Next Article in Journal
A Treatment Combination of IGF and EGF Promotes Hair Growth in the Angora Rabbit
Next Article in Special Issue
Comparative Transcriptome Analysis Reveals Key Genes and Pathways Involved in Prickle Development in Eggplant
Previous Article in Journal
Selection of Reference Genes for Normalization of Gene Expression in Thermobia domestica (Insecta: Zygentoma: Lepismatidae)
Previous Article in Special Issue
Genome-Wide Identification, Classification, Characterization, and Expression Analysis of the Wall-Associated Kinase Family during Fruit Development and under Wound Stress in Tomato (Solanum lycopersicum L.)
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Genes
Volume 12
Issue 1
10.3390/genes12010023
genes-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Genome-Wide Identification and Expression Profiling of the PDI Gene Family Reveals Their Probable Involvement in Abiotic Stress Tolerance in Tomato (Solanum lycopersicum L.)

by
Antt Htet Wai
1,2,
Muhammad Waseem
3,
A B M Mahbub Morshed Khan
4,
Ujjal Kumar Nath
5,
Do Jin Lee
1,
Sang Tae Kim
6,
Chang Kil Kim
7 and
Mi Young Chung
1,*
1
Department of Agricultural Education, Sunchon National University, 413 Jungangno, Suncheon, Jeonnam 540-950, Korea
2
Department of Botany, University of Mandalay, Mandalay 05032, Myanmar
3
College of Horticulture, South China Agricultural University, Guangzhou 510640, China
4
Department of Agricultural Botany, Faculty of Agriculture, Patuakhali Science and Technology University, Patuakhali 8602, Bangladesh
5
Department of Genetics and Plant Breeding, Bangladesh Agricultural University, Mymensingh 2202, Bangladesh
6
Department of Medical and Biological Sciences, The Catholic University of Korea, Bucheon, Gyeonggi-do 14662, Korea
7
Department of Horticulture, Kyungpook National University, Daegu 41566, Korea
*
Author to whom correspondence should be addressed.
Genes 2021, 12(1), 23; https://doi.org/10.3390/genes12010023
Submission received: 23 October 2020 / Revised: 4 December 2020 / Accepted: 23 December 2020 / Published: 25 December 2020
(This article belongs to the Special Issue Genetics and Genomics of Solanaceae)
Browse Figures
Versions Notes

Abstract

:
Protein disulfide isomerases (PDI) and PDI-like proteins catalyze the formation and isomerization of protein disulfide bonds in the endoplasmic reticulum and prevent the buildup of misfolded proteins under abiotic stress conditions. In the present study, we conducted the first comprehensive genome-wide exploration of the PDI gene family in tomato (Solanum lycopersicum L.). We identified 19 tomato PDI genes that were unevenly distributed on 8 of the 12 tomato chromosomes, with segmental duplications detected for 3 paralogous gene pairs. Expression profiling of the PDI genes revealed that most of them were differentially expressed across different organs and developmental stages of the fruit. Furthermore, most of the PDI genes were highly induced by heat, salt, and abscisic acid (ABA) treatments, while relatively few of the genes were induced by cold and nutrient and water deficit (NWD) stresses. The predominant expression of SlPDI1-1, SlPDI1-3, SlPDI1-4, SlPDI2-1, SlPDI4-1, and SlPDI5-1 in response to abiotic stress and ABA treatment suggested they play regulatory roles in abiotic stress tolerance in tomato in an ABA-dependent manner. Our results provide new insight into the structure and function of PDI genes and will be helpful for the selection of candidate genes involved in fruit development and abiotic stress tolerance in tomato.

1. Introduction

Protein disulfide isomerases (PDIs) are endoplasmic reticulum (ER)-resident thiodisulfide oxidoreductases whose primary function is to catalyze the formation, reduction, and rearrangement of disulfide bonds in newly synthesized proteins or target proteins. PDIs are thus of particular importance for proper folding and stability of proteins [1,2,3]. When plants are stressed, PDIs interact with misfolded or denatured proteins to prevent the accumulation of unfolded protein aggregates that would otherwise disrupt normal cellular metabolism, thereby contributing to plant tolerance of adverse environmental conditions [4,5]. The PDI gene family encodes PDI and PDI-like (PDIL) proteins that contain at least one redox-active thioredoxin domain responsible for the alteration of disulfide bonds, a feature that distinguishes the PDI family from other families in the thioredoxoin superfamily, such as glutaredoxins, ferredoxins, and peroxidoxins [6,7,8].
Although they are typically located in the ER, PDIs have also been found in other cellular locations, such as the nucleus, mitochondria, the cytoplasm, and the extracellular environment [9,10,11,12,13]. Many PDI proteins have been well investigated, particularly in mammals, including endoplasmic reticulum resident protein 57 (ERp57), PDIp, PDI-P5, ERp72, PDI-RELATED (PDIR), and PDI with D-domain (PDI-D). These proteins act as redox catalysts and isomerases in addition to having other functions, such as peptide binding, cell adhesion, and chaperone activities [14,15]. The modular structure of human PDI proteins typically consists of four thioredoxin-like domains (known as a, b, b’, and a’), a linker (x), and a C-terminal extension domain (c), arranged in the order abb’xa’c [16]. The a and a’ domains share homology to thioredoxin and each possesses a classic -Cys-Gly-His-Cys- active site within a conserved arrangement of α-helices and β-strands (β-α-β-α-β-α-β-β-α), which is important for isomerase and redox activity [17]. The middle b and b’ domains show similarity to the thioredoxin domain in their secondary structure but not in their primary sequence, and neither contains an active site, although the b’ domain serves as the primary substrate binding site during isomerization reactions [17,18]. The c domain, located in the C terminal region, is enriched in acidic residues characteristic of calcium-binding proteins and usually ends with a KDEL peptide motif critical for ER retention [19,20].
The completion of multiple genome projects in land plants has allowed the identification of each plant’s complement of PDI genes: 21 genes in Arabidopsis (Arabidopsis thaliana); 12 in rice (Oryza sativa), purple false brome (Brachypodium distachyon), and maize (Zea mays); 10 in grapevine (Vitis vinifera); 9 in wheat (Triticum aestivum); and 32 in field mustard (Brassica rapa) [21,22]. In Arabidopsis, PDI genes play roles in developmental processes such as the biogenesis of transitory starch granules in leaves, seed development through the regulation programmed cell death (PCD) during embryogenesis, and the development of the embryo sac [23,24,25]. Analysis of the rice mutant enclosed shorter panicle 2 (esp2) indicated that OsPDIL1-1 may regulate starch biosynthesis by mediating the segregation of proglutelin and prolamin polypeptides within the ER lumen during the early phase of seed development [26,27]. A role for PDI genes during endosperm development in wheat and maize has also been reported [28,29]. Soybean (Glycine max) GmPDIL-1, GmPDIL-2, GmPDIL-3a, and GmPDIL-3b were also reported to play a role in the proper folding and deposition of storage proteins [28,30].
Diverse environmental stresses, including salinity, heat, drought and cold, are detrimental to plant growth and development and lead to considerable yield loss in crops [31]. To mitigate damage to cellular structures, various abiotic stresses induce the expression of PDI genes to assist (re)folding misfolded or unfolded proteins to restore their biological functions, as shown in B. distachyon, wheat, Chinese cabbage (B. rapa spp. pekinensis), and Arabidopsis [22,23,32,33]. PDIs also participate in pathogen resistance, as evidenced by the higher expression of 14 BrPDI genes in response to Fusarium oxysporum f.sp. conglutinans infection in Chinese cabbage and the elevated resistance against powdery mildew conferred by the overexpression of PDI-V in susceptible wheat cultivars [22,34]. Likewise, Arabidopsis PDI1 is up-regulated by diverse abiotic stresses and its overexpression increases the seed germination rate and promotes root growth under different abiotic stress conditions, underscoring the role of PDI genes in abiotic stress tolerance [35].
Tomato (S. lycopersicum L.) is a model fleshy fruit plant species whose yields are adversely influenced by several environmental stresses. Thus, tomato has been extensively studied to understand the molecular mechanisms governing fruit development and ripening processes, in addition to enhancing fruit yield under different environmental conditions. Although the role of PDI proteins has been documented in several plant species in the context of plant growth and development and abiotic stress tolerance [22,28,33,35], the tomato PDI family has yet to be described. Here, we report the first genome-wide characterization, phylogenetic analysis, and expression profiling of tomato PDI genes in various organs and under different abiotic stresses to gain a better understanding of the molecular structure and biological functions of PDI genes in tomato.

2. Methods

2.1. Identification and Sequence Analysis of Protein Disulfide Isomerase (PDI) Genes

We identified tomato PDI family members using the Sol Genomics Network (SGN) (http://solgenomics.net/) and the National Center for Biotechnological Information (NCBI) websites using the keyword “PDI”. Arabidopsis PDI protein sequences were retrieved from the Arabidopsis Information Resource (TAIR) database (https://www.arabidopsis.org) [36] and used as a query to perform basic local alignment search tool (BLAST) searches with default parameters at the Sol genomics database [37]. The resulting 19 non-redundant PDI sequences were validated for the presence of a thioredoxin domain, using the NCBI conserved domain (NCBI CDD) search [38] and SMART web tool [39]. We gathered information on tomato PDI genes, such as locus name, open reading frame (ORF) length, coding sequence (CDS), and chromosomal locations from SGN [37]. The physicochemical parameters of deduced tomato PDI proteins (number of amino acids, molecular weight [MW], and isoelectric point [pI]) were determined using ProtParam (https://web.expasy.org/protparam/) [40] (Table 1). ProtComp Version 9.0 from SoftBerry (http://linux1.softberry. com/berry.phtml) was used to predict the subcellular localization of tomato PDI proteins [41]. We performed a multi-protein alignment of PDI proteins using Clustal Omega [42]. The exon/intron structures of tomato PDI genes were analyzed using the Gene Structure Display Server-2.0 (GSDS-2.0) web server (http://gsds.cbi.pku.edu.cn/index.php) by aligning genomic and coding DNA sequences [43]. Sequence homology across the 19 PDI proteins was investigated using the web tool “Immunomedicine Group” (http://imed.med.ucm.es/Tools/sias.html). We analyzed promoter regions of ~1500 bp upstream of the initiation codon [ATG] to predict putative cis-acting elements present in PDI promoters using the PlantCare database (http://bioinformatics.psb.ugent.be/webtools/plantcare/html/) [44].

2.2. Phylogenetic and Conserved Motif Analysis of the PDI Gene Family in Tomato

The full length tomato PDI protein sequences were aligned with those of Arabidopsis, poplar (Populus trichocarpa), Chinese cabbage, maize, and B. distachyon L. using Clustal Omega, followed by phylogenetic analysis using the neighbor-joining (NJ) algorithm in MEGA 6.0 [45]. The deduced amino acid sequences of Chinese cabbage, maize, poplar, and B. distachyon L. PDIs were obtained from the literature [22,28]. The gene names and accession numbers used in constructing the phylogenetic tree are listed in Supplementary Table S3. To examine the diversity of functional protein motifs in the putative SlPDI proteins, we employed Multiple Em for Motif Elicitation (MEME) software (http://meme-suite.org/) to identify conserved protein motifs with the following parameters: maximum motif number of 10 and a motif length between six and 50 amino acids [46].

