Abstract
KNOXs, a type of homeobox genes that encode atypical homeobox proteins, play an essential role in the regulation of growth and development, hormonal response, and abiotic stress in plants. However, the KNOX gene family has not been explored in sweet potato. In this study, through sequence alignment, genomic structure analysis, and phylogenetic characterization, 17, 12 and 11 KNOXs in sweet potato (I. batatas, 2n = 6x = 90) and its two diploid relatives I. trifida (2n = 2x = 30) and I. triloba (2n = 2x = 30) were identified. The protein physicochemical properties, chromosome localization, phylogenetic relationships, gene structure, protein interaction network, cis-elements of promoters, tissue-specific expression and expression patterns under hormone treatment and abiotic stresses of these 40 KNOX genes were systematically studied. IbKNOX4, -5, and − 6 were highly expressed in the leaves of the high-yield varieties Longshu9 and Xushu18. IbKNOX3 and IbKNOX8 in Class I were upregulated in initial storage roots compared to fibrous roots. IbKNOXs in Class M were specifically expressed in the stem tip and hardly expressed in other tissues. Moreover, IbKNOX2 and − 6, and their homologous genes were induced by PEG/mannitol and NaCl treatments. The results showed that KNOXs were involved in regulating growth and development, hormone crosstalk and abiotic stress responses between sweet potato and its two diploid relatives. This study provides a comparison of these KNOX genes in sweet potato and its two diploid relatives and a theoretical basis for functional studies.
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Background
The homeobox (HB) genes encode transcription factors (TFs) that contain a homeobox domain, also known as a homeodomain (HD), which play an important role in plant growth and development [1]. The HB genes have been categorized into 14 classes based on their structural characteristics, including HD-ZIP I, HD-ZIP II, HD-ZIP III, HD-ZIP IV, PLINC, WOX, DDT, PHD, NDX, LD, PINTOX, SAWADEE, BEL, and KNOX [2]. The KNOX (KNOTTED1-like homeobox) gene family plays an important regulatory role in plant morphogenesis, pattern formation, and other processes. With the continuous development and progress of plant genomics, the first KNOX gene was discovered in maize [3]. Genome-wide analysis led to the identification of KNOX genes in various plants, such as Arabidopsis [4], rice [5], maize [6], wheat [7], cotton [8], tobacco [9], tomato [2], soybean [10], radish [11], potato [12], cassava [13] and Phyllostachys edulis [14]. KNOX proteins generally contain four characteristic domains: KNOX1, KNOX2, ELK and Homeobox-KN [4]. The KNOX1 and KNOX2 domains of the N-terminus are connected by a poorly conserved splice sequence to form the MEINOX domain, which is followed by the ELK domain and the Homeobox-KN domain [15]. Based on their structural characteristics, phylogenetic relationships and expression patterns, KNOXs can be divided into three Classes: Class I, Class II and Class M [16].
In Arabidopsis, Class I KNOX genes are mainly expressed in the apical meristem and are involved in the regulation of plant hormones and plant multiorgan morphogenesis [17,18,19]. In tobacco, NtKNATM1 might be positively regulated by auxin and participate in the development of apical and lateral tissues [20]. TaKNOX1s in wheat was a positive regulator of wheat grain size and grain weight and was also related to the regulation of wheat plant type [21]. The rice KNOX II protein HOS59 negatively regulated rice glial cell length, rice grain size, and plant structure [22]. Moreover, the KNOX gene family plays an important role in the response to abiotic stress [7, 8]. TaKNOX11-A transgenic plants exhibited enhanced tolerance to drought and salt stress [23]. The Class KNOX I gene PagKNAT2/6b mediated changes in plant architecture in response to drought by downregulating GA20ox1 in Populus alba × P. glandulosa [24]. Overexpression of STM in Arabidopsis resulted in enhanced tolerance to drought stress [25]. In sweet potato, KNOX I genes had been reported to be involved in the development of sweet potato storage roots and regulate the level of cytokinin in storage roots [26]. Ibkn1- Ibkn3 were highly expressed in storage roots than in fibrous roots [27]. However, the mechanism of Ibkn1- Ibkn3 and the expression patterns of other KNOXs in sweet potato are still unknown.
Sweet potato (Ipomoea batatas (L.) Lam, 2n = B1B1B2B2B2B2 = 6x = 90) is an important food crop, as well as a high-quality raw material for feed and industry [28]. Due to its robust adaptability, extensive planting range, high yield and high nutritional value, sweet potato has a long history of cultivation in China [29]. However, with limited land availability, sweet potato cultivation constitutes merely approximately 3% of the total cultivated land area, significantly less than wheat, corn, and rice [30]. Soil salinization caused by industrial pollution and abuse of fertilizers and pesticides [30], as well as extreme weather, have also impacted the yield and quality of sweet potato [31]. With the completion of genome sequencing and assembly of hexaploid sweet potato Taizhong 6 and its two diploid relatives, Ipomoea trifida, NCNSP0306 (2n = 2x = 30) and Ipomoea triloba, NCNSP0323 (2n = 2x = 30) [32, 33], it is feasible to analyze and identify essential gene families at the whole genome level of sweet potato to improve the yield and quality of sweet potato.
