EFFECTS OF TEMPERATURE,NITROGEN SUPPLY,AND TISSUE NITROGEN ON AMMONIUM UPTAKE RATES OF THE CHLOROPHYTE SEAWEEDS ULVA CURVATA AND CODIUM DECORTICATUM1

Nitrogen uptake rates of Ulva curvata (Kütz.) de Toni (Ulvales) and Codium decorticatum (Woodw.) Howe (Caulerpales) grown under several N addition regimes were determined by perturbation and continuous mode techniques, and as N demand, by the product of growth rate and tissue N. Uptake rates are reported as the slope of rate vs. concentration curves in each case. N uptake rates of U. curvata were inversely correlated with tissue N and affected only slightly by temperature. There was no correlation of N uptake rate with tissue N in C. decorticatum. N uptake rates of C. decorticatum were affected by temperature but to a lesser degree than were growth rates. Neither N addition per se nor light affected N uptake capacity of either species. The proximal mechanism for seaweeds accumulation of N at low light and temperatures may be that N uptake is less limited by light and temperature than is growth. This in turn may partially compensate for the effects of reduced light and temperature on growth by increasing pigment and enzyme levels. Perturbation uptake rates were higher than continuous mode or N demand rates in Ulva but not in Codium. N uptake rates of Ulva were higher than those of Codium, but N storage capacities were lower. These two observations suggest that Ulva experiences a fundamentally more variable N supply than does Codium. This is consistent with the clarification of Ulva as an ephemeral form and of Codium as persistent. A seaweed's functional form therefore appears to influence the spectrum of resource variability available to it as well as its ability to persist in the environment.     

Seasonal variation in RuBPcase activity and N allocation in the chlorophyte seaweeds ulva curvata (kutz.) de toni and Codium decorticatum (Woodw.) Howe

Seasonal variation in ribulosebisphosphate carboxylase (RuBPCase) activity and cellular N allocation in Ulva curvata (Kutz.) De Toni and Codium decorticatum (Woodw.) Howe was followed over two annual cycles. Because apparent seasonal variation may result from random sampling of a coherent pattern of shorter-term variation, estimating the magnitude of seasonal variation in seaweed N allocation requires sampling over a range of time scales. Such sampling reveals annual ranges of variation in N allocation to be greater than those measured at time scales of hours to days. RuBPCase activity in both U. curvata and C. decorticatum peaks in winter and summer, with fall and spring lows. Total N and C exhibit pronounced winter highs and summer lows in C. decorticatum, with less predictable variation in U. curvata. Growth is controlled by temperature in both species, while N uptake is only loosely coupled to temperature or light. Seasonal variations in N allocation are driven by interactive effects of N supply, temperature, and light on growth and N uptake. These effects are largely independent of morphological and genetic differences between species.     

温度对4种大型海藻氮磷吸收效率及光合生理特性的影响

研究以裂片石莼(Ulva fasciata)、肠浒苔(Ulva intestinalis)、龙须菜(Gracilaria lemaneaformis)、坛紫菜(Pyropia haitanensis)为实验材料, 分析了不同温度(15、20、25、30℃)下4种大型海藻对海水中N、P元素的吸收效率和光合特性的特点。结果显示: (1)4种大型海藻对水体N、P均有明显的吸收效果, 吸收能力高低依次为肠浒苔>裂片石莼>坛紫菜>龙须菜; (2)温度过高或过低都会限制藻类对N、P的吸收和正常生长, 同时降低4种藻的相对电子传递速率及光化学效率; (3)裂片石莼与肠浒苔的N、P吸收能力强, 且光合系统对温度耐受性高, 是实施养殖污水生物净化的良好材料; (4)4种海藻对水体中N、P营养盐的吸收在48h内基本完成, 实地应用中可考虑24—48h周期换水或采用流通循环式的培养模式, 以达到既促进藻类的生长又提高营养盐吸收效率的目的, 以避免藻体因营养缺乏引起负生长而造成二次污染。     