2.3. Chromosomal Locations, Gene Duplication, and Microsynteny Analysis of the PDI Gene Family

The start and end locations of PDI genes, including their sub-genome information, were collected from SGN [36]. PDI positions on chromosomes were analyzed with the online tool MapGene2Chromosome2 (http://mg2c.iask.in/mg2c_v2.1/) [47]. Gene duplications among tomato PDI genes were identified with the TBtools software [48] according to the criteria stated by Kong et al. (2013). Genes were considered to be segmentally duplicated when their identity and query coverage were >80% [49]. The synonymous (Ks) and non-synonymous (Ka) nucleotide substitution rates of duplicated SlPDI gene pairs were determined using the method of Nei and Gojobori (1986) with Mega 6.0 software [50]. The mode of selection was identified by determining the Ka/Ks ratio [51]. Divergence time (T) for each duplicated gene pair was computed with the formula T = Ks/2r Mya (millions of years), where Ks is the synonymous substitution rate per site and r is the constant for dicotyledonous plants of 1.5 × 10−8 substitutions per site per year [52]. The microsyntenic relationship of PDI genes between tomato, Arabidopsis, and rice was investigated using a reciprocal BLAST search approach against the entire genomes of these species. The results were visualized using TBtools software [48]. The sequences for the three plants species used for microsynteny analysis were retrieved from Phytozome [53].

2.4. Preparation of Plant Materials, Treatments, and Sampling

Tomato seeds of the cultivar Ailsa Craig were germinated on horticultural commercial soil for seedlings (Zeolite (4%), Perlite (7%), vermiculite (4%), cocopeat (68%), peatmoss (14.73%), Humectant (0.065%) and fertilizer (0.2%)) in a growth chamber. Seedlings were then allowed to grow in a controlled environment with a relative humidity ranging from 55% to 70%, adjusted temperature of 25 °C during the day and 20 °C at night, under a 16 h light 8 h dark photoperiod, and a light intensity of 300 μmol m−2s−1. Fresh leaves, stems, and roots were collected from 28-day-old plants for analysis of tissue-specific expression of SlPDI genes. The remaining plants were moved to a greenhouse maintained at a temperature of 18 ± 2 °C and 65–80% relative humidity until the reproductive stage in order to collect flower and fruit samples. Flower samples were taken at three different stages: floral bud, anthesis, and flower senescence. Fruit samples were harvested at six developmental stages: (i) young fruits ~14 days after pollination and about 1 cm in diameter, (ii) immature fruits ~34 days after pollination (IM fruits), (iii) mature green fruits ~45 days after pollination (MG fruits), (iv) fruits at the breaker stage when the green color of mature fruits turns to yellow-orange (B fruits), (v) fruits 3 days after the breaker stage (B3 fruits), and (vi) fruits 7 days after the breaker stage (B7 fruits) [54].
In parallel, we used 28-day-old plants with uniform growth since sowing to investigate the expression patterns of SlPDI genes in response to different stress treatments. We subjected tomato plants to five different treatments: heat, cold, salt (NaCl), nutrient and water deficit (NWD), and abscisic acid (ABA). Leaves were collected at various time points: 0, 1, 3, 6, 12, and 24 h after onset of treatment. Tomato plants were incubated in a growth cabinet at 40 °C (heat treatment) or 4 °C (cold treatment) for 24 h. NaCl stress treatment was imposed by submerging plant roots in a 200 mM NaCl solution for 24 h. For NWD stress, whole plants were gently pulled out from the soil, their root systems carefully cleaned with fresh water and subsequently placed on a dry paper towel for 24 h [54,55,56,57,58]. ABA treatment was applied by spraying plant leaves with 100 μM ABA [54]. Tomato plants grown in soil under normal conditions (25 °C) served as the 0 h controls for all stress conditions. The samples were collected from three biological replicates, frozen in liquid nitrogen, and stored at −80 °C until RNA extraction.

2.5. RNA Isolation and Quantitative Real-Time Polymerase Chain Reaction (PCR)

We extracted total RNA from collected samples using the RNeasy mini kit (QIAGEN, Hilden, Germany) following the manufacturer’s instructions. Trace genomic DNA contamination was removed using an RNase-free DNase I kit (Qiagen, Hilden, Germany). RNA concentration and quality was determined with a NanoDrop® 1000 spectrophotometer (Wilmington, DE, USA). We used 1 µg total RNA per sample for first-strand cDNA synthesis using the Superscript® III First-Strand cDNA synthesis kit (Invitrogen, Carlsbad, CA, USA) following the manufacturer’s protocol. For quantitative real-time polymerase chain reaction (RT-qPCR) analysis, gene-specific primers were designed for all SlPDI genes using Primer3 software (http://frodo.wi.mit.edu/primer3/input.htm) (Supplementary Table S4) [59]. The melting curve analysis was conducted to validate the specificity of the amplicon for each primer pair [60]. 18S rRNA (F: AAAAGGTCGACGCGGGCT, R: CGACAGAAGGGACGAGAC) from tomato was used as reference for normalization [61]. Real-time PCR analysis was conducted in optical 96-well plates using a Light cycler® 96SW 1.1 instrument (Roche, Germany). Each reaction consisted of 10 μL iTaq™ from the SYBR® Green PCR kit (Qiagen, Hilden, Germany), 75−80 ng/μL cDNA, 2 μL each forward and reverse primer, and 7 μL double-distilled water, for a total volume of 20 µL. The conditions for qPCR were: initial denaturation at 95 °C for 5 min, followed by 40 cycles at 94 °C for 10 s, annealing at 58 °C for 10 s, and extension at 72 °C for 15 s. Relative expression ratios for each gene were determined by the 2−ΔΔCt method and normalized to leaf sample values for organ-specific expression; for stress treatments, relative expression values were normalized to leaf sample values harvested at 0 h [62]. Significant differences in the relative expression data were analyzed with Sigmaplot 12.1. (SYSTAT and MYSTAT Products, United States, and Canada) using two-tailed Student’s t-tests.

3. Results

3.1. In Silico Identification of PDI Genes in Tomato

We identified 19 non-redundant tomato genes that encoded proteins with similarity to PDI, which we designated SlPDI1-1-SlPDI11-3. The ORFs of SlPDI genes showed significant variation in length, ranging from 450 bp (SlPDI6-1) to 1743 bp (SlPDI2-3), with a mean of 1291 bp. Similarly, the lengths of the predicted PDI proteins varied from 149 to 580 amino acid (aa) for SlPDI6-1 and SlPDI2-3, respectively, with a mean of 451 aa. In addition, the predicted molecular weights (MW) vary from 16.9 to 64.6 kDa. The computed isoelectric points of these proteins ranged from 4.49 to 8.74, indicating that PDIs may be acidic or basic, depending on the SlPDI under consideration. Additional information on SlPDI family members, such as locus name and predicted subcellular location, are given in Table 1.

3.2. Phylogenetic and Domain Analysis

We compared the tomato PDI proteins and investigated their evolutionary relationships with respect to other members of the PDI family from various plant species. Accordingly, we generated a phylogenetic tree from the alignment of PDI and PDI-like protein sequences from tomato (with the Sl prefix in the tree, 19 proteins), Arabidopsis (At, 21 proteins), maize (Zm, 12 proteins), B. distachyon L. (Bd, 11 proteins), poplar (P. trichocarpa [Pt], 12 proteins), and B. rapa (Br, 32 proteins) (Figure 1). PDI family members clearly clustered into four clades, which were further divided into 11 groups. Tomato PDI members were distributed across all 11 groups, with the largest number of SlPDI proteins belonging to group I. We designated the tomato PDI proteins PDI1-1 to PDI11-3 on the basis of their phylogenetic relationships with other plant PDIs. Of the four clades, clade 1 was the largest clade and comprised groups I, II, III, and VII, of which groups I, II, and III consisted of PDI proteins with two active thioredoxin domains situated at the N-terminus and C-terminal tail. By contrast, group VII included PDI proteins with a single active thioredoxin domain at their N terminus (Figure 2). Based on their structural similarity, PDI proteins belonging to groups I, II, and III may have originated from the duplication of a common ancestral gene, whereas group VII may have arisen by degeneration of one of the two active thioredoxin domains encoded by the ancestral gene or one of its duplicated copies, offering a rational explanation for the close phylogenetic relationship between members of group VII and those of groups I, II, and III. Clade 3 was the smallest and was composed solely of group XI, whose members contained a phosphoadenosine phosphosulfate (PAPS) reductase domain, followed by a single active thioredoxin domain at their C-terminal end. Clade 2 comprised groups IV and V, which contained proteins with two active domains in tandem at their N terminus, as well as group VI, whose constituent proteins contained a single N-terminal active domain. The close phylogenetic relationship between the members of group VI and those of groups IV and V may indicate that group VI genes may have evolved from the degeneration of a gene from group IV or V, resulting in the loss of one active domain, thus paralleling our hypothesis of the evolution of Clade 1 genes. Clade 4 consisted of groups VIII, IX, and X, whose member proteins contained one active thioredoxin domain. Altogether these results indicated that PDI genes have diverged greatly over the course of evolution.
All but two of the tomato SlPDI proteins had at least one active thioredoxin domain with the canonical –CXXC– catalytic tetrad for isomerase and redox activities. The exceptions were SlPDI8-1 and SlPDI10-1, which had non-characteristic active sites (CYWS and CPFS, respectively; Table 2). Eleven out of the 19 tomato PDI proteins possessed a predicted N-terminal signal peptide (SP) necessary for polypeptide translocation, whereas only three had a clear transmembrane domain and six had a C-terminal KDEL or RDEL signal for ER retention (Figure 2 and Table 2). A conserved Arg residue, which modulates the redox potential of the active site by regulating the pKa of the Cys residues in the catalytic tetrad, was present in most PDI family members, while some of them possessed the conserved Glu-Lys pair, which is responsible for proton transfer reactions that are critical for the catalytic function of the thioredoxin domain. In addition to the a-type or b-type thioredoxin-like domains, we identified other domains in the tomato PDIs: a calcium-binding domain similar to that of calsequestrin, an Erp29c domain, an ER-Golgi Intermediate Compartment (ERGIC)_N domain, a C_ERV (Endogenous RetroVirus) domain, an Evr1_Air domain, and a PAPS_reduct domain (Figure 2 and Table 2). Alignment of the a-type domains of the predicted tomato PDI proteins and a typical human PDI protein revealed that these domains comprised four β-sheets sandwiched between three α-helices with the –CXXC– catalytic tetrad (Figure 3).

