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Transcript profile of skeletal muscle lipid metabolism genes affected by diet in a piglet model of low birth weight


Authors: Quentin L. Sciascia aff001;  Gürbüz Daş aff001;  Steffen Maak aff002;  Claudia Kalbe aff002;  Barbara U. Metzler-Zebeli aff003;  Cornelia C. Metges aff001
Authors place of work: Institute of Nutritional Physiology, Leibniz Institute for Farm Animal Biology, Wilhelm-Stahl-Allee, Dummerstorf, Germany aff001;  Institute of Muscle Biology and Growth, Leibniz Institute for Farm Animal Biology, Wilhelm-Stahl-Allee, Dummerstorf, Germany aff002;  Institute of Animal Nutrition and Functional Plant Compounds, Department for Farm Animals and Veterinary Public Health, University of Veterinary Medicine Vienna, Austria aff003
Published in the journal: PLoS ONE 14(10)
Category: Research Article
doi: https://doi.org/10.1371/journal.pone.0224484

Summary

Dysregulated skeletal muscle metabolism (DSMM) is associated with increased inter- and intramuscular fat deposition in low birth weight (L) individuals. The mechanisms behind DSMM in L individuals are not completely understood but decreased muscle mass and shifts in lipid and carbohydrate utilisation may contribute. Previously, we observed lower fat oxidation in a porcine model of low birth weight. To elucidate the biological activities underpinning this difference microfluidic arrays were used to assess mRNA associated with lipid metabolism in longissimus dorsi (LD) and semitendinosus (ST) skeletal muscle samples from thirty-six female L and normal birth weight (N) pigs. Plasma samples were collected from a sub-population to measure metabolite concentrations. Following overnight fasting, skeletal muscle and plasma samples were collected and the association with birth weight, diet and age was assessed. Reduced dietary fat was associated with decreased LD intermuscular fat deposition and beta-oxidation associated mRNA, in both birth weight groups. Lipid uptake and intramuscular fat deposition associated mRNA was reduced in only L pigs. Abundance of ST mRNA associated with lipolysis, lipid synthesis and transport increased in both birth weight groups. Lipid uptake associated mRNA reduced in only L pigs. These changes were associated with decreased plasma L glucose and N triacylglycerol. Post-dietary fat reduction, LD mRNA associated with lipid synthesis and inter- and intramuscular fat deposition increased in L, whilst beta-oxidation associated mRNA remains elevated for longer in N. In the ST, mRNA associated with lipolysis and intramuscular fat deposition increased in both birth weight groups, however this increase was more significant in L pigs and associated with reduced beta-oxidation. Analysis of muscle lipid metabolism associated mRNA revealed that profile shifts are a consequence of birth weight. Whilst, many of the adaptions to diet and age appear to be similar in birth weight groups, the magnitude of response and individual changes underpin the previously observed lower fat oxidation in L pigs.

Keywords:

Lipids – Diet – Birth weight – Fats – Skeletal muscles – Swine – lipid metabolism – Lipolysis

Introduction

Skeletal muscle is the primary metabolic organ for the disposal of lipids (and carbohydrates) and energy dissipation, where it plays a central role in regulating whole body energy homeostasis [1]. The regulation of lipid metabolism is a complex process that exists in a cycle of uptake, storage (lipid synthesis: when exogenous energy supply is in excess), release (lipolysis: when exogenous energy supply is not sufficient) and energy generation (beta-oxidation: when there is a demand for ATP) [1]. Dysregulation of these processes has been linked to the development of metabolic disorders such as obesity and type 2 diabetes, which have chronic negative impacts on an individual’s health and development [2]. A well-regarded model for investigating the etiology of metabolic disorders is the low birth weight (L) pig [3].

The skeletal muscles of L pigs have been shown to be prone to increased intramuscular (IMF; also known as intra-myocellular lipids) and intermuscular fat (INTMF; extra-myocellular lipids) deposition before [3] and after [4] weaning. The presence of increased IMF and INTMF has been associated with the development of type 2 diabetes, insulin resistance and dysregulated skeletal muscle metabolism in humans [5]. Differences in IMF and INTMF deposition have been linked to lower fibre number; primarily secondary fibres, in L compared to normal birth weight (N) individuals [6, 7]. Low fibre number results in the plateau of fibre growth being attained earlier, thus, energy may no longer be partitioned towards muscle accretion, but instead it may be primarily used to support fat deposition [8]. Master regulators of muscle energy metabolism are the mitochondria, who regulate fat utilisation via beta-oxidation and storage via acetyl-CoA production from carbohydrate oxidation [9]. Thus, as fibre number and / or size changes, due to birth weight [10], breed [11] so does the ability of skeletal muscle to metabolise fats (and carbohydrates).

Our previous work showed that prior (75 days (d) of age) to a reduction in dietary fat (9.2 to 3.8%) at 80 d there was no difference in whole body fat (FOX) or carbohydrate oxidation (COX), between L and N pigs [12]. Post-change, at 83, 97 and 104 d, FOX was lower and COX was higher in L pigs, indicating a preference for carbohydrates as an energy source and earlier lipid deposition. Evidence of earlier lipid deposition has been previously reported by our group, however the mechanisms and the role of skeletal muscle was not investigated [13]. Two of the most intensively studied skeletal muscles are the longissimus dorsi (LD) and semitendinosus (ST), and in a recent study it has been shown that IMF accumulation occurs earlier and deposition amounts are greater in the LD compared to the ST, but glucose consumption was lower [14].

The hypothesis of our candidate gene approach was that L pigs are prone to a more pronounced transcription of genes involved with lipid uptake and synthesis. Consequently, to understand the potential role skeletal muscle plays in regulating whole body FOX and how birth weight affects these processes, the objectives of this study were: i) to compare transcript profile changes of lipid metabolism in the LD and ST muscle of L and N pigs, and ii) investigate transcript profile changes of lipid metabolism before and after the adaptation period to a reduction in dietary fat.

Materials and methods

Animal handling

Ethical approval for all experimental procedures were approved by the relevant authorities of Mecklenburg-Vorpommern, Germany (Landesamt fur Landwirtschaft, Lebensmittelsicherheit und Fischerei, Mecklenburg-Vorpommern; permission no. LALLF M-V/TSD/7221.3–1.1-049/09). All work was conducted in accordance with the German Animal Protection regulations.

Pure German Landrace pigs were sourced from and the following experiment conducted at the experimental pig facility of the Leibniz Institute for Farm Animal Biology. Thirty-four litters (2nd to 7th parity sows; mean live litter size n = 15 ± 0.4; mean live piglet weight = 1.3 ± 0.02; S1 Table) were used. At birth, pairs of female littermates were selected of which one had a low (L; 0.9–1.2 kg) and the other had a normal (N; 1.4–1.8 kg) birth weight. In this study, L piglets were defined as having a bodyweight less than the lower quartile of the average litter birth weight in our pig breeding facility. Females were chosen for this study to remove the influence of gender specific tissue development. Experimental animals were suckled by their dam, weaned at 28 d and fed ad libitum a post-weaning diet (S2 Table) with 16.9 MJ ME/kg of dry matter (15.9% crude protein, 33% starch, 27% sugar and 9.2% crude fat/kg) until 79 d (S3 Table). From 80 d onwards, pigs were fed a diet containing 15.2 MJ ME/kg of dry matter (16.5% crude protein, 44% starch, 14.8% sugar and 3.8% crude fat/kg). All pigs received identical diets and received two equal meals per day (0800 and 1500 h) as previously published [12]. All diets were formulated to supply energy and nutrients at or above recommendations, as published previously [12]. The experiment was performed with four different age groups (75, 98, 104, 131 d; trial design S3 Table) spread across seven different dates (blocks). At 74, 83, 96 d (n = 36/age group) and 113 d (n = 18) of age a subpopulation of experimental animals were fasted for 14 h, for the analysis of plasma metabolite profiles. At 75 (n = 20), 98 (n = 18), 104 (n = 18) and 131 (n = 16) d, following a 12 h fast, animals were euthanized and the skeletal muscles LD (between the 13th and 14th rib) and ST (from the central portion of the muscle midbelly) were snap frozen in liquid nitrogen and stored at -80 oC for subsequent analysis.

