光质对韭菜碳氮代谢、生长和品质的影响

以‘平韭2号’为试材,以白光(W)处理为对照(CK),研究白+红(WR)、白+蓝(WB)、白+绿(WG)、白+紫(WP)4种不同光质处理对韭菜碳氮代谢、生长和品质的影响.结果表明: WR处理韭菜的光合速率(P_n)显著高于CK,而WB、WG和WP与CK无显著差异,但RuBP羧化酶(RuBPCase)活性均显著高于CK.各处理相比,总糖含量以WR最高,WP其次,WB和WG最低.WR下韭菜蔗糖磷酸合成酶(SPS)活性显著高于CK,其余三者均显著低于CK,其中以WB最低,但蔗糖合成酶(SS)和淀粉酶(AMS)活性均以WB最高,WR最低,WG和WP的SS活性与CK无差异,但AMS活性显著低于CK.可见,增加红、紫光比例可促进韭菜碳的同化和转化,加速糖的积累.总氮、蛋白氮含量、硝酸还原酶(NR)、谷氨酰胺酶(GS)和谷氨酸合成酶(GOGAT)活性以WB最高,显著高于CK,但WB下谷氨酸脱氢酶(GDH)活性最低,显著低于CK;WR的蛋白氮和非蛋白氮含量、NR和GS活性最低,显著低于CK,GOGAT和GDH活性显著高于CK,且GDH在所有处理中最高;WG的全氮、非蛋白氮含量及GDH活性均显著低于CK,但蛋白氮含量、NR和GOGAT活性显著高于CK,WP的氮含量及相关酶活性呈现出与WG相同的趋势,且GS活性亦同样高于CK.说明增加蓝光、紫光和绿光可使韭菜氮代谢增强,而增加红光对蛋白质的合成有一定的抑制作用.红光和紫光下韭菜生长较好,而蓝光则抑制其加粗生长,叶片较薄,单株生长量较低.紫光下韭菜的粗纤维含量最低,营养品质最优,因此,紫光对韭菜的生长最有利.     

川西平原五种水旱轮作模式旱作季杂草群落特征

为明确不同水旱轮作模式对川西平原旱作季杂草群落特征的影响,从而为旱作季杂草的高效防控提供理论依据。基于大蒜-水稻(GR)、小麦-水稻(WR)、蚕豆-水稻(BR)、油菜-水稻(RR)和马铃薯-水稻(PR)五种水旱轮作的长期定位试验,在2022年旱季采用生态学方法探究了不同水旱轮作模式下旱作季农田杂草种类、密度、株高、生物量等杂草群落结构和物种多样性特征。结果表明:(1)五种轮作模式下杂草田间密度表现为WR>BR>RR>GR>PR,生物量表现为WR>BR>GR>RR>PR,物种多样性表现为GR>BR>RR>PR>WR,物种均匀度表现为GR>PR>BR>RR>WR,群落优势度表现为WR>PR>RR>BR>GR,表明GR杂草群落稳定性最高,WR杂草群落稳定性最低且优势物种发生危害的程度最高,RR的杂草种类数少且不易发生危害;(2)五种水旱轮作模式杂草群落相似性较高,相似性指数在0.69-0.84之间,WR杂草生活型以一年生单子叶杂草为主,其余四种模式以一年生双子叶杂草为主;(3)WR优势杂草种类最少,为禾本科棒头草(Polypogon fugax Nees ex Steud),其重要值为59.53%;BR优势杂草种类最多,为棒头草、蔊菜(Rorippa indica (L.) Hiern)、毛茛(Ranunculus japonicus Thunb)和通泉草(Mazus japonicus (Thunb.) O. Kuntze);GR优势杂草为苣荬菜(Sonchus wightianus DC)和猪殃殃(Galium spurium L); RR和PR优势杂草均为三种,都包括为棒头草和蔊菜。因此,以确保旱作季杂草能得到有效控制,不同水旱轮作模式应制定不同的杂草防控措施。GR和PR应重点控制以猪殃殃为代表的双子叶杂草,WR应着重控制以棒头草等为代表的单子叶杂草,BR和RR应注重繁殖力强的单双子叶杂草的综合防治。     

Hydrogen production by Anabaena variabilis PK84 under simulated outdoor conditions

