Phycocyanobilin synthesis in the unicellular rhodophyte Cyanidium caldarium.

A method for the determination of the half-life of mitochondrial translation products in yeast in vivo is proposed. The method uses inhibitors of cytoplasmic and mitochondrial protein synthesis and is based on double-labelling pulse-chase techniques, the second label being used to estimate 'post-incorporation' during the 'chase'. For the first time the difference between post-incroporation and the widely known recycling of the label is considered. These studies show that, in the turnover of mitochondrial translation products, the problem is of post-incorporation into mitochondria (especially from the cell sap) is predominant. The results obtained with this procedure indicate that the half-life of the products of mitochondrial protein synthesis in yeast at the late-exponential phase is about 60 min. The results suggest that mitochondrial transplantation products are subject to proteolysis to acid-soluble forms.     

Bile pigment synthesis in plants. Incorporation of haem into phycocyanobilin and phycobiliproteins in Cyanidium caldarium.

A procedure was developed whereby haem was taken up by dark-grown cells of the unicellular rhodophyte Cyanidium caldarium. These cells were subsequently incubated either in the dark with 5-aminolaevulinate, which results in excretion of phycocyanobilin into the suspending medium or incubated in the light, which results in synthesis and accumulation of phycocyanin and chlorophyll a within the cells. Phycocyanobilin was isolated from phycocyanin by cleavage from apoprotein in methanol. Phycocyanobilin prepared from phycocyanin or excreted from cells given 5-aminolaevulinate was methylated and purified by t.l.c. By using 14C labelling either in the haem or in 5-aminolaevulinate administered, haem incorporation into phycocyanobilin was demonstrated in both dark and light systems. Since chlorophyll a synthesized in the light in the presence of labelled haem contained no radioactivity, it was clear that haem was directly incorporated into phycocyanobilin and not first converted into protoporphyrin IX. These results clearly demonstrate phycocyanobilin synthesis via haem and not via magnesium protoporphyrin IX as has also been postulated.     

Incorporation of haem into phycocyanobilin in levulinic acid treated Cyanidium caldarium

Cells of the red alga Cyanidium caldarium were preincubated with 5 mmol 1^–1 levulinic acid (LA) and subsequently incubated with ¹⁴C-labelled haem (5.67 Bq nmol^–1). Phycocyanin was isolated. The specific radio-activity of its chromophore phycocyanobilin (PCB) was determined after cleavage and purification by thin layer chromatography. The percentage of PCB formed from labelled haem within 0.5 h was considerably higher in LA treated cells than in non-treated controls. This difference disappeared after prolonged incubation (16.5 h) with haem. The results are interpreted as possible incorporation of haem into preexisting apoprotein.Abbreviations LA levulinic acid - PCB phycocyanobilin     

Biosynthesis of delta-aminolevulinic acid in the unicellular rhodophyte, cyanidium caldarium.

Intravenous injection of sheep antiserum to somatostatin in the rat not only increases basal plasma TSH levels but also potentiates TSH response following exposure to cold (5° C). Plasma levels of GH rise 2–3 fold during the first 3 h after injection of the antiserum, with a progressive decrease of the effect up to 10 h. Rhythmical change of serum GH levels during a 10-hour period of observation is not altered after antiserum injection. These data indicate that somatostatin plays a physiological role in the control of both TSH and GH secretion and suggest the involvement of GH-releasing hormone, in addition to somatostatin, in the GH release mechanism.     

Biosynthesis of phycocyanobilin from exogenous labeled biliverdin in Cyanidium caldarium

Phycocyanin is a major light-harvesting pigment in bluegreen, red, and cryptomonad algae. This pigment is composed of phycocyanobilin chromophores covalently attached to protein. Phycocyanobilin is an open-chain tetrapyrrole structurally close to biliverdin. Biliverdin is formed in animals by oxidative ring-opening of protoheme. Recent evidence indicates that protoheme is a precursor of phycocyanobilin in the unicellular rhodophyte, Cyanidium caldarium. To find out if biliverdin is an intermediate in the conversion of protoheme to phycocyanobilin, [14C]biliverdin was administered along with N-methylmesoporphyrin IX (which blocks endogenous protoheme formation) to growing cells of C. caldarium. To avoid phototoxic effects due to the porphyrin, a mutant strain was used that forms large amounts of both chlorophyll and phycocyanin in the dark. After 12 or 24 h in the dark, cells were harvested and exhaustively extracted to remove free pigments. Next, protoheme was extracted. Phycocyanobilin was then cleaved from the apoprotein by methanolysis. Protoheme and phycocyanobilin were purified by solvent partition, DEAE-Sepharose chromatography, and preparative reverse-phase high-pressure liquid chromatography. Absorption was monitored continuously and fractions were collected for radioactivity determination. Negligible amounts of label appeared in the protoheme-containing fractions. A major portion of label in the eluates of the phycocyanobilin-containing samples coincided with the absorption peak at 22 min due to phycocyanobilin. In a control experiment, [14C]biliverdin was added to the cells after incubation and just before the phycocyanobilin-apoprotein cleavage step. The major peak of label then eluted with the absorption peak at 12 min due to biliverdin, indicating that during the isolation biliverdin is not converted to compounds coeluting with phycocyanobilin. It thus appears that exogenous biliverdin can serve as a precursor to phycocyanobilin in C. caldarium, and that the route of incorporation is direct rather than by degradation and reincorporation of 14C through protoheme.     