In this study, the KNOX gene family members of sweet potato and its two diploid relatives were identified. They were classified into three Classes. Through comprehensive analysis of protein physicochemical properties, chromosome localization, phylogenetic relationships, gene structure, cis-elements of promoters, protein interaction networks and expression patterns in different tissues, hormones, and abiotic stresses by RNA-seq, we obtained a preliminary understanding of the evolution and function of KNOXs, which provided a theoretical basis for enhancing stress resistance, yield and quality in sweet potato.
Materials and methods
Plant materials
Sweet potato (I. batatas) and its two diploid relatives (I. trifida and I. triloba) were used in this study. The drought/salt-sensitive sweet potato variety Lizixiang (lzx), the salt-tolerent sweet potato line ND98 [34], the drought-tolerant sweet potato line Xushu55-2 (Xu55-2) [35] and two diploid relatives were used to analysis the expression pattern of KNOXs in abiotic stresses. Two diploid relatives and the sweet potato cultivar Xushu22 (Xu22) [36], Longshu9 with high yield and early maturity (Long9) [37], Xushu18 with high yield (Xu18) [38] were used to analysis the expression pattern of KNOXs in different tissues and periods.
Identification of KNOXs
The whole-genome sequences of I. batatas, I. trifida, and I. triloba were downloaded from the Ipomoea Genome Hub (https://ipomoea-genome.org/) and Sweetpotato Genomics Resource (http://sweetpotato.plantbiology.msu.edu/). To ensure the accuracy of the identification results, we integrated three screening methods. First, we used all AtKNATs from the Arabidopsis genome database (https://www.arabidopsis.org/) as queries to predict KNOXs through the BLAST algorithm (BLASTP, E value ≤ 1 × 10− 5) [16]. Next, potential KNOXs were identified by HMMER 3.0 software through hidden Markov Model profiles (hmmsearch, E value ≤ 1 × 10− 5) of the KNOX1 domain (pfam03790) and KNOX2 domain (pfam03791), which were extracted from the Pfam databases (http://pfam.xfam.org/) [39]. Finally, all putative KNOXs were verified using CD-search (https://www.ncbi.nlm.nih.gov/Structure/cdd/wrpsb.cgi) [40,41,42].
Protein property prediction of KNOXs
The molecular weight, theoretical isoelectric point, instability index and hydrophilicity of IbKNOX proteins were calculated by ExPASy (https://www.expasy.org/) [43], and the subcellular localization was predicted by PSORT (https://wolfpsort.hgc.jp/).
Chromosomal distribution of KNOXs
The positional information on chromosomes of KNOXs in sweet potato and their two diploid relatives were obtained from Ipomoea Genome Hub (https://ipomoea-genome.org/) and Sweetpotato Genomics Resource (http://sweetpotato.plantbiology.msu.edu/). The visualization was generated by TBtools software (v.1.098775) [44].
Phylogenetic analysis of KNOXs
First, MAFFT version 7 (https://mafft.cbrc.jp/alignment/server/) [45, 46] was used to align the protein sequences of Arabidopsis, I. batatas, I. trifida and I. triloba. Then, we selected the maximum likelihood method, AIC model and a bootstrap value of 500 to construct a phylogenetic tree by PhyML 3.0 (http://www.atgc-montpellier.fr/phyml/) [47]. The evolutionary trees of sweet potato and their two diploid relatives were also constructed in this way. Finally, the phylogenetic tree was visualized on Evolview (http://www.evolgenius.info/evolview/) [48,49,50].
Conserved domains and exon‒intron structure
The structural domain information of each protein was obtained from NCBI-CDD (https://www.ncbi.nlm.nih.gov/Structure/cdd/wrpsb.cgi) [40,41,42], and the exon‒intron structures of KNOX genes were obtained by GSDS 2.0 (http://gsds.gao-lab.org/) [51]. They were visualized by TBtools software (v.1.098775) [44].
Promoter analysis of KNOXs
The cis-elements of the approximately 2000 bp promoter region upstream of the KNOX gene in sweet potato were predicted by PlantCARE (https://bioinformatics.psb.ugent.be/webtools/plantcare/html/) [52].
Protein interaction network of KNOXs
The KNOX protein interaction network of sweet potato was predicted based on homologous proteins from Arabidopsis with a confidence level of 0.04 by using STRING (https://cn.string-db.org/), and the network map was visualized by using Cytoscape software [53].
Transcriptome analysis of KNOXs
The RNA-seq data of IbKNOXs in Long 9 and Xu18 were unpublished. The RNA-seq data of IbKNOXs in Xu55-2, ND98 and Xu22 were obtained from NCBI Sequence Read Archive (SRA, http://www.ncbi.nlm.nih.gov/Traces/sra) with accession number SRP092215 [34], PRJNA999504 [35] and SAMN10755180-SAMN10755194 [36], respectively. The RNA-seq data of ItfKNOXs and ItbKNOXs in I. trifida and I. triloba were downloaded from the Sweetpotato Genomics Resource (http://sweetpotato.plantbiology.msu.edu/). The expression levels of KNOXs were calculated as fragments per kilobase of exon per million fragments mapped (FPKM). The expression level was shown as the log2(FPKM), and heatmaps were constructed by TBtools software (v.1.098775) [44].