Plasma metabolites

Plasma samples (F-EDTA, Sarstedt AG & Co., Nümbrecht, Germany) were analysed for concentrations of non-esterified fatty acids (NEFA; number 434-91795s, Wako Chemicals GmbH, Neuss, Germany), glucose (no. 553–230) from MTL Diagnostics (Idstein, Germany), TG (GPO-PAP, number LT-TR 0015; Labor + Technik Lehmann, Berlin, Germany), urea (no. LT-UR 0050) and cholesterol (CHOD-PAP, no. LT-GL 01039) by the Clinic for Cattle (University of Veterinary Medicine Hannover, Hannover, Germany). Analyses were performed by spectrophotometry (Pentra 400, Axon Lab, Reichenbach, Germany).

Microfluidic real-time PCR

RNA extraction, purification and cDNA synthesis

Total RNA was extracted from pre-weighed -80 oC frozen LD and ST tissue using peqGOLD TriFast (VWR International GmbH, Hannover, Germany), purified using RNeasy minikits (Qiagen, Hilden, Germany) and quantified using a Nanophotometer (Implen GmbH, Munich, Germany). The RNA quality was assessed using a Bioanalyzer 2100 and RNA 6000 Nano kit (Agilent Technologies, Waldbronn, Germany), with a RIN cutoff of 8.5. Synthesis of cDNA was performed using 250 ng of purified RNA and the reverse transcription master mix kit (Fluidigm, Amsterdam, Netherlands), according to the manufacturer’s instructions.

Primers and primer specific cDNA pre-amplification

DELTAgene assays (Fluidigm) were designed for 27 lipid metabolism associated transcripts, and grouped according to function as shown in S4 Table. Briefly, five functional groups were created Lipid uptake / Transport (n = 3), Lipid Synthesis (n = 11), Lipolysis (n = 3), Beta-oxidation (n = 6), Nuclear receptors (n = 3) and Energy regulation (n = 1). Primers were designed using publicly available Sus scrofa transcript data available from NCBI (www.ncbi.nlm.nih.gov) and the primer design programs GenScript (https://www.genscript.com) or the Roche Universal ProbeLibrary assay design centre (http://www.roche-applied-science.com/). All primers (Metabion GmbH, Martinsried, Germany) were designed to be intron spanning and expected to behave identically during the pre-amplification. Pre-amplification was performed for 10 cycles using the PreAmp Master Mix (Fluidigm), according to the manufacturer’s instructions. For each assay, 1 μL of 100 μM forward and reverse primer was mixed into a tube and made to 200 μL with DNA suspension buffer (TEKnova, USA).

DELTAgene assay

Pre-amplified cDNA samples were analysed by qPCR using 48.48 Dynamic Array integrated fluidic circuits (IFCs) and the BioMark™ HD System from Fluidigm. Processing of the IFCs and operation of the instruments were performed according to the manufacturer’s instructions. Each experiment consisted of analysing 15-duplicate experimental samples (plus three additional samples: an inter-run calibrator, a no-template and a no-enzyme control for qPCR), with 48 DELTAgene assays. In order to prepare samples for loading into the IFC, a mix was prepared consisting of 180 μL Sso Fast EvaGreen Supermix with Low ROX (BioRad 1725211), 18 μL 20× DNA Binding Dye Sample Loading Reagent (Fluidigm 1003738) and 3.3 μL of this mix was dispensed to each well of a 96-well assay plate (Sarstedt 72.1978.202). Pre-amplified cDNA (2.7 μL) was added to each well and the plate briefly vortexed and centrifuged. Following priming of the IFC in the IFC Controller HX, 5 μL of the cDNA mix was dispensed to each Sample Inlet of the 48.48 IFC. For the DELTAgene assays, 5 μL of each 10× Assay (5 μM each primer) were dispensed to each Detector Inlet of the 48.48 IFC. After loading the assays and samples into the IFC in the IFC Controller HX, the IFC was transferred to the BioMark HD and PCR was performed using the thermal protocol GE Fast 48 × 48 PCR + Melt v2.pcl. This protocol consists of a Hot Start at 95°C, 60 s, PCR Cycle of 40 cycles of (96°C, 5 s; 60°C, 20 s), and Melting using a ramp from 60°C to 95°C at 1°C/3 s.

Differential mRNA abundance analysis

Data was analysed using the Fluidigm Real-Time PCR Analysis software using the Linear (Derivative) Baseline Correction Method and the Auto (Global) Ct Threshold Method and exported to qBASEplus 2.0 (Biogazelle, Ghent, Belgium). An upper limit Cq threshold of 31 cycles was set to remove poorly amplifying or low abundance cDNA targets, resulting in the LD targets ACAA2, CPT1A, DGAT2, FABP4, FASN, GPAT1 and GPAT3, and the ST targets DGAT2, FASN, GPAT1 and GPAT3 being removed from the study, in addition to 2 pairs of animals. The reference gene 18S ribosomal RNA was included as a target and it appears that the extremely high abundance saturated the pre-amplification process, leading to some key targets with quantitation cycle (Cq) values over 31. Further analysis of the imported qPCR data showed no amplification for one pig in all LD and ST samples, so it and the littermate were removed from the study. Thus, the total number of samples analysed per tissue, and per time point were at 75 (n = 18), 98 (n = 16), 104 (n = 16) and 131 (n = 16) d. The GeNorm applet selected the reference genes; ST: Hprt, Hspcb, Top2b; LD: Psmc3, Hprt, Hspcb, out of five genes (Hprt, Hspcb, Psmc3, Top2b, Rps18) as the most stably expressed across the two birth weight groups and four time points used in this study (132 samples, all examined in duplicate). Reference genes were used to normalize target gene expression in the qBASEplus software and the Cq values were converted into Log-Calibrated Normalized Relative Quantity (CNRQ) values, taking into account amplification efficiencies, inter-run variations, and normalization factors [15]. All qPCR data were reported according to the published MIQE guidelines [16].

Statistical analysis

Body weight and anthropometric data were analysed using the MIXED procedure of SAS (version 9.4; SAS Institute Inc., Cary, NC, USA) with the fixed factors of birth weight group (L, N) and sow as a random factor, with the repeated factor time point with the power spatial covariance matrix, used only for body weight analysis. Sow as a random allowed modelling of the potential dependency of littermates from the same sow. Plasma metabolite profiles were investigated with same model used to analyse pig body weight, but with the repeated factor of time of blood sampling (74, 83, 96 and 113 d). Probability values ≤ 0.05 were considered statistically significant, and values > 0.05 but ≤ 0.10 are discussed as trends. Real-time PCR Log-CNRQ values exported from qBASEplus 2.0 (Biogazelle, Ghent, Belgium) were statistically investigated using the MIXED procedure of SAS. The model included birth weight group (L, N), time point (75, 98, 104 and 131 d) and their interaction as fixed factors, experimental block (1, 2, 3, 4, 5, 6, and 7) as a factor, and the sow as a random factor. Probability values ≤ 0.05 were considered statistically significant, and values > 0.05 but ≤ 0.15 are discussed as trends. For all analyses, post hoc comparisons were performed using the Tukey–Kramer test. Results are reported as least square means (LSM) ± SE.

