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Characterization of the REVEILLE family in Rosaceae and role of PbLHY in flowering time regulation

Abstract

Background

The circadian clock integrates endogenous and exogenous signals and regulates various physiological processes in plants. REVEILLE (RVE) proteins play critical roles in circadian clock system, especially CCA1 (CIRCADIAN CLOCK ASSOCIATED 1) and LHY (LATE ELONGATED HYPOCOTYL), which also participate in flowering regulation. However, little is known about the evolution and function of the RVE family in Rosaceae species, especially in Pyrus bretschneideri.

Results

In this study, we performed a genome-wide analysis and identified 51 RVE genes in seven Rosaceae species. The RVE family members were classified into two groups based on phylogenetic analysis. Dispersed duplication events and purifying selection were the main drivers of evolution in the RVE family. Moreover, the expression patterns of ten PbRVE genes were diverse in P. bretschneideri tissues. All PbRVE genes showed diurnal rhythms under light/dark cycles in P. bretschneideri leaves. Four PbRVE genes also displayed robust rhythms under constant light conditions. PbLHY, the gene with the highest homology to AtCCA1 and AtLHY in P. bretschneideri, is localized in the nucleus. Ectopic overexpression of PbLHY in Arabidopsis delayed flowering time and repressed the expression of flowering time-related genes.

Conclusion

These results contribute to improving the understanding and functional research of RVE genes in P. bretschneideri.

Peer Review reports

Background

The circadian clock regulates most of the metabolic and developmental processes of plants and synchronizes plants with external environmental conditions, which greatly enhances the adaptability and competitiveness of plants [1, 2]. The circadian clock system is composed of three parts: the input pathway, core oscillator, and output pathways [3]. Specifically, photoreceptors transmit environmental signals such as light and temperature to the core oscillator [4, 5]. Then, the core oscillator integrates information to regulate various physiological processes, such as flowering time, hormone signaling, biotic and abiotic stress [6]. The core oscillator mainly consists of three interlocked feedback loops, including a core loop and two closely related loops (morning loop and evening loop) [2]. CCA1 (CIRCADIAN CLOCK ASSOCIATED 1) and LHY (LATE ELONGATED HYPOCOTYL) are important components of the core loop [7]. In recent years, CCA1 and LHY, as hub genes, have attracted increasing attention.

In Arabidopsis, CCA1 is the first circadian clock gene to be cloned [8]. The expression pattern of CCA1 has a circadian rhythm, peaking at dawn [8]. LHY is highly similar to CCA1 in sequence and function [9]. Constitutive expression of CCA1 or LHY causes arrhythmicity and late flowering, whereas both single mutants (cca1 or lhy) and double mutants (cca1 lhy) exhibit shortened rhythmic periods and early flowering [10]. CCA1 and LHY can function as transcription factors in the circadian rhythm process. As transcription inhibitors, CCA1 and LHY negatively regulate the expression of GI (GIGANTEA) and TOC1 (TIMING OF CAB EXPRESSION 1); while as transcription activators, CCA1 and LHY promote the expression of PRR7 (Pseudo-Response Regulator) and PRR9 [11]. In addition, CCA1 and LHY play vital roles in flowering time. Flowering marks the transition from vegetative growth to reproductive growth, and the appropriate flowering time is crucial for reproduction [12]. It is well known that plants sense photoperiod changes and integrate light signals into the circadian clock to initiate or inhibit flowering. CCA1 and LHY are involved in regulating photoperiodic flowering by modulating GI-CO-FT pathways [13]. Moreover, many studies on the orthologs of CCA1 and LHY have also been implemented in other species, such as rice [14], soybean [15], maize [16], and barley [17].

Members of the MYB transcription factor superfamily play critical roles in plant development. MYB proteins are classified into four subfamilies according to the number of adjacent MYB repeats (R) [18]. Among them, CCA1 and LHY belong to the REVEILLE group of the MYB-related (1R-MYB) subfamily [19, 20]. Nine other proteins in A. thaliana also belong to this group, including RVE1-RVE8 and RVE7-like, all of which share the consensus sequence SHAQK(Y/F) F [21]. Except for RVE5 and RVE6, the expression of the remaining members is clock-regulated in seedlings [19]. Although CCA1 and LHY are essential regulators of the circadian clock, some other members of the 1R-MYB subfamily are also involved in this regulatory process. For example, RVE8 can directly promote the expression of GI and TOC1 by binding with the evening element (EE), as is the case for the repressors CCA1 and LHY [19, 22]. Similarly, RVE4 and RVE6 can also bind with the EE and might be functionally redundant with RVE 8[23]. Moreover, increasing evidence indicates that RVE proteins play important roles in other biological processes. RVE1 regulates the auxin biosynthetic gene to connect the circadian clock and auxin pathways [24]. RVE8 modulates anthocyanin biosynthesis by promoting anthocyanin gene expression around dawn [25]. RVE4 and RVE8 function as essential transcription factors to regulate plant thermotolerance [26]. CCA1, LHY, RVE4 and RVE8 can trigger cold-inducible gene expression [27]. To date, RVE proteins have also been reported in other species. GmMYB133, as an RVE homologous gene in soybean, is involved in isoflavonoid biosynthesis [28]. Transient overexpression of PbRVE1b improves anthocyanin content in P. bretschneideri fruit skin [29]. Ectopic overexpression of SgRVE6 in tobacco enhances cold tolerance [30]. Therefore, these results support that RVE proteins are significant for plant development.

