AUX/IAA proteins are active repressors, and their stability and activity are modulated by auxin.

Aux/IAA genes are early auxin response genes that encode short-lived nuclear proteins with four conserved domains, referred to as I, II, III, and IV. Arabidopsis Aux/IAA proteins repressed transcription on auxin-responsive reporter genes in protoplast transfection assays. Mutations in domain II resulted in increased repression, whereas mutations in domains I and III partially relieved repression. Aux/IAA proteins fused to a heterologous DNA binding domain were targeted to promoters of constitutively expressed reporter genes and actively repressed transcription in an auxin-responsive and dose-dependent manner. In comparison with an unfused luciferase protein, luciferase fused to Aux/IAA proteins displayed less luciferase activity, which further decreased in the presence of auxin in transfected protoplasts. Domain II mutations increased and domain I mutations decreased luciferase activity with the fusion proteins. These results suggested that Aux/IAA proteins function as active repressors by dimerizing with auxin response factors bound to auxin response elements and that early auxin response genes are regulated by auxin-modulated stabilities of Aux/IAA proteins.

Identification of Arabidopsis histone deacetylase HDA6 mutants that affect transgene expression.

A mutant screen was conducted in Arabidopsis that was based on deregulated expression of auxin-responsive transgenes. Two different tightly regulated (i.e., very low expression in the absence of auxin treatment and very high expression after exogenous auxin treatment) auxin-responsive promoters were used to drive the expression of both a beta-glucuronidase (GUS) reporter gene and a hygromycin phosphotransferase (HPH)-selectable marker gene. This screen yielded several mutants, and five of the mutations (axe1-1 to axe1-5) mapped to the same locus on chromosome 5. A map-based cloning approach was used to locate the axe1 mutations in an Arabidopsis RPD3-like histone deacetylase gene, referred to as HDA6. The axe1 mutant plants displayed increased expression of the GUS and HPH transgenes in the absence of auxin treatment and increased auxin-inducible expression of the transgenes compared with nonmutant control plants. None of a variety of endogenous, natural auxin-inducible genes in the mutant plants were upregulated like the transgenes, however. Results of treatment with the DNA methylation inhibitor 5-aza-2'-deoxycytidine suggest that the axe1 mutations affect transgene silencing; however, histone deacetylase inhibitors had no affect on transgene silencing in mutant or control plants. The specific effect of AtHDA6 mutations on the auxin-responsive transgenes implicates this RPD3-like histone deacetylase as playing a role in transgene silencing. Furthermore, the effect of AtHDA6 on transgene silencing may be independent of its histone deacetylase activity.

Dimerization and DNA binding of auxin response factors.

Auxin response factors (ARFs) are transcription factors that bind with specificity to TGTCTC auxin response elements (AuxREs) found in promoters of primary/early auxin response genes. ARFs are encoded by a multi-gene family, consisting of more than 10 genes. Ten ARFs have been analyzed by Northern analysis and were found to be expressed in all major plant organs and suspension culture cells of Arabidopsis. The predicted amino acid sequences indicate that the 10 ARFs contain a novel amino-terminal DNA binding domain and a carboxyl-terminal dimerization domain, with the exception of ARF3 which lacks this dimerization domain. All ARFs tested bind with specificity to the TGTCTC AuxRE, but there are subtle variations in the sequence requirements at positions 5 (T) and 6 (C) of the AuxRE. While the amino-terminal domain of about 350 amino acids is sufficient for binding ARF1 to TGTCTC AuxREs, this domain is not sufficient for the binding of some other ARFs to palindromic AuxREs. Our results suggest that ARFs must form dimers on palindromic TGTCTC AuxREs to bind stably, and this dimerization may be facilitated by conserved motifs found in ARF carboxyl-terminal domains. Dimerization in at least some cases may dictate which ARF(s) are targeted to AuxREs.

Activation and repression of transcription by auxin-response factors.

Auxin-response factors (ARFs) bind with specificity to TGTCTC auxin-response elements (AuxREs), which are found in promoters of primary/early auxin-response genes. Nine different ARFs have been analyzed for their capacity to activate or repress transcription in transient expression assays employing auxin-responsive GUS reporter genes. One ARF appears to act as a repressor. Four ARFs function as activators and contain glutamine-rich activation domains. To achieve transcriptional activation on TGTCTC AuxREs in transient expression assays, ARFs require a conserved dimerization domain found in both ARF and Aux/IAA proteins, but they do not absolutely require their DNA-binding domains. Our results suggest that ARFs can activate or repress transcription by binding to AuxREs directly and that selected ARFs, when overexpressed, may potentiate activation further by associating with an endogenous transcription factor(s) (e.g., an ARF) that is bound to AuxREs. Transfection experiments suggest that TGTCTC AuxREs are occupied regardless of the auxin status in cells and that these occupied AuxREs are activated when exogenous auxin is applied to cells or when ARF activators are overexpressed. The results provide new insight into mechanisms involved with auxin regulation of primary/early-response genes.

