Analysis And Localization of the Water-Deficit Stress-Induced Gene ( lp3)

LP3 is a water-deficit-induced protein, which is highly homologous to ASR (ABA, stress and ripening) proteins. Homology was found in the C-terminal region of the putative LP3 protein while lower homologies were found in the N-terminal region. The goal of this study was to investigate the function of the LP3 protein and the mechanism of the lp3 promoter in response to water-deficit stress (WDS) and other stresses. In regenerated transgenic tobacco (T₀), expression of -glucuronidase (GUS) from the lp3 promoter-GUS construct was observed in polyethylene glycol (PEG), abscisic acid (ABA), methyl-jasmonate (MeJa), and fluridone (Flu) treatments. GUS expression was not observed following gibberellin (GA₃), 2-methyl-4-dichlorophenoxy acetic acid (2,4-D), silver nitrate, or ethephon (ethylene releasing agent) treatments. Germinated T₁ seedlings containing the lp3 promoter-GUS construct exhibited GUS activity up to 40 days postgermination. Expression could be restored when 5-azacytidine was included in the culture media, indicative of a developmentally regulated silencing mechanism involving methylation. In transgenic tobacco, the LP3 protein localized in the cell nucleus was induced by WDS and appeared to be developmentally regulated. Mailing address of Jau-Tay Wang: 4 Lane 9 Minsheng Rd., Wufeng 413, Taichung, Taiwan. Present address of Jean H. Gould: Department of Forest Science Texas A&M University College Station, Texas 77843-2135, USA; Present address of Veera Padmanabhan: Pioneer HiBred International Inc., 7250 NW 62nd Ave, Johnston, Iowa 50131-0552, USA; Present address of Ronald J. Newton: Department of Biology, East Carolina University, Greenville, North Carolina 27858-4353, USA     

Analysis of an ABA-responsive rice gene promoter in transgenic tobacco

We have analyzed in transgenic tobacco the expression of a chimeric gene containing 5 sequences of the rice rab-16B gene fused to the -glucuronidase (GUS) reporter gene. This construct, a translational fusion (–482 to +184) including 14 amino acids of the RAB-16B protein, is expressed only in zygotic and pollen-derived embryos. In zygotic embryos, GUS activity begins to accumulate 10 days after flowering (daf), and increases until seed maturation at 25 daf. Immunological measurements of endogenous abscisic acid (ABA) accumulation in these seeds showed a close parallel between hormone levels and GUS activity. However, GUS activity could not be reproducibly induced by treatment of immature embryos with ABA (10 M). Neither GUS activity nor GUS mRNA could be detected in leaves of transgenic tobacco even after ABA treatment. In contrast, GUS activity could be induced to high levels in pollen-derived embryos by treatment with ABA. Our results show that 482 bp of 5 sequences of the rice rab-16B promoter can confer in transgenic tobacco developmentally regulated expression in embryos but not ABA-responsive expression in vegetative tissues.     

Tissue-specific and ABA-regulated Maize GIN gene expression in transgenic tobacco

Summary To study the regulatory functions of the ON promoter region, a ppG1b1GUS construct, consisting of 1402 bp 5 flanking sequence ofGlbl, 1919 by GUS coding sequence, and 283 by 3 NOS terminator, was cloned into a binary vector and introduced into tobacco plants byAgrobacterium-mediated transformation. Histochemical GUS assays of T_o tobacco mature seeds indicate that theGlbl promoter drives GUS expression in ABA treated seeds. Further GUS assays of the T, seeds at different developmental stages revealed that without ABA treatment, theGibl promoter drives GUS expression in immature seeds. The results from both T_o and T₁ tobacco plants indicated thatGlbl-driven GUS expression in tobacco is embryo specific.     

