a process of normal intestinal growth in rats. Aust. J. Herb. Naturop. Med. 32, 15–23 (2020).
Chartier, L. C., Howarth, G. S., Trinder, D. & Mashtoub, S. Emu oil and grape seed extract reduce tumour burden and disease parameters in murine colitis-associated colorectal cancer. Carcinogenesis 42, 202–209. https://doi.org/10.1093/carcin/bgaa099 (2020).
Storch, J. & Thumser, A. E. Tissue-specific functions in the fatty acid-binding protein family*. J. Biol. Chem. 285, 32679–32683. https://doi.org/10.1074/jbc.R110.135210 (2010).
Ntambi, J. M. Regulation of stearoyl-CoA desaturase by polyunsaturated fatty acids and cholesterol. J. Lipid Res. 40, 1549–1558. https://doi.org/10.1016/S0022-2275(20)33401-5 (1999).
Choi, H. M., Doss, H. M. & Kim, K. S. Multifaceted physiological roles of adiponectin in inflammation and diseases. Int. J. Mol. Sci. 21, 1219. https://doi.org/10.3390/ijms21041219 (2020).
Maddineni, S. et al. Adiponectin gene is expressed in multiple tissues in the chicken: Food deprivation influences adiponectin messenger ribonucleic acid expression. Endocrinology 146, 4250–4256. https://doi.org/10.1210/en.2005-0254 (2005).
Ramachandran, R. et al. Expression of adiponectin and its receptors in avian species. Gen. Comp. Endocrinol. 190, 88–95. https://doi.org/10.1016/j.ygcen.2013.05.004 (2013).
Zhang, R. et al. Expression profiles and associations of adiponectin and adiponectin receptors with intramuscular fat in Tibetan chicken. Br. Poult. Sci. 58, 151–157. https://doi.org/10.1080/00071668.2016.1268252 (2017).
Adachi, H., Takemoto, Y., Bungo, T. & Ohkubo, T. Chicken leptin receptor is functional in activating JAK-STAT pathway in vitro. J Endocrinol. 197, 335–342. https://doi.org/10.1677/JOE-08-0098 (2008).
Funaoka, H., Kanda, T. & Fujii, H. Intestinal fatty acid-binding protein (I-FABP) as a new biomarker for intestinal diseases. Rinsho byori Jpn. J. Clin. Pathol. 58, 162–168 (2010).
Owada, Y. Fatty acid binding protein: Localization and functional significance in the brain. Tohoku J. Exp. Med. 214, 213–220 (2008).
Relja, B. et al. Intestinal-FABP and Liver-FABP: Novel markers for severe abdominal injury. Acad. Emerg. Med. 17, 729–735. https://doi.org/10.1111/j.1553-2712.2010.00792.x (2010).
Shan, T., Liu, W. & Kuang, S. Fatty acid binding protein 4 expression marks a population of adipocyte progenitors in white and brown adipose tissues. FASEB 27, 277–287. https://doi.org/10.1096/fj.12-211516 (2013).
Ramachandran, R., Ocón-Grove, O. M. & Metzger, S. L. Molecular cloning and tissue expression of chicken AdipoR1 and AdipoR2 complementary deoxyribonucleic acids. Domest. Anim. Endocrinol. 33, 19–31 (2007).
Cohen, P. & Friedman, J. M. Leptin and the control of metabolism: Role for stearoyl-CoA desaturase-1 (SCD-1). J. Nutr. 134, 2455S-2463S. https://doi.org/10.1093/jn/134.9.2455S (2004).
Prokop, J. W. et al. Discovery of the elusive leptin in birds: Identification of several ‘missing links’ in the evolution of leptin and its receptor. PLoS ONE 9, e92751. https://doi.org/10.1371/journal.pone.0092751 (2014).
Friedman-Einat, M. & Seroussi, E. Avian leptin: Bird’s-eye view of the evolution of vertebrate energy-balance control. Trends Endocrinol. Metab. 30, 819–832. https://doi.org/10.1016/j.tem.2019.07.007 (2019).
