Cotton PRP5 gene encoding a proline-rich protein is involved in fiber development

Proline-rich proteins contribute to cell wall structure of specific cell types and are involved in plant growth and development. In this study, a fiber-specific gene, GhPRP5, encoding a proline-rich protein was functionally characterized in cotton. GhPRP5 promoter directed GUS expression only in trichomes of both transgenic Arabidopsis and tobacco plants. The transgenic Arabidopsis plants with overexpressing GhPRP5 displayed reduced cell growth, resulting in smaller cell size and consequently plant dwarfs, in comparison with wild type plants. In contrast, knock-down of GhPRP5 expression by RNA interference in cotton enhanced fiber development. The fiber length of transgenic cotton plants was longer than that of wild type. In addition, some genes involved in fiber elongation and wall biosynthesis of cotton were up-regulated or down-regulated in the transgenic cotton plants owing to suppression of GhPRP5. Collectively, these data suggested that GhPRP5 protein as a negative regulator participates in modulating fiber development of cotton.     

Cotton TCTP1 gene encoding a translationally controlled tumor protein participates in plant response and tolerance to aphids

Cotton aphid (Aphis gossypii Glover) is one of the most important economic pests in the world. Long-term unreasonable usage of insecticides has made cotton aphid developing insecticide-resistance, which frequently leads to serious occurrences of cotton aphid in many regions. It is regarded effective and environmentally friendly to control aphids through utilizing plant resistance. In this study, a translationally controlled tumor protein gene, GhTCTP1, was isolated in cotton. It belongs to TCTP subfamily and encodes a protein of 168 amino acids. GhTCTP1 expression was suppressed in cotton plants under cotton aphid attack, but its expression level was up-regulated in the wounded cotton leaves. The choice test and no-choice test demonstrated that overexpression of GhTCTP1 in Arabidopsis enhanced plant resistance to green peach aphid (Myzus persicae). Quantitative RT-PCR analysis revealed that the defense response genes related to salicylic acid signaling pathway were activated in the GhTCTP1 overexpressing transgenic plants. Content of total amino acids was decreased, and phenylalanine ammonialyase activity was altered in leaves of the transgenic Arabidopsis plants, compared with those in wild type. Furthermore, the callose amount in transgenic Arabidopsis leaves was more than that of wild type. These data suggested that GhTCTP1 might be involved in regulation of plant tolerance to aphids, and can be potentially applied in improving aphid-resistance of crops by genetic manipulation.     

GhTZF1 regulates drought stress responses and delays leaf senescence by inhibiting reactive oxygen species accumulation in transgenic Arabidopsis

Redox homeostasis is important for plants to be able to maintain cellular metabolism, and disrupting cellular redox homeostasis will cause oxidative damage to cells and adversely affect plant growth. In this study, a cotton CCCH-type tandem zinc finger gene defined as GhTZF1, which was isolated from a cotton cell wall regeneration SSH library in our previous research, was characterized. GhTZF1 was predominantly expressed during early cell wall regeneration, and it was expressed in various vegetative and reproductive tissues. The expression of GhTZF1 was substantially up-regulated by a variety of abiotic stresses, such as PEG and salt. GhTZF1 also responds to methyl jasmonate (MeJA) and H₂O₂ treatment. Overexpression of GhTZF1 enhanced drought tolerance and delayed drought-induced leaf senescence in transgenic Arabidopsis. Subsequent experiments indicated that dark- and MeJA-induced leaf senescence was also attenuated in transgenic plants. The amount of H₂O₂ in transgenic plants was attenuated under both drought conditions and with MeJA-treatment. The activity of superoxide dismutase and peroxidase was higher in transgenic plants than in wild type plants under drought conditions. Quantitative real-time PCR analysis revealed that overexpression of GhTZF1 reduced the expression of oxidative-related senescence-associated genes (SAGs) under drought conditions. Overexpression of GhTZF1 also enhanced oxidative stress tolerance, which was determined by measuring the expression of a set of antioxidant genes and SAGs that were altered in transgenic plants during H₂O₂ treatment. Hence, we conclude that GhTZF1 may serve as a regulator in mediating drought stress tolerance and subsequent leaf senescence by modulating the reactive oxygen species homeostasis.     

