Abstract
Perception of seasonal cues is critical for reproductive success in many plants. Exposure to winter cold is a cue that can confer competence to flower in the spring via a process known as vernalization. In certain grasses, exposure to short days is another winter cue that can lead to a vernalized state. In Brachypodium distachyon, we find that natural variation for the ability of short days to confer competence to flower is due to allelic variation of the florigen paralog FT-like9 (FTL9). An active FTL9 allele is required for the acquisition of floral competence, demonstrating a novel role for a member of the florigen family of genes. Loss of the short-day vernalization response appears to have arisen once in B. distachyon and spread through diverse lineages indicating that this loss has adaptive value, perhaps by delaying spring flowering until the danger of cold damage to flowers has subsided.
Introduction
Many plants adapted to temperate climates have a biennial or winter-annual life history strategy. These plants become established in the fall, overwinter, and flower in the spring. Essential to this adaptive strategy is that flowering does not occur prior to winter and that the perception of winter leads to competence to flower in the spring (Woods et al., 2014). The winter cue perceived in many plants is exposure to a prolonged period of cold, and the process by which such exposure leads to competence to flower is known as vernalization (Chouard, 1960; Woods et al., 2014). In some plants, however, short days (SD) provide an alternative winter cue (Purvis and Gregory, 1937; Heide, 1994), and the process by which SD exposure leads to competence to flower has been referred to as SD vernalization (Purvis and Gregory, 1937). This phenomenon was called SD vernalization because a hallmark of cold-mediated vernalization is acquisition of competence to flower rather than flowering per se, and the SD-vernalization phenomenon is similar in that exposure to SD leads to competence, but plants must still be exposed to inductive LD to flower.
The physiology of SD vernalization has been studied extensively in rye, wheat, barley, and oat (Purvis and Gregory 1937; Dubcovsky et al.,2006; Sampson and Burrows 1972; Heide et al., 1994) although it exists in other families of plants as well (e.g., Chouard 1960). The study of SD vernalization in wheat and barley is complicated by the fact that there are genotypes of wheat (e.g. Templar) and barley (e.g. Morex) in which flowering per se occurs in SD; i.e., certain wheat and barley genotypes are facultative LD plants in that they flower most rapidly in LD but also will flower in SD (Kikuchi et al., 2009; Caseo et al., 2011a; Evans et al., 1987). This SD flowering in wheat and barley is distinct from SD vernalization. Brachypodium distachyon (B. distachyon), however, is an obligate LD plant that only has a SD-vernalization pathway and not a SD-flowering pathway (Ream et al., 2014; Gordon et al., 2017; Woods et al., 2014); thus, the SD-vernalization pathway can be studied in B. distachyon without the complication of SD flowering.
Little is known at a molecular level about how the SD-vernalization pathway operates in any plant species, and thus we have explored the genetic basis of SD vernalization in B. distachyon. Our work reveals a novel role for a florigen family gene in the SD-vernalization pathway and provides a molecular explanation of the distinction between SD vernalization and SD flowering in the pooid grasses.
Results and Discussion
Natural Variation in the SD vernalization response in B. distachyon
The model pooid grass B. distachyon has a robust cold-mediated vernalization response (Ream et al., 2014; Gordon et al., 2017). To determine if any accessions also have a SD vernalization response, we grew 51 accessions in 8-hour SD followed by long days (LD; 16-h or 20-h) and, as controls, solely in LD or SD. Forty of the accessions exhibited a robust SD-vernalization response: these accessions flowered rapidly after the shift from SD to LD, but in LD alone flowering occurred only after quite long periods of growth, and the accessions never flowered in SD alone further confirming that B. distachyon is an obligate LD plant (Figure 1A and B, Table S1 and S2, Figure 1-figure supplement 1; Materials and Methods contains the rationale for the controls). We refer to these 40 lines as SD-vernalization responsive and the 11 lines that did not have a SD vernalization response as SD-vernalization non-responsive.