Seroussi, E. et al. Identification of the long-sought leptin in chicken and duck: Expression pattern of the highly GC-rich avian leptin fits an autocrine/paracrine rather than endocrine function. Endocrinology 157, 737–751. https://doi.org/10.1210/en.2015-1634 (2016).
Tartaglia, L. A. et al. Identification and expression cloning of a leptin receptor, OB-R. Cell 83, 1263–1271. https://doi.org/10.1016/0092-8674(95)90151-5 (1995).
Trevaskis, J. L. et al. Glucagon-like peptide-1 receptor agonism improves metabolic, biochemical, and histopathological indices of nonalcoholic steatohepatitis in mice. Am. J. Physiol. Gastrointest. Liver Physiol. 302, G762–G772 (2012).
Tamura, K. et al. Mega5: Molecular evolutionary genetics analysis using maximum likelihood, evolutionary distance, and maximum parsimony methods. Mol. Biol. Evol. 28, 2731–2739. https://doi.org/10.1093/molbev/msr121Medline (2011).
Livak, K. J. & Schmitten, T. D. Analysis of relative gene expression data using real-time quantitative PCR and the 2−ΔΔCT method. Methods 25, 402–408 (2001).
Kitts, D. D., Huynh, M. D., Hu, C. & Trites, A. W. Season variation in nutrient composition of Alaskan walleye pollock. Can. J. Zool. 82, 1408–1415 (2004).
Ackman, R. G., Epstein, S. & Eaton, C. A. Differences in the fatty acid compositions of blubber fats from northwestern Atlantic finwhales (Balaenoptera physalus) and harp seals (Pagophilus groenlandica). Comp. Biochem. Physiol. Part B Comp. Biochem. 40, 683–697. https://doi.org/10.1016/0305-0491(71)90143-X (1971).
Budge, S. M., Iverson, S. J., Bowen, W. D. & Ackman, R. G. Among- and within- species variation in fatty acid signatures of marine fish and invertebrates on the Scotian Shelf, Georges Bank and southern Gulf of St. Lawrence. Can. J. Fish. Aquat. Sci. 59, 886–898. https://doi.org/10.1139/f02-062 (2002).
Huang, G., Li, J., Wang, H., Lan, X. & Wang, Y. Discovery of a novel functional leptin protein (LEP) in Zebra finches: Evidence for the existence of an authentic avian leptin gene predominantly expressed in the brain and pituitary. Endocrinology 155, 3385–3396. https://doi.org/10.1210/en.2014-1084 (2014).
Farkašová, H., Hron, T., Pačes, P. & Elleder, D. Identification of a GC-rich leptin gene in chicken. Agri Gene 1, 88–92 (2016).
Bornelov, S. et al. Comparative omics and feeding manipulations in chicken indicate a shift of the endocrine role of visceral fat towards reproduction. BMC Genom. 19, 295 (2018).
Friedman-Einat, M. et al. Discovery and characterization of the first genuine avian leptin gene in the rock dove (Columba livia). Endocrinology 155, 3376–3384 (2014).
Ntambi, J. M. et al. Loss of stearoyl–CoA desaturase-1 function protects mice against adiposity. Proc. Natl. Acad. Sci. 99, 11482–11486. https://doi.org/10.1073/pnas.132384699 (2002).
Miyazaki, M., Kim, Y. C., Gray-Keller, M. P., Attie, A. D. & Ntambi, J. M. The biosynthesis of hepatic cholesterol esters and triglycerides is impaired in mice with a disruption of the gene for stearoyl-CoA desaturase 1. Biol. Chem. 275, 30132–30138. https://doi.org/10.1074/jbc.M005488200 (2000).
Ntambi, J. M., Miyazaki, M. & Dobrzyn, A. Regulation of stearoyl-CoA desaturase expression. Lipids 39, 1061–1065. https://doi.org/10.1007/s11745-004-1331-2 (2004).
Zheng, Y. et al. Scd3—A novel gene of the stearoyl-CoA desaturase family with restricted expression in skin. Genomics 71, 182–191. https://doi.org/10.1006/geno.2000.6429 (2001).
