In vivo detection of regulatory factor binding sites of Arabidopsis thaliana Adh

In vivo footprinting experiments have been used to analyze the binding of trans-acting regulatory factors in the 5 flanking region upstream of the alcohol dehydrogenase (Adh) gene from Arabidopsis thaliana. Protein-DNA interactions were detected by dimethyl sulfate footprinting and genomic sequencing, using an A. thaliana cell suspension culture that constitutively expressed the Adh gene. Several distinct footprinting domains have been characterized, and the potential effects of the corresponding trans-acting factors have been inferred from a comparison with data from the maize alcohol dehydrogenase-1 (Adh1) gene. One binding site is similar in sequence to one of the anaerobic response elements (ARE) of the maize gene, which has also been shown to bind to a trans-acting factor. Several of the remaining binding sites apparently represent a class of elements sharing the sequence 5-GTGG-3 within their footprint.Comparisons with maize Adh1 in vivo protein interactions reveal that the elements of Adh promoter structure are highly conserved, but the relative and absolute positions of the elements are variable.     

Differential interactions of promoter elements in stress responses of the Arabidopsis Adh gene.

The Adh (alcohol dehydrogenase, EC 1.1.1.1.) gene from Arabidopsis thaliana (L.) Heynh. can be induced by dehydration and cold, as well as by hypoxia. A 1-kb promoter fragment (CADH: -964 to +53) is sufficient to confer the stress induction and tissue-specific developmental expression characteristics of the Adh gene to a beta-glucuronidase reporter gene. Deletion mapping of the 5' end and site-specific mutagenesis identified four regions of the promoter essential for expression under the three stress conditions. Some sequence elements are important for response to all three stress treatments, whereas others are stress specific. The most critical region essential for expression of the Arabidopsis Adh promoter under all three environmental stresses (region IV: -172 to -141) contains sequences homologous to the GT motif (-160 to -152) and the GC motif (-147 to -144) of the maize Adh1 anaerobic responsive element. Region III (-235 to -172) contains two regions shown by R.J. Ferl and B.H. Laughner ([1989] Plant Mol Biol 12: 357-366) to bind regulatory proteins; mutation of the G-box-1 region (5'-CCACGTGG-3', -216 to -209) does not affect expression under uninduced or hypoxic conditions, but significantly reduces induction by cold stress and, to a lesser extent, by dehydration stress. Mutation of the other G-box-like sequence (G-box-2: 5'-CCAAGTGG-3', -193 to -182) does not change hypoxic response and affects cold and dehydration stress only slightly. G-box-2 mutations also promote high levels of expression under uninduced conditions. Deletion of region I (-964 to -510) results in increased expression under uninduced and all stress conditions, suggesting that this region contains a repressor binding site. Region II (-510 to -384) contains a positive regulatory element and is necessary for high expression levels under all treatments.     

In vivo footprinting identifies an activating element of the maize Adh2 promoter specific for root and vascular tissues

In vivo footprinting identifies four putative cis elements of Adh2 that interact with protein factors within the DNase I hypersensitive domains of the 5′ flanking region. The power of in vivo footprinting to identify functionally significant sites within a gene promoter was tested by biochemical and transgenic analyses of the putative element at position −160. Biochemical analyses show that proteins isolated from maize cell suspensions will bind to the Adh2 promoter in vitro to generate a footprint at −160 identical to that seen in vivo. The partially purified factor bound to the promoter in vitro can be specifically competed with fragments of DNA containing the element sequence, further demonstrating that a specific protein generates the footprint over that sequence. Transgenic analyses indicate that the −160 element is a functional element of the maize Adh2 promoter that acts as an activator in the meristem and vascular tissue of roots and in the vascular tissue of stems and leaves.     

In vivo and in vitro characterization of protein interactions with the dyad G-box of the Arabidopsis Adh gene.

