Abstract

Simple Summary

   Carcass quality traits, such as lean depth and loin depth, are of
   extreme economic importance for the swine industry. This study aimed to
   identify the gene expression pattern related to carcass quality in
   crossbred pigs ((Landrace × Yorkshire) × Duroc). In total, 20 crossbred
   pigs were used in this study and divided into two groups based on the
   loin muscle quality grade. Total RNA samples extracted from the loin
   muscles of both groups were submitted for RNA-seq. Differentially
   expressed gene (DEG) analysis of the two groups revealed 282
   up-regulated and 189 down-regulated genes (p ≤ 0.01), linked to tissue
   development, striated muscle tissue development, tissue morphogenesis,
   and lipid metabolic process gene ontology (GO) terms. Kyoto
   Encyclopedia of Genes and Genomes (KEGG) enrichment analysis
   highlighted genes related to the calcium signaling pathway, apelin
   signaling pathway, and the mammalian target of rapamycin (mTOR)
   signaling pathway. We constructed an expressed gene catalog, which may
   serve as a resource for genomic studies focused on uncovering the
   molecular mechanisms underlying carcass quality in crossbred pigs.

Abstract

   Carcass quality traits, such as lean depth and loin depth, are of
   extreme economic importance for the swine industry. This study aimed to
   identify the gene expression pattern related to carcass quality in
   crossbred pigs ((Landrace × Yorkshire) × Duroc). In total, 20 crossbred
   pigs were used in this study and they were divided into two groups
   (class I grade, n = 10; class II grade, n = 10) based on the carcass
   grades. Total RNA samples extracted from the loin muscles of both
   groups were submitted for RNA-seq. The quality assessment of the
   sequencing reads resulted in 25,458 unigenes and found 12,795 candidate
   coding unigenes with homology to other species after annotation.
   Differentially expressed gene (DEG) analysis of the two groups revealed
   282 up-regulated and 189 down-regulated genes (p ≤ 0.01), linked to
   tissue development, striated muscle tissue development, tissue
   morphogenesis, and lipid metabolic process gene ontology (GO) terms.
   Kyoto Encyclopedia of Genes and Genomes (KEGG) enrichment analysis
   highlighted genes related to the calcium signaling pathway,
   melanogenesis, the sphingolipid signaling pathway, the apelin signaling
   pathway, and the mTOR signaling pathway. We constructed an expressed
   gene profile, which may serve as a resource for genomic studies focused
   on uncovering the molecular mechanisms underlying carcass quality in
   crossbred pigs.

   Keywords: differentially expressed genes, meat quality, RNA sequencing,
   Z-disc, apelin signaling pathway

1. Introduction

   Pork is the most consumed protein source (12.3 kg/capita/year)
   worldwide [[32]1]. Generally, meat customers are influenced more by
   product appearance, such as meat color and marbling, than by any other
   factor [[33]2,[34]3]. In addition, Korean consumers have a unique
   consumption pattern and a strong preference for high-fat cuts such as
   belly, Boston butt, and rib [[35]3].

   Intramuscular fat (IMF) is consistent with pork marbling, which is an
   important indicator of meat quality [[36]4]. Calcium ions are also
   important for muscle contraction and relaxation, as well as porcine
   stress syndrome [[37]5,[38]6]. These meat characteristics have been
   used in genetic improvement programs in commercial pig lines [[39]7].
   However, they have dramatically altered many porcine muscle
   characteristics, such as IMF, the loin area, and backfat thickness, and
   have had negative impacts on palatability measures, such as juiciness,
   flavor, tenderness, and overall acceptability [[40]7,[41]8].

   Traditionally, quantitative trait loci have been identified to
   accelerate the genetic control of economically important traits by
   means of various candidate genes, such as the ryanodine receptor
   (RYR1), protein kinase AMP-activated non-catalytic subunit gamma 3
   (PRKAG3), fatty acid-binding protein 3 (HFABP), and melanocortin 4
   receptor (MC4R) [[42]9,[43]10]. Recently, studies have investigated the
   transcript abundance of a group of candidate genes involved in
   metabolism, nutrient metabolites, and muscle structural genes
   [[44]4,[45]7,[46]8,[47]11,[48]12,[49]13,[50]14]. These studies
   identified key regulatory genes that are significantly associated with
   pork quality and muscle characteristics in purebred pigs. To our
   knowledge, these studies did not perform transcriptome analysis to
   detect changes in gene expression associated with carcass grade in
   crossbred pigs (Landrace × Yorkshire × Duroc). Our study used RNA
   sequencing methods to associate differentially expressed genes (DEGs)
   with loin muscle carcass quality in crossbred pigs.