CO_2和温度升高及干旱对小麦叶片化学成分的影响

研究了 CO2 浓度升高、高温和干旱对干旱区小麦叶片化学成分的影响 ,结果表明 :CO2 浓度升高时各化学成分之间的差异只有在 40 %田间持水量时才表现显著 ,说明未来 CO2 浓度升高对干旱区小麦化学成分的影响可能大于在非干旱区的影响 ;CO2 浓度升高可减小因为土壤水分不同而造成的小麦化学成分之间的差异 ;高温对小麦化学成分的主要影响是引起 N含量的显著降低 ;CO2 浓度升高、高温和干旱三因子对干旱区小麦化学成分的复合影响是 N含量下降和 C/ N的显著上升 ,这可能对未来农田生态系统的分解速率产生影响     

INTERACTING EFFECTS OF LIGHT AND NUTRIENT LIMITATION ON THE GROWTH RATE OF SYNECHOCOCCUS LINEARIS (CYANOPHYCEAE)1

The blue-green alga Synechococcus linearis (Naeg.) Kom. was grown in P- and N-limited chemostats over a range of potentially limiting irradiances in order to determine the combined effects of light and nutrient limitation on some aspects of the composition and metabolism of this alga. Over a narrow range of low irradiances, simultaneous limitation of growth rate by light and either N or P was shown. This simultaneous limitation of growth rate by a nutrient and a physical factor can be explained by the ability of an increased supply of one to compensate in part for a decreased supply of the other. At all irradiances, the internal concentration of the limiting nutrient increased with increasing dilution rate, and the results could be fitted to the Droop relationship. With decreasing irradiance, the internal concentration of the limiting nutrient increased. There appeared to be little or no effect of light on the minimum internal concentration of P but that of N increased with decreasing light. Both chlorophyll a and biliprotein per unit particulate C increased with increasing dilution rate and decreasing irradiance. The critical N/P ratio increased with decreasing light as the N requirement of N-limited cells increased faster than did the P requirement of P-limited cells. The composition of exponentially growing cells in complete medium varied much less with light. Neither dilution rate nor irradiance during growth had a great effect on saturated rates of P or N uptake or alkaline phosphatase activity. Calculated assimilation ratios increased with light and dilution rate. The role of the flexibility of nutrient composition in adaptation to adverse conditions and the implications of the results for the use of physiological indicators of nutrient status are discussed.     

增温对川西亚高山针叶林内不同光环境下红桦和岷江冷杉幼苗生长和生理的影响

 川西亚高山针叶林是青藏高原东部高寒林区的重要组成部分, 也是研究全球变化对森林生态系统影响的重要森林类型。开展亚高山针叶林不同树种对气候变暖响应差异的研究, 可为预测未来气候变暖背景下亚高山针叶林植被组成和森林动态提供科学依据。我们以川西亚高山针叶林两种主要树种——红桦(Betula albo-sinensis)和岷江冷杉(Abies faxoniana)为研究材料, 采用开顶式增温法(Open-top chamber, OTC)模拟气候变暖, 研究了增温对全光条件和林下低光环境中(约为全光的10%)生长的红桦和岷江冷杉幼苗生长和生理的影响。在人工林环境下, OTC使增温框内平均气温和地表温度分别升高了0.51和0.33 ℃; 而在林外空地处, OTC使二者分别升高了0.69和0.41 ℃。研究结果显示, 增温总体上促进了两种幼苗的生长和生理过程, 并促使幼苗将更多的生物量投入到其同化部位——叶, 使幼苗的根冠比(R/S)显著降低。增温通过增加叶片的光合色素含量和表观量子效率等光合参数, 促进了幼苗的光合过程和生长。然而, 增温对两种幼苗生长和生理的影响效果与植物种类及其所处的光环境有关。增温仅在林外全光条件下显著影响红桦幼苗的生长和生理过程。岷江冷杉幼苗对增温的响应与红桦相反, 即增温仅在林下低光环境下对岷江冷杉幼苗的生长和生理过程有明显促进作用。这种响应差异可能赋予这两种植物在未来气候变暖背景下面对外界环境变化时具有不同的适应能力和竞争优势, 从而对亚高山针叶林生态系统物种组成和森林动态产生潜在影响。     