Arabidopsis thaliana RNA polymerase II subunits related to yeast and human RPB5.

Arabidopsis thaliana contains at least four genes that are predicted to encode polypeptides related to the RPB5 subunit found in yeast and human RNA polymerase II. This subunit has been shown to be the largest subunit common to yeast RNA polymerases I, II, and III (RPABC27). More than one of these genes is expressed in Arabidopsis suspension culture cells, but only one of the encoded polypeptides is found in purified RNA polymerases II and III. This polypeptide has a predicted pI of 9.6, matches 14 of 16 amino acids in the amino terminus of cauliflower RPB5 that was microsequenced, and shows 42 and 53% amino acid sequence identity with the yeast and human RPB5 subunits, respectively.

The ARF family of transcription factors and their role in plant hormone-responsive transcription.

Auxin response factors or ARFs are a recently discovered family of transcription factors that bind with specificity to auxin response elements (AuxREs) in promoters of primary or early auxin-responsive genes. ARFs have an amino-terminal DNA-binding domain related to the carboxyl-terminal DNA-binding domain in the maize transactivator VIVIPAROUS1. All but one ARF identified to date contain a carboxyl-terminal protein-protein interaction domain that forms a putative amphipathic alpha-helix. A similar carboxyl-terminal protein-protein interaction domain is found in the Aux/IAA class of auxin-inducible proteins. Some ARFs contain transcriptional activation domains, while others contain repression domains. ARFs appear to play a pivotal role in auxin-regulated gene expression of primary response genes.

Two small subunits in Arabidopsis RNA polymerase II are related to yeast RPB4 and RPB7 and interact with one another.

An Arabidopsis cDNA (AtRPB15.9) that encoded a protein related to the RPB4 subunit in yeast RNA polymerase II was cloned. The predicted molecular mass of 15.9 kDa for the AtRPB15.9 protein was significantly smaller than 25 kDa for yeast RBP4. In SDS-PAGE, AtRPB15.9 migrated as the seventh or eighth largest subunit (i.e. apparent molecular mass of 14-15 kDa) in Arabidopsis RNA polymerase II, whereas RPB4 migrates as the fourth largest subunit (i.e. apparent molecular mass of 32 kDa) in yeast RNA polymerase II. Unlike yeast RPB4 and RPB7, which dissociate from RNA polymerase II under mildly denaturing conditions, plant subunits related to RPB4 and RPB7 are more stably associated with the enzyme. Recombinant AtRPB15.9 formed stable complexes with AtRPB19.5 (i.e. a subunit related to yeast RPB7) in vitro as did recombinant yeast RPB4 and RPB7 subunits. Stable heterodimers were also formed between AtRPB15. 9 and yeast RPB7 and between yeast RPB4 and AtRPB19.5.

Aux/IAA proteins repress expression of reporter genes containing natural and highly active synthetic auxin response elements.

A highly active synthetic auxin response element (AuxRE), referred to as DR5, was created by performing site-directed mutations in a natural composite AuxRE found in the soybean GH3 promoter. DR5 consisted of tandem direct repeats of 11 bp that included the auxin-responsive TGTCTC element. The DR5 AuxRE showed greater auxin responsiveness than a natural composite AuxRE and the GH3 promoter when assayed by transient expression in carrot protoplasts or in stably transformed Arabidopsis seedlings, and it provides a useful reporter gene for studying auxin-responsive transcription in wild-type plants and mutants. An auxin response transcription factor, ARF1, bound with specificity to the DR5 AuxRE in vitro and interacted with Aux/IAA proteins in a yeast two-hybrid system. Cotransfection experiments with natural and synthetic AuxRE reporter genes and effector genes encoding Aux/IAA proteins showed that overexpression of Aux/IAA proteins in carrot protoplasts resulted in specific repression of TGTCTC AuxRE reporter gene expression.

ARF1, a transcription factor that binds to auxin response elements.

