Molecular and Histochemical Analysis of a T-DNA Tagged Mutant of Arabidopsis Exhibiting Anther — Specific GUS Expression

An Arabidopsis thaliana mutant, exhibiting anther specific GUS expression, identified from a mutant population of Arabidopsis tagged with a promoterless β-glucuronidase (GUS), carries the T-DNA insertions at two distinct loci. We have been able to segregate the two inserts from each other by backcrossing with wild type plants. The insertion responsible for anther specific GUS expression in segregating population has been identified and confirmed to be in the upstream region of a putative peroxidase gene, AT2G24800. Here we report detailed histochemical and molecular characterization of the mutant Anth85, carrying a single insertion of T-DNA in the peroxidase gene. In Anth85, the GUS expression was observed in the anthers and rosette of the young seedlings. The expression of GUS in the anthers was restricted to the tapetum and microspores. The mutant has no developmental defects and the gene appears to be redundant for normal plant growth. Cloning of upstream region and detailed deletion study of upstream region in transgenic plants is likely to lead to the identification of anther specific promoter elements.     

Isolation and Characterization of OsGSTL1 Promoter from Rice

OsGSTL1 gene was isolated from the rice genomic library. Semi-quantitative RT-PCR analysis demonstrated that the expression of the OsGSTL1 in rice was not induced by chlorsulfuron, ethylene, abscisic acid, salicylic acid, and methyl jasmonate. In order to investigate the cis-elements of OsGSTL1 promoter, the promoter regions with different lengths were fused to the β-glucuronidase (GUS) reporter gene. All constructs were transformed into onion epidermal cells or A. thaliana plants to detect the expression patterns. In onion epidermal cells, the 160 bp fragment and longer ones were functional for directing GUS expression. In transgenic A. thaliana, the 2?155 bp upstream region of OsGSTL1 gene directed the GUS expression only in cotyledon after germination, but not in the root of young seedlings. In the later seedling, the 2?155 bp upstream region of OsGSTL1 gene directed GUS expression in roots, stems, and leaves. However, the GUS gene directed by a 1?224 bp upstream fragment is expressed in all the checked tissues. These results suggest that the spatiotemporal expression response elements of OsGSTL1 existed in the 5′-upstream region between −2?155 and −1?224 bp.     

The tissue expression pattern of the AtGRP5 regulatory region is controlled by a combination of positive and negative elements

The AtGRP5 gene from Arabidopsis thaliana encodes a glycine-rich protein which has a major activity in protoderm-derived cells and is expressed in cells that undergo the first anatomical modifications leading to somatic embryo development. It has been previously demonstrated that its minimum promoter is 316 bp long including the 5′UTR and presents three putative TATA-boxes sequences and several regions that are homologous to previous characterized cis-acting elements. In order to better characterize the AtGRP5 expression and to identify the promoter regions involved in its preferential epidermal expression, in situ hybridization and 5′ promoter deletions were employed. In situ hybridization and GUS expression assays indicate that, besides being present during somatic embryogenesis, AtGRP5 is also expressed during the zygotic embryo development. The sequential 5′ deletions indicate that multiple negative and positive regulatory elements are present in the AtGRP5 promoter and operate in order to confer its distinct expression pattern. A 44-bp region was shown to be essential for the epidermal expression of this gene in leaves, stems, flowers and fruits, and is also responsible for high activity of the AtGRP5 promoter in zygotic embryos. An element responsible for the phloem expression was also identified in a 35-bp region.     

Studies on the expression of linalool synthase using a promoter-β-glucuronidase fusion in transgenic Artemisia annua