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. Received: 24 March 1997 / Accepted: 26 November 1997     

A 796?bp PsPR10 gene promoter fragment increased root-specific expression of the GUS reporter gene under the abiotic stresses and signal molecules in tobacco

A 1681 bp PsPR10 promoter was isolated from Pinus strobus and a series of 5′-deletions were fused to the β-glucuronidase (GUS) reporter gene and introduced into tobacco. GUS activity in P796 (−796 to +69) construct transgenic plant roots was similar with that of P1681 and higher than those of the P513 (−513 to +69) and P323 (−323 to +69) transgenic plants. Moreover, the abiotic stresses of NaCl, PEG 6000 and mannitol, and salicylic acid (SA), abscisic acid (ABA) and jasmonic acid (JA) induced higher GUS activity in the roots of P796 transgenic tobacco. This study provides a potential inducible root-specific promoter for transgenic plants.     

Functional characterization of a cotton late embryogenesis-abundant D113 gene promoter in transgenic tobacco

Previous studies have shown that mRNA and protein encoded by late embryogenesis-abundant (LEA) gene D113 from Gossypium hirsutum L. accumulate at high levels in mature seeds and also in response to abscisic acid (ABA) in young embryo. In this study, we studied the expression of four promoter 5′ deletion constructs (−1383, −974, −578 and −158) of the LEA D113 gene fused to beta-glucuronidase (GUS). GUS activity analysis revealed that the −578 promoter fragment was necessary to direct seed-specific GUS expression in transgenic tobacco plants (Nicotiana tabacum L.). To further investigate the expression pattern of LEA D113 promoter under environmental stresses, 2-week-old transgenic tobacco seedlings were exposed to ABA, dehydration, high salinity and cold treatments. GUS activity in the seedlings was quantified fluorimetrically, and expression was also observed by histochemical staining. An apparent increase in GUS activity was found in plants harboring constructs −1383, −974 and −578 after 24 h of ABA or high-salinity treatments, as well as after 10 days of dehydration. By contrast, only a slight increase was observed in all the three lines after cold treatment. Virtually no change in expression was found in construct −158 in response to dehydration, salinity and cold, but there was a moderate response to ABA, suggesting that the region between −574 and −158 was necessary for dehydration- and salinity-dependent expression, whereas ABA-responsive cis-acting elements might be located in the −158 region of the promoter.     

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.     

Characterization of a histidine- and alanine-rich protein showing interaction with calreticulin in rice

Calreticulin (CRT) is a major calcium-sequestering protein in the endoplasmic reticulum and has been implicated in a variety of cellular functions. To analyze the function of CRT in rice, a yeast two-hybrid protein interaction assay was used for identifying interacting proteins. Fourteen of 17 interacting cDNA clones found coded for a novel histidine- and alanine-rich protein (OsHARP) of 342 amino acid residues. The mRNA expression level of OsHARP was up-regulated in rice seedlings treated with gibberellin (GA), but not ABA and showed a similar pattern as OsCRT mRNA. Rice plants transformed with the OsHARP promoter-GUS construct showed GUS staining in the basal parts of leaf sheaths, and although GUS activity increased when treated with GA₃, it was not as high an increase as when mRNA was analyzed. To elucidate the role of OsHARP in leaf sheath elongation, antisense OsHARP transgenic rice lines were constructed. The antisense OsHARP transgenic rice plants were consistently shorter than the vector control under normal conditions. To examine whether OsHARP expression would affect other proteins, basal leaf sheaths from antisense OsHARP transgenic rice plants were analyzed using proteomic techniques. In antisense transgenic-rice OsHARP plants, OsCRT was down-regulated and the levels of 20 other proteins were changed compared to the pattern of the vector control. These results signify an important role of HARP in rice leaf sheath cell division or elongation and suggest that CRT may interact with HARP during certain stages of development.     

