Growth Rates of Marine Phytoplankton: Correlation with Light Absorption by Cell Chlorophyll a

To better predict plant production in the sea, it would be desirable to be able to calculate, from easily obtainable measurements at one sampling, the growth rate of the prevailing stock of phytoplankton. To this end growth rates, pigment composition, cell volume and cell surface area data were collected for several species of marine phytoplankton in logarithmic growth at 20–21°C and 0.07 cal/cm². min light intensity. Similar data for one species, Dunaliella tertiolecta, are given for several combinations of light intensity and temperature, and for another species, Ditylum brightwellii, grown in nitrogen deficiency. The problem of estimating growth rates of phytoplankton was divided into three parts: 1) variation of growth rate among diverse species and its relationship to light absorption by cell chlorophyll a: 2) variation in growth rate with light intensity; 3) variation in growth rate with temperature. An equation has been formulated for calculating growth rate which provides a more precise fit of the data than do equations for growth rate based upon cell surface/volume ratios or cell volume. The formulation is based upon light absorption by chlorophyll a. It allows for variations in the efficiency of utilization of light absorbed by chlorophyll a and the changes in chlorophyll a content resulting from light intensity and temperature differences. We do not attempt to predict variations in growth rate with photoperiod or spectral distribution, nor do we allow for light effects upon growth rate not mediated by photosynthesis, so the model is, at best, a rough approximation of reality.     

光照强度对中华鳖稚鳖摄食和生长的影响

在３０００，１０００，３００和１０１ｘ的光照强度下，测定了中华鳖稚鳖的最大日摄食量和特定生长率。结果表明，光照强度对中华鳖稚瞥珠最大日摄食量影响显著，随着光照强度的减弱，中华鳖稚鳖的最大日摄食量逐渐增加，二者之间呈线性负相关。     

Predictors of light-limited growth and competition of phytoplankton in a well-mixed water column

Based on a model of light limited growth, Huisman and Weissing found that in a well mixed water column with constant light supply (energy reaching the water surface), equilibrium growth and competition of phytoplankton for light can be characterised by a critical light intensity at the base of the column (I*out). The present study attempts to give a further insight into this model. We first analyse the dependence of the critical light intensity on four parameters: initial slope of the photosynthesis-intensity (p-I) curve, maximal photosynthetic rate, the light-saturated parameter Ikand specific carbon loss rate. Increases in the first two parameters tend to reduce the critical light intensity and increases in the last two tend to increase the critical light intensity. Then we analyse the performance of a model under variable light supply with a time-scale of 1 day (24 hr). Within this time-scale, the critical light intensity changes with time. However, the equilibrium growth and the outcome of competition for light can be adequately characterised by critical light extinction defined as the upper limit of total light extinction due to both biomass and non-living matter in the water column. Under constant light supply, a critical light intensity uniquely corresponds to a critical light extinction. Therefore, critical light extinction can be utilised to predict the equilibrium growth and the outcome of competition under both constant and variable light supply. By changing the maximal light supply at noon, seasonal succession of species composition of communities is investigated. The possible effect of two typical photoresponses, photoadaptation and photoinhibition, on growth and competiton are discussed. Copyright 1999 Academic Press.     

Growth consequences of plasticity of plant traits in response to light conditions

Summary We present a method for quantifying the growth advantage, if any, that results from the plasticity of plant traits in response to growth in high vs. low resource levels. The method, which uses two phenotypes and two resource levels, quantifies the average advantage that a phenotype has, in its own set of conditions, over the other phenotype. The method is applied to the growth of two phenotypes of Abutilon theophrasti, induced by high and low light intensity, in response to two levels of incident light intensity. We calculated the growth advantage first using relative growth rate, and second using whole-plant photosynthetic assimilation rate, as the response variable. Then we used the photosynthetic responses to changes in light intensity to calculate changes in growth rates of each phenotype when exposed to a change in light conditions. These three quantifications of growth advantage broadly agree with one another. Despite the great plasticity of its traits induced by growth in high vs. low light intensity, whole-plant plasticity did not allow Abutilon theophrasti to exhibit a significant growth advantage under these conditions. Indeed, the relative growth rate of the low light phenotype greatly exceeded that of the high light phenotype in high incident light conditions. This may have resulted from the higher leaf area ratio of the low light phenotype. Furthermore, the high light phenotype had significantly greater transpiration rate in both light conditions. For these reasons we suggest that light-induced plasticity of traits in Abutilon theophrasti may confer advantage in response to the variation in vapor pressure deficit that is associated with variation in light intensity. Light-induced plasticity may also be advantageous because under high incident light conditions the high-light phenotype has greater reproductive allocation than the low-light phenotype.     

