B. R. Kuluev

Role of the expansin genes NtEXPA1 and NtEXPA4 in the regulation of cell extension during tobacco leaf growth

The tobacco plant genes NtEXPA1 and NtEXPA4 encode the α-expansin proteins involved in the regulation of cell growth and extension. We examined the levels of expression of these genes in various plant organs and under the effect of exogenous phytohormones. The highest level of NtEXPA1 expression were registered in the terminal bud and in the young growing leaves and flowers. NtEXPA1 expression ceased once the leaves stopped growing. The NtEXPA4 gene showed a similar expression profile, except for higher levels of mRNA in the leaves. In young leaves located near the terminal bud, high levels of NtEXPA1 and NtEXPA4 are induced by auxins. In the lower leaves, expansin expression is differentially regulated by brassinosteroids, which inhibit NtEXPA1 and upregulate NtEXPA4. We further showed that expression of the transgenic ARGOS-LIKE protein results in upregulation of NtEXPA1 and a reduction in the NtEXPA4 mRNA. In turn, overexpression of NtEXPA1 resulted in an increased size of the leaves and stems because of the larger size of the individual cells.

Constitutive expression of the ARGOS 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.

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.

Morphological and physiological characteristics of transgenic tobacco plants expressing expansin genes: AtEXP10 from Arabidopsis and PnEXPA1 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.

Activity of promoters of carnation etched ring virus and dahlia mosaic virus in tobacco protoplasts and transgenic plants

Promoters of carnation etched ring virus (CERV) and dahlia mosaic virus (DMV) were cloned into binary vectors pCambia 1304, pCambia 1281Z, and pCambia 1291Z with reporter GFP and GUS genes. Activities of these promoters in tobacco protoplasts and transgenic plants were determined using these constructs. Histochemical GUS analysis demonstrated the absence of tissue-specificity in transgenic plants transformed with these promoters. The quantitative analysis of these promoter activities in transgenic tobacco plants, using 4-methylumbelliferone as a substrate, showed that 35S CaMV, CERV, and DMV promoters displayed approximately similar activities in transgenic tobacco plants.

Effect of constitutive expression of ARGOS-LIKE gene on sizes of cells and organs of transgenic tobacco plants

Transgenic tobacco plants that overexpress the ARGOS-LIKE (ARL) gene of Arabidopsis thaliana have been developed. The transgenic plants possessed increased sizes of leaves and stem, whereas the magnitude of flowers was modified to a lesser degree. The increase in the organ sizes was a result of stimulation of cell expansion; the cell quantity in the organ was even decreased. Ectopic expression of the ARL gene was promoted in order to increase in the level of mRNA of tobacco expansin NtEXPA5. It has been shown that the ARL gene of A. thaliana can be used to obtain transgenic plants with increased sizes of the leaves and stem.

Construction of hybrid promoters of caulimoviruses and analysis of their activity in transgenic plants

By the techniques of DNA shuffling, PCR, and restriction-ligation, chimeric forms of cauliflower (Brassica oleracea) mosaic virus (CaMV), dahlia (Dahlia pinnata) mosaic virus (DMV), and carnation (Dianthus caryophillus) etching ring virus (CERV) promoters were obtained at various combinations. Twelve chimeric promoters were cloned into pCambia binary vectors comprising the reporter GUS gene, and their activities in transgenic tobacco (Nicotiana tabacum) plants were determined fluorimetrically. 35S promoter and those of DMV (442 bp) and CERV (371 and 501 bp) were used as controls. Seven of analyzed promoters displayed higher and seven promoters lower activity in transgenic tobacco plants than 35S promoter. The highest activity was characteristic of natural DMV promoter, and the least one — natural CERV promoter 501 bp in size. The CERV promoter 371 bp in size was approximately similar in strength to 35S promoter.

