Abstract
Shoots can be regenerated from roots in Arabidopsis by treating root explants with cytokinin, however, shoot regeneration requires preincubation on callus induction medium (CIM) prior to induction on cytokinin-rich shoot induction medium (SIM). A cytokinin-inducible marker gene, RESPONSE REGULATOR 15 (ARR15), was identified through a “CIM dropout experiment” with similar requirements for CIM preincubation. The requirements for ARR15 contrasted to ARR5, another cytokinin-inducible ARR gene that does not require CIM preincubation. We show here that despite their differences, both ARR5 and ARR15 are direct targets of the transcriptional B-type response regulator, ARR2. This was demonstrated by identifying genes upregulated following β estradiol induced nuclear relocation of an ARR2-estradiol receptor fusion protein. The differences in CIM preincubation requirements for ARR5 and ARR15 expression indicate an additional layer of control for these A-type ARR genes during SIM incubation. For ARR15, the CIM requirement is a transcriptional effect, because the expression of ARR15 promoter:GUS reporter gene constructs is also affected by CIM preincubation. A testable model is that transcription of ARR15, but not ARR5, is blocked by a repressor and that the effects of the repressor are relieved by CIM preincubation.
Key words: response regulator, shoot regeneration, transcriptional regulation, cytokinin, checkpoint
Shoots can be regenerated from roots in Arabidopsis by a process of indirect organogenesis in which root explants are preincubated on an auxin-rich callus induction medium (CIM) and then are transferred to a cytokinin-rich shoot induction medium (SIM) for shoot formation.1 During CIM preincubation, root explants “acquire competence” to form shoots during subsequent incubation on SIM.2 We have examined the impact of competence acquisition on the unfolding of the program of gene expression that underpins the shoot development process. To do so we conducted a “CIM dropout experiment” whereby we compared the program of gene expression during SIM incubation with and without CIM preincubation.3
Many genes were affected in the CIM dropout experiment, but ARR15 (At1g74890), encoding an A-type response regulator, was of special interest because ARR15, like several other A-type response regulator genes, can be induced by cytokinin.4 In our system, both ARR15 and ARR5 (At3g48100), another A-type ARR, are upregulated during incubation on SIM, but ARR15 was dependent on CIM preincubation. Using an ARR15 promoter:GUS reporter construct, we demonstrated that the dependency of ARR15 on CIM preincubation was transcriptional.3 We found subsequently, that another A-type ARR, ARR16 (At2g40670) was actually downregulated in response to CIM preincubation (Che, unpublished observations).
Several other A-type ARRs are known to be upregulated by cytokinin5–13 and activated by B-type ARRs, the transcriptional regulators in the cytokinin signaling pathway.10 For example, the A-type ARR6 has been shown to be directly activated by B-type ARRs, ARR1 (AT3G16857) and/or ARR2 (AT4G16110).6,7 In particular, Hass et al14 demonstrated that overexpression of a constitutively active form of ARR2 upregulated the expression of ARR5, -15 and -16. We were particularly interested in knowing whether ARR5, -15 and -16, which respond so differently to CIM preincubation, are directly activated by the same B-type ARR.
To do so, we fused ARR2ΔDDK (a constitutively active form of ARR27) to the β-estradiol receptor and expressed the construct in transgenic plants with the 35S promoter. Steroid receptor fusion proteins have been used in Arabidopsis by a number of investigators to identify immediate transcription factor targets.7,15–19 In response to β-estradiol treatment, the fusion protein, which accumulates in the cytoplasm, should be translocated to the nucleus. To identify genes directly activated by the ARR2ΔDDK-ER fusion, seedlings were treated (or not treated) with β-estradiol and cycloheximide (CHX) to block subsequent protein synthesis, then analyzed by Affymetrix DNA chip analysis. As a control for β-estradiol effects, CHX-treated non-transgenic seedlings were further treated or not treated with β-estradiol. Genes were rank ordered by the fold change between β-estradiol treated and untreated seedlings when controlling the false discovery rate at the level of 0.10 (Table 1).
Table 1.