Artemisinin, an antimalarial endoperoxide sesquiterpene, is synthesized in glandular trichomes of Artemisia annua L. A number of other enzymes of terpene metabolism utilize intermediates of artemisinin biosynthesis, such as isopentenyl and farnesyl diphosphate, and may thereby influence the yield of artemisinin. In order to study the expression of such enzymes, we have cloned the promoter regions of some enzymes and fused them to β-glucuronidase (GUS). In this study, we have investigated the expression of the monoterpene synthase linalool synthase (LIS) using transgenic A. annua carrying the GUS gene under the control of the LIS promoter. The 652 bp promoter region was cloned by the genome walker method. A number of putative cis-acting elements were predicted indicating that the LIS is driven by a complex regulation mechanism. Transgenic plants carrying the promoter-GUS fusion showed specific expression of GUS in T-shaped trichomes (TSTs) but not in glandular secretory trichomes, which is the site for artemisinin biosynthesis. GUS expression was observed at late stage of flower development in styles of florets and in TSTs and guard cells of basal bracts. GUS expression after wounding showed that LIS is involved in plant responsiveness to wounding. Furthermore, the LIS promoter responded to methyl jasmonate (MeJA). These results indicate that the promoter carries a number of cis-acting regulatory elements involved in the tissue-specific expression of LIS and in the response of the plant to wounding and MeJA treatment. Southern blot analysis indicated that the GUS gene was integrated in the A. annua genome as single or multi copies in different transgenic lines. Promoter activity analysis by qPCR showed that both the wild-type and the recombinant promoter are active in the aerial parts of the plant while only the recombinant promoter was active in roots. Due to the expression in TSTs but not in glandular trichomes, it may be concluded that LIS expression will most likely have little or no effect on artemisinin production.     

Isolation and characterization of a Pinus radiata lignin biosynthesis-related O-methyltransferase promoter

A putative promoter fragment of a Pinus radiata gene encoding a multi-functional O-methyltransferase (AEOMT) was isolated from genomic DNA. Sequence analysis revealed a number of putative cis elements, including AC-rich motifs common in promoters of genes related to the phenylpropanoid pathway. The isolated promoter was fused to the GUS reporter gene and its expression profile analyzed in transgenic tobacco and in transient transformation experiments with P. radiata embryogenic and xylogenic tissue. The promoter conferred weak expression in embryogenic tissue but caused strong GUS activity in both ray parenchyma cells and developing tracheary elements of xylem strips. Histochemical analysis in transgenic tobacco plants revealed that the AEOMT promoter induced GUS expression in cell types associated with lignification, such as developing vessels, phloem and wood fibers and xylem parenchyma as well as in non-lignifying phloem parenchyma. The isolated promoter was activated by challenge of the tissue with a fungal pathogen. Our results also indicate that the control of lignin-related gene expression is conserved and can be compared in evolutionarily distant species such as tobacco and pine.     

Sugar-Dependent Expression of the CHS-A Gene for Chalcone Synthase from Petunia in Transgenic Arabidopsis

Transgenic Arabidopsis thaliana plants were constructed by introduction of a fusion of the gene for β-glucuronidase (GUS) to the CHS-A gene, which is one of the two genes for chalcone synthase that are actively expressed in the floral organs of petunia. The expression of the fusion gene CHS-A::GUS was low in transgenic Arabidopsis plantlets, but it was enhanced when plantlets or detached leaves were transferred to a medium that contained 0.3 molar sucrose, glucose, or fructose. No enhancement was observed when plantlets were transferred to a medium that contained 0.3 molar mannitol. Measurements of cellular levels of sugars revealed a tight linkage between the level of expression of the CHS-A::GUS gene and the level of accumulation of exogenously supplied sugars, in particular sucrose. The parallelism between the organ-specific accumulation of sugar and the organ-specific expression of the CHS-A::GUS gene was also observed in petunia and A. thaliana plants grown under normal conditions in soil. The consensus sequences for sugar responses, such as boxes II and III in members of the family of sporamin genes from the sweet potato, were found in the promoter region of the CHS-A gene that was used for fusion to the GUS gene. It is suggested that the expression of the CHS-A gene is regulated by sugars, as is the expression of other sugar-responsive genes, such as the genes for sporamin. A putative common mechanism for the control of expression of “sugar-related” genes, including the CHS-A gene, is discussed.     

Molecular characterization of the PpMADS1 gene from peach

PpMADS1, a member of the euAP1 clade of the class A genes, was previously cloned from peach. In this study, PpMADS1 was constitutively expressed in Arabidopsis thaliana to study its function in plant development. The transgenic A. thaliana plants containing 35S::PpMADS1 showed severe phenotype variation including early flowering, conversion of inflorescence branches to solitary flowers, formation of terminal flowers, production of higher number of carpels, petals, and stamens than non-transgenic plants, and prevention of pod shatter. Significantly, the transgenic plants produced more than one silique from a single flower. The results obtained by using cDNA microarray and real-time PCR analyses in the transgenic Arabidopsis indicated that PpMADS1 might play dual roles in regulating the floral meristem development by activating or repressing different sets of genes that would determine the different fate of a floral meristem. In addition, the PpMADS1 gene promoter was further cloned, and deletion analyses were conducted by using fused GUS as a reporter gene in transgenic A. thaliana. Histochemical staining of different organs from transgenic plants revealed the region between ?197 and ?454?bp was specific for GUS expression in flower primordium, and the region between ?454 and ?678?bp was specific for GUS expression in sepals and petals. In contrast, a negative regulatory element present between ?678 and ?978?bp could suppress GUS expression in filament.     