明党参幼苗存活与生长对光照强度的响应

以濒危植物明党参低温催芽形成的幼苗和常温正常萌发的幼苗为对象,对其存活及形态、结构、生物量及其分配、生长速率等指标进行测定和分析.结果表明,明党参幼苗在较高光强（65％全光照）存活率最高,有利于幼苗建成,低光强存活率最低.低温催芽形成的幼苗和常温正常萌发的幼苗对光照强度的响应规律类似,明党参幼苗的生长参数（株高除外）叶生物量、根生物量、总生物量、生长速率和总叶面积均在65％全光照条件下达到最大值,表现出最佳生长状况,表明适宜明党参幼苗生长的光照条件是65％全光照;利用低温催芽形成的幼苗生物量约是常温正常萌发幼苗的5倍,能提高其经受不利环境的能力,为明党参的栽培和保护提供一种新的途径.     

集胞藻6803的混合培养——光照强度和葡萄糖的影响

利用摇瓶研究了混合营养条件下单细胞蓝藻集胞藻6803(Synechocystissp.PCC6803)的生长特性,以及葡萄糖和光照强度对集胞藻6803生长的影响。实验结果表明,在葡萄糖消耗完之前,集胞藻6803的混合营养型生长处于对数生长期,且葡萄糖浓度及光照强度都对集胞藻6803的混合营养型生长有显著影响:在初始葡萄糖浓度097～480g/L范围内,同一光照强度培养下藻细胞的比生长速率随葡萄糖浓度的增大而降低;而在光照强度15～55μE·m^-2·s^-1范围内,初始葡萄糖浓度相同条件下藻细胞的比生长速率及对葡萄糖的藻体得率都随光照强度的增强而增大,但当光照强度在55～96μE·m^-2·s^-1时,集胞藻6803混合培养的比生长速率基本不变,出现了光饱和现象。     

光照强度与氮肥施用水平对麦田杂草婆婆纳和离子草的生长及其竞争关系的影响

通过盆栽试验,研究了光照强度、氮肥施用水平对两种麦田杂草婆婆纳与离子草的生长及其竞争关系的影响。结果表明,在弱光照强度下,婆婆纳、离子草地上与地下部分的生长都相应减弱,但在施用高量氮肥时,婆婆纳植株能萌发更多的叶片以适应弱光照强度条件;增施氮肥,无论是在弱或强光照强度下都有利于婆婆纳的生长,但在弱光照强度下并不显著促进离子草的生长。当土壤中含有丰富的磷、钾养分时,婆婆纳的相对竞争能力要大于离子草,且光照强度与氮肥施用水平不能改变它的竞争优势。     

转小鼠金属硫蛋白-Ⅰ基因聚球藻7002的生长潜力分析

以野生聚球藻7002为对照,从室温吸收光谱、光合放氧速率、生长动力学参数以及气升式光生物反应器中的生长特性阐述了转小鼠金属硫蛋白-Ⅰ基因聚球藻7002的生长优势和培养潜力.结果表明:转MT聚球藻室温可见光光谱吸收峰比野生藻略高;最大净光合速率和饱和光强比野生藻高,呼吸速率和补偿光强比野生藻低;转MT聚球藻摇瓶培养的最大细胞浓度为野生藻的1.74倍,具有较高的细胞生长速率;气升式光生物反应器有利于转MT基因聚球藻生长潜力的发挥.     

Growth and phycocyanin formation of Spirulina platensis in photoheterotrophic culture

Summary Glucose and acetate enhanced cell growth and phycocyanin production of S. platensis. The highest specific growth rate, cell concentration and phycocyanin production were respectively 0.62 d^-1, 2.66 g/l and 322 mg/l on glucose and 0.52 d^-1, 1.81 g/l and 246 mg/l on acetate. The specific growth rate of the alga on 2.5 g glucose/l was markedly increased with increasing light intensity up to 2 klux. Further increasing light intensity to 4 klux only resulted in a very slight increase in specific growth rate. At a light intensity above 4 klux, photoinhibition occurred. Light favoured phycocyanin formation. The highest phycocyanin content was obtained at a light intensity of 4 klux. When the light intensity decreased to 2 klux or less, the optimal glucose concentration for biomass production shifted from 2.5 g/l to 5.0 g/l.     

Response of Rhodopseudomonas capsulata to illumination and growth rate in a light-limited continuous culture.