Paton, C. M. & Ntambi, J. M. Biochemical and physiological function of stearoyl-CoA desaturase. Am. J. Physiol. Endocrinol. Metab. 297(1), E28–E37. https://doi.org/10.1152/ajpendo.90897.2008 (2009).
Enoch, H. G., Catala, A. & Strittmatter, P. Mechanism of rat liver microsomal stearyl-CoA desaturase: Studies of the substrate specificity, enzyme–substrate interactions, and the function of lipid. J. Biol. Chem. 251, 5095–5510. https://doi.org/10.1016/S0021-9258(17)33223-4 (1976).
Dridi, S., Taouis, M., Gertler, A., Decuypere, E. & Buyse, J. The regulation of stearoyl-CoA desaturase gene expression is tissue specific in chickens. J. Endocrinol. 192, 229–236 (2007).
Liu, X. & Ntambi, J. Atherosclerosis: Keep your macrophages in shape. Nat. Med. 15, 1357–1358. https://doi.org/10.1038/nm1209-1357 (2009).
Zou, W. et al. Addition of cationic guar-gum and oleic acid improved the stability of plasma emulsions prepared with enzymatically hydrolyzed egg yolk. Food Hydrocoll. 105, 105827. https://doi.org/10.1016/j.foodhyd.2020.105827 (2020).
Leyton, J., Drury, P. & Crawford, M. Differential oxidation of saturated and unsaturated fatty acids in vivo in the rat. Br. J. Nutr. 57, 383–393. https://doi.org/10.1079/BJN19870046 (1987).
Raclot, T. & Groscolas, R. Selective mobilization of adipose tissue fatty acids during energy depletion in the rat. J. Lipid Res. 36, 2164–2173. https://doi.org/10.1016/S0022-2275(20)39200-2 (1996).
McKenzie, D., Higgs, D., Dosanjh, B., Deacon, G. & Randall, D. J. Dietary fatty acid composition influences swimming performance in Atlantic salmon (Salmo salar) in seawater. Fish Physiol. Biochem. 19, 111–122. https://doi.org/10.1023/A:1007779619087 (1998).
Blem, C. R. Patterns of lipid storage and utilization in birds. Am. Zool. 16, 671–684. https://doi.org/10.1093/icb/16.4.671 (1976).
Fokidis, H. B. et al. Unpredictable food availability induces metabolic and hormonal changes independent of food intake in a sedentary songbird. J. Exp. Biol. 215, 2920–2930. https://doi.org/10.1242/jeb.071043 (2012).
Conway, C., Eddleman, W. & Simpson, K. Seasonal changes in fatty acid composition of the wood thrush. Condor 96, 791–794. https://doi.org/10.2307/1369482 (1994).
Pierce, B. J. & McWilliams, S. R. Seasonal changes in composition of lipid stores in migratory birds: Causes and consequences. Condor 107, 269–279. https://doi.org/10.1093/condor/107.2.269 (2005).
Corder, K. R., DeMoranville, K. J., Russell, D. E., Huss, J. M. & Schaeffer, P. J. Annual life-stage regulation of lipid metabolism and storage and association with PPARs in a migrant species: The gray catbird (Dumetella carolinensis). J. Exp. Biol. 219, 3391–3398. https://doi.org/10.1242/jeb.141408 (2016).
Furuhashi, M., Ishimura, S., Ota, H. & Miura, T. Lipid chaperones and metabolic inflammation. Int. J. Inflam. 2011, 642612. https://doi.org/10.4061/2011/642612 (2011).
Michal, J. J., Zhang, Z. W., Gaskins, C. T. & Jiang, Z. The bovine fatty acid binding protein 4 gene is significantly associated with marbling and subcutaneous fat depth in Wagyu × Limousin F2 crosses. Anim. Genet. 37, 400–402. https://doi.org/10.1111/j.1365-2052.2006.01464.x (2006).
Hertzel, A. V. et al. Lipid metabolism and adipokine levels in fatty acid-binding protein null and transgenic mice. Am. J. Physiol. Endocrinol. Metab. 290, E814–E882 (2006).