Characterization of the GLP13 gene promoter in Arabidopsis thaliana

In transgenic plants, for many applications it is important that the inserted genes are expressed in a tissue-specific manner. This in turn could help better understanding their roles in plant development. Germin-like proteins (GLPs) play diverse roles in plant development and defense responses. In order to understand the functions and regulation of the GLP13 gene, its promoter (762 bp) was cloned and fused with a β-glucuronidase (GUS) reporter gene for transient expression in Arabidopsis thaliana and tobacco (Nicotiana tabacum cv. K326). Histochemical analysis of the transgenic plants showed that GUS was specifically expressed in vascular bundles predominantly in phloem tissue of all organs in Arabidopsis. Further analyses in transgenic tobacco also identified similar GUS expression in the vascular bundles.     

Functional analysis of a cryptic promoter from <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis> reveals bidirectionality

Cryptic promoter elements play a significant role in evolution of plant gene expression patterns and are prospective tools for creating gene expression systems in plants. In a previous report, a 452 bp promoter fragment designated as cryptic root-specific promoter (AY601849) was identified immediately upstream to T-DNA insertion, in the intergenic region between divergent genes SAHH1 and SHMT4, in T-DNA tagged mutant M57 of Arabidopsis thaliana. In silico analysis of 452 bp promoter revealed typical eukaryotic promoter architecture, presence of root-specific motifs and other cis-regulatory motifs responsible for the spatial and temporal expression. GUS expression driven by 452 bp in M57 was developmentally as well as light-regulated. The AT-rich 452 bp promoter does not show homology to any known sequences. The 452 bp promoter was further proved cryptic and detailed molecular characterization of the promoter carried out through serial 5′ and 3′ deletion analysis, by cloning the promoter fragments upstream to promoter-less GUS vector. A 279 bp fragment obtained by deleting 173 bp from 5′ end of 452 bp was capable of driving root-specific expression, similar to that of full-length promoter. Further, root tip-specific, root-specific and core-regulatory motifs for root-specific expression were identified at positions 173–227, 251–323 and 408–452 bp, respectively, from the 5′ end of 452 bp. The 452 bp promoter was equally functional in inverse orientation, hence bidirectional and symmetric. In heterologous systems, such as Brassica juncea and Oryza sativa, the promoter activity was not significant since GUS was not visually detected in transient assays.     

The sucrose synthase-1 promoter from Citrus sinensis directs expression of the β-glucuronidase reporter gene in phloem tissue and in response to wounding in transgenic plants

Interest in phloem-specific promoters for the engineering of transgenic plants has been increasing in recent years. In this study we isolated two similar, but distinct, alleles of the Citrus sinensis sucrose synthase-1 promoter (CsSUS1p) and inserted them upstream of the β-glucuronidase (GUS) gene to test their ability to drive expression in the phloem of transgenic Arabidopsis thaliana and Nicotiana tabacum. Although both promoter variants were capable of conferring localized GUS expression in the phloem, the CsSUS1p-2 allele also generated a significant level of expression in non-target tissues. Unexpectedly, GUS expression was also instigated in a minority of CsSUS1p::GUS lines in response to wounding in the leaves of transgenic Arabidopsis. Deletion analysis of the CsSUS1p suggested that a fragment comprising nucleotides −410 to −268 relative to the translational start site contained elements required for phloem-specific expression while nucleotides −268 to −103 contained elements necessary for wound-specific expression. Interestingly, the main difference between the two CsSUS1p alleles was the presence of a 94-bp insertion in allele 2. Fusion of this indel to a minimal promoter and GUS reporter gene indicated that it contained stamen and carpel-specific enhancer elements. This finding of highly specific and separable regulatory units within the CsSUS1p suggests that this promoter may have a potential application in the generation of constructs for the use in the development of transgenic plants resistant to a wide variety of target pests.     

