Oxidative stress tolerance and longevity in Arabidopsis: the late‐flowering mutant gigantea is tolerant to paraquat

Recent genetic analyses of longevity in animals have revealed that long-lived strains are more tolerant to environmental stresses. To investigate whether extended longevity in Arabidopsis also correlates with an increase in stress tolerance, the response was tested of 11 late-flowering mutants to the superoxide radical-generating herbicide paraquat. A tight correlation between flowering time and paraquat tolerance was found when plants were exposed to low doses of herbicide. Furthermore, the mutant gigantea (gi-3) with the longest delay in flowering time had a high tolerance level to paraquat-induced oxidative stress. All the tested gi alleles had an increased tolerance to paraquat toxicity compared to wild-type, although the actual levels of tolerance differed. In addition, the gi-3 mutant was more tolerant to hydrogen peroxide. These results suggest that the link between longevity and oxidative stress resistance in plants is similar to that found in animals, implying that this phenomenon may be general for all aerobic organisms.     

Flowering of Arabidopsis cop1 mutants in darkness

To elucidate the role of the COP1 gene in flowering, we analyzed flowering of cop1 mutant lines in darkness. When grown in the presence of 1% (w/v) sucrose, the cop1-6 mutant flowered in darkness, but cop1-1 and cop1-4 did not. However, cop1-1 and cop1-4 flowered in darkness when grown in the presence of 5% (w/v) sucrose. Therefore, the COP1 gene represses not only photomorphogenesis in seedlings but also flowering in darkness. Comparison of mRNAs levels of floral identity genes in cop1-6 and wild-type plants grown in darkness revealed increased mRNA levels of genes that act downstream of CO and reduced FLC mRNA level in cop1-6. Double mutants of cop1-6 and each of the late-flowering mutations cry2-1, gi-2, co-1, and ld-1 flowered in darkness. All of the double mutants except cry2-1 cop1-6 flowered later than cop1-6, demonstrating that cop1-6 is epistatic to cry2-1 for early flowering. The ld-1 cop1-6 double mutant flowered much earlier than the ld-1 mutant. The delay in flowering in the double mutants was not strongly influenced by the light conditions, whereas that of the gi-2 cop1-6 double mutant was reduced in darkness.     

Late-flowering genes interact with early-flowering genes to regulate flowering time in Arabidopsis thaliana.

To investigate the genetic mechanisms regulating the transition from the vegetative to reproductive growth in Arabidopsis, double mutants between three different early-flowering mutants, early flowering 1-1, 2-1, 3-1, (elf 1-1, 2-1, 3-1) and five different late-flowering mutants, gi-1, ft-1, fwa-1, ld-1, and fca-9, were constructed and phenotypes analyzed. Double mutants in all combinations displayed the late-flowering phenotypes which resembled their respective late-flowering parents in both flowering time and the number of vegetative leaves produced. The results indicate that five late-flowering mutants are epistatic to all three early-flowering mutants tested here. This epistatic relationship suggests that ELF1, ELF2, and ELF3 genes function upstream of these five late-flowering genes no matter if they are functioning in autonomous or photoperiod pathways. These three early-flowering genes may negatively modify the activity of most late-flowering genes to influence the time of the vegetative-to-reproductive transition in Arabidopsis.     

Polyamines and Paraquat Toxicity in Arabidopsis thaliana

The relationship between paraquat toxicity and polyamine levelswas analyzed in Arabidopsis wild-type and gi-3 plants. Paraquattreatment led to an increase in putrescine, but not of spermidineand spermine content. Additionally, polyamine feeding offeredhigh levels of protection against paraquat toxicity with spermidinebeing the most effective protectant. (Received March 24, 1998; Accepted June 17, 1998)     

Hormone physiology of pea mutants prevented from flowering by mutations gi or veg1

The veg1 ( vegetative ) mutant in pea ( Pisum sativum L.) does not flower under any circumstances and gi ( gigas ) mutants remain vegetative under certain conditions. gi plants are deficient in production of floral stimulus, whereas veg1 plants lack a response to floral stimulus. During long days in particular, these non-flowering mutant plants eventually enter a stable compact phase characterised by a large reduction in internode length, small leaves and growth of lateral shoots from the upper-stem (aerial) nodes. The first-order laterals in turn produce second-order laterals and so on in a reiterative pattern. The apical bud is reduced in size but continues active growth. Endogenous hormone measurements and gibberellin application studies with gi-1 , gi-2 and veg1 plants indicate that a reduction in gibberellin and perhaps indole-3-acetic acid level may account, at least partially, for the compact aerial shoot phenotype. In the gi-1 mutant, the compact phenotype is rescued by transfer from a 24- to an 8-h photoperiod. We propose that in plants where flowering is prevented by a lack of floral stimulus or an inability to respond, the large reduction in photoperiod gene activity during long days may lead to a reduction in apical sink strength that is manifest in an altered hormone profile and weak apical dominance.     