Results and discussion

Dysregulated skeletal muscle metabolism (DSMM) has been observed in a number of low birth weight models, resulting from maternal undernutrition [17] and metabolic disorder [18], placental insufficiency [19], and natural occurrence [20]. A consequence of DSMM is increased adiposity potentiated by a reduction in the utilisation of fatty acids as an energy source and their shuttling towards lipogenesis. However, the transcriptional mechanisms regulating lipid metabolism in the skeletal muscle of L individuals during the transition to a diet lower in fat are not well characterised. To our knowledge, this is the first time that the lipid metabolism transcript profile has been analysed in two muscle groups during this transition and the subsequent adaptation period, in a low birth weight model.

Body morphology and plasma metabolites

Prior to the dietary change L pigs were lighter (P < 0.01; Table 1), however, post change no difference in body weight was observed. Over this transition period is when we observed FOX and COX began to differ between L and N pigs [12]. In order to evaluate the potential effects of birth weight, diet and the post-diet change adaptation had on the metabolic status of L and N pigs, TAG, cholesterol, non-esterified fatty acid (NEFA), glucose and urea were measured. Plasma metabolite concentrations did not differ among L and N pigs at every time point measured. However, a comparison of the post- (83 d) to pre-dietary (74 d) time points, showed a significant decrease in plasma urea and cholesterol in both L and N pigs (Table 2). Plasma urea is a marker for amino acid utilization by protein synthesis, thus it appears that post dietary change, both L and N pigs had improved protein synthesis. The lower cholesterol concentration might reflect the lower fat intake. No changes in plasma NEFA concentrations were observed for either birth weight group. Interestingly, data analysis showed significantly lower plasma glucose concentrations in L pigs and a trend for lower plasma TAG in N pigs (Table 2), potentially reflecting differential energy substrate utilization between L and N pigs. The primary organ for the disposal of lipids (and carbohydrates) is the skeletal muscle, and thus transcriptional changes in lipid metabolism associated genes may explain the observed changes.

Tab. 1. Body weight (BW) and anatomical data from birth until age 131 days of low (L) and normal (N) birth weight pigs.
Body weight (BW) and anatomical data from birth until age 131 days of low (L) and normal (N) birth weight pigs.
Tab. 2. Plasma metabolite concentrations at 74, 83, 96 and 113 d of age for a sub-population of low (L) and normal (N) birth weight (BiW) piglets used in this study.
Plasma metabolite concentrations at 74, 83, 96 and 113 d of age for a sub-population of low (L) and normal (N) birth weight (BiW) piglets used in this study.

Longissimus dorsi, diet dependent adaptation

A comparison of post- (98 d) and pre- (75 d) dietary change showed that PLIN2 (Perilipin 2: lipid synthesis; P < 0.01), ATGL (Adipose triglyceride lipase), HSL (Hormone-sensitive lipase), MGLL (Monoglyceride Lipase) (lipolysis; P < 0.01), CPT1B (Carnitine palmitoyltransferase 1B: beta-oxidation; P < 0.01), PPARA (Peroxisome proliferator-activated receptor alpha: nuclear receptor; P < 0.01) and PGC1 (Peroxisome proliferator-activated receptor gamma coactivator 1-alpha: energy regulation; P < 0.01) mRNA were significantly lower at 98 d, in both L and N pigs (Table 3). These results indicate that both L and N pigs shifted energy away from IMF storage and reduced fatty acid (FA) oxidation in response to the change of diet at 80 d. In addition, at 98 d FABP3 (Fatty acid-binding protein 3: lipid transport; P < 0.01) mRNA was significantly lower in only N pigs, whilst PLIN1 (Perilipin 1: lipid synthesis; P < 0.01) was lower and ACADL (Acyl-CoA dehydrogenase. long chain: beta-oxidation; P < 0.01) mRNA was higher in only L pigs (Table 3). Thus, it appears FABP3-mediated FA trafficking was reduced in only N pigs, whilst PLIN1-associated INTMF deposition decreased in only L pigs.

Tab. 3. The effect of reduced dietary fat (pre-diet (75 days of age (d)) to post-diet change (98 d) time point comparison) and age (time point comparisons 98, 104 and 133 d; post-dietary fat reduction), on the abundance of longissimus dorsi mRNA molecules associated with lipid metabolism (lipid synthesis, lipolysis and beta oxidation) in low (L) and normal (N) birth weight pigs.
The effect of reduced dietary fat (pre-diet (75 days of age (d)) to post-diet change (98 d) time point comparison) and age (time point comparisons 98, 104 and 133 d; post-dietary fat reduction), on the abundance of longissimus dorsi mRNA molecules associated with lipid metabolism (lipid synthesis, lipolysis and beta oxidation) in low (L) and normal (N) birth weight pigs.

When birth weight groups were compared, data analysis showed that pre-dietary change (75 d), FABP3 (P = 0.03) and ACADL (P = 0.03) mRNA abundance was lower, whilst LPL (Lipoprotein lipase: lipid uptake; P = 0.05), PLIN1 and SCD (Stearoyl-CoA desaturase) (lipid synthesis; P < 0.01 and P = 0.08 respectively) mRNA abundance was higher in L pigs (Table 4). Thus, prior to the dietary change lipid synthesis, potentially through LPL-mediated uptake of FA and MAG derived from the circulation, biosynthesis via SCD and deposition into INTMF appeared to be higher in L pigs. However, post-dietary change, INTMF deposition or abundance appeared to be significantly reduced in L pigs via an almost 2-fold decrease in PLIN1 mRNA abundance (Table 4). Whilst LPL mRNA was no longer significantly higher in L pigs due to a 1.5-fold, increase in N pigs. In the same analysis FABP3 (P = 0.10), SCD (P = 0.02), HSL (P = 0.06) and PPARA (nuclear-receptor; P < 0.01) mRNA abundance was higher in L pigs (Table 4).

Tab. 4. The effect of diet (75, 98 days of age (d)) and age (98, 104 and 133 d; post-dietary fat reduction) on the abundance of longissimus dorsi mRNA associated with lipid metabolism (lipid synthesis, lipolysis and beta-oxidation).
The effect of diet (75, 98 days of age (d)) and age (98, 104 and 133 d; post-dietary fat reduction) on the abundance of longissimus dorsi mRNA associated with lipid metabolism (lipid synthesis, lipolysis and beta-oxidation).
Comparison between low (L) and normal (N) birth weight pigs.

