Functional regions of the cauliflower mosaic virus 35S RNA promoter determined by use of the firefly luciferase gene as a reporter of promoter activity

Epigenetic changes in the expression of the maize A1 gene in Petunia hybrida: role of numbers of integrated gene copies and state of methylation

The Petunia hybrida mutant RL01 is white flowering due to a genetic block in the anthocyanin pathway. The introduction of the maize A1 cDNA under the control of the CaMV 35S RNA promoter leads to the production of pelargonidin derivatives, resulting in a brick red flower phenotype. Among the transgenic petunia plants the pigmentation of the petals exhibited different expression patterns which could be categorized into the 'red', the 'variegated', and the 'white' phenotype. This system proved to be especially suitable for the investigation of gene expression by simply looking at the pigmentation pattern of the petals. The uniformity of floral pelargonidin pigmentation is inversely correlated with the number of integrated A1 copies. Furthermore, a correlation was found between the methylation status of the 35S RNA promoter and the instability of the floral pelargonidin coloration. The status of promoter methylation controlling the expression of the A1 gene seems to be influenced by the copy number and the chromosomal position of the transferred gene.

Analysis of leaky viral translation termination codons in vivo by transient expression of improved beta-glucuronidase vectors

Plant RNA viruses commonly exploit leaky translation termination signals in order to express internal protein coding regions. As a first step to elucidate the mechanism(s) by which ribosomes bypass leaky stop codons in vivo, we have devised a system in which readthrough is coupled to the transient expression of beta-glucuronidase (GUS) in tobacco protoplasts. GUS vectors that contain the stop codons and surrounding nucleotides from the readthrough regions of several different RNA viruses were constructed and the plasmids were tested for the ability to direct transient GUS expression. These studies indicated that ribosomes bypass the leaky termination sites at efficiencies ranging from essentially 0 to ca. 5% depending upon the viral sequence. The results suggest that the efficiency of readthrough is determined by the sequence surrounding the stop codon. We describe improved GUS expression vectors and optimized transfection conditions which made it possible to assay low-level translational events.

Transcription factor IIA of wheat and human function similarly with plant and animal viral promoters

Eucaryotic transcription initiation by RNA polymerase II involves protein:DNA interactions during the formation of a transcription complex. In addition to RNA polymerase II there are at least five other general transcription factors necessary for initiation with the adenovirus major late promoter. One of these, TFIIA, is involved in the earliest events during transcription complex assembly. We have purified TFIIA from wheat germ and characterized it in an in vitro transcription system. Wheat TFIIA is a single polypeptide of Mr approximately 35 kd which functionally replaces human (HeLa) TFIIA to form a wheat/HeLa transcription system. [This polypeptide can be eluted from a SDS-polyacrylamide gel, refolded to a native conformation, and will function as wheat TFIIA in the heterologous system.] The heterologous system requires a lower optimal incubation temperature than the HeLa system. Biochemical characterization, using the adenovirus major late promoter, indicates that transcription reaction parameters for both wheat and HeLa TFIIA are similar but the kinetics of transcription for both TFIIAs are somewhat dissimilar. A plant viral promoter, the cauliflower mosaic virus 35S promoter, accurately and efficiently directs in vitro transcription in both the wheat/HeLa and HeLa systems with identical transcription kinetics. We conclude that TFIIA function has been conserved during evolution.

Evolutionary conservation of transcriptional machinery between yeast and plants as shown by the efficient expression from the CaMV 35S promoter and 35S terminator

Complementation of fission yeast mutants by plant genomic libraries could be a promising method for the isolation of novel plant genes. One important prerequisite is the functioning of plant promoters and terminators in Schizosaccharomyces pombe and Saccharomyces cerevisiae. Therefore, we studied the expression of the bacterial beta-glucuronidase (GUS) reporter gene under the control of the Cauliflower Mosaic Virus (CaMV) 35S promoter and 35S terminator. We show here that S. pombe initiates transcription at exactly the same start site as was reported for tobacco. The 35S CaMV terminator is appropriately recognized leading to a polyadenylated mRNA of the same size as obtained in plant cells transformed with the same construct. Furthermore, the GUS-mRNA is translated into fully functional GUS protein, as determined by an enzymatic assay. Interestingly, expression of the 35S promoter in the budding yeast S. cerevisiae was found to be only moderate and about hundredfold lower than in S. pombe. To investigate whether different transcript stabilities are responsible for this enormous expression difference in the two yeasts, the 35S promoter was substituted by the ADH (alcohol dehydrogenase) promoter from fission yeast. In contrast to the differential expression pattern of the 35S promoter, the ADH promoter resulted in equally high expression rates in both fission and budding yeast, comparable to the 35S promoter in S. pombe. Since the copy number of the 35S-GUS constructs differs only by a factor of two in the two yeasts, it appears that differential recognition of the 35S promoter is responsible for the different transcription rates.

