Transgenic Turfgrasses Expressing Hyperactive Ser599Ala Phytochrome A Mutant Exhibit Abiotic Stress Tolerance

Turfgrasses are environmentally and recreationally valuable plants that are constantly subjected to various forms of stress in their artificial and natural habitats. Previously, it was shown that the transformation of a hyperactive mutant (Serine 599 Alanine, S599A) of oat phytochrome A in zoysia grass (Zoysia japonica) and creeping bentgrass (Agrostis stolonifera L.) resulted in superior quality turfgrass with improved shade tolerance response. We now examined the abiotic stress response of the transgenic turfgrasses expressing the hyperactive mutant S599A-PhyA. The transgenic S599A-PhyA plants subjected to high salinity and heavy metal toxicity stress exhibited higher chlorophyll content, lower hydrogen peroxide level, and higher proline accumulation than the controls. Furthermore, the anti-oxidative activities of four reactive oxygen species scavenging enzymes and the total biomass (above and below-ground) were higher in S599A-PhyA plants than in the controls under both the stress conditions. Moreover, higher photosynthetic efficiency (F _v/F _m) of S599A-PhyA plants indicated healthier growth than the controls under stress conditions. Results suggest that the hyperactive mutant of oat phytochrome A confers abiotic stress tolerance in plants, and can be used to efficiently develop abiotic stress tolerant crops in future.     

Overexpression of phytochrome A and its hyperactive mutant improves shade tolerance and turf quality in creeping bentgrass and zoysiagrass

Phytochrome A (phyA) in higher plants is known to function as a far-red/shade light-sensing photoreceptor in suppressing shade avoidance responses (SARs) to shade stress. In this paper, the Avena PHYA gene was introduced into creeping bentgrass (Agrostis stolonifera L.) and zoysiagrass (Zoysia japonica Steud.) to improve turf quality by suppressing the SARs. In addition to wild-type PHYA, a hyperactive mutant gene (S599A-PHYA), in which a phosphorylation site involved in light-signal attenuation was removed, was also transformed into the turfgrasses. Phenotypic traits of the transgenic plants were compared to assess the suppression of SARs under a simulated shade condition and outdoor field conditions after three growth seasons. Under the shade condition, the S599A-PhyA transgenic creeping bentgrass plants showed shade avoidance-suppressing phenotypes with a 45?% shorter leaf lengths, 24?% shorter internode lengths, and twofold increases in chlorophyll concentrations when compared with control plants. Transgenic zoysiagrass plants overexpressing S599A-PHYA also showed shade-tolerant phenotypes under the shade condition with reductions in leaf length (15?%), internode length (30?%), leaf length/width ratio (19?%) and leaf area (22?%), as well as increases in chlorophyll contents (19?%) and runner lengths (30?%) compared to control plants. The phenotypes of transgenic zoysiagrass were also investigated in dense field habitats, and the transgenic turfgrass exhibited shade-tolerant phenotypes similar to those observed under laboratory shade conditions. Therefore, the present study suggests that the hyperactive phyA is effective for the development of shade-tolerant plants, and that the shade tolerance nature is sustained under field conditions.     

The overaccumulation of glycinebetaine alleviated damages to PSII of wheat flag leaves under drought and high temperature stress combination

To analyze the physiological mechanisms underlying the increased tolerance to drought and high temperature stress combination by overproduction of glycinebetaine (GB) in wheat, a transgenic wheat line T6 and its wild-type (WT) Shi4185 were used. The transgenic line was generated by introducing a gene encoding betaine aldehyde dehydrogenase (BADH) into a wheat line Shi4185. The gene was cloned from Garden Orache (Atriplex hortensis L.). Wheat plants were exposed to drought (withholding irrigation), high temperature stress (40 °C), and their combination at the flowering stage. Analyses of oxygen-evolving activity and photosystem II (PSII) photochemistry, modulated chlorophyll fluorescence, rapid fluorescence induction kinetics, and the polyphasic fluorescence transients (OJIP) were used to evaluate PSII photochemistry in wheat plants. The results suggest that the PSII in transgenic plants showed higher resistance than that in wild-type plants under the stresses studied here, this increased tolerance was associated with an improvement in stability of the oxygen-evolving complex and the reaction center of PSII; streptomycin treatment can impair the protective effect of overaccumulated GB on PSII. The overaccumulated GB may protect the PSII complex from damage through accelerating D1 protein turnover to alleviate photodamage. The results also suggest that the PSII under combined high temperature and drought stress shows higher tolerance than under high temperature stress alone in both transgenic and wild-type plants.     