Given that the longest days experienced in the native growth habitats of the B. distachyon accessions tested range between 15-16h (Figure 1-figure supplement 2), we evaluated whether the SD vernalization response was still effective when SD-grown accessions Koz3, TR12c and RON2 were shifted into a range of more native photoperiods (Figure 1D). Plants were grown in 8h SD for 9 weeks before shifting into 10, 12, 14, 15, or 16-h photoperiods (Figure 1D). All three SD-responsive accessions flowered more rapidly after exposure to SD when the length of day was 12-h or longer (Figure 1D). In B. distachyon 12-h is the minimal photoperiod that is still partially inductive for flowering (Ream et al., 2014; Woods et al., 2017). Thus, the flowering effect of SD vernalization is manifest at the same inductive photoperiods as cold-mediated vernalization.
To determine if SD vernalization, like cold-mediated vernalization, is a quantitative response, we conducted a SD-exposure time course. Four SD-responsive and 5 non-responsive accessions were grown for 2, 4, 6, 8, 10, or 12 weeks in 8-h SD before shifting into LD. Like cold-mediated vernalization, the SD response is quantitative—longer periods of SD exposure result in more rapid flowering in the SD-responsive accessions (Figure 1E; figure supplement 1). Furthermore, 8 weeks of SD exposure saturates the SD-vernalization response. Lastly, even 12 weeks of SD exposure did not enable flowering in any of the accessions we had characterized as SD non-responsive in the 8-week SD exposure evaluation noted above.
We also explored whether the SD vernalization response is possible at a range of developmental stages. In the experiments described above, the SD treatment started when imbibed seeds were sown in soil and continued until plants were shifted into LD and, thus, depending upon the length of time in SD, the SD treatment spanned a range of early developmental stages. To determine if SD vernalization is effective at later developmental stages, we grew SD-responsive accessions in LD for 2, 4, and 6 weeks and subsequently exposed them to 8 weeks of SD. Plants were then returned to inductive LD to determine their SD vernalization responsiveness. All of the SD vernalized plants flowered within 35 days after shifting back into LD, forming 4 leaves on the parent culm in LD before flowering (Figure 1F; Figure 1- figure supplement 1D, E), indicating the SD vernalization is equally effective at early and later developmental stages.
Genetic mapping of the SD vernalization response identifies an FT paralog
To explore the genetic basis of natural variation in the SD-vernalization response, we generated mapping populations from crosses between responsive and non-responsive accessions (Koz3 X Bd1-1; 12c X Bd1-1; RON2 X Bd1-1; and Koz3 X 29-1; Figure 2-figure supplement 1). In all populations, SD responsiveness segregated as a single, dominant locus (Figure 2-figure supplement 1A) that mapped as a large-effect QTL near the bottom of chromosome 2 (Figure 2- figure supplement 1B). Fine mapping narrowed the interval to a region on chromosome 2 containing eight annotated genes (Figure 2-figure supplement 1C). None of these genes are differentially expressed in the shoot apical meristem or leaf tissue of responsive versus non-responsive lines grown in SD followed by LD, SD only, or LD only (data not shown), indicating that the variant underlying this trait is not likely to be in a cis-regulatory region of a gene. However, there is one nucleotide change in this interval present in all 11 SD non-responsive accessions that is not found in any of the 40 SD-responsive accessions; this change results in a threonine to lysine substitution at position 94 (T94K) in an FT paralog (Table S1-2; Figure 2- figure supplement 2) referred to as FT-like 9 (Bradi2g49795; FTL9) (Higgins et al., 2010; Figure 2-figure supplement 4). The founding member of this family is FT which encodes a small protein, also known as ‘florigen’, that travels from leaves to the shoot apical meristem to induce flowering (e.g., (Corbesier et al., 2007; Tamaki et al.)).