Sucrose Phosphate Synthase, Sucrose Synthase, and Invertase Activities in Developing Fruit of Lycopersicon esculentum Mill. and the Sucrose Accumulating Lycopersicon hirsutum Humb. and Bonpl

The green-fruited Lycopersicon hirsutum Humb. and Bonpl. accumulated sucrose to concentrations of about 118 micromoles per gram fresh weight during the final stages of development. In comparison, Lycopersicon esculentum Mill. cultivars contained less than 15 micromoles per gram fresh weight of sucrose at the ripe stage. Glucose and fructose levels remained relatively constant throughout development in L. hirsutum at 22 to 50 micromoles per gram fresh weight each. Starch content was low even at early stages of development, and declined further with development. Soluble acid invertase (EC 3.2. 1.26) activity declined concomitant with the rise in sucrose content. Acid invertase activity, which was solubilized in 1 molar NaCl (presumably cell-wall bound), remained constant throughout development (about 3 micromoles of reducing sugars (per gram fresh weight) per hour. Sucrose phosphate synthase (EC 2.4.1.14) activity was present at about 5 micromoles of sucrose (per gram fresh weight) per hour even at early stages of development, and increased sharply to about 40 micromoles of sucrose (per gram fresh weight) per hour at the final stages of development studied, parallel to the rise in sucrose content. In comparison, sucrose phosphate synthase activity in L. esculentum remained low throughout development. The possible roles of the sucrose metabolizing enzymes in determining sucrose accumulation are discussed.     

Monogenic Recessive Mutations Causing Both Late Floral Initiation and Excess Starch Accumulation in Arabidopsis

A recessive Arabidopsis mutation, carbohydrate accumulation mutant1 (cam1), which maps to position 22.8 on chromosome 3, was identified by screening leaves of ethyl methanesulfonate-mutagenized M2 plants stained with iodine for altered starch content. Increased starch content in leaves of the cam1 mutant was observed at the onset of flowering. This mutant also had a delayed floral initiation phenotype with more rosette leaves than the parental line. In addition, activities of several enzymes associated with starch metabolism were altered in the cam1 mutant. The late-flowering mutant gigantea (gi) also manifested an elevated starch level in leaves. However, not all late-flowering mutants had increased leaf starch content. Double mutants cam1 adg1 (for ADP-glucose pyrophosphorylase), cam1 pgm (for phosphoglucomutase), and gi pgm had no observable starch in leaves but showed the late-flowering phenotype, demonstrating that the elevated starch content is not the cause of late floral initiation. The pleiotropic effects of cam1 and gi suggest that they may play regulatory roles in starch metabolism and floral initiation. These data suggest that starch accumulation and floral initiation may share a common regulatory pathway.     

An analysis of seed development in Pisum sativum. VII. Embryo development and precocious germination in vitro

Three different culture media have been examined for their ability to support growth in culture of embryos of two pea lines near-isogenic except for the r-locus. Embryos showed a greater increase in fresh weight on a medium containing 10% sucrose and a high level of a mixture of amino acids than on either one containing an equivalent amount of glutamine as the sole nitrogen source or one containing both inorganic nitrogen and a low level of glutamine. Small embryos (up to 10 mg fresh weight) showed the greatest relative increase in fresh weight. Decreasing the osmotic pressure of an agar medium by lowering the sucrose content to 2% and reducing the concentration of amino acids induced precocious germination. Shoot growth was more sensitive than root growth to increasing sucrose concentrations and optimum development was obtained when embryos were cultured in liquid culture at a high osmotic pressure followed by growth on an agar medium at low osmotic pressure. Alternatively, precocious germination could be induced by removing the cotyledons. Embryos of all sizes and of both genotypes of pea responded in a similar manner.     