Effect of cadmium on promoter activity of rice phytochelatin synthase gene in transgenic tobacco plants

The effect of cadmium acetate (200 and 400 μM Cd(CH3COO)2) on the transcriptional promoter activity of rice (Oryza sativa L.) phytochelatin synthase gene 900 bp in size was studied. The reporter gene of glucuronidase was placed under the control of this promoter in transgenic tobacco (Nicotiana tabacum L.) plants. For determining boundaries of this gene promoter responsive to cadmium, deletion constructs were created and their transcriptional activity was measured under the influence of different cadmium concentrations. Deletion of 189 bp from the 5′-terminus of this gene promoter resulted in some transcription activation, whereas deletion of successive 95 bp from the 5′-terminus resulted in cadmium-independent activation of the promoter.

Expression profiles and hormonal regulation of tobacco expansin genes and their involvement in abiotic stress response

Changes in the expression levels of tobacco expansin genes NtEXPA1, NtEXPA4, NtEXPA5, and NtEXPA6 were studied in different organs of tobacco (Nicotiana tabacum L.) as well as in response to phytohormone and stress treatments. It was shown that NtEXPA1, NtEXPA4 and NtEXPA5 transcripts were predominantly expressed in the shoot apices and young leaves, but almost absent in mature leaves and roots. The NtEXPA6 mRNA was found at high levels in calluses containing a large number of undifferentiated cells, but hardly detectable in the leaves of different ages and roots. In young leaves, expression levels of NtEXPA1, NtEXPA4 and NtEXPA5 genes were induced by cytokinins, auxins and gibberellins. Cytokinins and auxins were also found to increase NtEXPA6 transcripts in young leaves but to the much lower levels than the other expansin mRNAs. Expression analysis demonstrated that brassinosteroid phytohormones were able either to up-regulate or to down-regulate expression of different expansins in leaves of different ages. Furthermore, transcript levels of NtEXPA1, NtEXPA4, and NtEXPA5 genes were increased in response to NaCl, drought, cold, heat, and 10μM abscisic acid (ABA) treatments but reduced in response to more severe stresses, i.e. cadmium, freezing, and 100μM ABA. In contrast, no substantial changes were found in NtEXPA6 transcript level after all stress treatments. In addition, we examined the involvement of tobacco expansins in the regulation of abiotic stress tolerance by transgenic approaches. Transgenic tobacco plants with constitutive expression of NtEXPA1 and NtEXPA5 exhibited improved tolerance to salt stress: these plants showed higher growth indices after NaCl treatment and minimized water loss by reducing stomatal density. In contrast, NtEXPA4-silenced plants were characterized by a considerable growth reduction under salinity and enhanced water loss. Our findings indicate that expression levels of all studied tobacco expansins genes are modulated by plant hormones whereas NtEXPA1, NtEXPA4, and NtEXPA5 expansins may be involved in the regulation of stress tolerance in tobacco plants.

Role of AINTEGUMENTA-like gene NtANTL in the regulation of tobacco organ growth

The Nicotiana tabacum AINTEGUMENTA-like gene (NtANTL), encoding one of AP2/ERF transcription factors, is a putative ortholog of the AtANT gene from Arabidopsis thaliana. In wild-type tobacco plants, the NtANTL gene was expressed in the actively dividing young flowers, shoot apices, and calluses, while the level of its mRNA increased considerably after treatment with exogenous 6-benzylaminopurine, indoleacetic acid and 24-epibrassinolide. We found a positive correlation among the expression levels of NtANTL, cyclin NtCYCD3;1 and cyclin-dependent kinase NtCDKB1-1 genes, suggesting possible molecular links between AINTEGUMENTA and cell cycle regulators in tobacco plants. However, no correlation was observed between NtANTL, NtCYCD3;1 and NtCDKB1-1 expression levels in response to NaCl and ABA. These observations indicate that the transcription factor NtANTL was not involved in the regulation of the cellular response to salinity nor did it affect the expression of NtCYCD3;1 and NtCDKB1-1 when tobacco plants were exposed to salt stress and ABA. In addition, we generated transgenic tobacco plants with both up-regulated and down-regulated expression of the NtANTL gene. Constitutive expression of the NtANTL gene contributed to an increase in the size of leaves and corolla of transgenic plants. Transgenic plants with reduced expression of the NtANTL gene had smaller leaves, flowers and stems, but showed a compensatory increase in the cell size of leaves and flowers. The results show the significance of the NtANTL gene for the control of organ growth by both cell division and expansion in tobacco plants.