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Lactiplantibacillus plantarum FRT4 attenuates high-energy low-protein diet-induced fatty liver hemorrhage syndrome in laying hens through regulating gut-liver axis
Journal of Animal Science and Biotechnology volume 15, Article number: 31 (2024)
Abstract
Background
Fatty liver hemorrhage syndrome (FLHS) becomes one of the most major factors resulting in the laying hen death for caged egg production. This study aimed to investigate the therapeutic effects of Lactiplantibacillus plantarum (Lp. plantarum) FRT4 on FLHS model in laying hen with a focus on liver lipid metabolism, and gut microbiota.
Results
The FLHS model of laying hens was established by feeding a high-energy low-protein (HELP) diet, and the treatment groups were fed a HELP diet supplemented with differential proportions of Lp. plantarum FRT4. The results indicated that Lp. plantarum FRT4 increased laying rate, and reduced the liver lipid accumulation by regulating lipid metabolism (lipid synthesis and transport) and improving the gut microbiota composition. Moreover, Lp. plantarum FRT4 regulated the liver glycerophospholipid metabolism. Meanwhile, “gut-liver” axis analysis showed that there was a correlation between gut microbiota and lipid metabolites.
Conclusions
The results indicated that Lp. plantarum FRT4 improved the laying performance and alleviated FLHS in HELP diet-induced laying hens through regulating “gut-liver” axis. Our findings reveal that glycerophospholipid metabolism could be the underlying mechanism for the anti-FLHS effect of Lp. plantarum FRT4 and for future use of Lp. plantarum FRT4 as an excellent additive for the prevention and mitigation of FLHS in laying hens.
Background
Non-alcoholic fatty liver disease (NAFLD) is one of the most central and affecting liver metabolic diseases worldwide, which is also defined as metabolic associated fatty liver disease (MAFLD) [1]. Generally, NAFLD is known as fatty liver hemorrhage syndrome (FLHS) in laying hens [2]. Genetics, nutrition, environment, and hormones are the main factors affecting the formation of FLHS, and lipid metabolism disorder and storage in liver are the major causes [3]. Actually, poultries require sufficient energy to maintain high laying performance in breeding industry. However, excess energy can be synthetized as lipids, which accumulate largely in liver and develop into FLHS in laying hens [4]. Nevertheless, cage systems remain by far the dominant way in egg production industry, with approximately 74% of caged laying hens dying from FLHS [5]. What’s worse, FLHS would lead to the decline of laying performance, causing huge economic losses [6].
As a functional additive with low cost and high safety, probiotics have emerged as an ideal strategy to attenuate the liver lipid metabolism disorder induced by the high energy diets [7]. Particularly, Lactiplantibacillus plantarum (Lp. plantarum) has been extensively employed in clinical settings for its safety and excellent efficacy. It has been reported that Lp. plantarum has a preventive effect on NAFLD [8]. What’s more, Loh et al. [9] reported that supplementation with 0.6% Lp. plantarum RI11, RG14 and RG11 metabolites decreased cholesterol level in plasma and yolk, and the content of cholesterol in eggs of Pengging duck was reduced by feeding Lp. plantarum Ina CC B76 mixed with inulin of gembili tuber [10]. There are few reports on the treatment of FLHS in laying hens by Lp. plantarum, and comprehensive studies on the lipid metabolism of Lp. plantarum in laying hens are scarce, and no relevant systematic study has been reported.
Lp. plantarum FRT4 was isolated, identified, and stored in our laboratory with CGMCC No.17955. Previous studies revealed that Lp. plantarum FRT4 regulated lipid metabolism and efficiently alleviated high-fat diet-induced obesity in mice through regulating gut microbiota [11, 12]. Therefore, we hypothesized that Lp. plantarum FRT4 had the efficiency to relieve FLHS in laying hens by regulating liver lipid metabolism and gut microbiota. This study was conducted to investigate the effect of Lp. plantarum FRT4 on liver lipid metabolism by liquid chromatography-mass spectrometry (LC-MS) and gas chromatography-mass spectrometry (GC-MS) analysis, and gut microbiota in laying hens with a high-energy low-protein (HELP) diet, which provided the evidences for the application of Lp. plantarum FRT4 to alleviate FLHS in laying hens.
Materials and methods
Ethics statement
Generated statement: The animal study was reviewed and approved by the Institutional Animal Care and Use Committee of the Institute of Feed Research of Chinese Academy of Agricultural Sciences (IFR-CAAS20220729).
Experimental design and animal management
A total of 450 44-week-old Hy-line brown laying hens with the initial egg laying rate of 80.27% were randomly divided into 5 groups: normal diet (CT, control group), high-energy low-protein diet (HELP, model group), HELP diet supplemented with 109 CFU/kg Lp. plantarum FRT4 (FRT4L group), HELP diet with 1010 CFU/kg Lp. plantarum FRT4 (FRT4M group), and HELP diet with 1011 CFU/kg Lp. plantarum FRT4 (FRT4H group). Each group contained 6 replications and each replication contained 15 hens. The laying hens were housed in a fully enclosed chicken house with a one-story ladder cage system and a relative humidity of appropriately 65% during the trial period and received water and diet ad libitum. After 2 weeks feeding normal diet, then the test was conducted and latest for 8 weeks. The laying rate, average daily feed intake (ADFI), and death rate were recorded daily. Average daily metabolic energy consumption (ADMEC) was calculated daily. Finally, the laying performance was corrected based on death rate.
The composition and nutrition contents of normal diet met the NRC (1994) [13], and the composition and nutrition contents of normal HELP diet referred to a previous study [14], which were shown in Additional file 1: Table S1.
Sample collection
At the end of 8th week, one laying hen per replicate was randomly selected for sampling after fasting for 12 h. The laying hens were euthanized via cutting the jugular vein for sample collection.
Liver and ovarian tissues were collected, and part of them were fixed in 4% neutral buffered paraformaldehyde for morphological observation and Oil Red O stain, and the other liver tissues were immediately frozen in liquid nitrogen, and then stored at −80 ºC. The caecal content was collected on ice and stored in liquid nitrogen immediately.