Heterotrophic growth patterns in the unicellular alga Cyanidium caldarium

A strain of Cyanidium caldarium has been studied which is able to grow in darkness using amino acids as sole energy sources. During growth ammonia was released into the external medium as a catabolic end product. With either threonine or glutamate similar rates of ammonia formation and similar kinetics of growth were observed. These observations suggest that the amounts of energy made available for cell growth from the two amino acids are equivalent.Deamination of threonine and glutamate by whole cells exhibited similar temperature-dependence profiles and similar Arrhenius energies of activation. Thus it is suggested that a partially common pathway is involved in the catabolism of these amino acids. Threonine dehydrase may play a role in this pathway.The threonine dehydrase of C. caldarium was inhibited by isoleucine and activated by valine. In the absence of isoleucine no cooperative effect of threonine was observed.Succinate or 2-ketoglutarate supported a faster growth than did amino acids. Growth tests in the presence of both a krebs cycle intermediate and an amino acid have shown that the oxidative metabolism of amino acids is in some way controlled by the more suitable energy sources, presumably through catabolite inhibition and catabolite repression.     

Revision of Cyanidium caldarium. Three species of acidophilic algae

Abstract

The authors carry out a systematic revision of three unicellular eucaryotic algae, often living in mixed population in thermal acidic environment. Such algae were often confused under the binomium Cyanidium caldarium.

The authors state that the following specific binomia are to be attributed to the three algae: Galdieria sulphuraria (Galdieri) Merola comb. nova; Cyanidium caldarium Geitler non (Tilden) Geitler emend.; Cyanidioschyzon merolae De Luca, Taddei & Varano.

The family Galdieriaceae is instituted for the first of these algae, whereas the other two algae are included in the family Cyanidiaceae Geitler emend.

The class Cyanidiophyceae Merola, a new class of the Rhodophyta, is instituted for these two families.     

Mechanism of aluminium tolerance in Cyanidium caldarium

Cyanidium caldarium, an acidophilic, thermophilic red alga, specifically tolerates Al. The tolerance increases at lower culture temperatures. The intracellular Al concentration is kept at low levels, especially when the cells are cultured at lower temperatures. Lower Al incorporation accounts for the Al tolerance in this alga. Fe incorporation antagonizes the Al incorporation, implying that Fe transporters incorporate Al ions. Treatment with an uncoupler, carbonylcyanide m-chlorophenylhydrazone, increases the intracellular concentration of Al. These results support the hypothesis that Al ions taken up by the algal cells are exported by an energy-dependent mechanism.     

Enzymatic heme oxygenase activity in soluble extracts of the unicellular red alga, Cyanidium caldarium

Extracts of the phycocyanin-containing unicellular red alga, Cyanidium caldarium, catalyzed enzymatic cleavage of the heme macrocycle to form the linear tetrapyrrole bilin structure. This is the key first step in the branch of the tetrapyrrole biosynthetic pathway leading to phycobilin photosynthetic accessory pigments. A mixed-function oxidase mechanism, similar to the biliverdin-forming reaction catalyzed by animal cell-derived microsomal heme oxygenase, was indicated by requirements for O2 and a reduced pyridine nucleotide. To avoid enzymatic conversion of the bilin product to phycocyanobilins and subsequent degradation during incubation, mesoheme IX was substituted for the normal physiological substrate, protoheme IX. Mesobiliverdin IX alpha was identified as the primary incubation product by comparative reverse-phase high-pressure liquid chromatography and absorption spectrophotometry. The enzymatic nature of the reaction was indicated by the requirement for cell extract, absence of activity in boiled cell extract, high specificity for NADPH as cosubstrate, formation of the physiologically relevant IX alpha bilin isomer, and over 75% inhibition by 1 microM Sn-protoporphyrin, which has been reported to be a competitive inhibitor of animal microsomal heme oxygenase. On the other hand, coupled oxidation of mesoheme, catalyzed by ascorbate plus pyridine or myoglobin, yielded a mixture of ring-opening mesobiliverdin IX isomers, was not inhibited by Sn-protoporphyrin, and could not use NADPH as the reductant. Unlike the animal microsomal heme oxygenase, the algal reaction appeared to be catalyzed by a soluble enzyme that was not sedimentable by centrifugation for 1 h at 200,000g. Although NADPH was the preferred reductant, small amounts of activity were obtained with NADH or ascorbate. A portion of the activity was retained after gel filtration of the cell extract to remove low-molecular-weight components. Considerable stimulation of activity, particularly in preparations that had been subjected to gel filtration, was obtained by addition of ascorbate to the incubation mixture containing NADPH. The results indicate that C. caldarium possesses a true heme oxygenase system, with properties somewhat different from that catalyzing heme degradation in animals. Taken together with previous results indicating that biliverdin is a precursor to phycocyanobilin, the results suggest that algal heme oxygenase is a component of the phycobilin biosynthetic pathway.     