3.3. Exon and Intron Distribution and Conserved Motif Analysis

We also investigated the exon-intron structure of SlPDI genes (Figure S1) and observed a high degree of structural divergence in the family. For instance, SlPDI genes in most of the phylogenetic groups (I, II, III, IV, V, VIII, and IX) contained more introns, ranging from 8 to 14 with a mean of 10, than members in the remaining groups (groups VI, VII, X and XI), which had only 3 or 4 introns. Most SlPDI genes falling within the same phylogenetic group displayed almost identical exon-intron organizations, both in terms of intron numbers and exon lengths. For instance, PDI members within group I contained 9 or 10 introns, while all group II members (SlPDI2-1, SlPDI2-2, and SlPDI2-3) all had 11 introns. In addition, genes within each gene pair in group VII shared the same exon-intron structural organization. Among all the SlPDI members, SlPDI6-1 and SlPDI10-1 had the fewest introns, with 3, while SlPDI8-1 had the most, with 14.
To characterize the structural diversity of the tomato PDI proteins further, we examined the composition and organization of conserved motifs in SlPDI proteins using the MEME online suite (Figure 4 and Figure S2). Among the 10 conserved motifs we identified, the –CXXC– catalytic triad critical for isomerase and redox activity was detected as Motif 1 and 2. Notably, Motif 1 was common to all phylogenetic groups, except SlPDI4-1. Similarly, Motif 3 was present in all groups, with the exception of group IX. Motif 2 was absent from PDI proteins belonging to groups VI, VII, VIII, IX, and XI. Likewise, Motif 4 was not detected in PDIs from groups V, VI, VIII, IX, X, and XI, with the exception of SlPDI5-1 from group V, which contained two copies of Motif 4. SlPD5-1 was the only protein in group V with this motif, suggesting that Motif 4 does not define group V. Motif 5 was largely restricted to groups I, II, and III, while Motifs 6, 7, and 9, located in the PAPS reductase domain, were unique to group XI. Finally, Motif 8 was specific to groups II, III, IV, and IX, whereas Motif 10 was mainly found in groups I, II, III, and VII from clade 1. PDI proteins from Arabidopsis, maize, and tomato that belonged to the same phylogenetic groups exhibited a similar domain composition and arrangement, suggesting functional conservation across these three plant species. We also noticed different motif distributions among various SlPDI groups, which is likely to drive evolution of the PDI protein family in tomato.

3.4. Chromosomal Position, Gene Duplication, and Microsynteny Analysis

We generated a map showing the chromosomal positions of all SlPDI genes (Figure 5): eight out of the 12 tomato chromosomes harbored at least one PDI gene, with most genes residing close to chromosome ends. Chromosomes 6 and 4 had the most PDI genes (4 and 3, respectively). Chromosomes 2, 3, 5, 7, and 11 each possessed 2 PDI genes, while chromosome 1 contained a single PDI gene.
Gene duplications such as tandem duplications and segmental duplications play a role in the expansion of a gene family. Genes that show ≥80% sequence identity over at least 80% of their sequence are predicted to be duplicated genes. In addition, if the gene pair is separated by five or fewer genes residing within a 100 kbp window on the same chromosome, they may be considered as tandem-duplicated genes [50]. Based on these criteria, we analyzed the potential for gene duplication events among PDI genes and determined that three SlPDI pairs, SlPDI2-2/SlPDI2-3, SlPDI11-1/SlPDI11-2, and SlPDI11-2/SlPDI11-3, likely originated by segmental duplication. We did not detect clear evidence for tandem duplications. As expected, all segmentally duplicated gene pairs belonged to the same phylogenetic groups. Only the SlPDI11-2/SlPDI11-3 pair was implicated in a regional duplication event within the same chromosome, while the segmentally duplicated genes involved in the remaining gene pairs (SlPDI2-2/SlPDI2-3 and SlPDI11-1/SlPDI11-2) mapped to distinct chromosomes (Figure S3).
SlPDI proteins displayed high sequence similarity within each group (Supplementary Table S1). To assess the extent and type of selective pressure imposed on the segmentally duplicated SlPDI gene family members, we calculated the Ka/Ks ratio for each pair of paralogous genes. We assigned a mode of selection based on Ka/Ks ratio values: a Ka/Ks ratio over 1 indicates accelerated evolution with positive selection; a Ka/Ks ratio of ~1 suggests neutral selection; a Ka/Ks ratio below 1 argues for the evolutionary constraints by negative or purifying selection. The Ka/Ks values of all three segmental duplicated gene pairs were below 1, suggesting that these genes experienced a strong purifying/negative selection, with slight variation after duplication. We estimated the divergence time for these paralogous gene pairs to have occurred 20.85 to 28.94 million years ago (MYA) (Table 3). In addition, we also constructed a comparative microsyntenic map to identify orthologous gene pairs of PDI genes between tomato, Arabidopsis, and rice to explore the evolutionary relationships across their genomes. We identified 14 pairs of orthologous between tomato and Arabidopsis, but only two pairs between tomato and rice, which agrees with the shorter evolutionary distance between tomato and the dicotyledonous model plant Arabidopsis than between tomato and the monocotyledonous model plant rice (Figure 6).

3.5. Analysis of Stress- and Hormone-Responsive Cis-Elements in the Promoter Regions of SlPDI Genes

Cis-regulatory elements in the upstream regions of genes play a pivotal role in the regulation of gene expression in response to various environmental stresses. Many stress responsive-genes have been reported to harbor a wide range of cis-acting elements in their promoter regions. Therefore, we utilized the web tool PlantCare database to identify putative phytohormone- and stress-responsive cis-regulatory elements in the SlPDI promoters. We observed various numbers of such cis-acting elements (Figure S5 and Supplementary Table S2), supporting the possible roles of SlPDI genes in abiotic stress tolerance. Of the abiotic stress-responsive cis-elements identified, ABA-responsive elements (ABRE) were present in the promoters of 14 genes, while TC-rich repeats with roles in defense and stress responses were detected in seven promoters. The low temperature responsive (LTR) element appeared in five promoters, while a MYB binding site (MBS) was found in four promoters. Finally, we identified the WUN-motif, which is involved in wound-responses, in one tomato PDI promoter. Despite having the putative cis-elements, some genes are not receptive to abiotic stress. For instance, five PDI genes, viz., SlPDI1-2, SlPDI2-1, SlPDI5-1, SlPDI11-1 and SlPDI11-3, revealed the presence of the LTR element in their promoter regions, but SlPDI2-1 did not exhibit the significant response to the cold stress application compared to the other four genes harboring the LTR element. Thus, these regulatory motifs present in the upstream of PDI genes should be validated experimentally to verify if they are functional regulatory elements.

3.6. Expression Analysis of Tomato PDI Genes in Various Organs

Analysis of organ-specific gene expression patterns can provide clues about the possible function of a gene over the course of development. Therefore, we investigated the expression pattern and relative levels of PDI transcripts across 12 tomato organs (i.e., leaves, stems, roots, flower buds, full blooming flowers, senescent flowers, 1 cm fruits, IM fruits, MG fruits, B fruits, B3 fruits, and B7 fruits) via RT-qPCR assay in the tomato cultivar Ailsa Craig.
Relative to their expression levels in leaves, 16 PDI genes were expressed 2- to 25-fold more in stem tissues; similarly, 10 PDI genes were more highly expressed in 1 cm fruits (2- to 17-fold) and 11 showed a 2- to 12-fold increase in relative expression in breaker fruits. The expression of SlPDI1-1, SlPDI1-2, and SlPDI1-3, which all belonged to group I, was relatively high in stems, flower buds, and early stages of fruit development, such as the breaker stage, compared to other organs and later fruit ripening stages. By contrast, the mRNA transcripts of SlPDI1-4 were more abundant in 1 cm fruits (~40-fold) in comparison with other organs. The expression of SlPDI2-1 and SlPDI2-3 was predominant in stems, 1 cm fruits, and breaker fruits, but their expression decreased at later ripening stages after the breaker stage. In contrast to its paralogous genes (SlPDI2-1 and SlPDI2-3), SlPDI2-2 showed flower-specific expression. We also determined that relative transcript levels of SlPDI3-1 and SlPDI5-1 reached their highest levels in 1 cm fruits, while transcripts of SlPDI4-1.
SlPDI6-1, and SlPDI11-3 were the most abundant in breaker fruits. The transcript levels of SlPDI7-1 and SlPDI8-1 were predominant in stems relative to other organs. SlPDI7-2 and SlPDI11-2 were preferentially expressed in floral buds and leaves, respectively.
When combined with our phylogenetic investigation, we noticed that several paralogous gene pairs belonging to the same phylogenetic groups shared similar expression patterns in the tested organs, while other paralogs exhibited different expression patterns. For example, SlPDI2-1 and SlPDI2-3 within group II were expressed to the highest levels in stems, whereas SlPDI11-1, SlPDI11-2, and SlPDI11-3 from group XI were most highly expressed in distinct organs such as stems, leaves, and breaker fruits, respectively.
Broadly, in silico analysis of publicly available transcriptome deep-sequencing (RNA-seq) data from the tomato genome consortium [63] was largely consistent with the expression profiles generated by RT-qPCR in our study (Figure 7, Figures S4 and S5). Indeed, both analyses revealed that SlPDI4-1 and SlPDI5-1 reached their peak expression in breaker fruits and 1 cm fruits, respectively. Moreover, the transcript level of SlPDI6-1 was highest in breaker fruits by RT-qPCR, whereas RNA-seq detected the highest level in roots. This variation in expression data could be in part due to the differences in data analysis approaches (Figure 7, Figures S4 and S5).