Resistance of transgenic zoysiagrass overexpressing the zoysiagrass class II chitinase gene <Emphasis Type="Italic">Zjchi2</Emphasis> against <Emphasis Type="Italic">Rhizoctonia solani</Emphasis> AG2-2 (IV)

Zoysiagrass (Zoysia japonica Steud.) is an important turfgrass species used in golf courses and athletic fields. However, zoysiagrass is susceptible to large patch disease caused by Rhizoctonia solani AG2-2 (IV). Chitinases are pathogen-related (PR) proteins induced by viruses, bacteria, and fungi that hydrolyze chitin. Recently, we isolated a class II chitinase gene (Zjchi2) from zoysiagrass. The purified recombinant Zjchi2 showed broad-spectrum activity against various fungi, including R. solani AG2-2 (IV). In the current study, we generated transgenic zoysiagrass overexpressing Zjchi2 and then verified the resistance of transgenic plants to R. solani AG2-2 (IV). Polymerase chain reaction and Southern blot hybridization showed the integration of transgenes in zoysiagrass genomes and constitutive expression of Zjchi2, respectively. Antifungal activity was enhanced significantly in the transgenic zoysiagrass compared with wild-type plants. To our knowledge, this report is the first on the antifungal activity of a class II chitinase in transgenic zoysiagrass.     

Transgenic tobacco plants expressingBoRS1 gene fromBrassica oleracea var.acephala show enhanced tolerance to water stress

Water stress is by far the leading environmental stress limiting crop yields worldwide. Genetic engineering techniques hold great promise for developing crop cultivars with high tolerance to water stress. In this study, theBrassica oleracea var.acephala BoRS1 gene was transferred into tobacco throughAgrobacterium- mediated leaf disc transformation. The transgenic status and transgene expression of the transgenic plants was confirmed by polymerase chain reaction (PCR) analysis, Southern hybridization and semi-quantitative one step RT-PCR analysis respectively. Subsequently, the growth status under water stress, and physiological responses to water stress of transgenic tobacco were studied. The results showed that the transgenic plants exhibited better growth status under water stress condition compared to the untransformed control plants. In physiological assessment of water tolerance, transgenic plants showed more dry matter accumulation and maintained significantly higher levels of leaf chlorophyll content along with increasing levels of water stress than the untransformed control plants. This study shows thatBoRS1 is a candidate gene in the engineering of crops for enhanced water stress tolerance.     

OsMsr9, a novel putative rice F-box containing protein,confers enhanced salt tolerance in transgenic rice and Arabidopsis

Salinity is a major environmental stress that limits agricultural production and geographical distribution of plants. In a previous study, it has been shown that OsMsr9 was induced by cold, drought and heat stresses. However, functions of OsMsr9 at physiological and molecular levels are still unknown. Here, we report that OsMsr9 plays roles in salt tolerance in plants. Quantitative real-time PCR (qPCR) analysis revealed that OsMsr9 was also rapidly and strongly induced by salt stress. Overexpression of OsMsr9 in Arabidopsis and rice showed enhanced salt stress tolerance displaying increased shoot and root elongation, higher survival rates in transgenic plants compared with wild type. OsMsr9 might act as a positive regulator of plant salt tolerance with reinforced expression of stress-related genes, such as RD29A, DREB2A and RAB18 in transgenic plants under salt conditions. Furthermore, transgenic plants accumulated more compatible solutes (proline and soluble sugar) and low level of malondialdehyde, alleviating the changes in reactive oxygen species. These results indicate that OsMsr9 could be a useful gene in developing transgenic crops with enhanced salt tolerance.     

Overexpression of osmotin gene confers tolerance to salt and drought stresses in transgenic tomato (Solanum lycopersicum L.)

Abiotic stresses, especially salinity and drought, are major limiting factors for plant growth and crop productivity. In an attempt to develop salt and drought tolerant tomato, a DNA cassette containing tobacco osmotin gene driven by a cauliflower mosaic virus 35S promoter was transferred to tomato (Solanum lycopersicum) via Agrobacterium-mediated transformation. Putative T0 transgenic plants were screened by PCR analysis. The selected transformants were evaluated for salt and drought stress tolerance by physiological analysis at T1 and T2 generations. Integration of the osmotin gene in transgenic T1 plants was verified by Southern blot hybridization. Transgenic expression of the osmotin gene was verified by RT-PCR and northern blotting in T1 plants. T1 progenies from both transformed and untransformed plants were tested for salt and drought tolerance by subjecting them to different levels of NaCl stress and by withholding water supply, respectively. Results from different physiological tests demonstrated enhanced tolerance to salt and drought stresses in transgenic plants harboring the osmotin gene as compared to the wild-type plants. The transgenic lines showed significantly higher relative water content, chlorophyll content, proline content, and leaf expansion than the wild-type plants under stress conditions. The present investigation clearly shows that overexpression of osmotin gene enhances salt and drought stress tolerance in transgenic tomato plants.     