Lipoprotein lipase is the rate-limiting enzyme for the uptake of FA by muscle and adipose tissue [21]. It is a transcriptionally, translationally and post-translationally regulated enzyme, which is synthesized and secreted by adipocytes and muscle to the capillary endothelium [22] where it hydrolyses the TAG core of circulating TAG-rich lipoproteins, chylomicrons, and VLDLs (Very-low-density lipoprotein) [23]. The hydrolysis products, FA and MAG, are then taken up by the target tissues to be stored or metabolized. Storage is regulated by the Perilipin family of proteins [24], of which PLIN1 is unique, as it is expressed only in adipocytes and steroidogenic cells [25], where the PLIN1 protein associates with lipid droplets to regulate INTMF deposition [26, 27]. The abundance of PLIN1 mRNA has been used as a marker of INTMF content in the LD and semimembranosus muscles of pigs [26]. Thus, prior to the dietary change, the LD of L pigs appeared to favour INTMF lipid synthesis. A key enzyme in the pathways that utilize the dietary FA made available by LPL, or derived from lipolysis is stearoyl-CoA desaturase (SCD), which catalyses the rate-limiting step in the biosynthesis of monounsaturated fatty acids destined for storage in lipid droplets [28, 29]. In this study, the abundance of SCD mRNA was higher pre- and post-dietary change in L pigs, indicating endogenous synthesis of substrates required for lipid droplet formation/lipid was unaffected by the diet change. A higher abundance of SCD1 mRNA has been shown to increase lipid accumulation in muscle [30, 31], by shifting substrates away from, and consequently lowering, beta-oxidation, as observed in this study. Pre-dietary change, the abundance of HSL and PPARA mRNA was higher in the LD of L pigs. Hormone sensitive lipase (HSL) is an enzyme that has been shown to hydrolyse TAG, DAG and MAG [32] and higher levels of HSL mRNA have been shown to lead to increased intracellular FA concentrations. These FA stimulate Ppara expression and bind to the protein product, facilitating its relocation to key genes involved in the regulation of FA metabolism, such as SCD. Thus, higher SCD mRNA, pre-dietary change, appears to be maintained by FA-activated PPARA, FA released through HSL mediated lipolysis, whilst the absence of higher PPARA mRNA post-dietary change suggests potential insulin-mediated regulation [33]. Interestingly, LPL expression is also regulated by insulin [34], and higher abundance of LPL and SCD has been linked to reduced beta-oxidation, and the development of hypertriglyceridemia and diabetes [30, 35]. The exact mechanisms are unknown, but what links them all is the accumulation of FA within the cell [29], their partitioning towards lipid droplet formation and the inhibitory properties these FA have on beta-oxidation [31]. Only one marker of beta-oxidation, pre- and post-dietary change was different between L and N pigs, ACADL (Acyl-CoA Dehydrogenase Long Chain), whose abundance was lower in L pigs, whilst none of the other investigated genes related to beta-oxidation were different. Fatty acid-binding protein (FABP3) is the major FABP in skeletal muscle [36] and several studies have shown that FABP3 is involved in FA transport, its oxidation or activation of nuclear-associated genes / proteins involved in energy homeostasis and fatty acid oxidation [37]. In this study, FABP3 mRNA abundance was higher in the LD of N pig’s pre-dietary change; however, post-dietary change the abundance was higher in L pigs. Increased abundance of FABP3 mRNA has been shown to increase glucose uptake independent of insulin signalling in C2C12 myotubes [38], potentially explaining why plasma glucose levels reduce significantly from the pre- to post-diet change period, in L pigs only.

Longissimus dorsi, post diet adaptation

A time point comparison from 98 to 104 d showed there was increased FABP3 (lipid transport; P < 0.12), CPT1B and HADH (beta-oxidation; P = 0.01, P = 0.05), and decreased ACADL (beta-oxidation; P = 0.14) mRNA in N pigs (Table 3). Whereas only PLIN2 (lipid synthesis; P = 0.04) increased and ACADL (P < 0.01) mRNA decreased in L pigs (Table 3). Analysis of these changes suggested that beta-oxidation in N pigs and IMF deposition in L pigs increased. From 104 to 133 d increased PLIN1, PLIN2 (lipid synthesis; L: P < 0.01; N = P < 0.01), HSL (lipolysis; L: P < 0.01; N: P < 0.01), ACADL (L: P < 0.01; N: P < 0.01), PPARA (nuclear-receptor; L: P = 0.02; N: P = 0.01) mRNA, and decreased CPT1B (L: P < 0.01; N: P < 0.01) was observed in both L and N pigs (Table 3). Thus, markers of IMF and INTMF deposition increased in both L and N pigs. Interestingly, the mRNA abundance of beta-oxidation marker ACADL increased whilst its companion marker CPT1B decreased. This dysregulation has only been observed in one previous study [39], but its basis is unknown and there is insufficient data in this study to speculate. In addition, only increased PPARG (Peroxisome proliferator-activated receptor gamma: nuclear receptor; P = 0.15) and decreased FABP3 (P < 0.14) and HADH (P < 0.01) was observed in N pigs (Table 3). PPARG is primarily expressed in adipocytes where it regulates glucose uptake and fat storage [11], whereas FABP3 is primarily expressed in muscle.

Comparative analysis of the birth weight groups showed that at 98 d FABP3 (P = 0.10), SCD (lipid synthesis; P = 0.02), HSL (lipolysis; P = 0.06) and PPARA (nuclear receptor; P < 0.01) mRNA abundance was higher in L pigs (Table 4). By 104 d FABP3 (P = 0.13) was now trending lower, and HSL (P = 0.09) and CPT1B (P = 0.07) mRNA were trending higher in L pigs. At 131 d ACACA (Acetyl-CoA carboxylase Alpha: lipid synthesis; P < 0.01) was and PLIN1 (P = 0.14) tended to be higher in L pigs (Table 4). Thus, from 98 to 104 d L pigs appear to reduce lipolysis and beta-oxidation, and transition to increased INTMF deposition by 131 d, compared with their N littermates.

At 98 d, the LD of L pigs appears to be releasing IMF stores of FA in a negative feedback-loop that leads to the repression of beta-oxidation, and may explain why in our companion study FOX reduced from 75 to 98 d [12]. Whilst at 98 d no changes in the abundance of mRNA encoding proteins involved in beta-oxidation were observed, at 104 d the abundance of CPT1B was lower in L pigs. Carnitine Palmitoyltransferase 1B (CPT1B) is the muscle specific isoform of the protein required for the uptake of long chain fatty acids by the mitochondria, the first and rate-limiting step in beta-oxidation [40] and a well-established marker of beta-oxidation [41]. Murine studies using synthetic inhibitors [42] and knockouts [43] of Cpt1b in skeletal muscle have shown that inhibition or knockout leads to increased COX, utilization of amino acids as an energy source, and the accumulation of intracellular DAG and TAG [42, 43]. Whilst the intracellular amino acid and DAG / TAG content was not measured in this study, a companion study did show increased COX [12], suggesting that the LD of L pigs may contribute to the observed increase in whole body COX. This may also explain the reduced abundance of FABP3 mRNA in L pigs at 104 d, which plays a role in the transport of FA destined for transport by CPT1B. Indeed, murine Fabp3 knockout studies in the skeletal and heart muscle have shown that the uptake of FA was almost completely inhibited and tissue metabolism switched from FOX to COX. The higher abundance of HSL at 104 d is interesting given its role in the release of FA and MAG via the hydrolysis of DAG [32]. Diacylglycerols have been implicated in the development of insulin resistance in human skeletal muscle, resulting in reduced glucose clearance from circulation [44]. A higher abundance of HSL may provide a mechanism to prevent insulin resistance from developing in the LD of L pigs, by reducing the level of DAG and allowing for greater glucose clearance to support increased levels of COX [12]. By 131 d repression of beta-oxidation appears to be maintained in the LD of L pigs, via higher ACACA mRNA, and its association with malonyl-CoA repression of CPT1B activity and the channelling of FA-substrates to INTMF fat deposition via PLIN1.