Oil Red O staining of liver tissue
The fixed liver tissue was dehydrated and embedded by OCT embedding agent (G6059, Servicebio, Wuhan, China). The tissue was rough cut and sliced for 8 μm by a slicer (LEICA 819, LEICA, Shanghai, China). Then, the slices were stained with Oil Red O solution (G1015, Servicebio, Wuhan, China) in the dark, and covered with lid during dying. Next, the slices were immersed in 60% isopropanol for differentiation in turn (G1039, Servicebio, Wuhan, China). After that, the slices were stained by hematoxylin solution (G1004, Servicebio, Wuhan, China). Finally, sealing the slice with glycerin gelatin (G1402, Servivebio, Wuhan, China). The stain section was observed with microscope inspection (NIKON ECLIPSE E100, Nikon, Japan) and image system (NIKON DS-U3, Nikon, Japan).
Biochemical assay of liver and ovarian tissues
The liver and ovarian tissues were washed with ice-cold phosphate buffered saline (PBS, pH 7.4), weighted 0.1 g and homogenized in 0.9 mL PBS or 1.0 mL isopropanol with a homogenizer. Then, the homogenates were centrifuged at 3,000 × g for 15 min at 4 ºC by a centrifuge (CT15RE, Hirachi Koki Co., Ltd., Tokyo, Japan). The supernatant was harvested for biochemistry parameters determination. The concentrations of triglyceride (TG), total cholesterol (TC), high-density lipoprotein cholesterol (HDL-C), low-density lipoprotein cholesterol (LDL-C), very low-density lipoprotein cholesterol (VLDL-C) in supernatant were measured with the corresponding kits (catalogue No. ml076637, ml076635, ml036973, ml036983, and ml060950, respectively) provided by Shanghai Enzyme-linked Biotechnology Co., Ltd. (Shanghai, China). All operations were carried out in accordance with the kits’ instructions. All the reading was performed with a microplate reader (1530, Thermo Fisher Scientific, Vantaa, Finland).
qRT-PCR analysis
Total RNA was isolated from liver tissues by FastPure® Cell/Tissue Total RNA Isolation Kit V2 (RC112-01, Vazyme Biotech Co., Ltd., Nanjing, China). RNA (0.1 µg) was used for reverse transcription by using Hiscript® RT SuperMix for qPCR (+ gDNA wiper) kits (R323-01, Vazyme Biotech Co., Ltd., Nanjing, China). The reverse productions were used to perform qRT-PCR with the kits of Taq Pro Universal SYBR qPCR Master Mix (Q712-03, Vazyme Biotech Co., Ltd., Nanjing, China). The house keeping gene (β-actin) was assessed for the stability of expression. The expression level of each gene was calculated by using the 2−ΔΔCt method. The primer sequences for all genes are presented in Additional file 1: Table S2.
Untargeted liver metabolic analysis with LC-MS and GC-MS
Liver tissue metabolites extraction
The samples (30 mg) were accurately weighted into EP tubes (2 replications). Two small steel balls and 600 µL methanol (A452, Thermo Fisher Scientific, Waltham, MA, USA)-water (Wahaha, China) (v:v = 4:1, containing L-2-chlorophenylalanine (C2001, Shanghai Hengchuang Bio-technology Co., Ltd, Shanghai, China, 4 µg/mL)) were added into tubes. After pre-cooling in a refrigerator at −40 ºC for 2 min, the mixture was placed into a grinder (F-060SD, Fuyang Technology Co., Ltd., Shenzhen, China) for grinding (60 Hz, 2 min), and then ultrasonic extraction was put in an ice water bath for 10 min, and stewed at −40 ºC for 2 h (LC-MS) and 30 min (GC-MS). Subsequently, the mixed solution was centrifuged at 12,000 × g for 10 min at 4 ºC with a centrifuge (TGL-16MS, Luxiangyi Centrifuge Instrument Co., Ltd., Shanghai, China), and then the supernatant was filtered with a 0.22-μm organic phase pinhole filter. The filtrate was stored at −80 ºC for LC-MS analysis. Quality control (QC) samples were prepared by mixing aliquot of the all samples to be a pooled sample.
The sample using for GC-MS analysis was centrifuged at 12,000 × g for 10 min at 4 ºC. The supernatant (150 µL) was put into a glass derivative bottle and evaporated using a centrifugal concentration dryer. The methoxylamine hydrochloride solution (80 µL) (M813479, Macklin, Shanghai, China)-pyridine (P141169, Aladdin, Shanghai, China) was added into the glass derivative vial (15 mg/mL), and the mixed solution was placed in a shaking incubator (THZ-82, Lichen Bangxi Instrument Technology Co., Ltd., Shanghai) at 37 ºC for 60 min to undergo oximation reaction. BSTFA derivatization reagent (50 µL) (B0830, TCI, Japan), 20 µL N-hexane (4.011518.0500, CNW, Germany), and 10 µL per internal standard (C8/C9/C10/C12/C14/C16/C18/C20/C22/C24, configured with chloroform, G75915B, Greagent, Shanghai, China) were added into the reaction mixture. After reacting at 70 ºC for 60 min, the sample was kept at room temperature for 30 min for GC-MS metabolomic analysis. QC samples were prepared by mixing aliquot of the all samples to be a pooled sample.