Expression analysis of IbKNOXs
Total RNA was extracted from the leaves of 4-week-old in vitro-grown Xu18 plants treated with 20% PEG6000 and ND98 plants treated with 200 mM NaCl in half-Hoagland solution. Experiments were conducted with three biological replicates, each with three plants. Transcript abundances were determined using reverse-transcription quantitative polymerase chain reaction (ZF502; ZOMANBIO, Beijing, China). The expression of IbKNOXs were measured and the sweet potato β-actin (AY905538) gene was used as the internal control (Table S1). Gene expression was quantified using the comparative CT method [54].
Results
Identification and characteristics of KNOXs in sweet potato and its two diploid relatives
In this study, BLASTP, hmmersearch and CD-search were employed to screen KNOXs of sweet potato and its two diploid relatives. Based on the screening results, a total of 40 KNOX genes were identified, including 17 in I. batatas, 12 in I. trifida, and 11 in I. triloba (named after “Ib”, “Itf”, and “Itb”). According to their chromosome positions, these genes were named IbKNOX1 ~ IbKNOX17, ItfKNOX1 ~ ItfKNOX12, and ItbKNOX1 ~ ItbKNOX11. The sequence attributes of IbKNOXs and their physicochemical properties were analyzed (Table 1). The genome length of IbKNOXs ranged from 1903 bp (IbKNOX17) to 8508 bp (IbKNOX2), while the length of CDS varied from 441 bp (IbKNOX1, IbKNOX12) to 1614 bp (IbKNOX15). The amino acid length of IbKNOXs ranged from 146 aa (IbKNOX1, IbKNOX12) to 537 aa (IbKNOX15). The molecular weight ranged from 16.623 kDa (IbKNOX1, IbKNOX12) to 59.589 kDa (IbKNOX15). The isoelectric point distribution is between 4.26 (IbKNOX13) and 9.98 (IbKNOX17), with only IbKNOX17 being an alkaline protein with an isoelectric point exceeding 7, while others were acidic proteins. Except for IbKNOX3 and IbKNOX17, the instability index of the other IbKNOXs was greater than 41, indicating that they are unstable. The GRAVY scores of all IbKNOXs were negative, suggesting that they were hydrophilic proteins, with IbKNOX9 being the most hydrophilic and IbKNOX17 the least hydrophilic. The subcellular localization prediction revealed that all IbKNOXs might be localized in the nucleus.
The KNOXs of I. batatas, I. trifida, and I. triloba were distributed across eight chromosomes (Fig. 1). In I. batatas, three IbKNOXs were detected on Chr07, Chr14 and Chr15, two on Chr06, Chr10 and Chr12, and one on Chr02 and Chr11. No genes were detected on Chr01, Chr03, Chr04, Chr05, Chr08, Chr09 and Chr13 (Fig. 1a). By comparing the chromosomal localization of KNOXs in I. trifida and I. triloba, we observed a slight difference, where there is one more gene (ItfKNOX5) on Chr06 of I. trifida than I. triloba (Fig. 1b and c). The remaining KNOXs on other chromosomes of the two diploid relatives were distributed similarly, with one gene on Chr01, Chr03, Chr05/04, and Chr09 and two on Chr07, Chr08, and Chr15 (Fig. 1b and c). The distribution of KNOX genes in sweet potato and its two diploid relatives differed significantly, indicating that KNOX genes in sweet potato had undergone some variation and loss in the process of evolution.
Phylogenetic relationship of KNOXs in sweet potato and its two diploid relatives
To investigate the evolutionary relationship of KNOXs in I. batatas, I. trifida, I. triloba, and Arabidopsis, a phylogenetic tree for 49 KNOXs of these four species (17 in I. batatas, 12 in I. trifida, 11 in I. triloba, and 9 in Arabidopsis) was constructed (Fig. 2). The evolutionary tree was clearly divided into three branches, Class I, Class II, and Class M (Fig. 2). The KNOXs of these four species were distributed in three branches as follows (total: I. batatas, I. trifida, I. triloba, Arabidopsis): Class I (8, 8, 6, 4), Class II (6, 4, 4, 4) and Class M (3, 0, 1, 1). AtKNAT2 and AtKNAT 6 in Class I and AtKNAT3, AtKNAT4, AtKNAT5 in Class II have no homologous proteins in sweet potato and its two diploid relatives (Fig. 2). KNOXs in Class M in different plants showed a distant genetic relationship (Fig. 2). Our results revealed that the difference in the number and type of homologous proteins in Arabidopsis, sweet potato, I. trifida and I. triloba was due to species specificity. The discrepancy shown in sweet potato and its two diploid relatives might be attributed to chromosomal hybridization during evolution.