Semitendinosus, diet dependent adaptation

Analysis of the pre- (75 d) and post- (98 d) dietary change data showed that the abundance of ATGL, HSL, MGLL (lipolysis; L: P = 0.03, P < 0.03, P = 0.03; N: P = 0.13, P < 0.01, P = 0.08), DGAT1 (Diacylglycerols acyltransferase 1), PLIN2 (lipid synthesis; L: P = 0.10, P = 0.06; N: P = 0.03, P = 0.01) and FABP3 (lipid transport; L: P = 0.15; N: P = 0.02) mRNA were higher, and NR4A1 (Nuclear Receptor Subfamily 4, Group A Member 1: nuclear receptor; L: P = 0.03; N: P = 0.01) was lower, at 98 d, in both L and N pigs (Table 5). These changes are in contrast to the LD where the abundance of lipolysis and lipid synthesis markers was lower at 98 d, indicating muscle specific changes in lipid metabolism in response to the dietary change. Additionally, the data indicates that even though lipolysis may have increased in both L and N pigs so had IMF deposition and lipid transport. There were unique changes, but only in L pigs, where LPL was lower (lipid uptake; P = 0.01) and FABP4 mRNA was higher (Fatty acid binding protein 4: lipid transport; P = 0.06) reflecting potentially lower FA uptake and increased transport compared to N pigs (Table 5).

Tab. 5. The effect of reduced dietary fat (pre-diet (75 days of age (d)) to post-diet change (98 d) time point comparison) and age (time point comparisons 98, 104 and 133 d; post-dietary fat reduction), on the abundance of semitendinosus mRNA molecules associated with lipid metabolism (lipid synthesis, lipolysis and beta oxidation) in low (L) and normal (N) birth weight pigs.
The effect of reduced dietary fat (pre-diet (75 days of age (d)) to post-diet change (98 d) time point comparison) and age (time point comparisons 98, 104 and 133 d; post-dietary fat reduction), on the abundance of semitendinosus mRNA molecules associated with lipid metabolism (lipid synthesis, lipolysis and beta oxidation) in low (L) and normal (N) birth weight pigs.

Analysis of data from the birth weight groups showed that pre-dietary change the abundance of LPL (P = 0.02) and ACACA (lipid synthesis; P = 0.13) mRNA were higher and HADH (Hydroxyacyl-CoA dehydrogenase: beta-oxidation; P = 0.10) tended to be lower in the ST of L pigs (Table 6). Post-dietary change LPL abundance trended lower (P = 0.14) and MGLL (P = 0.10) trended higher in the ST of L pigs (Table 6). These changes indicate that, in response to the dietary change, L pigs lowered FA uptake and malonyl-CoA synthesis, leading to increased lipolysis.

Tab. 6. The effect of diet (75, 98 days of age (d)) and age (98, 104 and 133 d; post-dietary fat reduction) on the abundance of semitendinosus mRNA associated with lipid metabolism (lipid synthesis, lipolysis and beta-oxidation).
The effect of diet (75, 98 days of age (d)) and age (98, 104 and 133 d; post-dietary fat reduction) on the abundance of semitendinosus mRNA associated with lipid metabolism (lipid synthesis, lipolysis and beta-oxidation).
Comparison between low (L) and normal (N) birth weight pigs.

Pre-dietary fat reduction, it appears that the ST of L pigs have greater FA uptake, as evidenced by the higher abundance of LPL mRNA. However, at 98 d, the abundance of LPL mRNA was lower in the ST of L pigs. These changes were also observed in the LD, suggesting that both muscles in L pigs were more sensitive to the dietary change at 80 d, potentially forcing them to reduce their reliance on FA-resources as a source of energy. In the ST of L pigs, this theory is supported by the higher ACACA and lower HADH mRNA abundance at pre-reduction in dietary fat and higher MGLL mRNA post-fat reduction. Acetyl-CoA carboxylase 1 is an enzyme that converts acetyl-CoA released by the mitochondria to malonyl-CoA, the rate-limiting step in FA synthesis from the mitochondria and is transcriptionally regulated [45]. The concentration of malonyl-CoA determines the switch between FA synthesis and oxidation, lower concentrations shift towards beta-oxidation, whilst higher lead to increased fatty acid synthesis [45]. A higher abundance of ACACA mRNA has been shown to correlate with increased concentrations of malonyl-CoA, which inhibits the first step of beta-oxidation, and has been associated with lower HADH mRNA abundance. Monoglyceride Lipase (MGLL) is a transcriptionally regulated gene whose protein product is the rate-limiting enzyme for lipolysis, where it is responsible for the conversion of MAG to free FA and glycerol [46]. We propose that the higher abundance of MGLL mRNA in the ST of L pigs was in response to the reduced ability to uptake FA when dietary fat was reduced.

Semitendinosus, post diet adaptation

At 104 d, ATGL and HSL mRNA were lower (lipolysis; L: P = 0.01, P < 0.01; N: P = 0.07, P < 0.01) and NR4A1 (nuclear receptor; L: P < 0.01; N: P = 0.04) was higher in both L and N pigs, compared to 98 d (Table 5). In L pigs LPL (lipid uptake; P = 0.05) was higher, and in N pigs FABP3, FABP4 (P = 0.07, P = 0.04) and ACAA2 (Acetyl-CoA acyltransferase 2: beta-oxidation; P = 0.10) mRNA were lower (Table 5). Analysis of the observed changes suggest that whilst lipolysis appears to have reduced in both L and N pigs over time, L pigs have potentially increased FA uptake whilst N pigs may have reduced beta-oxidation. At 133d, ATGL, HSL, MGLL (lipolysis; L: P = 0.10, P < 0.01, P = 0.04; N: P < 0.01), DGAT1, PLIN2 (lipid synthesis; L: P < 0.01; N: P < 0.01) mRNA were higher and NR4A1 (nuclear receptor; L: P < 0.01; N: P < 0.01) and PGC1 (energy regulation; L: P = 0.08; N: P = 0.05) were lower in both L and N pigs. Additionally, in L pigs MOGAT1 (Monoacylglycerol O-acyltransferase 1) and PLIN1 (lipid synthesis; P = 0.07, P = 0.08) trended higher at 133 d. Thus, whilst lipolysis and lipid synthesis appeared to be higher in both L and N pigs at 133 d, only L pigs appeared to increase INTMF lipid synthesis.

Birth weight group comparisons showed that at 98 d LPL (P = 0.14) mRNA trended lower and MGLL (P = 0.10) trended higher in L pigs. By 104 d, LPL (P = 0.02), MOGAT1 (P = 0.03) ACAA2, CPT1B, HADH (beta-oxidation; P = 0.04, P = 0.08, P = 0.12) and NR4A1 (nuclear receptor; P = 0.02) mRNA abundance was higher in L pigs (Table 6). At 131 d, the abundance of DGAT1, MOGAT1 (P = 0.06, P = 0.11), MGLL (P = 0.08) tended and PPARA (nuclear receptor; P = 0.04) mRNA was lower in L pigs (Table 6). Analysis of the data indicated that L pigs transitioned from higher beta-oxidation to higher lipolysis and lipid synthesis compared to N pigs.