Characteristics of a strong promoter from figwort mosaic virus: comparison with the analogous 35S promoter from cauliflower mosaic virus and the regulated mannopine synthase promoter

A segment of DNA from the genome of figwort mosaic virus (FMV) strain M3 possesses promoter activity when tested in electroporated protoplasts from, and transgenic plants of, Nicotiana tabacum cv. Xanthi nc. The 1.1 kb DNA segment, designated the '34S' promoter, is derived from a position on the FMV genome comparable to the position on the cauliflower mosaic virus (CaMV) genome containing the 35S promoter. The 34S and 35S promoters show approximately 63% nucleotide homology in the TATA, CCACT, and -18 to +1 domains, but in sequences further upstream the homology drops below 50%. Promoter activities were estimated using beta-glucuronidase and neomycin phosphotransferase II reporter gene systems. The activity of the 34S promoter segment approximates that of the 35S promoter in both protoplast transient expression assays and in stably transformed tobacco plants. Truncation of 5' sequences from the 34S promoter indicates that promoter strength depends upon DNA sequences located several hundred nucleotides upstream from the TATA box. In leaf tissue the 34S promoter is 20-fold more active than the mannopine synthase (MAS) promoter from Agrobacterium tumefaciens T-DNA. The 34S promoter lacks the root-specific and wound-stimulated expression of the MAS promoter, showing relatively uniform root, stem, leaf, and floral activities.

Interdependence and nodule specificity of cis-acting regulatory elements in the soybean leghemoglobin lbc3 and N23 gene promoters

The qualitative and quantitative contributions of four separate cis-acting DNA elements controlling the root nodule-specific soybean leghemoglobin lbc3 gene were analyzed in transgenic Lotus corniculatus plants. Expression from internal deletions in the 5' region between positions -49 and -1956 was monitored from a CAT reporter gene. The strong positive element (SPE; -1090, -947) responsible for high-level expression was demonstrated to be an organ-specific element by deleting proximal nodule-specific control elements. Deletion of the downstream qualitative organ-specific element (OSE; -139, -102) containing the putative nodulin consensus sequences 5'AAAGAT and 5'CTCTT resulted in a low expression level. Efficient SPE enhancement is therefore dependent on the organ-specific element, which by itself does not enhance expression. This quantitative effect of the immediate upstream region carrying the consensus sequences was also found in hybrid promoter studies using the soybean nodulin N23 gene promoter, suggesting the involvement of these motifs in a regulatory mechanism for nodulin genes. Deletion of the lbc3 negative element (NE, -102, -49) linking the SPE and OSE onto the TATA box did not lead to unregulated expression. These results indicate that interaction between positive, negative and neutral qualitative elements controls lbc3 expression. Binding of the nuclear protein NAT2 at the lbc3 weak positive element (WPE; -230, -170) is probably not directly required for this mechanism.

Cell cycle-regulated gene expression in transgenic plant cells

A majority of histone genes are expressed in the S phase during the cell cycle. Using the gene expression system of transformed sunflower cells into which wheat histone H3 gene was introduced by the Ti-plasmid gene transfer technique, we determined three cis-acting control sequences (hexameric, octameric, and nonameric motifs) which seemed to confer the S-phase-specific transcription of wheat histone genes. Furthermore, as candidates for regulatory transcription factors, three nuclear DNA-binding proteins HBP-1a, HBP-1b, and HBP-2 that interact with the hexameric and nonameric motifs were identified. The structural analysis of the cDNA of HBP-1a revealed that a nuclear protein has the leucine-zipper structure and a DNA-binding motif. The hexameric motif in the H3 gene was also seen in cauliflower mosaic virus 35S (CaMV 35S) promoter and shown to function as a regulatory element of this promoter. The wheat HBP-1b can interact with the hexameric motif of the CaMV 35S promoter. Much attention has been paid to the significance of the hexameric sequences within the H3 and CaMV 35S promoters and the DNA-binding proteins HBP-1a and HBP-1b.

