The Effect of Chromium on the Photosynthesis and Growth of Diatoms and Green Algae

The effect of hexavalent chromium ions on the photosynthesis and growth of the diatom Nitzschia palea and the green alga Chlorella pyrenoidosa has been studied and compared with the effect of Cu and Hg. The effect of chromium is very similar to that of Cu and Hg, but it is more than one hundred times less toxic for the algae than copper. The toxicity of chromium is not counteracted by adding Fe to the culture solution. The problems regarding cleaning glass-ware in dichromate-sulphuric acid are discussed and it is strongly recommended to use other cleaning agents.     

Influence of Deleterious Concentrations of Copper on the Growth of Chlorella pyrenoidosa

The effect of deleterious concentrations of ionic Cu on the growth of Chlorella pyrenoidosa has been studied. An earlier paper showed a distinct effect of the same concentrations on the photosynthesis of the alga. Several substances, e.g. Fe and citric acid counteract the effect of Cu. In media ordinarily used for growing unicellular algae the influence of Cu is relatively slight due to the extraordinarily large concentrations. of Fe. At a concentration of 6 μg/I Fe – near to that in nature –even one μg/I Cu significantly decreases the growth during the first 24 hours. Cu is adsorbed to the negative charges on micelles of Fe(OH)₃ created in the alkaline medium. Citric acid is readily assimilated by Chlorella and thus counteracts the influence of Cu for only relatively short period. Cell concentration is of decisive importance for the deleterious influence of Cu on growth. The effect of a certain Cu concentration stops at a certain concentration of of the algae regardless of whether the experiment is started at this cell concentration or this concentration is attained during the experiment. This is due to the binding of Cu by the organic matter of cell walls and slime envelopes. H⁺ ions compete with Cu both when combining with the organic matter in the cell walls and when occupying the active sites of the cell membranes. The latter explains the fact that the influence of Cu is only slight at pH 5 compared with that at pH 8. At a Cu-concentration where no growth of algae can take place, the algae are by no means killed. After being transferred to an ordinary medium the algae start to grow again. The influence of Cu depends on the division stage of the algae. If the initial steps of cell division have taken place, the cell continues to divide.     

Physiologische Untersuchungen an einer ungewöhnlich säureresistenten Chlorella

Summary The influence of the hydrogen-ion concentration on the growth and metabolism of a highly acid-resistant green alga, Chlorella ellipsoidea (strain Marburg St), was studied. Chlorella pyrenoidosa (Emerson strain) served as a normal control organism. Growth of Chlorella ellipsoidea occurs in the entire range from Ph 2.0 to Ph 10, whereas for Chlorella pyrenoidosa the limits were found to be Ph 3.5 and Ph 10. Respiration is much less sensitive to hydrogen-ion concentration in the acid-resistant as compared to the normal strain. Thus an increase in acidity from Ph 4.0 to Ph 2.0 increases the respiratory oxygen uptake by 120% in Chlorella pyrenoidosa and by 25% in Chlorella ellipsoidea. In addition, only the less resistant Chlorella pyrenoidosa shows an accumulation of nitrite in the dark in acid culture media, indicating a disturbance of the normal course of nitrate reduction under these conditions. On the other hand, the rate of photosynthesis of both organisms was found to be almost independent of acidity between Ph 4.0 and Ph 2.0. At the acid and alkaline limits of growth in both algae, an inhibition of cell division leads to an increase of cell size and dry weight per cell, frequently connected with the occurrence of bizarre giant cells. — In addition, adaptation phenomena were found to play a role in determining the acid limit of growth. Cells of Chlorella ellipsoidea, after inoculation from normal medium (Ph about 6) into a solution of Ph 2.0, begin growth at a high rate only after a lag of about two weeks. Cells grown previously in an acid medium, however, immediately resume growth upon inoculation into a medium of Ph 2.0. This adaptation involves a considerable reduction of cell size.     

Cultivation in the Dark of the Blue-green Alga Fremyella diplosiphon. A Photoreversible Effect of Green and Red Light on Growth Rate

The blue-green alga Fremyella diplosiphon Drouet can be grown in the dark on a medium consisting of mineral salts, glucose, and casein hydrolysate. A variety of organic substances was tested for effectiveness as a carbon or nitrogen source. The most effective individual compounds were glucose and citrulline, respectively. A daily irradiation of 5 min green light depresses the dark growth rate. The effect of green is reversible by brief irradiation with red light, and multiple photoreversibility was demonstrated. This green, red-reversible effect on dark growth rate may be related to other photomorphogenic responses to brief irradiation with green and red in the Cyanophyta. A master photoreversible pigment similar to phytochrome is a possible photoreceptor for these effects.     