Rhodopseudomonas capsulata was grown under anaerobic, photosynthetic conditions in a continuous culture device. Under light limitation, at a constant dilution rate, it was shown that cell composition, including photopigment (bacteriochlorophyll and carotenoids) and ribonucleic acid content, was not affected by incident light intensity; however, steady state culture density varied directly and linearly with light intensity. On the other hand, photopigment and ribonucleic acid levels were affected by growth rate regardless of light intensity. Additional experiments indicated a high apparent Ks for growth of R. capsulata with respect to light. These results were interpreted to mean that near the maximum growth rate (D = 0.45 h-1) some internal metabolic process became the limiting factor for growth, rather than the imposed energy limitation. A mathematical expression for the relation between steady-state culture density and dilution rate was derived and was found to adequately describe the data. A strong correlation was found between continuous cultures limited either by light or by a chemical energy source.     

The Influence of Light Intensity upon the Growth of an S. 37 Cocksfoot (Dactylis glomerata) Sward

A sward of S. 37 cocksfoot (Dactylis glomerata) was grown inthree different light intensities varied by means of muslinscreens. Decreasing the light intensity to 60 and 40 per centof full daylight decreased the growth-rate and the rate of tillerproduction, and so decreased competition between tillers andthe death-rate of tillers. Light intensity affected the areaof leaves but had no effect upon the number of leaves per tiller. The rate of increase in the total dry weight fluctuated becauseof loss through decay, and the rate of increase in the weightof green tissue was taken as a measure of the rate of assimilationby the swards. Since the growth-rate of the green tissue ateach light intensity varied little over a wide range of leafarea index, it seems that grass swards may be able to increasethe efficiency with which they use light by adaptation to achanging light environment as growth proceeds. The difficulties of performing a growth analysis in the presenceof the high and variable rates of senescence and decay of plantparts found on an established sward are discussed.     

High cell density culture of Anabaena variabilis with controlled light intensity and nutrient supply

Controlling the light energy and major nutrients is important for high cell density culture of cyanobacterial cells. The growth phase of Anabaena variabilis can be divided into an exponential growth phase and a deceleration phase. In this study, the cell growth in the deceleration phase showed a linear growth pattern. Both the period of the exponential growth phase and the average cell growth rate in the deceleration phase increased by controlling the light intensity. To control the light intensity, the specific irradiation rate was maintained above 10 micromol/s/g dry cell by increasing the incident light intensity stepwise. The final cell density increased by controlling the nutrient supply. For the control of the nutrient supply, nitrate, phosphate, and sulfate were intermittently added based on the growth yield, along with the combined control of light intensity and nutrient concentration. Under these control conditions, both final cell concentration and cell productivity increased, to 8.2 g/l and 1.9 g/l/day, respectively.     

Interrelationships between Light Intensity and the Physiological Effects of 2:4-Dichlorophenoxyacetic Acid on the Growth of Helianthus annuus

The interrelationships between light intensity and the effectsof sodium 2:4-dichlorophenoxyacetate on the growth of Helianthusannuus in the early vegetative stage have been studied by subjectingtreated and control plants to a range of light intensities from,1.0 to 0.12 daylight. The growth regulator in varying amountswas applied either as droplets of aqueous solution to the firstor second pairs of leaves or as an overall spray. When the amountof the compound is such as to cause small but significant reductionsin the relative growth rate, the leaf-area ratio and the ratioof leaf area to leaf weight are likewise depressed but the netassimilation rate is relatively unaffected. Between 0.25 daylightand full daylight the proportionate changes in the relativegrowth rate, leaf-area ratio, and net assimilation rate inducedby sub-lethal amounts of the growth regulator are not greatlymodified by the level of light. If the intensity is reducedfurther to 0.12 daylight, then the reactions of the shaded plantsdiffer markedly from those of unshaded plants. For example,when the plants are shaded both before and after a spray application,the concentration required to cause a 50 per cent. mortalityis one-tenth of that demanded for plants receiving full daylight.For less phytotoxic amounts the percentage reductions, relativeto the controls, induced in the growth rate of the shoot aremore dependent on the intensity after than before the applicationof either a spray or measured droplets. These greater depressions in shoot growth at 0.12 daylight afterthe application are linked with comparable depressions in therate of growth of the leaves of which the first pair are moresensitive. Similarly, the growth rate of the first internodeis also depressed more under shade conditions, but that of thesecond internode at low doses may be greatly increased. Forboth the leaves and internodes shading before as against shadingafter the application may have different significant effectson the changes in growth caused by the growth regulator. Undersome conditions the interactions between the light intensitybefore and after the application and the quantity of the growthregulator are exceedingly complex. By using sodium 2:4-dichloro-5-iodophenoxyacetatelabelled with radioactive I¹³¹, it has also been establishedthat the rate of penetration into leaves is accelerated by ahigh light intensity after the application, but that the intensityreceived prior to the application causes no significant effect.Evidence was also obtained that transport to the shoot fromthe treated leaf is more dependent on the light intensity afterthe application—the transport being greater in full daylight.It is concluded that a number of factors must be involved inbringing about these differential effects and their relativeimportance is discussed.     