Expression of the beta-glucuronidase gene under the control of the CaMV 35s promoter in Schizosaccharomyces pombe

We have transformed Schizosaccharomyces pombe with the beta-glucuronidase (GUS) gene from Escherichia coli under the control of the plant cauliflower mosaic virus (CaMV) 35S promoter element. Efficient expression of GUS enzyme was observed. Moreover, transcription initiated at a unique site identical to that used in plant cells.

Wheat nuclear protein HBP-1 binds to the hexameric sequence in the promoter of various plant genes

HBP-1 is a sequence-specific DNA-binding protein that interacts with the hexameric sequence ACGTCA, the putative cis-acting element of the wheat histone H3 gene. Gel mobility shift and DNase I footprint analyses showed that this protein interacts with homologous sequences in the regulatory regions for the transcription of the cauliflower mosaic virus (CaMV) 35S RNA and nopaline synthase (NOS) genes, evidence that HBP-1 may bind to hexameric sequences in the regulatory regions of various genes. An HBP-1-like protein, indistinguishable from wheat HBP-1 in its the DNA-binding specificity, is present in sunflower nuclear extract, an indication that HBP-1-like DNA-binding proteins also exist in dicots.

Photoregulation of a phytochrome gene promoter from oat transferred into rice by particle bombardment

The regulatory photoreceptor phytochrome controls the transcription of its own phy genes in a negative feedback fashion. We have exploited microprojectile-mediated gene transfer to develop a rapid transient expression assay system for the study of DNA sequences involved in the phytochrome-regulated expression of these genes. The 5'-flanking sequence and part of the structural region of an oat phy gene have been fused to a reporter coding sequence (chloramphenicol acetyltransferase, CAT) and introduced into intact darkgrown seedlings by using high-velocity microprojectiles. Expression is assayable in less than 24 hr from bombardment. The introduced oat phy-CAT fusion gene is expressed and down-regulated by white light in barley, rice, and oat, whereas no expression is detected in three dicots tested, tobacco, cucumber, and Arabidopsis thaliana. In bombarded rice shoots, red/far-red light-reversible repression of expression of the heterologous oat phy-CAT gene shows that it is regulated by phytochrome in a manner parallel to that of the endogenous rice phy genes. These data indicate that the transduction pathway components and promoter sequences involved in autoregulation of phy expression have been evolutionarily conserved between oat and rice. The experiments show the feasibility of using high-velocity microprojectile-mediated gene transfer for the rapid analysis of light-controlled monocot gene promoters in monocot tissues that until now have been recalcitrant to such studies.

Multiplicity of the DNA-binding protein HBP-1 specific to the conserved hexameric sequence ACGTCA in various plant gene promoters

A novel DNA-binding protein that specifically interacts with the hexameric sequence ACGTCA in the regulatory region of the wheat histone H3 gene has been identified in wheat nuclear extract and designated HBP-1a. The nuclear protein HBP-1 previously identified as a DNA-binding protein that interacts with hexameric sequences in the H3, cauliflower mosaic virus (CaMV) 35 S RNA, and nopaline synthase (NOS) promoter regions therefore has been renamed HBP-1b. The flanking sequences that surround the hexameric sequence may account for the difference in the binding properties of HBP-1a and HBP-1b.

Site-specific mutations alter in vitro factor binding and change promoter expression pattern in transgenic plants

The 35S promoter of cauliflower mosaic virus (CaMV) is able to confer high-level gene expression in most organs of transgenic plants. A cellular factor from pea and tobacco leaf tissue, which recognizes nucleotides in a tandemly repeated TGACG motif at the -75 region of this promoter, has been detected by DNase I footprinting and gel retardation assays. This factor is named activation sequence factor 1 (ASF-1). A cellular factor binding to the two TGACG motifs can also be detected in tobacco root extracts. Mutations at these motifs inhibit binding of ASF-1 to the 35S promoter in vitro. When examined in transgenic tobacco, these mutations cause a 50% drop in leaf expression of the 35S promoter. In addition, these same mutations attenuate stem and root expression of the 35S promoter about 5- to 10-fold when compared to the level of expression in leaf. In contrast, mutations at two adjacent CCAAT-box-like sequences have no dramatic effect on promoter activity in vivo. A 21-base-pair element containing the two TGACG motifs is sufficient for binding of ASF-1 in vitro when inserted in a green-tissue-specific promoter. In vivo, the insertion of an ASF-1 binding site caused high levels of expression in root. Thus, a single factor binding site that is defined by site-specific mutations is shown to be sufficient to alter the expression pattern of promoters in vivo.