2. Materials and Methods

2.1. Animals and Sample Collection

   Pork carcasses are graded in terms of loin muscle quality and
   conformation based on the Korea Institute for Animal Products Quality
   Evaluation (KAPE) and scored as first plus (1 ^+), first (1), or second
   (2), based on marbling, lean color, backfat thickness, and body weight
   [[51]15]. In Korea, all domestically produced pork is graded, which
   enables the standardized pork distribution system across the country.
   Pork is indicated as 1 ^+, 1, or 2 (primary decision and secondary
   decision), and the quality of pork belly, which has a high added value,
   is considered to be the highest. The 1 ^+ grade pork showed a carcass
   weight from 83 kg to 90 kg and a backfat thickness from 17 mm to 25 mm.
   Additionally, pork belly was more than 10.72 kg and the fat rate was
   from 22% to 42%. Twenty crossbred pigs were determined to be grades 1
   ^+ (class I) and 2 (class II) after being slaughtered according to KAPE
   standards. The carcass quality tenderloin muscle characteristics are
   listed in [52]Table 1 and [53]Supplementary Table S1. For
   transcriptomic analysis, 20 samples of loin muscles were immediately
   frozen in liquid nitrogen and stored at −80 °C until RNA extraction.

Table 1.

   Basic characteristics of the study subjects by grade.
   Item 1 ^+ 2 Total Statistical Test
   Carcass weight (kg) 89.2 ± 2.35 94.00 ± 4.22 91.6 ± 4.13 t = −3.16 **
   Backfat thickness (mm) 20.4 ± 2.17 27.2 ± 4.59 23.8 ± 4.94 t = −4.24
   ***
   pH 5.66 ± 0.06 5.60 ± 0.04 5.61 ± 0.05 t = 0.86 ^NS
   CIE color L * 55.06 ± 2.35 59.79 ± 1.77 57.42 ± 3.16 t = −5.09 ***
   a * 9.24 ± 1.09 8.15 ± 0.53 8.69 ± 1.00 t = 2.85 **
   b * 3.00 ± 0.66 3.85 ± 0.43 3.42 ± 0.70 t = −3.42 **
   [54]Open in a new tab

   Data are means ± SD. ^NS: not significant, **: p < 0.01, ***: p <
   0.001, CIE: International Commission on Illumination, L *: indicates
   lightness, a *: the red/green coordinate, b *: the yellow/blue
   coordinate.

2.2. Library Preparation and Data Generation

   Total RNA was isolated from the indicated tissues using the Qiagen
   RNeasy^® Mini kit (Qiagen, Valencia, CA, USA), and purification was
   performed according to the manufacturer’s instructions. The RNA
   concentration was determined using a NanoDrop ND-1000 spectrometer
   (Nanodrop technologies Inc., Wilmington, NC, USA), and the RNA
   integrity number was evaluated on a 2100 Bioanalyzer (Agilent
   Technologies, Santa Clara, CA, USA) using the RNA 6000 Nano Kit
   (Agilent Technologies). The mRNA libraries were prepared using the
   TruSeq Stranded mRNA Sample Preparation Kit (RS-122-2101) (Illumina,
   San Diego, CA, USA). Oligo (dT)’s attached to magnetic beads were used
   to purify poly-A-containing mRNA from 1 μg of total RNA. Next, the
   purified mRNA was disrupted into short fragments, and first-strand
   cDNAs were synthesized using SuperScript II reverse transcriptase
   (Invitrogen, Carlsbad, CA, USA) and random hexamers. The cDNA with
   adapters ligated to both ends were enriched by PCR. The cDNA library
   size and quality were evaluated electrophoretically using the Agilent
   DNA 1000 Kit (part # 5067-1504) (Agilent Technologies, Santa Clara, CA,
   USA) on a 2100 BioAnalyzer. Subsequently, the libraries were sequenced
   on an Illumina HiSeq 2500 (Illumina, San Diego, CA, USA). Image
   analysis was performed using the HiSeq control software version 2.2.58
   (Illumina, San Diego, CA, USA). Raw data were processed and base
   calling was performed using the standard Illumina pipeline (CASAVA
   version 1.8.2 and RTA version 1.18.64, Illumina, San Diego, CA, USA).