Ectopic Expression of Sweet Potato Cysteine Protease SPCP3 Alters Phenotypic Traits and Enhances Drought Stress Sensitivity in Transgenic Arabidopsis Plants

In this report sweet potato cysteine protease SPCP3 cDNAs, with or without the corresponding granulin-like domain, were overexpressed in transgenic Arabidopsis plants. Transgenic Arabidopsis plants with ectopic expression of full-length SPCP3 exhibited slight promotion of earlier floral transition from vegetative to reproductive growth and a higher percentage of yellowing siliques per plant. Transgenic progeny seeds showed similar patterns of germination rates and germination curves but lower germination percentages compared to those of wild-type control seeds. During drought treatment, photochemical F _v/F _m values and relative water content of transgenic plants were significantly reduced compared to those of wild-type controls. Transgenic Arabidopsis plants with ectopic expression of sweet potato SPCP3 with or without the corresponding C-terminal granulin-like domain exhibited similar drought-stress sensitivity patterns. Drought stress also enhanced SPCP3 gene expression, photochemical F _v/F _m reduction, and wilting in sweet potato detached leaves. Based on these data, we conclude that sweet potato granulin-containing cysteine protease SPCP3 is a functional gene, and its ectopic expression alters phenotypic traits and enhances drought-stress sensitivity in transgenic Arabidopsis plants. The presence of the C-terminal granulin-like domain has no significant influence on SPCP3-mediated drought-stress sensitivity in transgenic Arabidopsis plants.     

Cotton Chitinase Gene GhChi6 Improves the Arabidopsis Defense Response to Aphid Attack

Despite the involvement of many members of the chitinase family in the plant immune system, the exact functions of most chitinases remain poorly understood, especially in plant defense responses to phytophagous insects. Here, the gene GhChi6, which encodes a chitinase protein in Gossypium hirsutum, was shown to be induced by cotton aphid feeding and mechanical wounding. Overexpression of GhChi6 in Arabidopsis plants improved their defense response to aphids. The activities of chitinase and PPO in GhChi6 transgenic Arabidopsis plants were higher than those in wild-type plants. Callose deposition in leaves from GhChi6 transgenic Arabidopsis plants was clearly increased compared with wild-type plants. The levels of AtEDS1, AtPAD4, and AtEDS5 in the SA signaling pathway were higher in GhChi6 transgenic Arabidopsis Line4 than those in wild-type plants, while the expression levels of AtLOX2 in the JA signaling pathway and AtEIN2 in the ethylene signaling pathway were lower in GhChi6 transgenic Arabidopsis Line4 than those in wild-type plants. These results collectively showed that the cotton chitinase gene GhChi6 modulated the plant defense response to aphid attack, which may help guide strategies for improving cotton aphid prevention.

     

GhMPK17, a Cotton Mitogen-Activated Protein Kinase,Is Involved in Plant Response to High Salinity and Osmotic Stresses and ABA Signaling

Mitogen-activated protein kinase (MAPK) cascades play pivotal roles in mediating biotic and abiotic stress responses. Cotton (Gossypium hirsutum) is the most important textile crop in the world, and often encounters abiotic stress during its growth seasons. In this study, a gene encoding a mitogen-activated protein kinase (MAPK) was isolated from cotton, and designated as GhMPK17. The open reading frame (ORF) of GhMPK17 gene is 1494 bp in length and encodes a protein with 497 amino acids. Quantitative RT-PCR analysis indicated that GhMPK17 expression was up-regulated in cotton under NaCl, mannitol and ABA treatments. The transgenic Arabidopsis plants expressing GhMPK17 gene showed higher seed germination, root elongation and cotyledon greening/expansion rates than those of the wild type on MS medium containing NaCl, mannitol and exogenous ABA, suggesting that overexpression of GhMPK17 in Arabidopsis increased plant ABA-insensitivity, and enhanced plant tolerance to salt and osmotic stresses. Furthermore, overexpression of GhMPK17 in Arabidopsis reduced H₂O₂ level and altered expression of ABA- and abiotic stress-related genes in the transgenic plants. Collectively, these data suggested that GhMPK17 gene may be involved in plant response to high salinity and osmotic stresses and ABA signaling.     

Genetic analyses of the formation of the serrated margin of leaf blades in Arabidopsis : combination of a mutational analysis of leaf morphogenesis with the characterization of a specific marker gene expressed in hydathodes and stipules

Developmental control of the formation of the serrated margin of leaf blades was investigated. First, the expression was characterized of a marker gene encoding β-glucuronidase in strain #1-35-38, a transgenic strain of Arabidopsis thaliana (L.) Heynh, derived by the use of a previously described transposon-tagging system. In strain #1-35-38, expression of the marker gene was tissue-specific, being restricted to stipules and the toothed margins of laminae. Using this transgenic marker gene, we examined the development of leaf blade margins in Arabidopsis. We compared the pattern of expression of the marker gene in the leaves of the wild-type plant with that in plants carrying the asymmetric leaves1 (as1) mutation, which causes dramatic changes in leaf-blade morphology in Arabidopsis. The as1 mutant showed normal morphology of early leaf primordia. The mutation affected the development of leaf segmentation in Arabidopsis without any change in the number or morphology of cells in laminae. The as1 mutation affected leaf morphology independently of mutations in other genes known to affect leaf morphogenesis, such as the acaulis1 mutation and the angustifolia mutation. Based upon these results, the development of the morphology of leaf margins in Arabidopsis is discussed.     