Pear (Pyrus) is one of the representative fruits of Rosaceae species that is widely cultivated worldwide. Proper flowering and robust plant growth guarantee fruit quantity and quality. Although RVE proteins have been well studied in A. thaliana, the characterization of RVEs in Rosaceae species is limited. In this study, we identified 51 RVE genes from P. bretschneideri and six other Rosaceae species using published whole genome information. The phylogenetic relationship, chromosomal location, and evolutionary history were analyzed. Furthermore, we explored the protein motifs, gene structures and expression patterns of PbRVEs. Specifically, we demonstrate the function of PbLHY in repressing flowering time by ectopic transgenic analysis in A. thaliana. The results of this work contribute to further determining the functions of RVEs in Rosaceae species.

Results

Identification and phylogenetic analysis of RVE genes in seven Rosaceae species

To obtain the members of RVE families in seven Rosaceae species genome, including Pyrus bretschneideri, Malus domestica, Prunus mume, Prunus avium, Prunus persica, Rubus occidentalis, Fragaria vesca, an HMMER-BLASTP strategy was first used to search for the homologs with HMM profile (PF000249) and RVE protein sequences of A. thaliana were used as queries. RVE proteins have a single conserved MYB domain with a SHAQK(F/Y) F sequence. The candidate proteins were further verified by NCBI Batch CD-Search and multiple sequence alignment. In total, fifty-one RVE members were identified in this study: five in R. occidentalis, five in F. vesca, ten in M. domestica, ten in P. bretschneideri, seven in P. mume, seven in P. avium, and seven in P. persica (Fig. 1 and Table S1).

Fig. 1
figure 1

The evolutionary relationships, genome information, and the number of RVE genes in Arabidopsis and seven Rosaceae species. The black stars and the corresponding numbers above indicate the divergent events and the occurrence time, respectively. The first event (~ 115-130 MYA) was the ancient WGD event that occurred between A. thaliana and Rosaceae species, and the second event (30-45 MYA) was a recent WGD event that occurred before Malus domestica and Pyrus bretschneideri. MYA: millions of years ago

Pbr025890.1 with an incomplete MYB domain was identified as a homolog of AtCCA1 and AtLHY by BLASTP in the Chinese white pear genome [31]. However, the protein sequence of XP_009335251 (the corresponding ID of Pbr025890.1 in the NCBI database) with a complete MYB domain showed 38.18% and 45.24% sequence similarity with AtCCA1 and AtLHY, respectively (Fig. S1). Therefore, we retained this protein as a member of the PbRVE family and named it PbLHY. The protein sequence downloaded from NCBI was used for subsequent analysis. In addition, other PbRVE genes were named according to their homologous genes in A. thaliana.

To investigate the evolutionary relationships of the RVE family between Rosaceae species and A. thaliana, we constructed a maximum-likelihood phylogenetic tree using putative protein sequences. Based on the topology of the phylogenetic tree and the classification of RVEs in A. thaliana, all proteins from eight species were clearly divided into two groups, namely, subfamily I and subfamily II (Fig. 2). PbRVEs containing an additional LCL (LHY/CCA1-Like) domain were assigned to subfamily II, whereas PbRVEs without this domain were assigned to subfamily I (Fig. S2). The phylogenetic tree showed that the majority of Rosaceae RVE members were clustered together with A. thaliana RVE proteins. However, the number of RVE genes in M. domestica and P. bretschneideri was greater than that in the other five species, which is likely because of the lineage-specific whole-genome duplication (WGD) event (30-45 MYA) that occurred before the split of Malus and Pyrus lineages (Fig. 1).

Fig. 2
figure 2

Phylogenetic tree of RVE proteins in Arabidopsis and seven Rosaceae species. The blocks in brown and gray represent members in subfamilies I and II, respectively. The RVE proteins in Pyrus bretschneideri are labeled in red, and the RVE proteins in A. thaliana are labeled in blue

Chromosomal location and evolution events of RVE genes

To analyze the genomic distribution characteristics of RVE members, the locations of 51 RVE genes in seven Rosaceae species were detected (Table S1). Eight PbRVEs were mapped onto eight out of 17 P. bretschneideri chromosomes, and another two PbRVEs (PbRVE3b and PbRVE6a) were located on the scaffolds. We also found that five FvRVEs were located on three F. vesca chromosomes, five PmRVEs on four P. mume chromosomes, seven PaRVEs on four P. avium chromosomes, ten MdRVEs on seven M. domestica chromosomes, seven PpRVEs on four P. persica chromosomes, and five RoRVEs on three R. occidentalis chromosomes (Fig. 3a). Notably, RVE genes of different species were unevenly distributed across the chromosomes.