Locus | non-transgenic untreated mean | non-transgenic β-est treated mean | FC non-transgenic | Adjusted FC non-transgenic | ARR2-ER transgenic untreated mean | ARR2-ER transgenic β-est treated mean | FC ARR2-ER transgenic | pvalue | qvalue | transgenic adjusted FC-nontransgenic | Gene description |
At1g74890 | 197.5 | 185.4 | 0.94 | 1.00 | 102.5 | 1802.4 | 17.58 | 1.47E-04 | 6.91E-02 | 17.58 | ARR15 |
At1g34330 | 5.7 | 2 | 0.35 | 1.00 | 1.4 | 23.7 | 16.63 | 3.49E-03 | 1.30E-01 | 16.63 | putative peroxidase |
At1g10460 | 19.8 | 18.1 | 0.91 | 1.00 | 4.5 | 49.5 | 10.89 | 3.49E-03 | 1.30E-01 | 10.89 | germ in-like protein |
At2g14270 | 11.2 | 1.9 | 0.17 | 1.00 | 1.8 | 16.7 | 9.10 | 2.30E-03 | 1.17E-01 | 9.10 | putative protein phosphatase 2C |
At5g62920 | 300.1 | 310.1 | 1.03 | 1.03 | 228.5 | 1906.3 | 8.34 | 4.04E-04 | 7.96E-02 | 8.07 | ARR6 |
At3g28890 | 23.4 | 5.4 | 0.23 | 1.00 | 2.8 | 19.6 | 6.90 | 5.80E-03 | 1.50E-01 | 6.90 | leucine-rich repeat family protein |
At4g19770 | 28 | 339 | 1.21 | 1.21 | 2.4 | 19.2 | 7.99 | 1.11E-03 | 105E-C1 | 6.59 | glycosyl hydrolase family 18 protein |
At5g45830 | 56.6 | 33.9 | 0.60 | 1.00 | 12 | 78.1 | 6.54 | 3.03E-03 | 1.23E-01 | 6.54 | expressed protein |
At1g04840 | 42.1 | 28 | 0.66 | 1.00 | 5.5 | 36 | 6.49 | 7.49E-06 | 3.82E-02 | 6.49 | pentatricopeptide (PPR) repeat protein |
At5g45650 | 215.1 | 194.1 | 0.90 | 1.00 | 402.7 | 2536 | 6.30 | 2.76E-07 | 2.33E-03 | 6.30 | subtilisin-like protease |
At2g40670 | 378.2 | 338.6 | 0.90 | 1.00 | 516.4 | 3072.7 | 5.95 | 3.38E-05 | 5.89E-02 | 5.95 | ARR16 |
At5g56970 | 146.3 | 192.7 | 1.32 | 1.32 | 159.2 | 1217.2 | 7.64 | 5.83E-03 | 1.50E-01 | 5.80 | cytokinin oxidase family protein |
At1g10470 | 1715.8 | 1511.8 | 0.88 | 1.00 | 1150 | 6186.8 | 5.38 | 3.13E-04 | 7.33E-02 | 5.38 | ARR4 |
At1g16530 | 98.7 | 137.8 | 1.40 | 1.40 | 138.8 | 1033.8 | 7.45 | 9.55E-04 | 1.02E-01 | 5.33 | lateral organ boundaries protein 3 |
At3g48100 | 1219.9 | 1554.9 | 1.27 | 1.27 | 1043.5 | 6345.8 | 6.08 | 5.40E-03 | 1.47E-01 | 4.77 | ARR5 |
At3g57040 | 681.3 | 581.6 | 0.85 | 1.00 | 490.4 | 2284 | 4.66 | 1.70E-04 | 6.91E-02 | 4.66 | ARR9 |
At2g01890 | 412.5 | 243.1 | 0.59 | 1.00 | 432.2 | 1938.8 | 4.49 | 8.31E-08 | 1.40E-03 | 4.49 | putative purple acid phosphatase |
At4g26010 | 63.1 | 53.8 | 0.85 | 1.00 | 94.2 | 402.3 | 4.27 | 4.11E-03 | 1.40E-01 | 4.27 | putative peroxidase ATP13a |
At3g42380 | 27.1 | 6.5 | 0.24 | 1.00 | 8.2 | 34.3 | 4.15 | 5.43E-03 | 1.47E-01 | 4.15 | hypothetical protein |
At1g63360 | 173.9 | 176.6 | 1.02 | 1.02 | 120.2 | 505.7 | 4.21 | 4.28E-03 | 1.40E-01 | 4.14 | putative zinc finger protein |
At2g39920 | 111 | 126.3 | 1.14 | 1.14 | 130.8 | 604.9 | 4.63 | 8.84E-04 | 9.92E-02 | 4.06 | acid phosphatase class B protein |
At5g15190 | 271.7 | 311.9 | 1.15 | 1.15 | 210.6 | 912.3 | 4.33 | 1.21E-04 | 6.91E-02 | 3.77 | putative protein |
At4g13560 | 22 | 7.2 | 0.33 | 1.00 | 4.6 | 17.3 | 3.73 | 5.21E-04 | 8.60E-02 | 3.73 | LEA domain-containing protein |