3.7. Expression Profiling of Tomato PDI Genes under Various Abiotic Stresses and Phytohormone Treatment

To elucidate the putative function of tomato PDI gene family in response to abiotic stresses and ABA, we analyzed the expression patterns of SlPDI genes in leaves sampled at various time points (0 h, 1 h, 3 h, 9 h, and 24 h) after exposure to different abiotic stresses and ABA (Figure 8a,b and Figure S6a,b). The transcript level of SlPDI2-2 remained constant in all samples. By contrast, the expression of many PDI genes responded strongly to these treatments at different time points (Figure 8a,b and Figure S6a,b).
Notably, 12 out of 19 PDI genes (SlPDI1-1, SlPDI1-3, SlPDI1-4, SlPDI2-1, SlPDI3-1, SlPDI4-1, SlPDI5-1, SlPD6-1, SlPDI7-2, SlPDI8-1, SlPDI9-1, and SlPDI11-1) were induced by heat treatment, with expression levels 1.8- to 22.5-fold higher than the control (0 h) at various time points (Figure 8a,b and Figure S6a,b). Of these, four genes (SlPDI1-3, SlPDI1-4, SlPDI5-1, and SlPDI8-1) were highly up-regulated throughout the stress period. The expression of another four genes (SlPDI1-1, SlPDI2-1, SlPDI4-1, and SlPDI11-1) initially showed no response 1 h after heat exposure compared to the control, but subsequently rose at later time points. We also observed that three genes (SlPDI3-1, SlPDI7-2, and SlPDI9-1) were up-regulated by >1.5- to 6.5-fold at later time points of heat treatment relative to the control. By contrast, a few PDI genes (SlPDI1-2, SlPDI2-3, SlPDI10-1, and SlPDI11-2) were down-regulated (>2- to >8-fold) in heat-treated samples compared to the control. Expression of SlPDI7-1 and SlPDI11-3 was almost unchanged in response of heat treatment at most time points, but decreased slightly (>1.6-fold) at 24 h and 9 h, respectively.
Salt treatment also caused remarkable changes in the expression of tomato PDI genes: 18 PDI genes were differentially expressed across several time points following exposure to salt stress (Figure 8a,b). Most PDI genes were up-regulated in response to salt stress. Of the up-regulated PDI genes, SlPDI1-3, SlPDI1-4, SlPDI2-1, and SlPDI4-1 transcript levels were elevated at all time points. In addition, SlPDI1-1, SlPDI9-1, SlPDI11-2 and SlPDI11-3 were highly expressed at most time points. The expression levels of SlPDI5-1 and SlPDI7-2 initially did not change during early time points, but subsequently increased at later time points. SlPDI3-1, SlPDI6-1, and SlPDI10-1 were up-regulated by >1.5- to 2.5-fold at later time points. SlPDI7-1 and SlPDI11-1 were more highly expressed (>1.6-fold over control) specifically 1 h after onset of treatment. By contrast, the expression levels of three genes (SlPDI1-2, SlPDI2-3, and SlPDI8-1) were minimally down-regulated from >1.5- to >2.2-fold upon exposure to salt stress. The transcript levels of SlPDI8-1 decreased only slightly (1.5-fold relative to the control) 3 h after salt treatment.
The expression levels of 18 (out of 19) PDI genes were altered by nutrient and water deficit (NWD) treatment, most PDI genes being repressed (Figure 8a,b and Figure S6a,b). Only five genes (SlPDI1-1, SlPDI1-3, SlPDI2-1, SlPDI2-3, and SlPDI11-1) out of these 18 displayed up-regulated expression levels (>1.8- to 9.5-fold), whereas transcript levels for the remaining 13 PDI genes declined (1.5- to 80-fold relative to the control) at various time points of NWD treatment.
Cold stress lowered the expression of 14 PDI genes, particularly at the last time point following cold exposure (Figure 8a,b and Figure S6a,b). However, SlPDI1-1 transcript levels did not respond to the cold treatment. Intriguingly, three paralogous genes (SlPDI11-1, SlPDI111-2, and SlPDI11-3) within group XI displayed higher expression levels in response to cold stress.
ABA treatment triggered the differential expression of PDI genes at various time points (Figure 8a,b and Figure S6a,b). Fourteen PDI genes were significantly induced by ABA, whereas four PDI genes (namely, SlPDI7-2, SlPDI11-1, SlPDI11-2, and SlPDI11-3) showed little change in response to ABA application.

4. Discussion

In this study, we identified 19 SlPDI genes in tomato, clearly confirming that the size of the PDI gene family varies among different plant species. Tomato had more PDI genes than poplar (12), maize (12) or B. distachyon (11) but fewer than Chinese cabbage (32) or Arabidopsis (21) (Figure 1). As relatively small PDI gene families are found in plants with genomes that are both relatively small, such as B. distachyon (335 Mbp), and relatively large, such as maize (2300 Mbp), PDI gene family size and genome size do not appear to be correlated. From an evolutionary point of view, gene duplication events generate additional copies of genes that enable plants to adapt and survive in response to varying environmental conditions [64,65]. We detected a number of segmentally duplicated gene pairs in the tomato PDI gene family: SlPDI2-2/SlPDI2-3, SlPDI11-1/SlPDI11-2, and SlPDI11-2/SlPDI11-3 (Figure 5 and Figure S3). These duplicated genes shared similar motif compositions and exon/intron organization, suggesting that the 19 SlPDI genes likely originated from an initial set of 14 ancestral genes. Additionally, the duplication events detected for SlPDI genes were group-specific, which indicated that segmental duplications rather than tandem duplications drove the expansion of the SlPDI gene family.
Variations in exon-intron structures are a hallmark of the evolution of many gene families and also contribute to their structural diversity [66]. We observed similar exon-intron structures and motif distributions among the more closely related PDI genes in the phylogenetic tree, while we detected multiple differences between members belonging to different phylogenetic groups (Figure S1 and Figure 4). These findings suggest functional similarity among PDI genes within the same phylogenetic group and a possible explanation for the functional diversification of SlPDI genes over the course of evolution.
The phylogenetic analysis validated the 11 groups of PDI proteins falling into 4 clades in tomato, which was in agreement with the findings of Kayum et al. (2017) (Figure 1) [22]. The high homology between the PDI proteins in tomato and those in poplar, Arabidopsis, and Chinese cabbage indicated their close evolutionary relationships as well as their functional similarities in dicotyledonous plants. In accordance with the phylogenetic classification, we observed that two distinct subgroups comprised PDI and PDIL members from dicots (tomato, poplar, Arabidopsis, and Chinese cabbage) and monocots (B. distachyon and maize), which is consistent with a previous report by Zhu et al. (2014) [33].
Variable abundance of transcripts across organs may help predict functional divergence of their corresponding genes. In tomato, as in other species, we established differential expression of PDI genes in various organs, suggesting that functional diversity may have emerged and that individual PDI genes may play distinct regulatory roles in growth and development (Figure 7 and Figure S4). Previous reports had detected the expression of PDI family members in all tissues examined, hinting at a lack of organ-specificity, which is in agreement with our results [28,33]. However, transcripts for several Chinese cabbage PDI genes were not detected in all organs tested, suggesting the potential for functional variation in PDI genes in different species [22]. Tomato PDI genes exhibited diverse transcript levels in different organs (Figure 7 and Figure S4). For instance, several PDI family members, such as SlPDI7-1, SlPDI8-1, and SlPDI11-2, were predominantly expressed in vegetative organs, while others, such as SlPDI1-1, SlPDI1-2, SlPDI1-4, SlPDI2-2 and SlPDI7-2, were highly expressed in reproductive organs (i.e., fruits and flowers), suggesting their specific involvement in these organs and developmental stages in tomato.
The stem supports the above-ground parts of the plant and mediates long-range transport of water and nutrients, thereby supporting plant growth under normal and adverse conditions. Many PDI genes, (SlPDI1-1, SlPDI2-1, SlPDI2-3, SlPDI6-1, SlPDI8-1, SlPDI9-1, SlPDI10-1, and SlPDI11-1) were predominantly expressed in the stem (Figure 7 and Figure S4), implying that they may be involved in stem development, long-distance translocation of water and nutrients, and/or stress tolerance. Intriguingly, we observed that only one gene (SlPDI11-2) was highly expressed in leaves, in contrast to its segmentally duplicated sister genes (SlPDI11-1 and SlPDI11-3), which showed higher expression in stem and fruit, respectively. In addition, SlPDI2-3 was highly expressed in the stem and breaker fruits, while its duplicated gene (SlPDI2-2) was expressed only in floral organs, especially in floral buds (Figure 7 and Figure S4), suggesting their functional diversification after gene duplication. The induction and development of floral buds marks the transition from the vegetative phase to the reproductive phase, which is a requisite for fruit set and a critical factor that defines crop yield [67]. The higher transcript levels of SlPDI7-2 in flower buds and of SlPDI10-1 in full blooming flowers suggest that their functions are related to floral bud formation and flower development (Figure 7 and Figure S4).
Tomato, a model system for fleshy fruit plants, has been extensively studied with regard to the development and ripening of climacteric fruits. The development of tomato fruits occurs in two major steps: (1) fruit enlargement, which can be further divided into cell division phase and cell expansion phase, and (2) fruit ripening [68,69]. Many PDI genes were highly expressed in 1-cm fruits and during fruit-ripening stages (Figure 7 and Figure S4). SlPDI1-3 and SlPDI3-1 were preferentially expressed in both 1-cm fruits and at the fruit breaker stage (Figure 7 and Figure S4), indicating that they may be important for cell division and fruit ripening. The higher expression levels of SlPDI1-4 and SlPDI5-1 in 1-cm fruits also revealed its possible involvement in the cell division phase of tomato fruit development (Figure 7 and Figure S4). The predominant expression of SlPDI2-3, SlPDI4-1, SlPDI6-1, and SlPDI11-3 during the breaker stage suggests they have active roles in the fruit-ripening process in tomato (Figure 7 and Figure S4). The role of PDI gene family members during fruit development has not previously been studied in any vegetable species: our study, therefore, constitutes the first analysis of PDI gene expression patterns at different fruit developmental stages. Our results suggest possible functions for tomato PDI genes during initial fruit development and ripening, and lay the foundation for further functional validation of this gene family in tomato.
Various environmental stresses disturb plant physiological processes. More specifically, multiple abiotic stresses result in the aggregation of unfolded or denatured proteins, resulting in the disruption of normal cellular function [70,71]. Thus, among the myriad mechanisms used by plants to adapt to adverse environmental conditions is the reconstitution of active proteins from denatured or misfolded proteins by PDIs. The involvement of PDIs in plant stress responses has been corroborated by a number of reports that revealed the up-regulation of PDI genes in various plant species, including Arabidopsis, B. distachyon, and wheat [23,32,33]. The role of PDI genes in abiotic stress tolerance has also been highlighted by the higher expression levels of four PDI genes in Chinese cabbage in a cold-tolerant cultivar during exposure to cold stress. The expression of many other PDI genes was also responsive to additional environmental stresses, such as salt, drought, and ABA treatment [22].
In support of previous findings, tomato PDI genes showed differential expression in response to various stress stimuli (Figure 8a,b and Figure S6a,b). Twelve PDI genes were markedly up-regulated following heat stress (Figure 8a,b and Figure S6a,b), suggesting that elevated temperatures may trigger the chaperone activity of PDI proteins or the coordinated expression of PDI genes with other chaperone-encoding genes to reactivate heat-denatured proteins and to protect cells from thermal damage. This finding fits well with a recent report whereby transgenic rice plants overexpressing the MtPDI gene from the extremophilic bacterium Methanothermobacter thermautotrophicus exhibited robust tolerance to heat stress [72]. In addition, differential display analysis of heat-inducible genes in the leaves of a semiarid grass (Aneurolepidium chinense [Trin.] kitag), which can tolerate heat, drought, and high salinity conditions, revealed PDI genes that were induced by heat stress [73]. The presence of two active thioredoxin motifs and a putative ER localization motif in the PDI proteins encoded by the heat-induced genes SlPDI1-1, SlPDI1-3, SlPDI1-4, SlPDI2-1, SlPDI4-1, and SlPDI5-1 also suggest the active involvement of these proteins in correcting denatured proteins or protein misfolding in the ER during heat stress (Table 1 and Table 2 and Figure 8a and Figure S6a).
The possible role of PDI genes in response to salt stress was previously suggested by transcript profiling in leaves of salt-tolerant grapevine rootstocks [74]. In support of this previous report, the expression of thirteen tomato PDI genes, including SlPDI1-1, SlPDI1-3, SlPDI1-4, SlPDI2-1, SlPDI4-1, and SlPDI5-1, were also sharply elevated by salt treatment (Figure 8a and Figure S6a). Thus, we conclude that these six genes may play a role in tomato tolerance to both heat and salt stresses. Besides these six genes, SlPDI3-1, SlPDI6-1, SlPDI7-2, and SlPDI9-1 also showed increased expression in plants subjected to heat and salt stresses, underscoring their potential role in heat and salt tolerance (Figure 8a,b and Figure S6a,b).
Cold and nutrient and water deficit (NWD) stress conditions affected the expression of relatively few PDI genes, increasing transcript levels for three and five of the PDI genes, respectively (Figure 8a,b and Figure S6a,b). These results suggest the preferential function of most tomato PDI genes in adaptive responses to heat and salt stress rather than to NWD or cold. Intriguingly, the expression of both segmentally duplicated gene pairs (i.e., SlPDI11-1/SlPDI11-2 and SlPDI11-2/SlPDI11-3) in group XI increased under cold stress, indicating their redundant functions in cold tolerance. In light of their expression profiles under various abiotic stresses, SlPDI11-1 may be associated with low- and high-temperature stresses, whereas SlPDI11-2 and SlPDI11-3 may be involved in tolerance to cold and salt stresses (Figure 8a,b and Figure S6a,b).
ABA is a stress phytohormone that plays vital regulatory roles in response to heat, salinity, and drought [75,76]. The function of PDI genes in abiotic stress tolerance may also be related to ABA signaling directly, as previously hinted at by the up-regulation of many PDI genes in Chinese cabbage and B. distachyon in response to ABA treatment [22,33]. In the present study, ABA treatment induced the expression of 14 tomato PDI genes (Figure 8a,b and Figure S6a,b), which is consistent with previous reports that suggested a role for tomato PDI genes in the regulation of abiotic stress tolerance through an ABA-dependent pathway.
We identified several stress-associated cis-elements in the promoters of tomato PDI genes, consistent with the stress-responsiveness of these genes (Figure S7 and Supplementary Table S2). These observations are also consistent with previous findings of stress-related cis-acting elements in the promoter regions of stress-responsive PDI genes in Chinese cabbage and B. distachyon. The evidence provided here lays the foundation for additional functional characterization of SlPDI genes to gain a better understanding of the molecular mechanisms governed by PDI genes during abiotic stress tolerance in tomato.