Fig. 3
figure 3

Gene intragenomic collinearity and duplication events analysis of the RVE family in Rosaceae species. (a) Localization and intragenomic collinearity of RVE genes. The seven colored circles represent the chromosomes of the seven Rosaceae species. The approximate positions of RVE genes are marked with short black lines on the circles. The yellow lines represent gene pairs with syntenic relationships. Genes located on the scaffolds are not shown. (b) Statistics for different duplication events in seven species, including Pyrus bretschneideri, Malus domestica, Prunus avium, Prunus persica, Prunus mume, Fragaria vesca and Rubus occidentalis. The five colored rectangles represent different events, DSD (green), PD (brown), TD (pink), TRD (orange), and WGD (blue). The Y-axis of the left column chart represents the number of duplicated gene pairs in each event. The X-axis of the right column chart represents the percentage of the duplicated gene pairs in each event

Gene duplication events contribute to driving the expansion of gene families and generating new functions. We investigated the duplication events of RVE genes using the DupGen_finder pipeline. Five modes, including WGD, transposed duplication (TRD), tandem duplication (TD), proximal duplication (PD), and dispersed duplication (DSD), were detected with different contributions to the RVE family in seven Rosaceae species (Fig. 3b and Tables S2, S3). DSD was the dominant event, accounting for 60% of the 63 RVE duplicated gene pairs. In P. bretschneideri and M. domestica, RVE gene pairs were only derived from DSD and WGD, which were almost evenly distributed. Interestingly, the numbers and percentages of RVE genes originating from DSD, TRD and WGD were equal in F. vesca and R. occidentalis; the numbers and percentages of RVE genes originating from DSD, TRD, TD and WGD were equal in P. mume and P. persica.

The Ks value is used to estimate the evolutionary time of duplication events, such as the recent WGD (Ks ~ 0.15-0.3) and the ancient WGD (Ks ~ 1.5-1.8) of the P. bretschneideri genome [31]. In our study, the Ks value of P. bretschneideri RVE gene pairs ranged from 0.023 to 2.585 (Table S3). Among them, PbRVE6c and PbRVE6a had the lowest Ks value, while PbRVE3b and PbRVE7 had the highest Ks value. In addition, the Ks values of the other six Rosaceae species varied in different ranges. Next, we calculated Ka/Ks ratios to estimate the selection pressure driving the evolution of the RVE family. The ratios of all RVE gene pairs were lower than one, indicating that purifying selection was the main evolutionary driving force on RVE families in Rosaceae species (Table S3).

Protein and gene feature analysis of RVE members in P. bretschneideri

To further explore the conservation and diversity of PbRVE family members, we analyzed the features of their protein and gene sequences. The protein length of PbRVEs ranged from 226 to 777 amino acids (Table S1). Ten putative motifs were identified by the MEME tool (Fig. 4a and Fig. S3). All members of the PbRVE family contained motifs 1, 3, and 4, which represented the single conserved MYB domains. Motif 2, characterized as the LCL domain, was detected in all members of subfamily II. Motif 7 was identified only in all members of subfamily I. Motifs 6 and 8 were unique in some members of subfamily I, while motifs 9 and 10 appeared only in some members of subfamily II. These results supported the phylogenetic relationship and classification of the RVE family, and the specific motif patterns of different branches suggested that there might be functional divergence in these RVE members.

Fig. 4
figure 4

Analysis of the conserved motifs and gene structures of RVE genes in Arabidopsis and Pyrus bretschneideri. (a) Conserved motifs of PbRVE and AtRVE proteins. Ten conserved motifs were predicted by MEME. Different colored boxes represent different motifs. The proteins are arranged according to the phylogenetic tree. PbRVE proteins are labeled with yellow circles, and AtRVE proteins are labeled with green squares. (b) Exon–intron structure of PbRVE and AtRVE genes. Blue boxes, orange boxes, and gray lines represent exons, UTRs and introns, respectively

To analyze the structural characteristics of RVE genes, exon–intron compositions were investigated by the Gene Structure Display Server (GSDS) tool (Fig. 4b). The numbers of exons/introns were generally similar between RVE genes in P. bretschneideri and A. thaliana. Moreover, members in the same subfamilies shared relatively conserved gene structures. For example, the numbers of exons ranged from five to seven in subfamily I, whereas they ranged from seven to eight in subfamily II.

Cis-element analysis of putative PbRVE promoters

To elucidate the potential regulatory functions of PbRVE genes, 1500 bp promoter regions (upstream of the start codons) were obtained and analyzed by the PlantCARE tool. The promoter region of each gene was enriched with multiple cis-elements. Next, we focused on the cis-elements related to plant hormones, low temperature and light response in the promoters of PbRVEs (Table 1). All PbRVE genes except PbLHY might be involved in the abscisic acid response. Among them, PbRVE1a, PbRVE3a and PbRVE6a contained more than five ABRE cis-elements. Meanwhile, cis-elements related to auxin, gibberellin and MeJA responses were identified in the majority of PbRVEs. Notably, the promoters of eight PbRVEs contained LTR cis-elements, indicating that PbRVE genes might play roles in the low-temperature response. As expected, light-responsive elements were highly conserved in the promoter of PbRVEs. Specifically, only PbLHY contained one MRE element (MYB binding site involved in light responsiveness), and the rest of the PbRVEs contained different numbers of G-box elements.