At 98 d, a higher abundance of MGLL, an indicator of increased lipolysis, was observed in the ST of L pigs, and by 104 d, the abundance of beta-oxidation-associated CPT1B, ACAA2 and HADH mRNA was higher in the ST of L pigs. As previously mentioned CPT1B encodes the muscle specific isoform of CPT1 and is the rate-limiting step in the uptake of long chain fatty acids by the mitochondria, whilst HADH and ACAA2 mRNA are part of the mitochondrial trifunctional protein, which catalyses the last steps of beta-oxidation [40]. Interestingly, these three genes are regulated by PPARA, which in our study was not different between L and N pigs. It is possible PPARA stimulation occurred at an earlier time point, or NR4A1, whose mRNA abundance was higher in L pigs, is the transcriptional regulator of Cpt1b, Hadh and Acaa2, as it has been shown that Cpt1 transcription can be controlled by NR4A1 [47]. Additionally, MOGAT1 mRNA abundance was higher in the ST of L pigs. Monoacylglycerol acyltransferase enzymes convert MAG to DAG [48], where DAG not only acts as precursor for TAG synthesis, but several studies show that elevated DAGs are associated with impaired insulin signalling and increased beta-oxidation [49], as observed in this study. By 131 d, there is no longer a difference in the abundance of beta-oxidation associated mRNA, between the ST of L and N pigs, and lipid synthesis and lipolysis appears to be repressed in L pigs, as evidenced by the reduced abundance of PPARA mRNA, and three of its downstream targets, MGLL [50], MOGAT1 [51] and DGAT1 [52].

Perspectives

The lipid metabolism transcriptional profile differences observed between the skeletal muscles of L and N pigs may be explained by the influence birth weight has on muscle fibre number [6], type [53, 54] and subsequent postnatal growth [8]. L individuals have been shown to have a reduced number of secondary fibres [6] potentially resulting in fibre growth being attained earlier and energy being partitioned towards fat deposition (8). Additionally, the beta-oxidation capacity of skeletal muscle is determined by the fibre type composition, where low beta-oxidation occurs in fast-glycolytic, medium to high in fast-oxidative-glycolytic and high occurs in slow-oxidative fibres [55]. Changes in muscle fibre composition have been observed in humans [53], mice [17] and pigs [54, 56], that have been associated with increased adiposity and the development of insulin resistance.

Whilst a direct comparison of the individual mRNA molecules between LD and ST could not be performed, the associated shifts in the pathways they belong to suggest each muscle adapted differently during the change in diet and the post-diet adaptation period. Associated with the change in diet it appears both muscles reduced their reliance on FA-resources as a source of energy. However, where the LD appeared to reduce markers of lipolysis and lipid synthesis post-diet change, the ST increased them; the biology behind this remains unclear and requires further investigation. During the post-diet adaption phase, the LD appears to increase the abundance of markers of lipid synthesis (IMF and INTMF), and beta-oxidation whereas the ST has associated increases in the markers of lipid synthesis (IMF) and lipolysis. Thus, the changes in mRNA abundance from the ST match with the observed phenotype from L and N pigs [12].

Conclusion

The results presented in this study suggest that our previous observations of low birth weight being associated with changes in whole body metabolic physiology may be linked to adaptation of skeletal muscle lipid metabolism, which shifts in response to a reduction of dietary fat in adolescent female pigs. We propose that extra- and/or intra-mitochondrial regulatory dysfunction links impaired in utero growth with future metabolic disease.

Supporting information

S1 Table [docx]
Experimental litter.

S2 Table [docx]
Diet components, dry matter (DM), calculated crude nutrient composition, and metabolizable energy (ME), classified according to age of pigs.

S3 Table [docx]
Experimental design.

S4 Table [docx]
Name, symbol, accession number, primer sequence and amplicon size of genes analyzed by qPCR.


Zdroje

1. Kelley DE. Skeletal muscle fat oxidation: timing and flexibility are everything. J Clin Invest. 2005;115(7):1699–702. Epub 2005/07/12. doi: 10.1172/JCI25758 16007246; PubMed Central PMCID: PMC1159159.

2. Xiao X, Zhang ZX, Li WH, Feng K, Sun Q, Cohen HJ, et al. Low birth weight is associated with components of the metabolic syndrome. Metabolism. 2010;59(9):1282–6. Epub 2010/01/05. doi: 10.1016/j.metabol.2009.12.001 20045533; PubMed Central PMCID: PMC2895955.

3. Williams PJ, Marten N, Wilson V, Litten-Brown JC, Corson AM, Clarke L, et al. Influence of birth weight on gene regulators of lipid metabolism and utilization in subcutaneous adipose tissue and skeletal muscle of neonatal pigs. Reproduction. 2009;138(3):609–17. Epub 2009/06/09. doi: 10.1530/REP-08-0445 19502453.

4. Rehfeldt C, Tuchscherer A, Hartung M, Kuhn G. A second look at the influence of birth weight on carcass and meat quality in pigs. Meat Sci. 2008;78(3):170–5. Epub 2008/03/01. doi: 10.1016/j.meatsci.2007.05.029 22062267.

5. Hausman GJ, Basu U, Du M, Fernyhough-Culver M, Dodson MV. Intermuscular and intramuscular adipose tissues: Bad vs. good adipose tissues. Adipocyte. 2014;3(4):242–55. Epub 2015/09/01. doi: 10.4161/adip.28546 26317048; PubMed Central PMCID: PMC4550684.

6. Wigmore PM, Stickland NC. Muscle development in large and small pig fetuses. J Anat. 1983;137 (Pt 2):235–45. Epub 1983/09/01. 6630038; PubMed Central PMCID: PMC1171817.

7. Gondret F, Lefaucheur L, Juin H, Louveau I, Lebret B. Low birth weight is associated with enlarged muscle fiber area and impaired meat tenderness of the longissimus muscle in pigs. J Anim Sci. 2006;84(1):93–103. Epub 2005/12/20. doi: 10.2527/2006.84193x 16361495.

8. Rehfeldt C. Prenatal events that determine the number of muscle fibres are important for lean growth and meat quality in pigs. Arch Anim Breed. 2005;48(Sp.Iss.):11–22.

9. Befroy DE, Petersen KF, Dufour S, Mason GF, de Graaf RA, Rothman DL, et al. Impaired mitochondrial substrate oxidation in muscle of insulin-resistant offspring of type 2 diabetic patients. Diabetes. 2007;56(5):1376–81. Epub 2007/02/09. doi: 10.2337/db06-0783 17287462; PubMed Central PMCID: PMC2995532.

10. Hu L, Han F, Chen L, Peng X, Chen D, Wu, et al. High nutrient intake during the early postnatal period accelerates skeletal muscle fiber growth and maturity in intrauterine growth-restricted pigs. Genes Nutr. 2018;13:23. Epub 2018/08/02. doi: 10.1186/s12263-018-0612-8 30065792; PubMed Central PMCID: PMC6062929.

11. Zhao X, Mo D, Li A, Gong W, Xiao S, Zhang Y, et al. Comparative analyses by sequencing of transcriptomes during skeletal muscle development between pig breeds differing in muscle growth rate and fatness. PLoS One. 2011;6(5):e19774. Epub 2011/06/04. doi: 10.1371/journal.pone.0019774 21637832; PubMed Central PMCID: PMC3102668.

12. Krueger R, Derno M, Goers S, Metzler-Zebeli BU, Nuernberg G, Martens K, et al. Higher body fatness in intrauterine growth retarded juvenile pigs is associated with lower fat and higher carbohydrate oxidation during ad libitum and restricted feeding. Eur J Nutr. 2014;53(2):583–97. Epub 2013/08/03. doi: 10.1007/s00394-013-0567-x 23907209; PubMed Central PMCID: PMC3925302.

13. Metges CC, Gors S, Martens K, Krueger R, Metzler-Zebeli BU, Nebendahl C, et al. Body composition and plasma lipid and stress hormone levels during 3 weeks of feed restriction and refeeding in low birth weight female pigs. J Anim Sci. 2015;93(3):999–1014. Epub 2015/05/29. doi: 10.2527/jas.2014-8616 26020878.