5. Conclusions

PDI proteins participate in plant development and stress tolerance by ensuring the proper folding of misfolded or denatured proteins. This study represents the first comprehensive characterization of PDI genes in tomato by genome-wide bioinformatics identification and expression analysis in different organs and under various abiotic stresses. The 19 PDI genes identified here clustered into 11 groups belonging to four clades, reflecting their domain organizations. Many PDI genes (SlPDI1-1, SlPDI1-2, SlPDI1-3, SlPDI1-4, SlPDI2-3, SlPDI3-1, SlPDI4-1, SlPDI5-1, SlPDI6-1, SlPDI11-1, and SlPDI11-3) were preferentially expressed in the stem and fruits, suggesting their possible involvement in the development of these organs. The predominant expression of SlPDI2-2, SlPDI7-2 and SlPDI11-2 in floral buds and leaves suggested their role in floral and leaf development, respectively. Additionally, transcript levels of tomato PDI genes were differentially regulated by exposure to abiotic stresses and to the stress phytohormone ABA. Most PDI genes, particularly SlPDI1-1, SlPDI1-3, SlPDI1-4, SlPDI2-1, SlPDI4-1, and SlPDI5-1, were induced by various abiotic stresses and ABA treatment, suggesting that they may function in the adaptation of tomato to these stresses via an ABA-dependent pathway. Together, the information obtained in this study will provide a better understanding of the structures and functions of SlPDI genes, many of which may be potential candidate genes for developing tomato cultivars with improved fruit quality and stress tolerance via marker-assisted back crossing (MAB) or transgenesis.

Supplementary Materials

The following are available online at https://www.mdpi.com/2073-4425/12/1/23/s1, Figure S1. Schematic representation of the exon-intron organization of tomato PDI genes. Figure S2: Overview of conserved motifs of PDI proteins analysed by MEME online tool. Figure S3. Gene duplication analyses of PDI genes in the tomato genome. Figure S4. RT-qPCR analysis of the expression profiles of PDI genes in 12 organs. Figure S5. Relative expression levels of SlPDI genes based on RNA-seq data from the Tomato Genome Consortium (2012). Figure S6 (a,b). Relative expression levels of SlPDI genes in response to various abiotic stresses and phytohormone treatment. Figure S7. Predicted cis-regulatory elements in the promoters of tomato PDI genes. Table S1. Sequence identity among the 19 PDI proteins of tomato. Table S2. Putative cis-elements in tomato PDI genes identified by using PlantCARE database. Table S3. List of the PDI protein sequences in Solanum lycopersicum, Arabidopsis thaliana, Brassica rapa, Populus trichocarpa, Zea mays and Brachypodium distachyon. Table S4. Primers used for qRT-PCR assay to analyse the expression of the SlPDI genes.

Author Contributions

Conceptualization, D.J.L., S.T.K., C.K.K. and M.Y.C.; M.Y.C., D.J.L., S.T.K. and C.K.K. designed and supervised the work; Data curation, A.H.W., M.W., A.B.M.M.M.K. and U.K.N.; A.H.W., M.W. and A.B.M.M.M.K. conducted in silico analysis. A.H.W. grew plants, isolated RNA and conducted expression analysis as per the guidance of M.Y.C.; Formal analysis, A.H.W.; Investigation, A.H.W.; Methodology, A.H.W.; Supervision, M.Y.C.; Validation, A.H.W. and M.Y.C.; Writing—original draft, A.H.W. All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported by the National Research Foundation of Korea (NRF) Grant funded by the Korean government (MSIT) (no. NRF-2018R1A2B6001781).

Conflicts of Interest

The authors declare no conflict of interest exists.