Expression of the alcohol dehydrogenase (Adh) and ribulose-1,5-bisphosphate carboxylase small subunit (RbcS) genes of higher plants is cell-type-specific and environmentally inducible. However, the tissues in which these two genes are expressed, their modes of induction, and their protein functions are quite distinct. Adh is expressed in non-green tissue, induced by anaerobiosis, and repressed in leaves. RbcS is only expressed in green tissue. An 8-base pair G-box element (5'-CCACGTGG-3') is associated with light-induced expression of RbcS and chalcone synthase. The same sequence is also present in the 5'-flanking region of Arabidopsis thaliana Adh, and this sequence is associated with a trans-acting factor in vivo. We report here that in vitro Adh G-box binding activity is present in crude whole cell extracts of both cell culture and leaves of Arabidopsis. The authenticity of in vitro Adh G-box binding is supported by in vivo and in vitro dimethylsulfate footprinting. A clear in vivo Adh G-box footprint occurs in cell cultures, but comparable in vivo binding to the Adh G-box does not occur in leaves. Therefore, there does not appear to be a direct correlation between the presence of the G-box factor in a tissue and its binding to the Adh G-box.     

Transposon-mediated mutations in the untranslated leader of maize Adh1 that increase and decrease pollen-specific gene expression.

The unstable mutation Adh1-Fm335 contains a Dissociation (Ds1) transposable element at position +53 in the untranslated leader of the maize Alcohol dehydrogenase-1 (Adh1) gene. Excision of Ds1 is known to generate new alleles with small additions and rearrangements of Adh1 DNA. We characterized 16 revertant alleles with respect to ADH1 activity levels in scutellum (nutritive tissue of the seed), anaerobic root, and pollen. Whereas gene expression was not different from the wild type in the sporophytic tissues of the scutellum and anaerobic root, there were strong allelic differences in pollen. One allele underexpressed pollen ADH1 at 48% of the wild-type level, and another overexpressed pollen ADH1 at 163% of the wild-type level. Quantitative RNase protection assays demonstrated that the mutant phenotypes reflected changes in the levels of steady state mRNA in pollen. These data provide a definitive demonstration of an overexpression mutant in plants and further show that marked increases in mRNA levels can follow minor alterations in central untranslated leader sequences. The nucleotide sequence of 12 new revertant alleles and the molecular mechanisms responsible for pollen-specific gene expression are discussed.     

Anaerobic induction and tissue-specific expression of maize Adh1 promoter in transgenic rice plants and their progeny.

Summary In order to analyze expression of the maize alcohol dehydrogenase 1 gene (Adh1), its promoter was fused with the gusA reporter gene and introduced into rice by protoplast transformation. Histochemical analysis of transgenic plants and their progeny showed that the maize Adh1 promoter is constitutively expressed in root caps, anthers, anther filaments, pollen, scutellum, endosperm and shoot and root meristem of the embryo. Induction of expression by the Adh1 promoter was examined using seedlings derived from selfed progeny of the transgenic plants. The results showed that expression of the Adh1 promoter was strongly induced (up to 81-fold) in roots of seedlings after 24 h of anaerobic treatment, concomitant with an increase in the level of gusA mRNA. 2,4-D also induced Adh1 promoter-directed expression of gusA to a similar extent. In contrast, little induction by anaerobic treatment was detected in transformed calli, leaves or roots of primary transformants or shoots of seedlings. A detailed examination of seedling roots during anaerobic treatment revealed that the induction started first at the meristem and after 3 h there was strong induction in the elongation zone which is located 1–2 mm above the meristem; the induction then progressed upward from this region. Our results suggest that transgenic rice plants carring the gusA reporter gene fused with promoters are useful for the study of anaerobic regulation of genes derived from graminaceous species.     