Molecular analyses confirm that allelic variation at FTL9 is responsible for natural variation in the ability of SD exposure to confer competence to flower (Figure 2; Figure 2-figure supplement 1). First, reducing FTL9 expression in the SD-responsive accessions Koz3 and Bd21-3 using artificial microRNAs (amiRNAs) eliminated the SD-vernalization response (Figure 2A and Figure 2-figure supplement 1 D-I). However, the amiRNA lines remain fully responsive to cold-mediated vernalization demonstrating that the role of FTL9 is specific to the SD-vernalization pathway (Figure 2B and Figure 2-figure supplement 1E-F). Second, constitutive expression of an FTL9 cDNA from the SD-responsive accessions Koz3 and Bd21 under the control of the maize ubiquitin promoter in both SD-responsive (Bd21-3 and Koz3) and non-responsive accessions (Bd29-1) caused transgenic plants to behave as if they were vernalized without prior cold or SD treatment both in terms of accelerated flowering as well as expression of VERNALIZATION1 (VRN1) which is a marker of the vernalized state in grasses (Woods et al., 2014) (Figure 2C and Figure 2-figure supplement 3). Furthermore, overexpression of FTL9 does not result in rapid flowering when plants are grown in SD whereas overexpression of FT1 does result in rapid flowering (Figure 2-figure supplement 3). The lack of rapid flowering in the FTL9 overexpression transgenics is consistent with the gene providing competence to flower rather than flowering per se, whereas FT1 expression directly induces flowering. In contrast, constitutive expression of the FTL9 cDNA from the SD-non-responsive accession Bd1-1 did not affect the flowering behavior of transgenic lines (Figure 2C; Figure 2-figure supplement 3) indicating that the T94K change is likely to disrupt FTL9 function consistent with the recessive nature of this allele (Figure 2-figure supplement 1A) and that the T94K change occurs in a highly conserved amino acid in this family of proteins in plants and animals (Figure 2-figure supplement 2B). In the experiments described above we evaluated transgenic expression of FTL9 alleles from both Koz3 and Bd21-3 because FTL9 alleles from SD-responsive accessions exhibit variation in the predicted C terminus of the FTL9 protein: the ancestral state of FTL9 is 178 amino acids, but in Koz3 there is a deletion of a single nucleotide (G) in amino acid 175 that alters the reading frame such that FTL9 is 184aa long. As noted above, both versions of FTL9 confer competence to flower.
Characterization of FTL9 expression
Consistent with its role in SD vernalization, FTL9 mRNA is barely detectable in LD, whereas its expression is 350-fold greater in SD (Figure 3A). When SD-grown plants are shifted to LD, FTL9 mRNA expression declines to very low levels within a few days (Figure 3A). We tested whether the quantitative aspect of SD vernalization was correlated with changes in the expression of FTL9, but FTL9 mRNA levels remained the same over 10 weeks of SD exposure (Figure 3-figure supplement 1D). Finally, FTL9 exhibits a diurnal expression pattern in SD with mRNA levels increasing during the night to a peak at dawn and declining during the day to a minimum at dusk, FTL9 expression remains low throughout a 20-h LD (Figure 3B and Figure 3- figure supplement 1A). However, when plants are shifted to free-run, constant-dark conditions, FTL9 mRNA levels plummeted and did not oscillate, indicating that proper FTL9 expression requires short day/long night cycles (Figure 3-figure supplement 1B).
FTL9 is repressed in LD by VRN2
Given the day-length dependence of FTL9 expression, we analyzed its expression in a phyC-1 mutant background (Woods et al., 2014). In phyC the LD photoperiod flowering pathway is abolished and mutant plants are extremely delayed in flowering and have the appearance of SD-grown plants when grown under LD (Woods et al., 2014). Indeed, FTL9 expression is significantly elevated in phyC mutants grown in LD compared to wild type across all time points tested (Figure 4E). Thus, certain PHYC-regulated genes may be negative upstream regulators of FTL9. One candidate gene is FT1; in barley cultivars that can flower in SD, HvFT1 has been postulated to be a repressor of a closely related SD-expressed paralog of FTL9 called HvFT3 (Figure 2-figure supplement 4) because relatively high HvFT3 expression in SD precedes the expression of HvFT1 and, as HvFT1 expression levels increase in SD, HvFT3 expression decreases (Kikuchi et al., 2009). The FT1 expression pattern in wild-type and the phyC mutant is consistent with a model in which FT1 represses FTL9: in the phyC mutant in LD, FT1 is nearly undetectable (Woods et al., 2014), and FTL9, as noted above, is highly expressed, whereas in wild type FT1 is expressed in LD and FTL9 is not. To determine if FT1 represses FTL9 in B. distachyon, we evaluated FTL9 expression in UBI:FT1 transgenic lines grown in SD, a condition in which BdFT1 is not expressed in wild-type plants. FTL9 expression levels were similar between UBI:FT1 and wild-type (Figure 2-figure supplement 3H); thus, it is unlikely that FT1 acts as a LD repressor of FTL9 in B. distachyon.