ALLELOPATHIC GROWTH INHIBITION OF SELECTED PHYTOPLANKTON SPECIES BY SUBMERGED MACROPHYTES1

Allelopathic effects of submerged macrophytes on the growth and photosynthesis of different unialgal cultures of planktonic cyanobacteria, a diatom, and a green alga were tested in coexistence experiments using dialysis cultures. The method applied allowed measurements under conditions similar to that in lakes but without nutrient and light limitation. Growth and photosynthesis were measured with a pulse amplitude modulated fluorometer as an increase of chl a fluorescence and activity of PSII, respectively. Eurasian water milfoil Myriophyllum spicatum L. and rigid hornwort Ceratophyllum demersum L. proved to inhibit the PSII activity and then growth of the investigated phytoplankton species, whereas sago pondweed Potamogeton pectinatus L. showed no effect. Growth inhibition was dependent on biomass of M. spicatum. Considerable differences between phytoplankton groups and among species of cyanobacteria were found regarding their response to M. spicatum. Members of the Oscillatoriales and Microcystis aeruginosa Kütz. emend. Elenkin were more sensitive than the cyanobacterium Aphanizomenon flos‐aquae Ralfs ex Born. et Flah., the diatom Stephanodiscus minutulus (Kütz) Cleve et Möller, and the green alga Scenedesmus armatus Chodat. A possible contribution of this result to changes in the phytoplankton succession of lakes after loss of macrophytes is discussed.     

The Influence of CO2 Concentration and pH on Two Chlorella Species Grown in Continuous Light

Both Chlorella pyrenoidosa and Chlorella vulgaris grow equally well at 20°C aerated with ordinary air or mixtures of air with 5 or 12 per cent CO₂ (5 klux continuous light). Whereas C. vulgaris relatively rapidly adapts to a higher CO₂ tension, adaptation takes about 24 hours for C. pyrenoidosa. In Chlorella vulgaris pH in the range 3.6–7.6 has no apparent influence on the rate of photosynthesis in experiments having a duration of two hours. This is true both for algae grown aerated by ordinary air and for algae grown with a mixture of 5 per cent CO₂ in air. The adaptation time must be short. In Chlorella pyrenoidosa the same is found for algae in ordinary air, whereas an influence of pH is seen in some experiments where the aeration was by 5 per cent CO₂ in air. As is to be expected, the rate of photosynthesis in C. pyrenoidosa during the first two hours is very much influenced by the concentration of free CO₂. The highest rate is found at the CO₂ concentration at which the algae had been growing previously. The influence on the rate of photosynthesis in C. vulgaris is very much less, although in principle the same. The investigation of the corresponding influence on the rate of respiration is complicated by considerable variation from one series to another. In C. vulgaris this is particularly of importance. In C. pyrenoidosa, the highest rate of respiration is generally found at the CO₂-concentration at which the alga had been growing before the experiment. It seems probable that variations between similar series is due to the fact that the algae were grown in continuous light but with dilution with fresh culture medium when the optical density had reached a certain magnitude. Algae grown in this way are neither synchronized nor non-synchronized.Our thanks are due to the Danish State Research Foundation for financial support.     

Mechanisms of response to salinity in halotolerant microalgae

Summary A limited number of organic solutes are used by microalgae to adjust their internal osmotic pressure in response to changing external salinities. Glycerol and proline are used by the most extremely halotolerant algae. Only glycerol allows growth at salinities approaching saturation. In addition to organic osmoregulatory solutes, inorganic ions also play an important role in osmoregulation. The ability of microalgae to maintain intracellular ions at levels compatible with metabolic functions may set upper limits for their salt tolerance. Requirements for NaCl in the external medium for nutrient transport may define the lower salinity limits for growth observed for some euryhaline algae.Osmotic upshocks generally cause severe temporary inhibition of photosynthesis in euryhaline microalgae. Extensive osmotic downshocks have little effect on photosynthesis in microalgae with strong cell walls, while wall-less species appear to be more sensitive. Rapid glycerol synthesis takes place in response to increased external salinity inChlamydomonas pulsatilla both in light and dark. Starch supplies carbon for glycerol synthesis in the dark and also during the initial periods of inhibition of photosynthesis in the light. Turnover of osmoregulatory solutes such as glycerol and isofloridoside may be an important aspect of the osmoregulatory mechanism.At salinities beyond the growth limit for the green flagellateChlamydomonas pulsatilla, resting spores are formed that enable this alga to survive extreme salinities.     