The plant hormone auxin regulates plant physiology by modulating the interaction of transcription factors with auxin response elements (AuxREs) of the affected genes. A transcription factor, Auxin Response Factor 1 (ARF1), that binds to the sequence TGTCTC in AuxREs was cloned from Arabidopsis by using a yeast one-hybrid system. ARF1 has an amino-terminal DNA-binding domain related to the carboxyl terminus of the maize transactivator Viviparous-1. Sequence requirements for ARF1 binding in vitro are identical to those that confer auxin responsiveness in vivo. The carboxyl terminus of ARF1 contains two motifs found in the Aux/IAA class of proteins and appears to mediate protein-protein interactions.

Reconstitution of yeast and Arabidopsis RNA polymerase alpha-like subunit heterodimers.

Two subunits of about 36-44 kDa and 13-19 kDa in the eukaryotic nuclear RNA polymerases share limited amino acid sequence similarity to the alpha subunit in Escherichia coli RNA polymerase. The alpha subunit in the prokaryotic enzyme has a stoichiometry of 2, but the stoichiometry of the alpha-like subunits in the eukaryotic enzymes is not entirely clear. To gain insight into the subunit stoichiometry and assembly pathway for eukaryotic RNA polymerases, in vitro reconstitution experiments have been carried out with recombinant alpha-like subunits from yeast and plant RNA polymerase II. The large and small alpha-like subunits from each species formed stable heterodimers in vitro, but neither the large or small alpha-like subunits formed stable homodimers. Furthermore, mixed heterodimers were formed between corresponding subunits of yeast and plants, but were not formed between corresponding subunits in different RNA polymerases from the same species. Our results suggest that RNA polymerase II alpha-like heterodimers may be the equivalent of alpha homodimers found in E. coli RNA polymerase.

A G-Box-Binding Protein from Soybean Binds to the E1 Auxin-Response Element in the Soybean GH3 Promoter and Contains a Proline-Rich Repression Domain.

The E1 promoter fragment (-249 to -203) is one of three auxin-response elements (AuxREs) in the soybean (Glycine max L.) GH3 promoter (Z.-B. Liu, T. Ulmasov, X. Shi, G. Hagen, T.J. Guilfoyle [1994] Plant Cell 6: 645-657). Results presented here further characterize and delimit the AuxRE within the E1 fragment. The E1 fragment functioned as an AuxRE in transgenic tobacco (Nicotiana tabacum L.) plants, as well as in transfected protoplasts. The AuxRE within E1 contains a G-box, and this G-box was used to clone a G-box-binding factor (GBF) from soybean (SGBF-2). This 45-kD GBF contains an N-terminal proline-rich domain and a C-terminal basic/leucine zipper DNA-binding domain. Gel-mobility shift assays were used to characterize the binding specificity of SGBF-2. Antiserum raised against recombinant SGBF-2 was used to further characterize SGBF-2 and antigenically related GBFs in soybean nuclear extracts. Co-transfection assays with effector and reporter plasmids in carrot (Daucus carota L.) protoplasts indicated that the N-terminal proline-rich domain of SGBF-2 functioned as a repression domain in both basal and auxin-inducible transcription.

A 14-kDa Arabidopsis thaliana RNA polymerase III subunit contains two alpha-motifs flanked by a highly charged C terminus.

We have sequenced a cDNA and a gene, AtRPC14, from Arabidopsis thaliana (At) (ecotype Columbia) that encode a protein related to the yeast RNA polymerases (Pol) I and III subunits, yAC19. Polyclonal antibodies raised against the recombinant At polypeptide (AtC14) bind to the Pol I and/or III subunits of about 13-15 kDa, but do not bind to any Pol II subunit in Pol purified from cauliflower, wheat or At. The amino acid (aa) sequence derived from the AtRPC14 cDNA and genomic clones consists of 122 aa, as compared to the 142 aa in the yeast yAC19 subunit and 143 aa in a putative Caenorhabditis elegans CeAC16 subunit. AtC14, yAC19 and CeAC16 contain a conserved sequence of about 85 aa which is related to two motifs in the alpha subunit of Escherichia coli (Ec) Pol. AtC14 lacks a highly charged N terminus of about 50 aa found in both yAC19 and CeAC16, but has a highly charged C terminus of about 30 aa not found in yAC19 and CeAC16.

Association between 36- and 13.6-kDa alpha-like subunits of Arabidopsis thaliana RNA polymerase II.