VERNALIZATION2 (VRN2) is another candidate gene that might repress FTL9 during LD because VRN2 expression is abolished in the phyC mutant (Woods et al., 2014) and the level of FTL9 expression is inversely correlated with the level of expression of VRN2 (Figure 4A and Figure 4-figure supplement 1A). VRN2 is a flowering repressor, and its expression is a function of day-length (Figure 4A and Figure 4-figure supplement 1A) (Dubcovsky et al., 2006; Woods et al., 2016). In LD, VRN2 mRNA levels are elevated and FTL9 mRNA is barely detectable, whereas in SD VRN2 mRNA levels are low and FTL9 is highly expressed (Figure 4-figure supplement 1A). When plants are shifted from SD to LD, VRN2 levels rise to LD levels (Figure 4A), and FTL9 expression subsides (Figure 3A). This expression pattern contrasts with that of VRN2 in a SD-vernalization responsive variety of wheat in which VRN2 levels remain at low SD levels after a shift to LD (Dubcovsky et al., 2006). In wheat, VRN2 is down-regulated by both cold and short days suggesting that this gene might play a role in the integration of the SD vernalization and vernalization pathways (Dubcovsky et al., 2006). This is unlikely to be the case in B. distachyon as VRN2 is up-regulated during the cold (Ream et al., 2014) and VRN2 down-regulation in SD is not maintained during a SD-LD shift (Figure 4A).
That VRN2 controls FTL9 expression in B. distachyon is supported by the upregulation of FTL9 in LD when VRN2 expression is suppressed by amiRNAs (Figure 4B and Figure 4- figure supplement 1B) and the lack of FTL9 expression and lack of acquisition of competence to flower in SD when VRN2 is constitutively expressed (Figure 4C-D and Figure 4-figure supplement 1C). Thus, VRN2 is a repressor of flowering that creates a requirement for vernalization by suppressing flowering when the days are sufficiently long, and, when the day-length decreases below a threshold in winter, the lack of VRN2 expression permits FTL9 expression which leads to competence to flower. The regulation is one way: over- or under-expression of FTL9 does not affect VRN2 mRNA levels (Figure 2-figure supplement 3D).
The repression of FT family genes by LD-upregulated VRN2 appears to be conserved in grasses. For example, in rice, in which SD are inductive for flowering, expression of the VRN2 ortholog GHd7 (Woods et al., 2016) is reduced in SD enabling expression of Hd3 which encodes a florigen (Xue et al., 2008). Also, in wheat and barley, the florigen FT3 is expressed in SD. This SD-specific expression of FT3 results from the lower level of VRN2 expression in SD (Kikuchi et al., 2009; Casao et al., 2011b).
Loss of the SD-vernalization response arose once in B. distachyon
Although all SD non-responsive accessions contain the T94K change at the FTL9 locus, they do not cluster in a single group but rather are quite distantly related based on whole-genome analyses ((Gordon et al., 2017); Figure 2-figure supplement 5A) raising the possibility that the T94K allele arose independently more than once. However, a phylogenetic analysis focusing on the 65kb interval containing FTL9 indicates that in all of the SD-non-responsive accessions the 65kb FTL9 interval is highly conserved (Figure 2-figure supplement 5B) despite other regions of the genome being divergent. This suggests that the FTL9 variant associated with loss of SD responsiveness arose only once and then spread by outcrossing to diverse accessions where it was maintained by positive selection. Although, B. distachyon is typically inbreeding, outcrossing occurs as well (Sancho et al., 2018).
