Effect of ectopic expression of NtEXPA5 gene on cell size and growth of organs of transgenic tobacco plants

We obtained transgenic tobacco plants demonstrating overexpression of NtEXPA5 gene that encodes α-expansin of Nicotiana tabacum. The transgenic plants were characterized by increased size of leaves and stems. However, size of flowers remained almost unchanged. The increase of organ sizes was induced by cell elongation only. Moreover, the number of cell divisions was even decreased. The obtained data suggest tight interaction between cell stretching regulation and cell division, which together provide the basic mechanism aimed at the controlling of plant organ sizes.     

The creation of transgenic tobacco plants expressing fragments of the ARGOS and NtEXPA4 genes in antisense orientation

Transgenic tobacco plants expressing the fragments of the ARGOS and NtEXPA4 genes in antisense orientation have been created. Eleven lines of transgenic plants were investigated and five of them were characterized by a decrease in the sizes of the leaves and flowers as compared to control. Stem sizes decreased when only the NtEXPA4 gene fragment was used. The organ size of the experimental plants decreased because of a reduction in the level of both cell division and cell expansion. Two lines of transgenic tobacco plants expressing the part of the ARGOS gene in antisense orientation were characterized by a reduction in the level of the NtEXPA1 and NtEXPA4 gene expression.     

The poplar ARGOS-LIKE gene promotes leaf initiation and cell expansion,and controls organ size

We identified a Populus nigra auxin-regulated gene involved in organ size (PnARGOS)-LIKE, encoding one organ size related protein in black poplar. It is homologous to AtARGOS and AtARGOS-LIKE genes of Arabidopsis thaliana. ABRE-like, G-box, GATA and I-box motifs were discovered in the promoter region of the poplar ARGOS-LIKE gene. In wild type aspen (Populus tremula) plants, an ortholog of the PnARGOS-LIKE gene (PtrARGOS-LIKE) was noticeably expressed in actively dividing and expanding young leaves and calli, whereas its mRNA content increased in response to exogenous 6-benzylaminopurine, 1-naphthaleneacetic acid, and 24-epibrassinolide. Expression of the PtrARGOS-LIKE gene was reduced under a salinity treatment. In addition, we generated transgenic tobacco and aspen plants with an up-regulated expression of the PnARGOS-LIKE gene. A constitutive expression of the gene contributed to an increase in size of stems and leaves of the transgenic tobacco plants. In the transgenic aspen, a constitutive expression of the PnARGOS-LIKE gene promoted an increase in the frequency of leaf initiations and in leaf length and area. The size of transgenic tobacco and aspen leaves increased due to the enlargement of individual cells. The results show the significance of the PnARGOS-LIKE gene for control of leaf initiation and organ growth by cell expansion in poplar.     

Morphological and physiological characteristics of transgenic tobacco plants expressing expansin genes: <Emphasis Type="Italic">AtEXP10</Emphasis> from <Emphasis Type="Italic">Arabidopsis</Emphasis> and <Emphasis Type="Italic">PnEXPA1</Emphasis> from poplar

Expansins are non-enzymatic plant proteins breaking hydrogen bonds between cellulose microfibrils and hemicellulose polymer matrix. Each plant has many expansin genes, whose protein products participate in the regulation of plant growth and development mainly by regulating cell expansion. To analyze the effects of elevated expansin expression on the plant organ sizes, we cloned the AtEXPA10 gene from Arabidopsis thaliana and PnEXPA1 gene from Populus nigra. Transgenic tobacco plants expressing the target genes were obtained. The obtained transgenic tobacco plants were shown to have significantly larger leaves and longer stems compared to control plants. The flowers were quite insignificantly larger, but at the same time transgenic plants had more flowers. The microscopic studies showed that the organs of AtEXPA10-carrying plants were larger mainly due to stimulated cell proliferation, whereas the overexpression of the PnEXPA1 gene activated cell expansion.     