A <Emphasis Type="Italic">Vitis vinifera</Emphasis> xanthine dehydrogenase gene, <Emphasis Type="Italic">VvXDH</Emphasis>, enhances salinity tolerance in transgenic <Emphasis Type="Italic">Arabidopsis</Emphasis>

Xanthine dehydrogenase (EC1.1.1.204; XDH) plays an important role in purine catabolism that catalyzes the oxidative hydroxylation of hypoxanthine to xanthine and of xanthine to uric acid. Long attributed to its role in recycling and remobilization of nitrogen, recently, XDH is implicated in plant stress responses and acclimation, such research efforts, however, have thus far been restricted to Arabidopsis XDH-knockdown/knockout studies. This study, using an ectopic overexpression approach, is expected to provide novel findings. In this study, a XDH gene from Vitis vinifera, named VvXDH, was synthesized and overexpressed in Arabidopsis, the transgenic Arabidopsis showed enhanced salt tolerance. The VvXDH gene was investigated and the results demonstrated the explicit role of VvXDH in conferring salt stress by increasing allantoin accumulation and activating ABA signaling pathway, enhancing ROS scavenging in transgenic Arabidopsis. In addition, the water loss and chlorophyll content loss were reduced in transgenic plants; the transgenic plants showed higher proline level and lower MDA content than that of wild-type Arabidopsis, respectively. In conclusion, the VvXDH gene has the potential to be applied in increasing allantoin accumulation and enhancing the tolerance to abiotic stresses in Arabidopsis and other plants.     

Overexpression of a <Emphasis Type="Italic">Panax ginseng</Emphasis> tonoplast aquaporin alters salt tolerance,drought tolerance and cold acclimation ability in transgenic <Emphasis Type="Italic">Arabidopsis</Emphasis> plants

Water movement across cellular membranes is regulated largely by a family of water channel proteins called aquaporins (AQPs). Since several abiotic stresses such as, drought, salinity and freezing, manifest themselves via altering water status of plant cells and are linked by the fact that they all result in cellular dehydration, we overexpressed an AQP (tonoplast intrinsic protein) from Panax ginseng, PgTIP1, in transgenic Arabidopsis thaliana plants to test its role in plant’s response to drought, salinity and cold acclimation (induced freezing tolerance). Under favorable conditions, PgTIP1 overexpression significantly increased plant growth as determined by the biomass production, and leaf and root morphology. PgTIP1 overexpression had beneficial effect on salt-stress tolerance as indicated by superior growth status and seed germination of transgenic plants under salt stress; shoots of salt-stressed transgenic plants also accumulated greater amounts of Na⁺ compared to wild-type plants. Whereas PgTIP1 overexpression diminished the water-deficit tolerance of plants grown in shallow (10 cm deep) pots, the transgenic plants were significantly more tolerant to water stress when grown in 45 cm deep pots. The rationale for this contrasting response, apparently, comes from the differences in the root morphology and leaf water channel activity (speed of dehydration/rehydration) between the transgenic and wild-type plants. Plants overexpressed with PgTIP1 exhibited lower (relative to wild-type control) cold acclimation ability; however, this response was independent of cold-regulated gene expression. Our results demonstrate a significant function of PgTIP1 in growth and development of plant cells, and suggest that the water movement across tonoplast (via AQP) represents a rate-limiting factor for plant vigor under favorable growth conditions and also significantly affect responses of plant to drought, salt and cold stresses.     