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.     

Transgenic Tobacco Plants Low in Phytochrome A Content

Tobacco (Nicotiana tabacum) plants were transformed with a construct encoding phytochrome A (PHYA) antisense RNA. The construct inserted into the tobacco genome contained squash PHYA cDNA in an antisense orientation under the cauliflower mosaic virus 35S promoter providing for gene expression in higher plant tissues. Using immunoblot analysis and Z3-B1 antibodies against PHYA, the authors demonstrated that the PHYA content of the transgenic plants was lower than that of the wild-type plants. The studies of PHYA-dependent inhibition of hypocotyl elongation by high-intensity far-red light showed a considerable decrease in light sensitivity of the transgenic hypocotyl characteristic for aphyAmutation.     

Functional analysis of PsG6PDH, a cytosolic glucose-6-phosphate dehydrogenase gene from Populus suaveolens, and its contribution to cold tolerance improvement in tobacco plants

A 1,697-bp cDNA sequence, designated as PsG6PDH, was amplified from Populus suaveolens. Multiple sequence alignment and phylogenetic analysis indicated that PsG6PDH encodes a cytosolic G6PDH isoform, with Southern blot analysis demonstrating that the gene is single or low copy in Populus. Transgenic tobacco plants over-expressing PsG6PDH exhibited enhanced cold tolerance. In both transgenic and wild-type (WT) tobacco plants, cold stress increased leaf malondialdehyde (MDA) content, electrolyte leakage (EL), and peroxide (POD) and superoxide dismutase (SOD) activities; relative to WT, however, transgenic lines had lower MDA content and EL and higher SOD and POD activities. In addition, PsG6PDH activated the expression of stress-related genes, including NtERD10b, NtERD10c, and NtSOD, in tobacco plants. Our results provide evidence regarding PsG6PDH regulatory function in plants during low temperature stress.     

Expression analysis and functional characterization of a novel cold-responsive gene <Emphasis Type="Italic">CbCOR15a</Emphasis> from <Emphasis Type="Italic">Capsella bursa</Emphasis>-<Emphasis Type="Italic">pastoris</Emphasis>

The cold-responsive (COR) genes involved in C-repeat binding factor signaling pathway function essentially in cold acclimation of higher plants. A novel COR gene CbCOR15a from shepherd’s purse (Capsella bursa-pastoris) was predicted to be a homolog of COR15 in Arabidopsis. The analysis of tissue specific expression pattern as well as characterization of the CbCOR15a promoter revealed that the expression of CbCOR15a was induced by coldness not only in leaves and stem but also in roots. Sequence analysis showed that a 909 bp promoter region of CbCOR15a contained two CRT/DRE elements, two ABRE elements, one auxin-responsive TGA-element and one MeJA-responsive CGTCA-motif. In young seedlings the expression of CbCOR15a could be apparently increased by SA, ABA, MeJA and IAA, and transiently increased by GA₃ accompanied by obvious feedback suppression. According to the altered physiological index values in tobacco under cold treatments, the overexpression of CbCOR15a significantly increased the cold tolerance of transgenic tobacco plants. It can be suggested that CbCOR15a was involved in cold response of Capsella bursa-pastoris associated with SA, ABA, MeJA, IAA and GA₃ regulation and confers enhanced cold acclimation in transgenic plants.     

Protein Kinase LTRPK1 Influences Cold Adaptation and Microtubule Stability in Rice

Rice LTRPK1, which encodes a member of the casein kinase I family, has been reported to be involved in root development, hormone response, and metabolic processes. Here we further show that LTRPK1 participates in stress resistance by regulating cytoskeleton rearrangement and formation of cold tolerance and adaptation. Semiquantitative RT-PCR analysis revealed enhanced expression of LTRPK1 in plants subject to low-temperature stress at 4 °C, suggesting a role in low-temperature-related cell responses and signal transduction pathways. Further analysis of LTRPK1-deficient transgenic plants showed that under low-temperature treatment, the growth rate of transgenic plant primary roots, which is commonly used as an indicator for cold stress response abilities, was less inhibited than that of control plants. Moreover, damage to the plasma membrane of root cells in LTRPK1-deficient plants was greater than that of controls as measured by relative electrical conductivity (REC). The malondialdehyde (MDA) content of LTRPK1-deficient plants also increased over that of the control, indicating increased plasma membrane permeability. Further immunofluorescence localization observations indicated that microtubules of transgenic plants subject to low temperature disassembled more rapidly, whereas the control plant microtubules in most cells of the root elongation zone kept their normal habitus, which suggested that LTRPK1-deficient plants had reduced capacity to resist low-temperature stress through regulation of microtubule assembly. These results demonstrate involvement of LTRPK1 in low-temperature stress and provide new insight for rice breeding and germplasm innovation to improve crop cold tolerance.     

