Comprehensive growth performance, immune function, plasma biochemistry, gene expressions and cell death morphology responses to a daily corticosterone injection course in broiler chickens

Gamal M. K. Mehaisen; Mariam G. Eshak; Ahmed M. Elkaiaty; Abdel-Rahman M. M. Atta; Magdi M. Mashaly; Ahmed O. Abass

doi:10.1371/journal.pone.0172684

Abstract

The massive meat production of broiler chickens make them continuously exposed to potential stressors that stimulate releasing of stress-related hormones like corticosterone (CORT) which is responsible for specific pathways in biological mechanisms and physiological activities. Therefore, this research was conducted to evaluate a wide range of responses related to broiler performance, immune function, plasma biochemistry, related gene expressions and cell death morphology during and after a 7-day course of CORT injection. A total number of 200 one-day-old commercial Cobb broiler chicks were used in this study. From 21 to 28 d of age, broilers were randomly assigned to one of 2 groups with 5 replicates of 20 birds each; the first group received a daily intramuscular injection of 5 mg/kg BW corticosterone dissolved in 0.5 ml ethanol:saline solution (CORT group), while the second group received a daily intramuscular injection of 0.5 ml ethanol:saline only (CONT group). Growth performance, including body weight (BW), daily weight gain (DG), feed intake (FI) and feed conversion ratio (FC), were calculated at 0, 3 and 7 d after the start of the CORT injections. At the same times, blood samples were collected in each group for hematological (TWBC’s and H/L ratio), T- and B-lymphocytes proliferation and plasma biochemical assays (total protein, TP; free triiodothyronine hormone, fT₃; aspartate amino transaminase, AST; and alanine amino transaminase, ALT). The liver, thymus, bursa of Fabricius and spleen were dissected and weighed, and the mRNA expression of insulin-like growth factor 1 gene (IGF-1) in liver and cell-death-program gene (caspase-9) in bursa were analyzed for each group and time; while the apoptotic/necrotic cells were morphologically detected in the spleen. From 28 to 35 d of age, broilers were kept for recovery period without CORT injection and the same sampling and parameters were repeated at the end (at 14 d after initiation of the CORT injection). In general, all parameters of broiler performance were negatively affected by the CORT injection. In addition, CORT treatment decreased the plasma concentration of fT₃ and the mRNA expression of hepatic IGF-1. A significant increase in liver weight accompanied by an increase in plasma TP, AST and ALT was observed with CORT treatment, indicating an incidence of liver malfunction by CORT. Moreover, the relative weights of thymus, bursa and spleen decreased by the CORT treatment with low counts of TWBC’s and low stimulation of T & B cells while the H/L ratio increased; indicating immunosuppressive effect for CORT treatment. Furthermore, high expression of caspase-9 gene occurred in the bursa of CORT-treated chickens, however, it was associated with a high necrotic vs. low apoptotic cell death pathway in the spleen. Seven days after termination of the CORT treatment in broilers, most of these aspects remained negatively affected by CORT and did not recover to its normal status. The current study provides a comprehensive view of different physiological modulations in broiler chickens by CORT treatment and may set the potential means to mount a successful defense against stress in broilers and other animals as well.

Citation: Mehaisen GMK, Eshak MG, Elkaiaty AM, Atta A-RMM, Mashaly MM, Abass AO (2017) Comprehensive growth performance, immune function, plasma biochemistry, gene expressions and cell death morphology responses to a daily corticosterone injection course in broiler chickens. PLoS ONE 12(2): e0172684. https://doi.org/10.1371/journal.pone.0172684

Editor: Ruud van den Bos, Radboud Universiteit, NETHERLANDS

Received: September 5, 2016; Accepted: February 8, 2017; Published: February 24, 2017

Copyright: © 2017 Mehaisen et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Data Availability: All relevant data are within the paper and its Supporting Information files.

Funding: This work was supported by Project of Rapid Climate Change in Poultry Cellular and Molecular Physiology (RCC-PCMP), funded from General Scientific Research Department at Cairo University (GSRD-CU); http://gsrd.cu.edu.eg/. AOA was the principal investigator of the project and the fund was awarded to him during the management of the project. The funders have approved the study design, data collection and analysis, decision to publish, and preparation of the manuscript.