Differential Accumulation of a Transcript Driven by the CaMV 35S Promoter in Transgenic Tobacco

A transcriptional fusion composed of the CaMV 35S promoter, a 19 kD zein cDNA, and the 3' flanking regions from the 0' to 1' T(R) T-DNA genes was introduced into tobacco (Nicotiana tabacum) by Agrobacterium-mediated transformation. The accumulation of RNA generated from this transcriptional fusion varied both temporally and spatially in all tissues examined in greenhouse-grown tobacco plants, suggesting that the CaMV 35S promoter is not constitutive. Younger, actively dividing leaf, stem, root, and flower tissues contained higher steady state levels of zein RNA than did older, more quiescent tissues. Zein RNA levels greatly decreased during seed development and were undetectable in the mature seed. In addition, the two RNA termination or processing signals present in our construct were differentially utilized during seed development.

Nuclear proteins binding to a cauliflower mosaic virus 35S truncated promoter

Proteins present in tobacco nuclear extracts bind to a truncated cauliflower mosaic virus (CaMV) 35S promoter fragment (from -90 to +2 relative to the transcription start site) in a sequence specific manner. Gel mobility shift assays show the presence of two protein-DNA complexes that are not competed by a -47/+2 promoter fragment. DNAse I protection and DNA methylation interference reveal two protected sites in the slower migrating complex; both include the pentamer TGACG, separated by a stretch of eight nucleotides where G methylation does not prevent the binding of the proteins. The faster complex is the prevalent form at low protein concentrations. As the protein concentration increases a non-linear rise in the amount of the slower migrating complex relative to the faster one is seen suggesting that cooperative effects are involved in the binding to the second site.

Hairy roots - a short cut to transgenic root nodules

To facilitate molecular studies of symbiotic nitrogen fixation a procedure for rapid production of transgenic root nodules was established on the legumeLotus corniculatus (Bird'sfoot trefoil). Regeneration of transgenic plants is not required as transgenic nodules are formed onAgrobacterium rhizogenes incited roots inoculated withRhizobium. Easy identification of transformed roots is possible using a set ofA. rhizogenes acceptor strains carrying assayable marker genes such as chloramphenicol acetyltransferase (CAT), β-glucuronidase (GUS), or luciferase (LUC) under control of the cauliflower mosaic virus (CaMV) 35S promoter. Counterselection ofA. rhizogenes after infection of plants was improved using an auxotrophy marker.

Multiple cis regulatory elements for maximal expression of the cauliflower mosaic virus 35S promoter in transgenic plants

The 35S promoter is a major promoter of the cauliflower mosaic virus that infects crucifers. This promoter is still active when excised from cauliflower mosaic virus and integrated into the nuclear genome of transgenic tobacco. Previous work has shown that the -343 to -46 upstream fragment is responsible for the majority of the 35S promoter strength (Odell, J.T., Nagy, F., and Chua, N.-H. [1985]. Nature 313, 810-812). Here we show by 5', 3', and internal deletions that this upstream fragment can be subdivided into three functional regions, -343 to -208, -208 to -90, and -90 to -46. The first two regions can potentiate transcriptional activity when tested with the appropriate 35S promoter sequence. In contrast, the -90 to -46 region by itself has little activity but it plays an accessory role by increasing transcriptional activity of the two distal regions. Finally, we show that monomers and multimers of a 35S fragment (-209 to -46) can act as enhancers to potentiate transcription from a heterologous promoter.