14. Chen FF, Wang YQ, Tang GR, Liu SG, Cai R, Gao Y, et al. Differences between porcine longissimus thoracis and semitendinosus intramuscular fat content and the regulation of their preadipocytes during adipogenic differentiation. Meat Sci. 2019;147:116–26. Epub 2018/09/17. doi: 10.1016/j.meatsci.2018.09.002 30219363.

15. Hellemans J, Mortier G, De Paepe A, Speleman F, Vandesompele J. qBase relative quantification framework and software for management and automated analysis of real-time quantitative PCR data. Genome Biol. 2007;8(2):R19. Epub 2007/02/13. doi: 10.1186/gb-2007-8-2-r19 17291332; PubMed Central PMCID: PMC1852402.

16. Bustin SA. Why the need for qPCR publication guidelines?—The case for MIQE. Methods. 2010;50(4):217–26. Epub 2009/12/23. doi: 10.1016/j.ymeth.2009.12.006 20025972.

17. Beauchamp B, Ghosh S, Dysart MW, Kanaan GN, Chu A, Blais A, et al. Low birth weight is associated with adiposity, impaired skeletal muscle energetics and weight loss resistance in mice. Int J Obes (Lond). 2015;39(4):702–11. Epub 2014/08/06. doi: 10.1038/ijo.2014.120 25091727; PubMed Central PMCID: PMC4326251.

18. Kelstrup L, Hjort L, Houshmand-Oeregaard A, Clausen TD, Hansen NS, Broholm C, et al. Gene Expression and DNA Methylation of PPARGC1A in Muscle and Adipose Tissue From Adult Offspring of Women With Diabetes in Pregnancy. Diabetes. 2016;65(10):2900–10. Epub 2016/07/09. doi: 10.2337/db16-0227 27388218.

19. Brown LD, Hay WW Jr. Impact of placental insufficiency on fetal skeletal muscle growth. Mol Cell Endocrinol. 2016;435:69–77. Epub 2016/03/21. doi: 10.1016/j.mce.2016.03.017 26994511; PubMed Central PMCID: PMC5014698.

20. Hansen NS, Hjort L, Broholm C, Gillberg L, Schrolkamp M, Schultz HS, et al. Metabolic and Transcriptional Changes in Cultured Muscle Stem Cells from Low Birth Weight Subjects. J Clin Endocrinol Metab. 2016;101(5):2254–64. Epub 2016/03/24. doi: 10.1210/jc.2015-4214 27003303.

21. Weinstock PH, Levak-Frank S, Hudgins LC, Radner H, Friedman JM, Zechner R, et al. Lipoprotein lipase controls fatty acid entry into adipose tissue, but fat mass is preserved by endogenous synthesis in mice deficient in adipose tissue lipoprotein lipase. Proc Natl Acad Sci U S A. 1997;94(19):10261–6. Epub 1997/09/18. doi: 10.1073/pnas.94.19.10261 9294198; PubMed Central PMCID: PMC23350.

22. Walton RG, Zhu B, Unal R, Spencer M, Sunkara M, Morris AJ, et al. Increasing adipocyte lipoprotein lipase improves glucose metabolism in high fat diet-induced obesity. J Biol Chem. 2015;290(18):11547–56. Epub 2015/03/19. doi: 10.1074/jbc.M114.628487 25784555; PubMed Central PMCID: PMC4416858.

23. Wang H, Eckel RH. Lipoprotein lipase: from gene to obesity. Am J Physiol Endocrinol Metab. 2009;297(2):E271–88. Epub 2009/03/26. doi: 10.1152/ajpendo.90920.2008 19318514.

24. Itabe H, Yamaguchi T, Nimura S, Sasabe N. Perilipins: a diversity of intracellular lipid droplet proteins. Lipids Health Dis. 2017;16(1):83. Epub 2017/04/30. doi: 10.1186/s12944-017-0473-y 28454542; PubMed Central PMCID: PMC5410086.

25. Morales PE, Bucarey JL, Espinosa A. Muscle Lipid Metabolism: Role of Lipid Droplets and Perilipins. J Diabetes Res. 2017;2017:1789395. Epub 2017/07/06. doi: 10.1155/2017/1789395 28676863; PubMed Central PMCID: PMC5476901.

26. Li B, Weng Q, Dong C, Zhang Z, Li R, Liu J, et al. A Key Gene, PLIN1, Can Affect Porcine Intramuscular Fat Content Based on Transcriptome Analysis. Genes (Basel). 2018;9(4). Epub 2018/04/05. doi: 10.3390/genes9040194 29617344; PubMed Central PMCID: PMC5924536.

27. Gandolfi G, Mazzoni M, Zambonelli P, Lalatta-Costerbosa G, Tronca A, Russo V, et al. Perilipin 1 and perilipin 2 protein localization and gene expression study in skeletal muscles of European cross-breed pigs with different intramuscular fat contents. Meat Sci. 2011;88(4):631–7. Epub 2011/03/23. doi: 10.1016/j.meatsci.2011.02.020 21420243.

28. Miyazaki M, Ntambi JM. Role of stearoyl-coenzyme A desaturase in lipid metabolism. Prostaglandins Leukot Essent Fatty Acids. 2003;68(2):113–21. Epub 2003/01/23. doi: 10.1016/s0952-3278(02)00261-2 12538075.

29. Yu K, Shu G, Yuan F, Zhu X, Gao P, Wang S, et al. Fatty acid and transcriptome profiling of longissimus dorsi muscles between pig breeds differing in meat quality. Int J Biol Sci. 2013;9(1):108–18. Epub 2013/01/29. doi: 10.7150/ijbs.5306 23355796; PubMed Central PMCID: PMC3555150.

30. Matsui H, Yokoyama T, Sekiguchi K, Iijima D, Sunaga H, Maniwa M, et al. Stearoyl-CoA desaturase-1 (SCD1) augments saturated fatty acid-induced lipid accumulation and inhibits apoptosis in cardiac myocytes. PLoS One. 2012;7(3):e33283. Epub 2012/03/14. doi: 10.1371/journal.pone.0033283 22413010; PubMed Central PMCID: PMC3297642.

31. Hulver MW, Berggren JR, Carper MJ, Miyazaki M, Ntambi JM, Hoffman EP, et al. Elevated stearoyl-CoA desaturase-1 expression in skeletal muscle contributes to abnormal fatty acid partitioning in obese humans. Cell Metab. 2005;2(4):251–61. Epub 2005/10/11. doi: 10.1016/j.cmet.2005.09.002 16213227; PubMed Central PMCID: PMC4285571.

32. Kraemer FB, Shen WJ. Hormone-sensitive lipase: control of intracellular tri-(di-)acylglycerol and cholesteryl ester hydrolysis. J Lipid Res. 2002;43(10):1585–94. Epub 2002/10/05. doi: 10.1194/jlr.r200009-jlr200 12364542.

33. Pawlak M, Lefebvre P, Staels B. Molecular mechanism of PPARalpha action and its impact on lipid metabolism, inflammation and fibrosis in non-alcoholic fatty liver disease. J Hepatol. 2015;62(3):720–33. Epub 2014/12/03. doi: 10.1016/j.jhep.2014.10.039 25450203.

34. Goldberg IJ, Eckel RH, Abumrad NA. Regulation of fatty acid uptake into tissues: lipoprotein lipase- and CD36-mediated pathways. J Lipid Res. 2009;50 Suppl:S86-90. Epub 2008/11/27. doi: 10.1194/jlr.R800085-JLR200 19033209; PubMed Central PMCID: PMC2674753.

