The promoter of the geneItr1 from barley confers a different tissue specificity in transgenic tobacco

Tissue-specific expression of the gene coding for trypsin inhibitor BTI-CMe in barley (Itr1) occurs during the first half of endosperm development. In transgenic tobacco, theItr1 promoter drives expression of the β-glucuronidase reporter gene not only in developing endosperm but also in embryo, cotyledons and the meristematic intercotyledonary zone of germinating seedlings. A promoter fragment extending 343 bp upstream of the translation initiation ATG codon was sufficient for full transgene expression, whereas, the proximal 83 bp segment of the promoter was inactive. Possible reasons for the differences in expression patterns are discussed.     

Expression and Processing of an Arabidopsis 2S Albumin in Transgenic Tobacco

2S albumin seed storage proteins undergo a complex series of posttranslational proteolytic cleavages. In order to determine if this process is correctly carried out in transgenic plants, the gene AT2S1 encoding an Arabidopsis thaliana 2S albumin isoform has been expressed in transgenic tobacco. Initial experiments using a reporter gene demonstrated that the AT2S1 promoter directs seed specific expression in both transgenic tobacco and Brassica napus plants. The entire AT2S1 gene was then transferred into tobacco plants, where it showed a tissue specific and developmentally regulated expression. Arabidopsis 2S albumin accumulates up to 0.1% of the total high-salt extractable seed protein. Protein sequencing demonstrated that the amino termini of the two Arabidopsis 2S albumin subunits were correctly processed, suggesting that the protease(s) necessary for posttranslational processing of 2S albumin precursors may display common specificities among different dicot plant species. Immunocytochemical studies showed that the Arabidopsis 2S albumin is localized in the protein body matrix of tobacco endosperm and embryo. Correct processing and targeting of the 2S albumin in transgenic plants suggests that modified versions could be expressed, allowing the study of 2S albumin processing and in particular the possible roles of the processed fragments in protein stability and/or targeting.     

Characterization of <Emphasis Type="Italic">VvPAL-like</Emphasis> promoter from grapevine using transgenic tobacco plants

A 2000-bp 5′-flanking region of VvPAL-like was isolated from ‘Summer Black’ grapevine by PCR amplification, named pVvPAL-like. To gain a better understanding of the expression and regulatory mechanism of VvPAL-like, a chimeric expression unit consisting of the β-glucuronidase (GUS) reporter gene under the control of a 2000-bp fragment of the VvPAL-like promoter was transformed into tobacco via Agrobacterium tumefaciens. Histochemical staining showed that the full-length promoter directs efficient expression of the reporter gene in cotyledons and hypocotyls, stigma, style, anthers, pollen, ovary, trichomes, and vascular bundles of transgenic plants. A series of 5′ progressive deletions of the promoter revealed the presence of a negative regulatory region (?424 to ?292) in the VvPAL-like promoter. Exposure of the transgenic tobacco plants to various abiotic stresses demonstrated that the full-length construct could be induced by light, copper (Cu), abscisic acid (ABA), indole-3-acetic (IAA), methyl jasmonate (MeJA) (N-1-naphthylphthalamic acid), ethylene, and drought. Furthermore, the ethylene-responsive region was found to be located in the ?1461/?930 fragment, while the element(s) for the MeJA-responsive expression may be present in the ?424/?292 region in the VvPAL-like promoter. These findings will help us to better understand the molecular mechanisms by which VvPAL-like participates in biosynthesis of flavonoids and stress responses.     

The promoter of the gene Itr1 from barley confers a different tissue specificity in transgenic tobacco

Tissue-specific expression of the gene coding for trypsin inhibitor BTI-CMe in barley (Itr1) occurs during the first half of endosperm development. In transgenic tobacco, theItr1 promoter drives expression of the β-glucuronidase reporter gene not only in developing endosperm but also in embryo, cotyledons and the meristematic intercotyledonary zone of germinating seedlings. A promoter fragment extending 343 bp upstream of the translation initiation ATG codon was sufficient for full transgene expression, whereas, the proximal 83 bp segment of the promoter was inactive. Possible reasons for the differences in expression patterns are discussed. These authors have contributed equally to this work     

A transposable element insertion within ZmGE2 gene is associated with increase in embryo to endosperm ratio in maize

