Evolution and divergence in the coding and promoter regions of the Populus gene family encoding xyloglucan endotransglycosylase/hydrolases

Xyloglucan endotransglycosylase/hydrolases (XTHs) are believed to modify the cell wall structure by cleaving a xyloglucan polymer and transferring the newly generated, potentially reducing, terminal to another xyloglucan. We report here the detailed analysis of 37 Populus trichocarpa XTH genes/proteins in their divergence in both the coding and 5′ promoter regions. Our results show that the Populus XTH genes have experienced whole-genome and local duplications and pre- and post-speciation divergence. Genome-wide and segmental duplications seem to be dominant in subfamily I and III, while tandem duplication seems to be the major mechanism for the subfamily II expansion, which also has higher average ratios of K _a/K _s compared to those in subfamily I and III. There was a general lack of organ-specific gene expression. In contrast, the expression patterns in subfamily II varied in response to various hormone treatments, with II-A being up-regulated and II-B down-regulated after 2 h of hormone treatment. Expression for this subfamily was verified using the 1.5-kb PtXTH22 promoter that was fused with the GUS reporter gene and transformed into Arabidopsis. The PtXTH22 promoter contains auxin response element, ethylene insensitive 3-like factors, and brassinosteroid response cis-elements. Histochemical GUS staining of transgenic Arabidopsis seedlings confirmed that the PtXTH22 promoter was up-regulated by several hormones.     

Stress induction and developmental regulation of a rice chitinase promoter in transgenic tobacco

A 1.5 kb promoter fragment from the rice (Oryza sativa L.) RCH10 gene, which encodes a basic endochitinase inducible by wounding and fungal elicitor, was translationally fused to the β-glucuronidase (GUS) reporter gene and transferred to tobacco by Agrobacterium tumefaciens-mediated leaf disc transformation. Wounding of leaves induced GUS activity from low basal levels, and addition of fungal elicitor to the wounded tissue caused a further marked activation of the gene fusion. During vegetative development high levels of GUS activity were observed in roots and moderate levels in stems. Histochemical analysis indicated that the promoter was active in vascular and epidermal tissue, and the root apical tip. In flowers, high levels of GUS activity were observed in stigmas, ovaries and pollen-containing anthers, but only low levels in sepals and petals. The promoter 5′-deleted to ?160 exhibited the same patterns of expression in floral organs, and was also strongly induced by wounding and elicitor, but GUS activity was markedly reduced in vegetative organs. More detailed 5′ deletions showed that a cis-element required for floral expression was located between ?160 and ?74, and a cis element sufficient for stress induction was located 3′ of ?74. This proximal region 3′ of ?74 was also sufficient for expression in transfected rice protoplasts derived from suspension cultured cells. These data indicate that the complex developmental and environmental regulation of RCH10 promoter activity involves several distinct cis-elements for vegetative expression, floral expression and stress induction, and that signal pathways for wound and elicitor induction are conserved between monocotyledonous and dicotyledonous plants.     

Functional dissection of a bean chalcone synthase gene promoter in transgenic tobacco plants reveals sequence motifs essential for floral expression

Expression of chalcone synthase (CHS), the first enzyme in the flavonoid branch of the phenylpropanoid biosynthetic pathway in plants, is induced by developmental cues and environmental stimuli. We used plant transformation technology to delineate the functional structure of the French bean CHS15 gene promoter during plant development. In the absence of an efficient transformation procedure for bean, Nicotiana tabacum was used as the model plant. CHS15 promoter activity, evaluated by measurements of -d-glucuronidase (GUS) activity, revealed a tissue-specific pattern of expression similar to that reported for CHS genes in bean. GUS activity was observed in flowers and root tips. Floral expression was confined to the pigmented part of petals and was induced in a transient fashion. Fine mapping of promoter cis-elements was accomplished using a set of promoter mutants generated by unidirectional deletions or by site-directed mutagenesis. Maximal floral and root-specific expression was found to require sequence elements located on both sides of the TATA-box. Two adjacent sequence motifs, the G-box (CACGTG) and H-box (CCTACC(N)₇CT) located near the TATA-box, were both essential for floral expression, and were also found to be important for root-specific expression. The CHS15 promoter is regulated by a complex interplay between different cis-elements and their cognate factors. The conservation of both the G-box and H-box in different CHS promoters emphasizes their importance as regulatory motifs.     