LC-MS and GC-MS metabolomic analysis
LC-MS (Dionex U3000 UHPLC, QE plus, Thermo Fisher Scientific, Waltham, MA, USA) analysis conditions: chromatographic column (Acquity UPLC HSS T3, 100 mm × 2.1 mm × 1.8 μm, Waters, Milford, USA), and column temperature was 45 ºC. The mobile phases were A-water (containing 0.1% formic acid, A117-50, Thermo Fisher Scientific, Waltham, MA, USA), and B-acetonitrile (A998-4, Thermo Fisher Scientific, Waltham, MA, USA). The flow rate was 0.35 mL/min, and the injection volume was 5 µL. The UHPLC fitted with Q-Exactive Plus Quadrupole-Orbitrap mass spectrometer quipped with heated electrospray ionization (ESI) source (Thermo Fisher Scientific) was used to analyze the metabolic profiling in both ESI positive and ESI negative ion modes. The mass range was from 100 to 1,000 m/z. The resolution was set at 70,000 for the full MS scans and 17,500 for HCD MS/MS scans. The collision energy was set at 10, 20, and 40 eV. The mass spectrometer operated as follows: spray voltage, 3,800 V (+) and 3,000 V (−); sheath gas flow rate, 35 arbitrary units; auxiliary gas flow rate, 8 arbitrary units; capillary temperature, 320 ºC; Aux gas heater temperature, 350 ºC; S-lens RF level, 50. The QCs were injected at regular intervals throughout the analytical run to provide a set of data from which repeatability can be assessed.
GC-MS analysis conditions: DB-5MS capillary column (30 m × 0.25 mm × 0.25 μm, Agilent, Folsom, CA, USA). The carrier gas was high purity helium (purity not less than 99.999%). The flow rate was 1.0 mL/min, and the temperature of the sample inlet was 260 ºC. The injection volume was 1 µL. Without split injection, the solvent was delayed for 5 min. The programs of temperature rise: The initial temperature of the column temperature box was 60 ºC, maintained for 0.5 min, and then rose to 125 ºC at a rate of 8 ºC/min, to 210 ºC at a rate of 8 ºC/min, to 270 ºC at a rate of 15 ºC/min, to 305 ºC at a rate of 20 ºC/min and hold for 5 min. The temperature of MS quadrupole and ion source (electron impact) was set to 150 and 230 ºC, respectively. The collision energy was 70 eV. Mass spectrometric data was acquired in a full-scan mode (50–500 m/z). The QCs were injected at regular intervals throughout the analytical run to provide a set of data from which repeatability can be assessed.
16S rRNA sequencing and analysis
DNA extraction and amplification
Total DNA was extracted from the caecal contents using a DNeasy PowerSoil kit (Qiagen, Hilden, Germany) following the manufacturer’s instructions. DNA concentration and integrity were measured by a NanoDrop 2000 spectrophotometer (Thermo Fisher Scientific, Waltham, MA, USA) and agarose gel electrophoresis, respectively. PCR amplification of the V3-V4 hypervariable regions of the bacterial 16S rRNA gene was carried out in a 25 µL reaction system using universal primer pairs (343F: 5′-TACGGRAGGCAGCAG-3′, 798R: 5′-AGGGTATCTAATCCT-3′). The reverse primer contained a sample barcode and both primers were connected with an Illumina sequencing adapter.
Library construction and sequencing
The amplicon quality was visualized using gel electrophoresis. The PCR products were purified with Agencourt AMPure XP beads (Beckman Coulter Co., USA) and quantified using Qubit dsDNA assay kit. The concentrations were then adjusted for sequencing. Sequencing was performed on an Illumina NovaSeq 6000 with two paired-end read cycles of 250 bases each (Illumina Inc., San Diego, CA; OE Biotech Company, Shanghai, China).
Bioinformatic analysis
Raw sequencing data were in FASTQ format. Paired-end reads were then preprocessed using cutadapt software to detect and cut off the adapter. After trimming, paired-end reads were filtering low quality sequences, denoised, merged and detect and cut off the chimera reads using DADA2 with the default parameters of QIIME2. At last, the software output the representative reads and the amplicon sequence variants (ASVs) abundance table. The representative reads of each ASV were selected using QIIME2 package.
Statistical analysis
The data were arranged using Excel (version 2019). The differences between two groups were analyzed by t-test of SPSS (version 25.0). The graphs were performed using GraphPad Prism version 8.0 (GraphPad Software, San Diego, CA, USA) and expressed as the mean ± SEM; n = 6 hens per group. P < 0.05 was considered to be significant difference.
The original LC-MS data were processed by software Progenesis QI (Version 2.3, Nonlinear, Dynamics, Newcastle, UK) for baseline filtering, peaking identification, integral, retention time correction, peak alignment, and normalization. The obtained GC-MS raw data were imported into software MS-DIAL, performing peak identification, MS2Dec deconvolution, characterization, peak alignment, wave filtering, and missing value interpolation. Metabolite characterization was based on LUG database. After the data were normalized, redundance removal and peak merging were conducted to obtain the data matrix. Orthogonal Partial Least-Squares-Discriminant Analysis (OPLS-DA) was utilized to distinguish the metabolites that differed between groups. To prevent overfitting, 7-fold cross-validation and 200 response permutation testing were used to evaluate the quality of the model. Variable importance of projection (VIP) values obtained from the OPLS-DA model were used to rank the overall contribution of each variable to group discrimination. A two-tailed Student’s t-test was further used to verify whether the metabolites of difference between groups were significant.
Results
Effect of Lp. plantarum FRT4 on laying performance of laying hens
During the period of test, the laying performance was recorded. As shown in Fig. 1A, the laying rate was decreased in the HELP group (80.63%) compared to the CT group (81.49%) (P > 0.05). After supplementation with Lp. plantarum FRT4, the laying rates was increased significantly in the FRT4L, FRT4M, and FRT4H groups (83.45%, 87.49%, and 85.11%, respectively) compared to the HELP group (P < 0.05). The ADFI was decreased significantly and ADMEC was increased in the HELP group compared to the CT group (P < 0.05). Compared to the HELP group, no significant difference was observed for the ADFI and ADMEC in Lp. plantarum FRT4 treatment groups (P > 0.05). In addition, the death rate in the CT group was 1%. However, the HELP group (3%) had higher death rate than the CT group. Importantly, Lp. plantarum FRT4 treatment groups had no death rate. Thus, Lp. plantarum FRT4 had the advantages on improving the laying performance of laying hens.