Ghaly, M. M. & Li, M. Expression of adipocyte fatty acid-binding protein gene in abdominal adipose tissue and its association with growth and fatness traits in commercial meat type chickens. J. Genom. Gene Study 1(1), 5 (2018).
Furuhashi, M., Saito, S., Shimamoto, K. & Miura, T. Fatty acid-binding protein 4 (FABP4): Pathophysiological insights and potent clinical biomarker of metabolic and cardiovascular diseases. Clin. Med. Insights Cardiol. 8, 23–33. https://doi.org/10.4137/CMC.S17067 (2014).
Shen, W. J., Sridhar, K., Bernlohr, D. A. & Kraemer, F. B. Interaction of rat hormone-sensitive lipase with adipocyte lipid-binding protein. Proc. Natl. Acad. Sci. U. S. A. 96, 5528–5532 (1999).
Smith, A. J., Sanders, M. A., Juhlmann, B. E., Hertzel, A. V. & Bernlohr, D. A. Mapping of the hormone-sensitive lipase binding site on the adipocyte fatty acid-binding protein (AFABP). Identification of the charge quartet on the AFABP/aP2 helix-turn-helix domain. J. Biol. Chem. 283, 33536–33543 (2008).
Li, W. J. et al. Gene expression of heart- and adipocyte-fatty acid-binding protein and correlation with intramuscular fat in Chinese chickens. Anim. Biotechnol. 19, 189–193 (2008).
Ye, M. H., Chen, J. L., Zhao, G. P., Zheng, M. Q. & Wen, J. Associations of A-FABP and H-FABP markers with the content of intramuscular fat in Beijing-You chicken. Anim. Biotechnol. 21, 14–24 (2010).
Cao, Z. et al. Comparative proteomic analysis of ovaries from Huoyan geese between pre-laying and laying periods using an iTRAQ-based approach. Poult. Sci. 97, 2170–2182. https://doi.org/10.3382/ps/pey029 (2018).
Hu, E., Liang, P. & Spiegelman, B. M. AdipoQ is a novel adipose-specific gene dysregulated in obesity. J. Biol. Chem. 271, 10697–10703 (1996).
Maeda, K. et al. cDNA cloning and expression of a novel adipose specific collagen-like factor, apM1 (AdiPose most abundant gene transcript 1). Biochem. Biophys. Res. Commun. 221, 286–289. https://doi.org/10.1006/bbrc.1996.0587 (1996).
Yuan, J., Liu, W., Liu, Z. L. & Li, N. cDNA cloning, genomic structure, chromosomal mapping and expression analysis of ADIPOQ (adiponectin) in chicken. Cytogenet. Genome Res. 112, 148–151 (2006).
Yan, J., Yang, H., Gan, L. & Sun, C. Adiponectin-impaired adipocyte differentiation negatively regulates fat deposition in chicken. J. Anim. Physiol. Anim. Nutr. (Berl.) 98, 530–537 (2014).
Gamberi, T. et al. Activation of autophagy by globular adiponectin is required for muscle differentiation. Biochim. Biophys. Acta 1863, 694–702 (2016).
Ruan, H. & Dong, L. Q. Adiponectin signaling and function in insulin target tissues. J. Mol. Cell Biol. 8, 101–109 (2016).
Tahmoorespur, M., Ghazanfari, S. & Nobari, K. Evaluation of adiponectin gene expression in the abdominal adipose tissue of broiler chickens: Feed restriction, dietary energy, and protein influences adiponectin messenger ribonucleic acid expression. Poult. Sci. 89, 2092–2100 (2010).
Mellouk, N. et al. Chicken is a useful model to investigate the role of adipokines in metabolic and reproductive diseases. Int. J. Endocrinol. 2018, 4579734. https://doi.org/10.1155/2018/4579734 (2018).
Stuber, E. F., Verpeut, J., Horvat-Gordon, M., Ramachandran, R. & Bartell, P. A. Differential regulation of adipokines may influence migratory behavior in the White-Throated Sparrow (Zonotrichia albicollis). PLoS ONE 8, e59097. https://doi.org/10.1371/journal.pone.0059097 (2013).