Two subunits in RNA polymerase II (e.g. RPB3 and RPB11 in yeast) and two subunits common to RNA polymerases I and III (e.g. AC40 and AC19 in yeast) contain one or two motifs related to the alpha subunit in prokaryotic RNA polymerases. We have sequenced two different cDNAs (AtRPB36a and AtRPB36b), the two corresponding genes from Arabidopsis thaliana that are homologs of yeast RPB3, and an Arabidopsis cDNA (AtRPB13.6) that is a homolog of yeast RPB11. The B36a subunit is the predominant B36 subunit associated with RNA polymerase II purified from Arabidopsis suspension culture cells, and this subunit has a stoichiometry of about 1. Results from protein association assays showed that the B36a and B36b subunits did not associate, but each of these subunits did associate with the B13.6 subunit in vivo and in vitro. Two motifs in the B36b subunit related to the prokaryotic alpha subunit were shown to be required for the in vitro interactions with the B13.6 subunit. Our results suggest that the B36 and B13.6 subunits associate to form heterodimers in Arabidopsis RNA polymerase II like the AC40 and AC19 heterodimers reported for yeast RNA polymerases I and III but unlike the B44 homodimers reported for yeast RNA polymerase II.

Arabidopsis expresses two genes that encode polypeptides similar to the yeast RNA polymerase I and III AC40 subunit.

A 40-kDa subunit in eukaryotic RNA polymerases (Pol) I and III (e.g., yeast yAC40) is related in a part of its aa sequence to the alpha subunit of prokaryotic Pol and to a 35-44-kDa subunit in Pol II (e.g., yeast yB44). We have cloned two cDNAs, AtRPAC42 and AtRPAC43, from an Arabidopsis thaliana (At) (ecotype Columbia) lambda Yes expression library that encode Pol I and III subunits related to yAC40. The aa sequences derived from the cDNA clones were found to be 72% identical to each other and 40% identical to yeast Pol I and III subunits yAC40, but only 30% identical to yeast Pol II subunit yB44. While most other nuclear Pol genes identified to date are single-copy genes, two genes encode 42 and 43-kDa subunits of At Pol I and/or III. A 42-kDa subunit with identical mobility in SDS-PAGE to the aAC42 in vitro translated subunit is found in Pol III purified from At suspension culture cells.

Composite structure of auxin response elements.

The auxin-responsive soybean GH3 gene promoter is composed of multiple auxin response elements (AuxREs), and each AuxRE contributes incrementally to the strong auxin inducibility to the promoter. Two independent AuxREs of 25 bp (D1) and 32 bp (D4) contain the sequence TGTCTC. Results presented here show that the TGTCTC element in D1 and D4 is required but not sufficient for auxin inducibility in carrot protoplast transient expression assays. Additional nucleotides upstream of TGTCTC are also required for auxin inducibility. These upstream sequences showed constitutive activity and no auxin inducibility when part or all of the TGTCTC element was mutated or deleted. In D1, the constitutive element overlaps the 5' portion of TGTCTC; in D4, the constitutive element is separated from TGTCTC. An 11-bp element in D1, CCTCGTGTCTC, conferred auxin inducibility to a minimal cauliflower mosaic virus 35S promoter in transgenic tobacco seedlings as well as in carrot protoplasts (i.e., transient expression assays). Both constitutive elements bound specifically to plant nuclear proteins, and the constitutive element in D1 bound to a recombinant soybean basic leucine zipper transcription factor with G-box specificity. To demonstrate further the composite nature of AuxREs and the ability of the TGTCTC element to confer auxin inducibility, we created a novel AuxRE by placing a yeast GAL4 DNA binding site adjacent to the TGTCTC element. Expression of a GAL4-c-Rel transactivator in the presence of this novel AuxRE resulted in auxin-inducible expression. Our results indicate that at least some AuxREs have a composite structure consisting of a constitutive element adjacent to a conserved TGTCTC element that confers auxin inducibility.

Auxin regulated gene expression and gravitropism in plants.

Transcription of two gene families, SAURs and GH3, in soybean has been shown to be specifically induced by the plant hormone auxin. The SAUR mRNAs have been shown to accumulate on the lower half and disappear from the upper half of soybean hypocotyls during gravitropic curvature. The SAUR and GH3 promoters have been fused to the beta-glucuronidase (GUS) reporter gene and shown to be specifically induced by auxins in transgenic tobacco plants. Histochemical staining and quantitative GUS assays indicate that these auxin inducible promoters are activated on the lower half of transgenic tobacco stems undergoing gravitropic curvature. The auxin transport inhibitors, TIBA and NPA, block both gravitropic curvature and the activation of the auxin responsive promoters in transgenic tobacco stems. The auxin responsive elements (AuxREs) within the SAUR and GH3 promoters have been identified, and these AuxREs are likely to be the elements that are responsible for the increased expression of the SAUR and GH3 genes during gravitropism.