Promoter elements required for phloem-specific gene expression from the RTBV promoter in rice

Previous studies indicated that a DNA fragment comprising nucleotides (nt) ?164 to +45 of the RTBV promoter is sufficient to drive phloem-specific expression of a reporter gene in transgenic rice plants. In addition, two potential cis elements, Box I (nt ?3 to +5) and Box II (nt ?53 to ?39) were identified by DNA-protein interaction assays. In this study, the results of further in vivo studies involving mutagenesis of selected DNA sequences and analysis of expression of a reporter gene in transgenic rice plants revealed that, in addition to Box I and Box II, other elements are required for phloem-specific gene expression, among which are a direct repeat (ASL Box, nt ?98 to ?79) and a GATA motif (nt ?143 to ?135). All the these elements bind rice nuclear factors specifically, and mutations of the elements were identified that resulted in loss-of-competition in electrophoretic mobility shift assays. A DNA fragment comprising nt ?164 to ?32, which contains Box II, the ASL Box and the GATA motif, conferred phloem-specific reporter gene expression independent of Box I when fused to a heterologous CaMV 35S minimal promoter and introduced to transgenic rice plants. Studies that introduced point mutations suggested that in the context of the ?103 to +45 promoter fragment, Box II and the ASL Box act synergistically to confer tissue-specific gene expression. Similar studies in the ?164 to +45 promoter fragment indicated that the ?164 to ?103 region, which includes the GATA motif, contains sequences that are functionally redundant with those in the ?103 to ?32 region, including the ASL Box and Box II. It is concluded that these regions act additively to direct phloem-specific gene expression.     

Promoter analysis of the chalcone synthase (chsA) gene of Petunia hybrida: a 67 bp promoter region directs flower-specific expression

In order to scan the 5 flanking region of the chalcone synthase (chs A) gene for regulatory sequences involved in directing flower-specific and UV-inducible expression, a chimaeric gene was constructed containing the chs A promoter of Petunia hybrida (V30), the chloramphenicol acetyl transferase (cat) structural sequence as a reporter gene and the chs A terminator region of Petunia hybrida (V30). This chimaeric gene and 5 end deletions thereof were introduced into Petunia plants with the help of Ti plasmid-derived plant vectors and CAT activity was measured. A 220 bp chs A promoter fragment contains cis-acting elements conferring flower-specific and UV-inducible expression. A promoter fragment from –67 to +1, although at a low level, was still able to direct flower-specific expression but could not drive UV-inducible expression in transgenic Petunia seedlings. Molecular analysis of binding of flower nuclear proteins to chs A promoter fragments by gel retardation assays showed strong specific binding to the sequences from –142 to +81. Promoter sequence comparison of chs genes from other plant species, combined with the deletion analysis and gel retardation assays, strongly suggests the involvement of the TACPyAT repeats (–59 and –52) in the regulation of organ-specificity of the chs A gene in Petunia hybrida. We also describe an in vitro organ-specific transient expression system, in which flower or purple callus protoplasts are used, that enables us to pre-screen organ-specific expression of a chimaeric reporter gene.     

Overexpression of rice phytochrome A in tobacco seedlings modifies responsiveness but not competence to phytochrome