Morphological analysis of transgenic tobacco plants expressing the PnEXPA3 gene of black poplar (Populus nigra)

Transgenic tobacco plants overexpressing the PnEXPA3 gene of black poplar (Populus nigra), which encodes α-expansin, were obtained. The transgenic plants were characterized by increased size of epidermic and mesophyll cells of leaves. However, the size of leaves remained normal. Overexpression of the PnEXPA3 gene provided stimulatory effect only on the stem length. Other morphological traits of the transgenic plants remained unchanged.     

Constitutive expression of the <Emphasis Type="Italic">ARGOS</Emphasis> gene driven by dahlia mosaic virus promoter in tobacco plants

The auxin-inducible gene ARGOS from Arabidopsis thaliana is expressed in growing tissues and controls the plant organ size by regulating cell proliferation and meristematic competence. The promoter of the dahlia (Dahlia pinnata Cav.) mosaic virus (DMV) resembles the well-known cauliflower mosaic virus 35S promoter but shows a higher activity in transgenic tobacco plants (Nicotiana tabacum L.). We obtained transgenic tobacco plants expressing the Arabidopsis ARGOS gene under the control of the DMV promoter. Several of the T0 generation plants exhibited an accelerated transition to flowering, a slight increase in flower size, and a significant increase in the leaf size. The T1 transgenic plants were characterized by faster growth, the increased leaf size, and somewhat enlarged flowers as compared with control plants. These phenotypic traits, as well as stability and inheritance of the transgene were demonstrated also in T2 transgenic plants.     

Morphological features of the transgenic tobacco plant shoot expressing the 3-hydroxy-3-methylglutagyl-CoA reductase (<Emphasis Type="Italic">HMG1</Emphasis>) gene in the direct and reverse orientations towards the promoter

3-Hydroxy-3-methylglutaryl-CoA reductase (HMG1) catalyzes the formation of mevalonic acid, the key intermediate of the cytosolic isoprenoid synthesis pathway. The parameters of stem and leaf growth were studied in the transgenic tobacco plants that express the HMG1 gene in both sense and antisense orientations towards the constitutive promoter. The transgenic plant height did not significantly differ from that of the control plants, though the plants carrying the sense copy of the HMG1 gene were considerably taller than plants that carried the antisense gene copy. Plants carrying an extra copy of the HMG1 gene were also characterized by increased leaf area. The number of mesophyll cells calculated per square unit of transgenic plants leaves was smaller than in the control plant leaves, though their volume was not considerably changed in any of the variants, suggesting changes in the cell packing density in leaves.     

Growth enhancement of transgenic poplar plants by overexpression of Arabidopsis thaliana endo-1,4–β-glucanase (cel1)

Poplar (Populus tremula) plants which had been transformed with Arabidopsis thaliana cel1 cDNA and successfully over-expressed the gene, exhibited significant phenotypic alterations which included taller plants, larger leaves, increased stem diameter, wood volume index, dry weight and a higher percentage of cellulose and hemicellulose, compared to the wild-type plants. Transgenic A. thaliana plants over-expressing A. thaliana cel1 exhibited similar levels of cel1 mRNA in the elongation zone of the flowering stem and higher levels in mature leaves when compared with wild-type plants. CEL1 protein levels in the elongation zone of the flowering stem of transgenic plants were similar or slightly higher compared to that of the wild-type plants, whereas mature leaves of transgenic plants contained a higher level of CEL1. These data indicate that in elongating zone of Arabidopsis, CEL1 level is tightly regulated. In contrast to transgenic poplar over-expressing the A. thaliana cel1, no phenotypic difference was found between A. thaliana transgenic and wild-type plants.     