A Phosphate Transporter Promoter from Arabidopsis thaliana AtPHT1;4 Gene Drives Preferential Gene Expression in Transgenic Maize Roots Under Phosphorus Starvation

Phosphorus (P) stress responsive genes have been identified and characterized, including the high-affinity phosphate transporter AtPHT1;4 from Arabidopsis thaliana. This gene encodes a membrane protein that is primarily expressed in roots under phosphorus deficiency. A 2.3-kb promoter region from AtPHT1;4 has been fused with the β-glucuronidase (GUS) encoding gene and introduced into maize via biolistic bombardment to evaluate its spatiotemporal activity in a heterologous system. AtPHT1;4::GUS expression is detected preferentially in transgenic maize roots under P deficiency. Further analysis of transgenic plants has also revealed that GUS activity is higher in roots than in leaves by about sixfold. These results demonstrate the ability of AtPHT1;4 promoter to direct expression of the reporter gene in a monocot root system under P stress. This property of AtPHT1;4 promoter makes it useful to engineer maize plants to modify the soil’s rhizosphere and increase efficiency of P acquisition under P stress conditions.     

Regulation of promoter activity of ferredoxin-dependent glutamate synthase

The GLU1 promoter for Fd-glutamate synthase (Fd-GOGAT, EC 1.4.1.7) of Arabidopsis thaliana (ecotype Columbia) confers the expression of the β-glucuronidase (GUS) reporter gene on transgenic tobacco (Nicotiana tabacum L. cv. Xanthi) transformed with the GLU1 promoter-GUS construct. Histochemical analysis reveals that GUS expression is associated with mesophyll and vascular tissue of 14-d-old tobacco seedlings. Red light substitutes for white light and induces a 2-fold increase in the GUS expression associated with mesophyll, veins and vascular tissue. Sucrose also serves as a signal to induce GUS expression in mesophyll and veins of cotyledons. Mature leaves, adapted to the dark for 3 d, conserves the red light- and white light-dependent inductions of GUS activity, while GUS expression is repressed by white light in roots. The mesophyll-located expression of the GLU1 promoter suggests that Fd-glutamate synthase has a function in the photorespiratory ammonium cycling and primary ammonium assimilation. The distinct location of GLU1 promoter expression in the vascular tissue supports the view that Fd-glutamate synthase synthesises glutamate for intracellular transport of glutamine and glutamate.     

Exogenous brassinosteroids activate cytokinin signalling pathway gene expression in transgenic Arabidopsis thaliana

Transgenic Arabidopsis thaliana plants carrying the GUS reporter gene fused to the promoter of the gene of primary response to cytokinins (CKs), ARR5, were used to estimate the influence of several brassinosteroids (BRs): brassinolide (BL), epibrassinolide (EBL), homobrassinolide (HBL), and 6-o-carboxymethyloxohomocastasterone (CHC) on the expression of CK signalling genes. BRs tested differed in their ability to activate the ARR5 gene promoter in 4-day-old seedlings and 3-week-old plants. BL caused the most prominent effect, yet it was considerably less than that of 6-benzylaminopurine (BA). An increase in GUS activity was observed in both dark and light conditions; however, the rate of elevation was higher in dark conditions. The activation of the P _ARR5 :GUS fusion was accompanied by a moderate induction of the P _AHK :GUS constructs, in which the reporter GUS gene was fused to the promoter of one of the CK receptor histidine kinases. The effects of BL on the AHK gene promoters were organ specific and correlated with the ability of a particular AHK gene to respond to BA treatment. BL activated the AHK3 promoter in 4-day-old seedlings and in shoots and roots of 3-week-old plants without any effect in detached leaves. The AHK2 gene promoter was activated by BA and BL only in seedlings, whereas the AHK4 gene promoter was activated only in roots. BL treatment caused the coordinate elevation of the CK levels in leaves to the same degree as the activation of the P _AHK :GUS construct, suggesting that the accumulation of CKs was the reason for the activation by BRs of the CK signalling genes. The data obtained provide the evidence for the involvement of BRs in the regulation of the genes of the CK signalling pathway through an increase in the CK levels. However, the exact molecular mechanisms underlying BR-induced elevation of the CK content are unclear and warrant identification in the future.