Table 1 Types and numbers of responsive elements in the promoter regions of PbRVE genes

Expression analysis of RVE genes in P. bretschneideri

To explore the potential functions of PbRVE genes, we first examined their specific expression levels in five tissues using a quantitative real-time PCR (qRT–PCR) assay. PbRVE genes displayed diverse expression patterns in different tissues (Fig. 5). Most members were highly expressed in leaves. For example, PbLHY, PbRVE1a, and PbRVE8, except for a small amount of transcription in flowers, were mainly expressed in leaves, suggesting that they may play critical roles in leaves. In addition, PbRVE3a, PbRVE3b and PbRVE6b shared similar expression profiles with higher expression levels in roots than in other organs. PbRVE6a was detected in all five tissues, and the expression level was the highest in the stem.

Fig. 5
figure 5

Tissue-specific expression patterns of PbRVE genes. The expression patterns of ten PbRVEs were detected in the roots, stems, leaves, flowers, and fruits of Pyrus bretschneideri trees using qRT–PCR. PbUBQ was used as an internal control. The highest expression level of each gene was set to 1 for standardized calculation. Error bars represent the standard error

Previous studies have well proven that partial RVEs (CCA1, LHY and RVE8) are key circadian clock components in A. thaliana [2]. The expression of these genes was clock-regulated and showed rhythmic oscillations in seedlings [19]. To investigate the responses of PbRVE genes to the diurnal cycle and circadian clock, we detected the expression changes of PbRVE genes in P. bretschneideri leaves under 12-h light/12-h dark conditions (Fig. 6) and constant light conditions (Fig. 7). Under light/dark cycles, all PbRVE genes exhibited diurnal rhythms that could be divided into three types (Fig. 6). The expression of PbLHY and PbRVE3a peaked at dawn (zeitgeber time 1; ZT 1), then dropped steeply during the day and increased slightly before dawn. In P. bretschneideri, PbLHY, as the only homologous gene of AtCCA1 and AtLHY, shared the same expression pattern as the two genes in A. thaliana. In contrast, several PbRVE genes showed the highest expression levels before dawn (ZT 21), such as PbRVE1a and PbRVE1b. PbRVE6a showed a completely different pattern, characterized by a peak in the evening (ZT 17).

Fig. 6
figure 6

Diurnal expression patterns of PbRVE genes under 12-h light/12-h dark conditions. The time of the light beginning to turn on was defined as zeitgeber time zero (ZT 0). Starting from ZT1, leaves were harvested every 4 h for a total of 6 times throughout the whole day. White and black areas indicate light and darkness, respectively. PbUBQ was used as an internal control. The highest expression level of each gene was set to 1 for standardized calculation. Error bars represent the standard error

Fig. 7
figure 7

Circadian expression patterns of PbRVE genes under constant light conditions. The time of the light beginning to turn on was defined as zeitgeber time zero (ZT 0). Starting from ZT1, leaves were harvested every 4 h for a total of 18 times over three days. White and gray areas indicate subjective day and subjective night, respectively. PbUBQ was used as an internal control. The highest expression level of each gene was set to 1 for standardized calculation. Error bars represent the standard error

Circadian-controlled rhythms still persist with robust rhythms when a plant is transferred to a constant light environment (free-running conditions) [3]. In our study, after growing in 12-h light/12-h dark conditions for a time, P. bretschneideri seedlings were treated with constant light for three days, and the expression patterns of PbRVE genes were detected. The expression of PbLHY, PbRVE1a, PbRVE7 and PbRVE8 was clock-regulated (Fig. 7). The peak time on the first day was similar to that under light/dark cycles, occurring near dawn. As time progressed (the second and third days), they maintained the circadian rhythm, but the period lengthened and the expression amplitude decreased. In conclusion, PbLHY, PbRVE1a, PbRVE7 and PbRVE8 showed diurnal and circadian rhythms, implying that they might be involved in the circadian clock system.

Subcellular localization of PbLHY protein

In A. thaliana, CCA1 and LHY function as transcription factors and are localized in the nucleus [20]. To further examine the role of PbLHY, subcellular localization was performed using a construct with the full coding region of PbLHY fused to green fluorescent protein (GFP). When the construct was transiently transformed into leaf epidermal cells of tobacco, a fluorescent signal of PbLHY-GFP was observed in the nucleus (Fig. 8), indicating that PbLHY is a nuclear-localized protein.

Fig. 8
figure 8

Subcellular localization of the PbLHY-GFP in tobacco leaf epidermal cells. The images were obtained using laser scanning confocal microscopy. Green represents GFP fluorescence. Blue represents DAPI staining as the nuclear marker. The empty vector of 35S: GFP was used as a control. Bar = 20 μm

Overexpression of PbLHY delayed flowering in A. thaliana

Considering the high similarity between PbLHY and A. thaliana CCA1/LHY in sequence characteristics and expression patterns, we selected PbLHY for further functional study on regulating flowering time. In A. thaliana, lhy-1 mutation, which was an AtLHY overexpression line, caused late flowering under long-day conditions [10]. Due to the lack of a dependable transformation system and the extremely long time from seedling to florescence in P. bretschneideri, we transformed PbLHY into A. thaliana to observe the flowering phenotype. PbLHY showed significantly high expression levels in two independent transgenic lines but was not detected in the vector control plants (transformed with an empty vector) (Fig. 9d). Under long-day (16 h light/8 h dark) conditions, we counted the number of days and rosette leaves when the first flower bud opened. PbLHY overexpression (OE) lines exhibited an obviously delayed flowering phenotype (Fig. 9a). The average flowering time of the control plants was 32.58 days, while that of the PbLHY-OE lines was 39.78 days and 43.90 days (Fig. 9b). The number of rosette leaves in PbLHY-OE lines increased significantly compared with that in control plants (Fig. 9c), suggesting that PbLHY might play a conserved role in suppressing flowering.