Dissection of 5' upstream sequences for selective expression of the Nicotiana plumbaginifolia rbcS-8B gene

We have previously isolated and characterized a gene (rbcS-8B) from the wild-type species Nicotiana plumbaginifolia, encoding the small subunit of ribulose-1,5-bisphosphate carboxylase. Using transgenic N. plumbaginifolia as a host, we found that a 5' upstream region (-1038 to +32) of rbcS-8B contains all the sequences required for organ-specific and light-dependent expression of the gene. Here we report a detailed analysis of the 5' upstream region of rbcS-8B. Gene transfer experiments indicate that the region between -1038 to -102 contains at least two enhancer-like elements. The proximal element located between -312 and -102, confers organ-specific and light-inducible expression upon a reporter gene and closely resembles previously identified elements in other light-responsive plant genes. The distal element with novel characteristics is located between -1038 and -589. It can enhance expression from the cauliflower mosaic virus 35S promoter, but only when the -90 to -46 region of the 35S promoter is present. It confers on the heterologous promoter the organ-specificity of a typical rbcS gene but the enhanced transcription in leaves is insensitive to light. These experiments show for the first time that organ-specificity and light-responsiveness can be determined by separable cis-regulatory elements. The implications for the regulation of light-responsive genes are discussed.

Both positive and negative regulatory elements mediate expression of a photoregulated CAB gene from Nicotiana plumbaginifolia

We have analyzed promoter regulatory elements from a photoregulated CAB gene (Cab-E) isolated from Nicotiana plumbaginifolia. These studies have been performed by introducing chimeric gene constructs into tobacco cells via Agrobacterium tumefaciens-mediated transformation. Expression studies on the regenerated transgenic plants have allowed us to characterize three positive and one negative cis-acting elements that influence photoregulated expression of the Cab-E gene. Within the upstream sequences we have identified two positive regulatory elements (PRE1 and PRE2) which confer maximum levels of photoregulated expression. These sequences contain multiple repeated elements related to the sequence-ACCGGCCCACTT-. We have also identified within the upstream region a negative regulatory element (NRE) extremely rich in AT sequences, which reduces the level of gene expression in the light. We have defined a light regulatory element (LRE) within the promoter region extending from -396 to -186 bp which confers photoregulated expression when fused to a constitutive nopaline synthase ('nos') promoter. Within this region there is a 132-bp element, extending from -368 to -234 bp, which on deletion from the Cab-E promoter reduces gene expression from high levels to undetectable levels. Finally, we have demonstrated for a full length Cab-E promoter conferring high levels of photoregulated expression, that sequences proximal to the Cab-E TATA box are not replaceable by corresponding sequences from a 'nos' promoter. This contrasts with the apparent equivalence of these Cab-E and 'nos' TATA box-proximal sequences in truncated promoters conferring low levels of photoregulated expression.

Tn10-encoded tet repressor can regulate an operator-containing plant promoter

The Tn10-encoded tet repressor-operator system was used to regulate transcription from the cauliflower mosaic virus (CaMV) 35S promoter. Expression was monitored in a transient assay system by using electric field-mediated gene transfer ("electroporation") into tobacco protoplasts. The tet repressor, being expressed in the plant cells under the control of eukaryotic transcription signals, blocks transcription of a CaMV 35S promoter chloramphenicol acetyltransferase (cat) fusion gene when the two tet operators flank the "TATA" box. In the presence of the inducer tetracycline, expression is restored to full activity. Location of the operators 21 base pairs downstream of the transcription start site does not significantly affect transcription in the presence of the repressor. These experiments show that a prokaryotic regulatory protein can function in plant cells. The tet repressor-operator complex may be useful for specifically inducing transferred genes at different stages of plant development.

Bacillus thuringiensis section sign-Endotoxin Expressed in Transgenic Nicotiana tabacum Provides Resistance to Lepidopteran Insects

The crystal proteins, or section sign-endotoxins, of Bacillus thuringiensis are specifically lethal to Lepidopteran insects. We utilized a truncated and modified portion of a cloned crystal protein gene to construct a chimeric gene capable of expression in plant cells. Using an Agrobacterium tumefaciens binary vector system, we then transferred the chimeric toxin gene into tobacco (Nicotiana tabacum cv Havana 425) cells and regenerated recombinant plants. One to several copies per cell of the toxin gene are routinely present in the recombinant plants. Hybridization experiments demonstrated that these plants had a new RNA species of the size expected for the truncated toxin mRNA, and a polypeptide having the mobility expected for the truncated toxin was detected by immunoblotting. Significant variation was found in the levels of toxin-specific RNA expression between different recombinants, but the levels of hybridizing RNA in transformants correlated with the level of toxicity demonstrated against Manduca sexta (tobacco hornworm), and other Lepidopteran insects. The recombinant genes were transmitted to progeny and resistance to insects was maintained, thus demonstrating that the introduction of toxin genes into plants may be a practical method of providing protection against certain insect pests.