Dwarfism in Brassica napus L. induced by the over-expression of a gibberellin 2-oxidase gene from Arabidopsis thaliana

Gibberellins (GAs) are endogenous hormones that play an important role in regulating plant stature by increasing cell division and elongation in stem internodes. The GA2-oxidase gene from Arabidopsis thaliana (AtGA2ox8) was introduced into Brassica napus L. by Agrobacterium-mediated floral-dip transformation with the aim of decreasing the amount of bioactive GA and hence reducing plant stature. As anticipated, the transgenic plants exhibited dwarf phenotype. Compared with the wild type, the transgenic plants had increased primary branches (by 14.1?C15.3%) and siliques (by 10.8?C15.2%), which resulted in a significant increase in the seed yield (by 9.6?C12.4%). Moreover, the contents of anthocyanin in leaves of 60-day-old transgenic plants was about 9.4-fold higher in winter and about 6.8-fold higher in summer than the wild type. These excellent agronomic traits of the transgenic plants could not only improve the lodging resistance and seed yields, but also protect them against stress. Therefore, the over-expression of AtGA2ox8 might be used to produce dwarf varieties and increase seed yield in Brassica napus L.     

Antisense-overexpression of the MsCOMT gene induces changes in lignin and total phenol contents in transgenic tobacco plants

Initially, we isolated the caffeic acid O-methyltransferase (COMT) gene from Miscanthus sinensis (accession number HM062766.1). Next, we produced transgenic tobacco plants with down-regulated COMT gene expression to study its control of total phenol and lignin content and to perform morphological analysis. These transgenic plants were found to have reduced PAL and ascorbate peroxidases expression, which are related to the phenylpropanoid pathway and antioxidant activity. The MsCOMT-down-regulated plants had decreased total lignin in the leaves and stem compared with control plants. Reduced flavonol concentrations were confirmed in MsCOMT-down-regulated transgenic plants. We also observed a morphological difference, with reduced plant cell number in transgenic plants harboring antisense MsCOMT. The transgenic tobacco plants with down-regulated COMT gene expression demonstrate that COMT plays a crucial role related to controlling lignin and phenol content in plants. Also, COMT activity may be related to flavonoid production in the plant lignin pathway.     

Expression of a tuber-specific storage protein in transgenic tobacco plants: demonstration of an esterase activity

A chimaeric gene composed of the 5' upstream region of STLS1, a leaf/stem specifically expressed gene from Solanum tuberosum, and the RNA-coding as well as the 3' downstream region of patatin, the major storage protein of potato tubers, has been transferred into tobacco plants using the Agrobacterium system. The introduction of this gene led to a leaf/stem specific expression of a 42-kd large protein which immunocrossreacts with patatin antiserum. Only low amounts of immunoreacting protein of smaller size could be detected in transgenic tobacco leaves indicating that the patatin protein is fairly stable in this heterologous environment. The size of the protein as well as the size of the RNA detected in transgenic tobacco leaves using a patatin-specific probe indicates that the patatin RNA was accurately processed in both leaf and stem tissue of tobacco. The expression of the patatin gene led to the appearance of a new esterase activity in the transformed tobacco which co-migrated with a protein immunoreacting with patatin antiserum. These data therefore demonstrate that patatin in addition to serving as a storage protein displays an enzymatic activity.     