Art und Menge der Ausscheidung 14C-markierter Verbindungen bei Chlorella pyrenoidosa unter dem Einfluss des osmotischen Drucks der Nährlösung

Chlorella pyrenoidosa was labelled by ¹⁴CO₂ and the nature and amount of excreted organic compounds in nutrient media of different osmotic pressure were determined after a 24 h period. The total rate of excretion of organic bound ¹⁴C was about 4 μg ¹⁴C per mg harvested algal dry matter or 1% of the total ¹⁴C content of the algae at the beginning of the excretion period. The main compounds found in the excretions were unidentified substances with a molecular weight higher than 700, amino acids, organic acids and sugars. The osmotic pressure of the nutrient medium did not affect the total amount of the organic excretions. However, the excreted amounts of some specific compounds differed in respect to the osmotic conditions of the nutrient medium.     

Photosynthetic and growth responses of three freshwater algae to phosphorus limitation and daylength

1. Three common species of freshwater phytoplankton, the diatom Nitzschia sp., green alga Sphaerocystis schroeteri and cyanobacterium Phormidium luridum, were grown under contrasting daylengths [18 : 6 h light : dark cycles (LD) versus 6 : 18 h LD] and phosphorus (P) regimes (P‐sufficient versus 1 μm P). The rates of growth and photosynthesis, as well as growth efficiencies and pigment concentrations, were compared among treatments. 2. The growth and photosynthetic parameters of the three species depended on both P status and daylength in a species‐specific way. The responses to P limitation depended on daylength and, conversely, the responses to daylength depended on P status. 3. Growth rates and the maximum rates of photosynthesis (P_max) of all species decreased under P limitation under both light regimes. However, the decrease of P_max because of P limitation was greater under long daylength. The P_max of the green alga S. schroeteri decreased the most (ca. sixfold) under P limitation compared with the other two species. The photosynthesis saturation parameter I_k also decreased under P limitation; the decline was significant in Nitzschia and Sphaerocystis. P‐limitation significantly increased photoinhibition (β) in Nitzschia and Sphaerocystis, but not in Phormidium. The excess photochemical capacity (the ratio of the maximum photosynthesis rate to the photosynthesis rate at the growth irradiance), characterising the ability to utilise fluctuating light, was significantly lower under P limitation. 4. The growth efficiency (growth rate normalised to daylength) declined with increasing daylength in all species. Under short daylength the cyanobacterium Phormidium had the lowest growth efficiency of the three species. 5. The cellular chlorophyll a concentration in both Nitzschia and Sphaerocystis was significantly higher under short daylength, but only under P‐sufficient conditions. In Nitzschia, under short daylength, P‐limitation significantly decreased cellular chlorophyll concentration. In contrast, P‐limitation increased cellular chlorophyll concentration in Sphaerocystis, but under long daylength only. The ratio of chlorophyll a to b in the green alga also declined under short daylength and under P‐limited conditions.     

Einfluss verschiedener Lichtwellenlängen auf die Zusammensetzung von Chlorella in Glucosekultur bei gehemmter Photosynthese

Summary Increasing blue light intensity inhibits the growth of Chlorella pyrenoidosa in glucose culture in which photosynthesis is blocked by DCMU, whereas red light supports growth which is the same as or better than that in dark controls.The action spectrum of light induced protein synthesis from exogenous glucose (photosynthesis inhibited, blue light addition resulting in growth >90% of the dark control) shows only one broad maximum at 450–490 nm which resembles the absorption spectrum of carotenoids.     