35. Paton CM, Ntambi JM. Biochemical and physiological function of stearoyl-CoA desaturase. Am J Physiol Endocrinol Metab. 2009;297(1):E28–37. Epub 2008/12/11. doi: 10.1152/ajpendo.90897.2008 19066317; PubMed Central PMCID: PMC2711665.

36. Fischer H, Gustafsson T, Sundberg CJ, Norrbom J, Ekman M, Johansson O, et al. Fatty acid binding protein 4 in human skeletal muscle. Biochem Biophys Res Commun. 2006;346(1):125–30. Epub 2006/06/06. doi: 10.1016/j.bbrc.2006.05.083 16750515.

37. Furuhashi M, Hotamisligil GS. Fatty acid-binding proteins: role in metabolic diseases and potential as drug targets. Nat Rev Drug Discov. 2008;7(6):489–503. Epub 2008/05/31. doi: 10.1038/nrd2589 18511927; PubMed Central PMCID: PMC2821027.

38. Kusudo T, Kontani Y, Kataoka N, Ando F, Shimokata H, Yamashita H. Fatty acid-binding protein 3 stimulates glucose uptake by facilitating AS160 phosphorylation in mouse muscle cells. Genes Cells. 2011;16(6):681–91. Epub 2011/04/20. doi: 10.1111/j.1365-2443.2011.01517.x 21501347.

39. Modica S, Straub LG, Balaz M, Sun W, Varga L, Stefanicka P, et al. Bmp4 Promotes a Brown to White-like Adipocyte Shift. Cell Rep. 2016;16(8):2243–58. Epub 2016/08/16. doi: 10.1016/j.celrep.2016.07.048 27524617.

40. Mello T, Materozzi M, Galli A. PPARs and Mitochondrial Metabolism: From NAFLD to HCC. PPAR Res. 2016;2016:7403230. Epub 2017/01/25. doi: 10.1155/2016/7403230 PubMed Central PMCID: PMC5223052. 28115925

41. Henique C, Mansouri A, Fumey G, Lenoir V, Girard J, Bouillaud F, et al. Increased mitochondrial fatty acid oxidation is sufficient to protect skeletal muscle cells from palmitate-induced apoptosis. J Biol Chem. 2010;285(47):36818–27. Epub 2010/09/15. doi: 10.1074/jbc.M110.170431 PubMed Central PMCID: PMC2978610. 20837491

42. Timmers S, Nabben M, Bosma M, van Bree B, Lenaers E, van Beurden D, et al. Augmenting muscle diacylglycerol and triacylglycerol content by blocking fatty acid oxidation does not impede insulin sensitivity. Proc Natl Acad Sci U S A. 2012;109(29):11711–6. Epub 2012/07/04. doi: 10.1073/pnas.1206868109 PubMed Central PMCID: PMC3406830. 22753483

43. Wicks SE, Vandanmagsar B, Haynie KR, Fuller SE, Warfel JD, Stephens JM, et al. Impaired mitochondrial fat oxidation induces adaptive remodeling of muscle metabolism. Proc Natl Acad Sci U S A. 2015;112(25):E3300–9. Epub 2015/06/10. doi: 10.1073/pnas.1418560112 PubMed Central PMCID: PMC4485116. 26056297

44. Perreault L, Newsom SA, Strauss A, Kerege A, Kahn DE, Harrison KA, et al. Intracellular localization of diacylglycerols and sphingolipids influences insulin sensitivity and mitochondrial function in human skeletal muscle. JCI Insight. 2018;3(3). Epub 2018/02/09. doi: 10.1172/jci.insight.96805 29415895; PubMed Central PMCID: PMC5821197.

45. McGarry JD, Woeltje KF, Kuwajima M, Foster DW. Regulation of ketogenesis and the renaissance of carnitine palmitoyltransferase. Diabetes Metab Rev. 1989;5(3):271–84. Epub 1989/05/01. 2656156.

46. Zechner R, Kienesberger PC, Haemmerle G, Zimmermann R, Lass A. Adipose triglyceride lipase and the lipolytic catabolism of cellular fat stores. J Lipid Res. 2009;50(1):3–21. Epub 2008/10/28. doi: 10.1194/jlr.R800031-JLR200 18952573.

47. Ishizawa M, Kagechika H, Makishima M. NR4A nuclear receptors mediate carnitine palmitoyltransferase 1A gene expression by the rexinoid HX600. Biochem Biophys Res Commun. 2012;418(4):780–5. Epub 2012/02/09. doi: 10.1016/j.bbrc.2012.01.102 22310716.

48. Hall AM, Soufi N, Chambers KT, Chen Z, Schweitzer GG, McCommis KS, et al. Abrogating monoacylglycerol acyltransferase activity in liver improves glucose tolerance and hepatic insulin signaling in obese mice. Diabetes. 2014;63(7):2284–96. Epub 2014/03/07. doi: 10.2337/db13-1502 24595352; PubMed Central PMCID: PMC4066334.

49. Abel ED. Free fatty acid oxidation in insulin resistance and obesity. Heart Metab. 2010;48:5–10. Epub 2010/09/01. 23646039; PubMed Central PMCID: PMC3643515.

50. Sugden MC, Bulmer K, Gibbons GF, Knight BL, Holness MJ. Peroxisome-proliferator-activated receptor-alpha (PPARalpha) deficiency leads to dysregulation of hepatic lipid and carbohydrate metabolism by fatty acids and insulin. Biochem J. 2002;364(Pt 2):361–8. Epub 2002/05/25. doi: 10.1042/BJ20011699 12023878; PubMed Central PMCID: PMC1222580.

51. Sankella S, Garg A, Agarwal AK. Characterization of the Mouse and Human Monoacylglycerol O-Acyltransferase 1 (Mogat1) Promoter in Human Kidney Proximal Tubule and Rat Liver Cells. PLoS One. 2016;11(9):e0162504. Epub 2016/09/10. doi: 10.1371/journal.pone.0162504 27611931; PubMed Central PMCID: PMC5017789 report.

52. Muoio DM, Way JM, Tanner CJ, Winegar DA, Kliewer SA, Houmard JA, et al. Peroxisome proliferator-activated receptor-alpha regulates fatty acid utilization in primary human skeletal muscle cells. Diabetes. 2002;51(4):901–9. Epub 2002/03/28. doi: 10.2337/diabetes.51.4.901 11916905.

53. Jensen CB, Storgaard H, Madsbad S, Richter EA, Vaag AA. Altered skeletal muscle fiber composition and size precede whole-body insulin resistance in young men with low birth weight. J Clin Endocrinol Metab. 2007;92(4):1530–4. Epub 2007/02/08. doi: 10.1210/jc.2006-2360 17284623.

54. Handel SE, Stickland NC. The growth and differentiation of porcine skeletal muscle fibre types and the influence of birthweight. J Anat. 1987;152:107–19. Epub 1987/06/01. 2958439; PubMed Central PMCID: PMC1261750.

55. Reichmann H, De Vivo DC. Coordinate enzymatic activity of beta-oxidation and purine nucleotide cycle in a diversity of muscle and other organs of rat. Comp Biochem Physiol B. 1991;98(2–3):327–31. Epub 1991/01/01. doi: 10.1016/0305-0491(91)90186-h 1678689.

56. Bauer R, Gedrange T, Bauer K, Walter B. Intrauterine growth restriction induces increased capillary density and accelerated type I fiber maturation in newborn pig skeletal muscles. J Perinat Med. 2006;34(3):235–42. Epub 2006/04/11. doi: 10.1515/JPM.2006.042 16602845.


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