Fig. 9
figure 9

Overexpression of PbLHY delayed flowering in Arabidopsis. (a) Flowering phenotypes of representative control plants and PbLHY-OE lines grown under long-day conditions for six weeks. (b) and (c) The number of days and rosette leaves were recorded in control and PbLHY-OE lines when the first flower was visible. *** p < 0.001 vs. vector control by t test. (d) Expression of PbLHY in control and PbLHY-OE lines. (e-g) Expression of AtGI, AtCO, and AtFT in control and PbLHY-OE lines. Transcript levels were measured by qRT–PCR assay in 12-day-old seedlings under long-day conditions and normalized to AtACT. The highest expression level of each gene was set to 1 for standardized calculation. Error bars represent the standard error. White and black areas indicate light and darkness, respectively

Furthermore, we assessed the effect of PbLHY on flowering time-related genes in A. thaliana, including AtGI, AtCO, and AtFT. Although the expression waveforms of AtGI and AtCO in PbLHY-OE lines were similar to those in control plants, the expression levels were changed at different time points. For example, AtGI transcripts were significantly repressed at ZT9 (Fig. 9e), and AtCO transcripts were reduced at ZT13 and ZT21 (Fig. 9f) in both PbLHY-OE lines. The expression levels of AtFT were also decreased in PbLHY-OE lines at several time points during the day (Fig. 9g). The results indicated that PbLHY might delay flowering and accompanied by repression of these key factors.

Discussion

The life cycle of flowering plants includes vegetative growth and reproductive growth. Flowering is a symbolic process of the plant transition from vegetative development to reproductive growth. Several pathways and numerous genes have been implicated in regulating flowering, among which circadian clock genes play essential roles [32]. Most plants have evolved an endogenous circadian clock system to adapt to the periodic changes caused by the Earth’s rotation [33]. In addition to flowering, circadian clock genes also influence multiple physiological processes, such as plant growth, hormone signaling, metabolism and stress response. CCA1 and LHY are considered to be the most central genes for clock functions [2]. However, CCA1 and LHY in P. bretschneideri have not been previously reported. In this study, we performed an evolutionary analysis of the RVE family in seven Rosaceae species and found that PbLHY delay flowering time in A.thaliana. This result suggested that PbLHY may act as flowering time repressor.

Over the past decades, the MYB superfamily has been extensively studied. Genome-wide identification of MYB family members has been carried out in several species, such as A. thaliana [18], apple [34], pear [35, 36], peach [37], and strawberry [38]. Based on the number of repeats, MYB proteins are classified into four subfamilies: MYB-related (which contain a single MYB-like domain), R2R3, R1R2R3, and 4R [18]. It is considered that the MYB family has been selectively extended in plants, especially through the R2R3 subfamily. Therefore, previous studies focused more on the analysis of R2R3-MYB [39]. However, increasing evidence has shown that MYB-related members also play important roles in multiple stages of plant development, particularly the RVE group to which CCA1 and LHY belong [30, 40,41,42]. Because the RVE group is a small branch of the MYB superfamily, it is necessary to conduct detailed analysis to avoid missing important members. Although several studies have identified MYB family members in pear [29, 35, 36], we still obtained new members through strict screening. We identified ten RVE genes in P. bretschneideri, among which PbLHY, PbRVE6b and PbRVE6c were reported for the first time.

In A. thaliana, the RVE family, including 11 proteins, is divided into two subfamilies according to the MYB and LCL domains [22]. All RVE proteins in the seven Rosaceae species and A. thaliana were clustered into two groups in our results, but the number of RVE members in different species was obviously distinct. P. bretschneideri (10) and M. domestica (10) had a similar number of RVE members to A. thaliana, while F. vesca (5) and R. occidentalis (5) had only half the number of A. thaliana. In addition, P. mume, P. avium, and P. persica belong to Prunoideae with the same number of RVE proteins, seven. P. bretschneideri and M. domestica belong to Maloideae with the same number of RVE proteins, ten. The phenomenon also occurred with F. vesca and R. occidentalis, both of which belong to Rosoideae [43]. It has been reported that a recent WGD has occurred in Maloideae [31]. Therefore, WGD might be one of the primary driving forces for the expansion of the RVE family in P. bretschneideri and M. domestica. To further investigate the evolutionary process of RVE genes in Rosaceae, we analyzed gene duplication events in each species. Overall, DSD was the main duplication event of RVE genes in Rosaceae. DSD is ubiquitous in plant genomes and occurs in unpredictable and random patterns, producing two gene copies that are neither adjacent nor collinear [44]. The events of the RVE gene family in P. bretschneideri and M. domestica were only a WGD in addition to DSD, which clearly indicated that WGD was another main driving force for the evolution and expansion of these two RVE families. Meanwhile, the types of duplication events were similar between Rosaceae species that were more closely related. Since duplication events contribute greatly to the evolution and function of genes [45], it is worthwhile to understand RVE family members by analyzing gene duplication events.