Conserved domains and exon‒intron structure analysis of KNOXs in sweet potato and its two diploid relatives
To illustrate the structural characteristics of the 40 KNOX proteins from I. batatas, I. trifida, and I. triloba, motif and domain analyses using the MEME website were performed (Fig. 3). A total of four motifs were identified, including the KNOX1 and KNOX2 domains near the N-terminus, the ELK domain, and the homeobox-KN domain near the C-terminus (Fig. 3a). Overall, the protein structure of this family was relatively conserved, with most members characterized by the presence of four domains. KNOX proteins in Class I contained three or four domains, which were divided into two types. Most KNOXs in Class II contained two domains (KNOX1 and KNOX2), except ItfKNOX5, IbKNOX15, ItfKNOX11 and ItbKNOX10, which contained all four domains, and ItfKNOX3 and IbKNOX17, which contained only the KNOX1 domain. KNOXs in Class M contained KNOX1 and KNOX2 domains, which were similar to most KNOXs in Class II (Fig. 3a). They represented a novel type of KNOX TF that lacked the homeobox domain [55]. An interesting phenomenon was observed where proteins with high genetic relationships might contain different numbers of structural domains, with consistency in two diploids (I. trifida and I. triloba) but fewer in sweet potato (I. batatas). IbKNOX16, IbKNOX2, and IbKNOX10 contained one fewer ELK domain, and IbKNOX3 lacked both the ELK domain and the Homeobox-KN domain compared to their homologous proteins (Fig. 3a). In addition, IbKNOX15 and ItfKNOX5 in Class II contained a new PLN02617 domain. PLN02617 encoded imidazole glycerophosphate synthase, which was a glutamine aminotransferase in histidine biosynthesis [56]. These findings demonstrated that the presence, number, and distribution of different domains within KNOX genes were closely related to their sub-Class and homologous genes. We speculate that the ELK domain might be more susceptible to loss during evolution.
To better understand the gene structure of KNOXs, we analyzed the exon‒intron structure of IbKNOXs (17), ItfKNOXs (12) and ItbKNOXs (11) (Fig. 3b). The number of exons in the KNOX genes ranged from 1 to 12. KNOX genes in Class M contained 3 exons, those in Class I contained 4 to 7 exons, and those in Class II contained 1 to 12 exons. The gene structure of some IbKNOX genes differed from that of their homologous genes in I. trifida and I. triloba. IbKNOX16 in Class I contained 5 exons, while its homologous genes, ItfKNOX4 and ItbKNOX4, contained only 4 exons. IbKNOX11 and IbKNOX17 in Class II contained 5 exons, while their homologs, ItfKNOX3, ItfKNOX6 and ItbKNOX5, contained 1, 3 and 4 exons, respectively. IbKNOX3 in Class II contained 4 exons, while its homologous genes, ItfKNOX11 and ItbKNOX10, contained 5 exons. Taken together, these results indicated that the KNOX family might have undergone a lineage-specific differentiation event in the sweet potato genome.
Cis-element analysis in the promoter of IbKNOXs in sweet potato
Promoter cis-elements play a crucial role in initiating gene transcription associated with plant development, hormone regulation, and stress response. To investigate how KNOXs function in growth and development and abiotic stress adaptation in sweet potato, 2000 bp upstream sequences of IbKNOXs were extracted, and cis-element analysis was performed. According to the functional prediction, the elements were divided into six categories: core/binding sites, development regulation, hormone-responsive, abiotic/biotic stress-responsive, light-responsive and temperature elements (Fig. 4).
All IbKNOX genes were found to possess a multitude of core promoter elements, common cis-elements, light-responsive elements and some protein binding sites, such as TATA-box, CAAT-box and AT-rich elements (Fig. 4). Development regulation elements were found in most IbKNOX genes, such as cis-elements related to the meristem, a circadian rhythm control element, an element related to endosperm expression, an element involved in palisade mesophyll cell differentiation and elements involved in zein metabolism (Fig. 4). The hormone-responsive elements in the promoter of IbKNOXs were abundant, including MeJA-responsive (CGTCA-motif and TGACG-motif) in IbKNOX17, -11 in Class I, -9, -14, -7, -2, -10, -5 in Class II and − 1 in Class M; ABA-responsive (ABRE) in -15, -17, -3, -11 in Class I, -7, -2, -6, -4, -5 in Class II; SA-responsive (TCA-element) in -3, -8 in Class I, -7, -5 in Class II; GA-responsive (GARE-motif, TATC-box and P-box) in -8 in Class I, -16, -7, -2 in Class II and − 12, -13, -1 in Class M and IAA-responsive (AuxRR-core and TGA-element) in -11 in Class I, -16, -9, -14 in Class II and − 12 in Class M (Fig. 4). IbKNOXs contained three abiotic/biotic stress-responsive elements: defense and stress response element TC-rich repeats, wound-responsive element WUN-motif and MYB binding site involved in drought inducibility MBS (Fig. 4). Overall, IbKNOXs might be involved in the regulation of plant growth and development and hormone crosstalk in response to abiotic/biotic stresses in sweet potato through various cis-elements in promoters, especially IbKNOX11 in Class I with the maximum number and IbKNOX7 in Class II with the maximum type of hormone responsive elements in their promoters.