The adaptive value of an active FTL9 and a SD-vernalization response, which is the ancestral state, may be to ensure that vernalization occurs in mild climates in which SD may be a more reliable indicator of winter than cold. The adaptive value of loss of FTL9 activity and the corresponding loss of the SD-vernalization response might be to enable B. distachyon to grow in regions with a more variable spring climate in which a robust SD-vernalization response might lead to flowering before the danger of a hard freeze, which would damage sensitive floral organs, had passed. Interestingly, the SD-non-responsive accessions also require a longer period of cold exposure than the SD-responsive accessions to become fully vernalized ((Gordon et al., 2017) and Figure 1C; Table S3) which is consistent with the SD-non-responsive accessions having undergone adaptation for later spring flowering. Also, consistent with this hypothesis on the adaptive value of loss of FTL9 activity, the non-responsive accessions tend to have been collected at higher latitudes than the responsive accessions (Figure 1-figure supplement 2); however, latitude is only one of many factors that may relate to the latest date of a damaging freeze.
Roles of SD expressed FT-like genes in grass flowering
FTL9 is part of a FT-like gene family that has expanded to 14 members in grasses ((Higgins et al., 2010) and Figure 2-figure supplement 4). The roles of the other FT-like genes in grasses have not been thoroughly explored. Studies in wheat and barley indicate that a candidate gene underlying a QTL that confers the ability of certain varieties to flower in SD (Ppd-H2) (Laurie et al., 1995) is likely a paralog of FT referred to as FT3 (Faure et al., 2007; Kikuchi et al., 2009; Casao et al., 2011a). The dominant FT3 allele, which enables SD flowering, is often found in spring barley cultivars grown in more southern latitudes, whereas the recessive allele is typically associated with winter cultivars grown in more northern latitudes (Casao et al., 2011a). FT3 is implicated in actual flowering in SD in wheat and barley as opposed to the competence to flower in LD that is conferred by SD-specific expression of FTL9 in B. distachyon. FTL10 is the B. distachyon ortholog of wheat and barley FT3 (Halliwell et al., 2016; Figure 2-figure supplement 4). FTL10 and FTL9 are closely related paralogs that resulted from a grass-specific duplication event, and thus FTL10 and FTL9 reside in sister clades (Figure 2-figure supplement 4). FT3 is up-regulated in SD in barley and wheat, whereas FTL10 expression in B. distachyon is not modulated by day-length and its expression level is quite low in all conditions tested (Figure 3D). However, constitutive expression of FTL10 from the maize ubiquitin promoter results in flowering during transgenic line generation in tissue culture (Figure 3E) and rapid flowering in SD (Figure 2-figure supplement 3I, J) similar to the effects of expression of other FT1 orthologs in B. distachyon (Figure 2-figure supplement 3I, J ; Ream et al., 2014) and wheat (Lv et al., 2014) indicating that FTL10 has florigen activity. In contrast, as discussed above, constitutive expression of FTL9 does not induce flowering in SD or in tissue culture which is consistent with its role in establishing competence to flower as opposed to the florigen-like role of FTL10 in inducing flowering (Figure 2-figure supplement 3G, I, J).