Effect of Lp. plantarum FRT4 on liver and ovary biochemical indices of laying hens
A distinct dissimilarity of liver morphology was shown between CT group and HELP group (Fig. 1B). The liver was red in the CT group, while yellow in the HELP group, which was observed clearly. There was no significant difference between HELP and Lp. plantarum FRT4 intervention groups. Oil Red O stain of liver tissues showed that compared to the HELP group, the liver tissue in CT, FRT4L, FRT4M, and FRT4H groups contained lower lipid accumulation (Fig. 1C).
As shown in Fig. 1D, the contents of TC and TG in the HELP group were significantly higher than the CT group (P < 0.05), which were significantly reduced after Lp. plantarum FRT4 intervention. Furthermore, feeding HELP diet significantly reduced the contents of HDL-C and VLDL-C, and increased the content of LDL-C (P < 0.05) compared to the CT group, which were significantly reversed after Lp. plantarum FRT4 supplementation (P < 0.05).
As shown in Fig. 1E, compared to the CT group, the contents of TG and TC in HELP group were significantly increased (P < 0.05). No significant difference was observed for HDL-C, LDL-C, and VLDL-C between CT and HELP groups (P > 0.05). In the groups of FRT4M and FRT4H, the contents of TG and TC were significantly decreased after Lp. plantarum FRT4 supplementation (P < 0.05).
Effect of Lp. plantarum FRT4 on lipid metabolism-related factors in liver
The liver is the main organ of lipid homeostasis in the body, including lipid synthesis, transport, and β-oxidation. Compared to the CT group, the relative mRNA expressions of lipid synthesis including fatty acid synthase (FASN), stearoyl-CoA desaturase-1 (SCD-1), acetyl-CoA carboxylase alpha (ACACA), and malic enzyme 1 (ME1), and their upstream regulatory factor, sterol regulatory element binding protein 1 (SREBP-1), was significantly upregulated in the HELP group (P < 0.05) (Fig. 2), while was significantly downregulated after Lp. plantarum FRT4 supplementation (P < 0.05). The expression of fatty acid binding protein 1 (FABP1) and very low-density lipoprotein receptor (VLDLR), regulating liver lipid transport, was significantly downregulated (P < 0.05). The expression of FABP1 in the FRT4H group and VLDLR in FRT4M and FRT4H groups was significantly upregulated (P < 0.05). The results indicated that Lp. plantarum FRT4 supplementation mainly regulated and improved the lipid synthesis and transport to reduce the hepatic lipid deposition.
Effect of Lp. plantarum FRT4 on liver metabolites through untargeted metabonomic analysis
Multivariate statistical analysis of liver metabolites
After quality control (Additional file 2: Fig. S1–6), OPLS-DA was used to determine the metabolites, and permutation test displayed the stability of the OPLS-DA model. As shown in Fig. 3A and E, the OPLS-DA score scatter plot showed that there were significant differences between the HELP group and CT group, which indicated that HELP diet changed the liver metabolism of laying hens. Figure 3B and F showed that Lp. plantarum FRT4 intervention had significantly different clustering trends compared to the HELP group. Besides, the permutation test displayed the stability of the OPLS-DA model (Fig. 3C, D, G and H), indicating that OPLS-DA model had a good quality and was not over-fitted.
Differential metabolites analysis
Based on the OPLA-DA analysis, the VIP was used to measure the influence intensity and interpretation ability of the expression mode of each metabolite on the classification and discrimination. Further t-test was used to verify whether the different metabolites between two groups were significant. Finally, according to VIP > 1 and P < 0.05, 86 and 89 differential metabolites were identified for HELP compared to CT group and FRT4M compared to HELP group, respectively (see Additional file 3).
Compared to the CT group, 19 differential metabolites involving carboxylic acids and derivatives were significantly altered in HELP group (Fig. 4A), including 9 increased metabolites like D-glutamine (P < 0.001), L-serine and alanylserine (P < 0.01), L-aspartic acid, isoleucylproline, valylserine, (2S)-2-amino-5-aminooxy-5-oxopentanoic acid, prolyl-lysine and (R)-propyl 2-amino-3-mercaptopropanoate (P < 0.05), and 10 decreased metabolites including L-2-aminobutanoic acid (P < 0.01), aminoadipic acid, beta-alanine, creatine, glycine, sarcosine, malonic acid, N6-acetyl-L-lysine, 5-aminopentanoic acid, N-linoleoyl methionine (P < 0.05). Ten potential biomarkers involving fatty acyls were significantly altered, including 3 increased metabolites like 3-hydroxyhexanedioylcarnitine (P < 0.001), cis-9-palmitoleic acid and oleic acid (P < 0.05), and 7 decreased metabolites including cetyl alcohol, alpha-linolenic acid, 4-hydroxybutyric acid, lauric acid, (E,E)-3,7,11-trimethyl-2,6,10-dodecatrienyl octanoate, TMC-1 C and 3-methylglutarylcarnitine (P < 0.05). Five differential metabolites involving glycerophospholipids were significantly increased, including LysoPC(16:0/0:0), LysoPE(22:5(7Z,10Z,13Z,16Z,19Z)/0:0), glycerophosphoinositol (P < 0.001), PE(O-18:0/0:0) and PIM1(19:1(9Z)/18:0) (P < 0.05). Twenty-six differential metabolites involving organonitrogen compounds were significantly altered, including 16 increased metabolites, such as sphinganine and N-acetyl-b-glucosaminylamine (P < 0.001), 1-butylamine, formycin B and aminofructose 6-phosphate (P < 0.01), sphingosine, D-gulose, beta-D-glucose 6-phosphate, and glucose 1-phosphate (P < 0.05), etc., and 10 decreased metabolites like gluconic acid, glucosamine, beta-D-glucosamine and semilepidinoside B (P < 0.001), shikimic acid (P < 0.01), putrescine, L-threonic acid, pantothenic acid, 5-(3´-hydroxyphenyl)-γ-valerolactone 3´-glucuronide and 4-hydroxybenzaldehyde (P < 0.05).