Protein interaction network of IbKNOXs in sweet potato
To explore the potential regulatory network of IbKNOXs, we developed an interaction network based on homologous proteins of Arabidopsis (Fig. 5). The results showed that.
IbKNOXs might interact with each other and other proteins, such as floral and vegetative development related protein BEL1 [57], flower development related protein AG (AGAMOUS) [58], MYB transcription factor 75 (MYB75) [59], leaf morphogenesis related protein AS2 (ASYMMETRIC LEAVES 2) [60, 61], organ boundaries development related protein ATH1 (ARABIDOPSIS THALIANA HOMEOBOX GENE1) [62], cell differentiation related protein WUS (WUSCHEL) [63], meristem homeostasis and floral organ numbers regulator CLV3 (CLAVATA3) [64,65,66], secondary cell wall biosynthesis related proteins OFP1, OFP4 and OFP5 (Ovate Family Proteins) [67, 68] and BEL1-like homeodomain protein BLH1 [68], to regulate ovule and anthocyanin biosynthesis, leaf development and abiotic tolerance (Fig. 5). IbKNOXs interact with ATH1 to form an STM self-activation loop to maintain the self-renewal of the meristem stem cell population. CLAVATA3 (CLV3) and WUSCHEL (WUS) to maintain a constant number of stem cells [64,65,66]. The MYB75 and OFP4 transcription coregulatory factors could interact with IbKNOX2, -4 ~ 7, and − 10 to regulate the formation of the plant secondary cell wall [69,70,71]. These results showed that IbKNOXs might be involved in maintaining the state and number of stem cells, regulating hormone biosynthesis and response, and participating in various aspects of plant growth and development.
Expression analysis of KNOXs in sweet potato and its two diploid relatives
Expression analysis in various tissues
To explore the potential biological functions of KNOXs in the growth and development of sweet potato and its two diploid relatives, we analyzed the expression patterns of IbKNOXs in seven tissues (leaves, petiole, stem, stem tip, pencil root, fibrous root, storage root) of Longshu 9 and Xushu 18 (Fig. 6). Longshu 9 and Xushu 18 are varieties with high and stable yields, strong resistance to stress, and wide adaptability [37, 38]. In addition, Longshu9 is precocious [37]. IbKNOXs in Class II were widely expressed in various tissues of sweet potato and expressed at higher levels in leaves than in other tissues, while IbKNOXs in Class I were more likely to be expressed in stems, stem tips and storage roots, and IbKNOXs in Class M were only expressed in stem tips (Fig. 6). The expression patterns of IbKNOXs in Longshu 9 and Xushu 18 were similar, except for IbKNOX9 and IbKNOX16 in Class I and IbKNOX7 and IbKNOX10 in Class II (Fig. 6). IbKNOX9 was highly expressed in stems in Longshu9 (Fig. 6a) but in storage roots in Xushu18 (Fig. 6b). IbKNOX16 was highly expressed in the stem in Longshu9 (Fig. 6a) but in the storage root in Xushu18 (Fig. 6b). IbKNOX7 was highly expressed in leaves in Longshu9 (Fig. 6a) but in fibrous roots in Xushu18 (Fig. 6b). IbKNOX10 leaves were low in Longshu9 (Fig. 6a) and high in Xushu18 (Fig. 6b). These results indicated that IbKNOX3, IbKNOX9, and IbKNOX16, which were highly expressed in storage roots in both Longshu9 and Xushu18, may be involved in the development of storage roots. IbKNOXs in Class M may play an important role in plant morphogenesis.
The expression patterns of ItfKNOXs and ItbKNOXs in six tissues (flower, flower bud, leaf, stem, root 1, root 2) of I. trifida and I. triloba were also analyzed by RNA-seq (Fig. 7). The expression levels of ItfKNOXs and ItbKNOXs in Class II were significantly higher than those in the other two Classes in all tissues, which was consistent with the results in sweet potato (Fig. 6). In I. trifida, ItfKNOX2 was highly expressed in flowers and flower buds. ItfKNOX2, -7, -8 and − 12 were highly expressed in leaves. ItfKNOX4 was highly expressed in stems. ItfKNOX1, -2 and − 4 were highly expressed in root 1, and ItfKNOX2 was highly expressed in root 2 (Fig. 7a). In I. triloba, ItbKNOX6 was highly expressed in flowers. ItbKNOX9 was highly expressed in flowerbud. ItbKNOX7 and ItbKNOX11 were highly expressed in leaves. ItbKNOX1 and − 4 were highly expressed in stems, and ItbKNOX1 was highly expressed in root 1 and root 2 (Fig. 7b). We found that some homologous genes showed different expression patterns in sweet potato and its two diploid relatives. IbKNOX10 was highly expressed in the stem and storage root, while its homologous genes ItfKNOX7 and ItbKNOX6 were less expressed in the stem and root. The expression levels of IbKNOX5 and its homologous gene ItbKNOX2 in roots were low, while the expression levels of ItfKNOX2 in roots 1 and 2 were high. IbKNOX9 and IbKNOX16 were poorly expressed in stems, while their homologous genes were highly expressed in stems. In addition, IbKNOX9 and IbKNOX16 were poorly expressed in the storage root, while their homologous genes (except ItbKNOX4) were highly expressed in root 1 (Figs. 6 and 7). These results indicated that KNOXs had distinct expression patterns in different tissues and that homologous genes in sweet potato and its two diploid relatives were endowed with different functions during evolution.