Bucław, M., Majewska, D., Szczerbińska, D. & Ligocki, M. The influence of age and gender on emu (Dromaius novaehollandiae) fat. Sci. Rep. 10, 11082. https://doi.org/10.1038/s41598-020-68103-1 (2020).
Yang, S. et al. RNA-Seq reveals differentially expressed genes affecting polyunsaturated fatty acids percentage in the Huangshan Black chicken population. PLoS ONE 13, e0195132 (2018).
Wang, Q. et al. Identification of single nucleotide polymorphism of adipocyte fatty acid-binding protein gene and its association with fatness traits in the chicken. Poult. Sci. 85, 429–434. https://doi.org/10.1093/ps/85.3.429doi:10.1371/journal.pone.0195132 (2006).
Sato, S. et al. Genome-wide association studies reveal additional related loci for fatty acid composition in a Duroc pig multigenerational population. Anim. Sci. J. 88, 1482–1490 (2017).
Liu, L. et al. Stearoyl-CoA Desaturase is essential for porcine adipocyte differentiation. Int. J. Mol. Sci. 21, 2446. https://doi.org/10.3390/ijms21072446 (2020).
Yu, W. C. Y. & Burke, W. H. Infertility in the Turkey. II. A description of a spontaneous infertility condition and its alleviation by intramagnal insemination and sexual rest. Poult. Sci. 58, 1372–1377 (1979).
Robinson, F. E., Wilson, J. L., Yu, M. W., Fasenko, G. M. & Hardin, R. T. The relationship between body weight and reproductive efficiency in meat-type chickens. Poult. Sci. 72, 912–922 (1933).
Koshiishi, Y. et al. Development of 49 novel microsatellite markers from next-generation sequencing data and a robust method for parentage tests in the emu (Dromaius novaehollandiae). Gene 769, 145238 (2021).
Wright, K., Nip, K. M., Kim, J. E., Cheng, K. M. & Birol, I. Seasonal- and sex-dependent gene expression in emu (Dromaius novaehollandiae) fat tissues. Sci. Rep. (in press).
Moreira, G. C. M. et al. Integration of genome wide association studies and whole genome sequencing provides novel insights into fat deposition in chicken. Sci. Rep. 8, 16222. https://doi.org/10.1038/s41598-018-34364-0 (2018).
Zhang, M. et al. Identification of differentially expressed genes and pathways between intramuscular and abdominal fat-derived preadipocyte differentiation of chickens in vitro. BMC Genom. 20, 743. https://doi.org/10.1186/s12864-019-6116-0 (2019).
Acknowledgements
We thank Dwayne Harder (Try Harder Farm, Denholm, Saskatchewan, Canada) for allowing access to his emu flocks, for following straight research protocol for rearing of the experimental birds, and for rendering the emu oil for this study. Dr. Carl Douglas (UBC Department of Botany) kindly provided laboratory facilities for carrying out the qRT-PCR work. We thank Michael Friedmann (UBC Department of Botany) for assistance in sample collection and providing technical advice. Thanks to Minh Dien Huynh (UBC Department of Food Science) for carrying out the gas chromatography analysis of emu oil fatty acid composition. Dr. Masoumeh Bejaei (Agriculture and Agri-Food Canada Summerland Research and Development Centre) assisted in developing statistical models for data processing. Funding was provided by a BC Ministry of Agriculture and Lands grant to KMC (Funds were administered by the UBC Specialty Birds Research Committee).
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J.E.K. carried out the laboratory analysis. D.C.B. contributed in project management, assisted in sample collection and provided expertise in emu nutrition physiology and fatty acids composition. K.W. provided expertise in genome and gene network analysis. K.M.C. provided expertise in avian genetics and contributed in experimental design and manuscript preparation.
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Kim, J.E., Bennett, D.C., Wright, K. et al. Seasonal and sexual variation in mRNA expression of selected adipokine genes affecting fat deposition and metabolism of the emu (Dromaius novaehollandiae). Sci Rep 12, 6325 (2022). https://doi.org/10.1038/s41598-022-10232-w
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DOI: https://doi.org/10.1038/s41598-022-10232-w
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