Compared to the HELP group, 18 potential biomarkers involving carboxylic acids and derivatives were significantly altered in FRT4M group (Fig. 4B), including 6 increased metabolites like L-histidine and prolyl-glutamine (P < 0.001), L-2-amino-3-(1-pyrazolyl) propanoic acid (P < 0.01), L-2-aminobutanoic acid, 3-methylhistidine and ophthalmic acid (P < 0.05), and 12 decreased metabolites like D-proline, gamma-glutamylglutamic acid (P < 0.001), N-acetylhistidine (P < 0.01), cysteineglutathione disulfide, oxidized glutathione, N-isobutyryl-L-cysteine and glycyl-prolyl-glutamic acid (P < 0.05), etc. Eight potential biomarkers involving fatty acyls were significantly altered. The metabolite cetyl alcohol was increased (P < 0.05), while 7 metabolites like docosahexaenoic acid, 2-hydroxydocosanoylcarnitine (P < 0.001), 2-hydroxycaproic acid (P < 0.01), aminocaproic acid, 2-hydroxyhexadecanal and 8-hydroxy-17-octadecene-10,12-diynoic acid (P < 0.05) were decreased. Twenty-four potential biomarkers involving glycerophospholipid metabolism were significantly decreased, including glycerylphosphorylcholine, glycerophosphocholine, LysoPC(18:0/0:0), LysoPC(20:1(11Z)/0:0), LysoPC(20:3(8Z,11Z,14Z)/0:0), LysoPC(20:2(11Z,14Z)/0:0), PC(17:1(9Z)/0:0), LysoPE(20:3(5Z,8Z,11Z)/0:0), LysoPE(20:1(11Z)/0:0), LysoPE(20:2(11Z,14Z)/0:0), LysoPE(16:1(9Z)/0:0) and LysoPE(0:0/20:1(11Z)) (P < 0.001), PG(18:3(6Z,9Z,12Z)/0:0) (P < 0.01), PC(22:1(11Z)/0:0), PC(O-16:0/3:1(2E)) and LysoPI(18:1(9Z)/0:0) (P < 0.05), etc. Eleven potential biomarkers involving organonitrogen compounds were significantly altered, including 3 increased metabolites like gluconic acid (P < 0.01), 4-methylcatechol 1-glucuronide 5-(3´-hydroxyphenyl)-γ-valerolactone 3´-glucuronide (P < 0.05), and 8 decreased metabolites like sphingosine, (2R,3R)-2-aminooctadecane-1,3-diol and 4-hydroxysphinganine (P < 0.001), melibiose and aminofructose 6-phosphate (P < 0.01), glucose 1-phosphate, maltotriose and 3h-adrenaline (P < 0.05).
Differential metabolic pathway analysis
The differential metabolites were analyzed through pathway enrichment analysis based on Kyoto Encyclopedia of Genes and Genomes (KEGG) database. There were 50 and 28 metabolic pathways identified in HELP group compared to CT group and FRT4M group compared to HELP group, respectively (see Additional file 4). Furthermore, metabolic pathway was considered significantly differential pathway according to P < 0.05. Fifteen metabolic pathways were significantly different in HELP compared to the CT group (Fig. 5A), including sphingolipid metabolism, glycine, serine and threonine metabolism, beta-alanine metabolism, arginine and proline metabolism, lysine degradation, fatty acid biosynthesis, pantothenate and CoA biosynthesis, glycolysis/gluconeogenesis, pentose phosphate pathway, neuroactive ligand-receptor interaction, and glycerophospholipid metabolism, etc. Six metabolic pathways were significantly different in FRT4M group compared to the HELP group (Fig. 5B), including glycerophospholipid metabolism, lysosome, apoptosis, histidine metabolism, foxO signaling pathway, and necroptosis. It’s worth noting that the glycerophospholipid metabolism was the most significantly different pathway. Besides, the interactive metabolic pathway map based on the KEGG database involving glycerophospholipid metabolism, sphingolipid metabolism, glycine, serine and threonine metabolism, and beta-alanine metabolism was shown in Fig. 5C.
Effect of Lp. plantarum FRT4 on glycerophospholipid metabolism-related factors in liver
According to the metabolomic analysis, we found that glycerophospholipid metabolic pathway played an important role in alleviated FLHS in laying hens intervened by Lp. plantarum FRT4. Thus, we investigated the related genes expression involving in glycerophospholipid metabolic pathway in liver (Fig. 6). The key gene expression of phosphate cytidylyltransferase 1 alpha (PCYT1α), phosphate cytidylyltransferase 2 (PCYT2), glycerophosphodiester phosphodiesterase 1 (GDE1), glycerophosphodiester phosphodiesterase domain containing 5 (GDPD5), lysophosphatidylcholine acyltransferase 2 (LPCAT2), LPCAT3, and phosphatidylserine decarboxylase (PISD) in glycerophospholipid metabolic pathway were significantly increased in HELP group compared to the CT group (P < 0.05). The PCYT2 and PISD expression levels intervened by Lp. plantarum FRT4 were significantly decreased compared to the HELP group (P < 0.05).
Effect of Lp. plantarum FRT4 on caecal content microbiota of laying hens
A total of 3,030 ASVs were observed in this study. 1,154 ASVs with 170 unique ASVs, 1,158 ASVs with 321 unique ASVs, 1,470 ASVs with 317 unique ASVs, 1,451 ASVs with unique 384 ASVs, and 1337 ASVs with 288 unique ASVs were identified in CT, HELP, FRT4L, FRT4M, and FRT4H groups, respectively (Fig. 7A). Although the difference was not significant, the Chao1 and Simpson indices of α-diversity increased in HELP, which was reserved after Lp. plantarum FRT4 supplementation (Fig. 7B and C). PCoA analysis showed that the microbiota community structure in HELP group (purple interval) and FRT4L group (orange interval) differed from the CT group (shown with green interval) (Fig. 7D). The community structures of FRT4M (blue interval) and FRT4H (red interval) groups were more similar to the CT group.