Expression analysis of storage roots during different developmental periods of sweet potato
Storage root is the main product of sweet potato. The formation of sweet potato storage roots is a complex and changeable process that is related to the downregulation of lignin biosynthesis, upregulation of starch biosynthesis, maintenance of meristem tissue, cell division, and hormonal crosstalk [27, 36]. There was almost no starch accumulation in fibrous roots, while starch accumulated rapidly and continued to increase in the later stage during the early stage of storage root development [36]. To explore the function of IbKNOXs in the development of storage roots in sweet potato, we analyzed the expression patterns of IbKNOXs in fibrous roots and storage roots with diameters of 1, 3, 5, and 10 cm in the cultivated sweet potato cultivar Xu22 as determined by RNA-seq (Fig. 8, Table S2). IbKNOX3, -8, -9, -14 and − 16 in Class I were significantly upregulated in storage roots compared with fibrous roots, among which the expression of IbKNOX9 increased 46-fold. IbKNOXs in Class II, except IbKNOX2 and IbKNOX10, were expressed at higher levels in fibrous roots but at lower levels in storage roots. IbKNOXs in Class M were not expressed in either fibrous roots or storage roots (Fig. 8). These results suggested that IbKNOX2, -3, -8, -9, -10, -14 and − 16 might be involved in the development of storage roots.
Expression analysis of hormone response in I. Trifida and I. Triloba
We analyzed the expression patterns of ItfKNOXs and ItbKNOXs in I. trifida and I. triloba with ABA, GA and IAA treatments as determined by RNA-seq (Fig. 9). The expression patterns of homologous genes in I. trifida and I. triloba were similar. The expression levels of KNOXs in Class II were higher than those in Class I with or without treatments. Most ItfKNOXs and ItbKNOXs were induced by ABA and not very insensitive to GA3 and IAA (Fig. 9). However, ItfKNOX1 was inhibited, but ItbKNOX1 was induced by GA3. ItfKNOX10 was induced by ABA and inhibited by GA3, while its homologous gene ItbKNOX9 showed the opposite expression pattern. ItfKNOX2 was highly expressed under the treatment of three hormones in I. trifida, while its homologous gene ItbKNOX2 was almost not expressed in I. triloba under treatments. ItfKNOX8 was inhibited by IAA, but its homologous gene ItbKNOX7 was induced. Among all the ItfKNOXs and ItbKNOXs, only ItbKNOX6 could be induced by all three hormones (Fig. 9). These results showed that the homologous genes of the two diploids had different responses to different hormone treatments, indicating that ItfKNOXs and ItbKNOXs may be involved in different hormone pathways.
Expression analysis under abiotic stresses
To explore the role of IbKNOXs in abiotic stresses, the expression patterns of IbKNOXs in the drought-tolerant line Xu55-2 under PEG (30%) treatment, salt-sensitive cultivar Lizixiang and salt-tolerant line ND98 under NaCl (200 mM) treatment by RNA-seq were analyzed (Fig. 10, Tables S3 and S4). IbKNOXs in Class II showed a significantly higher degree of expression than those in Class I. IbKNOX9 in Class I and − 6 and − 10 in Class II were significantly induced by PEG, especially IbKNOX10. However, IbKNOX14 in Class I and − 7 in Class II were significantly inhibited by PEG. IbKNOX1 and − 12 in Class M were also induced by PEG treatment (Fig. 10a, Table S3). IbKNOX15 in Class I and − 2, -6, -7 in Class II were upregulated by NaCl in ND98 compared with lzx, suggesting that they might be involved in salt stress tolerance. IbKNOXs in Class M did not respond to NaCl treatment (Fig. 10b, Table S4). The expression levels of IbKNOX2 and IbKNOX6 were induced by PEG and NaCl treatments, which indicated that they might be involved in both drought and salt stress tolerance in sweet potato (Fig. 10).
To prove the expression pattern of IbKNOXs, we performed qRT-PCR analysis to verify the expression levels of IbKNOXs under NaCl and PEG treatments. The results showed that IbKNOX2, -4, -6, -10 were upregulated significantly and − 14, -16 were downregulated by PEG treatment (Fig. S1a-f; Table S5). IbKNOX2, -6, -7 and − 15 were upregulated significantly by NaCl treatment (Fig. S1g-j; Table S5). IbKNOX2 and − 6 were both upregulated by NaCl and PEG (Fig. S1; Table S5), which were consistent with RNA-seq data.