Hydrogen production by autotrophic, vanadium-grown cells of Anabaena variabilis PK84, a cyanobacterial mutant impaired in the utilization of molecular hydrogen, has been studied under simulated outdoor conditions. The cyanobacterium was cultivated in an automated helical tubular photobioreactor (4.35 L) under air containing 2% CO(2), with alternating 12-h light (36 degrees C) and 12-h dark (14 degrees to 30 degrees C) periods. A. variabilis steadily produced H(2) directly in the photobioreactor during continuous cultivation for 2.5 months. The maximum H(2) production by the continuously aerated culture under light of 332 microE. s(-1). m(-2) was 230 mL per 12-h light period per photobioreactor and was observed at a growth density corresponding to 3.6 to 4.6 microgram Chl a. mL(-1) (1.2 to 1.6 mg dry weight. mL(-1)). Replacement of air with an argon atmosphere enhanced H(2) evolution by a factor of 2. This stimulatory effect was caused mainly by N(2) deprivation in the cell suspension. A short-term decrease of the CO(2) concentration in the air suppressed H(2) evolution. Anoxygenic conditions over the dark periods had a negative effect on H(2) production. The peculiarity of hydrogen production and some physiological characteristics of A. variabilis PK84 during cultivation in the photobioreactor under a light-dark regime are investigated.     

Photochemical Properties of Photosystem 2 in Primary Leaves of Barley Seedlings Grown Under Various Blue or Red Irradiances

Photosystem 2 (PS2)-driven electron transfer was studied in primary leaves of barley (Hordeum vulgare L.) seedlings grown under various photon fluxes (0.3–170.0 mol m^–2 s^–1) of blue (BR) or red (RR) radiation using modulated chlorophyll fluorescence. The F_v/F_m ratio was 0.78–0.79 in leaves of all radiation variants, except in seedlings grown under BR or RR of 0.3 mol m^–2 s^–1. The extent of the photochemical phase of the polyphasic F_v rise induced by very strong white light was similar in leaves of all radiation treatments. Neither radiation quality nor photon flux under plant cultivation influenced the amount of non Q_B-transferring centres of PS2 except in leaves of seedlings grown under BR of 0.3 mol m^–2 s^–1, in which the amount of such centres increased threefold. Both BR and RR stimulated the development of photochemically competent PS2 at photon fluxes as low as 3 mol m^–2 s^–1. Three exponential components with highly different half times were distinguished in the kinetics of F_v dark decay. This indicates different pathways of electron transfer from Q_A ^–, the reduced primary acceptor of PS2, to other acceptors. Relative magnitudes of the individual decay components did not depend on the radiation quality or the photon flux during plant cultivation. Significant differences were found, however, between plants grown under BR or RR in the rate of the middle and fast components of F_v dark decay, which showed 1.5-times faster intersystem linear electron transport in BR-grown leaves.     

杨树人工林根际古菌群落随细根生长的演变

研究细根不同生长时期根际土壤古菌群落组成结构差异,对深入了解林木细根与土壤微生物互作关系具有重要理论意义.依据细根表面颜色,采集杨树一级细根不同生长时期(白色新生根、黄色成熟根、褐色衰老根)根际土壤并提取微生物总DNA,采用特异性引物对古菌16S rDNA V4-V5区进行扩增,利用Illumina MiSeq平台进行古菌高通量测序分析.结果表明: 新生根和衰老根根际土壤古菌群落操作分类单元(OTU)丰富度相似,而成熟根根际土壤古菌群落OTU数量较少.新生根和成熟根根际土壤共同含有134个OTU;成熟根和衰老根根际土壤共同含有87个OTU,新生根和衰老根根际土壤共同拥有90个OTU.α多样性分析表明,成熟根根际土壤古菌群落Chao1指数和ACE指数显著低于新生根和衰老根根际土壤,而衰老根根际土壤古菌群落Simpson指数和Shannon指数显著低于新生根和成熟根根际土壤.PERMANOVA分析表明,新生根和衰老根根际土壤古菌群落组成有显著差异.物种注释显示,杨树根际土壤共包含12个古菌属,其中新生根5个、成熟根10个、衰老根6个.β多样性指数表明,杨树根际土壤古菌群落相似度随着细根的生长逐渐下降,不同生长阶段细根根际土壤的古菌群落结构有较大差异.其中,占绝对优势的古菌为氨氧化古菌Candidatus_Nitrososphaera,其相对丰度超过70%.且随细根生长发育,该类古菌在根际土壤中的丰度呈现上升趋势,表明其可能与细根的生长发育关系密切.     