The Effect of Deleterious Concentrations of Copper on the Photosynthesis of Chlorella pyrenoidosa

If a single salt solution of CuSO₄ is used, Cu penetrates immediately iuto the plasma of Chlorella cells, reducing the rates of photosynthesis at both high and low illumination. If CuSO₄ is added to ordinary Österlind culture-medium (pH 8) it takes some hours before any influence of deleterious concentrations of Cu is observed and initially only at light saturation. The algae must have been illuminated during the whole period. Maximum influence of CuSO₄ is found duriug the first 24 hours of treatment. A significant deleterious influence of Cu concentrations as low as about 1 μg/l is found. The influence of Cu increases with decreasing concentrations of the alga. If a culture medium at pH 5 is used instead of the ordinary one at pH 8, copper concentrations ahout 10 times as high must he used be order to obtain the same deleterious effect. An increase of the cotncentration of K reduces the influence of Cu to some extent. These facts show that the effect of deleterious concentrations of Cu in halanced solutions is not due to a marked penelration of this ion into the plasma but to a binding to the cytoplasmic membrane whereby the celts i.a. become more or less unable to divide. The cells become saturated with assimilation products which have a depressant effect on the rate of photosynthesis. Other cations compete with Cu for the “active sites” on the membranes.     

氮、锰、硫缺乏对蛋白核小球藻Chlorella pyrenoidosa光合产氢及其生长的影响

本实验通过研究缺氮、缺锰和缺硫对蛋白核小球藻Chlorella pyrenoidosa产氢的影响,发现缺氮、缺锰及缺硫条件下该藻均能产氢,但在缺氮条件下产氢量最高,约为88.613μL H2/mgChla,分别是对照组、缺锰和缺硫实验组产氢量的4.61倍、1.92倍和3.63倍。通过对光合、呼吸及生长的比较研究,发现缺锰对该藻光合、呼吸及生长的影响要小于缺氮和缺硫;与正常培养条件相比,缺锰、缺硫抑制藻细胞的光合放氧和生长,对呼吸影响小,而缺氮不仅最大程度抑制光合放氧和生长,同时使呼吸作用增强,这为进一步优化该藻产氢条件及研究其产氢机制提供了线索。     

THE UPTAKE OF MANNITOL AND SORBITOL BY A SPECIES OF CHLORELLA (CHLOROPHYCEAE)1

Chlorella saccharophila (Krüger) Nadson takes up mannitol and sorbitol in the light and the dark. The rate of uptake is concentration dependent. is not affected by pH in the range pH 6.0 to 8.0 and ii not stimulated by light. Uptake is inhibited by the respiration inhibitor sodium azide (10^-2 M) but not by 3-(3,4-dichlorophenyl)-1,1-di-methyl urea (10^-6 M), an inhibitor of photosynthesis. Sorbitol. but not mannitol, stimulates the rate of dark respiration but both support the heterotrophic growth of the alga. Both compounds permeate the cells of C. miniata. and two strains of C. pyrenoidosa but do not support the heterotrophic growth of these algae. The cells of C. vulgaris are impermeable to both compounds.     

Responses of Heterotrophic Cultures of Chlorella vulgaris Beyerinck to Darkness and Light. II. Action Spectrum for and Mechanism of the Light Requirement for Heterotrophic Growth

Chlorella vulgaris Beyerinck (Emerson's strain), fails to grow in the dark even when sugars are provided. This phenomenon was clearly demonstrated in the alga, C. vulgaris, for which the growth rate in darkness on a glucose medium remained constant for 2 days and then declined to approach zero. Pigment concentrations also declined in darkness. Changes in flow rate of 1% CO₂-in-air from zero to 7 ml per minute caused a progressive increase in the dark growth rate over a 5-day period, but did not maintain growth in the dark. Rates above 7 ml per minute produced no changes in growth rates.

White light intensities below the compensation point of the alga maintained heterotrophic growth. The saturation value for this response was 0.8 μw/cm². White light also initiated growth in nongrowing cultures transferred from darkness to light.

The action spectrum for heterotrophic growth indicated a porphyrin as the active pigment. Light in the 425 mμ region was 4 times as effective as white light in stimulating heterotrophic growth. A secondary peak of growth stimulation occurred in the 575 mμ region.

The respiration of glucose by the alga was stimulated by low intensities of white light. This response was not immediate, but was clearly present after the third day of incubation.

Malonate and cyanide were inhibitory to growth of C. vulgaris on inorganic medium or glucose medium under 300 ft-c of white light. These data suggested that succinic dehydrogenase and cytochrome oxidase systems were present.

Substances inhibitory to growth were excreted into the medium under dark-growth conditions, and 2 of these substances were indentified as formic and acetic acids.

The evidence suggested that respiration of glucose cannot proceed for an extended period of time in darkness. The reason for this is postulated to be the lack of a cytochrome or a cytochrome precursor.