光强和温度变化对曲浒苔光合作用的调节机制

实验针对曲浒苔(Ulva flexuosa)光合作用系统对光照与温度变化的响应进行分子水平探究, 从原初反应、电子传递、光合磷酸化到碳的固定等方面对曲浒苔光合作用响应机制进行解析。叶绿素合成基因在高温高光[30℃、400 μmol/(m2·s)]环境下表达下调。类胡萝卜素合成基因在低温高光[4℃、400 μmol/(m2·s)]环境下表达下调。电子传递链、CF₁F₀-ATP合酶等基因对温度和光照变化的适应能力较弱, 各实验组的相关基因表达量均呈现下调趋势。聚光复合体基因表达量上调。各实验组的光系统Ⅱ反应中心基因均下调, 锰稳定蛋白则普遍上调。不同C₄途径关键酶基因在各个环境中的变化趋势不一致。综合实验结果可以发现曲浒苔对于温度和光照变化具有一定的耐受度, 分析得出温度对曲浒苔光合作用基因的影响较大, 而且高温高光对曲浒苔的影响最显著。     

BIOCHEMICAL STRATEGIES FOR GROWTH OF GRACILARIA TIKVAHIAE (RHODOPHYTA) IN RELATION TO LIGHT INTENSITY AND NITROGEN AVAILABILITY1

The main effects and interactions between light (I_o, full incident sunlight to 0.07 I_o) and NO₃^? loading (0.4 to 4.3 mmol · g dry weight^?1· d^?1) on growth rate, photosynthesis and biochemical constituents of Gracilaria tikvahiae McLachlan were studied using a factorial design experiment in outdoor, continuous-flow seawater cultures. Incipient nitrogen limitation in the low NO₃^? loading, I_o and 0.57 I_o treatments occurred after 2.5 weeks of growth under the experimental conditions and resulted in decreased tissue NO₃^? and R-phycoerythrin. Tissue NO₃^? and R-phycoerythrin accounted for up to ca. 15 and 20%, respectively, of the total N in G. tikvahiae suggesting a N reserve role for these N pools. Under light and NO₃^? limitation, growth rate was a parabolic function of the C:N ratio. As light limitation increased, growth rate and the C:N ratio decreased as levels of Chl-a, R-phycoerythrin, percent N and percent protein increased. As NO₃^? limitation increased, growth rate and levels of Chl-a, R-phycoerythrin, percent N and percent protein all decreased with parallel increases in the C:N ratio. In contrast to the inverse relationship between pigment content and light, ribulose bisphosphate carboxylase (RuBPCase) activity (on both a protein and dry weight basis) varied directly with light. This biochemical acclimation of G. tikvahiae to light and N availability appears to be a process directed towards maximizing photo synthetic capacity and growth.     

THE EFFECTS OF LIGHT AND NITROGEN ON GROWTH,PIGMENT CONTENT,AND BIOCHEMICAL COMPOSITION OF GRACILARIA FOLIIFERA V. ANGUSTISSIMA (GIGARTINALES,RHODOPHYTA)1

The combined effects of light intensity and nitrogen (NO₃^?) on growth rate, pigment content, and biochemical composition of Gracilaria foliifera v. angustissima (Harvey) Taylor was investigated using outdoor continuous cultures. Growth of Gracilaria increased linearly with increasing light to 0.43 doublings d^?1 at high light levels (383 ly d^?1 of in situ light), suggesting that light may often limit growth of this plant in nature. Chlorophyll a and phycoerythrin contents were inversely proportional to light level and growth rate. However, pigment content did not affect the growth capacity of Gracilaria. There was no increase in growth or pigment content with increasing additions of nitrogen. The low nitrogen treatment was unenriched seawater that had higher NO₃^? levels than most coastal waters (influent = 8.61 μM; residual = 0.94 μM). When growing near its maximum rate under high light intensities, Gracilaria had a significantly (P < 0.001) lower phycoerythrin: chlorophyll a ratio (phyco: Chl a) than did Gracilaria growing more slowly under lower light (Phyco:Chl a of 2.8 ± 0.2 vs. 3.8 ± 0.3). Faster growing plants also had C:N ratios above 10, indicating N- limitation. In addition to harvesting light the phycobiliproteins of Gracilaria may store nitrogen. Growth rates of Gracilaria correlated negatively with ash (r =–0.85) and positively with the carbon: phycoerythrin ratio (r = 0.85), suggesting that these two indices can be used to estimate growth in the field.     