Interestingly, like FTL9 in B. distachyon, the FTL9 ortholog in sorghum and maize called CENTRORADIALIS 12 (CN12) (Figure 2-figure supplement 4, Figure 2-figure supplement 6; Murphy et al., 2011; Meng et al., 2011) is also expressed only in SD. However, in sorghum and maize, which are SD-flowering or day neutral plants, CN12 along with CN8 (the FTL10/FT3 ortholog) are both florigenic (Meng et al., 2011; Lazakis et al., 2011). Thus, gene duplication of an ancestral SD-expressed FT-like gene at the base of the grass family appears to have resulted in the FTL9/CN12 and FTL10/FT3/CN8 clades (Figure 2-figure supplement 4). Grasses that are classified as SD plants like sorghum and photoperiodic maize (Murphy et al., 2011; Meng et al., 2011) are in fact SD plants because a florigenic member of one of the SD-expressed clades provides the primary florigen activity. Wheat and barley are LD plants because the strongest florigen activity is provided by LD-expressed FT family members in other clades such as FT1. However, many varieties of wheat and barley exhibit a facultative LD response—i.e., they also can flower in SD. The SD flowering of barley appears to result from expression of SD-induced clade members such as FT3 (Kikuchi et al., 2009; Faure et al., 2007). All accessions of B. distachyon that we have analyzed are obligate LD plants because the florigenic member of the clade, FTL10, is not expressed at sufficient levels to cause flowering in SD and the other member of the clade, FTL9, evolved the different function of providing competence to flower in pooid grasses rather than directly promoting flowering like it does in sorghum and maize.
SD-mediated vernalization was first described in rye in 1937 (Purvis and Gregory, 1937) and has been described in wheat and barley (Evans, 1987; Heide, 1994; Dubcovsky et al., 2006); however, sequence data available to date has not revealed a clear ortholog of FTL9 in wheat or barley (Figure 2-figure supplement 4; Faure et al., 2007). It will be interesting to determine whether FTL9 orthologs or other FT family members are involved in SD vernalization in cereals.
Gene duplication and divergence has enabled diverse roles for FT family members in flowering. The founding members of the FT family provide florigen activity (Corbesier et al., 2007; Tamaki et al.). In beet, an FT family member is an inhibitor of flowering that is key to establishing a requirement for vernalization. Our work in B. distachyon reveals a new role for an FT family member: the establishment of competence to flower without direct florigen activity.
Convergence between the SD vernalization and cold-mediated vernalization pathways
To explore the relationship between SD vernalization and the cold-mediated vernalization pathway, we evaluated the expression of the key flowering genes VRN1 and FT1 (known as VRN3 in wheat, Yan et al., 2006) in SD, LD and during a SD-LD shift (Figure 5). FT1 and VRN1 are lowly expressed in SD only and LD only in Koz3 and Bd1-1 consistent with the delayed flowering phenotype of these accessions without prior SD or cold vernalization (Figure 5). However, prolonged exposure of Koz3 (SD vernalization responsive) to SD followed by a shift to LD (SD-LD) results in the up-regulation of both FT1 and VRN1, whereas this treatment does not result in FT1 and VRN1 expression in the SD non-responsive accession Bd1-1 (Figure 5).
Thus, SD vernalization provides competence to flower by enabling the expression of VRN1 and FT1 once plants are in LD. As previously shown for cold-mediated vernalization (Woods et al., 2016), SD-mediated vernalization is attenuated in amiVRN1 transgenic lines (Figure 5C, D), further corroborating that the cold- and SD-mediated vernalization pathways converge on enabling expression of genes like VRN1 when plants are exposed to inductive LD. It is important to note that the loss of FTL9 activity has no effect on cold-mediated vernalization (Figure 2) demonstrating that there are features that define the two pathways as separate. It will be interesting to determine mechanisms through which FTL9 expression in SD enables an alternate path to cold-mediated vernalization to provide competence to flower. This competence is due, at least in part, by enabling VRN1 expression to increase in LD. For example, FTL9 may be involved in modifying VRN1 chromatin during SD to allow its activation during LD. A similar model may apply to the cold-mediated vernalization pathway: for example, repression of VRN1 before cold-mediated vernalization is associated with high levels of H3K27me3 at VRN1 chromatin in both wheat and B. distachyon (Oliver et al., 2009; Woods et al., 2017).