过表达或沉默棉花GhPCBER基因株系的获得及其茎叶木质素和木脂素含量研究

编码苯基香豆满苄基醚还原酶(phenylcoumaran benzylic ether reductase,PCBER)的基因PCBER属于PIP亚家族,是苯丙烷代谢途径中参与木脂素合成的关键基因。该研究构建了棉花GhPCBER基因的植物过表达载体并转化拟南芥,同时构建了VIGS(virus induced gene silencing,病毒诱导的基因沉默)载体转化棉花,采用实时荧光定量PCR技术对GhPCBER基因在不同组织中的表达进行分析;对野生型和转基因植株茎叶组织中的木质素和木脂素含量进行测定分析。结果表明:(1)成功构建了GhPCBER植物过表达载体pGWB17-GhPCBRE以及基因沉默重组载体pTRV2-GhPCBER;经遗传转化获得6株转棉花GhPCBER基因抗性拟南芥植株,同时获得15株GhPCBER基因沉默棉花植株(5株为一组)。(2)PCR检测表明,6株转基因拟南芥均为过表达株系,其中株系1、2、3相对表达量更高,且在茎、叶组织中的表达量分别较野生型提高了7～14倍和6～16倍,表明GhPCBER基因成功在拟南芥中过表达;GhPCBER基因沉默棉花植株的茎、叶组织中的表达量分别比野生型棉株约下降12%和26%,表明烟草脆裂病毒(TRV)体系(pTRV2-GhPCBER)成功抑制了GhPCBER基因的表达。(3)转GhPCBER基因拟南芥茎、叶中木质素和木脂素含量较野生型均显著降低;GhPCBER基因沉默棉花植株茎、叶中木质素和木脂素含量较野生型均极显著降低;组织化学染色观察发现GhPCBER基因沉默棉花植株茎秆颜色明显比野生型染色浅,也证明沉默基因棉花植株茎秆中的木质素含量减少。(4)苯丙烷代谢通路中8个相关基因的实时荧光定量PCR分析发现,过表达或抑制GhPCBRE基因均会导致苯丙烷代谢途径发生重新定向。     

The CCoAOMT1 gene from jute (Corchorus capsularis L.) is involved in lignin biosynthesis in Arabidopsis thaliana

The Caffeoyl-CoA 3-O-methyltransferase (CCoAOMT) is a key enzyme in lignin biosynthesis in plants. In this study we cloned the full-length cDNA of the Caffeoyl-CoA 3-O-methyltransferase (CCoAOMT) gene from jute using homology clone (primers were designed according to the sequence of CCoAOMT gene of other plants), and a modified RACE technique, subsequently named “CcCCoAOMT1”. Bioinformatic analyses showed that the gene is a member of the CCoAOMT gene family. Real-time PCR analysis revealed that the CcCCoAOMT1 gene is constitutively expressed in all tissues, and the expression level was greatest in stem, followed by stem bark, roots and leaves. In order to understand this gene's function, we transformed it into Arabidopsis thaliana; integration (one insertion site) was confirmed following PCR and southern hybridization. The over-expression of CcCCoAOMT1 in these transgenic A.thaliana plants resulted in increased plant height and silique length relative to non-transgenic plants. Perhaps the most important finding was that the transgenic Arabidopsis plants contained more lignin (20.44–21.26%) than did control plants (17.56%), clearly suggesting an important role of CcCCoAOMT1 gene in lignin biosynthesis. These data are important for the success of efforts to reduce jute lignin content (thereby increasing fiber quality) via CcCCoAOMT1 gene inhibition.     

Xylem-specific expression of a GRP1.8 promoter::4CL gene construct in transgenic tobacco

Lignin is a complex aromatic polymer of vascular plants that provides mechanical strength to the stem and protects cellulose fibres from chemical and biological degradation. 4-Coumarate:CoA ligases (EC 6.2.1.12) are key enzymes for the biosynthetic pathway of monolignols which is an important complex aromatic polymer for lignin biosynthesis and tree growth. Recently, 4-coumarate:CoA ligase has been used as exogenous gene in transgenic plants to genetically modify the lignin biosynthesis pathway. Since most lignin is produced in the vascular cells, a tissue-specific-expressed promoter in the vascular cell would be important and useful to change and modify the content of lignin. Here we report the existence of a promoter of GRP1.8 (the glycine-rich protein 1.8) in Sopho japonica L. (GenBank accession number AF250149) and studies on its function in transgenic tobacco. The promoter activity was analyzed in transgenic tobacco plants by histochemical staining of GUS gene expression driven by a 613-bp sjGRP1.8p promoter sequence. In sjGRP1.8p-GUS transgenic plants, intense GUS staining was detected in the xylem of the stem. To further investigate the regulation of the tissue-specific expression of the 4CL1 gene, we analyzed the activity of the 4CL1 gene which is sense orientated with the sjGRP1.8p promoter in transgenic tobacco. The Pto4CL1 gene was expressed in the stem of transgenic tobacco. The activity of the 4CL1 enzyme was increased 1–2-fold in the stem but not increased in the leaves of transgenic tobacco. In comparison with the control plants, the content of lignin was increased 25% in the stem but there was no increase in the leaves of transgenic tobacco.     