BIOMASS AND DYNAMICS OF GROWTH OF ULVA SPECIES IN PALMONES RIVER ESTUARY1

During the last decade, the Palmones River estuary has undergone severe eutrophication followed by a green tide episode; two species of Ulva, rotundata Blid. and Ulva curvata (Kütz.) De Toni, were the main macroalgae responsible for this bloom. From November 1993 to December 1994, we followed the biomass, the growth dynamics, and tissue elemental composition (C:N:P)of Ulva species, as well as some physicochemical variables in the estuary. Maximum biomass (up to 375 g dry wt·m^?2 in some spots, corresponding to a thallus area index of nearly 17 m²Ulva·m^?2 sediment) were observed in June and December. However, the biomass varied among the sampling stations. Water nitrate, ammonia, and phosphate showed high concentrations throughout the year, with extremely high transient pulses, sustaining the high growth rates observed. Growth rates were estimated directly in the field. The rates were generally higher in Ulva discs maintained in net cages than those estimated by changes in biomass standing stock between two consecutive samplings. The difference between both estimates was used to quantify the importance of the processes causing loss of biomass, which were attributable to grazing, exported biomass, and thallus decomposition under anaerobic conditions resulting from extreme self-shading. Maximum chlorophyll content was found in winter, whereas the minimum was in spring. Atomic N:P ratios were generally higher in the algae than in the water. However, the absolute concentrations of tissue N and P were always higher than the critical levels for maximum growth, which suggests that growth was not limited by inorganic N or P availability. The results suggested that the increase in nutrient loading in the river may have triggered the massive development of green algae and that light limitation and temperature stress in summer seem to be the main factors controlling the abundance of Ulva in the estuary. In addition to light availability and thermal stress, the different loss processes may have a decisive role in the dynamics of Ulva biomass.     

Environmental effects on photosynthesis, nitrogen-use efficiency, and metabolite pools in leaves of sun and shade plants

Effects of varying light intensity and nitrogen nutrition on photosynthetic physiology and biochemistry were examined in the sun plant Phaseolus vulgaris (common bean) and in the shade plant Alocasia macrorrhiza (Australian rainforest floor species). In both Phaseolus and Alocasia, the differing growth regimes produced large changes in photosynthetic capacity and composition of the photosynthetic apparatus. CO₂-saturated rates of photosynthesis were linearly related to leaf nitrogen (N) content in both species but photosynthesis per unit leaf N was markedly higher for Phaseolus than for Alocasia. Photosynthetic capacity was also higher in Phaseolus per unit ribulose 1,5-bisphosphate (RuBP) carboxylase (RuBPCase) protein. The leaf content of RuBPCase was linearly dependent on leaf N content in the two species. However, the proportion of leaf N which was RuBPCase was greater in Phaseolus than in Alocasia and was more sensitive to growth conditions, ranging from 6% of leaf N at low light to 20% at high light. In Alocasia, this range was much less, 6 to 11%. However, chlorophyll content was much more sensitive to light intensity in Alocasia. Thus, the RuBPCase/chlorophyll ratio was quite responsive to N availability and light intensity in both species (but for different reasons), ranging from 6 grams per gram for Phaseolus and 2 grams per gram for Alocasia at high leaf N and 1.5 gram per gram for Phaseolus and 0.5 gram per gram for Alocasia at low leaf N. These large changes in the proportions of components of the photosynthetic apparatus had marked effects on the sensitivity of these species to photoinhibition. These environmental effects also caused changes in the absolute levels of metabolites of the photosynthetic carbon reduction cycle. Concentrations of RuBP and P-glycerate were approximately 2-fold higher in high light-grown than low light-grown Phaseolus and Alocasia when expressed on a leaf area basis. However, if metabolite pool sizes are expressed on the basis of the RuBPCase catalytic site concentration, then they were little affected by the marked changes in leaf makeup. There appears to be fundamental differences between these species in the mechanism of sun-shade adaptation and N partitioning in the photosynthetic apparatus that result in significant differences in the N-use efficiency of photosynthesis between Phaseolus and Alocasia but similar RuBPCase:substrate:product ratios despite these differences.     