An auxin-inducible element in soybean SAUR promoters.

The soybean SAUR (Small Auxin-Up RNA) genes are transcriptionally induced by exogenous auxins within a few minutes after hormone application. This response is specifically induced by auxins primarily in epidermal and cortical cells within elongation zones of hypocotyls and epicotyls. We have previously shown that an 832-bp soybean SAUR promoter/beta-glucuronidase (GUS) reporter gene fusion is responsive to auxin in transgenic tobacco plants (Y. Li, G. Hagen, T.J. Guilfoyle [1991] Plant Cell 3: 1167-1175). Similar results were obtained with an 868-bp SAUR 15A promoter-GUS reporter gene in transgenic tobacco (Y. Li, unpublished results). We have now analyzed a soybean SAUR 15A promoter in transgenic tobacco plants using 5' unidirectional deletions, internal deletions and mutations, and gain-of-function assays with a minimal cauliflower mosaic virus 35S promoter. Our results indicate that the distal upstream element/NdeI restriction endonuclease site element (NDE) (B.A. McClure, G. Hagen, C.S. Brown, M.A. Gee, T.J. Guilfoyle [1989] Plant Cell 1: 229-239) in the SAUR 15A promoter is necessary and sufficient for auxin induction. Our results also show that the 30-bp NDE portion of this element is responsible for most, if not all, of the auxin inducibility of the SAUR 15A promoter. The NDE contains two adjacent sequences, TGTCTC and GGTCCCAT, which have been previously identified as putative auxin-responsive elements. We propose that these elements might function independently or together, possibly with an additional element(s), to confer auxin inducibility to the SAUR promoters.

Soybean GH3 promoter contains multiple auxin-inducible elements.

The soybean GH3 gene is transcriptionally induced in a wide variety of tissues and organs within minutes after auxin application. To determine the sequence elements that confer auxin inducibility to the GH3 promoter, we used gel mobility shift assays, methylation interference, deletion analysis, linker scanning, site-directed mutagenesis, and gain-of-function analysis with a minimal cauliflower mosaic virus 35S promoter. We identified at least three sequence elements within the GH3 promoter that are auxin inducible and can function independently of one another. Two of these elements are found in a 76-bp fragment, and these consist of two independent 25- and 32-bp auxin-inducible elements. Both of these 25- and 32-bp auxin-inducible elements contain the sequence TGTCTC just upstream of an AATAAG. An additional auxin-inducible element was found upstream of the 76-bp auxin-inducible fragment; this can function independently of the 76-bp fragment. Two TGA-box or Hex-like elements (TGACGTAA and TGACGTGGC) in the promoter, which are strong binding sites for proteins in plant nuclear extracts, may also elevate the level of auxin inducibility of the GH3 promoter. The multiple auxin-inducible elements within the GH3 promoter contribute incrementally to the overall level of auxin induction observed with this promoter.

The soybean SAUR open reading frame contains a cis element responsible for cycloheximide-induced mRNA accumulation.

Little is known about how mRNA stability is regulated in higher plants. The SAURs (Small Auxin-Up RNAs) are a family of highly unstable mRNAs in soybean that rapidly increase in abundance after excised organs are treated with the plant hormone auxin. The SAURs are also induced by protein synthesis inhibitors, including cycloheximide, in the absence of auxin treatment and are superinduced when organs are treated with cycloheximide plus auxin. While the induction of SAURs is transcriptionally regulated by auxin, the induction by cycloheximide is posttranscriptional. Cycloheximide as well as other protein synthesis inhibitors appear to induce SAUR accumulation by increasing the stabilities of these mRNAs. To determine whether the 5'-untranslated region, the 3'-untranslated region, or the open reading frame of these unstable mRNAs is responsible for the cycloheximide inducibility, we have used chimeric genes in transgenic tobacco plants to test each of these mRNA regions. Our results show that the SAUR open reading frame within a chimeric mRNA confers cycloheximide inducibility in transgenic tobacco plants whereas chimeric mRNAs containing the SAUR 5'-untranslated region or 3'-untranslated region as isolated elements or in combination are not induced by cycloheximide. These results suggest that the SAUR open reading frame contains sequence elements that are involved in the stability of these mRNAs.