An Isopentyl Transferase Gene Driven by the Stress-Inducible rd29A Promoter Improves Salinity Stress Tolerance in Transgenic Tobacco

Soil salinity is a serious worldwide problem. To improve the salt tolerance of plants, an increasing number of genes related to abiotic stress have been recently expressed by genetic engineers. In the present study, the successful introduction into tobacco of isopentenyl transferase (IPT) from Agrobacterium tumefaciens via Agrobacterium-mediated transformation is reported. A stress-inducible genetic construct was cloned using IPT under the control of the stress-inducible promoter rd29A from Arabidopsis thaliana. A total of 40 putative transgenic plant lines were obtained from independent Kan-resistant shoots. IPT integration into the tobacco genome was confirmed by polymerase chain reaction (PCR) and Southern blot analyses. Four positive transgenic lines each with a single T-DNA insertion were obtained. Real-time PCR confirmed a marked increase in IPT expression in young tobacco plants harboring rd29A-IPT after short-term exposure to salt. Ectopic IPT overexpression IPT under the control of the stress-inducible rd29A promoter resulted in significantly enhanced tolerance to salt stress. No obvious adverse effect on growth and development was observed in transgenic plants. Two IPT transgenic lines, T10 and T25, were chosen for further physiological analyses. The leaves of transgenic tobacco plants showed significantly prolonged chlorophyll retention times under a 2-week salt-stress treatment (150?mmol?L^?1). In contrast, the leaves of the non-transformed plants (wild type) gradually senesced under the same condition. After re-watering for 2?weeks, chlorophyll in transgenic plants increased to a level comparable with that in the unstressed plants. On the other hand, the level in the non-transgenic control still remained low. Malondialdehyde (MDA) levels increased in both transgenic plants and the control after salt stress. However, the MDA levels only mildly increased in transgenic plants, and dramatically increased in the control. After re-watering for 7?days, MDA in transgenic plants returned to normal, whereas the level in the control remained high. Superoxide dismutase activity also similarly increased in transgenic plants during salt stress, and returned to normal after re-watering. These results indicate that enhanced reactive oxygen species scavenging capability may play a significant role in acquiring tolerance to abiotic stress.     

Estradiol inducible and flower-specific expression of ARGOS and ARGOS-LIKE genes in transgenic tobacco plants

Transgenic tobacco plants expressing Arabidopsis thaliana ARGOS and ARGOS-LIKE genes under the control of the chalcone synthase promoter of Petunia hybrida L., as well as the estradiol inducible XVE system, have been obtained. The part of transgenic plants with flower-specific expression of the target genes was characterized by increased flower size, caused by an increase in cell size and quantity in the case of the ARGOS gene and by a stimulation of cell growth via stretching in the case of the ARGOS-LIKE gene. An enhanced expression level of the NtEXPA1, NtEXPA4 genes encoding expansins, NtEXGT gene encoding endo-xyloglucan transferase, and the AINTEGUMENTA-like gene was detected in the flowers of transgenic tobacco plants. In the case of inducible expression of ARGOS and ARGOS-LIKE genes, an increase in leaf, stem and flower size was revealed in several lines of transgenic plants as compared to control. Expression of the ARGOS gene also affected cell number and size in this case, while the ARGOS-LIKE gene mainly influenced cell size via stretching. Inducible expression of the ARGOS gene in flowers mainly provided an enhanced containment of AINTEGUMENTA-like mRNA, while ARGOS-LIKE gene expression resulted in the activation of NtEXPA1 and NtEXGT genes.