The C : N : P stoichiometry of autotrophs – theory and observations

Evolution has set biochemical constraints on the chemical composition of living organisms. These constraints seem to lead to increases in N : C and P : C ratios with increasing relative growth rate for all types of organisms. The N : P ratio also seems to decrease with relative growth rate for heterotrophs whereas autotrophs may show a more complex behaviour. Here I will show that, from biochemical considerations, N : C should increase linearly and P : C quadratically with relative growth rate in autotrophs with the consequence that N : P increases at low relative growth rates, passes a maximum and then decreases at high relative growth rates. These predictions are verified against observations for a freshwater alga (Selenastrum minutum) and a tree seedling (Betula pendula). Changes in temperature, light or other factors that affect the growth rate of autotrophs interact with nutrient supply in such a way that there are no simple rules for as to how N : P will change.     

环境因子对金藻生长和噬藻速率的影响

在微囊藻的大量培养过程中分离到一株能够快速吞噬微囊藻的鞭毛虫-金藻Poterioochromonas sp.,其具有混和营养的特点。研究以人工培养的铜绿微囊藻(Microcystis aeruginosa FACHB469)为饵料,研究了起始饵料浓度、光强、温度和pH等环境因子对Poterioochromonas sp.生长和吞噬饵料速率的影响。结果显示:当无饵料时,金藻的自养生长与光强和温度相关,而与pH无相关性。喂食饵料能显著促进金藻的生长,其吞噬速率和生长速率与起始饵料浓度相关性强,可分别用Michaelis-Menten方程和Monod方程拟合。提供相同量的饵料时,金藻的生长与光强相关性显著,而与温度和pH的相关性不显著;其吞噬速率与pH呈现负相关关系,而与光强和温度相关性不显著。除了在不同pH下的生长外,混合营养时金藻的生长速率与吞噬速率之间存在显著的正相关关系。实验表明适于Poterioochromonas sp.生存并吞噬微囊藻的环境条件较广,这也是进一步探索利用Poterioochromonas sp.控制微囊藻水华的前提。       

Degradation of ribulose-1,5-bisphosphate carboxylase by proteolytic enzymes from crude extracts of wheat leaves

In crude extracts from the primary leaf of wheat seedlings, Triticum aestivum L., cv. Olympic, maximum proteinase activity, as determined by measuring the rate of release of amino nitrogen from ribulose-bisphosphate carboxylase (RuBPCase), was found to be obtained only when EDTA and L-cysteine were included in the extraction buffer. Highest proteinase activity was obtained by grinding at pH 6.8, although the level of activity was similar in the pH range 5.6 to 8.0; this range also coincided with maximum extractability of protein. The lower amount of RuBPCase degrading proteinase extracted at low pH was not due to an effect of pH on enzyme stability. The optimum temperature of reaction was 50° C and reaction rates were linear for at least 120 min at this temperature. In the absence of substrate the proteinase was found to be very sensitive to temperatures above 30° C, with even short exposures causing rapid loss of activity. The relation between assay pH and RuBPCase degradation indicated that degradation was restricted to the acid proteinase group of enzymes, with a pH optimum of 4.8, and no detectable activity at a pH greater than 6.4. The levels of extractable RuBPCase proteinase exhibited a distinct diurnal variation, with activity increasing during the latter part of the light period and then declining once the lights were turned off. The effect of leaf age on the level of RuBPCase, RuBPCase proteinase and total soluble protein was investigated. Maximum RuBPCase activity occurred 9 days after sowing as did soluble protein. After the maximum level was obtained, the pattern of total soluble protein was shown to be characterised by three distinct periods of protein loss: I (day 9–13) 125 ng leaf^-1 day^-1; II (day 15–27) 11 ng leaf^-1 day^-1; III (day 29–49) 22 ng leaf^-1 day^-1. Comparison of the pattern of RuBPCase activity and total protein suggest that the loss of RuBPCase may be largely responsible for the high rate of protein loss during period I. Proteinase activity increased sharply during the period of most rapid loss of RuBPCase activity, and because the specific activity of RuBPCase also declined, we concluded that RuBPCase was being degraded more rapidly than the other proteins. Once the majority of the RuBPCase was lost, there did not appear to be a direct relation between RuBPCase proteinase activity and rate of total soluble protein loss, since the proteinase exhibited maximum activity during the slowest period of protein loss (II), and was declining in activity while the rate of protein loss remained stable during the third and final period of total protein loss.Abbreviations RuBPCase ribulose-1,5-bisphosphate carboxylase (EC 4.1.1.39) - TCA trichloroacetic acid Supported by the Wheat Industry Research Council of Australia and the Australian Research Grants Committee D2 74/15052     