The Role of GIGANTEA Gene in Mediating the Oxidative Stress Response and in Arabidopsis

The Arabidopsis GIGANTEA (GI) gene has been shown to be involved in the regulation of the oxidative stress response; however, little is known about the mechanism by which GI gene regulates the oxidative stress response. We show here that enhanced tolerance of the gi-3 mutant to oxidative stress is associated, at least in part, with constitutive activation of superoxide dismutase (SOD) and ascorbate peroxidase (APX) genes. The gi-3 plants were more tolerant to parquart (PQ) or hydrogen peroxide (H₂O₂)-mediated oxidative stress than wild-type plants. Analyses of concentrations of endogenous H₂O₂ and superoxide anion radicals as well as lipid peroxidation revealed that enhanced tolerance of gi-3 plants to oxidative stress was not due to defects in the uptake of PQ or the sequestration of PQ from its site of action, and that the gi-3 mutation alleviated oxidative damage of plant cells from PQ stress. Moreover, the gi-3 mutant showed constitutive activation of cytosolic Cu/ZnSOD and plastidic FeSOD as well as cytosolic APX1 and stromal APX genes, which at least in part contributed to constitutive increases in activities of anti-oxidative enzymes SOD and APX, respectively. To our knowledge, we demonstrate, for the first time, that GI gene regulates the oxidative stress response, at least in part, through modulation of SOD and APX genes.     

超大型烟草突变株的生理生化特征和分子生物学鉴定

超大型烟草突变株再生植株高度是野生型的2．2倍,叶片数是野生型的3．3倍,呈现晚花发育特征;叶片气孔保卫细胞中叶绿体数是野生型的1．3倍,叶绿素a、b和叶绿素总量均高于野生型,可溶性蛋白质含量是野生型的1．18倍,过氧化物酶、细胞色素氧化酶同工酶电泳图谱上有一定差异;可溶性蛋白SDS-PAGE电泳图谱上比野生型少4条谱带;RAPD结果表明突变体在DNA水平上确实发生了变化,DDRT-PCR结果显示出两者在基因表达上有差异。突变株再生植株可以开花结实,植株高大、叶数多,晚花的特征可以稳定遗传。     

Effects of sucrose on betacyanin accumulation and growth in suspension cultures of Phytolacca americana

The effects of sucrose on betacyanin accumulation and growth in suspension cultures of Phytolacca americana L. were investigated. Maximal betacyanin accumulation was observed at 88 m M sucrose on cell number basis and at 175 m M sucrose on fresh weight basis. This is because cell size decreased as the initial sucrose concentration was increased. Supplementary studies using mannitol indicated that sucrose itself caused increased cell number and that cell size was affected by both sucrose concentration and water potential. Betacyanin accumulation per cell and per fresh weight at a constant concentration of sucrose (88 m M ) decreased with decreasing water potential. When sucrose concentration increased at a constant water potential (–0.7 MPa), betacyanin accumulation per fresh weight increased up to 88 m M and remained at constant level at higher concentrations, while betacyanin accumulation per cell decreased remarkably, due to a dramatic increase in cell number.     

茄子幼苗耐低温性生理机制研究

选择耐低温性不同的6份茄子高代自交系幼苗为材料,进行白天10℃/夜间7℃低温处理10d,调查其耐低温性、生长指标(株高、茎粗、鲜重、干重)、生理指标(POD、SOD、APX活性及脯氨酸含量),以探讨低温对茄子幼苗生长过程中的生长和生理指标的影响.结果显示:(1)各材料的上述性状在常温下均差异不显著,而在低温处理下差异极显著;与对照相比较,幼苗株高、茎粗、鲜重和干重下降,而POD、SOD、APX活性及脯氨酸含量上升.(2)各材料指标的升降幅度与其低温耐受性密切相关,耐低温性强的材料生长指标下降幅度较小,而生理指标提高幅度较大,耐低温性弱的材料则表现相反.(3)各指标间相比较,茄子耐低温性与株高、茎粗、干重、POD活性、SOD活性呈显著正相关,与其余性状的相关未达显著水平.研究表明,低温使茄子幼苗的生长受到一定程度的抑制,但耐低温材料能够通过调节自身的保护酶系统活性来减轻低温的伤害,维持植物体的正常生长及生理代谢功能.     

Changes in oligosaccharide content and antioxidant enzyme activities in developing bean seeds as related to acquisition of drying tolerance and seed quality.