     

Effects of heavy metals on Tetraselmis suecica: Ultrastructural and energy-dispersive X-ray spectroscopic studies

The influence of metal contamination on the marine alga Tetraselmis suecica was investigated at physiological and ultrastructural levels. For this analysis, the growth response of this microalga was studied after the addition of various concentrations of heavy metals (Cd, Cu). The concentration corresponding to 50% growth inhibition (IC₅₀) and the number of days per cell cycle (Td) studied, revealed that the toxic effects of copper are heavier than those of cadmium. In the case of copper contamination, the Td grows with increasing metal concentration in the culture medium, while it remains unchanged during the cadmium contamination. The toxicity of cadmium, only observed in the latency phase of growth, suggests an adaptation phenomenon of T suecica to this metal. Ultrastructural changes in response to pollutants were investigated; copper induced cytoplasmic vacuolisation, organelle changes, appearance of cells with multilayered cell walls and excretion of organic matter. In the case of cadmium contamination, ultrastructural changes mainly affected the osmiophilic vesicles, of which both number and volume increased with increasing metal concentration in the culture medium. The results of X-ray microanalysis revealed that Cd and Cu were strongly present in excreted organic matter and osmiophilic vesicles. The latter can be excreted during cell division, thus participating in detoxification processes. Intracellular cadmium incorporation proved that some toxic effects of this metal are a result of interaction with endogenous cellular constituents. In the case of copper contamination, the presence of copper in walls of a multilayered cell suggests that these structures constitute an additionnal adsorbing area for this element, reducing metal free concentration in the medium. Mechanisms of metal detoxification of Tetraselmis suecica are discussed.     

Bioenergetic and metabolic processes for the survival of sulfur-deprived Dunaliella salina (Chlorophyta)

The work addressed bioenergetic, metabolic and physiological responses ofthe green alga Dunaliella salina to sulfur (S)-deprivation. Photo-autotrophically grown cells were suspended in a medium in which thesulfates were replaced by chloride salts. Growth characteristics, pigmentcontent, rates of photosynthesis and respiration, as well as endogenoussubstrate (starch and protein) accumulation were monitored as a functionof time under S-deprivation. Lack of S from the growth medium had adifferential effect on photosynthesis and respiration. The rate oflight-saturated photosynthesis declined semi-exponentially with time,whereas the activity of respiration remained fairly constant over a periodof up to 100 h in S-deprived medium. Cell division and `packed cell volumeincrease' declined in tandem with the decline in the rate of photosynthesis. There was gradual loss of chlorophyll from the cells and a concomitant lossof photochemically competent system-II reaction centers, whereas theconcentration of system-I remained largely unaffected under S-deprivation. Cells altered the partition of photosynthate between starch and protein sothat control steady-state starch/protein ratios in the light (0.1: 1, w: w)gradually increased up to about 1: 1 as a function of S-deprivation. SealedDunaliella salina cultures, in which the capacity of photosynthesisdeclined to levels lower than that of respiration, consumed dissolvedoxygen and became anaerobic in the light. These cultures, however, did notactivate the reversible `hydrogenase pathway' and did not produceH₂ gas. Instead, under extended S-deprivation, cells maintained alow-level cycling of O₂ and CO₂ between photosynthesis andrespiration that resulted in no net exchange of gases. Such low-level cyclingof photosynthesis and respiration was sufficient to ensure the generation ofATP needed for survival of the organism under protracted S-deprivationconditions.     

Responses of Two Coastal Algae (Skeletonema costatum and Chlorella vulgaris) to Changes in Light and Iron Levels1

Iron (Fe) is essential for phytoplankton growth and photosynthesis, and is proposed to be an important factor regulating algal blooms under replete major nutrients in coastal environments. Here, Skeletonema costatum, a typical red-tide diatom species, and Chlorella vulgaris, a widely distributed Chlorella, were chosen to examine carbon fixation and Fe uptake by coastal algae under dark and light conditions with different Fe levels. The cellular carbon fixation and intracellular Fe uptake were measured via ¹⁴C and ⁵⁵Fe tracer assay, respectively. Cell growth, cell size, and chlorophyll-α concentration were measured to investigate the algal physiological variation in different treatments. Our results showed that cellular Fe uptake proceeds under dark and the uptake rates were comparable to or even higher than those in the light for both algal species. Fe requirements per unit carbon fixation were also higher in the dark resulting in higher Fe: C ratios. During the experimental period, high Fe addition significantly enhanced cellular carbon fixation and Fe uptake. Compared to C. vulgaris, S. costatum was the common dominant bloom species because of its lower Fe demand but higher Fe uptake rate. This study provides some of the first measurements of Fe quotas in coastal phytoplankton cells, and implies that light and Fe concentrations may influence the phytoplankton community succession when blooms occur in coastal ecosystems.     