SEASONAL VARIATION OF PHOTOSYNTHETIC PERFORMANCE AND LIGHT ATTENUATION IN ULVA CANOPIES FROM PALMONES RIVER ESTUARY1

The primary production of Ulva populations relies on their photosynthetic performance, which is dependent on the light availability under natural conditions. This study concerns the light attenuation characteristics in Ulva canopies and the seasonal photosynthetic performance of two different species (Ulva rotundata Blid., Ulva curvata (Kütz.) De Toni) blooming in the Palmones river estuary. Light within canopies differed from that reaching the surface. Light availability was reduced through the water column (at high tide) and Ulva canopies. In addition, light was spectrally filtered. As a result, the photosynthetically usable radiation (PUR) was further attenuated through Ulva canopies, increasing the photosynthetically active radiation/PUR ratio. The muddy sediment deposited on and between the Ulva thalli also drastically restricted the light availability. Thick Ulva mats are frequently found covering the intertidal mudflats, and therefore, thalli within these mats may be subjected to steep light gradients. As a consequence, individual Ulva growth rates cannot be extrapolated to estimate the primary production of Ulva canopies. Interspecific differences were observed for light-saturated photosynthetic rates (P_max) and light compensation points (L_CP), with Ulva curvata generally displaying higher values than did U. rotundata. For both species, maxima were recorded in winter for P_max, quantum yield, chlorophyll content, and absorptance, whereas minima were found in summer. Dark respiration (R_d) was not seasonally affected, and a maximum L_CP was found in summer. To extrapolate these data to field situations, the temperature dependence of photosynthesis should be considered. The Q₁₀ values were 2.44 for R_d and 1.79 for P_max, whereas the photosynthesis rate at subsaturating light levels was unaffected. The Q₁₀ values showed an enhanced respiratory rate in summer and a minimum in winter, whereas the seasonal differences on P_max were damped.     

光照和氮交互作用对水曲柳幼苗生长、生物量和氮分配的影响

采用温室沙培方式,对水曲柳幼苗进行了不同光强（2个水平）和氮浓度（4个水平）处理,分析了其生长、生物量和氮分配对环境变化的响应.结果表明：与全光照处理相比,低光处理下水曲柳幼苗冠根比（S/R）和净氮吸收速率（NNUR）极显著提高（P<0.01）,但相对生长速率（RGR）和净同化速率（NAR）极显著下降（P<0.01）;低光处理下的幼苗根、茎、叶和整株生物量分别较全光照处理降低了36.8%（P<0.01）、1.7%、12.7%（P<0.05）和24.3%（P<0.01）;低光处理使幼苗分配到根系的氮比例明显下降,而叶片的分配比例增加.无论光强大小,氮对幼苗生长都具有十分明显的促进作用,而且幼苗S/R和叶片的氮分配比例都随氮供给浓度的增加而明显提高.光强和氮浓度对水曲柳幼苗的基径、S/R、RGR和生物量（根和叶）分配比例具有显著的交互作用（P<0.05）.     

温度和光照强度对鼠尾藻生长和生化组成的影响

在实验室条件下,研究了温度(10、15、20、25 ℃)和光照强度(20、60、100、140、180 μE·m^-2·s^-1)对鼠尾藻生长和生化组成的影响.结果表明,温度、光照强度及两者的交互作用对鼠尾藻生长均具有极显著影响.鼠尾藻在15 ℃和20 ℃下生长速率较高,随着温度的升高,达到最大生长速率所需要的光照强度有上升趋势.在10 ℃和15 ℃下,较高的光照强度对鼠尾藻生长产生了一定抑制作用,而在20 ℃和25 ℃下,其生长速率总体随光照强度的增加而增加.温度和光照强度对鼠尾藻叶绿素a、墨角藻黄素的含量影响极显著,其中光照强度的影响大于温度.总体上,叶绿素a和墨角藻黄素的含量均随着光照强度的升高而显著下降,随着温度的升高而升高.鼠尾藻碳水化合物含量随着光照强度的升高而显著升高,而温度对碳水化合物含量影响不显著.鼠尾藻蛋白质含量随着光照强度的增加而显著下降,在10 ℃和15 ℃下含量较高,随着温度的继续升高,蛋白质含量呈下降趋势.光照强度和温度的变化可改变鼠尾藻的藻体成分含量,这种改变可能是鼠尾藻为了适应环境因子改变而做出的积极的生理调节,对其生长和生存具有重要的生态意义.     