In A. thaliana, RVE genes play important roles in controlling the circadian clock, photoperiod flowering, anthocyanin biosynthesis, hormone signaling, and stress responses [10, 24,25,26]. In our study, the expression pattern of PbRVEs varied in different tissues, indicating that PbRVEs may have potential functions in plant development. For example, PbLHY and PbRVE8 were highly expressed in leaves, which was consistent with previous reports of homologs in poplar [46], rice [47], and mungbean [48]. Leaves are the main sites for sensing light signals and measuring time [49], and the high expression of these genes in leaves suggested that they may participate in the photoperiod pathway of P. bretschneideri. Meanwhile, we examined the expression of PbRVE genes under light/dark cycles and constant light conditions to explore their expression characteristics in leaves. PbLHY, PbRVE1a, PbRVE7, and PbRVE8 exhibited both typical diurnal and circadian rhythms, peaking around dawn. These genes not only have highly conserved structures and motifs but also have the same expression patterns as their homologs in A. thaliana [10, 19], suggesting that they may play similar roles in circadian clock regulation in P. bretschneideri. Additionally, transcripts of many RVE genes showed relatively high levels in roots, such as PbRVE3b and PbREVE6b. The function of RVE genes in roots has rarely been reported before. Recently, transcriptome analysis of Juglans regia and Medicago truncatula found that RVE genes may be involved in the nitrogen metabolic pathway [50, 51]. Moreover, RVE genes had diverse expression patterns in different developmental stages of jujube fruit [52], and PbRVE1b promoted anthocyanin accumulation in P. bretschneideri peel [29]. In our study, PbRVE3b and PbRVE6c were also highly expressed in fruit, implying that they may be involved in P. bretschneideri fruit development.

PbLHY, which was the only homolog of CCA1 and LHY in P. bretschneideri, was filtered in the P. bretschneideri genome due to the lack of conserved residues. However, the full-length PbLHY gene containing the complete conserved domain was cloned. Our results complemented the conservation of circadian clock genes in plants [33]. Furthermore, the nuclear localization of PbLHY indicated that it may function as a transcription factor similar to CCA1 and LHY in A. thaliana [20]. In long-day representative plants such as A. thaliana, the dynamic interaction of photoperiodic flowering is largely controlled by the level of GI-CO-FT module activity [13]. In short-day plants, such as rice, OsGI-Hd1-Hd3a is the parallel module [49]. In both of these annual model plants, AtCCA1/AtLHY and OsLHY affect flowering mainly through that conserved pathway [13, 47]. Overexpressing PbLHY could delay flowering in transformed A. thaliana. The expression of GI, CO, and FT was repressed at different time points in PbLHY-OE lines. Thus, we proposed that PbLHY was the candidate gene as a circadian clock component and regulated flowering in P. bretschneideri. Further studies will focus on confirming this hypothesis and exploring more functions of the PbRVE genes.

Conclusions

In this study, we identified 51 RVE genes in seven Rosaceae species and investigated their evolutionary characteristics, such as phylogenetic relationship, chromosomal locations, and duplication events. Then, a systematical analysis was carried out to study RVE members in P. bretschneideri. Based on the analysis of gene structures, conserved motifs, and phylogenetic tree, PbRVE genes were clustered into two subfamilies. The expression levels of ten PbRVE genes varied among P. bretschneideri tissues. Under 12-h light/12-h dark conditions, ten PbRVE genes exhibited diurnal rhythms; among them, four PbRVE genes also exhibited rhythms under constant light conditions. In addition, overexpression of PbLHY could delay flowering time in transgenic A. thaliana plants. These results provide evidence for the functional verification of the P. bretschneideri clock genes and represent a foundation for further functional characterization of RVE genes in Rosaceae.

Methods

Collection of genome data and identification of RVE genes

The genome sequence of Chinese white pear (Pyrus bretschneideri) was downloaded from the Pear Genome Project (http://gigadb.org/dataset/100083) [31]. The genome sequences of M. domestica [53] and P. persica [54] were downloaded from Phytozome (https://phytozome-next.jgi.doe.gov). The genome sequences of R. occidentalis [55], F. vesca [56], P. avium [57], and P. mume [58] were downloaded from the Genome Database for Rosaceae (GDR; https://www.rosaceae.org/). The genome sequence of A. thaliana was downloaded from the Arabidopsis Information Resource (TAIR; http://www.Arabidopsis.org/) [59]. Protein sequences of 11 AtRVEs were used as queries to perform BLASTP searches against the seven Rosaceae genome databases (P value <1e− 10). Protein sequences of candidate RVEs in the seven Rosaceae species were analyzed by Pfam and SMART to verify the MYB domain. The sequences without the MYB domain were deleted.