Growth, photosynthesis, nitrogen partitioning and responses to CO2 enrichment in a barley mutant lacking NADH-dependent nitrate reductase activity

Plant growth, photosynthesis and leaf constituents were examined in the wild-type (WT) and mutant nar1 of barley (Hordeum vulgare L. cv. Steptoe) that contains a defective structural gene encoding NADH-dependent nitrate reductase (NADH-NAR). In controlled environment experiments, total biomass, rates of photosynthesis, stomatal conductance, intercellular CO(2) concentrations and foliar non-structural carbohydrate levels were unchanged or differed slightly in the mutant compared with the WT. Both genotypes displayed accelerated plant growth rates when the CO(2) partial pressure was increased from 36 to 98 Pa. Total NADH-NAR activity was 90% lower in the mutant than in the WT, and this was further decreased by CO(2) enrichment in both genotypes. Inorganic nitrate was greater in the mutant than in the WT, whereas in situ nitrate assimilation by excised leaves was two-fold greater for the WT than for the mutant. Foliar ammonia was 50% lower in the mutant than in the WT under ambient CO(2). Ammonia levels in the WT were decreased by about one-half by CO(2) enrichment, whereas ammonia was unaffected by elevated CO(2) in mutant leaves. Total soluble amino acid concentrations in WT and mutant plants grown in the ambient CO(2) treatment were 30.1 and 28.4 micromol g(-1) FW, respectively, when measured at the onset of the light period. Seven of the twelve individual amino acids reported here increased during the first 12 h of light in the ambient CO(2) treatment, leading to a doubling of total soluble amino acids in the WT. The most striking effect of the mutation was to eliminate increases of glutamine, aspartate and alanine during the latter half of the photoperiod in the ambient CO(2) treatment. Growth in elevated CO(2) decreased levels of total soluble amino acids on a diurnal basis in the WT but not in mutant barley leaves. The above results indicated that a defect in NADH-NAR primarily affected nitrogenous leaf constituents in barley. Also, we did not observe synergistic effects of CO(2) enrichment and decreased foliar NADH-NAR activity on most N-containing compounds.     

Influence of Spectral Range and Carbon and Nitrogen Sources on Oxygen Evolution and Emerson Enhancement in Chlamydomonas reinhardtii

Chlamydomonas reinhardtii was grown in medium with different carbon (acetate, CO₂, or both), and nitrogen (ammonium chloride, peptone, urea) sources and under light of different spectral composition. The light-dark cycles were found more suitable for mixotrophic growth than continuous irradiation. Both blue (BR) and red (RR) radiations decreased photosynthetic capacity of mixotrophic cells compared to “white light” (WL). Effect of RR was associated with photon distribution favouring photosystem 1 (PS1) suggesting increased cyclic phosphorylation. Mixotrophic growth in 10 mM NH₄Cl increased photosynthetic oxygen evolution compared to standard concentration of 5 mM NH₄Cl used for growing C. reinhardtii. Autotrophic growth stimulated the photosynthetic capacity compared to mixotrophic one. However, higher photosynthetic capacity was achieved for mixotrophic cells by growing them at high NH₄ ⁺/K⁺ ratio and high phosphate concentration. This revised version was published online in July 2006 with corrections to the Cover Date.     

Properties of mutants of Synechocystis sp. strain PCC 6803 lacking inorganic carbon sequestration systems

A mutant (Delta5) of Synechocystis sp. strain PCC 6803 constructed by inactivating five inorganic carbon sequestration systems did not take up CO(2) or HCO(3)(-) and was unable to grow in air with or without glucose. The Delta4 mutant in which BicA is the only active inorganic carbon sequestration system showed low activity of HCO(3)(-) uptake and grew under these conditions but more slowly than the wild-type strain. The Delta5 mutant required 1.7% CO(2) to attain half the maximal growth rate. Electron transport activity of the mutants was strongly inhibited under high light intensities, with the Delta5 mutant more susceptible to high light than the Delta4 mutant. The results implicated the significance of carbon sequestration in dissipating excess light energy.     

H(2) photoproduction by batch culture of Anabaena variabilis ATCC 29413 and its mutant PK84 in a photobioreactor.