Most of the maize kernel oil is located in the embryo while the majority of starch is located in the endosperm. Maize kernel composition and value are affected significantly by the ratio of the embryo size to the endosperm size; however, the genetic regulation of embryo to endosperm ratio (EER) in maize is unknown. Here we identified ZmGE2 gene, which encodes a cytochrome p450 protein, as a gene associated with EER variation in maize. We first expressed rice Giant Embryo (GE) gene driven by oleosin promoter in maize and detected a 23.2?% reduction in EER in transgenic seeds, demonstrating the existence of evolutionarily conserved mechanisms for EER determination in rice and maize. We next identified maize GE2, a homolog of rice GE sharing 70?% identity in amino sequence, as a candidate based on the similar expression pattern and co-localization with a previously detected QTL for EER. Followed by linkage and association mapping, a 247-bp transposable element (TE) insertion in 3′-untranslated region of ZmGE2 gene was identified to be associated with increase in EER and kernel oil content. Expression level of the favorable ZmGE2 allele containing the 247-bp TE insertion was strongly reduced. In addition, the 247-bp TE insertion site was a selection target during the artificial long-term selection for the high EER trait in a high oil population. This is the first report that demonstrates an association of ZmGE2 with EER variation in maize and identifies ZmGE2 gene as a promising target for manipulation of EER and grain composition by either transgenic approach or molecular breeding in maize.     

Jasmonate response of the Nicotiana tabacum agglutinin promoter in Arabidopsis thaliana

NICTABA is a carbohydrate-binding protein (also called lectin) that is expressed in several Nicotiana species after treatment with jasmonates and insect herbivory. Analyses with tobacco lines overexpressing the NICTABA gene as well as lines with reduced lectin expression have shown the entomotoxic effect of NICTABA against Lepidopteran larvae, suggesting a role of the lectin in plant defense. Until now, little is known with respect to the upstream regulatory mechanisms that are controlling the expression of inducible plant lectins. Using Arabidopsis thaliana plants stably expressing a promoter-β-glucuronidase (GUS) fusion construct, it was shown that jasmonate treatment influenced the NICTABA promoter activity. A strong GUS staining pattern was detected in very young tissues (the apical and root meristems, the cotyledons and the first true leaves), but the promoter activity decreased when plants were getting older. NICTABA was also expressed at low concentrations in tobacco roots and expression levels increased after cold treatment. The data presented confirm a jasmonate-dependent response of the promoter sequence of the tobacco lectin gene in Arabidopsis. These new jasmonate-responsive tobacco promoter sequences can be used as new tools in the study of jasmonate signalling related to plant development and defense.     

Analysis of a maize α-tubulin gene promoter by transient expression and in transgenic tobacco plants

The pattern of expression directed by the promoter of the maize Tub α 1 gene was investigated by analysis of chloramphenicol acetyl transferase (CAT) and β-glucuronidase (GUS) activities in transient expression experiments of maize and tobacco protoplasts. The same promoter was also investigated by histochemical GUS analysis in transgenic tobacco plants containing promoter gene fusions. As determined by histochemical tests, the Tub α 1 promoter gene preferentially directs GUS expression in regenerating root tip meristems and pollen. This pattern corresponds to the distinctive features of natural expression of the gene in maize as determined by Northern analysis. However, no expression is observed in other meristematic tissues of the transgenic tobacco plants, as in shoot apex or in coleoptiles, which is weakly detected in maize. Analysis of the regulatory properties of 5' promoter deletions showed that the proximal region of the promoter, from positions −1410 or −449 to 15 bp upstream of the ATG, is sufficient to establish the qualitative pattern of expression in transgenic tobacco plants. Deletions to positions −352 or −117 abolished the expression in roots, but not in pollen, suggesting that upstream of these positions there are elements responsible for the pattern in root. Further deletions abolished all the promoter activity, suggesting that this promoter region contains the elements essential for expression in pollen. The different patterns and levels of transient and stable expression are discussed.     