Differential sensitivity of green algae to allelopathic substances from Chara

Three short-term laboratory experiments were conducted to investigate allelopathic effects of a mixture of Chara globularis var. globularis Thuillier and Chara contraria var. contraria A. Braun ex Kützing on three different green algae. Single phytoplankton species were exposed to filtered water originating from charophyte cultures. Phytoplankton growth was monitored by determination of chlorophyll concentrations in batch cultures. The change in chlorophyll concentration during the experiments was analysed with a logistic growth model, resulting in an estimate of the exponential growth rate and the duration of the lag phase of the single green algae. The results indicate allelopathic effects of Chara on the growth of the green algae Selenastrum capricornutum Printz and Chlorella minutissima Fott et Nováková, whereas Scenedesmus obliquus (Turpin) Kützing did not seem to be affected. The exponential growth rate of S. capricornutum decreased 7% in the presence of water from a charophyte culture, while the growth rate of C. minutissima decreased with 3%. The allelopathic effect of Chara did not increase when the green alga C. minutissima was P-limited. The effect of Chara was different when young sprouts were used. With young sprouts the duration of the lag phase of C. minutissima was extended (25%), whilst for old plants the growth rate of this green alga decreased. Although the inhibiting effect of charophytes on specific phytoplankton species is rather small, the differential sensitivity of the species to Chara might influence the composition and biomass of phytoplankton communities in the field.     

ALGAL EXCRETION AND BACTERIAL ASSIMILATION IN HOT SPRING ALGAL MATS1

Benthic algal-bacterial mats are present in the effluents of alkaline hot springs at temperatures between 50 and 73 C. The thin surface layer is composed of the unicellular blue-green alga Synechococcus lividus. Also present in the surface layer and forming thick, orange mats beneath it, are filamentous, phototrophic, gliding bacteria of the genus Chloroflexis, also capable of heterotrophic growth. The very low species diversity and the constancy of the hot spring environment, make these mats a good ecosystem for studying the transfer of nutrients from the algae to the bacteria. To determine whether the alga might supply organic materials to the bacterium, excretion by natural populations of S. lividus was studied in the field by means of short-term radioisotope experiments. Under optimal conditions for photosynthesis, between 3 and 12% of the total ¹⁴C fixed was excreted as ¹⁴C-labeled organic compounds. Variations in cell density at concentrations of S. lividus approximating those found in the mat had no effect on the percentage excretion. However, at cell densities below a threshold, level, the percentage excretion increased with diminishing cell density. Except at very low light intensities the percentage of fixed carbon excreted, was very similar for all light intensities tested. Excretion at temperatures approaching the upper limit for growth was not significantly different from the percentage excretion values observed at lower temperatures. ¹⁴C-labeled organic compounds excreted during algal photosynthesis could be subsequently assimilated by natural populations of the bacteria present in the mat.     

Activity of salicylic acid on the growth and biochemism of Chlorella vulgaris Beijerinck

This study was conducted to investigate the influence of salicylic acid (SA) on the growth and changes of nucleic acids, protein, photosynthetic pigments, sugar content and photosynthesis levels in the green alga Chlorella vulgaris Beijerinck (Chlorophyceae). The most significant changes in the content of nucleic acids and proteins was observed at the concentration 10⁻⁴ M SA between 8 and 12 day of cultivation. This concentration of SA increased the number of cells (about 40 %) and content of proteins (about 60 %) and its secretion to the medium. The slight stimulation of protein secretion occurred on the 12th day of cultivation at concentration 10⁻⁴ M, while in the range of 10⁻⁵ M to 10⁻⁶ M the protein secretion was inhibited. SA also stimulated the content of nucleic acids, especially RNA by 20–60 %, compared with the control. The most stimulating influence upon the contents of chlorophylls a and b (50–70 %), total carotenoids (25–57 %), sugar (27–41 %) and intensity of net photosynthesis (18–33 %) was found at 10⁻⁴ M of SA. At the concentration of 10⁻⁶ M SA the slight inhibition of growth and biochemical activity of the algae was recorded at the first days of cultivation.