2.3. Data Analysis

   Total sequenced reads were subjected to preprocessing as follows:
   adapter trimming was performed using cut adapt with the default
   parameters, and quality trimming (Q30) was performed using FastQC
   (Babraham Institute, Cambridge, UK) with the default parameters.
   Processed reads were mapped to the pig reference genome (Sus
   scrofa—Ensembl 89) using TopHat (ver. 2.0.9) and Cufflinks (ver. 2.1.1)
   with the default parameters [[55]16]. Fragments per kilobase of exon
   model per million reads mapped (FPKM) values were normalized and
   quantitated using the R package Tag Count Comparison to determine
   statistical significance (e.g., p and Q values) and differential
   expression (e.g., fold changes) [[56]17]. The number of DEGs was
   analyzed with the number of reads estimated by the Kalisto program
   [[57]18]. Reads were subjected to functional annotations by a sequence
   homology search against biological databases such as Gene Ontology
   (GO), and the Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway
   [[58]19]. Output files of differentially expressed (DE) genes (False
   Discovery Rate (FDR)  <  0.05) were used in Gene Set Enrichment
   Analysis (GSEA) to evaluate the relationship between gene expression
   patterns significantly associated with carcass quality (Kobas 3:
   [59]http://kobas.cbi.pku.edu.cn/kobas3/). In this study, we focused
   only on the quantification of known mRNA sequences. Therefore, unknown
   genes or isoforms were not considered in this study.

3. Results

3.1. Pig Loin Muscle Transcriptome Profiling

   In this study, twenty cDNA libraries from class I and class II groups
   were constructed using Illumina sequencing. Principal Component
   Analysis (PCA) showed that the samples were clustered according to
   class I and class II ([60]Figure 1). A total of 25,458 clean mapped
   transcripts were considered for further analysis, and a total of 471
   genes were found to be significantly differentially expressed (log[2]FC
   > 2 and q < 0.01), of which 282 and 189 genes were either up- or
   down-regulated between class I and class II, respectively (see
   [61]Supplementary Table S2).

Figure 1.

   [62]Figure 1
   [63]Open in a new tab

   Plot of principal component analysis. Relative abundance log folds
   accounting for the total raw count are shown. Red point: class I (first
   plus grade), blue point: class II (second grade).

3.2. Putative Candidate Genes Involved in Loin Muscle Carcass Quality

   To identify the putative biological function of the DEGs, GO function
   and KEGG pathway enrichment analysis were performed for the libraries
   from class I and class II by assigning GO terms associated with the
   unigenes. Significantly, 2757 gene sets were enriched (FDR < 25%) in
   class I and class II. DEGs in class II showed that the GO terms of
   metal ion binding (GO:0046872), cation binding (GO:0043169), immune
   response cell activation (GO:0006629), cell surface (GO:0009986),
   calcium ion transport (GO:0006816), tissue development (GO:0009888),
   striated muscle tissue development (GO:0014706), tissue morphogenesis
   (GO:0048729), and the cellular lipid metabolic process (GO:0044255)
   were enriched (See [64]Supplementary Table S3; [65]Figure 2).

Figure 2.

   [66]Figure 2
   [67]Open in a new tab

   Heatmap gene cluster classification for the class I and class II muscle
   samples. C1 (white) and C2 (black) refers to the cluster 1 and cluster
   2, respectively. Using the expression for each gene (in rows) and
   sample (in columns), the heatmap was generated by the R package
   “plots”.