The top 15 relative abundance microorganisms of the microbiota composition at different levels were calculated. At phylum level (Fig. 8A), Bacteroidota, Firmicutes, Fusobacteriota, Proteobacteria, and Campilobacterota were the dominant phyla in all groups, and total relative abundance of which were more than 95%. The laying hens fed HELP diet reduced the relative abundance of Bacteroidota, Fusobacteriota, Proteobacteria and Campilobacterota, and the ratio of Firmicutes to Bacteroidota (F/B), while supplied with Lp. plantarum FRT4 reconstructed these microbes. At the genus level, Bacteroides, Rikenellaceae_RC9_gut_group, Fusobacterium, Prevotellaceae_UCG-001, Muribaculaceae, [Ruminococcus]_torques_group, Campylobacter, and Lactobacillus were the dominant genera in all groups (Fig. 8B). The relative abundances of Fusobacterium, Prevotellaceae_UCG-001, Muribaculaceae, Campylobacter, Lactobacillus were decreased, and the relative abundances of Bacteroides, Faecalibacterium, and Prevotellaceae_Ga6A1_group were increased in HELP group compared to the CT group, while Lp. plantarum FRT4 supplementation reconstructed these microbes as well.
The linear discriminant analysis (LDA) effect size (LEfSe) analysis was used to identify the significant difference between groups (LDA > 3) using LEfSe software. In the CT group, Slackia was the biomarker (Fig. 9A). In the HELP group, Butyricicoccaceae and Colidextribacter were the biomarkers. Blautia was the biomarker in FRT4L group. Bacilli, Lactobacillales, Lactobacillus, WPS-2, and WPS-2 were the biomarkers in FRT4M group. Proteobacteria, Enterobacter, and Allobaculum were the biomarkers in FRT4H group.
Lp. plantarum FRT4 intervention not only altered the composition of gut microbiota, but also improved the liver lipid metabolism. Therefore, the correlation between gut microbiota and liver lipid parameters was analyzed by Spearman correlation analysis (Fig. 9B). The results showed that Bacteroidota was negatively related with TG, TC, and LDL-C (P < 0.05). Synergistota, Desulfbacterota, and Verrucomicrobiota were positively related with TG (P < 0.05). Firmicutes was positively related with LDL-C (P < 0.001), while Proteobacteria was negatively with LDL-C (P < 0.05). The correlated results suggested that there was interaction between liver lipids and gut microbiota, which demonstrated the beneficial roles of Lp. plantarum FRT4 on the regulation of gut microbiota in FLHS of laying hens.
Discussion
FLHS is one of the most serious liver metabolic diseases that causes decrease in the laying rate and unexpected death of laying hens, which has brought great losses to the breeding industry. Although FLHS has been explored for a long time, there are no efficient methods to solve the problem. In this study, Lp. plantarum FRT4 was used to treat the FLHS in laying hens induced by HELP diet, aiming to clarify the regulatory mechanisms that Lp. plantarum FRT4 alleviated the FLHS in laying hens.
In recent years, HELP diet has become the popular approach to construct FLHS chicken model [14, 15]. The TG accumulation in liver was often considered the main characteristic of FLHS [16]. The hens suffering FLHS or liver lipid metabolism disorder would have lower laying production [17, 18]. In our study, the laying rate was decreased after feeding HELP diet, and the concentrations of TG, TC, and LDL-C in HELP group were higher than the CT group. Meanwhile, the representative photographs and Oil Red O stain of liver tissues showed that the liver steatosis occurred in HELP group. These results indicated that the FLHS model in laying hens was successfully established, which was consistent with the reported reference [14]. However, supplementation with Lp. plantarum FRT4 significantly increased the laying rate, and reduced the concentrations of TG, TC, and LDL-C in liver. The concentrations of HDL-C and VLDL-C in HELP were significantly lower than the CT group. Meanwhile, supplementation with Lp. plantarum FRT4 significantly increased the concentrations of HDL-C and VLDL-C in liver compared to the HELP group, which did not differ from the CT group. Jia et al. [19] considered the density of lipoprotein was related to the transport of cholesterol as well as HDL-C and VLDL-C has been considered to have a protective effect for liver lipid metabolism, while LDL-C was harmful to liver. Batista et al. [20] considered high level of VLDL could promote lipolysis. Importantly, our previous study suggested that Lp. plantarum FRT4 reduced the TG and GLU contents in liver and serum in HFD-induced obese mice [12]. Evidences above suggested that Lp. plantarum FRT4 could reduce the lipid deposition induced by HELP diet in laying hens.
SREBP-1, FASN, SCD-1, ACACA, and ME1 are the key genes involved in lipid synthesis [21]. SREBP-1 is the important transcription factor regulating the lipid biosynthesis and uptake. FSAN is the key enzymes that catalyzes fatty acid synthesis. ACACA is the important fatty acid rate-limiting enzyme. SCD-1 and ME1 are the major enzymes that catalyze lipogenesis. HELP diet significantly upregulated the expressions of SREBP-1, FASN, SCD-1, ACACA, and ME1 in liver of laying hens, resulting in lipid accumulating. However, supplementation with Lp. plantarum FRT4 reversed the expression increase of these genes, and reduced the lipid synthesis in liver. FABP is related with lipid transport [22]. VLDLR, LPL, and microsomal triglyceride transfer protein (MTTP) usually play a crucial role in transport and metabolism of lipoprotein and lipid [23, 24]. The expressions of FABP1 and VLDLR were significantly decreased by HELP diet, while were upregulated after Lp. plantarum FRT4 intervention. Therefore, Lp. plantarum FRT4 intervention reduced the lipid accumulation in laying hens through reducing lipid synthesis and promoting lipid transport.