Changes in shell and soft tissue growth, tissue composition, and survival of quahogs, Mercenaria mercenaria, and softshell clams, Mya arenaria, in response to eutrophic-driven changes in food supply and habitat

Eutrophic-driven changes in the composition of near-bottom seston and surface sediment potentially affect food resources and habitat of commercially important bivalves like quahogs, Mercenaria mercenaria, and softshell clams, Mya arenaria. To define how land-derived nitrogen loads and resulting eutrophication affect bivalves, we compared estuarine features to growth and survival of clams across estuaries receiving different N loads. The major effects of nitrogen enrichment on near-bottom seston and surface sediment were to (1) increase microalgal concentrations and reduce carbon to nitrogen ratios, increasing quantity and quality of available foods, and (2) reduce oxygen content in sediments, potentially reducing habitat quality. Shell growth of juvenile and native clams increased with increasing food supply, driven by N enrichment. Growth of soft tissue followed growth of shell, and %N content of soft tissue increased across N loads, providing direct evidence of a link between N loads and growth responses in clams. In some locations, low salinity limited growth and low oxygen concentrations may have reduced survival. Despite these factors, our data indicate the major effect of N enrichment on clams was increased secondary production in terms of shell and soft tissue growth.     

Elevated CO2 plus chronic warming reduce nitrogen uptake and levels or activities of nitrogen‐uptake and ‐assimilatory proteins in tomato roots

Atmospheric CO₂ enrichment is expected to often benefit plant growth, despite causing global warming and nitrogen (N) dilution in plants. Most plants primarily procure N as inorganic nitrate (NO₃^?) or ammonium (NH₄⁺), using membrane‐localized transport proteins in roots, which are key targets for improving N use. Although interactive effects of elevated CO₂, chronic warming and N form on N relations are expected, these have not been studied. In this study, tomato (Solanum lycopersicum) plants were grown at two levels of CO₂ (400 or 700 ppm) and two temperature regimes (30 or 37°C), with NO₃^? or NH₄⁺ as the N source. Elevated CO₂ plus chronic warming severely inhibited plant growth, regardless of N form, while individually they had smaller effects on growth. Although %N in roots was similar among all treatments, elevated CO₂ plus warming decreased (1) N‐uptake rate by roots, (2) total protein concentration in roots, indicating an inhibition of N assimilation and (3) shoot %N, indicating a potential inhibition of N translocation from roots to shoots. Under elevated CO₂ plus warming, reduced NO₃^?‐uptake rate per g root was correlated with a decrease in the concentration of NO₃^?‐uptake proteins per g root, reduced NH₄⁺ uptake was correlated with decreased activity of NH₄⁺‐uptake proteins and reduced N assimilation was correlated with decreased concentration of N‐assimilatory proteins. These results indicate that elevated CO₂ and chronic warming can act synergistically to decrease plant N uptake and assimilation; hence, future global warming may decrease both plant growth and food quality (%N).     

The effects of nuclear mutation on chloroplast development

Summary Under greenhouse conditions the dark green wild type (su/su) tobacco grows 2–3 times faster than the yellow mutant (Su/su) and contains five-fold more chlorophyll. On a fresh weight basis, however, both genotypes contain similar amounts of RuBPCase and fraction 11 protein in approximately equal proportion and have similar levels of 70s and 80s ribosomes. When seedlings are cultured on agar medium supplemented with sucrose and equal concentrations of IAA and kinetin or kinetin alone, a drastic reduction of RuBPCase and free 70s ribosomes, but not of chlorophyll content, were observed. Moreover, albino (Su/Su) seedlings developed on supplemented media still contain appreciable amounts of RuBPCase and free 70s ribosomes although chlorophyll levels are extremely low indicating no correlation between RuBPCase and chlorophyll content. RuBPCase crystallized from both wild type and yellow mutant plants seem to have identical composition and structure when examined by isoelectric focusing, amino acid analysis or peptide mapping techniques. The slow-growing yellow mutant is apparently deficient only in chlorophyll of the light harvesting chlorophyll-protein complex but with no alteration of the protein moiety or chlorophyll a/b ratio.