Seeds of bean (Phaseolus vulgaris cv. Vernel) were collected throughout their development on the plant and dried at 15 degrees C and 75% relative humidity to a final moisture content of about 16% (fresh weight basis) to determine whether the onset of tolerance to this drying condition was related to changes in soluble sugars or the activities of the main antioxidant enzymes, namely superoxide dismutase (SOD), catalase (CAT), ascorbate peroxidase (APX), and glutathione reductase (GR). Measurements of soluble sugars and enzyme activities were made after drying the seeds, and drying tolerance was evaluated by the ability of dried seeds to germinate and to produce normal seedlings. Seeds became tolerant to drying at 45 d after anthesis, a time marking physiological maturity. At physiological maturity, the moisture content of seeds was about 50-55% (fresh weight basis) and seed dry matter reached about 190 mg per seed. Seed vigour, evaluated by controlled deterioration and conductivity measurements, continued to increase after seed mass maturity, but decreased when seeds remained thereafter for more than 7 d on the plant. Acquisition of drying tolerance was coincident with an accumulation of raffinose and stachyose. Dried-tolerant seeds were also characterized by a high amount of sucrose, the most abundant sugar, and by a low content of monosaccharides. The (raffinose+stachyose)/sucrose ratio increased during seed filling, reaching a value close to 1 when all the seeds became tolerant to drying, and maintaining this proportion during the final stages of maturation. Acquisition of drying tolerance was also related to a reorientation of the enzymatic antioxidant defence system. Drying-tolerant dried seeds displayed high CAT and GR activities and low SOD and APX activities, while the opposite condition was observed in immature dried seeds. The shift in antioxidant enzymes corresponded to the beginning of the maturation-drying phase. These results suggest that oligosaccharide metabolism and enzymatic antioxidant defences may be involved in acquisition of drying tolerance during bean seed development, but are not related to seed vigour.     

Compartmentation Analysis of Paraquat Fluxes in Maize Roots as a Means of Estimating the Rate of Vacuolar Accumulation and Translocation to Shoots

Efflux analysis conducted after five loading periods of various lengths (2, 6, 12, 18, or 24 h) was used to investigate uptake, compartmentation, and translocation of [14C]paraquat in maize (Zea mays L.) seedlings. The time course for net paraquat uptake (paraquat concentration in uptake solution = 25[mu]M) into maize roots was linear (56.7 nmol g-1 root fresh weight h-1) for 24 h. Estimates of changes in paraquat content in the vacuole, cytoplasm, and cell wall after 2-, 6-, 12-, 18-, and 24-h loading periods indicated that the cell wall saturated rapidly, whereas accumulation of paraquat into the vacuole increased linearly (12.4 nmol g-1 root fresh weight h-1) over 24 h. In contrast to vacuolar accumulation, cytoplasmic paraquat content appeared to approach saturation. The half-time for paraquat efflux from the cell wall (16.6 min [plus or minus] 1.2 SD) and cytoplasm (58.8 min [plus or minus] 8.9 SD remained relatively constant regardless of the length of the loading period, whereas the half-time for efflux from the vacuole was considerably longer and increased linearly with increased loading time (6.1-18.7 h). The time course for paraquat translocation to the shoot was linear within a 24-h exposure to radiolabeled herbicide, but translocation did not begin until 5 h after initiation of treatment. The experimental approach used in these experiments provides a valuable method for examining the movement of paraquat in maize seedlings. Results indicate that the herbicide slowly accumulates in the vacuole of root cells but is also translocated to the shoot.     

Further studies on the photosynthesis of carrot tissue cultures

The influence of kinetin and sucrose on the photosynthetic activity of carrot (Daucus carota) tissue cultures in relation to growth was investigated. The results showed that light contributes heavily to the growth of tissue cultures measured in terms of fresh and dry weight and cell division activity. In light, the fresh weight, dry weight, and number of cells per explant were about or more than doubled. This indicated that after the development of chloroplasts, carrot tissue cultures can grow autotrophically at least as far as energy and carbon are concerned. Kinetin was shown to have an important role in developing the photosynthetic apparatus and photosynthetic activity of tissue cultures as manifested by the increase of chlorophyll content (60%), Hill activity (about 3-fold), and ¹⁴C-fixation from NaH¹⁴CO₃ (about 20%). On the other hand, the presence of sucrose in the medium reduced the chlorophyll content by about 30% and ¹⁴C-fixation from NaH¹⁴CO₃ in the soluble fraction by about 60%. A possible correlation between the influence of kinetin on sugar uptake and the effect of kinetin on ¹⁴C-fixation from NaH¹⁴CO₃ was discussed.     