The expression patterns of ItfKNOXs and ItbKNOXs in I. trifida and I. triloba treated with mannitol, NaCl and low temperature (10/4°C day and night) were determined by RNA-seq (Fig. 11). Under low-temperature stress, the expression of ItfKNOXs was inhibited, except for ItfKNOX2 and − 8 in I. trifida (Fig. 11a). In I. triloba, the expression levels of ItbKNOX6 and − 11 were upregulated, while the expression levels of ItbKNOX4 and − 9 were downregulated (Fig. 11b). Under mannitol and NaCl treatments, the expression levels of most homologous KNOXs were similar, except ItfKNOX6/ItbKNOX5, ItfKNOX9/ItbKNOX8 and ItfKNOX11/ItbKNOX10. ItfKNOX6 was induced, but ItbKNOX5 did not respond to mannitol and NaCl. ItfKNOX9 was inhibited, and ItbKNOX8 was induced. ItfKNOX11 did not respond to mannitol, but ItbKNOX10 was induced (Fig. 11b). These results indicate that the expression pattern of this gene has changed in sweet potato and its two diploid relatives.
Discussion
KNOX genes have been reported to be involved in plant growth and development, drought and salt stress, and hormone regulation in a variety of crops [7, 20, 23, 72, 73]. However, the KNOX gene family in sweet potato has not been fully analyzed. Sweet potato (I. batatas) is an autohexaploid (2n = 6x = 90) varying from I. trifida NCNSP0306 (2n = 2x = 30) and I. triloba NCNSP0323 (2n = 2x = 30) and is an important crop because of its storage root [33, 74]. Moreover, I. trifida showed better stress tolerance [75]. The difference between sweet potato and its two diploid relatives can help to identify the key genes related to storage root development and abiotic tolerance.
The KNOX gene family has been reported in many species [5,6,7, 11,12,13,14, 76]. In this study, a total of 40 KNOX genes, I. batatas (17), I. trifida (12) and I. triloba (11), were identified (Fig. 1). KNOXs in sweet potato contained 5 and 6 more genes than its two diploid relatives, respectively, indicating that KNOX genes were amplified in sweet potato compared with its two diploid relatives. Sequence differences between genomes and chromosome differentiation reveal the direction of evolution [77]. The location and distribution of KNOX genes on the chromosomes of sweet potato were significantly different from those in its two diploid relatives, while there were only two differences on chromosomes between the two diploid relatives (Fig. 1). According to the phylogenetic relationship with Arabidopsis thaliana, KNOXs were divided into three Classes (Class I, Class II, Class M) (Fig. 2). I. batatas and I. triloba contained 3 IbKNOXs and 1 ItbKNOX in Class M, respectively, while I. trifida did not contain ItfKNOXs in Class M (Fig. 2). The exon‒intron distributions of some IbKNOXs in I. batatas were different from their homologous genes in I. trifida and I. triloba (Fig. 3b). IbKNOX16 in Class I contained five exons, while its homologous genes ItfKNOX4 and ItbKNOX4 contained four exons (Fig. 3b). IbKNOX3 in Class II contained three introns, while its homologous genes ItfKNOX11 and ItbKNOX10 contained four introns (Fig. 3b). The results indicated that a complex evolutionary process took place in the evolution of sweet potato and its two diploid relatives.
KNOX proteins play important roles in regulating plant organ differentiation [78,79,80]. In this study, the expression patterns of many KNOXs showed tissue specificity (Fig. 6). It is indicated that KNOXs might participate in regulating organ differentiation of sweet potato. The result of KNOX protein interaction network showed that IbKNOXs might interact with BEL1 [57], MYB75 [59] and OFPs [67, 68]. In tomato, SlKN5-SlBLH regulatory modules inhibited fruit greening [81]. In Arabidopsis thaliana, both MYB6 and MYB75 interacted with KNAT7 to regulate secondary cell wall formation [59, 82]. OFPs, which often interact with both Class I and II KNOX proteins [83] and also BELL proteins to form OFP/KNOX/BELL complexes [71, 84, 85], control fruit shape and secondary cell wall biosynthesis. It should be noted that Class I KNOX proteins can control secondary cell wall (SCW) and lignin biosynthesis through GA signal pathway [86, 87]. In this study, the promoters of more than one IbKNOXs contained GA responsive elements (Fig. 4). It is worth investigating if IbKNOXs interact with BEL/MYB/OFP proteins to regulate SCW and lignin biosynthesis during the development of storage roots in such a pathway.