Hydrogen production by Anabaena variabilis ATCC 29413 and of its mutant PK84, grown in batch cultures, was studied in a photobioreactor. The highest volumetric H(2) production rates of native and mutant strains were found in cultures grown at gradually increased irradiation. The native strain evolved H(2) only under an argon atmosphere with the actual rate as high as the potential rate (measured in small vials under optimal conditions). In this case 61% of oxygenic photosynthesis was used for H(2) production. In contrast the mutant PK84 produced H(2) during growth under CO(2)-enriched air. Under these conditions at the maximum rate of H(2) production (10 mL h(-1) L(-1)), 13% of oxygenic photosynthesis was used for H(2) production and the actual H(2) production was only 33% of the potential. Under an atmosphere of 98% argon + 2% CO(2) actual H(2) production by mutant PK84 was 85% of the potential rate and 66% of oxygenic photosynthesis was used for H(2) production. Hydrogen production under argon + CO(2) by the mutant was strictly light-dependent with saturation at about 300 microE m(-2) s(-1). However, the rate of photosynthesis was not saturated at this irradiation. At limiting light intensities (below 250 microE m(-2) s(-1)) 33-58% of photosynthesis was used for H(2) production. Hydrogen evolution by PK84 under air + 2% CO(2) was also stimulated by light; but was not saturated at 332 microE m(-2) s(-1) and did not cease completely in darkness. The rate of oxygen photoevolution was also not saturated. A mechanism for increasing cyanobacterial hydrogen production is proposed.     

Esterase polymorphisms for analysis of genetic diversity and structure of soybean (Glycine max) cultivars

We used native polyacrylamide gel electrophoresis to identify polymorphism levels in α- and β-esterase loci from leaf tissues of Brazilian soybean cultivars for the analysis of population genetic diversity and structure, and to investigate relationships between conventional and genetically modified cultivars. The cultivars included lines developed by a soybean-grower cooperative (CD), by EMBRAPA (BR), and "Roundup Ready" (RR) cultivars. Esterase isozymes recorded with α-naphthyl acetate and β-naphthyl acetate were produced from 14 loci. Two to three allelic variants were detected in leaves from 420 plants of 21 CD, BR, and RR cultivars at Est-1, Est-2, Est-3, Est-5, and Est-14 loci. The estimated proportion of polymorphic loci in CD cultivars was 21.4%, and in BR and RR cultivars it was 28.6%. High and low H(O) and H(E) values were observed within CD and BR cultivars and a very high cultivar differentiation level was evident in the plants of the 21 CD, BR, and RR cultivars (F(ST) = 0.3865). A low level of differentiation (F(ST) = 0.0289) was detected between conventional and RR cultivars. Plants from cultivar BR37 had the highest level of genetic differentiation compared to the other cultivars. The genetic basis of BR cultivars (0.5538-0.9748) was found to be broader than the genetic basis of CD cultivars (0.7058 for CD205 and CD209 and 0.9995 for CD205 and CD208). Higher genetic identity was detected between plants of CD and CDRR cultivars (I = 0.9816). Understanding the genetic structure of these populations can help provide specific culture strategies for each cultivar, depending on its level of heterozygosity.     

A comparative screening of hybrid,modern varieties and local rice cultivar for brown leaf spot disease susceptibility and yield performance

Five rice cultivars, one hybrid (WR96), three modern (BR16, BR26, and BRRI Dhan27) and one local (Pari) were screened for reaction to brown leaf spot disease caused by Cochliobolus miyabeanus and performance of yield-related characters. The severity of brown leaf spot varied with growth stages of rice plant as well as different cultivars tested under field condition. Low disease severity was observed at maximum tillering stage compared to moderate to high at dough stage, with hybrid cultivar WR96 showing highest disease, while local cultivar Pari had the lowest. Brown spot disease severity in different cultivars under induced epiphytic condition also followed the similar trend. The results also revealed that most of the yield-contributing characters examined showed wide variations among the cultivars. Modern cultivar BR16 produced the highest panicle length, number of grain per panicle and grain yield per hectare. At the same time as local cultivar Pari generated the lowest number of tiller per plant, panicle length, grain number per panicle and grain yield per hectare. Moreover, hybrid cultivar WR96 produced the highest percentage of spotted grain per panicle and seed yielding C. miyabeanus, and also the lower percentage of seed germination, while the reverse was observed in local cultivar Pari. These findings may allow producers and breeders to select rice cultivar, resistant or tolerant to brown leaf spot disease and to avoid significant reductions in grain yields.     