Phylogenetic analysis and multiple sequence alignment

The RVE protein sequences of the seven Rosaceae species and A. thaliana were aligned by MAFFT v7.0 (https://mafft.cbrc.jp/alignment/software/) [60]. The results of multiple sequence alignment were visualized by Jalview (http://www.jalview.org/). The maximum likelihood phylogenetic tree of the RVE family was created by iqtree (http://www.iqtree.org/) (bootstrap =1000) and visualized by iTOL (https://itol.embl.de/).

Collinearity analysis and Ka and Ks calculation

Collinearity analysis among the seven Rosaceae genomes was conducted locally using a method similar to that developed for the Plant Genome Duplication Database (http://chibba.agtec.uga.edu/duplication/) [61]. Candidate homologous RVE gene pairs were identified using DIAMOND software with the parameters --bin 2 --max-target-seqs 5 --e-value 1e− 10. Then, the RVE gene pairs and their chromosome location information were fed into MCScanX software to identify the collinear chains with default parameters. Genes located on the scaffolds were removed. The result was visualized by TBtools [62]. Duplication events in the RVE gene family were identified using the DupGen_finder pipeline [45]. The nonsynonymous substitution rates (Ka) and the synonymous substitution rates (Ks) of homologous RVE gene pairs in each Rosaceae species were calculated by KaKs_Calculator 2.0 using the Nei-Gojobori method [63].

Conserved motifs, gene structures and cis-regulatory element analysis

Conserved motifs of RVE proteins in the seven Rosaceae species were analyzed by MEME tool v5.0.5 (http://meme-suite.org/tools/meme) [64] with the following parameters: maximum numbers of different motifs--10. Gene structures of RVEs in the seven Rosaceae species were plotted by the Gene Structure Display Server (http://gsds.cbi.pku.edu.cn/) [65]. These results were visualized by TBtools. The 1500 bp sequences ahead of the initiation codon (ATG) of PbRVE genes were downloaded from the Pear Genome Project [31]. Cis-acting regulatory elements of PbRVE genes were obtained using the PlantCARE database (http://bioinformatics.psb.ugent.be/webtools/plantcare/html/) [66].

Plant materials and growth conditions

For tissue-specific expression analysis, all materials were harvested from ten-year-old Pyrus bretschneideri Rehd. cultivar ‘Dangshansuli’ trees grown in the Nanjing Agricultural University Experimental Field, China. The harvested seeds from ‘Dangshansuli’ trees were vernalized at 4 °C in sand for 2 months. Then, the rooted seedlings were selected and transferred to a room with settings of 22 °C, 100 μmol m− 2 s− 1 light, and 65% relative humidity. All seedlings had grown under 12-h light/12-h dark conditions for 30 days. The time of the light beginning to turn on was defined as zeitgeber time zero (ZT 0). For diurnal rhythm analysis, leaves of seedlings were collected every 4 h for one day. For circadian rhythm analysis, seedlings were released to constant light, and the leaves were collected every 4 h for 3 days. The leaves of three seedlings with uniform growth were randomly selected as a mixed sample at the designated time point. Three independent biological repeats were collected for the experiments. All samples were frozen immediately in liquid nitrogen and stored at − 80 °C.

A. thaliana plants were grown under long-day conditions (16-h light/8-h dark) in the controlled room with settings of 22 °C, 100 μmol m− 2 s− 1 light, and 65% relative humidity. Seeds of transgenic A. thaliana plants were sterilized and screened on Murashige and Skoog (MS) medium with 20 mg L− 1 hygromycin. Flowering phenotypes were observed in the T3 generation. For gene expression analysis, seeds were grown in MS medium for 12 days, and then the seedlings were collected every 4 h for one day.

RNA extraction and quantitative real-time PCR (qRT–PCR)

Total RNA was extracted from frozen tissues using a Plant Total RNA Isolation Kit (FOREGENE, Chengdu, China) specifically designed for plants rich in polysaccharides and polyphenols. One microgram of total RNA was reverse transcribed in a 20 μl reaction volume using One-Step gDNA Removal and cDNA Synthesis SuperMix (TransGen Biotech, Beijing, China). Gene-specific primers of PbRVEs were designed by Primer Premier 5.0 software, and the specificity was verified by the Primer search program against the P. bretschneideri genome (Table S4). To test relative gene expression levels, qRT–PCR was performed using SYBR Green I Master Mix (Roche, Germany) in a Roche LightCycler 480 II. The reactions were prepared in a total volume of 20 μl containing 0.1 μl of cDNA, 5 μl of 0.5 μM gene-specific primer premix, 10 μl of 2 × SYBR Green Master Mix, and 4.9 μl of water. Data were calculated using the 2-ΔCT method. PbUBQ (POLYUBIQUITIN) of P. bretschneideri or AtACT (ACTIN) of A. thaliana was used as the reference control to normalize the expression of the target genes. Three biological replicates and three technical replicates were used for each experiment. All qRT–PCR experiments followed MIQE guidelines [67].