Anaerobic tolerant null: a mutant that allows Adh1 nulls to survive anaerobic treatment

Anaerobic tolerant null (ATN) is a recessive factor that allows alcohol dehydrogenase-1 (ADH1) null individuals of Zea mays L. to survive 24 h of anaerobic conditions. ADH1 null lines that do not possess this factor survive only a few hours of anoxia. We studied ADH activity levels in protein extracts from the primary root tissue of ATN. ADH levels were similar in ATN and other ADH1 null lines, suggesting that ADH activity does not account for differences in the ability of ATN to survive anaerobic treatment. The ATN survival trait segregated as a single recessive locus in crosses between ATN and double null (Adh1-S5657, Adh2-33). We also made crosses between ATN and 1s2p, an inbred line with ADH1 activity that carries an electrophoretic mutation of Adh2, to determine whether atn increases the number of survivors over that which would be expected from the segregation of Adh1 alone and to use the Adh2P allele to study the cosegregation of Adh2 and atn. The observed number of survivors in that cross exceeded the expected number of survivors by a margin consistent with a single recessive gene adding to the ADH+ survivors. Extracts from the primary root or scutellum of induced F2 seedlings from the above crosses were assayed for ADH activity by native polyacrylamide gel electrophoresis (PAGE) and simultaneously scored for survival to determine whether Adh2 and atn were segregating independently. We screened the (ATN x 1s2p)F2 progeny for ADH1 activity by staining root tips with an ADH-specific stain to select Adh1 null individuals prior to gel assay. Atn was found to be assorting independently of Adh1 and Adh2 in both crosses.     

A deletion adjacent to the maize transposable element Mu-1 accompanies loss of Adh1 expression.

Insertion of the maize transposable element Mu-1 into the first intron of the alcohol dehydrogenase locus (Adh1) of maize produced mutant Adh1-S3034 with 40% of the wild-type level of protein and mRNA. Continued instability at this locus resulted in secondary mutations with lower levels of protein expression. One of these, Adh1-S3034a, has no detectable ADH1 expression. This paper describes the precise nature of the changes in the Adh1 gene that gave rise to the S3034a allele. The Mu-1 element is still present in the mutant, but Adh1 sequences immediately adjacent to the element are deleted. The deletion starts precisely at the Mu-1 insertion site and extends 74 bp leftward removing part of the first intron, the intron:exon junction and 2 bp of the eleventh amino acid codon in the first exon of the gene. Tests for reversion within the somatic tissue of plants show that mutant S3034a, unlike its progenitor, is stably null for ADH1 activity.     

Molecular analysis of an alcohol dehydrogenase (Adh) gene from chromosome 1 of wheat

We have cloned and determined the nucleotide sequence of a gene encoding alcohol dehydrogenase (Adh) from Triticum aestivum cv. Millewa. Southern analysis using cv. Chinese Spring nullisomic-tetrasomic and ditelosomic lines established that the cloned gene mapped to the long arm of chromosome 1A and does not correspond to any previously identified wheat Adh locus. Southern analysis also provided evidence for triplicate copies of this Adh gene on the homoeologous group 1 chromosomes, while Northern blots indicated that the homoeologous group 1 Adh genes, like several other plant Adh genes, are transcribed under anaerobic conditions. Sequence analysis indicates that the cloned gene has a structure similar to both monocot and dicot Adh genes with an open reading frame encoding a polypeptide of 379 amino acids. Sequences important for eucaryotic gene expression such as the TATA box, polyadenylation signal, and intron splice sites were found in the expected positions. The open reading frame is interrupted by 8 introns which are in identical positions with 8 of the 9 introns in maize and pea Adh genes, suggesting that during evolution there are processes occurring that result in the loss of introns. Sequence analysis also revealed that the cloned wheat Adh gene shared extensive homology with the barley Adh3 gene not only in the coding region but also in the noncoding regions. However, this homology is discontinuous as a result of a 1.8-kbp insertion (TLM), which is present in the cloned wheat Adh gene and absent in the barley Adh3 gene. Sequence analysis of this insertion reveals features characteristic of the short terminal inverted repeat class of eucaryotic transposable elements. We have no evidence for the transposition of the TLM element. However, Southern blots reveal multiple copies of sequences related to TLM in the wheat genome and in other closely related species, suggesting that transposition may once have played an important role in the evolution of the Gramineae family.