Developmental and pathogen-induced activation of an msr gene, str246C, from tobacco involves multiple regulatory elements

A family of genes, the so-called msr genes (multiple stimulus response), has recently been identified on the basis of sequence homology in various plant species. Members of this gene family are thought to be regulated by a number of environmental or developmental stimuli, although it is not known whether any one member responds more specifically to one stimulus, or whether each gene member responds to various environmental stimuli. In this report, we address this question by studying the tobacco msr gene str246C. Using transgenic tobacco plants containing 2.1 kb of 5 flanking DNA sequence from the str246C gene fused to the -glucuronidase (GUS) coding region, the complex expression pattern of the str246C promoter has been characterized. Expression of the str246C promoter is strongly and rapidly induced by bacterial, fungal and viral infection and this induction is systemic. Elicitor preparations from phytopathogenic bacteria and fungi activate the str246C promoter to high levels, as do wounding, the application of auxin, auxin and cytokinin, salicylic acid or copper sulfate, indicating the absence of gene specialization within the msr gene family, at least for str246C. In addition, GUS activity was visualized. histochemically in root meristematic tissues of tobacco seedlings and is restricted to roots and sepals of mature plants. Finally, analysis of a series of 5 deletions of the str246C promoter-GUS gene fusion in transgenic tobacco plants confirms the involvement of multiple regulatory elements. A region of 83 by was found to be necessary for induction of promoter activity in response to Pseudomonas solanacearum, while auxin inducibility and root expression are apparently not controlled by this element, since its removal does not abolish either response. An element of the promoter with a negative effect on promoter activation by P. solanacearum was also identified.Joint first authors     

The Mode of Expression and Promoter Analysis of the arcA Gene, an Auxin-Regulated Gene in Tobacco BY-2 Cells

The arcA, a member of the G protein rß-subunit family,was isolated from tobacco BY-2 cells as an auxin-responsivegene. Characterization of arcA, which should help to elucidatethe function of the gene product in the plant cells, was performedwith emphasis on the mode of expression and the analysis ofits promoter. Accumulation of the arcA message was detectedonly after treatments with auxins and not after treatments withother phytohormones or CdCl₂, implying that responsiveness ofarcA was exclusive to auxin. The putative arcA promoter regionwas fused to a reporter gene for rß-glucuronidase(GUS), and transient expression was analyzed in tobacco BY-2cells. Two series of arcA promoter/GUS chimeric genes were constructed.One consisted of a set of 5' nested deletions of the arcA promoterconnected to the gene for GUS and the other consisted of a varietyof the arcA promoter fragments fused to a minimal promoter-GUSconstruct. The results indicated that the promoter sequencecovering four sets of direct repeats (– 562 to –167)was necessary for the sufficient response of arcA promoter toauxin in BY-2 cells. Moreover, irrespective of auxin treatment,elevated activity of GUS driven by this promoter fragment wasdetected, a result that implies that this region behaves anenhancer in BY-2 cells. (Received September 30, 1995; Accepted March 1, 1996)     

Analysis of an abscisic acid (ABA)-responsive gene promoter belonging to the Asr gene family from tomato in homologous and heterologous systems

Asr is a family of genes that maps to chromosome 4 of tomato. Asr2, a recently reported member of this family, is believed to be regulated by abscisic acid (ABA), stress and ripening. A genomic Asr2 clone has been fully sequenced, and candidate upstream regulatory elements have been identified. To prove that the promoter region is functional in vivo, we fused it upstream of the β-glucuronidase (GUS) reporter gene. The resulting chimeric gene fusion was used for transient expression assays in papaya embryogenic calli and leaves. In addition, the same construct was used to produce transgenic tomato, papaya, tobacco, and potato plants. Asr2 upstream sequences showed promoter function in all of these systems. Under the experimental conditions tested, ABA stimulated GUS expression in papaya and tobacco, but not in tomato and potato systems.     