Nitrate reductase and glutamine synthetase activities,nitrate and ammonia assimilation,in the unicellular alga Cyanidium caldarium

Nitrogen-limited continuous cultures of Cyanidium caldarium contained induced levels of glutamine synthetase and nitrate reductase when either nitrate or ammonia was the sole nitrogen source. Nitrate reductase occurred in a catalytically active form. In the presence of excess ammonia, glutamine synthetase and nitrate reductase were repressed, the latter enzyme completely. In the presence of excess nitrate, intermediate levels of glutamine synthetase activity occurred. Nitrate reductase was derepressed but occurred up to 60% in a catalytically inactive form.Cell suspensions of C. caldarium from nitrate- or ammonialimited cultures assimilated either ammonia or nitrate immediately when provided with these nutrients. In these types of cells, as well as in cells grown with excess nitrate, the rate of ammonia assimilation was 2.5-fold higher than the rate of nitrate assimilation. It is proposed that the reduced rate at which nitrate was assimilated as compared to ammonia might be due to regulatory mechanisms which operate at the level of nitrate reductase activity.     

Pattern of inhibition of nitrate utilization by ammonium in the acidophilic thermophilic unicellular alga Cyanidium caldarium

Ammonium-induced inhibition of nitrate utilization was monitored in cell suspensions of the unicellular alga Cyanidium caldarium. It was found that the inhibition followed an exponential pattern with a t _1/2 value of about 1.5 min in cells previously grown under conditions of excess nitrate, and of about 15 min in cells grown under conditions of severe nitrate limitation. In the latter cells only, a pretreatment with cycloheximide greatly increased the t _1/2 value of inhibition. Also the resumption of nitrate utilization when ammonium was depleted followed an exponential pattern with a t _1/2 value of about 4.5 min.Our results are consistent with the hypothesis that inhibition of nitrate utilization occurs at the level of nitrate reductase activity.     

Mechanism of proton-linked nitrate uptake in Cyanidium caldarium,an acidophilic non-vacuolated alga

The unicellular non-vacuolated alga Cyanidium caldarium, grown under conditions of nitrogen limitation, possesses two permease systems for nitrate uptake, one of which, the so-called ‘high-affinity nitrate uptake system’, enables the alga to take up nitrate through a mechanism involving cotransport of protons. Measurements of nitrate and proton stoichiometry, and determination of the kinetic parameters of uptake in cells resuspended in medium adjusted at different pH values, are consistent with a mechanism of uptake in which two protons for each nitrate ion are transported across the plasmalemma. Furthermore, kinetic data suggest that the carrier first binds nitrate and, subsequently, protons. Permutations of this binding sequence do not agree with the experimental results.     

Studies on utilization of 2-ketoglutarate,glutamate and other amino acids by the unicellular alga Cyanidium caldarium

Two strains of Cyanidium caldarium which possess different biochemical and nutritional characteristics were examined with respect to their ability to utilize amino acids or 2-ketoglutarate as substrates.One strain utilizes alanine, glutamate or aspartate as nitrogen sources, and glutamate, alanine or 2-ketoglutarate as carbon and energy sources for growth in the dark. The growth rate in the dark on 2-ketoglutarate is almost twice as high or higher than that on glutamate or alanine. During growth or incubation of this alga on amino acids, large amounts of ammonia are formed; however, ammonia formation is strongly inhibited by 2-ketoglutarate. The capacity of the alga to form ammonia from amino acids is inducible and develops fully only when the cells are grown or incubated in the presence of glutamate.By contrast, the other strain of Cyanidium caldarium cannot utilize alanine or aspartate as nitrogen sources. It utilizes glutamate only very poorly and does not excrete ammonia into the external medium. This strain is unable to utilize amino acids or 2-ketoglutarate as carbon and energy sources for heterotrophic growth.Cell-free extracts were tested for the occurrence of enzymes which could account for amino acid metabolism and ammonia formation.     

Effect of L-methionine-DL-sulphoximine, a specific inhibitor of glutamine synthetase, on ammonium and nitrate metabolism in the unicellular alga Cyanidium caldarium

In the unicellular alga Cyanidium caldarium nitrate utilization is strongly inhibited by ammonium and it is resumed when ammonium has been depleted. In the presence of L-methionine-DL-sulphoximine (MSX), which prevents ammonium assimilation through a specific irreversible inhibition of glutamine synthetase, nitrate reduction is no longer inhibited by ammonium, and most of the ammonium derived from nitrate reduction is excreted into the external medium. However, in the presence of MSX, nitrate reduction to ammonium proceeds at a reduced rate (45 to 70% of the control); this is particularly marked at low nitrate concentration. It is hypothesized that either MSX or accumulating ammonium bring about decrease in the rate of nitrate entry into the cell.