Subcellular localization and A. thaliana transformation

Full-length cDNA without the termination codon of PbLHY was amplified by PCR. The product was inserted into the pCAMBIA1300-35S: CDS-GFP vector [68] using the ClonExpress II One Step Cloning Kit (Vazyme Biotech, Nanjing, China). After sequencing, the recombinant plasmid and vector control plasmid were transformed into Agrobacterium competent GV3101 cells. For the subcellular localization assay, Agrobacterium-mediated transient expression in tobacco (Nicotiana benthamiana) leaves was performed according to a published protocol [69]. DAPI (Thermo Fisher Scientific, US) was used as a nuclear counterstain. The fluorescence in the transformed cells was imaged under a laser scanning confocal microscope LSM800 (Zeiss, Germany). For the A. thaliana transformation assay, the above Agrobacterium strains were transformed into A. thaliana (Columbia-0) plants using the floral dip method [70]. The PbLHY transgenic lines were confirmed by PCR with gene-specific and vector primers (Table S4). The transgenic lines of the T3 generation were used to observe the phenotypes and perform other analyses. Seeds of T3 generation were also sterilized and screened on MS medium with 20 mg L− 1 hygromycin. After 3 days of vernalization, the seeds were grown under long-day conditions mentioned above. The time of the seeds normally exposed to light was defined as the beginning day. And flowering days were counted from the beginning day to the first flower opening after bolting. At the same time, the number of rosette leaves was counted.

Availability of data and materials

All data used in this study are included in this article and additional flies. All genome sequence used in this study are publicly available in: A. thaliana (http://www.Arabidopsis.org/), P. bretschneideri (http://gigadb.org/dataset/100083), M. domestica and P. persica (https://phytozome-next.jgi.doe.gov), R. occidentalis, F. vesca, P. avium, and P. mume (https://www.rosaceae.org/).

Abbreviations

RVE:

REVEILLE

CCA1:

CIRCADIAN CLOCK ASSOCIATED 1

LHY:

LATE ELONGATED HYPOCOTYL

GI:

GIGANTEA

TOC1:

TIMING OF CAB EXPRESSION 1

PRR7:

Pseudo-Response Regulator 7

CO:

CONSTANS

FT:

FLOWERING LOCUS T

LCL:

LHY/CCA1-Like

UBQ:

POLYUBIQUITIN

ACT:

ACTIN

WGD:

whole-genome duplication

TRD:

transposed duplication

TD:

tandem duplication

PD:

proximal duplication

DSD:

dispersed duplication

MYA:

million years ago

qRT–PCR:

quantitative real-time PCR

ZT:

zeitgeber time

GFP:

green fluorescent protein

OE:

overexpression

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Acknowledgements

We thank the Bioinformatics Center of Nanjing Agricultural University for supporting bioinformatic analysis. We thank Dr. Yuehua Ma (Central laboratory of College of Horticulture, Nanjing Agricultural University) for assistance in using laser scanning confocal microscope LSM800.

Funding

This work is supported by National Key Research and Development Program of China (2020YFE0202900); Fundamental Research Program of Shanxi Province (20210302124231); the National Natural Science Foundation of China (31501715); Jiangsu Agricultural Science and Technology Innovation Fund (CX(22)3044); the guidance foundation of Hainan Institute of Nanjing Agricultural University (NAUSY-MS08); Outstanding Talent for Agricultural Research Project (13210324); the Earmarked Fund for China Agriculture Research System (CARS-28).

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All authors contributed to the research planning and experimental designs; P. W., J. W., S. Z. initiated and supervised the project; Z. L., X. Z., W. L., K. Q., and Z. X. performed the experiments and analyzed the data; Z. L. and P. W. wrote the manuscript. All authors read and approved the manuscript.

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Correspondence to Peng Wang.

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Supplementary Information

Additional file 1: Fig. S1.

(a) Coding sequence of PbLHY. (b) Alignment of PbLHY and AtCCA1/AtLHY protein sequences. The red box indicates the MYB domain. The blue backgrounds correspond to the percent identity of the multiple alignment. Fig. S2. Alignment of conserved domains from PbRVE proteins. (a) Alignment of MYB domains from ten PbRVEs and eleven AtRVEs. Red box indicates MYB domain, and blue box indicates SHAQK(Y/F) F sequence. (b) Alignment of LCL domains from subfamily II members. The red box indicates the MYB domain. The green box indicates the LCL domain. The blue backgrounds correspond to the percent identity of the multiple alignment. Fig. S3. The motif details of ten conserved domains identified in RVE proteins and the logos of these domains created using the MEME. Amino acids are expressed in the standard single letter code. The size of the letters at each position represents their frequency.

Additional file 2: Table S1.

Characteristics of RVE family members in seven Rosaceae species. Table S2. Numbers of RVE gene pairs from different duplication events in seven Rosaceae species. Table S3. Ka and Ks calculation of duplicated RVE gene pairs in seven Rosaceae species. Table S4. The primers used in the assays.

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Liu, Z., Zhu, X., Liu, W. et al. Characterization of the REVEILLE family in Rosaceae and role of PbLHY in flowering time regulation. BMC Genomics 24, 49 (2023). https://0-doi-org.brum.beds.ac.uk/10.1186/s12864-023-09144-4

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