In order to clarify the role of Lp. plantarum FRT4 in adjusting liver metabolism in FLHS, untargeted metabolic assay was used through LC-MS and GC-MS analysis. Previous studies reported that sphingolipid was an important biomarker for NAFLD [25]. Concurrently, researchers have proclaimed that glycerophospholipid metabolism was one of the most important pathways in influencing liver lipid metabolism [26]. In the present study, sphingolipid metabolism associated with sphingolipids metabolites, such as L-serine, sphingosine, sphinganine and o-phosphoethanolamine, were significantly upregulated in HELP group compared to the CT group, as well as glycerophospholipid metabolism associated with glycerophospholipid metabolites like PE(O-18:0/0:0), LysoPC(16:0/0:0), LysoPE(22:5(7Z,10Z,13Z,16Z,19Z)/0:0) and glycerophosphoinositol were significantly upregulated. Sphingolipids are bioactive lipids regulating organism biology and could be found in livers of NAFLD [27]. Therefore, HELP diet could cause the FLHS in laying hens through gathering lipid in liver. Compared to the HELP group, glycerophospholipid metabolism associated with 23 glycerophospholipid metabolites, such as LysoPC(18:0/0:0), LysoPC(20:1(11Z)/0:0), glycerylphosphorylcholine, glycerophosphocholine, PC(17:1(9Z)/0:0), LysoPC(20:3(8Z,11Z,14Z)/0:0), LysoPE(16:1(9Z)/0:0), etc., were significantly downregulated in FRT4M group. Phosphatidylcholine (PC) and phosphatidylethanolamine (PE) were the main parts of glycerophospholipids [26]. Vinaixa et al. [28] considered that animals, suffering from NAFLD, had a higher conversion of PC and PE in liver. Meanwhile, glycerophospholipids and sphingolipids were the important metabolites affecting the development and progression of NAFLD [29]. In the present study, the concentrations of PC and PE were significantly increased in the HELP group, while decreased significantly in the FRT4M group. Therefore, it has compelling reasons to convince that Lp. plantarum FRT4 ameliorated FLHS in laying hens by the way of improving glycerophospholipid metabolism.
The results of liver metabonomic analysis indicated the glycerophospholipid metabolic pathway (gga00564) played a crucial role in the occurrence and development of FLHS. Herein, we determined the correlated genes expression level of glycerophospholipid metabolism to clarify the regulatory mechanism of alleviating FLHS by Lp. plantarum FRT4. PC is one of the most abundant phospholipids [30], as well as phospholipids are esters of glycerol, fatty acids, phosphoric acid, and other alcohols. PE is the substrate of lipid peroxidation [31]. PCYT1α [EC: 2.7.7.15] and PCYT2 [EC: 2.7.7.14] were reported importantly associated with PC and PE de novo synthesis [32, 33]. The expression levels of PCYT1α and PCYT2 were significantly increased resulting from HELP diet, while significantly decreased after Lp. plantarum FRT4 intervention. The expressions of key genes PISD [EC: 4.1.1.65] and ethanolamine kinase (ETNK, [EC: 2.7.1.82]) had the similar expression trends, catalyzing the PS decarboxylation for synthesis of PE [34]. Furthermore, the liver metabonomic results showed that the contents of glycerophospholipid metabolites were significantly decreased in liver after Lp. plantarum FRT4 treatment. A previous study reported that glycerophospholipids played a vital role in the development of NAFLD [35]. Concurrently, other related genes of PE and PC metabolism (M00090, M00091, M00092, M00093), such as choline/ethanolamine phosphotransferase 1 (CEPT1 [EC: 2.7.8.1]), choline kinase alpha (CHKα [EC: 2.7.1.32]), GDPD5 [EC: 3.1.4.2], phospholipase A2 group VI (PLA2G6 [EC: 3.1.1.4]), LYPLA2 [EC: 3.1.1.5], LPCAT2 and LPCAT3 [EC: 2.3.1.23], were regulated by Lp. plantarum FRT4. The results indicated that Lp. plantarum FRT4 treatment decreased the expression of glycerophospholipid metabolism-related factors to reduce the glycerophospholipid metabolites synthesis, enhance the glycerophospholipid metabolites metabolism, and protect laying hens against FLHS.
Substantial studies have supported that the gut microbiota plays a pivotal role in NAFLD. The gut microbiota composition always keeps a relatively stable state of laying hens, and the dominant phyla were Bacteroidota, Firmicutes, Proteobacteria, Actinobacteriota, and Fusobacteriota. The higher of Firmicutes and lower Bacteroidota, as well as descended F/B, were the characteristic of NAFLD [36]. Alferink et al. [37] perceived that hepatic steatosis was usually associated with Ruminococcus. Higher abundance of Firmicutes and Ruminococcaceae, and lower Bacteroidota was found in the HELP group, while Lp. plantarum FRT4 supplementation decreased the abundances of Firmicutes and Ruminococcaceae, and increased the abundance of Bacteroidota. In addition, the correlation analysis indicated that TG, TC, and LDL-C showed a negative correlation with Bacterioda, and LDL-C was positive correlation with Firmicutes. Wang et al. [38] reported that Clostridium butyricum could affect lipid metabolism of laying hens by increasing the abundance of Clostridia, Prevotellaceae, and Bifidobacteriaceae. Besides, Fan and Pedersen [39] reported that Proteobacteria and Fusobacteria were enriched in liver cirrhosis or nonalcoholic steatohepatitis. Contrarily, the abundances of Proteobacteria and Fusobacteria were decreased in HELP group compared to the CT group, and increased in FRT4L and FRT4H groups compared to the HELP group, while decreased in FRT4M group compared to the HELP group. However, the lipid contents in groups supplied with Lp. plantarum FRT4 were decreased. Thus, it is required to be further confirmed that how Lp. plantarum FRT4 improved the liver lipid metabolism in laying hens through altering Proteobacteria and Fusobacteria abundances in our future research. Although with a lower abundance, what the interesting was that WPS-2 was only identified in FRT4M group and identified as a biomarker. WPS-2 is not culturable and its specific function has not yet been reported [40]. Zheng et al. [41] reported that WPS-2 was highly positively correlated with 4-hydroxyphenylpyruvic acid, which was related to L-tyrosine metabolism. However, it has not been reported that whether the WPS-2 played a role in regulating lipid metabolism in laying hens. This may provide a new idea to study the relationship between liver metabolism and gut microbiota.