Physiological and Ecological Studies in the Analysis of Plant Environment: IX. Adaptive Changes in the Vegetative Growth and Development of Helianthus annuus induced by an Alteration in Light Level

Pot experiments were carried out in which sunflowers in theearly vegetative phase were first grown for a period under threelevels of light (1·0, 0·5, and 0·24 daylight).Subsequently pots from each light group were subdivided intothree so that in a second period plants could be subjected tothe nine possible combinations of the same three light intensitiesbefore and after transference. During the post-transference period of adaptation to eithera higher or a lower intensity the net assimilation rate is logarithmicallyproportional to the light received and there is no residualeffect of the initial light treatments. Eight days after transferencethe leaf-area ratios (total leaf area/total plant weight) ateach light level become adjusted to a new equilibrium irrespectiveof the large initial differences in the ratio induced by thepre-transference intensities. In both periods there is an inverseand logarithmic relationship between the leaf-area ratio andfalling light intensity; consequently, the greater the degreeof shading in the pre-transference period, the higher are themean ratios in the second period. Since the relative growthrate is the product of the net assimilation rate and the leaf-arearatio, the variations in the leaf-area ratio in the post-transferenceperiod induced by the initial light treatments are reflectedin the relative growth rates. Thus plants transferred from alower to a higher light intensity are leafier and initiallygrow faster than plants maintained at the higher level in bothperiods: the converse conditions lead to a reduction in thegrowth rate. Shading depresses the growth of the roots, but the relativegrowth rate is dependent on the light intensity in both thepre-transference and post-transference periods. With transferencefrom daylight to 0·24 daylight, the roots during theperiod of adjustment may lose weight, while the growth rateis maximal when plants are moved from the lowest to the highestintensity. In two out of the three experiments the relativegrowth rate of the shoot in the post-transference period isof the same order at all light intensities and is largely independentof the light received in the initial period. In terms of leaf weight, decreasing the light intensity decreasesthe relative growth rate and there is no consistent after-effectof the initial light treatments. The rate of expansion in leafarea tends to be highest at the intermediate level of 0·5daylight and over all the post-transference intensities therates are maximal for those plants which received initiallyfull daylight. The ratio of leaf area to leaf weight is inversely and logarithmicallyproportional to the light level. After transference the slopesof the regressions are independent of the initial light treatments,but the mean ratios are inversely correlated with the initialdegree of shading. These adaptive changes to a variation in the light level arediscussed with particular reference to the control of growthexerted by growth-regulating substances. It is concluded thaton the basis of existing knowledge no adequate interpretationis yet possible.     

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.     

杉木和木荷种子萌发及幼苗生长对光梯度的响应

光是影响种子萌发和幼苗生长的关键因素.为理解不同树种种子萌发及幼苗生长对光梯度变化的响应机制,本文研究了不同光照强度(分别为自然光强的100%、60%、40%、15%和5%)对杉木和木荷种子萌发及幼苗生长的影响,探讨了两树种种子萌发和幼苗生长对光照响应的差异性.结果表明: 光照强度对两树种的种子萌发和幼苗生长均具有显著影响. 随着光照强度的减弱, 杉木种子萌发率增大,萌发指数增大,木荷种子萌发率和萌发指数则先增大后减小,在40%光照强度下达到最大值.两树种幼苗存活率在全光照(100%光照)下均为0,在5%～60%光照处理下则随着光照强度的减弱而显著降低.两树种幼苗根长、地径和株高对光梯度变化的响应趋势一致,随着光照强度的减弱,根长显著减小,地径和株高则先增大后减小,在5%光照强度下达到最小.随着光照强度的减弱,杉木幼苗根、茎、叶及总生物量降低,木荷幼苗生物量积累在15%～60%光照强度下较高, 5%光照强度下最小,且相同光照强度下,木荷幼苗各部分生物量均大于杉木.两树种幼苗应对低光环境时,表现出较大的茎和叶的生物量分配比,而根生物量比和根冠比降低.表明杉木苗期生长不耐阴,需要相对较强的光照,而木荷苗期具有较强的耐阴性,对弱光环境的适应性更强,能够在郁闭的林冠下定植和正常生长.     

Physiological and structural analysis of light-harvesting mutants of Rhodobacter sphaeroides.