   Based on previous studies, we filtered out some genes in order to gain
   a better understanding of the 116 candidate genes and their putative
   roles in loin muscles ([68]Table 2). Among the GO categories, metal ion
   transport was enriched, including calcium voltage-gated channel subunit
   alpha 1 S (CACNA1S), calcium/calmodulin-dependent protein kinase II
   gamma (CAMK2G), potassium voltage-gated channel subfamily D member 2
   (KCND2), potassium voltage-gated channel subfamily Q member 4 (KCNQ4),
   presenilin 1 (PSEN1), sodium voltage-gated channel alpha subunit 4
   (SCN4A), and solute carrier family 9 member A4 (SLC9A4). In terms of
   molecular function, the following genes were predicted to be related to
   ATP binding: alpha-protein kinase 3 (ALPK3), apoptotic
   protease-activating factor 1 (APAF1), ATPase H+ transporting accessory
   protein 1 (ATP6AP1), CAMK2G, dual-specificity
   tyrosine-phosphorylation-regulated kinase 1B (DYRK1B), eukaryotic
   initiation factor 4A-II (EIF4A2), inositol hexakisphosphate kinase 3
   (IP6K3), nucleotide-binding protein 1 (NUBP1), protein kinase domain
   containing, cytoplasmic (PKDCC), proteasome 26S subunit, ATPase 6
   (PSMC6), RecQ-like helicase 4 (RECQL4), structural maintenance of
   chromosomes 6 (SMC6), striated muscle-enriched protein kinase (SPEG),
   ubiquitin-conjugating enzyme E2 D3 (UBE2D3), and unc-51-like autophagy
   activating kinase 1 (ULK1). In addition, genes related to anion binding
   with ALPK3, APAF1, ATP6AP1, CAMK2G, DYRK1B, early endosome antigen 1
   (EEA1), EIF4A2, fatty acid-binding protein 4 (FABP4), GUF1 homolog,
   GTPase (GUF1), IP6K3, NLR family pyrin domain containing 1 (NLRP1),
   NUBP1, PKDCC, PSMC6, RECQL4, SMC6, sorting nexin 13 (SNX13), SPEG,
   UBE2D3, ULK1, and UDP-glucuronate decarboxylase 1 (UXS1) genes were
   found. Significantly, integrin subunit beta 1 binding protein 2
   (ITGB1BP2), myotilin (MYOT), myozenin 3 (MYOZ3), protein phosphatase 2
   regulatory subunit B’alpha (PPP2R5A), and PSEN1 were classified as
   Z-disk-related in the cellular component category (false discovery rate
   = 0.0153). Furthermore, the cation channel complex was associated with
   CACNA1S, KCNQ4, and SCN4A in the cellular component category.

Table 2.

   Functional gene ontology (GO) categories enriched in the crossbred
   pigs.
   Category Term ID Term Description Observed Gene Count Background Gene
   Count FDR Matching Genes *
   Biological Process GO:0008104 Protein localization 24 1966 0.0471 ABRA,
   ADORA1, AP2A1, ATP6AP1, CAMK2G, DVL2, GRIP1, ITGAL, LIN7A, MSX1, NRXN1,
   NUBP1, PICK1, PITRM1, PKDCC, PSEN1, RAB3IP, RPS6, RRAGA, SNX13, UBE2D3,
   ULK1, VAMP8, VPS18
   GO:0030001 Metal ion transport 7 664 0.0034 CACNA1S, CAMK2G, KCND2,
   KCNQ4, PSEN1, SCN4A, SLC9A4
   GO:0016192 Vesicle-mediated transport 9 1699 0.0137 ADORA1, ADORA2A,
   ALB, EEA1, HSP90AB1, LIN7A, MAPK3, PICK1, VAMP8
   Molecular Function GO:0005524 ATP binding 22 1462 0.0182 AKT3, ALPK3,
   APAF1, ATP6AP1, CAMK2G, DYRK1B, EIF4A2, HSP90AB1, IP6K3, LIG1, MAPK3,
   MTOR, NLRP1, NUBP1, PKDCC, PRKCA, PSMC6, RECQL4, SMC6, SPEG, UBE2D3,
   ULK1
   GO:0005324 Long-chain fatty acid transporter activity 2 6 0.0324 FABP3,
   FABP4
   GO:0005504 Fatty acid binding 3 27 0.0324 ALB, FABP3, FABP4
   GO:0043168 Anion binding 31 2696 0.0324 AKT3, ALB, ALPK3, APAF1,
   ATP6AP1, CAMK2G, DYRK1B, EEA1, EIF4A2, FABP3, FABP4, GOT2, GUF1,
   HSP90AB1, IP6K3, LIG1, MAPK3, MTOR, NLRP1, NUBP1, PKDCC, PRKCA, PSMC6,
   RECQL4, RRAGA, SMC6, SNX13, SPEG, UBE2D3, ULK1, UXS1
   GO:0019901 Protein kinase binding 11 599 0.0414 AP2A1, DUSP1, DVL2,
   HSP90AB1, MTOR, NR3C1, PCNA, PICK1, PRMT1, PTPRJ, RPS6
   GO:0004674 Protein serine/threonine kinase activity 7 444
   0.000000000313 AKT3, CAMK2G, DYRK1B, MAPK3, MTOR, PRKCA, ULK1
   Cellular Component GO:0030018 Z disc 5 122 0.0153 ITGB1BP2, MYOT,
   MYOZ3, PPP2R5A, PSEN1
   GO:0034703 Cation channel complex 3 206 0.0394 CACNA1S, KCNQ4, SCN4A
   [69]Open in a new tab

   FDR: False discovery rate, *: Bold text: candidate genes in subjects.
   ALPK3: alpha-protein kinase 3, APAF1: apoptotic protease-activating
   factor 1, ATP6AP1: ATPase H+ transporting accessory protein 1, CACNA1S:
   calcium voltage-gated channel subunit alpha 1 S, CAMK2G:
   calcium/calmodulin-dependent protein kinase II gamma, DYRK1B:
   dual-specificity tyrosine-phosphorylation-regulated kinase 1B, EEA1:
   early endosome antigen 1, EIF4A2: eukaryotic initiation factor 4A-II,
   FABP4: fatty acid-binding protein 4, GUF1: GUF1 homolog, GTPase, IP6K3:
   inositol hexakisphosphate kinase 3, ITGB1BP2: integrin subunit beta 1
   binding protein 2, KCND2: potassium voltage-gated channel subfamily D
   member 2, KCNQ4: potassium voltage-gated channel subfamily Q member 4,
   MYOT: myotilin, MYOZ3: myozenin 3, NLRP1: NLR family pyrin domain
   containing 1, NUBP1: nucleotide-binding protein 1, PKDCC: protein
   kinase domain containing, cytoplasmic, PPP2R5A: protein phosphatase 2
   regulatory subunit B’alpha, PSEN1: presenilin 1, PSMC6: proteasome 26S
   subunit, ATPase 6, RECQL4: RecQ-like helicase 4, SCN4A: sodium
   voltage-gated channel alpha subunit 4, SLC9A4: solute carrier family 9
   member A4, SMC6: structural maintenance of chromosomes 6, SNX13:
   sorting nexin 13, SPEG: striated muscle-enriched protein kinase,
   UBE2D3: ubiquitin-conjugating enzyme E2 D3, ULK1: unc-51-like autophagy
   activating kinase 1, and UXS1: UDP-glucuronate decarboxylase 1.

   In the case of the KEGG enrichment pathways, we mapped the DEGs into
   the KEGG database to search for genes involved in signaling pathways. A
   total of 471 DEGs were assigned to 240 KEGG pathways (see
   [70]Supplementary Table S4). Some of the significantly enriched KEGG
   pathways were related to the signaling pathways, including the cyclic
   adenosine monophosphate (cAMP) signaling pathway, mitogen-activated
   protein kinase (MAPK) signaling pathway, calcium signaling pathway,
   AMP-activated protein kinase (AMPK) signaling pathway, mammalian target
   of rapamycin (mTOR) signaling pathway, sphingolipid signaling pathway,
   and apelin signaling pathway. Moreover, there were candidate genes
   involved in pathways related to glycine, serine, and threonine
   metabolism, autophagy-animal, and melanogenesis.

4. Discussion

   In this study, we determined the DEGs associated with carcass grade
   through transcriptome sequencing in crossbred pigs. We identified
   associations of the Z-disc, cation channel complex, ion transmembrane
   transport, protein tyrosine kinase activity, metal ion transport, and
   apelin signaling pathway with carcass grade using RNA sequencing. The
   Z-disk is a simple structure at the lateral border of the sarcomere
   unit in muscles that plays a role in the structure, maintenance, and
   protein quality control mechanisms of muscles in humans and animals
   [[71]20,[72]21,[73]22,[74]23,[75]24].