At1g13740 | 388.7 | 271.8 | 0.70 | 1.00 | 259.1 | 957.6 | 3.70 | 9.90E-04 | 1.02E-01 | 3.70 | expressed protein |
At5g46230 | 384 | 314.5 | 0.82 | 1.00 | 346.2 | 1266.6 | 3.66 | 4.33E-03 | 1.41E-01 | 3.66 | expressed protein |
At3g57010 | 112.6 | 66.4 | 0.59 | 1.00 | 63.8 | 223.4 | 3.50 | 5.54E-04 | 8.60E-02 | 3.50 | strictosidine synthase family protein |
At5g05860 | 337.7 | 303.8 | 0.90 | 1.00 | 320.8 | 1115.9 | 3.48 | 2.19E-03 | 1.15E-01 | 3.48 | UDP-glucosyl transferase family protein |
At2g07630 | 1.4 | 1.1 | 0.77 | 1.00 | 1 | 3.4 | 3.23 | 2.87E-03 | 1.22E-01 | 3.23 | expressed protein |
At2g01830 | 185.6 | 199.7 | 1.08 | 1.08 | 215.7 | 712.7 | 3.30 | S.12E-04 | 9.63E-02 | 3.07 | his kinase cytokinin receptor (AHK4) |
At3g15720 | 68 | 76 | 1.12 | 1.12 | 191 | 654.2 | 3.43 | 1.76E-03 | 1.07E-01 | 3.06 | glycoside hydrolase family 28 |
At1g13420 | 18.8 | 4.3 | 0.23 | 1.00 | 32.1 | 97.5 | 3.04 | 8.26E-04 | 9.63E-02 | 3.04 | steroid sulfotransferase |
At5g23270 | 38 | 49.5 | 1.30 | 1.30 | 33.3 | 128.2 | 3.85 | 3.98E-03 | 1.38E-01 | 2.96 | sugar transporter |
At1g28100 | 190.3 | 186.4 | 0.98 | 1.00 | 186 | 543.3 | 2.92 | 1.64E-04 | 6.91E-02 | 2.92 | expressed protein |
At1g69040 | 1368.1 | 1466.6 | 1.07 | 1.07 | 1113.5 | 3466.2 | 3.11 | 8.75E-04 | 9.92E-02 | 2.90 | ACT domain containing protein (ACR4) |
At5g41890 | 17.4 | 4.9 | 0.28 | 1.00 | 6.2 | 17.3 | 2.79 | 2.65E-03 | 1.21E-01 | 2.79 | GDSL-motif lipase/hydrolase protein |
At2g43550 | 537.8 | 362 | 0.67 | 1.00 | 262.2 | 698.6 | 2.66 | 1.59E-03 | 1.07E-01 | 2.66 | defensin-like family protein |
At4g23750 | 941.7 | 1054.5 | 1.12 | 1.12 | 1337.4 | 3845.3 | 2.88 | 4.55E-04 | 8.45E-02 | 2.57 | ERF/AP2 transcription factor family |
At1g19050 | 5149.1 | 5267.9 | 1.02 | 1.02 | 4038 | 10567.9 | 2.62 | 1.54E-04 | 6.91E-02 | 2.56 | ARR7 |
To identify genes directly activated by the ARR2ΔDDK-ER fusion, seedlings were treated (or not treated) with β-estradiol and cycloheximide (CHX) to block subsequent protein synthesis, then analyzed by Affymetrix DNA chip analysis. As a control for β-estradiol effects, CHX-treated non-transgenic seedlings were further treated or not treated with β-estradiol. Each of the treatments was duplicated, employing a total of eight DNA chips. Estimated means of the MAS 5.0 signal intensities are shown based on back-transformation of log-scale data. A two-way ANOVA was performed on log-scale data to identify genes exhibiting significant interaction between genotype (wild type vs. transgenic) and treatment (β-estradiol vs. no β-estradiol). Q-values were computed according to Storey and Tibshirani (2003). Data are sorted by the ratio of the fold change (FC) between the treated and untreated transgenic plants divided by the adjusted FC between the treated and untreated non-transgenic plants. The FC for the non-transgenic plants was adjusted to 1 for any values <1 to prevent inflation of the ratio of the FCs when the mean for the β-estradiol treated controls was less than the untreated controls.