Induction of karyopherin α1 expression by indole-3-acetic acid in auxin-treated or overproducing tobacco plants

Macromolecules may transfer between the cytoplasm and the nucleus only through specific gates—the nuclear pore complexes (NPCs). Translocation of nucleic acids and large proteins requires the presence of a nuclear localization signal (NLS) within the transported molecule. This NLS is recognized by a class of soluble transport receptors termed karyopherins α and β. We previously characterized the expression pattern of the tomato karyopherin α1 (LeKAPα1) promoter in transformed tobacco plants. Expression of LeKAPα1 was mainly observed in growing tissues where cell division and extension is rapid. The expression pattern of LeKAPα1 resembled that of auxin-responsive genes. This led us to suggest that auxin participates in the regulation of LeKAPα1 expression. Here we characterized the correlation between auxin level and the activity of the LeKAPα1 promoter. To this end, transgenic tobacco plants carrying the GUS reporter gene under the control of the LeKAPα1 promoter were treated with various levels of exogenous auxin. We also studied transgenic plants in which we increased the endogenous levels of auxin. For this, we expressed in plants both the LeKAPα1 promoter-GUS reporter and the Agrobacterium tumefaciens iaaM gene, which increases the endogenous levels of auxin. The results indicate that the auxin indole-3-acetic acid (IAA) can induce LeKAPα1 expression. We also identified that the sites and levels of LeKAPα1 expression correlated with the endogenous pathways of polar auxin transport.Key words: auxin, karyopherin α1, nuclear pore complex, TYLCV, plant virus     

Rol genes alter hormonal requirements for protoplast growth and modify the expression of an auxin responsive promoter

Summary Growth characteristics of tobacco protoplasts containing rolA linked to its own promoter, or the rolB, or rolC genes of Agrobacterium rhizogenes linked to the Cauliflower Mosaic Virus 35S RNA promoter were compared with those from untransformed plants. RolA protoplasts require auxin and cytokinin for callus formation. Protoplasts overexpressing rolB and C form callus in the absence of exogenously applied auxin and cytokinin, respectively. Long term callus growth requires auxin, but the requirement for cytokinin is not critical. Optimal transient expression of an auxin responsive promoter element occurred at lower external levels of auxin in rolB and rolC protoplasts compared with untransformed protoplasts. Addition of putrescine was required for auxin responsive transient gene expression in rolA protoplasts suggesting that polyamines, or their products affect gene expression in rolA plants.Abbreviations T-DNA transferred DNA - TL-DNA left transferred DNA - NAA naphthalene acetic acid - PEG polyethylene glycol - GUS glucuronidase - CaMV cauliflower mosaic virus     

Cloning and characterization of a cold inducible Pal promoter from Fagopyrum tataricum

Phenylalanine ammonia-lyase (PAL) catalyzes the first reaction in biosynthesis pathway of flavonoids and plays an important role in plant stress resistance. In this study, the 5’ flanking region of phenylalanine ammonia-lyase gene was isolated from Fagopyrum tataricum by thermal asymmetric interlaced PCR method, named PFtPal (GenBank: KF463139). To investigate the functional properties of PFtPal, we constructed a series of plant expression vectors that contained different promoter fragments resulting from nest deletions and had successfully transformed them into tobacco leaves by Agrobacterium tumefaciens. Histochemical assay of GUS suggested that PFtPal could drive GUS gene expression in leaves and roots, while GUS activity was not detected in the stem. In addition, the region of ?274 bp to ?1 bp was enough to drive normal expression of GUS gene. Low temperature treatment of transgenic tobacco plants demonstrated that PFtPal conferred cold-induced expression. Taken together, our study will help to better understand the Pal promoter, and provides a candidate promoter for molecular breeding in Fagopyrum plants.     

hsr203J, a tobacco gene whose activation is rapid, highly localized and specific for incompatible plant/pathogen interactions

A novel plant defense gene, hsr203J, whose corresponding mRNA accumulates preferentially during the incompatible interaction of tobacco (Nicotiana tabacum L.) with a pathogenic bacterium, Pseudomonas solanacearum, has been isolated and sequenced. No sequence homology of the putative product of this gene has been found in data bases. Evidence is presented here that the hsr203J gene promoter, when fused to the GUS reporter gene, is selectively expressed in response to the hypersensitive response (HR)-inducing bacteria in tobacco protoplasts and that the sequences responsible for this response are contained within 1.4 kb of the 5′ noncoding region. The temporal and spatial patterns of hsr203J activation in leaves and roots inoculated with P. solanacearum indicate that the hsr 203J promoter exhibits a rapid (3–6 h post-inoculation) and high level of induction only in plant cells inoculated with the HR-inducing bacterial isolate. In addition, this gene promoter which does not respond to various stress conditions and is only very weakly induced during compatible interactions, is strongly dependent on hrp (hypersensitive response and pathogenicity) genes of P. solanacearum. These data indicate that the hsr 203J gene promoter exhibits new and original characteristics of activation with regard to the plant defense genes studied so far; its spatial and temporal program of activation together with its specific induction during the HR underline the importance of this gene as a molecular tool for studying the establishment and regulation of the HR.