Studies on photoacoustic uptake signals in tobacco leaves under high carbon dioxide levels

Photoacoustic signals were measured in expanded tobacco leaves, exposed to a controlled atmosphere by being only partly enclosed within the photoacoustic cell. It was aimed to corroborate the conjecture of Reising and Schreiber (Photosynthesis Research 42: 65-73, 1994) that under exceptionally high CO2 levels (ca. 1–5%) the photobaric uptake contribution reflects CO2 uptake induced by light dependent stromal alkalinization. This is shown here by: (1) the shallower damping of the uptake signal vs. the modulation frequency, compared to a normal oxygen evolution signal; (2) the partial inhibition of the uptake signal under 5% CO2 by nigericin; (3) the complete absence of uptake signals under 5% CO2 in a carbonic-anhydrase-deficient mutant, which gave rather a normal oxygen evolution signal. The photoacoustic signals from the wild type and the transgenic tobacco in air could not be distinguished, indicating that the CO2 uptake signal is negligible under this condition. Uptake photobaric signals were also measured in modulated far-red light (ca. 715–750 nm), following addition of white background light (in light limiting intensity). In normal tobacco under 5% CO2, the background light induced an uptake transient, lasting about a minute, then declining to a low steady level. Significantly smaller transients were obtained under normal air, and in the carbonic-anhydrase deficient mutant also under 5% CO2. Extrapolation to zero frequency of the signal damping vs. modulation frequency, in both tobacco genotypes, suggests however similar magnitudes of the uptake transients. On the other hand, no proportional steady-state uptake was observed for the last two cases. Presumably, the steady uptake under 5% CO2 in modulated far-red light reflects CO2 solubilization, while it is an open question whether the transient could be partly contributed also by oxygen photoreduction by PS I (Mehler reaction). It is reasoned that, under conditions of low light, the respiratory activity results in accumulation of CO2 in the photoacoustic cell, which is sufficient to induce an uptake phenomenon, giving a more satisfactory interpretation for the so-called 'low light state' [Cananni and Malkin (1984) Biochim Biophys Acta 766: 525–532].     

Gas exchange in the filamentous cyanobacterium Nostoc punctiforme strain ATCC 29133 and Its hydrogenase-deficient mutant strain NHM5

Nostoc punctiforme ATCC 29133 is a nitrogen-fixing, heterocystous cyanobacterium of symbiotic origin. During nitrogen fixation, it produces molecular hydrogen (H(2)), which is recaptured by an uptake hydrogenase. Gas exchange in cultures of N. punctiforme ATCC 29133 and its hydrogenase-free mutant strain NHM5 was studied. Exchange of O(2), CO(2), N(2), and H(2) was followed simultaneously with a mass spectrometer in cultures grown under nitrogen-fixing conditions. Isotopic tracing was used to separate evolution and uptake of CO(2) and O(2). The amount of H(2) produced per molecule of N(2) fixed was found to vary with light conditions, high light giving a greater increase in H(2) production than N(2) fixation. The ratio under low light and high light was approximately 1.4 and 6.1 molecules of H(2) produced per molecule of N(2) fixed, respectively. Incubation under high light for a longer time, until the culture was depleted of CO(2), caused a decrease in the nitrogen fixation rate. At the same time, hydrogen production in the hydrogenase-deficient strain was increased from an initial rate of approximately 6 micro mol (mg of chlorophyll a)(-1) h(-1) to 9 micro mol (mg of chlorophyll a)(-1) h(-1) after about 50 min. A light-stimulated hydrogen-deuterium exchange activity stemming from the nitrogenase was observed in the two strains. The present findings are important for understanding this nitrogenase-based system, aiming at photobiological hydrogen production, as we have identified the conditions under which the energy flow through the nitrogenase can be directed towards hydrogen production rather than nitrogen fixation.     