Competing interests: The authors have declared that no competing interests exist.

Introduction

Broiler production forms an essential component to meet the increasing demand of animal protein in either the developed or developing countries. The modern large-scale broiler production provokes a new stressful situation around broilers due to thermal conditions, high-stocking density, immunological challenge, handling, transportation and feed quality. All kinds of such stressors can elicit the biological response of broiler chickens to re-establish homeostatic conditions [1], and directly or indirectly activate the hypothalamic-pituitary-adrenal (HPA) axis [2]. The activated HPA axis results in the release of adrenocorticotropic hormone (ACTH), which stimulates the adrenals to secret and release glucocorticoids, including corticosterone (CORT), into blood circulation [1]. In chickens, the high levels of CORT in blood circulation is associated with a marked regression in the growth performance, feed efficiency and fuel metabolism [3–8]. The weight and function of the lymphoid organs including thymus, bursa of Fabricius and spleen also decreased by the CORT treatment in birds [3,4,9]. In contrast, the effect of CORT on the liver is anabolic and the fat pads are grossly enlarged in liver of broilers treated with CORT [6].

It was found that exposure to stressors elevates the blood concentration of heterophils (the avian counterpart to the mammalian neutrophils) and depresses the blood concentration of lymphocytes [10]. As an important immune parameter, the ratio of circulating heterophils to lymphocytes (H/L ratio) is one of the most recognizable symptoms of stress in chickens [11–14]. The administration of exogenous corticosterone resulted in an increase in the plasma corticosterone concentration and H/L ratio with a global decrease in the circulating leukocyte number in young chickens [9,13,14]. On the other hand, lymphocytes in birds are specifically separated into T and B cells during the development of the thymus and bursa of Fabricius glands, respectively. Such cells carry receptors for stress hormones produced by the adrenal and pituitary glands, so it could be used as another index to stress [9]. Particularly, high concentrations of glucocorticoids have immunosuppressive effects by inhibiting, for example, antibody production from B cells, T cell proliferation and phagocytosis [15,16]. In addition, some blood physiological and biochemical changes may occur in the stress- and/or CORT-exposed broiler chickens and may be responsible for their low growth rates [17]. In a recent study, the CORT treatment enhanced the total plasma protein levels in broiler chickens [3]. It was previously found that corticosterone increased protein degradation as indicated by the reduction in skeletal RNA/protein synthesis [18] and the rising in the muscle proteolysis [19]. The increase in aspartate and alanine amino transaminase (AST and ALT) enzymes levels usually appear in the blood when there is tissue impairment or liver malfunctioning caused by excessive stress [20]. Two other components are mediated by each other and strongly correlated with the growth performance in young chickens; triiodothyronine hormone (T₃) and insulin-like growth factor 1 (IGF-1) [21,22]. It has been reported that the decreased performance in stressed broilers is mainly caused by the reduction in T₃ and thyroxin (T₄) levels [23]. Many studies have also reported the negative effects of environmental and nutritional stress on the expression of IGF-1 gene and its circulating levels in different avian species during embryonic and post-hatch growth and development [24–26]. It was clearly reported that glucocorticoid administration in chickens has a suppressive effect on the plasma T₃ levels [27,28] and the circulating concentrations of hepatic IGF-1 [29].

Rearing stress conditions and physical agents can also activate apoptosis; a mode of cell death that occurs under normal physiological conditions and is triggered by one or more of intracellular factors [30–32]. The apoptotic morphology, including plasma membrane blebbing, cytoplasm vacuolization, chromatin condensation and DNA degradation, is essentially the result of the proteolytic action of caspases upon specific cellular substrates [33,34]. Caspase cascades are responsible for both initiating and amplifying early apoptotic signals (e.g. caspase-1, -2, -8, -9, -10) as well as executing apoptosis (e.g. caspase-3, -6, -9) [35,36]. It has been well documented that the chronic stress may influence the expression of caspase genes in broiler chickens and other vertebrates [37]. In some cases, stressful stimuli can initiate the necrotic pathway form of cell death programs, a process that has distinct morphological features; it is accompanied by a rapid collapse of plasma membrane, and it is independent of expression of new genes [38]. In one of few studies that differentiated between apoptosis and necrosis pathways in rat’s Leydig cells [39] and postnatal neuron cells [40] cultured with CORT, a higher necrotic than apoptic cells were detected in groups with higher CORT concentration.

Most researchers have focused on the effect of stressors itself and/or stress-related glucocorticoids administration on specific pathways related to stress in birds. However, the administration of corticosterone to broiler chickens simply serves as a practical, controlled and flexible tool in the research of their adaptation to stress. In the present study, the research was to set forth an overall view of modulation induced by corticosterone exposure as simulation for stress condition in broiler chickens. Hence, this work aimed to assess comprehensive responses related to broiler performance, immune function, plasma biochemistry, gene expression and cell death morphology throughout a 7-day course of daily CORT injections. In addition, all measurements were repeated at 7 d after termination of the 7-day course of the CORT treatment to estimate the capability of broiler chickens for recovery to normal physiological status after overriding the stress.

Materials and methods

Birds, treatment and ethical statement

The current study was conducted in the Poultry Services Center at the Faculty of Agriculture, Cairo University. A total of 200 one-day-old commercial broiler chicks (Cobb500^™) were obtained from a commercial hatchery and housed on a deep litter floor brooder. Ambient temperature on d 1 was set at 33°C and then was gradually reduced until 24°C by d 21. The light regimen was 23L:1D. Chicks were fed commercial broiler diets according to the recommendations of the National Research Council (NRC, 1994). Water and feed were supplied ad libitum during the study.

From 21 to 28 d of age, birds were randomly assigned to one of 2 groups with 5 replicates of 20 birds per replicate. Broilers of the first group received a daily intramuscular injection (at 10:00 AM) of corticosterone (cat# C2505, Sigma, St. Louis, MO 63103, USA) adjusted based on the average body weight of birds at dose of 5 mg/kg; dissolved in 0.5 ml ethanol:saline (1:1, vol/vol) solution (CORT group). The second group received a daily intramuscular injection of 0.5 ml ethanol:saline (1:1, vol/vol) solution and served as positive control (CONT group). Growth performance of broilers was recorded during the experimental period as detailed later. At 21 d of age, before CORT treatment (0 d of injection), blood samples were collected from 5 birds per treatment group (one per replicate) via the wing vein for determination of hematological assay and lymphocyte proliferation. Another 5 birds from each group were sampled and plasma was obtained for biochemical analyses. In addition, 5 birds from each treatment group were sacrificed, by cervical dislocation, and the liver, thymus, bursa of Fabricius and spleen were harvested, weighed and kept on ice until the following analyses. The mRNA expression of insulin-like growth factor 1 gene (IGF-1) was analyzed in liver tissues, while the expression of cell-death-program gene (caspase-9) was analyzed in bursa tissues. Finally, spleen tissues were subjected to a morphological detection of apoptotic/necrotic cells under fluorescent microscope. The same sampling procedures and parameters were repeated during the treatment at 3 and 7 d after the start of CORT injection (at 24 and 28 d of age). After that, birds were kept for recovery period without CORT injection and the same parameters were measured 7 d later (at 14 d after the start of CORT injection = 35 d of age). Each bird in the group was sampled only once and then was removed from the experiment.

Birds were monitored closely, twice a day, to detect any signs of stress (breathing difficulty, watery discharge of the peak, decreased appetite, ruffled feathers, or droopy looking) throughout the experimental period. Accordingly, when one or more of these signs appeared, cervical dislocation was used to end the life of these birds. This process was accomplished to minimize suffering of birds and to allow humane endpoints. All experimental protocols were approved by Cairo University Ethics Committee for the Care and Use of Experimental Animals in Education and Scientific Research (CU-IACUC).

Growth performance and organs weight

Individual body weights (BW) were recorded at 0, 3 and 7 d after the start of CORT injection course (21, 24 and 28 d of age), and at 7 d after cessation of the 7-day course of the CORT treatment (14 d after initiation of CORT injection; 35 d of age) for each group. The average daily gain (DG), feed intake (FI) and feed conversion ratio (feed/gain; FC) for each replication in the group were obtained at periods 0–3 d and 3–7 d of the CORT treatment course and at 7–14 d of the recovery period (21–24, 24–28 and 28–35 d of age, respectively). After cervical dislocation of broilers, the weights of liver, thymus, bursa of Fabricius and spleen were also calculated relatively to the body weights in each group at 0, 3 and 7 d after initiation of the CORT injection, and after 1 week of recovery period.

Hematological assay

Whole blood samples of approximately 3 ml were collected using heparinized syringes and transferred immediately to heparinized tubes. The total white blood cells (TWBC’s) were manually determined by mixing 490 μl of brilliant cresyl blue dye with 10 μl of whole blood sample, and then the total leukocytes were counted under a microscope at a magnification of 200x using a hemocytometer slide [41]. The H/L ratio was determined according to Zhang et al. [42] with modification. In brief, a droplet of blood (5 μl) was used to make smears on a clean glass slide (2 slides per each sample). The smears were stained with Hema-3 (cat# 22–122911, Fisher scientific, USA) after drying and fixing with methyl alcohol. On each slide, heterophils and lymphocytes were counted under a microscope at magnification of 1000x with oil immersion until a total of 100 cells were reached. After averaging the cells of 2 slides, the ratios of heterophils to lymphocytes were calculated.

Lymphocyte proliferation

The T and B lymphocyte proliferation assays were done according to methods described by Zhang and Guo [43] with some modifications. The heparinized blood samples were added to separation medium Histopaque-1077 (cat# 10771, Sigma, USA), and were then centrifuged at 1030 xg for 20 min at 4°C. Peripheral blood mononuclear cells (PBMCs) were isolated and washed twice with RPMI-1640 (Invitrogen Corp., Grand Island, NY, USA) incomplete culture medium, and then re-suspended in 2 ml of RPMI-1640 complete culture medium. The viable lymphocytes were detected using Trypan Blue dye and plated in triplicate wells (96-well plate) at 1×10⁶ cells per well. Then, 50 μl of either Concanavalin-A (Con-A, 45 μg/ml, cat# C5275, Sigma, USA) or Lipopolysaccharide (LPS, 10 μg/ml, cat# L4391, Sigma, USA) was added to selected wells to induce the proliferation of T lymphocyte and B lymphocyte, respectively; while control wells received 50 μl of RPMI-1640 medium. Cells were then incubated for 48 h at 42°C with 5% CO₂. After incubation, 15 μl of 3-[4,5-dimethylthiazol]-2,5-diphenyltetrazolium bromide (MTT, 5 mg/ml, cat# M2128, Sigma, USA) was added to each well and the cells were incubated for another 4 h. Subsequently, 100 μl of 10% sodium dodecyl sulfate dissolved in 0.04 M HCl solution was added to each well to lyse the cells and solubilize the MTT crystals. Finally, the absorbance at 570 nm was recorded using an automated ELISA microplate reader (ChroMate Microplate Reader-4300, Awareness Technology Inc., Palm City, FL, USA). Stimulating index (SI) for T and B cells was calculated as follows: SI = OD570_{(stimulated cells)} / OD570_{(unstimulated cells)}.

Plasma biochemical analyses

Blood samples of approximately 3 ml were withdrawn from the brachial wing vein in heparinized tubes and centrifuged at 1030 xg for 10 min at 4°C. The plasma was separated and stored at -20°C until analyzed. The plasma levels of total protein (TP), AST and ALT were analyzed by automatic scanning spectrophotometer (CE1010, Cecil Instruments Limited, Cambridge, United Kingdom) using colorimetric assay kits (TP-2020 for TP, and AT-1034(45) for both AST and ALT; Biodiagnostic Inc, Dokki-Giza, Egypt). The fT₃ was measured by the automated ELISA microplate reader using enzyme immunoassay ELISA kits (EIA-10301, Chemux BioScience Inc, San Francisco, CA, USA). The standard curves and calculations, as well as accuracy and sensitivity of the assay were performed following the kits protocol for each assay.

Quantitative real-time PCR analysis

Total RNA was extracted from liver and bursa tissues using the standard TRIzol Reagent extraction method. RNA was dissolved in diethylpyrocarbonate (DEPC)-treated water by passing solution a few times through a pipette tip. Total RNA was treated with 1 U of RQ1 RNase-free DNase (Invitrogen, Germany) to digest DNA residues, then re-suspended in DEPC-treated water. The purity of total RNA was assessed spectrophotometrically at 260/280 nm, and the integrity of extracted RNA was determined by using 1.5% agarose gel electrophoresis. Then total RNA was reverse-transcribed into cDNA by using RevertAidTM First Strand cDNA Synthesis Kit (MBI Fermentas, Germany) according to the manufacturer's directions. Briefly, an amount of total RNA (5μg) was used with a reaction mixture, termed as master mix (MM). The MM consisted of 50 mM MgCl₂ and 5x reverse transcription (RT) buffer (50 mM KCl, 10 mM Tris-HCl, pH 8.3, 10 mM dNTPs, 50 μM oligo-dT primers, 20 U ribonuclease inhibitor and 50 U M-MuLV reverse transcriptase). The RT reaction was carried out at 25°C for 10 min, followed by 1 h at 42°C, and the reaction was stopped by heating for 5 min at 99°C. Afterwards, the reaction tubes containing cDNA were stored at -20°C until being used for quantitative real time-polymerase chain reaction (qRT-PCR).

PCR reactions were set up in 25 μl reaction mixtures containing 12.5 μl of 1× SYBR Premix Ex TaqTM (TaKaRa, Biotech. Co. Ltd., Germany), 0.5 μl sense primers (0.2 μM), 0.5 μl antisense primer (0.2 μM), 6.5 μl distilled water, and 5 μl of cDNA template. The reaction program was allocated to 3 steps of thermal cycling parameters. The first step was set to 95.0°C for 3 min. The second step consisted of 40 cycles in which each cycle was divided to 3 steps: (a) at 95°C for 15 sec, (b) at 55°C for 30 sec, and (c) at 72°C for 30 sec. The last step consisted of 71 cycles which started at 60°C and then increased by 0.5°C every 10 sec up to 95°C. At the end of each qRT-PCR, a melting curve analysis was performed at 95°C to check the quality of the used primers. Each experiment included a distilled water control.

The qRT-PCR of IGF-1and caspase-9 genes were normalized to the main expression of ß-actin and transformed using the comparative cycle threshold (CT) method to quantify expression levels as previously described by Ellestad et al. [44]. Sequence-specific primers (Table 1) for the real-time PCR were designed using the Primer blast web interface (http://www.ncbi.nlm.nih.gov/tools/primer-blast/index.cgi).

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Table 1. Details of primers used for real-time PCR quantitative analysis.

https://doi.org/10.1371/journal.pone.0172684.t001

Morphological detection of cell death categories

Apoptotic changes in the spleen samples were determined morphologically by fluorescent microscope after labeling with acridine orange and ethidium bromide (AO/EB) dyes [45]. Briefly, spleen tissues were washed in PBS (Sigma), chopped finely and centrifuged at 9220 xg for 5 min. The pellet obtained was suspended in trypsin-EDTA solution (0.25%, 53 mM; cat#T4049, Sigma) in PBS for 1 hr at 37°C and smeared on clean glass slides. Finally, spleen cells smears were air-dried and fixed in a solution of methanol/acetic acid (3:1). The slides were stained with 25 μl of AO/EB dye mixture (4μg/ml AO (cat#A9231, Sigma) and 4μg/ml EB (cat#E7637, Sigma) in PBS, pH 7.4). The slides were examined under fluorescence microscope using B2A filter (450–490 nm excitation, 515 nm emission, at 100x magnification, Nikon Tokyo, Japan), and connected to a COHU 4910 video camera (Cohu, Inc., San Diego, CA, USA) and a personal computer—based image analysis system (Lucia-Comet v.4.51). The cells were divided into three categories as follows: viable cells (green colored), apoptotic cells (yellow colored), and necrotic cells (red colored). A total of 100 cells were counted, and the % of total apoptotic and necrotic cells were examined for each experimental group (CONT 0, 3, 7 and 14; CORT 0, 3, 7 and 14). Detailed information on the cell death categories and its rates in each experimental group has been demonstrated in (S1 Table). Also, visual examples for apoptotic categories in each experimental group are represented in (S1 Fig).

Statistical analysis

All statistical analyses were performed using IBM SPSS 22.0 software package (IBMcorp., NY, USA, 2013). A general linear model (GLM) procedure was performed to analyze all data including CORT treatment (CORT and CONT groups), time (0, 3, 7 and 14 d of the course of the treatment) and their interactions as fixed effects. When interactions between main effects were significant, a multiple pairwise comparison among multiple means within CORT treatment group were made by Duncan’s test and the differences between CONT and CORT groups within each time was also performed using independent-samples T-test. Values were considered statistically different at P <0.05 and results were expressed as least square means ± standard error.

Results

Growth performance

The effect of the 7 d course of daily corticosterone injections on the BW, DG, FI and FC of broiler chickens during the treatment course and after the post-treatment recovery period is shown in Fig 1. The corticosterone injection, significantly, decreased the BW of broiler chickens at 3 and 7 d of the course of the treatment when compared with the control group (516 g vs. 624 g and 584 g vs. 792 g BW for CORT vs. CONT group at 3 and 7 d of the treatment course, respectively), and it was still low after recovery (828 g vs. 1303 g BW of CORT vs. CONT chickens at 14 d of the treatment course, Fig 1-A). A significantly (P<0.05) lower DG was observed for CORT-treated chickens compared to the CONT group during the first 3 days from the start of the CORT injection (52 g vs. 136 g DG during 21–24 d of age). This was also observed during the recovery period (244 g vs. 512 g DG during 28–35 d of age) (Fig 1-B). The FI estimated for CORT-treated chickens was significantly lower than the CONT during 3–7 d from the start of the corticosterone treatment (47.8 vs. 70.2 g FI/chicken/day during 24–28 d of age) and also during the recovery period (47.3 vs. 95.7 g FI/chicken/day during 28–35 d of age) (Fig 1-C). In contrast, the FC was significantly higher in chickens of CORT group than in those of CONT group only within 3 days from the start of the corticosterone injection (3.9 vs. 1.5 FC during 21–24 d of age, Fig 1-D).

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Fig 1. Effect of a 7 d course of daily saline (CONT) or corticosterone at dose of 5 mg/kg BW (CORT) injections on the body weight (A), daily gain (B), feed intake (C) and feed conversion (D) of broiler chickens during the treatment course (0, 3 and 7 d after the start of injection; 21, 24 and 28 d of age) and one week after cessation of the treatment (14 d after the start of injection; 35 d of age).

Bars express the mean ± SEM (n = 36). Bars of CONT and CORT groups, within each time of the treatment course, with different letters (a, b) are significantly different at P<0.05.

https://doi.org/10.1371/journal.pone.0172684.g001

Organs weight

The effect of the 7 d course of daily corticosterone injection on the organs relative weights of broilers during the treatment course and after the post-treatment recovery period is shown in Fig 2. The relative liver weight of broilers in CORT group (4.17%) was significantly (P<0.05) higher than that in CONT group (3.01%) at both 3 and 7 d after the start of treatment (Fig 2-A). As shown in Fig 2-B, the relative weight of thymus glands in treated chickens was significantly (P<0.05) lower than that in the control chickens during the 7-d course of treatment (0.32% vs. 0.54% and 0.21% vs. 0.49% for CORT vs. CONT at 3 and 7 d after the start of injection, respectively). The same trend was also observed at the end of the recovery period (0.35% for CORT vs. 0.47% for CONT at 14 d after the start of injection). The relative weight of bursa was lower in CORT group than in CONT group (Fig 2-C); however, this decrease was significant (P<0.05) only at 7 d after the start of injection (0.08% vs. 0.18% for CORT vs. CONT group, respectively). A significantly lower relative spleen weight was observed in treated chickens (0.07%) compared to the controls (0.10%) at 7 d after the start of the CORT injection (Fig 2-D).

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Fig 2. Effect of a 7 d course of daily saline (CONT) or corticosterone at dose of 5 mg/kg BW (CORT) injections on the relative weights of liver (A), thymus (B), bursa (C) and spleen (D) to the body weights of broiler chickens during the treatment course (0, 3 and 7 d after the start of injection; 21, 24 and 28 d of age) and one week after cessation of the treatment (14 d after the start of injection; 35 d of age).

Bars express the mean ± SEM (n = 5). Bars of CONT and CORT groups, within each time of the treatment course, with different letters (a, b) are significantly different at P<0.05.

https://doi.org/10.1371/journal.pone.0172684.g002