SD-mediated vernalization in other groups of plants
Similar to cold-mediated vernalization, the SD-mediated vernalization response is found in an array of species spanning flowering plant diversification (Chouard, 1960; Heide et al., 1994). Advances in understanding the molecular underpinnings of cold-mediated vernalization in several different plant groups as well in paleobotany and earth climate history indicate that cold-mediated vernalization likely evolved independently multiple times as flowering plants were radiating some 140 million years ago (e.g., Bouche et al., 2017). The fact that FTL9 appears to be grass-specific suggests that SD-mediated vernalization likely evolved independently several times. It will be interesting to evaluate the molecular basis of SD-vernalization pathways in different plant groups.
Materials and Methods
Growth Conditions and Plant Phenotyping
Seeds were imbibed overnight in distilled water at 5°C then grown in MetroMix 360 (Sungrow) in 3-inch plastic pots under four 5000 K T5 fluorescent bulbs (300 mmol m−2 s−1 at plant level) at 21-22°C during the light period and 18°C during the dark and fertilized weekly with Peters Excel 15-5-15 Cal-Mag and Peters 10-30-20 Blossom Booster (RJ Peters). To minimize light intensity differences, plant positions were rotated several times per week. Flowering time was measured as the number of days from the emergence of the coleoptile to the day when emergence of the spike was visible. The developmental stage of the plant was recorded as the number of primary leaves derived from the parent culm at the time of heading. For all experiments at least 6 plants were used to obtain the days to heading and leaf count averages. Representative phenotyping results are presented, each of which were repeated in independent experiments with similar results.
Marker Development
Development of indel markers (Table S4) was done using the sequenced genomes of Koz3, Bd1-1, 12c, Bd29-1, and RON2 (Gordon et al., 2017). All markers are optimized to anneal at 51°C and produce a product roughly 100bp in length. Markers were resolved using a 3% sodium borate agarose gel.
Generation of amiFTL9 and UBIFTL9, UBIFTL10 Transgenic lines
amiRNAs specific for two distinct parts of the FTL9 mRNA were designed using the amiRNA designer tool at wmd3.weigelworld.org based on MIR528 from rice in the pNW55 vector. Gateway-compatible amiFTL9 PCR products were recombined into pDONR221 using Life Technologies BP Clonase II following the manufacturer’s protocol. Clones were verified by sequencing. The pDONR221 vector containing the desired amiRNA in combination with another vector containing the maize ubiquitin promoter were both recombined into destination vector p24GWI (designed by Devin O’Connor at the Plant Gene Expression Center, Albany, CA) using Life Technologies LR clonase II plus following the manufacturer’s protocol. Clones were verified by sequencing to ensure that the maize ubiquitin promoter was upstream from the amiRNA. The constructs were transformed into A. tumefaciens strain Agl-1. Plant callus transformation was as previously described (Vogel et al., 2008). Independent transgenic lines were genotyped for the transgene using an amiRNA forward primer specific for the targeted transcript and a reverse primer derived from the pNW55 backbone sequence (Table S5). Primers used to generate the amiRNAs are listed in Table S5.
FTL9 cDNAs were amplified from SD-grown Bd21, Koz3, and Bd1-1 plants. FTL10 cDNAs were amplified from Bd21-3 grown in LD. cDNAs were gel extracted (Qiagen) and cloned using CloneJET PCR according to the manufacturer’s protocol (Thermo Fischer Scientific). Clones were verified by sequencing. The cDNA was then subcloned using primers compatible with the Gateway BP clonase system according to the manufacturer’s protocol (Thermo Fischer Scientific). The BP plasmid was verified by sequencing and then recombined into pANIC10A (Mann et al., 2012) using Life Technologies LR Clonase II following the manufacturer’s protocol. Clones were verified by sequencing in pANIC10A and then transformed into Agrobacterium tumefaciens strain Agl-1. Plant callus transformation was performed as described (Vogel et al., 2008). Independent transgenic lines were genotyped for the transgene using a cDNA-specific forward and pANIC vector AcV5 tag reverse primer (Table S5). Primer pairs used to clone each cDNA are listed in Table S5.
RNA expression analysis and qPCR
RNA extraction and expression analysis were performed as described in (Ream et al., 2014).