The expression of a potato (Solanum tuberosum) S-RNase gene in Nicotiana tabacum pollen

Self-incompatibility in the Solanaceae is controlled by a single multiallelic genetic locus, the S locus. The stylar gene products of the S locus are abundant glycoproteins with ribonuclease activity, secreted in the transmitting tract tissue of the pistil. To investigate the structural and functional integrity and possible phenotypic effects of expression of the S-gene product in the male gametophyte, N. tabacum plants were transformed with a construct containing the genomic S ₂ -RNase coding sequence from S. tuberosum under the control of the promoter of the pollen-specific LAT52 gene from tomato. The expression pattern of the S ₂ RNase in the male gametophyte at both the protein and RNA level was found to be identical to that already reported for expression of the -glucuronidase (GUS) gene directed by the LAT52 promoter in transgenic tomato and tobacco. The S ₂ -RNase gene fusion led to a tissue-specific and developmentally regulated accumulation of the S ₂ polypeptide in pollen of transgenic tobacco plants. The transgenic protein product was of the same size and charge as the potato stylar product, had ribonuclease activity, and was glycosylated. The transgenic plants, however, did not show any morphological variations in their flower organs, and their fertility was not influenced by the accumulation of the S ₂ -RNase protein in pollen.     

Ectopic expression of a conifer <Emphasis Type="Italic">Abscisic Acid Insensitive3</Emphasis> transcription factor induces high-level synthesis of recombinant human α-<Emphasis Type="SmallCaps">l</Emphasis>-iduronidase in transgenic tobacco leaves

We are examining various plant-based systems to produce enzymes for the treatment of human lysosomal storage disorders. Constitutive expression of the gene encoding the human lysosomal enzyme, alpha-L-iduronidase (IDUA; EC 3.2.1.76) in leaves of transgenic tobacco plants resulted in low-enzyme activity, and the protein appeared to be subject to proteolysis. Toward enhancing production of this recombinant enzyme in vegetative tissues, transgenic tobacco plants were generated to co-express a CaMV35S:Chamaecyparis nootkatensis Abscisic Acid Insensitive3 (CnABI3) gene construct, along with the human gene construct. The latter contained regulatory sequences of the Phaseolus vulgaris arcelin 5-I gene (5'-flanking, signal-peptide-encoding, and 3'-flanking regions). Ectopic synthesis of the CnABI3 protein led to the transactivation of the arcelin promoter and accordingly high activity (e.g., 25,000 pmol/min/mg total soluble protein) and levels of recombinant IDUA mRNA and protein were induced in leaves of transgenic tobacco, particularly in the presence of 150-200 microM S-(+)-ABA. Synthesis of human IDUA containing a carboxy-terminal ER retention (SEKDEL) sequence was also inducible by ABA in leaves co-transformed with the CnABI3 gene. As compared to the natural S-(+)-ABA, two persistent ABA analogues, (+)-8' acetylene ABA and (+)-8'methylene ABA, led to greater levels of beta-glucuronidase (GUS) reporter activities in leaves co-expressing the CnABI3 gene and a vicilin:GUS chimeric gene. In contrast, (+)-8' acetylene ABA and natural ABA appeared to be equally effective in stimulating the CnABI3-induced expression of an arcelin:GUS gene, and of the human IDUA gene, the latter also driven by arcelin-gene-regulatory sequences. Various stress-related treatments, particularly high concentrations of NaCl, had an even greater effect than ABA in promoting accumulation of human IDUA in co-transformed tobacco leaves. This strategy provides the means of enhancing the yields of recombinant proteins in transgenic plant vegetative tissues and potentially in cultured plant cells. The human recombinant protein can be readily induced in the presence of chemicals such as NaCl that can be added to cell cultures or even whole plants without a significant increase in production costs.     