Rapid,Blue-Light-Induced Acidifications at the Surface of Ectocarpus and Other Marine Macroalgae

In most brown algae, photosynthesis saturated with red light can be stimulated by continuous blue light. Pulses of blue light lead to transient increases in photosynthetic rate. When a CO2-sensitive electrode was used, occasionally blue light was observed to cause an apparent increase of CO2 instead of the expected decrease. This was changed by buffering the seawater medium and, under these conditions, blue light caused stimulation of CO2 consumption. These results led to investigations of blue-light-dependent pH changes at the outer surface of the plants. Shifts of the pH were recorded in the presence of the photosynthetic inhibitor 3-(3,4-dichlorophenyl)-1,1-dimethylurea. In all brown algae tested and in the green algae Ulva and Enteromorpha, blue-light pulses caused transient acidification of 0.03 to 0.18 pH units, depending on the species. The kinetics showed lag phases of a few seconds and the minimum was reached after 5 to 9 min. Fluence response relationships indicated that the sensitivity (threshold) to blue light was very similar in all species. The responses in Ectocarpus changed with time, and about 5 h after the beginning of red light or darkness, a second component became evident, which peaked 20 min after the blue-light pulse. The refractory period of the whole system was about 3 h in Ectocarpus. The blue-light-dependent pH changes show striking similarities to those of higher plant guard cells, and it is possible that similar responses may occur in other tissues of higher plants. In red algae, however, no blue-light-dependent acidifications could be detected. The possible role of the observed pH shifts in a mechanism of CO2 acquisition is discussed.     

Overexpression of constitutive differential growth 1 gene, which encodes a RLCKVII-subfamily protein kinase, causes abnormal differential and elongation growth after organ differentiation in Arabidopsis

To better understand genetic regulation of differential growth of plant organs, a dominant and semidwarf mutant, constitutive differential growth 1-Dominant (cdg1-D), was isolated utilizing the technique of activation tagging. cdg1-D showed pleiotropic phenotype including dwarfism, exaggerated leaf epinasty, and twisted or spiral growth in hypocotyl, inflorescence stem, and petiole. Hypocotyls of cdg1-D were longer than those of wild type under light conditions. The phenotype was caused by activation tagging of CDG1 gene that encodes a receptor-like cytoplasmic kinase of RLCKVII subfamily. When treated with high concentrations of brassinolide, light-grown wild-type seedlings showed long hypocotyls and strong leaf epinasty as observed in cdg1-D seedlings. Treatment of cdg1-D with brassinazole, a specific inhibitor of brassinosteroid (BR) biosynthesis, did not rescue the mutant phenotype. Gene expression of CONSTITUTIVE PHOTOMORPHOGENESIS AND DWARFISM involved in BR biosynthesis and phyB ACTIVATION-TAGGED SUPPRESSOR1 that inactivates BR was repressed and induced, respectively, in cdg1-D plants, suggesting constitutive activation of BR signaling in the mutant. CDG1 was expressed at a very low level in all the organs of the wild type tested. We isolated two independent intragenic suppressors of cdg1-D. However, they showed normal morphology and responded to BR in a similar manner to wild type. Taken together, CDG1 gene may interfere with signal transduction of BR when overexpressed, but is not an essential factor for it in the wild type.     

Carbon monoxide complex of cytochrome b(5) at acidic pH

CO complex of cyt b(5) generated at acidic pH is investigated by absorption, resonance Raman (RR), and far UV CD measurements. The Soret maximum wavelength blue-shifted to 420 nm with other absorption bands observed around 540 and 570 nm for reduced cyt b(5) upon interaction with CO at acidic pH (pH 3.1-3.5). Under this condition, the iron-carbon stretching RR band was observed at 529 cm(-1) (520 cm(-1) for C(18)O), which indicated formation of a heme&bond;CO adduct with a histidine as an axial ligand. Heme dissociated from the reduced cyt b(5) protein at pH approximately 3.5, whereas its rate decreased under CO atmosphere compared with N(2) atmosphere, due to formation of a heme&bond;CO adduct with a histidine as an axial ligand.     

UV-B辐射增强对海洋大型藻与微型藻种群生长关系的影响

选用孔石莼和青岛大扁藻为海洋大型藻和微型藻的代表,通过室内添加模拟试验研究了UV-B辐射增强对孔石莼(重量固定)与青岛大扁藻(密度不同)种群生长关系的影响。结果表明:(1)在单养情况下,4个UV-B辐射剂量都对孔石莼的生长产生抑制作用;对青岛大扁藻生长的影响却不同,低剂量(U-1)的UV-B辐射对青岛大扁藻的生长有促进作用,而高剂量的UV-B辐射则有显著的抑制作用;且因初始接种密度不同而各异。(2)在共养情况下,微藻对孔石莼的生长表现出一定的抑制作用,随着微藻初始接种密度的增加,其抑制作用亦增加;反之,在共培养的初始阶段(6 d内)孔石莼对微藻的生长也有抑制作用,但后期阶段(9 d后)表现出促进作用。(3)在共培养的同时附加UV-B辐射处理,随着初始接种密度的增加,青岛大扁藻对孔石莼生长的抑制作用更加明显;同时,与共养相比较,孔石莼对微藻生长的抑制作用亦趋于明显。     