References

  1. Tu, B.P.; Ho-Schleyer, S.C.; Travers, K.J.; Weissman, J.S. Biochemical basis of oxidative protein folding in the endoplasmic reticulum. Science 2000, 290, 1571–1574. [Google Scholar] [CrossRef]
  2. Wedemeyer, W.J.; Welker, E.; Narayan, M.; Scheraga, H.A. Disulfide bonds and protein folding. Biochemistry 2000, 39, 4207–4216. [Google Scholar] [CrossRef] [PubMed]
  3. Hayano, T.; Hirose, M.; Kikuchi, M. Protein disulfide isomerase. Biochim. Biophys. Acta 2004, 1699, 35–44. [Google Scholar]
  4. Hayano, T.; Hirose, M.; Kikuchi, M. Protein disulfide isomerase mutant lacking its isomerase activity accelerates folding in the cell. FEBS Lett. 1995, 377, 505–511. [Google Scholar] [PubMed] [Green Version]
  5. Venetianer, P.; Straub, F.B. The enzymatic reactivation of reduced ribonuclease. Biochim. Biophys. Acta 1963, 67, 166–168. [Google Scholar] [CrossRef]
  6. Kanai, S.; Toh, H.; Hayano, T.; Kikuchi, M. Molecular evolution of the domain structures of protein disulfide isomerases. J. Mol. Evol. 1998, 47, 200–210. [Google Scholar] [CrossRef] [PubMed]
  7. Motohashi, K.; Kondoh, A.; Stumpp, M.T.; Hisabori, T. Comprehensive survey of proteins targeted by chloroplast thioredoxin. Proc. Natl. Acad. Sci. USA 2001, 98, 11224–11229. [Google Scholar] [CrossRef] [Green Version]
  8. Jacquot, J.P.; Gelhaye, E.; Rouhier, N.; Corbier, C.; Didierjean, C.; Aubry, A. Thioredoxins and related proteins in photosynthetic organisms: Molecular basis for thiol dependent regulation. Biochem. Pharm. 2002, 64, 1065–1069. [Google Scholar] [CrossRef]
  9. Cheng, S.Y.; Gong, Q.H.; Parkison, C.; Robinson, E.A.; Appella, E.; Merlino, G.T.; Pastan, I. The nucleotide sequence of a human cellular thyroid hormone binding protein present in endoplasmic reticulum. J. Biol. Chem. 1987, 262, 11221–11227. [Google Scholar]
  10. Lahav, J.; Gofer-Dadosh, N.; Luboshitz, J.; Hess, O.; Shaklai, M. Protein disulfide isomerase mediates integrin-dependent adhesion. FEBS Lett. 2000, 475, 89–92. [Google Scholar] [CrossRef] [Green Version]
  11. Rigobello, M.P.; Donella-Deana, A.; Cesaro, L.; Bindoli, A. Distribution of protein disulphide isomerase in rat liver mitochondria. Biochem. J. 2001, 356, 567–570. [Google Scholar] [CrossRef] [PubMed]
  12. Turano, C.; Coppari, S.; Altieri, F.; Ferraro, A. Proteins of the PDI family: Unpredicted non-ER locations and functions. J. Cell Physiol. 2002, 193, 154–163. [Google Scholar] [CrossRef] [PubMed]
  13. Trebitsh, T.; Meiri, E.; Ostersetzer, O.; Adam, Z.; Danon, A. The protein disulfide isomerase-like RB60 is partitioned between stroma and thylakoids Chlamydomonas Reinhardtii chloroplasts. J. Biol. Chem. 2001, 276, 4564–4569. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  14. Ferrari, D.M.; Söling, H.D. The protein disulphide-isomerase family: Unraveling a string of folds. Biochem. J. 1999, 339, 1–10. [Google Scholar] [CrossRef] [PubMed]
  15. Markus, M.; Benezra, R. Two isoforms of protein disulfide isomerase alter the dimerization status of E2A proteins by a redox mechanism. J. Biol. Chem. 1999, 274, 1040–1049. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  16. Gruber, C.W.; Cemažar, M.; Heras, B.; Martin, J.L.; Craik, D.J. Protein disulfide isomerase: The structure of oxidative folding. Trends. Biochem. Sci. 2006, 31, 455–464. [Google Scholar] [CrossRef] [PubMed]
  17. Kemmink, J.; Darby, N.J.; Dijkstra, K.; Nilges, M.; Creighton, T.E. The folding catalyst protein disulfide isomerase is constructed of active and inactive thioredoxin modules. Curr. Biol. 1997, 7, 239–245. [Google Scholar] [CrossRef] [Green Version]
  18. Klappa, P.; Ruddock, L.W.; Darby, N.J.; Freedman, R.B. The b′ domain provides the principal peptide-binding site of protein disulfide isomerase but all domains contribute to binding of misfolded proteins. EMBO J. 1998, 17, 927–935. [Google Scholar] [CrossRef] [Green Version]
  19. Denecke, J.; De Rycke, R.; Botterman, J. Plant and mammalian sorting signals for protein retention in the endoplasmic reticulum contain a conserved epitope. EMBO J. 1992, 11, 2345–2355. [Google Scholar] [CrossRef]
  20. Lucero, H.A.; Kaminer, B. The role of calcium on the activity of ER calcistorin/protein disulfide isomerase and the significance of the Cterminal and its calcium binding. A comparison with mammalian protein-disulfide isomerase. J. Biol. Chem. 1999, 274, 3243–3251. [Google Scholar] [CrossRef] [Green Version]
  21. Houston, N.L.; Fan, C.; Schulze, J.M.; Jung, R.; Boston, R.S. Phylogenetic analyses identify 10 classes of the protein disulfide isomerase family in plants, including single-domain protein disulfide isomerase-related proteins. Plant Physiol. 2005, 137, 762–778. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  22. Kayum, M.A.; Park, J.I.; Nath, U.K.; Saha, G.; Biswas, M.K.; Kim, H.T.; Nou, I.S. Genome-wide characterization and expression profiling of PDI family gene reveals function as abiotic and biotic stress tolerance in Chinese cabbage (Brassica rapa ssp. pekinensis). BMC Genom. 2017, 18, 885. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  23. Lu, D.P.; Christopher, D.A. Endoplasmic reticulum stress activates the expression of a sub-group of protein disulfide isomerase genes and AtbZIP60 modulates the response in Arabidopsis thaliana. Mol. Genet. Genom. 2008, 280, 199–210. [Google Scholar] [CrossRef] [PubMed]
  24. Lu, D.P.; Christopher, D.A. Arabidopsis protein disulfide isomerase-5 inhibits cysteine proteases during trafficking to vacuoles before programmed cell death of the endothelium in developing seeds. Plant Cell 2008, 20, 2205–2220. [Google Scholar]
  25. Wang, H.; Boavida, L.C.; Ron, M.; McCormick, S. Truncation of a protein disulfide isomerase, PDIL2-1, delays embryo sac maturation and disrupts pollen tube guidance in Arabidopsis Thaliana. Plant Cell 2008, 20, 3300–3311. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  26. Han, X.; Wang, Y.; Liu, X.; Jiang, L.; Ren, Y.; Liu, F.; Peng, C.; Li, J.; Jin, X.; Wu, F.; et al. The failure to express a protein disulphide isomerase-like protein results in a floury endosperm and an endoplasmic reticulum stress response in rice. J. Exp. Bot. 2012, 3, 121–130. [Google Scholar] [CrossRef]
  27. Takemoto, Y.; Coughlan, S.J.; Okita, T.W.; Satoh, H.; Ogawa, M.; Kumamaru, T. The rice mutant esp2 greatly accumulates the glutelin precursor and deletes the protein disulfide isomerase. Plant Physiol. 2002, 128, 1212–1222. [Google Scholar] [CrossRef] [Green Version]
  28. D’Aloisio, E.; Paolacci, A.R.; Dhanapal, A.P.; Tanzarella, O.A.; Porceddu, E.; Ciaffi, M. The protein disulfide isomerase gene family in bread wheat (T. Aestivum L.). BMC Plant Biol. 2010, 10, 101. [Google Scholar]
  29. Li, C.P.; Larkins, B.A. Expression of protein disulfide isomerase is elevated in the endosperm of the maize floury-2 mutant. Plant Mol. Biol. 1996, 30, 873–882. [Google Scholar] [CrossRef]
  30. Iwasaki, K.; Kamauchi, S.; Wadahama, H.; Ishimoto, M.; Kawada, T.; Urade, R. Molecular cloning and characterization of soybean protein disulfide isomerase family proteins with nonclassic active center motifs. FEBS J. 2009, 276, 4130–4141. [Google Scholar] [CrossRef]
  31. Wai, A.H.; Naing, A.H.; Lee, D.J.; Kim, C.K.; Chung, M.Y. Molecular genetic approaches for enhancing stress tolerance and fruit quality of tomato. Plant Biotechnol. Rep. 2020, 14, 515–537. [Google Scholar] [CrossRef]
  32. Chauhan, H.; Khurana, N.; Tyagi, A.K.; Khurana, J.P.; Khurana, P. Identification and characterization of high temperature stress responsive genes in bread wheat (Triticum aestivum L.) and their regulation at various stages of development. Plant Mol. Biol. 2011, 75, 35–51. [Google Scholar] [CrossRef] [PubMed]
  33. Zhu, C.; Luo, N.; He, M.; Chen, G.; Zhu, J.; Yin, G.; Li, X.; Hu, Y.; Li, J.; Yan, Y. Molecular characterization and expression profiling of the protein disulfide Isomerase gene family in Brachypodiumdistachyon L. PLoS ONE 2014, 9, 94704. [Google Scholar]
  34. Faheem, M.; Li, Y.; Arshad, M.; Jiangyue, C.; Jia, Z.; Wang, Z.; Xiao, J.; Wang, H.; Cao, A.; Xing, L.; et al. A disulphide isomerase gene (PDI-V) from Haynaldia villosa contributes to powdery mildew resistance in common wheat. Sci. Rep. 2016, 6, 1–14. [Google Scholar] [CrossRef] [Green Version]
  35. Zhang, Z.; Liu, X.; Li, R.; Yuan, L.; Dai, Y.; Wang, X. Identification and functional analysis of a protein disulfide isomerase (AtPDI1) in Arabidopsis thaliana. Front. Plant Sci. 2018, 9, 913. [Google Scholar] [CrossRef]
  36. Poole, R.L. The TAIR database. Methods Mol. Biol. 2007, 406, 179–212. [Google Scholar]
  37. Mueller, L.A.; Solow, T.H.; Taylor, N.; Skwarecki, B.; Buels, R.; Binns, J.; Lin, C.; Wright, M.H.; Ahrens, R.; Wang, Y.; et al. The SOL genomics network. A comparative resource for Solanaceae biology and beyond. Plant Physiol. 2005, 138, 1310–1317. [Google Scholar] [CrossRef] [Green Version]
  38. Marchler-Bauer, A.; Derbyshire, M.K.; Gonzales, N.R.; Lu, S.; Chitsaz, F.; Geer, L.Y.; Geer, R.C.; He, J.; Gwadz, M.; Hurwitz, D.I.; et al. CDD: NCBI’s conserved domain database. Nucleic Acids Res. 2015, 43, D222–D226. [Google Scholar] [CrossRef] [Green Version]
  39. Letunic, I.; Bork, P. 20 years of the SMART protein domain annotation resource. Nucleic Acids Res. 2018, 46, D493–D496. [Google Scholar] [CrossRef]
  40. Gasteiger, E.; Hoogland, C.; Gattiker, A.; Wilkins, M.R.; Appel, R.D.; Bairoch, A. Protein identification and analysis tools on the ExPASy server. In The Proteomics Protocols Handbook; Humana Press: Totowa, NJ, USA, 2005; pp. 571–607. [Google Scholar]
  41. Palmer, E.; Freeman, T. Investigation into the use of C-and N-terminal GFP fusion proteins for subcellular localization studies using reverse transfection microarrays. Comp. Funct. Genom. 2004, 5, 342–353. [Google Scholar] [CrossRef] [Green Version]
  42. Sievers, F.; Wilm, A.; Dineen, D.; Gibson, T.J.; Karplus, K.; Li, W.; Lopez, R.; McWilliam, H.; Remmert, M.; Söding, J.; et al. Fast, scalable generation of high-quality protein multiple sequence alignments using Clustal Omega. Mol. Syst. Biol. 2011, 7, 539. [Google Scholar] [CrossRef] [PubMed]
  43. Guo, A.Y.; Zhu, Q.H.; Chen, X.; Luo, J.C. GSDS: A gene structure display server. Yi Chuan 2007, 29, 1023–1026. [Google Scholar] [CrossRef] [PubMed]
  44. Lescot, M.; Déhais, P.; Thijs, G.; Marchal, K.; Moreau, Y.; Van de Peer, Y.; Rouzé, P.; Rombauts, S. PlantCARE, a database of plant cis-acting regulatory elements and a portal to tools for in silico analysis of promoter sequences. Nucleic Acids Res. 2002, 30, 325–327. [Google Scholar] [CrossRef] [PubMed]
  45. Tamura, K.; Stecher, G.; Peterson, D.; Filipski, A.; Kumar, S. MEGA6: Molecular evolutionary genetics analysis version 6.0. Mol. Biol. Evol. 2013, 30, 2725–2729. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  46. Bailey, T.L.; Boden, M.; Buske, F.A.; Frith, M.; Grant, C.E.; Clementi, L.; Ren, J.; Li, W.W.; Noble, W.S. MEME SUITE: Tools for motif discovery and searching. Nucleic Acids Res. 2009, 37, W202–W208. [Google Scholar] [CrossRef] [PubMed]
  47. Jiangtao, C.; Yingzhen, K.; Qian, W.; Yuhe, S.; Daping, G.; Jing, L.; Guanshan, L. MapGene2Chrom, a tool to draw gene physical map based on Perl and SVG languages. Zhongguo Yi Chuan Xue Hui Bian Ji 2015, 37, 91–97. [Google Scholar]
  48. Chen, C.; Chen, H.; Zhang, Y.; Thomas, H.R.; Frank, M.H.; He, Y.; Xia, R. TBtools: An integrative toolkit developed for interactive analyses of big biological data. Mol. Plant 2020, 13, 1194–1202. [Google Scholar] [CrossRef]
  49. Kong, X.; Lv, W.; Jiang, S.; Zhang, D.; Cai, G.; Pan, J.; Li, D. Genomewide identification and expression analysis of calcium-dependent protein kinase in maize. BMC Genom. 2013, 14, 1–15. [Google Scholar] [CrossRef] [Green Version]
  50. Nei, M.; Gojobori, T. Simple methods for estimating the numbers of synonymous and nonsynonymous nucleotide substitutions. Mol. Biol. Evol. 1986, 3, 418–426. [Google Scholar]
  51. Nekrutenko, A.; Makova, K.D.; Li, W.H. The KA/KS ratio test for assessing the protein-coding potential of genomic regions: An empirical and simulation study. Genome Res. 2002, 12, 198–202. [Google Scholar] [CrossRef] [Green Version]
  52. Koch, M.A.; Haubold, B.; Mitchell-Olds, T. Comparative evolutionary analysis of chalcone synthase and alcohol dehydrogenase loci in Arabidopsis, Arabis, and related genera (Brassicaceae). Mol. Biol. Evol. 2000, 17, 1483–1498. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  53. Goodstein, D.M.; Shu, S.; Howson, R.; Neupane, R.; Hayes, R.D.; Fazo, J.; Mitros, T.; Dirks, W.; Hellsten, U.; Putnam, N.; et al. Phytozome: A comparative platform for green plant genomics. Nucleic Acids Res. 2012, 40, D1178–D1186. [Google Scholar] [CrossRef] [PubMed]
  54. Khatun, K.; Nath, U.K.; Robin, A.H.K.; Park, J.I.; Lee, D.J.; Kim, M.B.; Kim, C.K.; Lim, K.B.; Nou, I.S.; Chung, M.Y. Genome-wide analysis and expression profiling of zinc finger homeodomain (ZHD) family genes reveal likely roles in organ development and stress responses in tomato. BMC Genom. 2017, 18, 695. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  55. Khatun, K.; Robin, A.H.K.; Park, J.I.; Nath, U.K.; Kim, C.K.; Lim, K.B.; Nou, I.S.; Chung, M.Y. Molecular characterization and expression profiling of tomato GRF transcription factor family genes in response to abiotic stresses and phytohormones. Int. J. Mol. Sci. 2017, 18, 1056. [Google Scholar] [CrossRef] [Green Version]
  56. Khatun, K.; Robin, A.H.K.; Park, J.I.; Kim, C.K.; Lim, K.B.; Kim, M.B.; Lee, D.J.; Nou, I.S.; Chung, M.Y. Genome-wide identification, characterization and expression profiling of ADF family genes in Solanum lycopersicum L. Genes 2016, 7, 79. [Google Scholar] [CrossRef] [Green Version]
  57. Khatun, K.; Robin, A.H.K.; Park, J.I.; Ahmed, N.U.; Kim, C.K.; Lim, K.B.; Kim, M.B.; Lee, D.J.; Nou, I.S.; Chung, M.Y. Genome-wide identification, characterization and expression profiling of LIM family genes in Solanum lycopersicum L. Plant Physiol. Biochem. 2016, 108, 177–190. [Google Scholar] [CrossRef]
  58. Khatun, K.; Nath, U.K.; Park, J.I.; Kim, C.K.; Nou, I.S.; Chung, M.Y. Expression Profiling of the CSDP Transcription Factor Gene Family Points to Roles in Organ Development and Abiotic Stress Response in Tomato (Solanum lycopersicum L.). Plant Mol. Biol. Rep. 2018, 36, 273–283. [Google Scholar] [CrossRef]
  59. Untergasser, A.; Cutcutache, I.; Koressaar, T.; Ye, J.; Faircloth, B.C.; Remm, M.; Rozen, S.G. Primer3—new capabilities and interfaces. Nucleic Acids Res. 2012, 40, e115. [Google Scholar] [CrossRef] [Green Version]
  60. Verma, J.K.; Wardhan, V.; Singh, D.; Chakraborty, S.; Chakraborty, N. Genome-wide identification of the Alba gene family in plants and stress-responsive expression of the rice Alba genes. Genes 2018, 9, 183. [Google Scholar] [CrossRef] [Green Version]
  61. Balestrini, R.; Gómez-Ariza, J.; Lanfranco, L.; Bonfante, P. Laser microdissection reveals that transcripts for five plant and one fungal phosphate transporter genes are contemporaneously present in arbusculated cells. Mol. Plant Microbe Interact. 2007, 20, 1055–1062. [Google Scholar] [CrossRef] [Green Version]
  62. Schmittgen, T.D.; Livak, K.J. Analyzing real-time PCR data by the comparative CT method. Nat. Protoc. 2008, 3, 1101–1108. [Google Scholar] [CrossRef] [PubMed]