KNOXs are mainly expressed in the root, stem, leaf, flower and shoot tip meristem in dicotyledons and in the stem, meristem and spike in monocotyledons [2, 5, 6, 8,9,10, 12, 13, 16]. KNOX I genes had been reported to be involved in the development of sweet potato storage roots and regulate the level of cytokinin in storage roots [26]. During the development of storage roots, Ibkn2 (IbKNOX9 in this study) and Ibkn3 (IbKNOX16 in this study) were highly expressed, while Ibkn1 (IbKNOX14 in this study) and Ibkn3 were highly expressed in mature stem internodes [26], and their expression was higher in storage roots than in fibrous roots [27]. In this study, IbKNOX4, -5, and − 6 were highly expressed in the leaves of the high-yield varieties Longshu9 and Xushu18 (Fig. 6), indicating that they might regulate the development of leaves. Interestingly, IbKNOXs in Class M were specifically expressed in the stem tip and hardly expressed in other tissues, suggesting that they might play an important role in the development of meristem tissue (Fig. 6). In addition, the expression levels of IbKNOX14 (Ibkn1), -9 (Ibkn2) and − 16 (Ibkn3) in initial storage roots were increased compared to those in fibrous roots (Fig. 8), which was consistent with previous studies. These results indicate that these three genes may be related to the development of storage roots. Moreover, IbKNOX3 and IbKNOX8 in Class I were upregulated in initial storage roots compared to fibrous roots (Fig. 8). Notably, the promoters of IbKNOX14, -9, -16, -3 and − 8 contained more than one hormone responsive elements, such as ABA, IAA, GA and MeJA (Fig. 4). The development of storage roots in tuberous crops is a complex process, which is regulated by multiple hormone signaling pathways [88, 89]. Based on the above results, we speculated that IbKNOX14, -9, -16, -3 and − 8 might be involved in the development of storage roots through ABA, SA and GA signaling pathways.
Abscisic acid (ABA) is a stress resistance hormone in plants. Abiotic stresses, such as salt stress, drought and low temperature, in land plants can increase the endogenous level of ABA [90]. ABA responds to abiotic stress by inducing stomatal closure and root development and promoting ROS clearance, ion transport and osmotic adjustment [91,92,93,94,95]. Accumulating evidence has shown that the increase in endogenous GA3 and IAA levels could promote the expansion and division of leaf epidermal cells [96], and GA3 and IAA are also involved in abiotic stress tolerance [97,98,99,100]. In this study, IbKNOX2, -7 and − 10, which contained some abiotic and hormone response elements in their promotors, were induced by PEG and NaCl treatments, which indicated that they might be involved in both drought and salt stress tolerances in sweet potato (Figs. 4 and 10). The homologous genes of IbKNOX2 and − 10 in two diploid relatives, ItbKNOX6, ItfKNOX7, and ItbKNOX11, were also induced by mannitol and NaCl treatments (Figs. 2 and 11). In I. trifida, ItfKNOX6 was induced by ABA, mannitol and NaCl, which contained one response element and two low-temperature response elements in the promotor of its homologous gene (Figs. 2, 4, 9a and 11a). ItfKNOX2 was induced under cold and NaCl treatments and induced by GA3, which contained one ABA response element and two MYB binding sites involved in drought inducibility in the promotor of its homologous gene (Figs. 2, 4, 9a and 11a). These results indicated that these genes might be involved in the response of sweet potato to abiotic stress tolerance through hormone signaling pathways.
Conclusion
In this study, 17, 12, and 11 KNOX genes in sweet potato (I. batatas, 2n = 6x = 90) and its two diploid relatives, I. trifida (2n = 2x = 30) and I. triloba (2n = 2x = 30), were identified. There were differences in protein physicochemical properties, chromosomal localization, phylogenetic relationships, gene structure, protein interaction networks and promoter cis-elements among these 40 KNOX genes. Their expression patterns in different tissues during different periods of storage root development under different hormones and abiotic stresses, as determined by RNA-seq data, showed tissue specificity and indicated that homologous KNOXs might be involved in distinct hormone crosstalk and abiotic stress responses to regulate the growth and development of sweet potato. Among them, IbKNOX4, -5, and − 6 (highly expressed in the leaves), IbKNOX14, -9, -16, -3 and − 8 (higher expression in initial storage roots than fibrous roots), and IbKNOX2 and − 6 (induced by PEG and NaCl treatments) might be involved in the growth and development of sweet potato storage roots. This study provides a theoretical basis and potential candidate genes for further functional characterization and for improving the yield and abiotic stress tolerance of sweet potato and other species.
Data availability
The datasets generated and/or analysed during the current study are available in the NCBI SRA repository (http://www.ncbi.nlm.nih.gov/Traces/sra) under accessions SAMN10755180-SAMN10755194, SRP092215, PRJNA999504, SRP132113, SRP132112, SRP162110, and SRP162021. The datasets unpublished used and/or analyzed during the current study can be obtained from the corresponding author upon reasonable request.
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This work was supported by the earmarked fund for CARS-10-Sweetpotato, the Project of Sanya Yazhou Bay Science and Technology City (grant no. SCKJ-JYRC-2022-61/SYND-2022-09), the National Key Research and Development Program of China (2023YFD1200700/2023YFD1200703), and the Beijing Natural Science Foundation (grant no. 6212017).
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G.-S.X., X.L. and H.Z. conceived and designed the experiment. L.-C.J. and Z.-T.Y. performed the experiments, analyzed all the data and wrote the manuscript. S.-Z.H. and L.-L.S. revised the manuscript. All of the authors read and approved the final manuscript.
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Jia, LC., Yang, ZT., Shang, LL. et al. Genome-wide identification and expression analysis of the KNOX family and its diverse roles in response to growth and abiotic tolerance in sweet potato and its two diploid relatives. BMC Genomics 25, 572 (2024). https://doi.org/10.1186/s12864-024-10470-4
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DOI: https://doi.org/10.1186/s12864-024-10470-4