   In the present study, we showed that the expression of ITGB1BP2, MYOT,
   MYOZ3, PPP2R5A, and PSEN1 in muscles differed according to carcass
   grade. Generally, muscle fiber type is an important factor influencing
   meat quality, including meat color, tenderness, and water-holding
   capacity (WHC) [[76]21,[77]25,[78]26]. In addition, the MYOZ family of
   genes (e.g., MYOZ3 and MYOT) influences the formation and maintenance
   of the Z-disc, which includes α-actinin, β-filamin, telethonin, and
   calcineurin [[79]21,[80]23]. The MYOT genes are known as the titin
   immunoglobulin domain (TTID) gene and localize to the Z-line in muscles
   and are associated with various carcass traits, such as loin eye area,
   meat pH, meat color, value, and WHC [[81]27]. Collectively, these data
   suggest that the cellular components of the Z-disc have important
   relationships with genes, such as MYOZ3 and MYOT, affecting carcass
   grade in crossbred pigs.

   We assessed ion channel function, such as the cation channel complex,
   ion transmembrane transport, and metal ion transport. Genetic
   approaches have shown that ion channel function is closely related to
   increased and decreased Ca^2+ ion sensitivities of muscle contraction
   [[82]20,[83]22]. Typically, the RYR1 gene causes uncontrolled release
   by Ca^2+ release channels within the sarcoplasmic reticulum in response
   to stress [[84]10,[85]28]. Additionally, CACNA1S and UBE2D3 genes have
   been found with DEG analysis in relation to tenderness in pork [[86]7].
   Gene expression has been associated with various meat quality traits,
   as well as the concentration of some minerals, e.g., calcium, copper,
   iron, potassium, magnesium, manganese, sodium, phosphorus, selenium,
   and zinc [[87]29]. Thus, we suggest that the expression of genes
   related to metal ion function (e.g., CACNA1S and UBE2D3) is likely to
   be associated with carcass grade and meat quality.

   We also observed a relationship between the mTOR signaling pathway and
   DVL2 and ULK and the carcass grade of pork. Fatty acid synthesis was
   reduced, which enhanced fatty acid oxidation by up-regulating hepatic
   lipogenic gene expression, and this was mediated through the mTOR
   pathway [[88]30]. Previous studies have suggested that the activation
   of mTOR signaling plays an important role during the initial conversion
   of muscle to meat [[89]29,[90]31]. There are similarities between
   metabolic pathways, including the mTOR pathway and oncogenic signaling;
   these similarities are therapeutic targets [[91]31,[92]32]. DVL2 gene
   expression has also been shown to be up- and down-regulated in adipose
   tissue and muscles, respectively, under insulin-resistant conditions
   [[93]33]. Taken together, these data suggest that DVL2 and the mTOR
   pathway might have important roles in carcass grade.

   We also observed a relationship between the apelin signaling pathway
   and carcass quality. It is interesting that the apelin signaling
   pathway associated with increased myofilament sensitivity to Ca^2+ ions
   and increased intracellular pH [[94]34,[95]35]. Furthermore, this
   signaling pathway has been implicated in hypertension, diabetes, and
   obesity and it has emerged as a novel therapeutic targeting in humans
   [[96]34]. Thus, the apelin signaling pathway may be related to carcass
   quality and grade, but this did not approach the molecular level in the
   loin muscles of pigs.

5. Conclusions

   Transcriptome sequencing can be used to provide remarkable information
   about the molecular basis of the economically important traits of an
   organism. Here, we described crossbred pigs’ loin muscle
   transcriptomes. The transcriptome data in this study will be a valuable
   resource for genomic studies focused on uncovering the molecular
   mechanisms underlying carcass quality in crossbred pigs. Thus, those
   candidate genes identified in this study might be used as predictive
   markers for pork carcass quality.

Supplementary Materials

   The following are available online at
   [97]https://www.mdpi.com/2076-2615/10/8/1279/s1, Table S1: Basic
   characteristics of the study all subjects, Table S2: Summary of gene
   expression and DEG information from loin muscle transcriptome, Table
   S3: Summary of enriched GO categories assigned to DEG’s, Table S4:
   Summary of enriched KEGG pathways assigned to DEG’s.
   [98]Click here for additional data file.^ (4.2MB, zip)

Author Contributions

   S.-M.K., K.M., J.-Y.L., and J.Y.Y. drafted the manuscript. S.-M.K. and
   J.-Y.L. performed the sample data recording, collected RNA samples, and
   statistical analyses. J.Y.Y. and G.-W.K. carried out the study design,
   data interpretation, and study supervision. All authors read and
   approved the final manuscript.

Funding

   This research received no external funding.

Conflicts of Interest

   The authors declare that there is no conflict of interests.

References