  63. Tomato Genome Consortium. The tomato genome sequence provides insights into fleshy fruit evolution. Nature 2012, 485, 635. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  64. Cannon, S.B.; Mitra, A.; Baumgarten, A.; Young, N.D.; May, G. The roles of segmental and tandem gene duplication in the evolution of large gene families in Arabidopsis thaliana. BMC Plant Biol. 2004, 4, 10. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  65. Li, Z.; Jiang, H.; Zhou, L.; Deng, L.; Lin, Y.; Peng, X.; Yan, H.; Cheng, B. Molecular evolution of the HD-ZIP I gene family in legume genomes. Gene 2014, 533, 218–228. [Google Scholar] [CrossRef] [PubMed]
  66. Xu, G.; Guo, C.; Shan, H.; Kong, H. Divergence of duplicate genes in exon–intron structure. Proc. Natl. Acad. Sci. USA 2012, 109, 1187–1192. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  67. Koutinas, N.; Pepelyankov, G.; Lichev, V. Flower induction and flower bud development in apple and sweet cherry. Biotechnol. Biotechnol. Equip. 2010, 24, 1549–1558. [Google Scholar] [CrossRef]
  68. Giovannoni, J.J. Fruit ripening mutants yield insights into ripening control. Curr. Opin. Plant Biol. 2007, 10, 283–289. [Google Scholar] [CrossRef]
  69. Lemaire-Chamley, M.; Petit, J.; Garcia, V.; Just, D.; Baldet, P.; Germain, V.; Rothan, C. Changes in transcriptional profiles are associated with early fruit tissue specialization in tomato. Plant Physiol. 2005, 139, 750–769. [Google Scholar] [CrossRef] [Green Version]
  70. Liu, J.X.; Howell, S.H. Endoplasmic reticulum protein quality control and its relationship to environmental stress responses in plants. Plant Cell 2010, 22, 2930–2942. [Google Scholar] [CrossRef] [Green Version]
  71. Wang, W.; Vinocur, B.; Shoseyov, O.; Altman, A. Role of plant heat-shock proteins and molecular chaperones in the abiotic stress response. Trends Plant Sci. 2004, 9, 244–252. [Google Scholar] [CrossRef]
  72. Wang, X.; Chen, J.; Liu, C.; Luo, J.; Yan, X.; Ai, A.; Cai, Y.; Xie, H.; Ding, X.; Peng, X. Over-expression of a protein disulfide isomerase gene from Methanothermobacter thermautotrophicus, enhances heat stress tolerance in rice. Gene 2019, 684, 124–130. [Google Scholar] [CrossRef] [PubMed]
  73. Shi, W.; Ueda, A.; Ozaki, K.; Inada, M.; Takamatsu, A.; Takahe, T. Analysis of heat-stress responsive genes in Aneurolepidium chinense leaves by differential display. Plant Prod. Sci. 2002, 5, 229–235. [Google Scholar] [CrossRef]
  74. Çakır Aydemir, B.; Yüksel Özmen, C.; Kibar, U.; Mutaf, F.; Büyük, P.B.; Bakır, M.; Ergül, A. Salt stress induces endoplasmic reticulum stress-responsive genes in a grapevine rootstock. PLoS ONE 2020, 15, e0236424. [Google Scholar] [CrossRef] [PubMed]
  75. Huang, Y.C.; Niu, C.Y.; Yang, C.R.; Jinn, T.L. The heat stress factor HSFA6b connects ABA signaling and ABA-mediated heat responses. Plant Physiol. 2016, 172, 1182–1199. [Google Scholar] [CrossRef] [PubMed]
  76. Suzuki, N.; Bassil, E.; Hamilton, J.S.; Inupakutika, M.A.; Zandalinas, S.I.; Tripathy, D.; Luo, Y.; Dion, E.; Fukui, G.; Kumazaki, A.; et al. ABA is required for plant acclimation to a combination of salt and heat stress. PLoS ONE 2016, 11, e0147625. [Google Scholar] [CrossRef] [Green Version]
Genes 12 00023 g001 550
Figure 1. Phylogenetic relationships of protein disulfide isomerase (PDI) proteins identified in tomato (Solanum lycopersicum), poplar (P. trichocarpa), field mustard (Brassica rapa), Arabidopsis (A. thaliana), purple false brome (B. distachyon L.), and maize (Z. mays). The phylogenetic tree was constructed using MEGA6 software by the neighbor-joining method with 1000 bootstrap replicates based on 107 full-length PDI protein sequences from the above-mentioned plant species. The proteins were clustered into 11 groups (I–XI) belonging to four clades. The amino acid sequences used in the phylogenetic analysis are listed in Supplementary Table S3, along with their accession numbers.
Figure 1. Phylogenetic relationships of protein disulfide isomerase (PDI) proteins identified in tomato (Solanum lycopersicum), poplar (P. trichocarpa), field mustard (Brassica rapa), Arabidopsis (A. thaliana), purple false brome (B. distachyon L.), and maize (Z. mays). The phylogenetic tree was constructed using MEGA6 software by the neighbor-joining method with 1000 bootstrap replicates based on 107 full-length PDI protein sequences from the above-mentioned plant species. The proteins were clustered into 11 groups (I–XI) belonging to four clades. The amino acid sequences used in the phylogenetic analysis are listed in Supplementary Table S3, along with their accession numbers.
Genes 12 00023 g001
Genes 12 00023 g002 550
Figure 2. Schematic representation of the domain composition of tomato PDI proteins. The putative signal peptides (SP), the a and b thioredoxin-like domains, the N-terminal calcium binding domain similar to calsequestrin, the D domain (Erp29c), the ERGIC_N domain, the C_ERV (COPII-coated ERV) domain, the Evr1_Air domain, the PAPS_reduct domain, and the transmembrane domain (TM) are displayed. The start and end boundaries of the a, b, and b’ domains, where two of the domain regions overlap, are marked by blue, green, and black hooks, respectively.
Figure 2. Schematic representation of the domain composition of tomato PDI proteins. The putative signal peptides (SP), the a and b thioredoxin-like domains, the N-terminal calcium binding domain similar to calsequestrin, the D domain (Erp29c), the ERGIC_N domain, the C_ERV (COPII-coated ERV) domain, the Evr1_Air domain, the PAPS_reduct domain, and the transmembrane domain (TM) are displayed. The start and end boundaries of the a, b, and b’ domains, where two of the domain regions overlap, are marked by blue, green, and black hooks, respectively.
Genes 12 00023 g002
Genes 12 00023 g003 550
Figure 3. Multiple sequence alignment of a-type domains of tomato PDI proteins alongside those of a classic human PDI. The thioredoxin-like domains in tomato PDIs were annotated by the SMART webtool, and aligned using Clustal Omega. The elements of the secondary structure are indicated by blue (α-helices) and black (β-sheets) bars above the alignment. The red arrows indicate the Glu-Lys charged pair located near the active site, a green arrow indicates the conserved Arg (R) between β5 and α4 of each catalytic domain, and a blue arrow indicates the cis Pro (P) near each active site. The –CXXC– catalytic sites are marked by a green box.
Figure 3. Multiple sequence alignment of a-type domains of tomato PDI proteins alongside those of a classic human PDI. The thioredoxin-like domains in tomato PDIs were annotated by the SMART webtool, and aligned using Clustal Omega. The elements of the secondary structure are indicated by blue (α-helices) and black (β-sheets) bars above the alignment. The red arrows indicate the Glu-Lys charged pair located near the active site, a green arrow indicates the conserved Arg (R) between β5 and α4 of each catalytic domain, and a blue arrow indicates the cis Pro (P) near each active site. The –CXXC– catalytic sites are marked by a green box.
Genes 12 00023 g003
Genes 12 00023 g004 550
Figure 4. Schematic representation of 10 conserved motifs in PDI proteins from tomato, Arabidopsis, and maize as analyzed by Multiple Em for Motif Elicitation (MEME) software. The a and a’ domains homologous to the thioredoxin (TRX) domains harbor three types of motifs (1, 2, and 3). The –CXXC– catalytic tetrad is included in Motifs 1 and 2, and Motif 3 is closely linked with Motifs 1 and 2. Motif 3 contains the cis Pro (P) near the active site that is important for the catalytic activity of thioredoxin. Detailed sequence logos of the motifs are shown in Figure S5.
Figure 4. Schematic representation of 10 conserved motifs in PDI proteins from tomato, Arabidopsis, and maize as analyzed by Multiple Em for Motif Elicitation (MEME) software. The a and a’ domains homologous to the thioredoxin (TRX) domains harbor three types of motifs (1, 2, and 3). The –CXXC– catalytic tetrad is included in Motifs 1 and 2, and Motif 3 is closely linked with Motifs 1 and 2. Motif 3 contains the cis Pro (P) near the active site that is important for the catalytic activity of thioredoxin. Detailed sequence logos of the motifs are shown in Figure S5.
Genes 12 00023 g004
Genes 12 00023 g005 550
Figure 5. Distribution of the 19 PDI genes on the 12 tomato chromosomes. The duplicated genes in the genome are connected by the black dotted lines. Chromosome numbers are indicated at the top of each chromosome. Chromosome sizes and gene locations were estimated using the scale in Megabase pairs (Mbp) to the left of the figure.
Figure 5. Distribution of the 19 PDI genes on the 12 tomato chromosomes. The duplicated genes in the genome are connected by the black dotted lines. Chromosome numbers are indicated at the top of each chromosome. Chromosome sizes and gene locations were estimated using the scale in Megabase pairs (Mbp) to the left of the figure.
Genes 12 00023 g005
Genes 12 00023 g006 550
Figure 6. Microsynteny analysis of PDI genes among tomato, Arabidopsis, and rice. The chromosomes of the three species are represented in different colors: tomato, blue; Arabidopsis, green; and maize, pink. All chromosomes are drawn to scale (in Mbp).
Figure 6. Microsynteny analysis of PDI genes among tomato, Arabidopsis, and rice. The chromosomes of the three species are represented in different colors: tomato, blue; Arabidopsis, green; and maize, pink. All chromosomes are drawn to scale (in Mbp).
Genes 12 00023 g006
Genes 12 00023 g007 550
Figure 7. Quantitative real-time polymerase chain reaction (RT-qPCR) analysis of the expression profiles of PDI genes in 12 organs: leaves, roots, stems, flower buds (FB), full blooming flowers (FF), senescent flowers (SF), 1 cm fruits, immature fruits (IM), mature green fruits (MG), Breaker fruits (B), fruits 3 days after breaker stage (B3), and fruits 7 days after breaker stage (B7). Le18S (18S rRNA) expression levels were used as a reference. Error bars represent standard errors of the means of three replicates. The asterisk marks denote the significant difference as determined by t-test (* p-value ≤ 0.05, ** p-value ≤ 0.01 and *** p-value ≤ 0.001).
Figure 7. Quantitative real-time polymerase chain reaction (RT-qPCR) analysis of the expression profiles of PDI genes in 12 organs: leaves, roots, stems, flower buds (FB), full blooming flowers (FF), senescent flowers (SF), 1 cm fruits, immature fruits (IM), mature green fruits (MG), Breaker fruits (B), fruits 3 days after breaker stage (B3), and fruits 7 days after breaker stage (B7). Le18S (18S rRNA) expression levels were used as a reference. Error bars represent standard errors of the means of three replicates. The asterisk marks denote the significant difference as determined by t-test (* p-value ≤ 0.05, ** p-value ≤ 0.01 and *** p-value ≤ 0.001).
Genes 12 00023 g007
Genes 12 00023 g008a 550Genes 12 00023 g008b 550
Figure 8. (a,b). Relative expression levels of SlPDI genes in response to various abiotic stresses, viz., heat stress, salt stress, nutrient and water deficit (NWD) stress and cold stress, and phytohormone treatment. Error bars indicate the standard errors of the means of three replicates. *, ** and *** represent the significant difference at p-value ≤ 0.05, ≤ 0.01 and ≤ 0.001, respectively.
Figure 8. (a,b). Relative expression levels of SlPDI genes in response to various abiotic stresses, viz., heat stress, salt stress, nutrient and water deficit (NWD) stress and cold stress, and phytohormone treatment. Error bars indicate the standard errors of the means of three replicates. *, ** and *** represent the significant difference at p-value ≤ 0.05, ≤ 0.01 and ≤ 0.001, respectively.
Genes 12 00023 g008aGenes 12 00023 g008b
Table
Table 1. List of identified tomato PDI gene family members with their corresponding encoded protein information.
Table 1. List of identified tomato PDI gene family members with their corresponding encoded protein information.
Gene NameLocus NameORF (bp)Chrom.
(Strand)		No. of IntronsProteinsSubcellular
Localization
Length (aa)MW (kDa)PI
SlPDI1-1Solyc06g0602901557C06 (−strand)943858.115.02Endoplasmic reticulum
SlPDI1-2Solyc05g0187001185 C05 (−strand)1049644.475.10Endoplasmic reticulum
SlPDI1-3Solyc06g0059401500C06 (−strand)949955.745.18Endoplasmic reticulum
SlPDI1-4Solyc05g0564001590 C05 (+strand)953759.014.96Endoplasmic reticulum
SlPDI2-1Solyc04g0494501692C04 (+strand)1156363.104.65Endoplasmic reticulum
SlPDI2-2Solyc06g0752101644C06 (+strand)1155461.664.91Endoplasmic reticulum
SlPDI2-3Solyc11g0694001743C11 (−strand)1158064.584.49Endoplasmic reticulum
SlPDI3-1Solyc03g1207201617C03 (+strand)1153860.684.81Endoplasmic reticulum
SlPDI4-1Solyc01g1003201080 C01 (−strand)1035939.455.43Endoplasmic reticulum
SlPDI5-1Solyc07g0494501299C07 (−strand)843247.075.58Extracellular
SlPDI6-1Solyc11g069690450C11 (+strand)312516.924.83Extracellular
SlPDI7-1Solyc06g0653201329 C06 (+strand)432649.695.20Plasma membrane
SlPDI7-2Solyc11g0199201308C11 (+strand)443549.305.09Plasma membrane
SlPDI8-1Solyc07g0642501446C07 (−strand)1448153.986.62Plasma membrane
SlPDI9-1Solyc04g0076101545C04 (−strand)1151457.667.76Extracellular
SlPDI10-1Solyc04g074240972 C04 (−strand)332335.568.74Plasma membrane
SlPDI11-1Solyc03g031620885C03 (−strand)445650.826.78Chloroplast
SlPDI11-2Solyc02g0806401044C02 (+strand)346148.206.08Chloroplast
SlPDI11-3Solyc02g032860660C02 (+strand)445650.706.40Chloroplast
Abbreviations: ORF, open reading frame; bp, base pair; aa, amino acid; MW, molecular weight; kDa, kilo Dalton; PI, iso-electric point.
Table
Table 2. Structural and functional characteristics of tomato PDI proteins.
Table 2. Structural and functional characteristics of tomato PDI proteins.
NameSignal PeptideTrans-MembraneDomain OrganizationActive Site MotifConserved Charge Pair SequenceConserved ArginineC-Terminal Signal
SlPDI1-1NoNoa-b-a’CGHC, CGHCE56-K90, E399-K432R130-RCYC
SlPDI1-21-17Noa-b-a’CGYC, CRYCQ44-K78, E387-K420R118, R457-KDEL
SlPDI1-31-23Noa-b-a’CGHC, CGHCE50-K84, E393-K426R124-FRGL
SlPDI1-41-21512-534a-b-a’-tCGHC, CGHCE49-K83, E392-K425R123, R462-ISCN
SlPDI2-11-24Noa-b-b’-a’CGHC, CGHCE105-K137, E444-K477R173, R515-KDEL
SlPDI2-21-27Noa-b-a’NGYC, CRQCE102-K134, E443-K476R170, P514-RDEL
SlPDI2-31-26Noa-b-b’-a’CGHC, CGHCE121-K153, E460-K493R189, R531-KDEL
SlPDI3-11-29Noa-c-b-a’CARS, CITCL103-K137, E444-R477F173, S514-RDEL
SlPDI4-1NoNoa°-a-DCGHC, CGHCE47-K80, E166-N199R118, R237-ATFA
SlPDI5-11-22Noa°-a-bCGHC, CGHCE52-A83, E180-H211R120, R249-KDEL
SlPDI6-1NoNoaCKHCK51-Q84R121-TERY
SlPDI7-1NoNoa-c-bCGHCD18-K52R88-TETY
SlPDI7-21-25378-400a-b-tCGHCD57-K91R127-EKID
SlPDI8-1NoNoe-a-fCYWSN164-K203R249-GKNF
SlPDI9-11-22478-500a-g-tCPACE71-R109Q147-RSWN
SlPDI10-11-22NoaCPFSL92-I123R159-SSTH
SlPDI11-1NoNoh-a’CRFCV370-R404R443-NALR
SlPDI11-2NoNoh-a’CQFCV375-R409R448-NALR
SlPDI11-3NoNoh-a’CQFCV370-R404R443-NALR
Table
Table 3. Estimated Ka/Ks ratios of the segmentally duplicated SlPDI genes with their divergence time in tomato.
Table 3. Estimated Ka/Ks ratios of the segmentally duplicated SlPDI genes with their divergence time in tomato.
Duplicated Gene PairsKaKsKa/KsDuplication TypeTypes of SelectionTime (MYA)
SlPDI2-2/SlPDI2-30.1971660.8681920.227099SegmentalPurifying selection28.94
SlPDI11-1/SlPDI11-20.0952690.625440.152323SegmentalPurifying selection20.85
SlPDI11-2/SlPDI11-30.0720360.6287260.114574SegmentalPurifying selection20.96
Ks the number of synonymous substitutions per synonymous site, Ka the number of non-synonymous substitutions per nonsynonymous site, MYA million years ago.
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Share and Cite