To analyse the control of rice phytochrome A (phyA) overexpression (wild type or variously mutated) on gene regulation, transgenic tobacco lines overexpressing various rice phyA constructs were crossed with transgenic tobacco lines containing mustard Lhcb1 or Chs1 promoters fused to the uidA reporter gene (-glucuronidase). It was demonstrated that the temporal pattern of competence to respond to phytochrome was not altered by rice phyA overexpression. Also, overexpression of rice phyA did not change the spatial pattern of gene expression. The responsiveness to red and far-red light, on the other hand, depended on the type of overexpressed rice phyA in a structure-function relation: the serine-to-alanine mutant mediated an enhanced response both under continuous red and far-red light, whereas the N-terminal deletion mutant showed a dominant negative effect under continuous far-red light and even after red light pulses. However, the effectiveness of rice phyA overexpression depended on the promoter construct and the developmental stage of the seedlings. The Lhcb1 promoter also conferred -glucuronidase activity in etiolated seedlings. This dark expression could be decreased by a long-wavelength farred light pulse given early in development (24 h after sowing), indicating that this phenomenon is under the control of stable types of phytochrome.Abbreviations Chs1 chalcone synthase - GUS -glucuronidase - Lhcb1 type 1 light-harvesting chlorophyll a/b-binding protein - NTD N-terminal deletion mutant of rice phyA - phyA phytochrome A - phyB phytochrome B - Pfr far-red absorbing form of phytochrome - Pr red-absorbing form of phytochrome - RW rice wild-type phyA - S/A serine-to-alanine mutant of rice phyA - XAN wild-type tobacco cv. Xanthi We thank N.-H. Chua (Rockefeller Univ., New York, USA) and J. Stockhaus (Heinrich-Heine-Universität, Düsseldorf, Germany) for providing seeds from tobacco lines overexpressing the diverse rice phyA proteins. The work was supported by a grant from the Human Frontier Science Program and a grant from Deutsche Forschungsgemeinschaft (SFB 388). K.E. is a recipient of a Landesgraduierten-förderung fellowship     

Cis-acting elements of the CHS1 gene from white mustard controlling promoter activity and spatial patterns of expression

Chalcone synthase (CHS) catalyses the first regulatory step in the branch pathway of phenylpropanoid biosynthesis specific for synthesis of ubiquitous flavonoid pigments and UV protectants. External stimuli such as stress, light and wounding induce CHS expression that is both tissue-specific and under developmental control. In order to identify cis-acting elements involved in organ and tissue specifity, we fused varying parts of the CHS1 promoter of white mustard (Sinapis alba L.) to the GUS-coding region and analysed the expression of these constructs in stably transformed Arabidopsis plants. Two different stages of development were examined, seedlings as an early stage and flowers as the final stage of development. In seedlings, the full-length promoter showed expression in all organs except the hypocotyl; in flowers expression could be observed in all whorls. Unit 1 of the mustard CHS1 promoter, an element conserved in several CHS genes, which has been recently identified as a light responsive element, is able to mediate a tissue-specific expression pattern similar to that obtained with the full-length promoter in seedlings as well as in flowers. Other elements enhance or repress expression in combination with Unit 1, or mediate defined spatial expression independently of Unit 1. One such element, located between-907 and -655, directs expression similar to that of the full-length promoter in flowers but not in seedlings and differs therefore in function to Unit 1. Our data suggest a dominant regulation of CHS1 expression by Unit 1. Other elements within this promoter might interact with Unit 1 or confer a subset of spatial expression patterns when Unit 1 is deleted.Abbreviations ADH alcohol dehydrogenase - CaMV cauliflower mosaic virus - CHS chalcone synthase - GUS -glucuronidase     

The pea plastocyanin promoter directs cell-specific but not full light-regulated expression in transgenic tobacco plants

A series of 5′ deletions of the pea plastocyanin gene (petE) promoter fused to the β-glucuronidase (GUS) reporter gene has been examined for expression in transgenic tobacco plants. Strong positive and negative cis-elements which modulate quantitative expression of the transgene in the light and the dark have been detected within the petE promoter. Disruption of a negative regulatory element at ?784 bp produced the strongest photosynthesis-gene promoter so far described. Histochemical analysis demonstrated that all petE-GUS constructs directed expression in chloroplast-containing cells, and that a region from ?176 bp to +4 bp from the translation start site was sufficient for such cell-specific expression. The petE-promoter fusions were expressed at high levels in etiolated transgenic tobacco seedlings but there was no marked induction of GUS activity in the light. The endogenous tobacco plastocyanin genes and the complete pea plastocyanin gene in transgenic tobacco plants were also expressed in the dark, but showed a three- to sevenfold increase in the light. This indicates a requirement for sequences 3′ to the promoter for the full light response of the petE gene.     