The Expression of a Cytosolic Cyclophilin Promoter from Periwinkle in Transgenic Tobacco Plants

The cloning of a 465 bp fragment from the 5-flanking region of the gene encoding a cytosolic cyclophilin from periwinkle was achieved through inverse polymerase chain reaction. The DNA fragment was fused to a gusA-intron marker then introduced into tobacco by Agrobacterium tumefaciens-mediated transformation. Histochemical analysis of the transgenic shoot cultures demonstrated that the construct was able to drive GUS expression in stomata guard cells, but not in mesophyll cells when shoots were still attached to the callus from which they were initiated. In separated transgenic shoots and in seedlings, GUS was expressed in external and internal phloem and root hairs, respectively. GUS activity in transgenic tobacco seedlings was also investigated by fluorimetric assays. Treatments with NaCl or ABA decreased promoter activity whereas treatment with yeast extracts increased it.     

Tissue-specific activation of the osmotin gene by ABA,C2H4 and NaCl involves the same promoter region

The gene encoding the antifungal protein osmotin is induced by several hormonal and environmental signals. In this study, tissue-specific and inducer-mediated expression of the reporter gene -glucuronidase (uidA) fused to different fragment lengths of the osmotin promoter was evaluated in transgenic tobacco (Nicotiana tabacum). The region of the promoter between –248 to –108 (Fragment A) was found to be essential and sufficient for inducer (abscisic acid (ABA), C₂H₄ and NaCl)-mediated expression of the reporter gene. Expression of the reporter gene was developmentally regulated and increased with maturity of leaves, stem and flowers. Expression also was tissue-specific being most highly expressed in epidermis and vascular parenchyma of the stem. The regulators ABA, C₂H₄ and NaCl exhibited tissue-specific induction of this promoter. The promoter was specifically responsive to C₂H₄ in flowers at virtually all stages of development, but not responsive in these tissues to ABA or NaCl. Conversely, ABA and NaCl were able to induce reporter gene activity using promoter Fragment A in specific tissues of root where C₂H₄ was unable to induce activity. Further dissection of the promoter Fragment A into fragments containing either the conserved GCC element (PR); PR/AT; or G/AT sequences, and subsequent testing of these fragments fused to GUS in transgenic plants was performed. These experiments revealed that the promoter fragment containing PR element alone, although required, was barely able to allow responsiveness to C₂H₄. However, significant C₂H₄-induced activity was obtained with a promoter fragment containing the AT and PR elements together.     

Genetic transformation of peanut (Arachis hypogaea L.) using cotyledonary node as explant and a promoterlessgus::nptII fusion gene based vector

We have generated putative promoter tagged transgenic lines inArachis hypogaea cv JL-24 using cotyledonary node (CN) as an explant and a promoterless gus::nptII bifunctional fusion gene mediated byAgrobacterium transformation. MS medium fortified with 6-benzylaminopurine (BAP) at 4 mg/l in combination with 0.1 mg/l α-napthaleneacetic acid (NAA) was the most effective out of the various BAP and NAA combinations tested in multiple shoot bud formation. Parameters enhancing genetic transformation viz. seedling age,Agrobacterium genetic background and co-cultivation periods were studied by using the binary vector p35SGUSINT. Genetic transformation with CN explants from 6-day-old seedlings co-cultivated withAgrobacterium GV2260 strain for 3 days resulted in high kanamycin resistant shoot induction percentage (45%); approximately 31% transformation frequency was achieved with p35S GUSINT in Β-glucuronidase (GUS) assays. Among thein vivo GUS fusions studied with promoterless gus::nptII construct, GUS-positive sectors occupied 38% of the total transient GUS percentage. We have generated over 141 putative T₀ plants by using the promoterless construct and transferred them to the field. Among these, 82 plants survived well in the green house and 5 plants corresponding to 3.54% showed stable integration of the fusion gene as evidenced by GUS, polymerase chain reaction (PCR) and Southern blot analyses. Twenty-four plants were positive for GUS showing either tissue-specific expression or blue spots in at least one plant part. The progeny of 15 T₀ plants indicated Mendelian inheritance pattern of segregation for single-copy integration. The tissue-specific GUS expression patterns were more or less similar in both T₀ and corresponding T₁ progeny plants. We present the differential patterns of GUS expression identified in the putative promoter-tagged transgenic lines in the present communication.