The gut-liver axis theory considered that gut microbiota affected the metabolism of host, and the variation of liver metabolites could reflect the difference of gut microbiota composition [42]. In the present study, supplementation with Lp. plantarum FRT4 altered not only the composition of hepatic metabolites, but also cecal microbial structure. Besides, the results of the Spearman correlation analysis between gut microbiota and liver metabolites showed a greatly different relationship between HELP group compared to the CT group and FRT4M compared to the HELP group. Consequently, Lp. plantarum FRT4 could alleviate the HELP diet-induced FLHS through the “gut-liver” axis, and then heighten the laying performance of laying hens.
Conclusions
Collectively, HELP diet resulted in lower laying performance, FLHS formation, and development in laying hens. Supplementation with Lp. plantarum FRT4 significantly increased laying performance, and attenuated FLHS with the decline of TG, TC, LDL-C, and the increase of HDL-C and VLDL-C in liver. Importantly, Lp. plantarum FRT4 regulated the different metabolites of PE and PC to affect the glycerophospholipid metabolic pathway. Meanwhile, Lp. plantarum FRT4 reshaped gut microbiota structure caused by HELP diet. In summary, Lp. plantarum FRT4 mitigated FLHS in laying hens through regulating liver lipid metabolism, liver function, and gut microbiota. In addition, the results showed that targeting glycerophospholipid metabolic pathway could be a potential and promising therapy method for FLHS in laying hens.
Availability of data and materials
The data analyzed during the current study are available from the corresponding author on reasonable request. The datasets generated for this study can be found in NCBI https://dataview.ncbi.nlm.nih.gov/object/PRJNA1004760?reviewer=c9h5arl098kh2bqob1i1p1gmbd.
Abbreviations
- ACACA:
-
Acetyl-CoA carboxylase alpha
- ADFI:
-
Average daily feed intake
- ADMEC:
-
Average daily metabolic energy consumption
- CEPT1:
-
Choline/ethanolamine phosphotransferase 1
- CHKα:
-
Choline kinase alpha
- ETNK:
-
Ethanolamine kinase
- FABP1:
-
Fatty acid binding protein 1
- FASN:
-
Fatty acid synthase
- FLHS:
-
Fatty liver hemorrhage syndrome
- GC-MS:
-
Gas chromatography-mass spectrometry
- GDE1:
-
Glycerophosphodiester phosphodiesterase 1
- GDPD5:
-
Glycerophosphodiester phosphodiesterase domain containing 5
- HDL-C:
-
High-density lipoprotein cholesterol
- HELP:
-
High-energy low-protein
- LC-MS:
-
Liquid chromatography-mass spectrometry
- LDA:
-
Linear discriminant analysis
- LDL-C:
-
Low-density lipoprotein cholesterol
- LEfSe:
-
Linear discriminant analysis effect size
- Lp. plantarum :
-
Lactiplantibacillus plantarum
- LPCAT2:
-
Lysophosphatidylcholine acyltransferase 2
- LPCAT3:
-
Lysophosphatidylcholine acyltransferase 3
- MAFLD:
-
Metabolic associated fatty liver disease
- ME1:
-
Malic enzyme 1
- MTTP:
-
Microsomal triglyceride transfer protein
- NAFLD:
-
Non-alcoholic fatty liver disease
- OPLS-DA:
-
Orthogonal Partial Least-Squares-Discriminant Analysis
- PBS:
-
Phosphate buffered saline
- PC:
-
Phosphatidylcholine
- PCYT1α:
-
Phosphate cytidylyltransferase 1 alpha
- PCYT2:
-
Phosphate cytidylyltransferase 2
- PE:
-
Phosphatidylethanolamine
- PISD:
-
Phosphatidylserine decarboxylase
- PLA2G6:
-
Phospholipase A2 group VI
- SCD-1:
-
Stearoyl-CoA desaturase-1
- SREBP-1:
-
Sterol regulatory element binding protein 1
- TC:
-
Total cholesterol
- TG:
-
Triglyceride
- VIP:
-
Variable importance of projection
- VLDL-C:
-
Very low-density lipoprotein cholesterol
- VLDLR:
-
Very low-density lipoprotein receptor
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Acknowledgements
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Funding
This research was supported by Science and Technology Innovation Project of the Chinese Academy of Agricultural Sciences (CAAS-ASTIP-2023-IFR-10) and National Key Research and Development Program of China (2022YFD1300601).
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DJL contributed to experimental design, performed experiments and collected samples, analyzed the data, wrote and revised the manuscript; HYC contributed to experimental design, analyzed the data and revised the manuscript; GHL, YSH, KQ and WWL interpreted the results. KM and PLY conceived the projected and provided the funding. All authors discussed the results and approved the final manuscript.
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Generated Statement: The animal study was reviewed and approved by The Institutional Animal Care and Use Committee of the Institute of Feed Research of Chinese Academy of Agricultural Sciences (IFR-CAAS20220729).
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The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.
Supplementary Information
Additional file 1: Table S1.
Compositions and nutrients contents of experimental diets. Table S2. The primer sequences for qRT-PCR.
Additional file 2: Fig. S1.
PCA analysis of evaluating the system stability through 7-fold cross validation (7 cycles of cross validation) for LC-MS. Fig. S2. Boxplot the metabolite strength of QC samples for LC-MS. Fig. S3. The plot of hierarchical clustering of metabolite expression for LC-MS. Supplementary Fig. S4. PCA analysis of evaluating the system stability through 7-fold cross validation (7 cycles of cross validation) for GC-MS. Fig. S5. Boxplot the metabolite strength of QC samples for GC-MS. Fig. S6. The plot of hierarchical clustering of metabolite expression for GC-MS.
Additional file 3.
Deposited data.
Additional file 4.
Deposited data.
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Li, D., Cai, H., Liu, G. et al. Lactiplantibacillus plantarum FRT4 attenuates high-energy low-protein diet-induced fatty liver hemorrhage syndrome in laying hens through regulating gut-liver axis. J Animal Sci Biotechnol 15, 31 (2024). https://doi.org/10.1186/s40104-023-00982-6
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DOI: https://doi.org/10.1186/s40104-023-00982-6