QTL analysis
QTL analysis was performed as described in (Woods et al., 2017).
Phylogenetic and syntenic analyses
Phylogenetic analyses of FT-like genes were performed using both the full-length FTL9 and FT genes and the PEBP domains as seed sequences for BLAST searches using Phytozome and NCBI as described in (Woods et al., 2011). Maximum-likelihood analyses were conducted using SeaView 4.5.4 (Gouy et al., 2010). Phylogenetic analysis of the SD-vernalization interval across 51 B. distachyon accessions was done using variants called within a VCF file generated as in (Gordon et al., 2017). Relationships among B. distachyon accessions based on the mapped interval were determined using the TASSEL 5 software package (Bradbury et al., 2007). Synteny in the chromosomal regions around FTL9 of Brachypodium distachyon, Oryza sativa, Seteria italica, Sorghum bicolor, Panicum hallii, and Zea mays was investigated using the GEvo software package within CoGe (Lyons et al., 2008).
LD only and SD only controls for characterization of the SD-vernalization response
To determine if prolonged growth in short days followed by a shift into long days (SD-LD) can promote flowering, we grew 43 delayed flowering accessions in 8-hour short days for 8 weeks before shifting into either 16 or 20-hour days (Table S1-2). The two controls for this experiment were accessions grown in SD and LD only. The SD only control demonstrates that growth in SD is indeed non-inductive for flowering because growth for 150 days does not permit flowering in any of the accessions tested (Table S1-2). Dissections on the parent culm revealed that the meristems were still vegetative after 150 days of growth in SD in all accessions tested, consistent with previous reports (Woods et al., 2014; Gordon et al., 2017). The LD only control was chosen to ensure that if robust flowering occurs following a shift from SD to LD, this was indeed due to the prior SD treatment and not simply due to the age of the plant when shifted into inductive LD. Thus, an accession is SD vernalization responsive if the SD-LD shifted plants flower much more rapidly than the LD only controls.
Control for day and night temperature during SD vernalization
To ensure the acceleration of flowering by prolonged exposure to SD was indeed due to the shorter photoperiod and not due to extended periods of cooler dark temperatures of 18°C, we grew four accessions (KOZ3, 12c, RON2 and Bd18-1) in SD under constant day and night temperatures of 21°C. Accessions grown under constant 21°C day/night temperatures showed the same robust SD vernalization response as those grown under 21°C/18°C day/night temperatures (data not shown), indicating that the SD vernalization phenomenon is due strictly to the photoperiod and not a composite of photoperiod and temperature.
Funding
This work was funded in part by the National Science Foundation (IOS-1258126 to R.M.A.), the Great Lakes Bioenergy Research Center (Department of Energy Biological and Environmental Research Office of Science DE-FCO2-07ER64494), a National Institutes of Health-sponsored pre-doctoral training fellowship to the University of Wisconsin Genetics Training program to D.P.W., a Gordon and Betty Moore Foundation and the Life Sciences Research Foundation fellowship to support T.S.R., and a Wallonie-Bruxelles International fellowship to F.B.
Author Contributions
D.P.W., and R.M.A. conceived and designed research plans with assistance from T.S.R and F.B.; D.P.W. and Y.D. characterized the SD vernalization phenomenon across sequenced B. distachyon accessions; F.B. analyzed climate data; M.R. and D.P.W. developed markers and performed QTL analysis; R.B. and Y.D. cloned FTL9 and phenotyped with D.P.W; D.P.W. prepared figures with input from F.B. and R.M.A.; D.P.W. and R.M.A. wrote the article with contributions and approval of all authors.
Competing Interests
Authors declare no competing interests.
Data and materials availability
All data us available in the main text or the supplementary materials.
Acknowledgments
We thank John Vogel and Sean Gordon for leading the effort to sequence and analyze 51 B. distachyon genomes (Gordon et al., 2017) which provided data critical for this work. We thank Jill Mahoy and Heidi Kaeppler for providing transgenic B. distachyon lines, and Scott Woody for many helpful suggestions on improving this manuscript.