Molecular evolution and diversification of phytoene synthase (PSY) gene family

Lisboa, Marcia Pagno; Canal, Drielli; Filgueiras, João Pedro Carmo; Turchetto-Zolet, Andreia Carina

doi:10.1590/1678-4685-GMB-2021-0411

Abstract

Phytoene synthase (PSY) is a crucial enzyme required for carotenoid biosynthesis, encoded by a gene family conserved in carotenoid-producing organisms. This gene family is diversified in angiosperms through distinct duplication events. Understanding diversification patterns and the evolutionary history of the PSY gene family is important for explaining carotenogenesis in different plant tissues. This study identified 351 PSY genes in 166 species, including Viridiplantae, brown and red algae, cyanobacteria, fungi, arthropods, and bacteria. All PSY genes displayed conserved intron/exon organization. Fungi and arthropod PSY sequences were grouped with prokaryote PSY, suggesting the occurrence of horizontal gene transfer. Angiosperm PSY is split into five subgroups. One includes the putative ortholog of PSY3 (Subgroup E3) from eudicots, and the other four subgroups include PSY from both monocots and eudicots (subgroups E1, E2, M1, and M2). Expression profile analysis revealed that PSY genes are constitutively expressed across developmental stages and anatomical parts, except for the eudicot PSY3, with root-specific expression. This study elucidates the molecular evolution and diversification of the PSY gene family, furthering our understanding of variations in carotenogenesis.

Keywords
biosynthesis; evolutionary history; expression profile; paralogs; phylogeny

Introduction

Carotenoids are a complex class of C40 isoprenoid pigments synthesized by photosynthetic organisms, non-photosynthetic bacteria, and fungi (Cuttriss et al., 2011Cuttriss AJ, Cazzonelli CI, Wurtzel ET and Pogson BJ (2011) Carotenoids. Adv Bot Res 58:1-36.). In the chloroplast, carotenoids participate in photosynthesis, contribute to photoprotection, and act as precursors for strigolactone and abscisic acid (ABA) biosynthesis. They thus play a major role in mediating developmental signaling and stress responses. As secondary metabolites, carotenoids accumulate in chromoplasts, providing attractive colors and aroma precursors in fruits and flowers essential for pollination and seed dispersal (Ahrazem et al., 2019Ahrazem O, Diretto G, Argandoña Picazo J, Fiore A, Rubio-Moraga Á, Rial C, Varela RM, Macías FA, Castillo R, Romano E et al. (2019) The specialized roles in carotenogenesis and apocarotenogenesis of the phytoene synthase gene family in saffron. Front Plant Sci 10:249.).

Except for some arthropods (Moran and Jarvik, 2010Moran NA and Jarvik T (2010) Lateral transfer of genes from fungi underlies carotenoid production in aphids. Science 328:624-627.; Grbić et al., 2011Grbić M, Van Leeuwen T, Clark RM, Rombauts S, Rouzé P, Grbić V, Osborne EJ, Dermauw W, Ngoc PC, Ortego F et al. (2011) The genome of Tetranychus urticae reveals herbivorous pest adaptations. Nature 479:487-492.; Cobbs et al., 2013Cobbs C, Heath J, Stireman JO and Abbot P (2013) Carotenoids in unexpected places: Gall midges, lateral gene transfer, and carotenoid biosynthesis in animals. Mol Phylogenet Evol 68:221-228.), animals are unable to synthesize carotenoids de novo. Instead, the compounds are obtained directly from food consumed or partially modified through metabolic reactions (Maoka, 2019Maoka T (2019) Carotenoids as natural functional pigments. J Nat Med 74:16.). Carotenoids are essential dietary nutrients metabolized to retinol (vitamin A) and its derivatives. Retinol oxidation provides retinal, necessary for vision, and retinoic acid, a transcription factor ligand essential to regulating genes involved in cell morphogenesis, differentiation, and proliferation (Dawson, 2000Dawson MI (2000) The importance of vitamin A in nutrition. Curr Pharm Des 6:311-325.).

Carotenoid biosynthesis in plants is well described. Phytoene synthase (PSY) converts two molecules of geranylgeranyl pyrophosphate (GGPP) (C20) into phytoene (C40). Phytoene desaturase (PDS) then catalyzes colorless phytoene into lycopene, forming 9, 15, 9-tri-cis-ζ-carotene. The product is then desaturated via ζ-carotene desaturase (ZDS) to generate 7, 9, 9, 7-tetra-cis-lycopene (prolycopene), and from here, subsequent reactions are responsible for producing the different carotenoids found in nature (Nakkanong et al., 2012Nakkanong K, Yang JH and Zhang MF (2012) Carotenoid accumulation and carotenogenic gene expression during fruit development in novel interspecific in bred squash lines and their parents. J Agric Food Chem 60:5936-5944.). Carotenoid color varies according to the number of double bonds, with greater unsaturation corresponding to shorter absorbed wavelengths. Phytoene and phytofluene carotenoids are colorless, zeta-carotene is yellow, neurosporene is yellowish-orange, and lycopene is red. During desaturation, various intermediate reactions with the cis configuration are produced (Tanaka et al., 2008Tanaka Y, Sasaki N and Ohmiya A (2008) Biosynthesis of plant pigments: Anthocyanins, betalains and carotenoids. Plant J 54:733-749.). Phytoene synthase is pivotal to the carotenoid pathway as the first committed biosynthetic step, controlling metabolic flux through the pathway (Welsch et al., 2000Welsch R, Beyer P, Hugueney P, Kleinig H and von Lintig J (2000) Regulation and activation of phytoene synthase, a key enzyme in carotenoid biosynthesis, during photomorphogenesis. Planta 211:846-854.).

Previous analysis of carotenoid pathway genes indicated early evolutionary roots in prokaryotes, with more than 700 different natural carotenoid structures identified, many presents in bacteria. Genes encoding C40 phytoene are well conserved in Archaea and bacteria, indicating a common carotenogenic progenitor (Sandmann, 2021Sandmann G (2021) Diversity and origin of carotenoid biosynthesis: Its history of coevolution towards. New Phytol 232:479-493.). In plants, two PSY genes (PSY1 and PSY2) are present inthe angiosperm ancestor and a specific duplication event in both the monocot (Dibari et al., 2012Dibari B, Murat F, Chosson A, Gautier V, Poncet C, Lecomte P, Mercier I, Bergès H, Pont C, Blanco A et al. (2012) Deciphering the genomic structure, function and evolution of carotenogenesis related phytoene synthases in grasses. BMC Genomics 13:221.) and eudicot (Han et al., 2015Han Y, Zheng QS, Wei YP, Chen J, Liu R and Wan HJ (2015) In silico identification and analysis of phytoene synthase genes in plants. Genet Mol Res 14:9412-9422.; Stauder et al., 2018Stauder R, Welsch R, Camagna M, Kohlen W, Balcke GU, Tissier A and Walter MH (2018) Strigolactone levels in dicot roots are determined by an ancestral symbiosis-regulated clade of the PHYTOENE SYNTHASE gene family. Front Plant Sci 9:255.) groups resulted in a third PSY (PSY3) gene. PSY3 seems to have evolved independently in the monocot and eudicot species. Most plant species have a PSY gene family comprising two or three homologous genes. Arabidopsis has a single PSY gene, whereas carrots have two PSY genes (Clotault et al., 2008Clotault J, Peltier D, Berruyer R, Thomas M, Briard M and Geoffriau E (2008) Expression of carotenoid biosynthesis genes during carrot root development. J Exp Bot 59:3563-3573.; Rodriguez-Villalon et al., 2009Rodriguez-Villalon A, Gas E and Rodriguez-Concepcion M (2009) Phytoene synthase activity controls the biosynthesis of carotenoids and the supply of their metabolic precursors in dark-grown Arabidopsis seedlings. Plant J 60:424-435.). Tomato, cassava, and grasses such as maize, rice, and sorghum have three PSY paralogs in their genomes (Chaudhary et al., 2010Chaudhary N, Nijhawan A, Khurana JP and Khurana P (2010) Carotenoid biosynthesis genes in rice: Structural analysis, genome-wide expression profiling and phylogenetic analysis. Mol Genet Genom 283:13-33.; Dibari et al., 2012Dibari B, Murat F, Chosson A, Gautier V, Poncet C, Lecomte P, Mercier I, Bergès H, Pont C, Blanco A et al. (2012) Deciphering the genomic structure, function and evolution of carotenogenesis related phytoene synthases in grasses. BMC Genomics 13:221.). PSY gene duplication has led to subfunctionalization, with each paralog exhibiting differential gene expression. This functional diversification of PSY homologs allows carotenoids to accumulate in non-photosynthetic tissues (e.g., fruits, seeds, and flowers) and respond to environmental stress (Cárdenas et al., 2012Cárdenas PD, Gaijardo HA, Huebert T, Parkin IA, Iniguez-Luy FL and Federico ML (2012) Retention of triplicated phytoene synthase (PSY) genes in Brassica napus L. and its diploid progenitors during the evolution of the Brassiceae. Theor Appl Genet 124:1215-1228.).

Thus, in this work, we inferred a phylogenetic tree including PSY genes found in complete genomes of a range of taxa, including bacteria, algae, plants, arthropods, and fungi. We then mapped the possible PSY duplication and loss events on the tree’s internal nodes. Finally, we investigated the functional divergence of the PSY paralogs. This analysis allowed us to explore the protein motif and domain organization, gene structure, and expression patterns of PSY genes in different tissues. This study contributes to understanding PSY gene family evolution and functional divergence.

Material and Methods

Database search and sequence retrieval

PSY homologs were identified via BLAST searches in public databases (NCBI, Phytozome 12.1, Ensembl Plants, Congenie, and Klebsormidium Genome ProjectKlebsormidium genome project, Klebsormidium genome project, http://www.plantmorphogenesis.bio.titech.ac.jp/~algae_genome_project/klebsormidium/ (accessed day February 2021).
http://www.plantmorphogenesis.bio.titech... ). Query sequences were selected from organisms in which PSY was previously identified and characterized. A preliminary BLASTp search was performed with three PSY sequences identified in Solanum lycopersicum (Solyc03g031860.2.1, Solyc02g081330.2.1, and Solyc01g005940.2.1) (Giorio et al., 2008Giorio G, Stigliani A L and D’Ambrosio C (2008) Phytoene synthase genes in tomato (Solanum lycopersicum L) new data on the structures, the deduced amino acid sequences and the expression patterns. FEBS J 275:527-535.; Stauder et al., 2018Stauder R, Welsch R, Camagna M, Kohlen W, Balcke GU, Tissier A and Walter MH (2018) Strigolactone levels in dicot roots are determined by an ancestral symbiosis-regulated clade of the PHYTOENE SYNTHASE gene family. Front Plant Sci 9:255.), and the results indicated that each recovered practically the same sequence. Thus, only Solyc03g031860.2.1 was used for a BLASTp search (with default parameters) against 63 fully sequenced genomes of Viridiplantae species from PhytozomePhytozome, Phytozome, https://phytozome-next.jgi.doe.gov/blast-search (accessed day September 2019).
https://phytozome-next.jgi.doe.gov/blast... ; 28 Viridiplantae species from Ensembl PlantsEnsembl plants, Ensembl plants, https://plants.ensembl.org/Multi/Tools/Blast (accessed day February 2020).
https://plants.ensembl.org/Multi/Tools/B... ; 13 Rhodophyta species, 12 Cyanobacteria species, 11 Ochorophyta species, 10 Fungi species, and six Arthropoda species from NCBINCBI, Nucleotide Basic Local Alignment Search Tool, Nucleotide Basic Local Alignment Search Tool, NCBI, Nucleotide Basic Local Alignment Search Tool, Nucleotide Basic Local Alignment Search Tool, https://blast.ncbi.nlm.nih.gov/Blast.cgi (accessed day February 2021).
https://blast.ncbi.nlm.nih.gov/Blast.cgi... ; nine Prokaryote species from Ensembl Bacteria; two Gymnosperm species from CongenieCongenie, Congenie, https://congenie.org/blast (accessed day February 2021).
https://congenie.org/blast ... ; and one representative Charophyta species from Plant morphogenesis. Additionally, the Pantoea ananatis (D90087.2) sequence was used for a BLASTp search with default parameters against 10 Prokaryotespeciesfrom NCBI. The Tetranychus urticae (tetur01g11260) sequence was used for a BLASTp search with default parameters against one Arthropoda species from Ensembl Metazoa. These searches yielded166 species for analysis, and 351 sequences were retrieved (^{Table S1} Table S1 - Detailed data of retrieved sequences and species used in this study. ).

Sequence alignment and phylogenetic analysis

Protein sequences were aligned using MUSCLE (Edgar, 2004Edgar RC (2004) MUSCLE: Multiple sequence alignment with high accuracy and high throughput. Nucleic Acids Res 32:1792-1797.) implemented in Molecular Evolutionary Genetics Analysis (MEGA X) (Kumar et al., 2018Kumar S, Stecher G, Li M, Knyaz C and Tamura K (2018) MEGA X: Molecular evolutionary genetics analysis across computing platforms. Mol Biol Evol 35:1547-1549.). Alignments were manually inspected, and conserved blocks for phylogenetic analysis were selected with GBLOCKS (Castresana, 2000Castresana J (2000) Selection of conserved blocks from multiple alignments for their use in phylogenetic analysis. Mol Biol Evol 17:540-552.). Phylogenetic analysis was performed based on two methods: the Bayesian inference in MrBayes 3.2 (Ronquist et al., 2012Ronquist F, Teslenko M, van der Mark P, Ayres DL, Darling A, Höhna S, Larget B, Liu L, Suchard MA and Huelsenbeck JP (2012) MrBayes 3.2: Efficient Bayesian phylogenetic inference and model choice across a large model space. Syst Biol 61:539-542.) and Maximum Likelihood (ML) in IQ-Tree 2.1.3 (Minh et al., 2020Minh BQ, Schmidt HA, Chernomor O, Schrempf D, Woodhams MD, von Haeseler A and Lanfear R (2020). IQ-TREE 2: New models and efficient methods for phylogenetic inference in the genomic era. Mol Biol Evol 37:1530-1534.). The posterior probability and the bootstrap test were presented as statistical supports for the internal nodes for Bayesian and ML trees, respectively. To select the best-fit models of amino acid substitution based on BIC and AIC scores, we used ModelTest-NG 0.1.5 (Darriba et al., 2020Darriba D, Posada D, Kozlov AM, Stamatakis A, Morel B and Flouri T (2020) ModelTest-NG: A new and scalable tool for the selection of DNA and protein evolutionary models. Mol Biol Evol 37:291-294.), available on the CIPRES Science Gateway v.3.3 (Miller et al., 2010Miller MA, Pfeiffer W and Schwartz T (2010) Creating the CIPRES science gateway for inference of large phylogenetic trees. IEEE:1-8.). We performed two independent runs, each with four chains of 12, 000, 000 generations of Markov chain Monte Carlo (MCMC) algorithms for amino acid sequences. The first 25% of generations were deleted as burn-in. Tracer 1.7.1 (Rambaut et al., 2018Rambaut A, Drummond AJ, Xie D, Baele G and Suchard MA (2018) Posterior summarization in Bayesian phylogenetics using Tracer 1.7. Syst Biol 67:901-904. ) was then used to verify data obtained by the convergence of Markov chains and satisfactory effective sample sizes (>200). Trees were visualized and edited in FigTree v.1.4.4FigTree v1.4.4 software, 4 software, http://tree.bio.ed.ac.uk/software/Figtree/ (accessed day July 2021).
http://tree.bio.ed.ac.uk/software/Figtre... (http://tree.bio.ed.ac.uk/). We used TimeTree (Hedges et al., 2006Hedges SB, Dudley J and Kumar S (2006) TimeTree: A public knowledge-base of divergence times among organisms. Bioinformatics 22:2971-2972.) and constructed a simplified species tree using the divergence time between pairs of representative organisms from each major group.

Gene structure

Intron/exon organization in PSY genes was analyzed to better understand the rules governing gene structure and their consequences on protein function and evolutionary patterns among species (Wang et al., 2014Wang H, Ou C-G, Zhuang F-Y and Ma Z-G (2014) The dual role of phytoene synthase genes in carotenogenesis in carrot roots and leaves. Mol Breed 34:2065-2079.). Specifically, a comparative analysis was conducted using genomic sequences and CDS for PSY from 13 representative species (Physcomitrella patens, Selaginella moellendorffii, Brachypodium distachyon, Setaria italica, Oryza sativa, Sorghum bicolor, Solanum lycopersicum, Solanum tuberosum, Eucalyptus grandis, Citrus sinensis, Arabidopsis thaliana, Brassica rapa, and Glycine max). The Gene Structure Display Server (GSDS 2.0)Gene Structure Display Server (GSDS 2.0), 0), http://gsds.cbi.pku.edu.cn (accessed day November 2020).
http://gsds.cbi.pku.edu.cn... (Hu et al., 2015Hu B, Jin J, Guo A-Y, Zhang H, Luo J and Gao G (2015) GSDS 20: An upgraded gene feature visualization server. Bioinformatics 31:1296-1297.) was used to display intron/exon organization and intron phase patterns, along with a phylogenetic tree for the representative species constructed using protein sequence alignments of those species and following methods described in the previous section.

Identification of transmembrane domains and conserved motifs

The presence of transmembrane domains in PSY protein sequences was predicted in TMHMM-2.0 (Krogh et al., 2001Krogh A, Larsson B, von Heijne G and Sonnhammer EL (2001) Predicting transmembrane protein topology with a hidden Markov model: Application to complete. J Mol Biol 305:567-580.), provided by CBS Prediction ServersCBS Prediction Servers, CBS Prediction Servers, https://services.healthtech.dtu.dk/service.php?TMHMM-2.0 (accessed day November 2020).
https://services.healthtech.dtu.dk/servi... and PROTTERPROTTER, PROTTER, https://wlab.ethz.ch/protter/start/ (accessed day November 2020).
https://wlab.ethz.ch/protter/start/ ... (Omasits et al., 2014Omasits U, Ahrens CH, Muller S and Wollscheid B (2014) Protter: Interactive protein feature visualization and integration with experimental proteomic data. Bioinformatics 30:884-886.). Potential functional motifs were identified using the MEME utility program (Multiple Expectation Maximization for Motif ElicitationMEME utility program (multiple expectation maximization for motif elicitation), MEME utility program (multiple expectation maximization for motif elicitation), http://meme.sdsc.edu (accessed day November 2020).
http://meme.sdsc.edu... ) (Bailey et al., 2006Bailey TL, Williams N, Misleh C and Li WW (2006) MEME: Discovering and analyzing DNA and protein sequence motifs. Nucleic Acids Res 34:W369-W373.). The sequence logo was constructed in WebLogoWebLogo, WebLogo, http://weblogo.berkeley.edu/logo.cgi (accessed day November 2021).
http://weblogo.berkeley.edu/logo.cgi ... (Crooks et al., 2004Crooks GE, Hon G, Chandonia J-M and Brenner SE (2004) WebLogo: A sequence logo generator. Genome Res 14:1188-1190.).

Gene expression analysis

To determine tissue specificity and intensity of PSY gene expression in A. thaliana, G. max, O. sativa, and S. bicolor, we used microarray and RNA-seq data from the GENEVESTIGATOR websiteGENEVESTIGATORweb site, GENEVESTIGATORweb site, https://www.genevestigator.com (accessed day February 2021).
https://www.genevestigator.com ... (Hruz et al., 2008Hruz T, Laule O, Szabo G, Wessendorp F, Bleuler S, Oertle L, Widmayer P, Gruissem W and Zimmermann P (2008) Genevestigator v3: A reference expression database for the meta-analysis of transcriptomes. Adv Bioinformatics 2008:420747.), along with its hierarchical clustering tool. The highest expression values were considered for genes with more than one probe set. Expression data were normalized and hierarchically clustered based on Pearson coefficients. The potential for PSY gene expression in different anatomical regions and developmental stages is represented with heat maps.

Results

**Identification of PSY homologs**

After analyzing 351 PSY gene sequences from 166 species (^{Table S1} Table S1 - Detailed data of retrieved sequences and species used in this study. ), we found that red algae, brown algae, fungi, and arthropods have only one PSY gene. This pattern is generally true for the prokaryotes, algae, and cyanobacteria species. Most plant species have more than one PSY gene, but the following only have one: bryophytes Marchantia polymorpha and Sphagnum fallax; lycophyte Selaginella moellendorffii; monocots Zostera marina and Saccharum spontaneum; Brassicaceae species Arabidopsis halleri, A. lyrata, A. thaliana, Boechera stricta, Capsella grandiflora, and C. rubella; as well as eudicots Carica papaya and Beta vulgaris.

Phylogenetic analysis

To understand PSY phylogeny and diversification patterns, we inferred a phylogenetic tree with 351 PSY amino acid sequences spanning 166 species. The dataset includes 20 sequences from bacteria, 13 from red algae, 11from brown algae, 13 from cyanobacteria, eight from algae, five from bryophytes, 10 from fungi, seven from arthropods, one from charophytes, one from lycophytes, four from gymnosperms, two from early angiosperms, and 256 from angiosperms (monocotyledons and eudicotyledons) (^{Table S1} Table S1 - Detailed data of retrieved sequences and species used in this study. ). Alignments used for the phylogenetic analysis consisted of 264 sites. The best model suggested for the protein dataset, for both BIC and AIC scores, was LG+I+G4. The tree topology presented in Figure 1 results from the Bayesian inference analysis and shows both posterior probability and bootstrap values.

Figure 1 -
Phylogenetic tree for PSY genes in representative Viridiplantae, fungi, arthropods, brown algae, red algae, cyanobacteria, and prokaryote lineages, providing insight into PSY origin and diversification among terrestrial plants. Figures show the resulting tree of the Bayesian inference analysis and present both posterior probabilities (numbers in red) with a cut-off point of 0, 8 and bootstrap values (numbers in blue) with a cut-off point of 70. The tree was rooted with prokaryotes as a sister group of the other organisms (root selected manually in FigTree v.1.4.4). Bayesian and maximum likelihood analyses were performed using PSY amino acid sequences from 166 selected representative species. Five main nodes that potentially mark taxonomic divergence during plant evolution (Nodes 1, 2, 3, 4 and 5) are marked with green circles. Inside the square in the upper right corner of the figure is the original unrooted tree.

We identified two major groups (A and B) in the phylogenetic tree constructed using all 351 sequences (Figure 1). Identified as group A are brown algae Ochrophyta, red algae Rhodophyta, blue algae Cyanophyta, fungi, bacteria, and arthropods. Group B included angiosperms (eudicots subgroups E1, E2 and E3, and monocots subgroups M1 and M2), gymnosperms (subgroups G1 and G2), the early angiosperm Amborella trichopoda, sequences of bryophytes, lycophyte Selaginella moellendorffii, green algae chlorophyta and the charophyta Klebsormidium nitens. Terrestrial plants had sequences that formed distinct groups in the phylogeny. Interestingly, PSY3 gene orthologs (subgroup E3), identified and functionally characterized in tomatoes, includes only eudicotyledon species and seems to be the most divergent one, being located at the more external position than other angiosperms and even gymnosperms.

Patterns of gene duplication and gene loss

After analyzing the angiosperm group in the phylogenetic tree, we observed that most eudicots had at least one representative species in subgroup E3 (^{Figure S3} Figure S3 - Phylogenetic relationships among PSY genes belonging to subgroup E3 from Figure 1. ), except for Brassicaceae family and Lupinus angustifolius, Beta vulgaris, Solanum tuberosum species. The absence of members from a given PSY group in each species might represent gene loss. Still, it could also result from an incomplete or locally misassembled genome, improper annotation, or failure to meet our screening criteria. In subgroup E3, Glycine max presented two PSY members that were grouped together. Because other Fabaceae family members had only one gene in this cluster, the two grouped genes probably resulted from a WGD (whole genome duplication) event. Mimulus guttatus, Linum usitatissimum, and Kalanchoe laxiflora species in subgroup E3 also may have experienced WGD events, with two gene members clustered together. In this subgroup, two branches with Citrus clementina and Citrus sinensis were clustered in a single branch, suggesting duplication in the Citrus base genus.

Subgroups E1, E2, M1, M2, and two sequences from early angiosperm Amborella trichopoda were positioned in the same branch (Figure 1). The subgroups E1 and E2 (Figures S4 and S5 respectively) grouped eudicot sequences, while the subgroups M1 and M2 (Figures S6 and S7, respectively) grouped monocot sequences. Based on these results, we suggest that the duplication events leading to the emergence of these groups occurred prior to the monocot-eudicot divergence. In subgroup E1 (^{Figure S4} Figure S4 - Phylogenetic relationships among PSY genes belonging to Subgroup E1 from Figure 1. ), several recent duplications appear to have occurred, with one duplication in Glycine max, two duplications in Linum usitatissimum that are probably separate WGD events, one duplication in Malus domestica, and one duplication in Gossypium raimondii. Additionally, in this clade, two branches with the species Kalanchoe laxiflora and Kalanchoe fedtschenko were clustered in a single branch, suggesting duplication in the Kalanchoe base genus. Salix purpurea also had two subsequent duplications, each containing a sequence from Populus trichocarpa, suggesting duplication at the base of the Salicaceae family. In subgroupM1 (^{Figure S6} Figure S6 - Phylogenetic relationships among PSY genes belonging to subgroup M1 from Figure 1. ), four monocots had duplications suggestive of WGD: Triticum turgidum, Zea mays, Eragrostis tef, and Musa acuminata. In subgroup E2 (^{Figure S5} Figure S5 - Phylogenetic relationships among PSY genes belonging to Subgroup E2 from Figure 1. ), species with duplications suggestive of WGD were Glycine max, Solanum tuberosum, Actinidia chinensis, Eucalyptus grandis, Citrus clementina, Eutrema salsugineum, and Malus domestica. In this subgroup two branches with the species Cynara cardunculus and Helianthus annuus were clustered in a single branch, suggesting duplication at the Asteraceae base Family. In subgroup M2 (^{Figure S7} Figure S7 - Phylogenetic relationships among PSY genes belonging to Subgroup M2 from Figure 1. ), species that may have experienced WGD were Musa acuminata, Leersia perrieri, Eragrostis tef, Panicum virgatum, and Zea mays.

Comparative analysis of gene structure and conserved domains and motifs in PSY proteins

Exon and intron length (in base pairs) was manually counted via aligning cDNA sequences with their corresponding genomic DNA sequences. Analysis of gene structure for exon-intron organization revealed that the number of introns per gene varied from four to five, with a few exceptions. Intron number and gene organization were fairly conserved among species (Figure 2). The length of PSY amino acid sequences ranged from 300 to 440. To analyze functional motifs, we searched for conserved domains in representative proteins from the retrieved sequences. Examining amino acid sequences encoded by these genes allowed us to identify conserved sites and motifs characteristic of the PSY family. We inferred that proteins encoded by PSY genes are highly conserved and feature a common domain, the SQS-PSY (squalene/ phytoene synthase-Pfam accession no. 00494) domain (Figure 3). Predictions of transmembrane structures revealed that transmembrane sequences were absent in PSY genes, suggesting that PSY are soluble proteins and not associated with membrane systems.

Figure 2 -
Exon-intron organization of PSY genes in terrestrial plants. PSY sequences from 13 representative species (Physcomitrella patens, Selaginella moellendorffii, Brachypodium distachyon, Setaria italica, Oryza sativa, Sorghum bicolor, Solanum lycopersicum, Solanum tuberosum, Eucalyptus grandis, Citrus sinensis, Arabidopsis thaliana, Brassica rapa, Glycine max) are presented. Gene features are displayed on a Bayesian phylogenetic tree.

Figure 3-
Amino acid sequence logo of PSY alignments from angiosperm species, highlighting the high gene conservation. The vertical axis indicates information content of a sequence position, in bits (log2 4 = 2 bits for DNA/RNA, log2 20 = 4.3 bits for protein). The height of the y-axis is the maximum entropy for a given sequence type. The horizontal axis indicates the residue number. The blue line indicates the SQS_PSY domain.

Gene expression analysis of PSY in monocot and eudicot model species

We used RNA-seq and microarray data from GENEVESTIGATOR to analyze the global expression profile of PSY genes from four model species representing monocot (Oryza sativa and Sorghum bicolor) and eudicot (Arabidopsis thaliana and Glycine max) groups. We analyzed 127 anatomical parts and 10 developmental stages from A. thaliana, 28 anatomical parts and eight developmental stages from G. max, nine anatomical parts and five developmental stages from S. bicolor, and 42 anatomical parts and nine developmental stages from O. sativa. In each species, PSY was ubiquitously expressed across all developmental stages and anatomical parts, with species-specific differences in the tissue and stage that had higher expression (Table 1, ^{Figures S8} Figure S8 - Gene expression analysis across developmental stages of Arabidopsis thaliana performed using GENEVESTIGATOR database. -¹⁵ Figure S15 - Gene expression analysis across anatomical parts of Sorgum bicolor performed using GENEVESTIGATOR. ). Arabidopsis thaliana has only one PSY gene (AthPSY1) in its genome, included in Subgroup E2 and highly expressed in sperm cells, mesophyll protoplasts, seedling cultures, shoots, leaves, and inflorescence parts. AthPSY1 expression was high at all developmental stages and decreased during final ripening (Table 1, ^{Figure S8} Figure S8 - Gene expression analysis across developmental stages of Arabidopsis thaliana performed using GENEVESTIGATOR database. -⁹ Figure S9 - Gene expression analysis across anatomical parts of Arabidopsis thaliana performed using GENEVESTIGATOR. ). Additionally, AthPSY1 expression was low in roots but upregulated in perturbation experiments. Glycine max is a model oleaginous crop and has eight PSY paralog genes: Glyma.14G209700 and Glyma.02G240200 in subgroup E2; Glyma.14G031200, Glyma.02G283400, Glyma.18G111900, and Glyma.08G306200 in subgroup E1; Glyma.18G000600 and Glyma.11G256400 in subgroup E3. GmaPSY genes exhibited medium to high expression in developmental stages and anatomical parts (Table 1, ^{Figure S10} Figure S10 - Gene expression analysis across anatomical parts of Glycine max performed using GENEVESTIGATOR. -¹¹ Figure S11 - Gene expression analysis across developmental stages of Glycine max performed using GENEVESTIGATOR. ). Glyma.18G000600 was lowly expressed under normal conditions but upregulated in perturbation experiments with biotic stress (e.g., fungi, insect pests, and parasites). Glyma.11G256400 was not detected in either RNA-seq or microarray data. Hierarchical clustering revealed that GmaPSY genes were grouped together on the phylogenetic tree. Oryza sativa has three PSY genes that are highly expressed across all developmental stages, especially during heading (Table 1, ^{Figure S12} Figure S12 - Gene expression analysis across developmental stages of Oryza sativa performed using GENEVESTIGATOR. -¹³ Figure S13 - Gene expression analysis across anatomical parts of Oryza sativa performed using GENEVESTIGATOR. ). The two PSY genes from S. Bicolor presented a similar expression pattern, with medium to high expression detected in all tissues and developmental stages (^{Figure S14} Figure S14 - Gene expression analysis across developmental stages of Sorgum bicolor performed using GENEVESTIGATOR. -¹⁵ Figure S15 - Gene expression analysis across anatomical parts of Sorgum bicolor performed using GENEVESTIGATOR. ).

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Table 1 -
Gene expression analysis from Genevestigator showing expression pattern of PSY in anatomical parts and developmental stages of Arabidopsis thaliana, Glycine max, Oryza sativa and Sorghum bicolor.

Discussion

The PSY gene family encodes a rate-limiting enzyme in carotenoid biosynthesis and is ubiquitous in plants (Welsch et al., 2000Welsch R, Beyer P, Hugueney P, Kleinig H and von Lintig J (2000) Regulation and activation of phytoene synthase, a key enzyme in carotenoid biosynthesis, during photomorphogenesis. Planta 211:846-854.; Yang et al., 2005Yang Z, Wong WSW and Nielsen R (2005) Bayes empirical bayes inference of amino acid sites under positive selection. Mol Biol Evol 22:1107-1118.). The first member of the angiosperm PSY gene (PSY1) was cloned from tomato fruits, and its expression correlated with lycopene accumulation (Bartley et al., 1992Bartley GE, Viitanen PV, Bacot KO and Scolnik PA (1992) A tomato gene expressed during fruit ripening encodes an enzyme of the carotenoid biosynthesis pathway. J Biol Chem 267:5036-5039.; Ray et al., 1992Ray J, Moureau P, Bird C, Bird A, Grierson D, Maunders M, Truesdale M, Bramley P and Schuch W (1992) Cloning and characterization of a gene involved in phytoene synthesis from tomato. Plant Mol Biol 19:401-404.). Since then, many researchers have identified and characterized PSY family members in a variety of plants, demonstrating their importance in controlling carotenoid biosynthesis and their association with pigment diversity and stress response (Shao et al., 2018Shao H, Yong B, Xu P, Zheng H, Liao R, Wang X, Li X, Zhang L and Shen J (2018) Phytoene synthase gene (PSY) from sweet potato (Ipomoea batatas Lam) enhances tolerance to abiotic stress. Braz Arch Biol Technol 61:e18160558.). While most plant species have two or more PSY paralog genes, some have only one (e.g., A. thaliana). The presence of multiple paralogs could potentially explain carotenogenesis in various tissues (Fantini et al., 2013Fantini E, Falcone G, Frusciante S, Giliberto L and Giuliano G (2013) Dissection of tomato lycopene biosynthesis through virus-induced gene silencing. Plant Physiol 163:986-998.; Wang et al., 2014Wang H, Ou C-G, Zhuang F-Y and Ma Z-G (2014) The dual role of phytoene synthase genes in carotenogenesis in carrot roots and leaves. Mol Breed 34:2065-2079.; Yuan et al., 2015Yuan H, Zhang J, Nageswaran D and Li L (2015) Carotenoid metabolism and regulation in horticultural crops. Hortic Res 2:15036.), given that the expression profiles of different PSY isoforms exhibited tissue specificity. For example, in tomato (Solanum lycopersicum), PSY1 is expressed in the fruit at levels that correlate with carotenoid content, while PSY2 is expressed in leaves; PSY3 expression is specific to roots and also conditional on being under stress (Nisar et al., 2015Nisar N, Li L, Lu S, Khin NC and Pogson BJ (2015) Carotenoid metabolism in plants. Mol Plant 8:68-82.). These findings spur new questions regarding such an important gene family from an evolutionary point of view. Thus, in this study, we used a phylogenetic approach to gain insights into the evolution and diversification of the PSY gene family. After searching available whole-genome sequences of plants, algae, red algae, brown algae, fungi, bacteria, cyanobacteria, and arthropods in GenBank, we identified 351 PSY genes across 166 species. We confirmed that most species have more than one PSY gene and that most duplications occurred after angiosperm diversification since angiosperms have the most significant number of genes.

In this study, we observed a discrepancy between the gene (Figure 1) and species (^{Figure S1} Figure S1 - Simplified species tree using the divergence time between pairs of representative organisms used from each major group. ) tree. Fungi and arthropod PSY sequences were grouped with prokaryote PSY, and ochrophyta PSY grouped with rodophyta PSY, suggesting the occurrence of horizontal gene transfer. Horizontal gene transfer is the acquisition of genes from organisms other than a direct ancestor (Crisp et al., 2015Crisp A, Boschetti C, Perry M, Tunnacliffe A and Micklem G (2015) Expression of multiple horizontally acquired genes is a hallmark of both vertebrate and invertebrate genomes. Genome Biol 16:50.). Our results corroborate with other studies, such those that have demonstrated that the ochrophytahas a red alga-derived plastid through eukaryote-eukaryote endosymbiosis (Ševčíková et al., 2015Ševčíková T, Horák A, Klimeš V, Zbránková V, Demir-Hilton E, Sudek S, Jenkins J, Schmutz J, Přibyl P, Fousek J et al. (2015) Updating algal evolutionary relationships through plastid genome sequencing: Did alveolate plastids emerge through endosymbiosis of an ochrophyte? Sci Rep 5:10134.; Sibbald and Archibald, 2020Sibbald SJ and Archibald JM (2020) Genomic insights into plastid evolution. Genome Biol Evol 12:978-990.; Azuma et al., 2022Azuma T, Pánek T, Tice AK, Kayama M, Kobayashi M, Miyashita H, Suzaki T, Yabuki A, Brown MW and Kamikawa R (2022) An enigmatic stramenopile sheds light on early evolution in Ochrophyta plastid organellogenesis. Mol Biol Evol 39:msac065.). Bacteria can obtain genes from other species via horizontal gene transfer, resulting in the genes being distributed among different species. Previous studies have shown that the horizontal transfer of carotenoid biosynthesis genes plays a major role in the distribution of carotenoid pathways across unrelated phylogenetic lineages (Phadwal, 2005Phadwal K (2005) Carotenoid biosynthetic pathway: Molecular phylogenies and evolutionary behavior of crt genes in eubacteria. Gene 345:35-43.; Klassen, 2010Klassen JL (2010) Phylogenetic and evolutionary patterns in microbial carotenoids biosynthesis are revealed by comparative genomics. PLoS One 5:e11257.). The lateral transfer has been reported for some arthropod species (red aphids, spider mites, and gall midges) that received enzymatic machinery for carotenoid biosynthesis from fungi (Moran and Jarvik, 2010Moran NA and Jarvik T (2010) Lateral transfer of genes from fungi underlies carotenoid production in aphids. Science 328:624-627.; Grbić et al., 2011Grbić M, Van Leeuwen T, Clark RM, Rombauts S, Rouzé P, Grbić V, Osborne EJ, Dermauw W, Ngoc PC, Ortego F et al. (2011) The genome of Tetranychus urticae reveals herbivorous pest adaptations. Nature 479:487-492.; Cobbs et al., 2013Cobbs C, Heath J, Stireman JO and Abbot P (2013) Carotenoids in unexpected places: Gall midges, lateral gene transfer, and carotenoid biosynthesis in animals. Mol Phylogenet Evol 68:221-228.). In prokaryotes, horizontal gene transfer has great adaptive significance, although its impact on eukaryotic evolution remains unclear. Some evidence suggests that the presence of certain genes in various plant-feeding insects, mites, and fungi can only be explained by horizontal gene transfer (Moran and Jarvik, 2010Moran NA and Jarvik T (2010) Lateral transfer of genes from fungi underlies carotenoid production in aphids. Science 328:624-627.; Novikova et al., 2010Novikova O, Smyshlyaev G and Blinov A (2010) Evolutionary genomics revealed interkingdom distribution of Tcn1-like chromodomain-containing Gypsy LTR retrotransposons among fungi and plants. BMC Genomics 11:231.; Walsh et al., 2013Walsh AM, Kortschak RD, Gardner MG, Bertozzi T and Adelson DL (2013) Widespread horizontal transfer of retrotransposons. Proc Natl Acad Sci U S A 110:1012-1016.; Wybouw et al., 2016Wybouw N, Pauchet Y, Heckel DG and Van Leeuwen T (2016) Horizontal gene transfer contributes to the evolution of arthropod herbivory. Genome Biol Evol 8:1785-1801.).

We identified five main nodes in the angiosperms subgroups PSY gene tree (Figure 1) that potentially mark taxonomic divergence during plant evolution. Node 1 probably corresponds to the divergence between lycophytes and other plants (gymnosperms + angiosperms). After lycophyte diversification, the PSY gene was duplicated in the spermatophyte ancestor. However, the ancestor paralog was maintained only in the eudicot lineage, which gave rise to subgroup E3. Node 2 appears to mark the divergence between gymnosperms and angiosperms. Gymnosperms inherited two copies, whereas angiosperms inherited only one copy. Node 3 presents the duplication events of PSY in the angiosperm clade. One copy remained in the three lineages from Node 4 (monocots, eudicots, and Amborella). The other paralogs were acquiredin eudicots (subgroup E2), monocots (subgroup M2), and Amborella. Node 4 is split into two branches. The first groupis a Coffea species with Amborella, suggesting a horizontal transfer event. The second group leads to Node 5, which marks the separation between monocots and eudicots. ^{Figure S2} Figure S2 - Scheme of PSY gene duplications and losses. summarizes these patterns of gene duplication and loss.

Using RNA-seq and microarray data, we demonstrated that genes Glyma.18G000600 and Glyma.11G256400 in subgroup E3 were expressed when exposed to biotic stress. This characteristic resembles tomato PSY3, which is expressed during fungal colonization. In subgroup M2, the genes Sobic.002G292600 (S. bicolor) and LOC_Os9g38320 (O. sativa) exhibit abiotic-stress-inducible expression, similar to PSY3 in Poaceae (Dibari et al., 2012Dibari B, Murat F, Chosson A, Gautier V, Poncet C, Lecomte P, Mercier I, Bergès H, Pont C, Blanco A et al. (2012) Deciphering the genomic structure, function and evolution of carotenogenesis related phytoene synthases in grasses. BMC Genomics 13:221.). The absence of subgroup E3 PSY in some species, such as those from Brassicaceae, suggests that this paralog was lost in the ancestor of the family.

Our results show a duplication pattern consistent with WGD, indicating that such events may be the main source of PSY duplication. Our findings corroborate with previous studies that have found evidence of WGD events in Salix purpurea and Populus trichocarpa (Tuskan et al., 2006Tuskan GA, Difazio S, Jansson S, Bohlmann J, Grigoriev I, Hellsten U, Putnam N, Ralph S, Rombauts S, Salamov A et al. (2006) The genome of black cottonwood, Populus trichocarpa. Science. 313:1596-1604.; Koenen et al., 2021Koenen EJM, Ojeda DI, Bakker FT, Wieringa JJ, Kidner C, Hardy OJ, Pennington RT, Herendeen P, Bruneau A and Hughes CE (2021) The origin of the legumes is a complex paleopolyploid phylogenomic tangle closely associated with the cretaceous-paleogene (K-Pg) mass extinction event. Syst Biol 70:508-526.). Fabaceae experienced three WGD events, one in the ancestor of the family and the other two occurring independently in subfamilies Detarioideae and Papilionoideae (Koenen et al., 2021Koenen EJM, Ojeda DI, Bakker FT, Wieringa JJ, Kidner C, Hardy OJ, Pennington RT, Herendeen P, Bruneau A and Hughes CE (2021) The origin of the legumes is a complex paleopolyploid phylogenomic tangle closely associated with the cretaceous-paleogene (K-Pg) mass extinction event. Syst Biol 70:508-526.). Polyploidy in grasses is an ongoing process (Levy and Feldman, 2002Levy AA and Feldman M (2002) The impact of polyploidy on grass genome evolution. Plant Physiol130:1587-1593.), further supporting the possibility of WGD.

Our study inferred the phylogenetic tree of the PSY gene family in various species and contributed to the knowledge about the evolutionary history of this gene family. The divergence between subgroup E3 and the other subgroups of plants most likely occurred after an ancient replication, when other terrestrial plants besides eudicots lost the subgroup E3 copy over time. Mapping the gain and losses of PSY genes in the phylogenetic tree, we got insights into the process leading to the diversification of this gene family. It is well known that gene gain and loss are significant forces driving evolution (Delabre et al., 2020Delabre M, El-Mabrouk N, Huber KT, Lafond M, Moulton V, Noutahi E and Castellanos MS (2020) Evolution through segmental duplications and losses: A super-reconciliation approach. Algorithms Mol Biol 15:12.). Thus, the preponderance of PSY duplicates in plant genomes could explain the capacity to evolve different carotenoids profiles associated with ecological circumstances, such as biotic stress.

Acknowledgements

This swork was financially supported by Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq; Grant number: 306202/2016-6 and 308135/2020-2), Coordenação de Aperfeiçoamento de Pessoal de Nível Superior, and Fundação de Amparo à Pesquisa do Estado do Rio Grande do Sul (Grant number: 16/491-9).

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Supplementary material

The following online material is available for this article:

Table S1 - Detailed data of retrieved sequences and species used in this study.

Figure S1 - Simplified species tree using the divergence time between pairs of representative organisms used from each major group.

Figure S2 - Scheme of PSY gene duplications and losses.

Figure S3 - Phylogenetic relationships among PSY genes belonging to subgroup E3 from Figure 1.

Figure S4 - Phylogenetic relationships among PSY genes belonging to Subgroup E1 from Figure 1.

Figure S5 - Phylogenetic relationships among PSY genes belonging to Subgroup E2 from Figure 1.

Figure S6 - Phylogenetic relationships among PSY genes belonging to subgroup M1 from Figure 1.

Figure S7 - Phylogenetic relationships among PSY genes belonging to Subgroup M2 from Figure 1.

Figure S8 - Gene expression analysis across developmental stages of Arabidopsis thaliana performed using GENEVESTIGATOR database.

Figure S9 - Gene expression analysis across anatomical parts of Arabidopsis thaliana performed using GENEVESTIGATOR.

Figure S10 - Gene expression analysis across anatomical parts of Glycine max performed using GENEVESTIGATOR.

Figure S11 - Gene expression analysis across developmental stages of Glycine max performed using GENEVESTIGATOR.

Figure S12 - Gene expression analysis across developmental stages of Oryza sativa performed using GENEVESTIGATOR.

Figure S13 - Gene expression analysis across anatomical parts of Oryza sativa performed using GENEVESTIGATOR.

Figure S14 - Gene expression analysis across developmental stages of Sorgum bicolor performed using GENEVESTIGATOR.

Figure S15 - Gene expression analysis across anatomical parts of Sorgum bicolor performed using GENEVESTIGATOR.

Edited by

Associate Editor

Louis Bernard Klaczko

Publication Dates

Publication in this collection
19 Dec 2022
Date of issue
2022

History

Received
29 Dec 2021
Accepted
30 Oct 2022

This is an open-access article distributed under the terms of the Creative Commons Attribution License (type CC-BY), which permits unrestricted use, istribution and reproduction in any medium, provided the original article is properly cited.

[1] Ahrazem O, Diretto G, Argandoña Picazo J, Fiore A, Rubio-Moraga Á, Rial C, Varela RM, Macías FA, Castillo R, Romano E et al (2019) The specialized roles in carotenogenesis and apocarotenogenesis of the phytoene synthase gene family in saffron. Front Plant Sci 10:249.

[2] Azuma T, Pánek T, Tice AK, Kayama M, Kobayashi M, Miyashita H, Suzaki T, Yabuki A, Brown MW and Kamikawa R (2022) An enigmatic stramenopile sheds light on early evolution in Ochrophyta plastid organellogenesis. Mol Biol Evol 39:msac065.

[3] Bailey TL, Williams N, Misleh C and Li WW (2006) MEME: Discovering and analyzing DNA and protein sequence motifs. Nucleic Acids Res 34:W369-W373.

[4] Bartley GE, Viitanen PV, Bacot KO and Scolnik PA (1992) A tomato gene expressed during fruit ripening encodes an enzyme of the carotenoid biosynthesis pathway. J Biol Chem 267:5036-5039.

[5] Cárdenas PD, Gaijardo HA, Huebert T, Parkin IA, Iniguez-Luy FL and Federico ML (2012) Retention of triplicated phytoene synthase (PSY) genes in Brassica napus L. and its diploid progenitors during the evolution of the Brassiceae. Theor Appl Genet 124:1215-1228.

[6] Castresana J (2000) Selection of conserved blocks from multiple alignments for their use in phylogenetic analysis. Mol Biol Evol 17:540-552.

[7] Chaudhary N, Nijhawan A, Khurana JP and Khurana P (2010) Carotenoid biosynthesis genes in rice: Structural analysis, genome-wide expression profiling and phylogenetic analysis. Mol Genet Genom 283:13-33.

[8] Clotault J, Peltier D, Berruyer R, Thomas M, Briard M and Geoffriau E (2008) Expression of carotenoid biosynthesis genes during carrot root development. J Exp Bot 59:3563-3573.

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Species	Accesion number	Location on phylogeny	Expression data		Source
Species	Accesion number	Location on phylogeny	Development stadios	Anatomical parts	Source
Arabidopsis thaliana	AT5G17230.1	Subgroup E2	The expression was high in all stages, except in final ripening	The expression detected in almost all anatomical parts, with high expression level detected in sperm cell, mesophyll cell protoplast, root culture, seedling culture, shoot cell and tissues, leaf cell and tissues, inflorescence parts	^{Figure S8} Figure S8 - Gene expression analysis across developmental stages of Arabidopsis thaliana performed using GENEVESTIGATOR database. and ^S9 Figure S9 - Gene expression analysis across anatomical parts of Arabidopsis thaliana performed using GENEVESTIGATOR.
Glycine max	Glyma.14G209700	Subgroup E2	The expression was detected in all stages, with higher expression level in main shoot growth, stem elongation, inflorescence formation and flowering	Higher expression was detected in cotyledon, shoot apex, hypocotyl, flower, pod, pericarp (pod wall), shoot, stem internode, leaf, unifoliolate leaf, trifoliolate leaf, shoot apex, shoot apical meristem	^{Figure S10} Figure S10 - Gene expression analysis across anatomical parts of Glycine max performed using GENEVESTIGATOR. and ^S11 Figure S11 - Gene expression analysis across developmental stages of Glycine max performed using GENEVESTIGATOR.
	Glyma.02G240200	Subgroup E2	The expression was detected in all stages, with higher expression level in main shoot growth, stem elongation, inflorescence formation and flowering	Higher expression was detected in cotyledon, shoot apex, hypocotyl, flower, pod, pericarp (pod wall), shoot, stem internode, leaf, unifoliolate leaf, trifoliolate leaf, shoot apex, shoot apical meristem	^{Figure S10} Figure S10 - Gene expression analysis across anatomical parts of Glycine max performed using GENEVESTIGATOR. and ^S11 Figure S11 - Gene expression analysis across developmental stages of Glycine max performed using GENEVESTIGATOR.
	Glyma.14G031200	Subgroup E1	The expression was detected in all stages, with higher expression level in main shoot growth and inflorescence formation	Higher expression was detected in shoot apex, flower, pod, shoot, leaf, unifoliolate leaf, trifoliolate leaf shoot apex, shoot apical meristem	^{Figure S10} Figure S10 - Gene expression analysis across anatomical parts of Glycine max performed using GENEVESTIGATOR. and ^S11 Figure S11 - Gene expression analysis across developmental stages of Glycine max performed using GENEVESTIGATOR.
	Glyma.02G283400	Subgroup E1	The expression was detected in all stages, with higher expression level in main shoot growth and inflorescence formation	Higher expression was detected in shoot apex, flower, pod, shoot, leaf, unifoliolate leaf, trifoliolate leaf shoot apex, shoot apical meristem	^{Figure S10} Figure S10 - Gene expression analysis across anatomical parts of Glycine max performed using GENEVESTIGATOR. and ^S11 Figure S11 - Gene expression analysis across developmental stages of Glycine max performed using GENEVESTIGATOR.
	Glyma.18G111900	Subgroup E1	The expression was detected in all stages, with higher expression level in main shoot growth, inflorescence formation and flowering	Higher expression was detected in cotyledon, shoot apex, flower, pod, shoot, leaf, unifoliolate leaf, trifoliolate leaf, shoot apex, shoot apical meristem	^{Figure S10} Figure S10 - Gene expression analysis across anatomical parts of Glycine max performed using GENEVESTIGATOR. and ^S11 Figure S11 - Gene expression analysis across developmental stages of Glycine max performed using GENEVESTIGATOR.
	Glyma.08G306200	Subgroup E1	The expression was detected in all stages, with higher expression level in main shoot growth, inflorescence formation and flowering	Higher expression was detected in cotyledon, shoot apex, flower, pod, shoot, leaf, unifoliolate leaf, trifoliolate leaf, shoot apex, shoot apical meristem	^{Figure S10} Figure S10 - Gene expression analysis across anatomical parts of Glycine max performed using GENEVESTIGATOR. and ^S11 Figure S11 - Gene expression analysis across developmental stages of Glycine max performed using GENEVESTIGATOR.
	Glyma.18G000600	Subgroup E3	Low level of expression in all stages	Low expression was detected in root	^{Figure S10} Figure S10 - Gene expression analysis across anatomical parts of Glycine max performed using GENEVESTIGATOR. and ^S11 Figure S11 - Gene expression analysis across developmental stages of Glycine max performed using GENEVESTIGATOR.
Oryza sativa	LOC_Os09g38320	Subgroup M2	High level of expression in all stages	Higher expression was detected in seedling, coleoptile, leaf, root, radicle, panicle, spikelet, floret, stigma, ovary, panicle branch, peduncle, leaf, blade (lamina), central vein, collar	^{Figure S12} Figure S12 - Gene expression analysis across developmental stages of Oryza sativa performed using GENEVESTIGATOR. and ^S13 Figure S13 - Gene expression analysis across anatomical parts of Oryza sativa performed using GENEVESTIGATOR.
	LOC_Os06g51290	Subgroup M2	High level of expression in all stages	Higher expression was detected in seedling, leaf, panicle, spikelet, floret, ovary, panicle branch, shoot, leaf, blade (lamina), central vein	^{Figure S12} Figure S12 - Gene expression analysis across developmental stages of Oryza sativa performed using GENEVESTIGATOR. and ^S13 Figure S13 - Gene expression analysis across anatomical parts of Oryza sativa performed using GENEVESTIGATOR.
	LOC_Os12g43130	Subgroup M1	High level of expression in all stages	Higher expression was detected in shoot, leaf, blade (lamina), central vein, flag leaf	^{Figure S12} Figure S12 - Gene expression analysis across developmental stages of Oryza sativa performed using GENEVESTIGATOR. and ^S13 Figure S13 - Gene expression analysis across anatomical parts of Oryza sativa performed using GENEVESTIGATOR.
Sorghum bicolor	Sobic.002G292600	Subgroup M2	The expression was detected in all stages, with higher expression level in flowering stage	Medium expression was detected in all 9 anatomical parts with higher expression in leaf	^{Figure S14} Figure S14 - Gene expression analysis across developmental stages of Sorgum bicolor performed using GENEVESTIGATOR. and ^S15 Figure S15 - Gene expression analysis across anatomical parts of Sorgum bicolor performed using GENEVESTIGATOR.
Sorghum bicolor	Sobic.008G180800	Subgroup M1	The expression was detected in all stages, with higher expression level in stem elongation stage	Medium expression was detected in all 9 anatomical parts	^{Figure S14} Figure S14 - Gene expression analysis across developmental stages of Sorgum bicolor performed using GENEVESTIGATOR. and ^S15 Figure S15 - Gene expression analysis across anatomical parts of Sorgum bicolor performed using GENEVESTIGATOR.

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