Two mutants of Rhodobacter sphaeroides defective in formation of light-harvesting spectral complexes were examined in detail. Mutant RS103 lacked the B875 spectral complex despite the fact that substantial levels of the B875-alpha polypeptide (and presumably the beta polypeptide) were present. The B800-850 spectral complex was derepressed in RS103, even at high light intensities, and the growth rate was near normal at high light intensity but decreased relative to the wild type as the light intensity used for growth decreased. Mutant RS104 lacked colored carotenoids and the B800-850 spectral complex, as well as the cognate apoproteins. This strain grew normally at high light intensity and, as with RS103, the growth rate decreased as the light intensity used for growth decreased. At very low light intensities, however, RS104 would grow, whereas RS103 would not. Structural analysis of these mutants as well as others revealed that the morphology of the intracytoplasmic membrane invaginations is associated with the presence or absence of the B800-850 complex as well as of carotenoids. A low-molecular-weight intracytoplasmic membrane polypeptide, which may play a role in B800-850 complex formation, is described, as is a 62,000-dalton polypeptide whose abundance is directly related to light intensity as well as the absence of either of the light-harvesting spectral complexes. These data, obtained from studies of mutant strains and the wild type, are discussed in light of photosynthetic membrane formation and the abundance of spectral complexes per unit area of membrane. Finally, a method for the bulk preparation of the B875 complex from wild-type strain 2.4.1 is reported.     

光照强度对广西地不容光合特性和生长的影响

以盆栽当年生广西地不容为材料,研究不同光照强度(100%、50%、30%和15%自然光强)对其光合特性和生长的影响。结果表明:随着光照强度的降低,广西地不容最大净光合速率(P_(max))、光饱和点(LSP)、光补偿点(LCP)先减小,而后稍有增大;表观量子效率(AQY)在30%和50%光强下显著高于100%和15%光强处理;叶片叶绿素总量(Chl)、叶绿素a(Chla)、叶绿素b(Chlb)、类胡萝卜素(Car)含量随光强的减弱而增大,Car/Chl随光强的减弱而减小,Chla/Chlb比值在各处理间无显著差异;单叶面积随生长光强的减弱而增大,比叶重(LMA)则随着生长光强的减弱而减小;30%光强下广西地不容块根生物量最高,光照过强和过弱都不利于其生物量的积累。广西地不容对光强的适应范围较广,但光照过强或过荫均对生长造成不良影响,光合速率降低,生长减缓,块根生物量积累下降,30%光强是其当年生苗生长的最佳光强。     

Diatom growth responses to photoperiod and light are predictable from diel reductant generation

Light drives phytoplankton productivity, so phytoplankton must exploit variable intensities and durations of light exposure, depending upon season, latitude, and depth. We analyzed the growth, photophysiology and composition of small, Thalassiosira pseudonana, and large, Thalassiosira punctigera, centric diatoms from temperate, coastal marine habitats, responding to a matrix of photoperiods and growth light intensities. T. pseudonana showed fastest growth rates under long photoperiods and low to moderate light intensities, while the larger T. punctigera showed fastest growth rates under short photoperiods and higher light intensities. Photosystem II function and content responded primarily to instantaneous growth light intensities during the photoperiod, while diel carbon fixation and RUBISCO content responded more to photoperiod duration than to instantaneous light intensity. Changing photoperiods caused species‐specific changes in the responses of photochemical yield (e^?/photon) to growth light intensity. These photophysiological variables showed complex responses to photoperiod and to growth light intensity. Growth rate also showed complex responses to photoperiod and growth light intensity. But these complex responses resolved into a close relation between growth rate and the cumulative daily generation of reductant, across the matrix of photoperiods and light intensities.     

弱光胁迫对不同生育期番茄光合特性的影响

以耐弱光番茄品系02S02、02S32和不耐弱光番茄品系02S52、02S57为材料,以普通塑料大棚光照环境为对照(晴天9:00-11:00平均光强约为800 μmol·m^-2·s^-1),普通塑料大棚上覆盖一层黑色遮阳网模拟弱光环境(光强约为对照的50%),研究弱光对4个番茄品系苗期、开花座果期、果实膨大期光合特性的影响.结果表明：弱光环境下,4个番茄品系叶片光合速率在低光强下略有增加,超过此光强后大幅下降,不同品系在不同生育期的变化趋势一致,但变化幅度不同;叶片光补偿点和暗呼吸速率随发育进程逐渐降低,耐弱光品系的降幅均大于不耐弱光品系;叶片光饱和点、最大光合速率和表观量子效率在不同生育期均有所降低,但变化幅度不同,且与品系的弱光耐受性无一致性关系.