MDPI and ACS Style

Wai, A.H.; Waseem, M.; Khan, A.B.M.M.M.; Nath, U.K.; Lee, D.J.; Kim, S.T.; Kim, C.K.; Chung, M.Y. Genome-Wide Identification and Expression Profiling of the PDI Gene Family Reveals Their Probable Involvement in Abiotic Stress Tolerance in Tomato (Solanum lycopersicum L.). Genes 2021, 12, 23. https://doi.org/10.3390/genes12010023

AMA Style

Wai AH, Waseem M, Khan ABMMM, Nath UK, Lee DJ, Kim ST, Kim CK, Chung MY. Genome-Wide Identification and Expression Profiling of the PDI Gene Family Reveals Their Probable Involvement in Abiotic Stress Tolerance in Tomato (Solanum lycopersicum L.). Genes. 2021; 12(1):23. https://doi.org/10.3390/genes12010023

Chicago/Turabian Style

Wai, Antt Htet, Muhammad Waseem, A B M Mahbub Morshed Khan, Ujjal Kumar Nath, Do Jin Lee, Sang Tae Kim, Chang Kil Kim, and Mi Young Chung. 2021. "Genome-Wide Identification and Expression Profiling of the PDI Gene Family Reveals Their Probable Involvement in Abiotic Stress Tolerance in Tomato (Solanum lycopersicum L.)" Genes 12, no. 1: 23. https://doi.org/10.3390/genes12010023

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop