Plant material and treatments

Seed were collected from wild P. chinensis and grown in Yangguangzhan (113.128926°E, 37.1422345°N) in Taiyuan City, Shanxi Province. Samples of P. chinensis seeds were authenticated by Professor Guoyue Zhong of Jiangxi University of Chinese Medicine. After pre-treatment, the seeds were sown on two layers of filter paper and placed in a controlled environment chamber set at 25°C and 12 h in the dark/12 h in the light.

Samples were taken 0, 2, 4 and 6 d after imbibition. Seeds were rinsed 2–3 times with PBS buffer. Surface moisture was absorbed, and the samples were frozen immediately in liquid nitrogen and stored at −80°C for transcriptome sequencing. Of the total of four treatments, each treatment was replicated three times.

RNA extraction, library construction and transcriptome sequencing

Total RNA was extracted from the 12 samples by using the Illumina Novaseq 6000 sequencing platform at Shanghai Majorbio Bio-pharm Biotechnology Co., Ltd. Sequencing experiments were performed using OmniPlant RNA Kit for library construction. The concentration and purity of the extracted RNA was tested by Nanodrop2000, RNA integrity was detected by agarose gel electrophoresis, and RIN was measured by Agilent2100. A single library construction required total RNA ≥ 1 μg, concentration ≥ 35 ng μl⁻¹, OD 260/280 ≥ 1.8 and OD 260/230 ≥ 1.0.

Magnetic beads with oligo(dT) for A-T base pairing with polyA were used to isolate the mRNA from the total RNA. Then, fragmentation buffer was added to randomly fragment the mRNAs, and small fragments of approximately 300 bp were isolated by magnetic bead screening. Under the action of reverse transcriptase, random hexamers were added to reversely synthesize one-strand cDNA by using mRNA as a template, followed by two-strand synthesis to form a stable double-strand structure. The double-stranded cDNA structure was a sticky end filled with End Repair Mix to make a blunt end, and then an ‘A’ base was added to the 3′ end to connect a Y-shaped adapter. Finally, the following steps were performed for Illumina onboard sequencing: (1) library enrichment, PCR amplification for 15 cycles; (2) addition of 2% agarose gel to recover the target band; (3) TBS380 (Picogreen) quantification, mixed in accordance with the data ratio; (4) bridge PCR amplification on cBot to generate clusters and (5) Illumina platform sequencing (PE library, read length 2 × 150 bp).

De-novo assembly and functional annotation

For transcriptome studies without reference genomes, after high-quality RNA-seq, data were obtained, all quality-controlled sequencing reads needed to be assembled de novo to generate contigs and singletons. The software used was Trinity (https://github.com/trinityrnaseq/trinityrnaseq/wiki) (Grabherr et al., Reference Grabherr, Haas, Yassour, Levin, Thompson, Amit, Adiconis, Fan, Raychowdhury, Zeng, Chen, Mauceli, Hacohen, Gnirke, Rhind, di Palma, Birren, Nusbaum, Lindblad-Toh, Friedman and Regev2011). After splicing was performed on Trinity, the assembly results were evaluated. The initial assembly sequence obtained generally needs to be optimized, filtered and re-evaluated. (1) TransRate (http://hibberdlab.com/transrate/) (Smith-Unna et al., Reference Smith-Unna, Boursnell, Patro, Hibberd and Kelly2016) and CD-HIT (http://weizhongli-lab.org/cd-hit/) were used to optimize filtering (Li and Godzik, Reference Li and Godzik2006). (2) For assembly evaluation, the software Benchmaking Universal Single-Copy Objects was used (http://busco.ezlab.org) (Simão et al., Reference Simão, Waterhouse, Ioannidis, Kriventseva and Zdobnov2015).

All transcripts obtained from the transcriptional group sequencing were compared with six databases (NR, Swiss-Prot, Pfam, COG, GO and KEGG databases) to obtain annotation information in each database and apply appropriate statistics to each database annotation. The Plant Transcription Factor Database was used to annotate transcription factors (TFs). (http://planttfdb.cbi.pku.edu.cn/) (Jin et al., Reference Jin, Tian, Yang, Meng, Kong, Luo and Gao2017).

Analysis of DEGs

The transcripts per million reads (TPM) values of all genes were used to analyse the correlation between each of the samples (Conesa et al., Reference Conesa, Madrigal, Tarazona, Gomez-Cabrero, Cervera, McPherson, Szcześniak, Gaffney, Elo, Zhang and Mortazavi2016). DESeq2 (Robles et al., Reference Robles, Qureshi, Stephen, Wilson, Burden and Taylor2012) was used for the analysis to further reveal the molecular events that occur during seed development, with expression levels expressed as |log2FC| > = 1 and adjusted P-value (P adjust) < 0.001 (Li et al., Reference Li, Zhang and Wang2014; Love et al., Reference Love, Huber and Anders2014; Gao et al., Reference Gao, Xue, Xue, Liu, Ren, Wang and Zhang2020), in at least one of the comparisons where DEGs were considered for further analysis.

DEGs were analysed for functional enrichment, including GO and KEGG enrichments (Ashburner et al., Reference Ashburner, Ball, Blake, Botstein, Butler, Cherry, Davis, Dolinski, Dwight, Eppig, Harris, Hill, Issel-Tarver, Kasarskis, Lewis, Matese, Richardson, Ringwald, Rubin and Sherlock2000; Kanehisa and Goto, Reference Kanehisa and Goto2000). Goatools was used for unigene/transcript GO enrichment analysis using Fisher's exact test. When P adjust < 0.05, the function was considered to be significantly enriched. The KEGG pathway was used for unigene/transcript enrichment analysis, and the calculation principle was the same as that in GO functional enrichment analysis. When P adjust < 0.05, the KEGG pathway was considered to be significantly enriched.

Proteins are involved in most biological processes in cells (Keskin et al., Reference Keskin, Tuncbag and Gursoy2016), but they rarely act on their own but mostly in complexes (Alberts, Reference Alberts1998; Charbonnier et al., Reference Charbonnier, Gallego and Gavin2008). Therefore, to fully understand the function of proteins, their interactions must be explored (Struk et al., Reference Struk, Jacobs, Sánchez Martín-Fontecha, Gevaert, Cubas and Goormachtig2019). Protein–protein interactions (PPIs) are an important aspect of plant systems biology (Struk et al., Reference Struk, Jacobs, Sánchez Martín-Fontecha, Gevaert, Cubas and Goormachtig2019). Identification of the interactors of a protein could help predict its function. In plants, most physiological processes are regulated by complex signal transduction pathways required for development, differentiation and adaptation to changing environments (Vanstraelen and Benková, Reference Vanstraelen and Benková2012). Identification of key protein players and their interaction networks provides important insights into the regulation of plant developmental processes and how plants interact with their environment (Struk et al., Reference Struk, Jacobs, Sánchez Martín-Fontecha, Gevaert, Cubas and Goormachtig2019). In the present study, the interactions between phytohormone signalling-related proteins were searched by using STRING (https://string-db.org/cgi). These protein interaction networks were visualized using Cytoscape software (Doncheva et al., Reference Doncheva, Morris, Gorodkin and Jensen2019).

Using the transcriptome sequencing results, the coding sequence (CDS) information of the core protein gene was obtained. The CDS of the gene was blasted in Nucleotide BLAST (https://blast.ncbi.nlm.nih.gov/Blast.cgi) to obtain the similarity sequence.

On this basis, Mega was used to calculate the similarity of sequences and construct a phylogenetic tree of genes. Among them, when using MEGA 11 software to build the best model of its phylogenetic tree, the number of bootstrap repetitions is 1000 times, and the tree-covering method is the neighbour-joining method (NJ).

qRT-PCR analysis

According to the sequenced transcriptome data of P. chinensis seeds during germination, the TPM value of gene expression was greater than 50, and the TPM value between samples was basically the same as the screening standard (Ma et al., Reference Ma, Cui, Wang, Jia, Duan, Du, Wang and Chen2019). The relative amounts of these genes were verified using qRT-PCR. The primer sequences were provided by Majorbio Bio.

The RNA was extracted from different samples following the instructions in the OmniPlant RNA Kit. The purity and concentration were checked by NanoDrop2000, and the integrity of the total RNA was examined using 1% agarose gel electrophoresis. The RNA was synthesized into cDNA in accordance with HiScript Q RT SuperMix for qPCR (+gDNA wiper, Novizan). The qRT-PCR reaction was performed using an ABI7500 fluorescence quantitative PCR instrument (Applied Biosystems, USA) and ChamQ SYBR Color qPCR Master Mix (2X) (Nanjing Novizan Biotechnology Co., Ltd). The following were used for the qRT-PCR reaction system: cDNA, 2 μl; upstream and downstream primers, 0.8 μl; 2X ChamQ SYBR Color qPCR Master Mix 10 μl, 50X ROX Reference Dye2, 0.4 μl and ddH₂O, 6 μl. The cycle conditions were as follows: pre-denaturation at 95°C for 5 min, followed by cycling for 40 rounds (melting at 95°C for 5 s, annealing at 55°C for 30 s and extension at 72°C for 40 s). After the above steps were completed, a 96-well plate with the sample added (10-fold dilution of cDNA) was placed in the ABI 7500 fluorescence quantitative PCR machine for reaction. The gene expression changes between different sample materials were calculated using the 2^−ΔΔCt method, with three biological replicates (Livak and Schmittgen, Reference Livak and Schmittgen2001).

Hormone treatment

After pre-treatment, the seeds were soaked in different concentrations of gibberellic acid (GA₃) and abscisic acid (ABA) at room temperature for 12 h. The control group (CK) was soaked with distilled water for 12 h. The GA₃ treatment concentrations were 50, 100, 150 and 200 mg l⁻¹, and the ABA treatment concentrations were 0.1, 1.0, 10 and 100 mg l⁻¹. The seeds were placed on a double-layer moistened filter paper (9-cm Petri dish) for germination light was provided for 12 h d⁻¹, the temperature was (25 ± 1)°C, and each treatment was repeated three times. The following germination parameters were calculated as follows:

1. a. Germination rate = germination number/total number of grains*100%;

2. b. Germination potential = the number of seeds germinated within the specified number of days/the total number of seeds*100% (Shi et al., Reference Shi, Zhang, Yu and Wei2005);

3. c. Germination index $( {\rm Gi}) = \sum ( {{\rm Gt}/{\rm Dt}} ) $ (Li and Piao, Reference Li and Piao2010) with Gt is the normal number of germinated seeds on each day and Dt is the corresponding germination days.