Harvest-inducibility of the promoter of alfalfa<Emphasis Type="Italic"> S</Emphasis>-adenosyl-<Emphasis Type="SmallCaps">l</Emphasis>-methionine:<Emphasis Type="Italic"> trans</Emphasis>-caffeoyl-CoA3-<Emphasis Type="Italic">O</Emphasis>-methyltransferase gene

A major limitation on the expression of some foreign proteins in transgenic plants is the toxic effect of such proteins on the host plant resulting in inhibition of normal growth and development. A solution to this problem is to control the expression of genes for such proteins by means of inducible promoters, as is frequently done in microbial systems. A cDNA clone was obtained from subtractive hybridization of non-harvested and harvested alfalfa leaf tissue, named hi12. The hi12 cDNA was identified as part of the S-adenosyl-l-methionine: trans-caffeoyl-CoA3-O-methyltransferase gene of alfalfa, a gene encoding an essential key enzyme in lignin synthesis. The hi12 gene was strongly induced by harvesting and wounding but not by heat shock. The promoter of the hi12 gene, isolated by genomic walking, contained several stress response cis-elements. Transgenic plants of tobacco and Medicago truncatula containing the GUS gene driven by the promoter showed GUS expression following harvesting, demonstrating the activity of these regulatory regions in other plant species.     

Expression of ethylene response factor JERF1 in rice improves tolerance to drought

Ethylene response factor (ERF) proteins regulate a variety of stress responses in plant. JERF1, a tomato ERF protein, can be induced by abscisic acid (ABA). Overexpression of JERF1 enhanced the tolerance of transgenic tobacco to high salt concentration, osmotic stress, and low temperature by regulating the expression of stress-responsive genes by binding to DRE/CRT and GCC-box cis-elements. In this research, we further report that overexpression of JERF1 significantly enhanced drought tolerance of transgenic rice. The overexpression activated the expression of stress-responsive genes and increased the synthesis of the osmolyte proline by regulating the expression of OsP5CS, encoding the proline biosynthesis key enzyme deltal-pyrroline-5-carboxylate synthetase. JERF1 also activated the expression of two ABA biosynthesis key enzyme genes, OsABA2 and Os03g0810800, and increased the synthesis of ABA in rice. Analysis of cis-elements of JERF1-targeted genes pointed to the existence of DRE/CRT and/or GCC box in their promoters, indicating that JERF1 could activate the expression of related genes in rice by binding to these cis-elements. Unlike some other ERF proteins, constructive overexpression of JERF1 did not change the growth and development of transgenic rice, which makes JEFR1 a potentially useful source in breeding for greater tolerance to abiotic stress.     

Cis elements and potential trans-acting factors for the developmental regulation of the Phaseolus vulgaris CHS15 promoter

A nuclear factor (SBF-1) has previously been identified in Phaseolus vulgaris L. (bean) suspension cell nuclear extracts that binds in vitro to three DNase I-footprinted elements (SBF-1 boxes I, II, and III, 5 to 3) in the 5 region of the bean CHS15 (chalcone synthase) gene promoter. To define the functional role of the three SBF-1 boxes in development, we examined transgenic tobacco plants carrying a series of nested CHS15 promoter--glucuronidase (GUS) fusions for GUS activity by histochemical staining. We show that the CHS15 promoter deleted to position-173 and lacking all three SBF-1 boxes directs the same qualitative pattern of expression in initiating lateral roots and in developing seeds as the full length promoter (-326). Thus, activation of expression in these organs is mediated by sequence elements located downstream of the three SBF-1 boxes. However, specific deletions within the-326 to-173 region modulate expression. Thus, deletion of box II abolishes GUS activity in initiating lateral roots. Further deletion of box III fails to restore expression but subsequent deletion of an additional 43 bp to position-173 re-establishes expression. We show that sequence-specific DNA-binding activities consistent with these results are present in nuclear extracts of bean roots and seeds. These studies reveal cis elements within the CHS15 promoter, and potential trans factors, that permit organ- and tissue-specific developmental patterns of regulation to be combined with a flexible response to environmental cues.