Combination of viral promoter sequences to generate highly active promoters for heterologous therapeutic protein over-expression in plants

To develop strong promoters for protein over-expression in both dicots and monocots, we constructed a new family of chimeric promoters using sequences of the Commelina Yellow Mosaic Virus (CoYMV), of the Cassava Vein Mosaic Virus (CsVMV) and activating sequences from the CaMV 35S promoter. The chimeric promoters were cloned upstream from the gusA reporter gene. The constructs were used in transient expression experiments, via DNA-coated gold particle delivery to tobacco leaves and maize endosperms. The results showed that candidates among the chimeric promoters could drive expression of the reporter gene to very high levels in the dicot plant tobacco, and all chimeric promoters showed higher expression in maize endosperm than the maize γ-zein promoter used as reference for the monocot expression. Expression cassettes were then used in stable tobacco transformation. Determination of GUS activity throughout growth of the primary transformants showed that two promoters (MPr1163 and MPr1165) could drive expression three to five-fold higher than the highly efficient enhanced 35S promoter. The use of MPr1163 was additionally validated for successful heterologous protein production of human lactoferrin in tobacco via agroinfiltration.     

Isolation and characterization of <Emphasis Type="Italic">Brittle2</Emphasis> promoter from <Emphasis Type="Italic">Zea Mays</Emphasis> and its comparison with <Emphasis Type="Italic">Ze19</Emphasis> promoter in transgenic tobacco plants

ADP-glucose pyrophosphorylase (AGPase) represents a key regulatory step in starch synthesis. A 0.9 kb of 5′ flanking region preceding Brittle2 gene, encoding the small subunit of maize endosperm AGPase, was cloned from maize genome and its expression pattern was studied via the expression of β-glucuronidase (GUS) gene in transgenic tobacco. Analysis of GUS activities showed that the 0.9 kb fragment flanking Brittle2 gene was sufficient for driving the seed-preferred expression of the reporter gene. The activity of the 0.9 kb 5′ flanking fragment was compared with that of the tandem promoter region from a zein gene (zE19, encoding a maize 19 kDa zein protein). The results indicated that both promoters were seed-preferred in a dicotyledonous system as tobacco and the activity of zE19 promoter was three to fourfold higher than that of the 0.9 kb fragment flanking Brittle2 gene in transgenic tobacco seeds. At the same time, zE19-driven GUS gene expressed earlier than Brittle2 promoter during seed development. Histochemical location of GUS activity indicated that both promoters showed high expression in embryos, which is different from similar promoters tested in maize.     

Locus- and Site-Specific DNA Methylation of 19 kDa Zein Genes in Maize

An interesting question in maize development is why only a single zein gene is highly expressed in each of the 19-kDa zein gene clusters (A and B types), z1A2-1 and z1B4, in the immature endosperm. For instance, epigenetic marks could provide a structural difference. Therefore, we investigated the DNA methylation of the arrays of gene copies in both promoter and gene body regions of leaf (non-expressing tissue as a control), normal endosperm, and cultured endosperm. Although we could show that expressed genes have much lower methylation levels in promoter regions than silent ones in both leaf and normal endosperm, there was surprisingly also a difference in the pattern of the z1A and z1B gene clusters. The expression of z1B gene is suppressed by increased DNA methylation and activated with reduced DNA methylation, whereas z1A gene expression is not. DNA methylation in gene coding regions is higher in leaf than in endosperm, whereas no significant difference is observed in gene bodies between expressed and non-expressed gene copies. A median CHG methylation (25–30%) appears to be optimal for gene expression. Moreover, tissue-cultured endosperm can reset the DNA methylation pattern and tissue-specific gene expression. These results reveal that DNA methylation changes of the 19-kDa zein genes is subject to plant development and tissue culture treatment, but varies in different chromosomal locations, indicating that DNA methylation changes do not apply to gene expression in a uniform fashion. Because tissue culture is used to produce transgenic plants, these studies provide new insights into variation of gene expression of integrated sequences.     

Characterization of a Novel Pollen-Specific Promoter from Wheat (Triticum Aestivum L.)

PSG076 is a pollen-specific gene isolated from wheat. The 1.4-kb promoter upstream of the ATG start codon was isolated by inverse-PCR (IPCR). To determine its activity, the PSG076 promoter was fused with the ??-glucuronidase (GUS) reporter gene and introduced into tobacco. Histochemical analysis in transgenic tobacco showed that GUS activity was detected in late bicellular pollen grains and increased rapidly in mature pollen. GUS activity was also detected in pollen tubes of transgenic tobacco. No GUS activity was found in other floral and vegetable tissues. These results indicate that the PSG076 promoter directs pollen-specific activity at late stages of pollen development and pollen tube growth. Deletion analysis showed that a 0.4?kb fragment of the promoter was enough to confer pollen-specific expression.