Influence of irradiation quality on photosynthetic pigments, saccharides, nitrate reductase activity, thylakoid organization and growth of Ulva pertusa

A floating green alga Ulva pertusa Kjallman was grown in the laboratory under various irradiations: "white light" (as reference, broad spectral band, WLC), red radiation (600-700 nm, RRC) and blue radiation (400-500 nm, BRC). During 15 d of culture, the specific growth rate of WLC varied highly when compared to BRC and RRC. The contents of chlorophyll (Chl) and proteins, and the nitrate reductase (NR) activity were significantly higher in BRC than in RRC while the content of saccharides was slightly higher in RRC than BRC. U. pertusa in WLC had the highest contents of saccharides, proteins, and Chl, and the highest NR activity. In the WLC, closely arranged well organized thylakoids were seen whereas in the BRC, although the number of thylakoid layers was similar to WLC, they were widely separated from each other. In contrast to this, in the RRC, the thylakoids were less prominent and were also densely covered with ribosomes. This revised version was published online in July 2006 with corrections to the Cover Date.     

春小麦对大气CO2浓度升高的响应及其对麦长管蚜生长发育和繁殖的影响

通过开顶式气室研究了春小麦对大气CO₂浓度升高(542.1±24.8和738.8±25.7 μl·L^-1 vs.382.4±248 μl·L^-1)的响应及其对麦长管蚜生长发育和繁殖的影响.结果表明,大气CO₂浓度升高有利于春小麦的生长.与对照相比,5月5日～6月14日,550和750 μl·L^-1 CO₂浓度处理春小麦的株高分别增加2.80%～14.92%和6.30%～17.56%;4月30日～6月9日,叶面积分别增加5.68%～50.52%和6.14%～83.45%;DC₅₀分别提前了0.39和0.90 d,DC₇₅也分别提前了0.53和1.02 d;茎、叶、穗以及整个地上部组织的鲜、干重均有不同程度的增加.大气CO₂浓度升高可显著提高春小麦的穗长和穗粒数,降低千粒重.与对照相比,550和750 μl·L^-1 CO₂浓度处理的麦穗长分别增加0.56%和3.20%;单株穗粒数分别增加12.5%和18%;而千粒重分别降低了2.23%和6.34%.随着大气中CO₂浓度增加,麦穗中葡萄糖、二糖、多糖、总糖、总糖与总氮的比值都显著增加,而果糖、三糖和总氮含量都显著降低.大气CO₂浓度升高可缩短麦长管蚜的产卵前期和世代历期,提高繁殖量和平均相对生长率.与对照相比,550和750 μl·L^-1 CO₂浓度处理麦长管蚜的平均相对生长率分别提高33.26%和74.34%.麦长管蚜种群的平均相对生长率与寄主麦穗中总糖和总氮的比值相关显著.     

Enhancement of rice canopy carbon gain by elevated CO(2) is sensitive to growth stage and leaf nitrogen concentration

Increasing our understanding of the factors regulating seasonal changes in rice canopy carbon gain (C(gain): daily net photosynthesis -- night respiration) under elevated CO(2) concentrations ([CO(2)]) will reduce our uncertainty in predicting future rice yields and assist in the development of adaptation strategies. In this study we measured CO(2) exchange from rice (Oryza sativa) canopies grown at c. 360 and 690 micromol mol(-1)[CO(2)] in growth chambers continuously over three growing seasons. Stimulation of C(gain) by elevated [CO(2)] was 22-79% during vegetative growth, but decreased to between -12 and 5% after the grain-filling stage, resulting in a 7-22% net enhancement for the whole season. The decreased stimulation of C(gain) resulted mainly from decreased canopy net photosynthesis and partially from increased respiration. A decrease in canopy photosynthetic capacity was noted where leaf nitrogen (N) decreased. The effect of elevated [CO(2)] on leaf area was generally small, but most dramatic under ample N conditions; this increased the stimulation of whole-season C(gain). These results suggest that a decrease in C(gain) enhancement following elevated CO(2) levels is difficult to avoid, but that careful management of nitrogen levels can alter the whole-season C(gain) enhancement.