Solute Accumulation and Compartmentation during the Cold Acclimation of Puma Rye

During cold acclimation of Puma rye (Secale cereale L. cv Puma), the intracellular osmotic potential nearly doubles. During this period, the accumulation of glycinebetaine, proline, and soluble sugars was monitored. The amount of glycinebetaine increased from 290 to 1300 micrograms per gram fresh weight during the 4-week acclimation period. Proline content did not change during the first 3 weeks of acclimation but then increased from 27 to 580 micrograms per gram fresh weight during the next 3 weeks. The total soluble sugar content more than doubled by the second week of cold acclimation, increasing from 11 to 26 milligrams per gram fresh weight. Most of this increase can be attributed to the accumulation of sucrose and raffinose, whose levels increased from 2.4 and 0 to 11 and 5 milligrams per gram fresh weight, respectively. The content of monosaccharides, predominantly glucose, remained at a constant 10 milligrams per gram fresh weight throughout the acclimation period. A comparison of the sugar content of protoplasts versus vacuoles isolated from cold-acclimated leaves revealed that the extravacuolar volume contained monosaccharides, sucrose, and raffinose. Thus, the increased amounts of sucrose and raffinose that occur during cold acclimation are present in compartments external to the vacuole and may contribute to cryoprotection.     

Polyamines reduce paraquat-induced soxS and its regulon expression in Escherichia coli

Polyamines, ubiquitous polycationic compounds, are involved in many cellular responses and relieve paraquat-induced cytotoxicity inEscherichia coli. We constructed a newE. coli mutant strain, JIL528, which is deficient in the biosynthesis of both putrescine and spermidine, to examine the physiological role of polyamines under oxidative stress caused by paraquat. Putrescine and spermidine downregulate the expression ofsoxS induced by paraquat in a concentration-dependent manner. The product of SoxS is a key regulator governing cellular responses against oxidative stress inE. coli. The downregulation ofsoxS expression by polyamines was not shown in thesoxR mutant background. Glucose-6-phosphate dehydrogenase (G6PDH; encoded byzwf) and manganese-containing superoxide dismutase (Mn-SOD; encoded bysodA) activities induced by paraquat were decreased by exogenous polyamines. The induction of thezwf expression by paraquat was also decreased by exogenous polyamines. The polyamine-deficient mutant strain JIL528 showed a highersoxS expression than its parent polyamine-proficient wild type BW1157, on exogenous supplementation of paraquat concentrations below 1 mol/L. While the growth rate of the mutant was decreased,soxS expression was increased in a concentration-dependent manner above 0.01 mol/L of paraquat. In contrast, growth inhibition of the mutant by paraquat was relieved, andsoxS was no longer induced by exogenous putrescine (1 mmol/L). In conclusion, polyamines protect against paraquat-induced toxicity but downregulatesoxS expression, suggesting that the protective role of polyamines against oxidative damage induced by paraquat results insoxS downregulation.     

The role of the hexose transporter in the chloroplasts of Arabidopsis thaliana L.

The metabolism of wild-type Arabidopsis thaliana L. and its mutant TC265 were compared in order to reveal the role of the chloroplast glucose transporter. Plants were grown in a 12-h photoperiod. From 20 to 40 days after germination, starch per gram fresh weight of shoot in the mutant was four times that in the wild type. The extent of this difference did not alter during this period. Stereological analysis showed that the chloroplasts in the mutant were larger than those in the wild type; the thylakoids appeared to be distorted by the high starch content. [U-¹⁴C]Glucose and [U-¹⁴C]glycerol were supplied, separately, to excised leaves in the dark. [U-¹⁴C]Glucose was a good precursor of sucrose in the wild type and mutant; [U-¹⁴C]glycerol was a poor precursor of sucrose in both. The distribution of ¹⁴C in the wild type was used to calculate that the net flux was from hexose monophosphates to triose phosphates, not vice versa. During the first 4 h of the night the sugar content (75% sucrose, 20% glucose) of the leaves of the mutant dropped sharply, and at all times during the night it was less than that of the wild-type leaves. This drop in sugar coincided with a decrease in the rate of respiration. The growth rate of the mutant was less than that of the wild type. Addition of sucrose restored the rate of respiration at night and increased the rate of growth. It is argued that a major function of the glucose transporter in Arabidopsis chloroplasts is export of the products of starch breakdown that are destined for sucrose synthesis at night.We thank Professor C.R. Somerville for his generous gift of seed of the Arabidopsis mutant TC265. We are also grateful to Mr B. Chapman for assistance with the preparation of the sections for electron microscopy. R.N.T. thanks the Science and Engineering Research Council for a studentship.