AtCPK6, a functionally redundant and positive regulator involved in salt/drought stress tolerance in Arabidopsis

The calcium-dependent protein kinase (CDPK) family is needed in plant signaling during various physiological pathways. The Arabidopsis AtCPK6 gene belongs to the subclass of stress-inducible CDPKs, which is stimulated by salt and osmotic stress. To elucidate the physiological function of AtCPK6, transgenic Arabidopsis plants under the control of double CaMV 35S promoter were obtained. AtCPK6 over-expressing plants showed enhanced tolerance to salt/drought stresses. The elevated tolerance of the AtCPK6 over-expressing plants was confirmed by the change of proline and malondialdehyde (MDA). Real-time PCR analyses revealed that the expression levels of several stress-regulated genes were altered in AtCPK6 over-expressing plants. However, cpk6 mutant displayed no obvious difference with control. These results are likely to indicate that AtCPK6 is functionally redundant and a positive regulator involved in the tolerance to salt/drought stress in Arabidopsis.     

Photoresponses of transgenic tobacco plants expressing an oat phytochrome gene

The physiological responses of transgenic tobacco (Nicotiana tabacum L.) plants that express high levels of an introduced oat (Avena sativa L.) phytochrome (phyA) gene to various light treatments are compared with those of wild-type (WT) plants. Seeds, etiolated seedlings, and light-grown plants from a homozygous transgenic tobacco line (9A4) constructed by Keller et al. (EMBO J, 8, 1005–1012, 1989) were treated with red (R), far-red (FR), or white light (WL) with or without supplemental FR light, revealing major perturbations of the normal photobiological responses. White light stimulated germination of both WT and transgenic seed, but addition of FR to the WL treatment suppressed germination. In the WT, all fluence rates tested inhibited germination, but in the transgenics, reduction effluence rate partially relieved germination from the FR-mediated inhibition. It is suggested that the higher absolute levels of the FR-absorbing form of phytochrome (Pfr) in the irradiated transgenics, compared to the WT, may be responsible for the reduced FR-mediated inhibition of germination in the former. Hypocotyl extension of dark-grown seedlings of both WT and transgenic lines was inhibited by continuous R or FR irradiation, typical of the high-irradiance response (HIR). After 2 d of de-etiolation in WL, the WT seedlings had lost the FR-mediated inhibition of hypocotyl extension, whereas it was retained in the transgenics. The FR-mediated inhibition of hypocotyl extension in the transgenic seedlings after de-etiolation may reflect the persistence of an, FR-HIR response mediated by the overexpressed oat PhyA phytochrome. Light-grown WT seedlings exhibited typical shade-avoidance responses when treated with WL supplemented with high levels of FR radiation. Internode and petiole extension rates were markedly increased, and the chlorophyll ab ratio decreased, in the low-R: FR treatment. The transgenics, however, showed no increases in extension growth under low-R: FR treatments, and at low fluence rates both internode and petiole extension rates were significantly decreased by low R FR. Interpretation of these data is difficult. The depression of the chlorophyll ab ratio by low R FR was identical in WT and transgenic plants, indicating that not all shade-avoidance responses of light-grown plants were disrupted by the over-expression of the introduced oat phyA gene. The results are discussed in relation to the proposal that different members of the phytochrome family may have different physiological roles.Abbreviations FR far-red light - PAR photosynthetically active radiation - Pr, Pfr red- and FR-absorbing forms of phytochrome - Ptot total phytochrome - PhyA (PhyA) gene (encoded protein) for phytochrome - R red light - WL white light - WT wild type This work was supported by an Agricultural and Food Research Council research grant to H.S. and A.C.M.; the production of the transgenic seed was funded by the U.S. Department of Energy (DE-F602-88ER13968) to R.D.V., and by E.I. du Pont de Nemours; Dr. G.C. Whitelam is thanked for the provision of monoclonal antibodies for the immunoblot analyses.