海岛棉GbHCT13基因的功能验证

该研究利用海岛棉‘新海21’和陆地棉ND203以及模式植物拟南芥,通过转基因及荧光定量检测等方法探究海岛棉GbHCT13基因(GenBank 登录号MW048849)在纤维发育中的功能。结果显示：(1)成功构建重组载体pCAMBIA3301 GbHCT13,经农杆菌介导法转化、除草剂抗性基因筛选、荧光定量检测方法鉴定获得转GbHCT13基因拟南芥T₃代植株4株;qRT PCR检测表明,转基因植株中GbHCT13基因表达量较野生型极显著增加。(2)转基因拟南芥过表达GbHCT13基因使植株同一时期的生长较野生型旺盛,株形、叶片数、抽薹数和茎秆表皮毛数量均与野生型存在差异;组织化学分析发现,转GbHCT13基因的拟南芥较野生型茎秆初生木质部生长活跃,导管增粗,次生木质部导管细胞壁横截面积变大,但髓质细胞无明显变化;过表达GbHCT13使拟南芥中木质素合成途径基因发生不同程度改变,其中CAD、CCoAOMT、PAL和4CL与GbHCT13基因的表达呈正相关。(3)经大田筛选、分子鉴定,成功获得转GbHCT13基因棉花植株3株;转GbHCT13基因棉花的棉纤维伸长率增加,纤维强度增大;沉默GbHCT13基因使棉花植株木质素含量降低,茎秆表皮毛数量减少,木质部导管细胞数量减少,导管细胞壁中木质素沉积量降低,而棉株并未发生株高上的明显矮化现象,且木质素合成通路中的CAD、CCoAOMT、CCR、PAL 4个基因的表达均呈降低趋势,说明抑制GbHCT13使得棉花生长代谢受阻,影响纤维发育起始。研究表明,GbHCT13基因能影响棉花植株中木质素合成从而调控纤维的生长发育,其功能与GbHCT13基因在模式植物拟南芥中的基本一致。     

Identification of an Arabidopsis Nodulin-related protein in heat stress

We identified a Nodulin-related protein 1 (NRP1) encoded by At2g03440, which was previously reported to be RPS2 interacting protein in yeast-two-hybrid assay. Northern blotting showed that AtNRP1 expression was suppressed by heat stress (42°C) and induced by low temperature (4°C) treatment. Strong GUS staining was observed in the sites of meristematic tissues of pAtNRP1:: GUS transgenic plants, such as shoot apex and root tips, young leaf veins, stamens and stigmas of flowers, and abscission layers of young siliques. To study AtNRP1 biological functions, we have characterized both loss-of-function T-DNA insertion and transgenic overexpression plants for AtNRP1 in Arabidopsis. The T-DNA insertion mutants displayed no obvious difference as compared to wild-type Arabidopsis under heat stress, but the significant enhanced susceptibility to heat stress was revealed in two independent AtNRP1-overexpressing transgenic lines. Further study found that the decreased thermtolerance in AtNRP1-overexpressing lines accompanied significantly decreased accumulation of ABA after heat treatment, which was probably due to AtNRP1 playing a role in negative-feedback regulation of the ABA synthesis pathway. These results support the viewpoint that the application of ABA inhibits nodulation and nodulin-related gene expression and threaten adverse ambient temperature can impact the nodulin-related gene expression.     

Overexpression of the downward leaf curling (DLC) gene from melon changes leaf morphology by controlling cell size and shape in Arabidopsis leaves

A plant-specific gene was cloned from melon fruit. This gene was named downward leaf curling (CmDLC) based on the phenotype of transgenic Arabidopsis plants overexpressing the gene. This expression level of this gene was especially upregulated during melon fruit enlargement. Overexpression of CmDLC in Arabidopsis resulted in dwarfism and narrow, epinastically curled leaves. These phenotypes were found to be caused by a reduction in cell number and cell size on the adaxial and abaxial sides of the epidermis, with a greater reduction on the abaxial side of the leaves. These phenotypic characteristics, combined with the more wavy morphology of epidermal cells in overexpression lines, indicate that CmDLC overexpression affects cell elongation and cell morphology. To investigate intracellular protein localization, a CmDLC-GFP fusion protein was made and expressed in onion epidermal cells. This protein was observed to be preferentially localized close to the cell membrane. Thus, we report here a new plant-specific gene that is localized to the cell membrane and that controls leaf cell number, size and morphology.     

Overexpression of Arabidopsis Molybdenum Cofactor Sulfurase Gene Confers Drought Tolerance in Maize (Zea mays L.)

Abscisic acid (ABA) is a key component of the signaling system that integrates plant adaptive responses to abiotic stress. Overexpression of Arabidopsis molybdenum cofactor sulfurase gene (LOS5) in maize markedly enhanced the expression of ZmAO and aldehyde oxidase (AO) activity, leading to ABA accumulation and increased drought tolerance. Transgenic maize (Zea mays L.) exhibited the expected reductions in stomatal aperture, which led to decreased water loss and maintenance of higher relative water content (RWC) and leaf water potential. Also, transgenic maize subjected to drought treatment exhibited lower leaf wilting, electrolyte leakage, malondialdehyde (MDA) and H₂O₂ content, and higher activities of antioxidative enzymes and proline content compared to wild-type (WT) maize. Moreover, overexpression of LOS5 enhanced the expression of stress-regulated genes such as Rad 17, NCED1, CAT1, and ZmP5CS1 under drought stress conditions, and increased root system development and biomass yield after re-watering. The increased drought tolerance in transgenic plants was associated with ABA accumulation via activated AO and expression of stress-related gene via ABA induction, which sequentially induced a set of favorable stress-related physiological and biochemical responses.