By these criteria, the top genes most highly activated by ARR2ΔDDK-ER are some of the A-type response regulators, including ARR4, -6, -7, -9, -15 and -16. These genes are affected very little by β-estradiol treatment in the wild type control, but are significantly upregulated by β-estradiol treatment in transgenic seedlings bearing ARR2ΔDDK-ER constructs (Table 1). The data show that ARR15 is more than 17-fold upregulated by β-estradiol treatment, ARR16 nearly 6 fold and ARR5 nearly 5 fold. These observations support the proposition that several A-type ARR genes, noting ARR5, ARR15 and -16, in particular, are direct transcriptional targets of the B-type ARR2. Comparable results have been obtained by Taniguchi et al20 with a constitutively active construct involving another B-type ARR, ARR1ΔDDK-GR (in which GR=glucocorticoid receptor). Thus, both ARR1 and ARR2 have very broad control over genes which otherwise have been shown to be cytokinin regulated.
The finding that CIM preincubation was required for ARR15 upregulation during subsequent incubation on SIM was unexpected and interesting. From what was discussed above, it was anticipated that ARR15 would be induced on cytokinin-rich SIM, whether or not explants had been preincubated on CIM. Other A-type ARRs, such as ARR5 and ARR6, which are also normally upregulated in SIM, did not require CIM preincubation. The response of ARR15 and -16 to CIM preincubation was particularly intriguing because the expression of both appear to depend on the function of AHK4 as a receptor. Kiba et al.21 showed that ARR15 and ARR16 expression is markedly reduced in cre1-1, a loss-of-function mutation in AHK4.
One major difference between ARR15 and -16 expression (noted by Kiba et al., ref. 21) is that a ARR15 promoter:GUS construct is expressed in the vasculature of roots treated with cytokinin (t-zeatin), while ARR16 promoter:GUS is expressed in the endodermis. On the other hand, we have found in other experiments that ARR5 and -15 appear to be expressed in the same root tissue (Che unpublished), yet they too differ in their dependence on CIM preincubation. A possible explanation for this is that ARR5 and -15 may be activated by different branches of the cytokinin signaling pathway—ARR5 expression in seedlings is not dependent on AHK4, while ARR15 expression is. As pointed out above, Kiba et al21 found that ARR15 expression was downregulated in cre1-1 (AHK4 loss-of-function mutant), but ARR5 expression was relatively unaffected. In addition, we found that ARR15 was highly upregulated by β-estradiol treatment of ARR2ΔDDK-ER seedlings, but ARR5 was not.
The fact that ARR5, -15 and -16 are direct targets of ARR1 and ARR2, yet their regulation in response to CIM preincubation differs, indicates an additional layer of control for these A-type ARR genes during SIM incubation. For ARR5 and ARR15, that regulation is exercised at a transcriptional level, because the expression of promoter: GUS reporter gene constructs is also affected by CIM preincubation. A testable model for the control is that transcription of ARR15 is blocked by a repressor and that the effects of the repressor are relieved by CIM preincubation. If that kind of control can be generalized to other genes that are expressed during SIM incubation, then the function of CIM preincubation might be to overcome a major gene expression checkpoint in shoot regeneration.
Footnotes
Previously published online as a Plant Signaling & Behavior E-publication: www.landesbioscience.com/journals/psb/article/4958
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